Puna vegetation Moquegua S Peru: Chasmophytes, grasslands, Puya raimondii - Montesinos et al. 2015 by JPZ.

Phytocoenologia Vol. 45 (2015), Issue 4, 365–397 Stuttgart, December 2015

Research Paper

The Puna vegetation of Moquegua, South Peru: Chasmophytes, grasslands and Puya raimondii stands Daniel B. Montesinos-Tubée*, Antoine M. Cleef & Karlé V. Sýkora Abstract: The phytosociology and ecology of puna vegetation in twelve localities at an altitude of 3750–4500 m in northern Moquegua (south Peru) have been studied. The study area has a pluviseasonal climate with summer rainfall. Using TWINSPAN, Detrended Correspondence Analysis and Farthest Neighbor Clustering, 157 phytosociological relevés were analyzed. For each community, the syntaxonomy, floristic diversity and relation with environmental variables are discussed. 210 vascular plant species belonging to 131 genera and 52 families were recorded. Three main vegetation types were distinguished: 1. chasmophyte vegetation composed of a great diversity of shrubs, dwarf shrubs, ferns and annuals, 2. Puya raimondii stands characterized by considerable species richness in shrubs, grasses and herbs, and 3. extensive puna grasslands influenced by grazing. The zonal vegetation of the supratropical and orotropical bioclimatic belts was represented by two phytosociological classes: Argyrochosmetea niveae (chasmophytes) and Calamagrostietea vicunarum (Puya raimondii and puna grasslands). Within the Argyrochosmetea niveae and Salpichroetalia glandulosae, the new alliances Argyrochosmo niveae-Neowerdermannion peruvianae and Hypochaerido mucidae-Loricarion graveolentis were distinguished, including six associations consisting of steep rock and crevice shrublands on lithosols. Within the Azorello compactae-Festucion orthophyllae (Calamagrostietea vicunarum) two associations with four subassociations and two communities were distinguished comprising grasslands and Puya raimondii stands. One association was described in the Calamagrostion minimae. The puna vegetation of Moquegua hosts rare, endangered and/or protected plant species in Peru. The vulnerability of the flora and vegetation in the mountains of Moquegua is briefly discussed. Keywords: Andes, Argyrochosmetea niveae, Calamagrostietea vicunarum, Peru, phytosociology, syntaxonomy. Nomenclature: Tropicos.org (http://www.tropicos.org; accessed January 2015; further referred to as Tropicos) and The Plant List, Version 1 (http://www.theplantlist.org; accessed January 2015) except for Solanaceae where the PBI Solanum Project 2014 (http://www.solanaceaesource.org; accessed November 2014) was used. Submitted: 19 May 2014; revised version submitted: 15 January 2015; final revision submitted: 23 September 2015; accepted: 24 September 2015 Co-ordinating Editor: Erwin Bergmeier

dominated by dwarf grasses, rosettes and cushion plants, although these occur also in the puna albeit with lower frequency. For the evergreen shrub formations occurring above 4200 m, Weberbauer (1945) used the term tolares. In the traditional vegetation classification for Bolivia, the term ‘puna’ has been used for the vegetation of the high plateaus of the Central Andes (Beck & García 1991; García & Beck 2006). Kuentz et al. (2007) characterized the southern Andes of Peru as ‘mountainous steppe and

Introduction Puna is the name given to extensive highlands in the central and southern Andes of South America and particularly to their distinctive alpine grassland vegetation (Cabrera 1968; Navarro 1993; Galán de Mera et al. 2003, 2009, 2011, 2014; García & Beck 2006; Montesinos et al. 2012). Weberbauer (1912, 1945) distinguished the puna from the vegetation of the Altiplano plateaus, which is

*Corresponding author‘s address: Nature Conservation and Plant Ecology Group, Wageningen University, The Netherlands; daniel. montesinos@wur.nl. Complete addresses of all authors can be found at the bottom of the paper. © 2015 Gebrüder Borntraeger, 70176 Stuttgart, Germany DOI: 10.1127/phyto/2015/0006

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puna’, and considered the puna to be dry vegetation located on the Altiplano and on the mountain slopes, above 3000 m. The tropical Andes belong to the world’s biodiversity hotspots (Myers et al. 2000). The dry puna is one of its largest pastoral ecosystems, with a unique assemblage of shrubs, tussock grasses, cushion and matforming species (Smith 1994). The floristic composition of the dry puna of South Peru is affected by grazing (Catorci et al. 2014). In the north of Moquegua (in south Peru) the puna vegetation is influenced by the rainy season (December to April) and is characterized by shrubs, dwarf shrubs, tussock grasses, annual herbs and ferns. Most of the Peruvian puna grasslands are grazed by livestock (predominantly llamas and alpacas) (Wilcox et al. 1986). The continuous fumarolic activity of the Ubinas volcano (Rivera et al. 2014) could have strong negative effects on the plant communities in north Moquegua. The term chasmophyte (Antonsson 2012) refers to plant species that grow in crevices on steep rocky slopes with lithosols. Although relatively species-poor, the vegetation of alpine rock communities is of great interest as it is adapted to harsh and extreme environments (Nowak et al. 2014a, 2014b) in which many endemics can be found. With seepage or run-off water, rocks can offer wet microhabitats even in dry areas (Deil 2014) and as such usually host species, including several endemics, which do not occur in adjacent ecosystems. Other authors (Mucina et al. 1990; Escudero 1996; Caiafa & Da Silva 2007) present important studies of chasmophytic vegetation and the significance of their functional role. In Peru, Gutte (1986) and Galán de Mera et al. (2003, 2014) identified different plant communities of chasmophytic vegetation in the Arequipa and Tacna provinces representing the class Argyrochosmetea niveae. The vegetation of this class develops on basalt crags and includes two orders with an extensive Andean distribution (Seibert & Menhofer 1992). Montesinos et al. (2012) presented an overview of the climatic thermotype zonation of the upper Tambo River in the Moquegua region. Gutte (1986) and Galán de Mera et al. (2003, 2009) described the chasmophyte vegetation of the central and south Andes of Peru. Gutte (1985) and Galán de Mera et al. (2009) also described the phytosociology of the giant bromeliad Puya raimondii. Other authors (Weberbauer 1945; Pedrotti & Venanzoni 1986; Venero 2001; Sgorbati et al. 2004; Vadillo et al. 2007; Lambe 2009; Hornung-Leoni et al. 2013; Vargas Sierra 2013; Montesinos-Tubée 2014) also refer to the presence of this vegetation and the genetic variation of P. raimondii in Peru and Bolivia. The stands of P. raimondii commonly known in Spanish as ‘rodales’, were recently inventoried in the Moquegua region by Montesinos-Tubée (2011a, 2014). In addition, several authors have studied the vegetation of the puna in the Central Andes: Galán de Mera et al. (2002, 2003, 2004, 2009, 2011, 2012, 2014), Gutte (1980, 1985, 1986, 1987, 1988, 1995), Lambrinos et

al. (2006), Luebert & Gajardo (2000, 2005), Montesinos et al. (2012), Montesinos-Tubée et al. (2015), Navarro (1993), Navarro & Maldonado (2005), Rivas-Martínez & Tovar (1982), Ruthsatz (1977), Seibert & Menhofer (1991, 1992, 1993). However, prior to the present research, the ecology and vegetation structure of the high Andes of north Moquegua had not been studied (Montesinos et al. 2012). Thus, the aim of this article was to: (a) perform a syntaxonomic characterization of puna vegetation in South Peru, based on full and synoptic tables, (b) determine the distribution of chasmophytic and grassland vegetation in Moquegua (South Peru), (c) find an explanation for their rare and local occurrence as well as floristic diversity, and (d) evaluate the importance of Puna rocky slopes, cliffs and grasslands as habitats for specific vegetation types, and for some endemic plant species in Moquegua (South Peru). We hypothesize that environmental factors such as altitude, slope aspect and inclination, cover of rocks and stones, and soil properties as well as the disturbance caused by grazing and fire are important environmental factors affecting the diversity and species composition of the puna vegetation. The relations between plant communities and these factors are described. The present contribution is an extension of the study by Montesinos et al. (2012) that described the prepuna vegetation found at an altitude between 3470 m and 3700 m in the Moquegua department. The study here extends the previous observations and represents the altitudinal range from 3750 m to 4500 m.

Study area The research was conducted in an area of approximately 550 km² in the districts of Ichuña, Ubinas and Yunga, in the General Sánchez Cerro province in the north of the department of Moquegua, South Peru, located between 70°44’33”, 26’59” W and 16° 06’37”, 16’30” S (Fig. 1, Table 1). Average annual precipitation at the Ichuña meteorological station (at 3790 m) is 460 mm with over 80% of the annual rainfall between December and April. The mean annual minimum temperature is 3.7 °C and the mean annual maximum is 19.4 °C (SENAMHI 2013). Precipitation is markedly seasonal. Soil moisture ranges from 0 in the dry season to below 10% in the rainy season (Montenegro et al. 2010). The study area is located in the high altitude sectors of the northwest Andes between 3750 m and 4500 m. The bedrock is volcanic and sedimentary with intercalations of conglomerates and sand; ravines and crevices have infill of sandy silt and calcareous sediment (EIAS-PEC 2009). The fieldwork area comprises the grasslands and rocky slopes of the two mountain chains of volcanic origin that eschweizerbart_xxx

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Fig. 1. Location of the upper reaches of the Tambo and Ichuña rivers in the Andes of Moquegua, Peru. The black broken lines indicate the district boundaries. The numbers show the locations of the studied sites as listed in Table 1. Image source: Landsat 7 Enhanced Thematic. Mapper (ETM+) Acquisition date = 10 May, 2001. Glovis Visualization Portal (http://www.glovis. usgs.gov), a part of the Earth Resources and Science Center (EROS) of the USGS.

form the watersheds of the upper Tambo, Sefincane, Paltuture and Ichuña rivers and their tributaries.

mogeneity of the vegetation as well as on the presence of shrubs such as Plazia daphnoides). For each relevé, the presence of species was noted and their percentage cover was estimated (Mueller-Dombois & Ellenberg 1974; Knapp 1984). For computer calculations the percentage values were transformed into a nine-point ordinal cover/ abundance scale (Westhoff & Van der Maarel 1973): 1% = 1; 2% = 2; 3% = 3; 4–7% = 4; 8–20% = 5; 21–37% = 6; 38–68% = 7; 69–88% = 8 and 89–100% = 9. In chasmophytic and grassland units we noted the cover by vascular plants only. The presence of bryophytes and lichens was noted, but the species were not identified. We ensured that no sample plots traversed ravines, clefts or streams. In chasmophytic environments, sample plots were selected on bare rock that included soil pockets and crevices but had no contact with grassland vegetation. For each relevé we collected data on altitude (meters above sea level = m a.s.l.), slope inclination (degrees) and slope aspect (compass), cover of rocks and stones (per-

Methods Data collection, phytosociological classification and data analysis The sample plots were preferentially selected adopting homogeneity criteria as defined by the Zürich-Montpellier method (Braun-Blanquet 1979) and stratified by rocky cliffs, scrubland, grassland with tussocks and Puya raimondii vegetation. Fieldwork was conducted during March and April in four years: 2009, 2011, 2012 and 2013. A total of 166 relevés was made in 12 sites. The plot size was 25 m² or 36 m² for grasslands and Puya raimondii stands and 1 m², 4 m² or 25 m² for chasmophyte communities (plot size depended on accessibility of sites and hoeschweizerbart_xxx

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Table 1. Overview of parameters for each research site (1–12) in the puna of the Andes of Moquegua, Peru. #rels. = number of relevés at the site in question, year = year(s) in which fieldwork was done, Elevation = altitudinal range where the relevés were set out, Slope = slope angle. #

Locality

District # rels.

Year

Lat S

Lon W Elevation (m) Slope (°) Aspect Environment

Tolapampa

Ichuña

2012

16°09’ 70°27’

4000–4250

30–90

E-S

grassland, chasmophyte

Italpallune

Ichuña

2009

16°09’ 70°29’

3900–4050

30–45

N-NNE

grassland

Rocky slopes near Ichuña

Ichuña

2009

16°08’ 70°32’

3800–4050

30–80

S-SW, N

grassland, Puya raimondii

Yanapuquio – Condorwasi (Yanahuara locality)

Ichuña

2012

16°06’ 70°33’

4250–4500

40–60

grassland, chasmophyte

Santa Cruz de Oyo Oyo

Ichuña

2009

16°10’ 70°34’

4050–4250

40–50

N-NW

Puya raimondii

Sefincane

Ichuña

2013

16°09’ 70°39’

3950–4000

60–80

S-W

chasmophyte

Coalaque

Ubinas 9

2009

16°05’ 70°44’

4300–4500

15–30

grassland

Pirhuani, Rancho, Ubinas 30 Punku (Tassa locality)

2009– 16°10’ 70°42’ 2013

3900–4470

30–50

N-NE, grassland, SW-SE Puya raimondii

Patune

Ubinas 16

2011– 16°11’ 70°43’ 2012

4050–4200

10–80

S, W

grassland, chasmophyte

10 Qellepunku

Ubinas 6

2013

16°12’ 70°42’

3750–3850

50–60

chasmophyte

11 Kasullama – Sura

Yunga

2009– 16°11’ 70°39’ 2013

3900–4500

5–100

N, S, W chasmophyte, Puya raimondii

12 Pampilla

Yunga

2013

4100–4250

5–35

N, W

16°13’ 70°41’

grassland, chasmophyte

calculations, constancy class values (1–5) were used, both in our communities and in those from referenced sources. In total, 76 communities were included in the analysis. All species were used, except casual ruderals and introduced species. The Farthest Neighbor Clustering was done on the basis of the communities 1–31 and 275 species (Appendix 1) which included species and community types found by Navarro (1993), Luebert & Gajardo (2005) and Galán de Mera et al. (2003, 2009, 2011). The first cluster analysis revealed an outgroup (45 communities by Gutte 1985, 1986; Seibert & Menhofer 1991, 1992; Luebert & Gajardo 2000, 2005; Galán de Mera et al. 2003, 2004, 2009, 2012, 2014; Navarro & Maldonado 2005, and Montesinos et al. 2012) which was removed prior to the second run. Detrended Correspondence Analysis (DCA; CANOCO 4.5, Ter Braak & Šmilauer 2002) was used to study the relation between species composition and environmental variables of our own relevés. All 210 vascular plant species were included in the analysis. In the synoptic table (Appendix 1), species constancies are given in percentage values. Full tables are presented as electronic supplement (Supplements S1, S2 and S3). The character and differential species in the description of the communities are mentioned in the order of their diagnostic value. The environmental variables

cent). Within each relevé, five subsamples were taken from the upper 10 cm of the soil and combined into one bulked sample for pH analysis in the laboratory (only for the relevés done in 2009). The presence of manure was determined by the amount of dung found in each relevé and classed as 0: absence; I: 1–30%; II: 31–70%; III: >71% (dung cover). Grazing intensity was determined by the percentage of tussock grasses showing signs of grazing at the moment of field analysis, and was later transformed into I-III values. Newly described syntaxa were named and formed according to the rules of the International Code of Phytosociological Nomenclature (Weber et al. 2000) and defined after consulting Galán de Mera (2005). The relevés were classified by means of TWINSPAN (Hill 1979) and 15 groups were selected from the divisions. Syntaxonomic vegetation tables were constructed and a Farthest Neighbor Clustering was performed (PC-ORD, Sørensen, Bray-Curtis Distance Measure) (McCune & Mefford 1999) to show the hierarchical similarity structure of the syntaxa and to compare related communities from literature (Peru: Rivas-Martínez & Tovar 1982; Gutte 1985, 1986; Galán de Mera et al. 2003, 2004, 2009, 2011, 2012, 2014; Montesinos et al. 2012; Bolivia: Seibert & Menhofer 1991, 1992; Navarro 1993, Navarro & Maldonado 2005; Chile: Luebert & Gajardo 2000, 2005). For eschweizerbart_xxx

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rocks, stones, slope degree and the vegetation cover were presented as box-and-whisker charts and a distribution chart for altitude.

Hypochaerido mucidae-Paronychietum muschleri ass. nov. (Typus: Rel. 49, Supplement S1; Appendix 2) Community of Asplenium triphyllum and Polystichum orbiculatum (Representative relevés: 55-58, Supplement S1)

Floristics Class: Calamagrostietea vicunarum Rivas-Martínez & Tovar 1982 Order: Parastrephietalia lepidophyllae Navarro 1993 Alliance: Azorello compactae-Festucion orthophyllae Galán de Mera, Cáceres & Gonzáles 2003 (Supplements S2, S3) Associations and subassociations: Parastrephio quadrangularis-Festucetum dolichophyllae Galán de Mera 2011 (Appendix 1). Parastrephio lucidae-Festucetum orthophyllae Galán de Mera, Cáceres & Gonzáles 2003 (Appendix 1). Baccharido tricuneatae-Puyetum raimondii Galán de Mera, Linares Perea, Campos de la Cruz & Vicente Orellana 2009 – senecionetosum ferreyrae subass. nov. (Typus: Rel. 10, Supplement S2; Appendix 2) – ageratinetosum sternbergianae subass. nov. (Typus: Rel. 28, Supplement S2; Appendix 2) – lupinetosum cuzcensis subass. nov. (Typus: Rel. 35, Supplement S2; Appendix 2) – calamagrostietosum heterophyllae subass. nov. (Typus: Rel. 49, Supplement S2; Appendix 2) Sisyrinchio rigidifolii-Parastrephietum quadrangularis ass. nov. (Typus: Rel. 3, Supplement S3; Appendix 2) Community of Misbrookea strigosissima and Stipa ichu (Representative relevés: 21-29, Supplement S3) Community of Plagiobothrys humilis and Stipa ichu (Representative relevés: 30-38, Supplement S3) Alliance: Calamagrostion minimae Rivas-Martínez & Tovar 1982 (Supplement S3) Baccharido caespitosae-Azorelletum diapensioidis ass. nov. (Typus: Rel. 42, Supplement S3; Appendix 2)

The plant species were identified directly in the field; unidentified species were collected and later deposited in various herbaria (USM, HUSA, MOL, CPUN, HUPCH, CUZ, HSP, MO, L; for codes see Index Herbariorum, http://ciweb.nybg.org/science2/IndexHerbariorum.asp). Information on the taxonomy and species distribution were obtained from the literature (Arakaki & Cano 2003; Brako & Zarucchi 1993; Franco et al. 2004; Galán de Mera et al. 2003, 2009, 2012; Linares Perea 2005; Schwarzer et al. 2010; Talavera 2010; Ostolaza 2011; Montesinos-Tubée 2011a, 2012, 2013a,b; Montesinos et al. 2012; Britto & Arana 2014; Freire et al. 2014). Hypochaeris mucida occurs in our study area as its variety integrifolia. This taxon occurs in the Peruvian departments of Puno (southern part) and Moquegua (northern part); see also Brako & Zarucchi (1993), Beltrán et al. (2007), Tropicos. Plantago sericea occurs as its subspecies sericea which is distributed in the central and south Andean mountains of Peru (Rahn 1981; Brako & Zarucchi 1993; Tropicos).

Results and discussion Syntaxonomic overview Class: Argyrochosmetea niveae Gutte 1986 Order: Salpichroetalia glandulosae Galán de Mera, Cáceres & González 2003 Alliance: Argyrochosmo niveae-Neowerdermannion peruvianae all. nov. (Typus: Neowerdermannio peruvianaeFestucetum weberbaueri Montesinos-Tubée, Cleef & Sýkora hoc loco) Associations: Plantagini sericeae-Plazietum daphnoidis ass. nov. (Typus: Rel. 5, Supplement S1; Appendix 2) Phacelio secundae-Ribesetum brachybothryos ass. nov. (Typus: Rel. 9, Supplement S1; Appendix 2) Neowerdermannio peruvianae-Festucetum weberbaueri ass. nov. (Typus: Rel. 19, Supplement S1; Appendix 2)

Chasmophytic vegetation (Argyrochosmetea niveae) The class Argyrochosmetea niveae comprises the vegetation growing in rock crevices and on cliffs in the central Andean mountains. Gutte (1986) described the class Argyrochosmetea niveae as occurring at an altitude of 2500– 3500 m in Junin (Central Peru), with Argyrochosma nivea, a species characteristic of rock crevices. Galán de Mera et al. (2003) confirmed the presence of this species in the south of Peru, and we refer to the Argyrochosmetea niveae based on the occurrence of certain common chasmophytes such as Argyrochosma nivea, Cheilanthes pilosa, Cystopteris fragilis and Woodsia montevidensis. Galán de Mera et al. (2012) refers to the alliance Cheilanthion pruinatae as commonly occurring on constructed

Alliance: Hypochaerido mucidae-Loricarion graveolentis all. nov. (Typus: Hypochaerido mucidae-Paronychietum muschleri Montesinos-Tubée, Cleef & Sýkora hoc loco) Associations: Hypochaerido mucidae-Valerianetum nivalis ass. nov. (Typus: Rel. 24, Supplement S1; Appendix 2) Paronychio ubinensis-Hypochaeridetum mucidae ass. nov. (Typus: Rel. 34, Supplement S1; Appendix 2) eschweizerbart_xxx

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rock walls near Andean roads and on the edges of agricultural terraces. However, we consider Cheilanthes pruinata to be only a companion species, because of its occurrence outside chasmophytic habitats and its common presence in grasslands and scrublands. The character species of the Argyrochosmetea niveae (Woodsia montevidensis, Cheilanthes pruinata, Cystopteris fragilis and Bromus catharticus) are considered to be widely distributed in both temperate and non-temperate regions (Tryon & Stolze 1989, 1991; Tropicos). We identified these species in different ecosystems ranging from arid ecosystems to the superpuna. In this paper we classify them as companions which are not particularly characteristic of the chasmophytic class Argyrochosmetea niveae as they also occur in other classes. The communities we describe in the present paper under Argyrochosmetea niveae have some character species in common with the Senecioni culcitioidis-Valerianetum nivalis (Galán de Mera et al. (2003), Woodsio montevidensis-Cheilanthion pruinatae (Galán de Mera et al. 2012) and Asplenio triphylli-Melpomenetum moniliformis (Galán de Mera et al. 2014) from the Belloo schultzii-Salpichroion glandulosae as described by Galán de Mera et al. (2003, 2012), such as Asplenium peruvianum, Asplenium triphyllum, Belloa schultzii, Cheilanthes pruinata, Galium corymbosum, Salpichroa glandulosa, Valeriana nivalis, Woodsia montevidensis, and the companion Ribes brachybothrys, but were described from undisturbed rocky slopes, have a very different species composition and greater species richness. The order Salpichroetalia glandulosae includes the chasmophyte vegetation of steep basalt cliffs from south Peru. In Moquegua it is represented at altitudes ranging from 3750 to 4500 m. Character species: Belloa schultzii, Bomarea dulcis, Cheilanthes pilosa, Luzula racemosa, Pellaea ternifolia, Peperomia scutellaefolia, Ribes brachybothrys, Salpichroa glandulosa, Saxifraga magellanica and Senecio sublutescens. A number of chasmophytic associations and communities (3–7, Appendix 1) gradually appear and may cooccur up to 4500 m. The Phacelio secundae-Ribestum brachybothrys occurs throughout the zone of the puna grasslands.

district, where its boundaries are with the puna communities of Calamagrostietea vicunarum (Rivas-Martínez & Tovar 1982). The alliance is distributed between 3750 and 4500 m. Based on 22 relevés we distinguished three new associations that grow on steep rocky slopes where basalt cracks that contain subhumid soils. Character and differential species: The alliance is characterized by Argyrochosma nivea, Neowerdermannia peruviana and Phacelia pinnatifida. Differential species against the other chasmophytic alliance are Coreopsis fasciculata, Oxalis megalorrhiza, Spergularia fasciculata, Stipa ichu and Tillandsia capillaris. The new alliance of Argyrochosmo niveae-Neowerdermannion peruvianae is based on the characteristic cooccurrence of the fern Argyrochosma nivea and Neowerdermannia peruviana, the latter being an endemic species of cactus in the Moquegua and Tacna regions (Brako & Zarucchi 1993; Arakaki et al. 2006; Montesinos-Tubée 2011b). This alliance comprises three new associations with a species combination never previously reported in phytosociological studies. Plantagini sericeae-Plazietum daphnoidis (Appendix 1, col. 1; Fig. 2) Physiognomy and composition: Chasmophytes growing (sometimes abundantly) in rock crevices with fissures in steep basalt cliffs and composed of shrubs (0.4–1.5 m), annual herbs, ferns and grasses. The vegetation cover is 15–20%. The shrub layer is composed of Plazia daphnoides and, with less cover, also of Lophopappus tarapacanus and Salpichroa glandulosa. In the herb layer, annuals less than 15 cm tall, such as Cardionema ramosissimum, Galium corymbosum, Hieracium streptochaetum, Oxalis megalorrhiza and Peperomia scutellaefolia are common. The dwarf shrub Plantago sericea and the tussock grass Stipa ichu (1 m tall) are constant. The dwarf cactus Neowerdermannia peruviana has low cover. Several fern species can be found on these rocky slopes, together with a varied cover of bryophytes. Character and differential species: Character species are Plantago sericea, Plazia daphnoides and Polypodium pycnocarpum. Cheilanthes scariosa, Cheilanthes myriophylla, Aa matthewsii and Pellaea ternifolia. Crassula connata, Hieracium streptochaetum, Muhlenbergia peruviana and Tagetes multiflora are differential species against the other communities of the ArgyrochosmoNeowerdermannion. Other differential species with low cover include: Lophopappus tarapacanus, Oreocereus hendriksenianus, Puya ferruginea, Triniochloa stipoides. Ecology and distribution: The Plantagini sericeae-Plazietum daphnoidis grows at 3750–3850 m on 50–60° SWfacing outcrops. It occurs between the Echinopsio schoenii-Proustietea cuneifoliae at lower altitudes and the Calamagrostietea vicunarum at higher altitudes. The metamorphic rock outcrops are widespread on the upper Tambo River valley slopes between 3750 and 4000 m.

Alliance: Argyrochosmo niveae-Neowerdermannion peruvianae (Appendix 1, col. 1–3; Fig. 2, 3) Physiognomy, composition and distribution: The alliance is represented by Argyrochosma nivea distributed in rock crevices in the highlands of Peru, Bolivia and NW Argentina (Brako & Zarucchi 1993; Tropicos). Neowerdermannia peruviana is locally distributed in the highlands of the departments of Moquegua and Tacna (Brako & Zarucchi 1993; Montesinos-Tubée 2011b) inhabiting rock crevices. It borders on the Echinopsio-Proustietea from the prepuna communities (Montesinos et al. 2012) in the Ubinas and Yunga districts except in the Ichuña eschweizerbart_xxx

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Phacelio secundae-Ribesetum brachybothryos (Appendix 1, col. 2; Fig. 3) Physiognomy and composition: Vegetation cover can reach up to 40%, with high frequency of shrubs and annuals. The shrub layer (0.8–1.5 m) is composed of Bomarea dulcis, Ribes brachybothrys and Salpichroa glandulosa. In general, the herb layer is no taller than 10 cm, only Valeriana interrupta can reach 30 cm. Dwarf shrubs with a height of 1–10 cm consist of Belloa piptolepis, Paronychia weberbaueri and Senecio klattii. Ferns and bryophytes are less abundant and less frequent. The cushion-forming Azorella compacta develops within rock crevices, sometimes on near-vertical surfaces. This association is classified on the basis of ten relevés with a total of 27 vascular plant species. Character and differential species: Character species are Phacelia secunda and with a very low frequence also Paronychia weberbaueri and Senecio klattii. The latter two species despite having a low frequency are only known to occur in this community. Bomarea dulcis and Ribes brachybothrys are differential within the Argyrochosmo niveae-Neowerdermannion peruvianae. Ecology and distribution: The vegetation grows at 4100–4500 m, on E, S and SE-facing slopes with an inclination of 30–90°. The clayey soils on the rocky slopes are characterized by high concentrations of iron oxides and are also known as Ultisols (USDA classification). They can be found in the Ichuña River valley at the boundary with grassland vegetation above 4000 m.

and Festuca weberbaueri. Differential species within the alliance are Achyrocline alata, A. ramosissima, Aristeguietia ballii, Asplenium peruvianum, Bartsia peruviana, Bowlesia lobata, Calceolaria lobata, Chersodoma jodopappa, Hypochaeris meyeniana, Paronychia andina, Spergularia fasciculata, Vasquezia oppositifolia and Viguiera procumbens. The character species of the alliance Neowerdermannia peruviana has its highest presence in this association. The same applies for Senecio sublutescens and Woodsia montevidensis which are character species of the class and order. Ecology and distribution: The crevices and cracks of the steep rock slopes contain soil deposits of silty clay particles with iron oxides. They can be found at an altitude of 3950–4100 m. on S and W. facing, steep (60–80°) rocky slopes on the east side of the Paltuture River at the boundary between the Ubinas and Ichuña districts. The vegeteation has a higher cover and the species diversity is higher than in other chasmophytic units. Alliance: Hypochaerido mucidae-Loricarion graveolentis (Appendix 1, col. 4–6; Fig. 4, 5) Physiognomy, composition and distribution: This alliance combines the vegetation growing on shallow soils from rock plateaus and rock crevices in the north of Moquegua, South Peru. One of the characteristic species, Hypochaeris mucida, is almost restricted to this geographical region (but is expected to occur also in the south of Puno department and probably in SW Bolivia) (Brako & Zarucchi 1993, Montesinos-Tubée 2012, Tropicos). Between 4000 to 4500 m this species has an extensive distribution on the slopes of the tributaries and dry ravines of the upper Tambo and Ichuña Rivers. The other species, Loricaria graveolens, is an erect or hanging dwarf shrub with scale-like leaves, pubescent and strongly aromatic. This species inhabits rocky slopes, crevices or grows on superficial soils; its geographical distribution comprises central and southern Peru (Brako & Zarucchi 1993, Tropicos). Character and differential species: Character species are: Belloa kunthiana, Hypochaeris mucida and Loricaria graveolens. Species such as Bomarea dulcis, Calamagrostis vicunarum, Cerastium subspicatum and Cheilanthes pilosa are differential against the Argyrochosmo niveaeNeowerdermannion peruvianae. The absence of Salpichroa glandulosa and Stipa ichu is characteristic. Except for the common Valeriana nivalis, we found little floristic similarity with the Chersodomo diclinaeValerianetum nivalis occurring in Tacna and Puno Regions (Galán de Mera et al. 2003). The Hypochaerido mucidae-Loricarion graveolentis comprises the vegetation from shallow soils and rock crevices at higher altitudes; it is dominated by the endemic ground rosette plant Hypochaeris mucida, a biannual herb with dense pubescence on both surfaces of the leaves. The presence of this species is restricted to the south of Puno (Brako &

Neowerdermannio peruvianae-Festucetum weberbaueri (Appendix 1; col. 3) Physiognomy and composition: High diversity of shrubs, annual herbs and tussock grasses. The abundance of the dwarf cactus Neowerdermannia peruviana (1–4 cm, 8–12%) and the tussock grass Festuca weberbaueri are characteristic of this community. The shrub layer is composed of Aristeguietia ballii, Clinopodium bolivianum, Coreopsis fasciculata, Salpichroa glandulosa, Senecio sublutescens and Viguiera procumbens, reaching up to 1.6 m in height. Several annuals, the most frequent of which are Peperomia scutellaefolia and Vasquezia oppositifolia, compose the herb layer. The ferns Asplenium peruvianum, Cheilanthes pruinata, Elaphoglossum minutum, Argyrochosma nivea and Woodsia montevidensis, are also present (10–20 cm, 4–8%). Grasses are represented by Bromus catharticus and Stipa ichu. Bryophytes and lichens are common. Noteworthy is the presence of the 1–1.6 m high resinous shrubs of Aristeguietia ballii with a cover of 10–20% growing abundantly in rock crevices. This species has aromatic dark green leaves and pink flowers. In this association 41 vascular plant species have been noted. Character and differential species: Character species are Asplenium peruvianum, Campyloneurum amphostenon, Echeveria peruviana, Elaphoglossum minutum eschweizerbart_xxx

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Zarucchi 1993) and the north of Moquegua department (Montesinos-Tubée 2011a). In the Moquegua region it is especially common on rocky slopes, where it is restricted to rock crevices and shallow soils. Here, in association with species such as Loricaria graveolens, it forms dense and extensive communities that do not occur in grasslands. The new association Paronychio ubinensis-Hypochaeridetum mucidae is characterized by the endemic Paronychia ubinensis (Montesinos-Tubée 2013), which grows on shallow soils where several endemics have been found, especially from the Caryophyllaceae.

dina and Valeriana radicata. The grass layer is composed of Bromus catharticus, Calamagrostis vicunarum, Nassella inconspicua with relatively low cover and Luzula racemosa with 10–30 cm height and cover of 2–4%. Character and differential species: Character species are Cerastium sp., Chaetanthera peruviana Paronychia ubinensis and Spergularia andina. Differentials within the alliance are Bartsia crenoloba, Cardionema ramosissimum, Cyperus seslerioides Galium corymbosum, Hypochaeris meyeniana, Lupinus ananeanus, Muhlenbergia peruviana and Plantago sericea var. lanuginosa. Nototriche foetida can be considered character species of the Loricario graveolentis-Pycnophylletum mollis, an association still to be described for the Hypochaerido mucidaeLoricarion graveolentis (Montesinos-Tubée et al., unpubl.). Ecology and distribution: This association is generally found near grasslands and steep rock formations, at edges of slopes or on hilltops. It grows at altitudes of 4120– 4300 m, on slopes with an inclination of 5–40°. The soils contain stones and are of grayish color in the surface layer. These communities can be found on the rocky slopes of the upper Tambo River valley, in the Yunga and Ubinas districts.

Hypochaerido mucidae-Valerianetum nivalis (Appendix 1, col. 4) Physiognomy and composition: Association with low density and diversity of dwarf shrubs, annual herbs, few grasses and ferns. Characteristic are the pubescent-leaved shrubs of Senecio sp. (0.5–1.5 m, cover 5–10%) hanging from rock crevices. The relatively dense, 1–20 cm high layer of annual herbs and dwarf shrubs is dominated by Belloa piptolepis, Cerastium subspicatum, Gnaphalium polium, Hypochaeris mucida, Paronychia andina, Peperomia scutellaefolia, Solanum bukasovii and Valeriana nivalis. The abundance of the grass Nassella inconspicua in combination with the ferns Cheilanthes pruinata and Woodsia montevidensis is diagnostic. Character and differential species: Character species are Valeriana nivalis, Gnaphalium polium, Senecio sp. and Perezia ciliosa. Differential species within the alliance are Solanum bukasovii, Bowlesia lobata, Valeriana interrupta, Cheilanthes pruinata and Woodsia montevidensis. Bomarea dulcis, a characteristic species of the order, also has its highest frequency in this association. Ecology and distribution: This association is widely distributed at 4050–4200 m, growing in crevices, cracks and shallow soils of the dry rocky ravines in the northwest of the upper Tambo River catchment in the Ubinas district. The vegetation of this association extends over convex, wind-exposed slopes with an inclination of 10° to almost 80°. Soils are variable in depth (5–30 cm) and their texture is predominantly clayey-silty.

Hypochaerido mucidae-Paronychietum muschleri (Appendix 1, col. 6) Physiognomy and composition: Chasmophyte vegetation with 80–120 cm tall shrubs hanging from the rock crevices and a cover of 10–20% among Dwarf rosettes and annual herbs cover 10–15% of the surface. The surface is further covered to 4–8% by grasses 60–100 cm tall. The ground layer is dominated by several herbs and dwarf rosettes such as Belloa kunthiana, B. piptolepis, B. schultzii, Cerastium sp., Hieracium streptochaetum, Hypochaeris mucida, Paronychia muschleri and Peperomia scutellaefolia. The grass layer is composed of Bromus catharticus and Calamagrostis vicunarum. Further, 10–20 cm tall ferns (Cheilanthes pilosa and Polystichum orbiculatum) are also present and cover 4–8% of the surface. Bryophytes and lichens are abundant on rock surfaces. Character and differential species: Character species are Paronychia muschleri and an as yet unidentified species of Draba (coll. no. 3186). It is further differentiated against the other associations of this alliance by the species characteristic of the order, Cheilanthes pilosa and Senecio sublutescens. Ecology and distribution: The vegetation of this association grows on steep metamorphic rock surfaces, in fissures and cracks frequently filled with clayey-silty soil deposits. It occurs at 4000–4300 m in the steep ravines of the Yunga district. At its lower limit the Hypochaerido mucidae-Paronychietum muschleri is in contact with the Baccharido tricuneatae-Puyetum raimondii. It also grows above the upper boundary of the chasmophyte community of Plantagini sericeae-Plazietum daphnoidis. In ad-

Paronychio ubinensis-Hypochaeridetum mucidae (Appendix 1, col. 5; Fig. 5) Physiognomy and composition: Association with variable frequency of annual herbs, dwarf shrubs and grasses. It consists of 1–4 cm tall acaulescent herbs and dwarf shrubs with a cover of 20–30% in combination with the 10–30 cm high shrub Loricaria graveolens with a cover of 10–15% and a layer of grasses that reach a height of up to 1 m with 8–12% cover. Among the dwarf shrub layer species with substantial cover are Belloa piptolepis, B. kunthiana, Lupinus ananeanus, Nototriche foetida, Paronychia andina, P. ubinensis and Wahlenbergia peruviana. The herb layer is dominated by Cardionema ramosissimum, Plantago sericea var. lanuginosa, Spergularia aneschweizerbart_xxx

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Fig. 5. Overview of the steep rocky outcrops in the Yunga district where (A) lupinetosum cuzcensis (Baccharido tricuneatoe-Puyetum raimondii) occurs, (B) Paronychio ubinensis-Hypochaeridetum mucidae, at 4400 m and (C) downstream of the Tambo River where the class Echinopsio schoenii-Proustietea cuneifoliae occurs (3500 m) in the Ubinas district.

Fig. 2. Plantagini sericeae-Plazietum daphnoidis (A) on the rocky west-facing slopes of the upper Tambo River (3750– 4000 m) within Echinopsio-Proustietea Montesinos, Cleef & Sýkora (B); (C) represents the Plantaginetalia tubulosae Gutte (Plantagini rigidae-Distichietea muscoidis Rivas-Martínez & Tovar)

Fig. 3. Phacelio secundae-Ribesetum brachybothryos (A) and Sisyrinchio rigidifolii-Parastrephietum quadrangularis (B) at 4000 m near the Ichuña River, close to Tolapampa town.

Fig. 6. The giant bromeliad Puya raimondii (ca. 12 m) occurring in the senecionetosum ferreyrae (Baccharido tricuneatae-Puyetum raimondii), Punku site, Tassa locality, Ubinas district (4030 m).

Fig. 4. Hypochaeris mucida var. integrifolia at 4300 m in Sura, Yunga district.

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dition, it borders the azonal vegetation of Plantaginetalia tubulosae on humid ground.

arid and semi-arid Andes occupying the supratropical and orotropical bioclimates (Navarro 1993). Its area extends over southwest Peru, west of Bolivia, northwest Argentina and northwest Chile. The following are character species of the order: Baccharis tricuneata, Chersodoma jodopappa, Cumulopuntia boliviana subsp. ignescens, Ephedra rupestris, Festuca dolichophylla, Gomphrena meyeniana, Parastrephia quadrangularis, Plantago sericea var. lanuginosa and Tetraglochin cristatum.

Community of Asplenium triphyllum and Polystichum orbiculatum (Appendix 1, col. 7) Physiognomy and composition: The vegetation is characterized by the relatively high density of shrubs, hanging with sprawling stems, characteristic of which are Bomarea dulcis, Loricaria graveolens, Ribes brachybothrys and Senecio sublutescens. The edges are dominated by Calceolaria lobata, Cerastium subspicatum and Stellaria weddellii 10–15 cm tall and reaching 1–2% cover. Ferns are more abundant than in the other chasmophyte communities. Asplenium triphyllum, Cystopteris fragilis, Polystichum orbiculatum and Woodsia montevidensis occur with 2–4% cover. A grass layer is hardly present and only represented by Bromus catharticus, 60–80 cm tall and with 2% cover. Bryophytes and lichens are abundant on the rock surfaces. Character and differential species: It is characterized by the combination of Asplenium triphyllum, Stellaria weddellii, Polystichum orbiculatum and, with low presence, also Descurainia athrocarpa. As there are no own character species this plant community is ranked only to the level of order. Ecology and distribution: The vegetation occurs on humid rocky edges of caves and caverns, frequently with water seeping out of the rocks on slopes with about 70– 90° inclination. It occurs in contact with the vegetation of the Calamagrostietea vicunarum. The sites studied are on steep slopes of the Yunga district and occur at an altitude of 4500 m. The community is restricted to rock sehlters and caverns and probably occurs at other altitudes and in other regions as well.

Alliance: Azorello compactae-Festucion orthophyllae (Appendix 1, col. 8–14; Fig. 5–7) Physiognomy and composition: The alliance is documented here by 89 relevés containing 156 plant species. The communities described are characterized by the high presence and cover of the resinous composite shrub Parastrephia quadrangularis and the spiny Tetraglochin cristatum, together with the constant species Stipa ichu. Character and differential species: Character species for the alliance: Belloa longifolia, Clinopodium bolivianum, Conyza deserticola, Geranium sessiliflorum, Lepechinia meyenii, Lobivia maximiliana, Oxalis calachaccensis, Philibertia lysimachioides, Tarasa nototrichoides and Wahlenbergia peruviana. Within the Azorello compactae-Festucion orthophyllae we distinguish three associations and two rankless plant communities. One of the associations, the Baccharido tricuneatae-Puyetum raimondii, has been subdivided into four subassociations. Ecology and distribution: This alliance dominates large areas in the puna of northern Moquegua and also occurs in the Arequipa, Tacna and Puno departments. In our study region, it occurs at an altitude of 4000–4500 m, where Festuca dolichophylla, Parastrephia quadrangularis, Stipa ichu and Tetraglochin cristatum dominate the landscape. These dry to subhumid grasslands grow on slopes with inclinations of 10–40°, without preference for a particular slope aspect. Grazing intensity varies; a few types of grassland are heavily grazed while others can be considered to be ungrazed. The Azorello compactae-Festucion orthophyllae represents the large tracts of puna grasslands in south Peru, in the Moquegua region where Festuca dolichophylla, Parastrephia quadrangularis and Tetraglochin cristatum are common. Festuca dolichophylla is the tussock grass that dominates the puna grasslands of Moquegua in association with Parastrephia quadrangularis. The latter species is replaced by Parastrephia lucida in the superpuna grasslands above 4500 m a.s.l. The tussock grass distribution is in agreement with Navarro & Ferreira (2004), who recorded Festuca dolichophylla in the subhumid puna of Bolivia at 3500–4000 m and 4500 m and Festuca orthophylla at higher altitudes in the superpuna and subnival puna. Above 4500 m Festuca orthophylla co-occurred with cushion plants such as Azorella and Pycnophyllum.

Grassland and shrubland vegetation of the puna (Calamagrostietea vicunarum) The vegetation of the Calamagrostietea vicunarum grows on clay and loamy clay (rarely on sand) on rocky slopes, plateaus and hills at 3800–4500 m. In the Andean regions of northern Moquegua, it is in contact with scrubland of the class Echinopsio-Proustietea cuneifoliae and upslope with various units of the Anthochloo-Dielsiochloetea. In rocky areas the Calamagrostietea vicunarum is in direct contact with the Argyrochosmetea niveae. The diagnostic species of the class is Calamagrostis vicunarum. As Deyeuxia vicunarum and Deyeuxia minima are considered synonyms of Calamagrostis vicunarum and Calamagrostis minima, respectively (Tropicos, The Plant List), we recommend to retain the names Calamagrostietea vicunarum Rivas-Martínez & Tovar 1982 and Calamagrostion minimae Rivas-Martínez & Tovar 1982, in contrast to the suggestion of Galán de Mera et al. (2014). The order Parastrephietalia quadrangularis combines the puna grasslands, the Parastrephia (‘tolares’) communities and scrublands proper of the central and southern eschweizerbart_xxx

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We found the same co-occurrence in the Andes of north Moquegua and presume that the species also occurs in the high Andes of Arequipa and Tacna.

9–10 m. Asteraceous shrubs together with tussock grasses dominate a 50–100 cm high dense shrub layer. Puya raimondii is particularly prominent in the upper layer, together with a few other species of shrubs such as Ageratina azangaroensis, Baccharis tricuneata, Chersodoma jodopappa, Clinopodium bolivianum, Escallonia myrtilloides, Mutisia orbignyana, Parastrephia quadrangularis, Senecio ferreyrae and S. sublutescens. In the intermediate layer, Puya raimondii grows together with Festuca dolichophylla and Stipa ichu. The cacti Cumulopuntia boliviana subsp. ignescens and Lobivia maximiliana are present in the ground layer. More frequent species in the ground layer are Alstroemeria pygmaea, Belloa piptolepis, Cardionema ramosissimum, Cyperus seslerioides, Euphorbia huanchahana, Galium corymbosum, Hypochaeris chillensis and Oxalis megalorrhiza. The ferns Cheilanthes pruinata, Ch. pilosa and Woodsia montevidensis are present as well. This subassociation is extremely species-rich, with 96 vascular plant species in 15 relevés. Differential species are Ageratina azangaroensis, Bomarea involucrosa, Gomphrena meyeniana, Loricaria graveolens, Perezia pungens, Senecio ferreyrae, Stevia macbridei, and with low frequency also Aphanes andicola, Escallonia myrtilloides, Solanum chamaesarachidium and Triniochloa stipoides. A. andicola and S. chamaesarachidium have been found only in this subassociation, albeit with very low frequency. Ecology and distribution: The subassociation can be found either as extensive vegetation or in small stands. It grows at 3850–4150 m, on rocky slopes with inclinations between 10 and almost 55 degrees. Stands occur in the areas of Yunga and Tassa, upper Tambo River. The senecionetosum ferreyrae is in contact with the chasmophytic association Hypochaerido mucidae-Paronychietum muschleri.

Baccharido tricuneatae-Puyetum raimondii (Appendix 1, col. 8–11; Fig. 5–6) Physiognomy and composition: The association is characterized by the co-occurrence, presence and cover of the giant bromeliad Puya raimondii and the shrub Baccharis tricuneata as described by Galán de Mera et al. (2009). In our study the Baccharido tricuneatae-Puyetum raimondii appears to be notably species-rich: we found 131 plant species in 51 relevés. Character and differential species: Character species are Alstroemeria pygmaea, Baccharis genistelloides, Euphorbia huanchahana, Lupinus paruroensis, Mutisia orbignyana, Puya raimondii, Lophopappus tarapacanus and Solanum fragile. In addition, species such as Achyrocline ramosissima, Calceolaria inamoena, C. lobata, Paronychia setigera, Solanum bukasovii and Valeriana interrupta are differential against the other associations and communities within the alliance. Ecology and distribution: The Baccharido tricuneataePuyetum raimondii, with its stands of giant rosettes, is widespread and presumably restricted to the Andean slopes of southern Peru. The communities develop on steep, subhumid scree slopes in which several species of the Argyrochosmetea niveae also occur. When Puya raimondii establishes, the scree becomes stabilized. The subassociations differ greatly in slope aspect percentage of rock cover and grazing pressure. The importance of the conservation of the endangered giant bromeliad Puya raimondii is widely recognized (Lambe 2009). According to Gutte (1986), Galán de Mera et al. (2009) and this study, Puya raimondii is distributed between 3800–4500 m but its range is expected to extend to even higher altitudes. The Senecioni nutantis-Parastrephietum quadrangularis described by Galán de Mera et al. (2011) is close to the Baccharido tricuneatae-Puyetum raimondii lupinetosum cuzcensis because of the presence of Senecio nutans and Parastrephia quadrangularis. It differs greatly in species composition, however, because of the absence of Festuca orthophylla, Azorella compacta, Senecio spinosus, Lupinus saxatilis, Polylepis rugulosa among other species with lower presence. In addition, it is distinct in its distribution which comprises the Condesuyos province in the Arequipa region.

2. B.-P. ageratinetosum sternbergianae (Appendix 1, col. 9) Physiognomy and composition: Grassland vegetation with a great abundance of shrubs with dominance of tussock grasses and annual herbs. The Puya raimondii rosettes cover 20–40% of the surface. A layer of tall tussock grasses up to 80–140 cm height covers 20–30%. Additionally, shrubs and dwarf shrubs attain 40–60 cm in height; 10–20 cm tall annual herbs and ferns cover 10– 15%. In the upper layer, the dominance of Puya raimondii is noteworthy, together with other species such as Baccharis tricuneata, Chersodoma jodopappa, Parastrephia quadrangularis, Ribes brachybothrys and Clinopodium bolivianum. The cacti are represented by Cumulopuntia boliviana subsp. ignescens and Echinopsis maximiliana. Herbs include species such as Cardionema ramosissimum, Cyperus seslerioides, Galium corymbosum, Hieracium streptochoetum, Hypochaeris chillensis, Tagetes multiflora, Valeriana interrupta and dwarf shrubs by Achyrocline ramosissima, Conyza deserticola and

1. B.-P. senecionetosum ferreyrae (Appendix 1, col. 8; Fig. 6) Physiognomy and composition: Grassland vegetation with high density and diversity of rosette shrubs, tussock grasses and annual herbs. Puya raimondii, a species with 2 to 3.5 (4) m tall stem rosettes with spiny, coriaceous leaves and with huge inflorescences can attain a height of eschweizerbart_xxx

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Fig. 8. Grassland represented by Baccharido caespitosaeAzorelletum diapensioidis (Calamagrostion minimae) at Pirhuani-Rancho, near Tassa locality, at 4400 m.

Fig. 7. Grassland slopes with the community of Misbrookea strigosissima and Stipa ichu, in Yanapuquio, near Condorwasi, Ichuña District (4350 m).

phalium dombeyanum, Hieracium streptochaetum, Hypochaeris meyeniana, Microsteris gracilis, Muhlenbergia peruviana, Olsynium junceum, Oxalis nubigena and Plantago sericea var. lanuginosa. Ferns are almost absent. Differential species: Calamagrostis vicunarum, Calamagrostis violacea, Gnaphalium dombeyanum, Lupinus cuzcensis, Lupinus ananeanus, Lupinus sp. 1, Olsynium junceum, Ourisia muscosa, Oxalis nubigena, Senecio nutans and Valeriana radicata. Ecology and distribution: The Puya raimondii grasslands belonging to the lupinetosum cuzcensis occur at an altitude between 4400–4500 m, on slopes of 20–30°, in the Ubinas, Yunga and Ichuña districts. In this subassociation the spiny rosettes of Puya raimondii reach their altitudinal limit, with inflorescences up to 4 m tall. 4. B.-P. calamagrostietosum heterophyllae (Appendix 1, col. 11) Physiognomy and composition: Grassland vegetation with low density and diversity of shrubs. The 2–3 (10) m tall rosettes of Puya raimondii cover 20–30%. A 40– 80 cm high, dense grass layer is present, dominated by tussock grasses and small shrubs. In the intermediate layer, the dominance of Baccharis tricuneata, Chersodoma jodopappa, Lupinus paruroensis and Parastrephia quadrangularis is characteristic. The ground layer is dominated by Alstroemeria pygmaea, Bowlesia lobata, Cyperus seslerioides, Galium corymbosum, Gilia laciniata, Hieracium streptochaetum, Hypochaeris chillensis, Lepechinia meyenii, Microsteris gracilis and Tarasa nototrichoides. Festuca dolichophylla is absent and instead a variety of other grasses occur, such as Calamagrostis heterophylla, Nassella inconspicua, Poa gymnantha and Stipa ichu. A total of 51 vascular species have been recorded in seven relevés. Differential species: It is characterized by Achyrocline ramosissima, Alstroemeria pygmaea, Calamagrostis heterophylla, Gamochaeta purpurea, Gilia laciniata Laennecia artemisioides, Lepechinia meyenii, Poa gymnantha, Stipa obtuse and Viola micranthella.

Spergularia fasciculata. Dominant grasses are Bromus catharticus, Nassella inconspicua, Festuca dolichophylla and Stipa ichu. This subassociation is very species-rich, having 96 vascular species in 19 relevés. Differential species: This subassociation is characterized by Ageratina sternbergiana, Calandrinia acaulis, Cheilanthes pilosa, Facelis plumosa, Ribes brachybothrys, Stevia mandonii and Weberbauera peruviana, and, but with low cover only, Bougueria nubicola, Cheilanthes arequipensis and Spergularia fasciculata. Ecology and distribution: The subassociation extends over grasslands and rocky crevices along the Ichuña River between 3850 and 4250 m. It is present on convex slopes with inclinations of 10–80°. The soils are comparatively deep, 20–60 cm, with clay in grasslands and with silty clay in rock crevices. 3. B.-P. lupinetosum cuzcensis (Appendix 1, col. 10; Fig. 5) Physiognomy and composition: Dense grassland vegetation, with a variable frequency of spiny rosettes and tussock grasses. The vegetation is composed of three layers: a layer of 2–3.5 (4) m tall leptophyllous shrubs including spiny rosettes, with a cover of 20–35% and an inflorescence of 4 m height; a layer of tall tussock grasses that reach 1–1.3 m with 40–50% cover; and a ground layer consisting of annual herbs and some bryophytes covering 10– 15%. Among the shrub and dwarf shrub species with high cover are Baccharis tricuneata, Lupinus cuzcensis, L. paruroensis, Parastrephia quadrangularis, Puya raimondii, Senecio nutans and Tetraglochin cristatum. The cactus species Cumulopuntia boliviana subsp. ignescens is present with 4–6% cover. Among the grasses are Festuca dolichophylla and Stipa ichu in the shrub layer; in the herb layer are Calamagrostis vicunarum, Galium corymbosum, Gnaeschweizerbart_xxx

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Ecology and distribution: The calamagrostietosum heterophyllae covers grassland slopes with an inclination of 20–40° and a NE exposure, at an altitude of 4100– 4200 m, in the northwest area of the upper Tambo River catchment, in the Ubinas district. As there are fewer rocks and stones, the cover of the vegetation is very high. Soils are predominantly clayey and soil depth varies from 20–50 cm.

strephia quadrangularis (60–80 cm) and Baccharis tricuneata, attaining 30% cover. The absence of Chersodoma jodopappa, the tussock Festuca dolichophylla and the cushion cactus Cumulopuntia boliviana subsp. ignescens are characteristic. The 10–20 cm tall dwarf shrubs Ephedra rupestris and Tetraglochin cristatum cover 4–6%. The ground layer (20% cover) is dominated by rosettes and annual herbs such as Belloa longifolia, B. piptolepis, Calamagrostis vicunarum, Geranium sessiliflorum, Gomphrena meyeniana, Hypochaeris meyeniana, Misbrookea strigosissima, Muhlenbergia peruviana, Oxalis calachaccensis, Plantago sericea var. lanuginosa and Stenomesson sp. Several herbs such as Crassula connata, Geranium sessiliflorum, Belloa sp., Misbrookea strigosissima and Senecio rhizocephalus on sites with accumulated manure indicate intensive grazing. Ferns are absent. Character and differential species: This community is characterized by Misbrookea strigosissima, Stenomesson sp., Senecio rhizocephalus, Belloa sp.1 and Perezia coerulescens, and further weakly differentiated within the alliance by Laennecia artemisioides and Gomphrena meyeniana. Ecology and distribution: The community extends as grassland over large areas on slopes in the north of the Ichuña River at an altitude of 4250–4500 m and can also be found in the upper grasslands of the Yunga district. The slopes mainly face NE with an inclination of about 35°. In general the red to gray clayey soils are 30–60 cm deep. The community is in contact with the chasmophyte vegetation of the Phacelio secundae-Ribesetum brachybothryos. At higher altitude on less steep terrain, grazing by sheep, llamas and alpacas is much more common. The long history of grazing and manuring has favored the presence of the tussocks of Stipu ichu, with small rosettes such as Misbrookea strigosissima and Plagiobothrys humilis. As happens in the high Ecuadorian and Colombian páramos or, at high altitude (4100-4300 m) azonal cushion communities appear on zonal slopes before the transition to superpáramo. They are mainly of Plantago rigida and with less presence of Azorella multifida, and they replace the bunch grassland (e.g. Cuatrecasas 1958, Harling 1979). Increased precipitation and persistent mist seem responsible (Salamanca et al. 2003). The puna association (12) Baccharido caespitosae-Azorelletum diapensioidis seems a vicariant community in this context.

Sisyrinchio rigidifolii-Parastrephietum quadrangularis (Appendix 1, col. 12) Physiognomy and composition: Grassland vegetation with a cover of about 70-80% and with a great abundance of shrubs, dwarf shrubs, tussock grasses, annual herbs and ferns. The 30–50 cm tall Sisyrinchium rigidifolium layer covers 4–6%. The upper layer is dominated by the tussock grass Stipa ichu (70–100 cm tall) and the resinous shrub Parastrephia quadrangularis (60–90 cm), with a combined cover of 40%. The 1–1.6 (2) m tall Mutisia orbignyana (4% cover), is represented in only four relevés out of twenty. The dominant grass in this association is Stipa ichu. Small shrubs and dwarf shrubs (Baccharis tricuneata, Tetraglochin cristatum) reach 30–60 cm with a cover of 6–8%. The 10–15 cm tall cushion cactus Cumulopuntia boliviana subsp. ignescens is constant and covers between 4 and 6%. Rosettes and annual herbs such as Belloa piptolepis, Bowlesia lobata, Caiophora chuquitensis, Conyza deserticola, Galium corymbosum, Gilia laciniata, Hypochaeris chillensis, Lepechinia meyenii, Oxalis megalorrhiza, Perezia pungens and Silene genovevae dominate the ground layer. Ferns are dominated by the 10–20 cm tall Cheilanthes pruinata with a cover of 4–6%. Character and differential species: Character species are Sisyrinchium rigidifolium and Caiophora chuquitensis and, with low presence, also Bartsia melampyroides and Oenothera nana and Astragalus arequipensis, Hedeoma mandoniana, Lobivia sp., Ophioglossum crotalophoroides, Perezia sublyrata. It is further differentiated by Paronychia muschleri, Plantago sp., Senecio evacoides, Silene genovevae and Valeriana coarctata. Ecology and distribution: The Sisyrinchio-Parastrephietum extends over large areas on slopes at the edges of ravines of the Ichuña River between 3950 and 4200 m. The majority of slopes face N, E and S with an inclination of 25–55°. In general, the soils are 30–60 cm deep, with clayey texture and red-purple color. This association is in contact with the chasmophytic Phacelio secundae-Ribesetum brachybothryos.

Community of Plagiobothrys humilis and Stipa ichu (Appendix 1, col. 14) Physiognomy and composition: Grassland vegetation with a high cover of tussock grasses (70-80%), but with a low diversity of dwarf shrubs and annual herbs. It is highly affected by grazing. The upper layer is dominated by the 80–130 cm tall tussock grass Stipa ichu covering 40–60% and the 50–70 cm tall resinous shrub Parastrephia quadrangularis with 10–12% cover. The dwarf shrub Tetraglochin cristatum covers 6–8% while the 8–

Community of Misbrookea strigosissima and Stipa ichu (Appendix 1, col. 13; Fig. 7) Physiognomy and composition: Grassland vegetation with a great abundance of annual herbs with rosettes, tussock grasses and dwarf shrubs and a cover of about 65– 75%. The upper layer is dominated by the tussock grass Stipa ichu (80–120 cm tall) and the resinous shrubs Paraeschweizerbart_xxx

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15 cm tall cushion cactus Cumulopuntia boliviana subsp. ignescens covers 4–6%. Other shrubs are absent in these communities. The ground layer is dominated by rosettes and annual herbs such as Arenaria sp., Belloa piptolepis, Geranium sessiliflorum, Plagiobothrys humilis and Urtica echinata. The last three species indicate intensive grazing. This community is very species-poor: only 15 vascular plant species in 9 relevés. Character and differential species: It is characterized by Plagiobothrys humilis, Urtica echinata and Arenaria sp. Ecology and distribution: Intensively grazed by llamas and alpacas and extending over large areas on Coalaque Mountain (Ubinas district) at 4300–4500 m altitude on NE-facing slopes with an inclination of 15–30°. In general the clayey soils are 30–60 cm deep.

cushions, short grasses and some annuals. A total of 57 species have been recorded in 10 relevés. Character and differential species: This community is characterized by Azorella diapensioides, Baccharis caespitosa and Calamagrostis curvula, and with low presence also of Senecio humillimus, Sisyrinchium brevipes, Aa rosei, Oxalis eriolepis, Sisyrinchium jamesonii. It is further differentiated by Brayopsis calycina and Senecio candollei. Ecology and distribution: It develops at 4350–4470 m of altitude, covering the extensive grasslands on the slopes west of the upper Tambo River in the Ubinas district. Furthermore, it occurs on slopes with an inclination of 10–35° and a SW to SE exposure. Downslope the association is in contact with the Baccharido tricuneataePuyetum raimondii senecionetosum ferreyrae and upslope with different communities of the superpuna class Anthochloo-Dielsiochloetea. The Baccharido caespitosae-Azorelletum diapensioidis differs greatly from the Parastrephia lucidae-Festucetum orthophyllae azorelletosum diapensioidis (Galán de Mera et al. 2003) because of the absence of tussock grasses and other elements of the puna. We have included the Baccharido-Azorelletum in the Calamagrostion minimae (RivasMartínez & Tovar 1982) because of the abundance of cushion plants such as Azorella diapensioides and the presence of small grasses such as Calamagrostis curvula (morphologically similar to C. minima), and the absence of many species characterizing the Azorello-Festucion. Seibert & Menhofer (1992) also mention Azorella diapensioides-Calamagrostis brachyphylla vegetation (Calamagrostion minimae) from the Cordillera de Apolobamba, Bolivia.

Alliance: Calamagrostion minimae (Appendix 1, col. 15) Physiognomy and composition: One community is described for this alliance characterized by the presence of cushion plants, dwarf shrubs, tussock grasses, annual grasses and herbs. The vegetation is defined by the high cover of the cushion umbellifer Azorella diapensioides. Character and differential species: Character species is Calandrinia acaulis. Ecology and distribution: Grassland puna known as cesped de puna formed by small herbs and ground rosettes with long root systems, mostly developing on open and uniform slopes with shallow soils. The alliance is known to occur in the highlands of Peru and Bolivia (Rivas-Martínez & Tovar 1982; Galán de Mera et al. 2014) below 4800 m. Baccharido caespitosae-Azorelletum diapensioidis (Appendix 1, col. 15; Fig. 8) Physiognomy and composition: Grassland with high density and diversity of dwarf shrubs, cushions, grasses and annual herbs. Vegetation cover is about 50–60%. The 20–40 (50) cm tall resinous shrubs of Parastrephia quadrangularis cover 15–20%. Cushions attain 10–15% of the total cover (mainly represented by Azorella diapensioides). A dense 60–80 cm tall grass layer is present, dominated by the grasses Stipa ichu with Festuca dolichophylla. The absence of Nassella inconspicua is characteristic. The dwarf shrub layer is dominated by Baccharis tricuneata, Parastrephia quadrangularis and Tetraglochin cristatum. The ground layer is mainly represented by Arenaria digyna, Baccharis caespitosa, Belloa piptolepis, Brayopsis calycina, Calamagrostis curvula, C. vicunarum, Calandrinia acaulis, Gomphrena meyeniana, Muhlenbergia peruviana and Plantago sericea var. lanuginosa. Ferns are almost absent. The presence of the cushionforming Pycnophyllum glomeratum and P. molle, together with Junellia minima and Senecio candollei indicate the proximity of the association to the highland communities above 4500 m composed of dwarf shrubs,

Gradients and zonation The main gradient in species composition (DCA axis 1, Fig. 9) was strongly correlated to rock cover (r = -0.69), slope (r = -0.62), vegetation cover (r = 0.62), grazing (r = 0.57) and manure (r = 0.53). The correlation between the second axis and environmental variables was insignificant. The chasmophytic units on the left-hand side of the diagram were positively correlated with rock cover percentage and slope, but negatively with grazing, manure and vegetation cover. The Puya raimondii units were positively correlated with altitude, stone cover percentage, and pH. The grassland communities are correlated with grazing, manure, vegetation cover and species diversity but negatively correlated with rock cover percentage and slope angle. Finally, the Baccharido caespitosaeAzorelletum diapensioidis is positively correlated with altitude and negatively correlated with the cover of stones, and pH.

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Fig. 9. DCA analysis of 15 plant communities (weighted by presence class) and based on 210 plant species (see Appendix 1). The points representing the respective alliances, associations and communities are enveloped. Axis 1 eigenvalue is 0.512 and gradient length is 4.131; Axis 2 eigenvalue is 0.367 and gradient length is 4.064.

Rock cover is high in the chasmophytic units (Fig. 10). It is also relatively high in two of the subassociations of the Baccharido tricuneatae-Puyetum raimondii: the senecionetosum ferreyrae and the ageratinetosum sternbergianae. The mean rock cover is only around 10% in the lupinetosum cuzcensis and the calamagrostietosum heterophyllae. On steep slopes the cover by stones is usually low, except sometimes (high standard deviation) in the chasmophyte association Phacelio secundae-Ribesetum brachybothryos. Within the Baccharido tricuneatae-Puyetum raimondii the mean cover of stones is highest in the senecionetosum ferreyrae and the ageratinetosum sternbergianae. In the grasslands it is generaly low, with the exception of the Sisyrinchio rigidifolii-Parastrephietum

quadrangularis. Four of the chasmophyte associations occur on slopes steeper than 60° but in the case of the Paronychio ubinensis-Hypochaeridetum mucidae, the inclination is only 5–40°. As can be expected, vegetation cover is least on the steep, rocky cliffs with chasmophyte vegetation and highest for the Baccharido tricuneataePuyetum raimondii and the zonal puna grasslands. Figure 11 shows the altitudinal distribution of the syntaxa described in this survey. The gray boxes represent the distribution as based on the present field survey and the boxes in dashed lines the expected distribution based on the co-occurrence of the following character species of the syntaxa distinguished (Montesinos-Tubée 2011a, b, 2012, 2014): Plazia daphnoides and Plantago sericea; eschweizerbart_xxx

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Fig. 10. Bar charts showing the mean values (in per cent, except slope in degrees) with standard deviation for (a) rock cover, (b) stone cover, (c) slope inclination and (d) vegetation cover. (1) Plantagini sericeae-Plazietum daphnoidis, (2) Phacelio secundae-Ribesetum brachybothryos, (3) Neowerdermannio peruvianae-Festucetum weberbaueri (Argyrochosmo niveae-Neowerdermannion peruvianae), (4) Hypochaerido mucidae-Valerianetum nivalis, (5) Paronychio ubinensis-Hypochaeridetum mucidae, (6) Hypochaerido mucidae-Paronychietum muschleri (Hypochaerido mucidae-Loricarion graveolentis), (7) Asplenium triphyllum and Polystichum orbiculatum (Salpichroetalia glandulosae), (8.1) Baccharido tricuneatae-Puyetum raimondii senecionetosum ferreyrae, (8.2) ageratinetosum sternbergianae, (8.3) lupinetosum cuzcensis, (8.4) calamagrostietosum heterophyllae, (9) Sisyrinchio rigidifolii-Parastrephietum quadrangularis, (10) Community of Misbrookea strigosissima and Stipa ichu, (11) Community of Plagiobothrys humilis and Stipa ichu (Azorello compactae-Festucion orthophyllae), (12) Baccharido caespitosae-Azorelletum diapensioidis (Calamagrostion minimae).

Phacelia secunda and Ribes brachybothrys; Neowerdermannia peruviana; Hypochaeris mucida together with Valeriana nivalis, Paronychia ubinensis and P. muschlerii; Asplenium triphyllum and Polystichum orbiculatum; Puya raimondii with Senecio ferreyrae, Ageratina sternbergiana, Lupinus cuzcensis and Calamagrostis heterophylla; Stipa ichu with Misbrookea strigosissima and Plagiobothrys humilis; Baccharis caespitosa and Azorella diapensioides.

Floristic composition and affinity with previously published syntaxa In total, 210 vascular plant species belonging to 131 genera and 52 families were recorded. The flora list of the total relevé dataset is dominated by composites (57 spp.), Caryophyllaceae (19 spp.), Poaceae (15 spp.), Fabaceae (11 spp.), Brassicaceae (9 spp.), Pteridaceae (7 spp.), Cactaceae (6 spp.), Boraginaceae and Plantaginaceae (5 spp. each). Shrubs (20–140 cm height) are represented by 42 species, the dwarf shrubs (2–20 cm height) by 39 species, and herbs by 95 species, including 18 species of grasses and sedges, 8 succulents and 15 fern species. eschweizerbart_xxx

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Fig. 11. Altitudinal distribution of syntaxa (association, subassociation) and communities of the study area based on the relevĂŠs (solid lines) and references and field observations of diagnostic species elevation range (dashed lines) from Moquegua by the first author (Montesinos-TubĂŠe 2011a,b, 2012, 2014).

The floristic composition and diversity of the Andean grasslands of Moquegua change with altitude. Family composition shows the same trend as observed in the Andean prepuna of Moquegua (Montesinos et al. 2012) where the composites dominate the environment. Species diversity and composition also change along the altitudinal gradient, with variation caused by slope inclination. In the chasmophytic communities, species richness generally decreases with elevation; however, species richness was observed to increase locally between 3800 and 4200 m in the Puya raimondii communities, probably as a result of nursing effects. The high diversity of lichens and mosses reported by Gutte (1985) and Seibert & Menhofer (1991, 1992, 1993) is in accordance with our observations, although in our study these groups were not included in the phytosociological analysis. Substantial cover was observed only in the following associations with a prominent cover of pottiaceous mosses and lichens: Neowerdermannio peruvianae-Festucetum weberbaueri, Hypochaerido mucidae-Paronychietum muschleri, community of Asplenium triphyllum and Polystichum orbicula-

tum and Baccharido tricuneatae-Puyetum raimondii senecionetosum ferreyrae. The communities and high ranked syntaxa of the Moquegua study area presented here were compared in a broader geographical context with similar vegetation types from other region of Peru, from Bolivia and Chile. A first run of the Farthest Neighbor Clustering resulted in a group of outliers of 45 vegetation units (see Supplement S4). These syntaxa have been excluded from the cluster analysis. The dendrogram (Fig. 12) was used to interpret the community structure by comparing related communities described in literature. The chasmophytic units presented in this paper are clearly separated from the other communities. At the next level of similarity the data are divided into two groups: one group comprises the highland grasslands and some scrublands as described in literature, mainly from Southwest Bolivia, north of Chile and south Peru and the other the grasslands from Arequipa and Moquegua. The latter group is subdivided into a group with communities from the literature (16-20 in Fig. 12) and a group consisteschweizerbart_xxx

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Fig. 12. Dendrogram from Farthest Neighbor Clustering of 31 clusters (weighted by presence class) and based on 275 plant species (see methods and Appendix 1). The cluster numbers correspond to the plant communities 1â&#x20AC;&#x201C;31 in the synoptic table (Appendix 1)

ing of the Baccharido tricuneatae-Puyetum raimondii and of the grasslands presented in this study. The main difference is the characteristic and constant presence of Festuca dolichophylla in our communities by contrast with the presence of Festuca orthophylla in the first group. In Figure 12, at the highest level, the chasmophyte vegetation growing in rock crevices, fissures and shallow soils, the Argyrochosmetea niveae (1 to 7) is separated from the grassland vegetation of the Calamagrostietea vicunarum (8 to 15). At the next level, the Argyrochosmo niveae-Neowerdermannion peruvianae is separated from the Loricarion graveolentis (5-7). Argyrochosmo niveae-

Neowerdermannion peruvianae includes the community of Asplenium triphyllum and Polystichum orbiculatum, which we decided to include at the order level only, since it is restricted to one cave community and does not represent the cave communities in general; this needs further investigation. The Puya raimondii communities are grouped from 8 to 11; the association with Sisyrinchium rigidifolium is closely related to the Puya raimondii rocky environment since the association shares chasmophytic and grassland species. The communities of Misbrookea strigosissima and Stipa ichu and Plagiobothrys humilis and Stipa ichu (13 and 14) are closely related to the association of Baceschweizerbart_xxx

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cut down and burned to prevent livestock becoming ensnared in the spines of the giant rosettes. Fire has been regularly observed on several mountain slopes. These fires were probably started on purpose as part of a festivity in June. Fortunately, due to advice and information given to the local communities by the first author, this practice is now gradually decreasing (personal observation), and conservation programs have been started. At the same time, interviews with the local communities suggest that the pastures are being grazed in a way that prevents overgrazing. Negative effects have been observed only in some grassland communities where livestock is abundant and species richness is relatively poor (communities of Misbrookea strigosissima and Stipa ichu, and Plagiobothrys humilis and Stipa ichu) and where tussock grasses are abundant and cover almost 70% of the ground. In addition to livestock, wild grazers including vicuñas (Vicugna vicugna), viscacha (Lagidium peruanum), taruca (Hippocamelus antisensis) and suri (lesser rhea, Rhea pennata) are known to occur in the region. It is also known that the villagers harvest the wood of Escallonia myrtilloides for fuel and for use in festivities, causing gradual decline of their stands. This highlights the vulnerability of the flora and vegetation of the Andes to human pressure, and requires further studies.

charido caespitosae-Azorelletum diapensioidis (15), because they share companions, order and class species although belonging to the alliance Azorello compactae-Festucion orthophyllae. Studies from north Chile (Lambrinos et al. 2006; Luebert & Gajardo 2000, 2005) and Bolivia (Seibert & Menhofer, 1991, 1992, 1993; Navarro 1993; Gutte 1995) were compared with our results and appear to differ significantly in species composition and zonation. Moreover the communities described by Montesinos et al. (2012) lack the presence of Parastrephia quadrangularis, Tetraglochin cristatum and the tussock grass Festuca dolichophylla, which are diagnostic elements of the puna. We compared our communities with the alliance Saturejion bolivianae occurring in the Bolivian puna (Seibert & Menhofer 1993), which is distinct from the puna in the sites we studied in South Peru. The shrub Clinopodium bolivianum is present in our study area and considered an additional species of the order and alliance, since it is widely distributed in different highland environments in south Peru (Tropicos). The difference in species composition between the Saturejion bolivianae and Stipetalia ichu (Gutte 1986), which is well represented in Central Peru, is considerable. The name Stipetalia ichu has not been used in recent years, because of the lack of phytosociological studies in Central Peru. The name Parastrephietalia quadrangularis has been introduced for south Peru (Navarro 1993): it comprises the highland units of the puna with grasslands and scrublands.

Author contributions D.B.M.T. planned the research and conducted the field sampling, D.B.M.T. and K.V.S. performed the statistical analyses and all authors jointly wrote and revised the manuscript.

Concluding remarks Our vegetation research in northern Moquegua (south Peru), an area not studied before, extends the knowledge of the syntaxonomy, floristic diversity and synecology of Puya raimondii stands, chasmophytic and grassland vegetation. It comprises two new alliances, eight new associations and four subassociations, representing an important basis for a future overview and synopsis of the Andean vegetation of South America. The vegetation studied in Moquequa appears to be floristically different from comparable vegetation in north Chile and Bolivia. Further research is needed, however, to study the relation with chasmophytic and grassland associations in the highlands of other mountainous regions in South America. The present overview is also important as a reference and tool for nature conservation. Apart from the impressive giant bromeliad Puya raimondii, many other endemic species are found in the newly described syntaxa, increasing the need for conservation schemes and measures. In recent years, the puna grasslands and Puya raimondii communities have been increasingly affected by grazing and human influence. The natural vegetation is being disturbed and Puya raimondii has regularly been

Acknowledgements Special thanks to the supervisors of the herbaria USM, HUSA, CPUN, CUZ, L, LPB, WAG, MO and F for the admission to their collections for the study of the botanical specimens. We are grateful for the financial support from the Alberta Mennega Stichting (Utrecht, Netherlands). We are also thankful to the DGFFS (Ministry of Agriculture, Peru) for the permits to make botanical collections during our study. We acknowledge the laboratory of Huasacache (UCSM) and UNALM for their availability for the soil analysis. We also thank I. Al-Shehbaz, B. León, H. Trinidad, D. Trujillo, V. Quipuscoa, O. Tovar, M. Chanco, A. Granda, C. Ostolaza, J. Campos, F. Cáceres, R. Chávez, H. Ballard, W. Galiano, A. Pauca, J. Roque, E. Navarro, H. Trinidad, A. Meerow, P. Goldblatt, and J. Wieringa for their support in the identification of plant species. Special thanks also to E. Banegas, F. Calisaya, J.C. Quiroz, C. Pinto, C. Tejada and D. Figueroa for fieldwork support and B. DeVries for the map image development. J. Burrough checked and edited the English text.

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Daniel B. Montesinos-Tubée et al. Galán de Mera, A., Baldeón, S., Beltrán, H., Benavente, M. & Gómez, J. (2004): Datos sobre la vegetación del centro del Perú. Acta Botanica Malacitana 29: 89–115. Galán de Mera, A. 2005. Clasificación fitosociológica de la vegetación de la región del Caribe y América del Sur. Arnaldoa 12: 86–111. Galán de Mera, A., Linares Perea, E., Campos de la Cruz, J. & Vicente Orellana, J. 2009. Nuevas observaciones sobre la vegetación del sur del Perú. Del desierto pacífico al altipla Acta Botanica Malacitana 34: 1–35. Galán de Mera, A., Linares Perea, E., Campos de la Cruz, J., Trujillo Vera, C., Villasante Benavides, F. & Vicente Orellana, J.A. 2011. Novedades sobre la vegetación del departamento de Arequipa (Perú). Arnaldoa 18: 125–144. Galán de Mera, A., Linares Perea, L., Campos de la Cruz, J., Trujillo Vera, C. & Vicente Orellana, J. 2012. Las comunidades vegetales relacionadas con los ambientes humanos en el sur del Perú. Phytocoenologia 41: 265–305. Galán de Mera, A., Linares Perea, E., Campos, J. & Vicente Orellana, J. 2014. Las comunidades vegetales relacionadas con los procesos criogénicos en los Andes peruanos. Phytocoenologia 44: 121–161. García, E. & Beck, S.G. 2006. Puna. In: Moraes, M., Øllgaard, B., Kvist, L.P., Borchsenius, F. & Balslev, H. (eds.) Botánica económica de los Andes Centrales, pp. 51–76. Universidad Mayor de San Andrés, La Paz, BO. Gutte, P. 1980. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften II. Die hochandinen Moore und ihre Kontaktgesellschaften. Feddes Repertorium 91: 327–336. Gutte, P. 1985. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften IV. Die grasreiche Vegetation der alpine Stufe. Wissenschaftliche Zeitschrift Karl-Marx-Universität Leipzig. Mathematisch-Naturwissenschaftliche Reihe 34(4): 357–401. Gutte, P. 1986. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften III. Pflanzengesellschaften der subalpinen Stufe. Feddes Repertorium 97: 319–371. Gutte, P. 1987. Beitrag zur Kenntnis zentralperuanischer Pflanzengesellschaften V. Die Vegetation der subnivalen Stufe. Feddes Repertorium 98: 447–460. Gutte, P. 1988. Der anthropogene Einfluss in der Puna-Region Zentralperus. Flora 180: 31–36. Gutte, P. 1995. Segetal- und Ruderalpflanzengesellschaften im Wohngebiet der Kallawaya (Bolivianische Anden). Phytocoenologia 25: 33–67. Harling, G. 1979. The vegetation types of Ecuador. A brief survey. In: Larsen, K. & Holm-Nielsen, L.B. (eds.) Tropical Botany, pp. 165–174. Academic Press. London, New York, San Francisco. Hill, M.O. 1979. Twinspan, a Fortran program for arranging multivariate data in an ordered two way table by classification of the individuals and the attributes. Cornell University, Department of Ecology and Systematics, Ithaca, New York, US. Hornung-Leoni, C.T., Sosa, V., Simpson, J. & Gil, K. 2013. Genetic variation in the emblematic Puya raimondii (Bromeliaceae) from Huascarán National Park, Peru. Crop Breeding and Applied Biotechnolgy 13: 67–74. Knapp, R. 1984. Considerations on quantitative parameters and qualitative attributes in vegetation analysis and in phytosociological relevés. In: Knapp, R. (ed.) Sampling methods and taxon analysis in vegetation science, pp. 77–100. Dr. W. Junk Publishers, The Hague, NL. Kuentz, A., Galán de Mera, A., Ledru, M.P. & Thouret, J.C. 2007. Phytogeographical data and modern pollen rain of the

References Antonsson, H. 2012. Plant Species Composition and Diversity in Cliff and Mountain Ecosystems. University of Gothenburg. Faculty of Science. Doctoral thesis. Gothenburg, SE. Arakaki, M. & Cano, A. 2003. Composición florística de la cuenca del río Ilo-Moquegua y lomas de Ilo, Moquegua, Perú. Revista Peruana de Biología 10: 5–19. Arakaki, M., Ostolaza, C., Cáceres, F. & Roque, J. 2006. Cactaceae endémicas del Perú. Revista Peruana de Biología 13: 193–219. Beck, S. & Garcia, E. 1991. Flora y vegetación en los diferentes pisos altitudinales. In: Forno, E. & Baudoin, M. (eds.) Historia natural de un valle en los Andes, pp. 65–108. Instituto de Ecología, Universidad Mayor de San Andrés, La Paz, BO. Beltrán, H., Granda, A., León, B., Sagástegui, A., Sanchez, I. & Zapata, M. 2007. Asteraceae endémicas del Perú. In: León, B., Roque, J., Ulloa, C., Pitman, N., Jørgensen, P.M. & Cano, A. (eds.) El libro rojo de las plantas endémicas del Perú. Revista Peruana de Biología 13: 64s–164s. Brako, L. & Zarucchi, J. 1993. Catalogue of the Flowering Plants and Gymnosperms of Peru. Monographs in Systematic Botany from the Missouri Botanical Garden. 45: 1–1286. Braun-Blanquet, J. 1979. Plant sociology, the study of plant communities. Transl. by G. D. Fueller and H. S. Conard. Mc. Graw-Hill, New York, US. Britto, B. & Arana, C. 2014. Corotipos preliminares de Perú basados en la distribución de la familia Asteraceae. Darwiniana 2: 39–56. Cabrera, A.L. 1968. Ecología vegetal de la Puna. Geoecology of the mountainous regions of the tropical Americas (ed. by C. Troll), 91–116 p. Colloquium Geographicum 9, Ferd. Dümmlers Verlag, Bonn, DE. Caiafa, A.N. & Da Silva, A.F. 2007. Structural analysis of the vegetation on a highland granitic rock outcrop in Southeast Brazil. Revista Brasileira de Botanica 30: 657–664. Catorci, A., Velasquez, J.L., Cesaretti, S., Malatesta, L., Tardella, F.M. & Zeballos, H. 2014. How environment and grazing influence floristic composition of dry puna in the southern Peruvian Andes. Phytocoenologia 44: 103–119. Cuatrecasas, J. 1958. Aspectos de la vegetación natural de Colombia. Revista de la Academia Ciolombiana de Ciencias Exactas, Físicas y Naturales 10(40): 221–264. Deil, U. 2014. Rock communities and succulent vegetation in Northern Yemen (SW Arabia) – ecological, phytochorological and evolutionary aspects. Phytocoenologia 44: 193–239. EIAS-PEC. 2009. Estudio de Impacto Ambiental Semidetallado. Proyecto de Exploración “Chucapaca”. 1–32 pp. Compañia de Minas Buenaventura, Lima, PE. Escudero, A. 1996. Community patterns on exposed cliffs in a Mediterranean calcareous mountain. Vegetatio 125: 99–110. Franco, J. Cáceres, C. & Sulca, J. 2004. Flora y Vegetación del departamento de Tacna. Ciencia y Desarrollo 8: 23–30. Freire, S.E., Chemisquy, M.A., Anderberg, A.A., Beck, S.G., Meneses, R.I., Loeuillr, B. & Urtubey, E. 2014. The Lucilia group (Asteraceae, Gnaphaleae): phylogenetic and taxonomic considerations based on molecular and morphological evidence. Plant Systematics and Evolution 301: 1227– 1248. Galán de Mera, A. Rosa, M. & Cáceres, C. 2002. Una aproximación sintaxonómica sobre la vegetación del Perú. Clases, órdenes y alianzas. Acta Botanica Malacitana 27: 75–103. Galán de Mera, A., Cáceres, C. & Gonzáles, A. 2003. La vegetación de la alta montaña andina del sur de Perú. Acta Botanica Malacitana 28: 121–147.

eschweizerbart_xxx

phyto_45_4_0365_0398_montesinos_0006.indd 384

24.11.15 06:40

The Puna vegetation of Moquegua, South Peru

385

Puna belt in southern Peru (Nevado Coropuna, Western Cordillera). Journal of Biogeography 34: 1762–1776. Lambe, A. 2009. Puya raimondii. The IUCN Red List of Threatened Species 2009: e.T168358A6482345. http://dx. doi.org/10.2305/IUCN.UK.2009-2.RLTS.T168358A648 2345.en. Accessed on 19 September 2014. Lambrinos, J.G., Kleier, C.C. & Rundel, P.W. 2006. Plant community variation across a puna landscape in the Chilean Andes. Revista Chilena de Historia Natural 79: 233–243. Linares Perea, E. 2005. Flora Andina: Estudio Botánico de Quebradas y Puna entre Arequipa y el Valle del Colca. Boletín de la Sociedad Geográfica de Lima 118: 91–144. Luebert, F. & Gajardo, R. 2000. Vegetación de los Andes áridos del norte de Chile. Lazaroa 21: 111–130. Luebert, F. & Gajardo, R. 2005. Vegetación altoandina de Parinacota (norte de Chile) y una sinopsis de la vegetación de la puna meridional. Phytocoenologia 35: 79–128. McCune, B. & Mefford, M.J. 1999. PC-ORD for Windows. Multivariate Analysis of Ecological Data Version 4.25. MjM Software, Gleneden Beach, Oregon, US. Montenegro, B., Zúñiga, S. & Zeballos, H. 2010. Climatología de la Reserva Nacional Salinas y Aguada Blanca, suroeste del Perú. In: Zeballos, H., Ochoa, J.A. & López, E. (eds.) Diversidad biológica de la Reserva Nacional de Salinas y Aguada Blanca, pp. 261–273. Litho & arte sac., Lima, PE. Montesinos-Tubée, D.B. 2011a. Diversidad florística de la cuenca alta del río Tambo-Ichuña (Moquegua, Peru). Revista Peruana de Biología 18: 119–132. Montesinos-Tubée, D.B. 2011b. Ecología y usos populares de ‘Towana’: Neowerdermannia chilensis subsp. peruviana (Ritter) Ostolaza (Cactaceae) en la Provincia General Sánchez Cerro, Moquegua, Perú. Quepo 25: 78–86. Montesinos-Tubée, D.B. 2012. Lista anotada de nuevas adiciones para la flora andina de Moquegua, Perú. Revista Peruana de Biología 19: 303–312. Montesinos, D.B., Cleef, A.M. & Sýkora, K.V. 2012. Andean shrublands of Moquegua, South Peru: Prepuna plant communities. Phytocoenologia 42: 29–55. Montesinos-Tubée, D.B. 2013a. Paronychia ubinensis (Caryophyllaceae): A new species from South Peru. Phytotaxa 124: 50–54. Montesinos-Tubée, D.B. 2013b. Flora de los Andes de Moquegua. Etnobotánica de la Cuenca de los ríos Alto TamboIchuña. Inca Legacy Cultural Society. Lima, PE. Montesinos-Tubée, D.B. 2014. Inventario y estado de conservación de Puya raimondii (Bromeliaceae) en el departamento de Moquegua, Peru. Chloris chilensis 17: 1–9. Montesinos-Tubée, D.B., Sýkora, K.V., Quipuscoa-Silvestre, V. & Cleef, A.M. 2015. Species composition and phytosociology of xerophytic plant communities after extreme rainfall in South Peru. Phytocoenologia 45: 203–250. Mucina, L., Valachovič, Jarolímek, I., Šeffer, J., Kubinská, A. & Pišut, I. 1990. The vegetation of rock fissures, screes, and snow-beds in the Pirin Planina Mountains (Bulgaria). Studia Geobotanica 10: 15–58. Mueller-Dombois, D. & Ellenberg, H. 1974. Aims and methods of vegetation ecology. John Wiley & Sons, US. Myers, N., Mittermeier, R.A., Mittermeier, C.G., Da Fonseca, G.A.B. & Kent, J. 2000. Biodiversity hotspots for conservation priorities. Nature 403: 853–858. Navarro, G. 1993. Vegetación de Bolivia: el Altiplano meridional. Rivasgodaya 7: 69-98. Navarro, G. & Maldonado, M. 2005. Geografía ecológica de Bolivia. Vegetación y ambientes acuáticos. Fundación Simón 1. Patiño. Santa Cruz, BO.

Navarro, G. & Ferreira, W. 2004. Zonas de vegetación potencial de Bolivia: Una base para el análisis de vacíos de conservación. Revista Boliviana de Ecologia 15: 1–40. Nowak, A., Nowak, S., Nobis, M. & Nobis, A. 2014a. Vegetation of solid rock faces and fissures of the alpine and subnival zone in the Pamir Alai Mountains (Tajikistan, Middle Asia). Phytocoenologia 44: 81–101. Nowak, A., Nowak, S., Nobis, M. & Nobis, A. 2014b. Vegetation of rock clefts and ledges in the Pamir Alai Mts, Tajikistan (Middle Asia). Central European Journal Biology 9: 444–460. Ostolaza, C. 2011. 101 cactus del Perú. Ministerio del Ambiente. Lima, PE. Pedrotti, F. & Venanzoni, R. 1986. Observaciones fitogeográficas sobre Puya raimondii Harms en Bolivia. Documents phytosociologiques 10(2): 1–9. Rahn, K. 1981. Plantago ser. Sericeae, a taxonomic revision. Nordic Journal of Botany 1: 297–232. Rivas-Martínez, S. & Tovar, O. 1982. Vegetatio Andinae, I. Datos sobre las comunidades vegetales altoandinas de los Andes Centrales del Perú. Lazaroa 4: 167–187. Rivera, M., Thouret, J.C., Samaniego, P. & Le Pennec, J.L. 2014. The 2006–2009 activity of the Ubinas volcano (Peru): Petrology of the 2006 eruptive products and insights into genesis of andesite magmas, magma recharge and plumbing system. Journal of Volcanology Geothermal Research 270: 122–141. Ruthsatz, B. 1977. Pflanzengesellschaften und ihre Lebensbedingungen in den Andinen Halbwüsten Nordwest-Argentiniens. Dissertationes Botanicae 39: 1–90. Salamanca, S., Cleef, A.M. & Rangel, O. 2003. The páramo vegetation of the volcanic Ruíz-Tolima massif. In: van der Hammen, T & dos Santos, A.G. (eds.), La Cordillera Central Colombiana. Transecto Parque de los Nevados. Studies on Tropical Andean Ecosystems 5: 1–77. J. Cramer. Berlin-Stuttgart, DE. Schwarzer, C., Cáceres, F., Cano, A., La Torre, M.I. & Weigend, M. 2010. 400 years for long-distance dispersal and divergence in the northern Atacama Desert and insights from the Huaynaputina pumice slopes of Moquegua, Peru. Journal of Arid Environments 74: 1540–1551. Seibert, P. & Menhofer, X. 1991. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 20: 145–276. Seibert, P. & Menhofer, X. 1992. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 20: 289–438. Seibert, P. & Menhofer, X. 1993. Die Vegetation des Wohngebietes der Kallawaya und des Hochlandes von Ulla-Ulla in den bolivianischen Anden. Phytocoenologia 22: 275–278. SENAMHI 2013. Servicio Nacional de Meteorología e Hidrología del Perú. Información meteorológica de las estaciones de Ichuña y Ubinas (Moquegua). Arequipa, PE. Smith, A.P. 1994. Introduction to Tropical Alpine Vegetation. In: Rundel, P.W., Smith, A.P. & Meinzer, F.C. (eds.) Tropical Alpine Environments: Plant Form and Function, pp. 1–20, Cambridge University Press, Cambridge, UK. Sgorbati, S., Labra, M., Grugni, E., Barcaccacia, G., Galasso, G., Boni, U., Mucciarelli, M., Citerio, S., Benavides, S., Venero, J.L. & Scannerini, S. 2004. A survey of genetic diversity and reproductive biology of Puya raimondii (Bromeliaceae), the endangered queen of the Andes. Plant Biology 6: 222–230. Talavera, C., Ortega, A. & Villegas, L. 2010. Flora y vegetación de la Reserva Nacional de Salinas y Aguada Blanca, Perú. In: Zeballos, H., Ochoa, J.A. & López, E. (eds) Diversidad biológica de la Reserva Nacional de Salinas y Aguada Blanca

eschweizerbart_xxx

phyto_45_4_0365_0398_montesinos_0006.indd 385

24.11.15 06:40

386

Daniel B. Montesinos-Tubée et al.

(Arequipa-Moquegua). pp. 89–104. Litho & arte sac., Lima, PE. Ter Braak, C.J.F. & Šmilauer, P. 2002. CANOCO. Reference manual and CanoDraw for Windows User’s Guide: Software for Canonical Community Ordination (version 4.5). Microcomputer Power, Ithaca, NY, US. Tryon, R.M. & Stolze, R.G. 1989. Pteridophyta of Peru. Part II. Fieldiana, Botany 22: 27–28; 38–40. Tryon, R.M. & Stolze, R.G. 1991. Pteridophyta of Peru. Part IV. Fieldiana, Botany 27: 92–95. Vadillo, G., Suni, M. & Cano, A. 2004. Viabilidad y germinación de semillas de Puya raimondii Harms (Bromeliaceae). Revista Peruana de Biología 11: 71–78. Vargas Sierra, N. 2013. Evaluación del estado actual de la población de Puya raimondii Harms en la comunidad de P’isku Mayu-Municipio Vacas, Cochabamba. Universidad Mayor de San Simón, Cochabamba, BO.

Venero, J.L. 2001. Puya raimondii en Espinar-Cusco. Biota 100: 37–42. Weber, H.E., Moravec, J. & Theurillat, J.P. 2000. International Code of Phytosociological Nomenclature. 3rd edition. Journal of Vegetation Science 11: 739–768. Weberbauer, A. 1912. Pflanzengeographische Studien im südlichen Peru. Botanische Jahrbücher für Systematik 107: 27–46. Weberbauer, A. 1945. El mundo vegetal de los Andes Peruanos. Estación Experimental Agrícola de la Molina, Dirección de Agricultura, Lima, PE. Westhoff, V. & Van der Maarel, E. 1973. The Braun-Blanquet approach. In: Whittaker, R.H. (ed.) Handbook of Vegetation Science 5, pp. 617–726, Dr. W. Junk, The Hague, NL. Wilcox, B.P., Wood, M.K., Tromble, J.T. & Ward, T.J. 1986. Grassland communities and soils on a high elevation grassland of central Peru. Phytologia 61: 231–250.

Author addresses Montesinos-Tubée, Daniel Bernardo (Corresponding author, daniel.montesinos@wur.nl, dbmtperu@gmail.com)1,2, Cleef, Antoine Marie (cleef@uva.nl)3, Sýkora, Karel Vaclav (karle.sykora@gmail.com)1, 1Environmental Sciences, Nature Conservation and Plant Ecology Group. Wageningen University. Droevendaalsesteeg 3a, 6708 PB Wageningen, Netherlands 2Instituto Científico Michael O. Dillon (IMOD), Arequipa, Perú 3University of Amsterdam, Institute for Biodiversity and Ecosystem Dynamics (IBED). P.O. Box 94248, 1090 GE Amsterdam, Netherlands

Appendix 1 Synoptic table of the plant communites. This study: 1. Plantagini sericeae-Plazietum daphnoidis, 2. Phacelio secundaeRibesetum brachybothryos, 3. Neowerdermannio peruvianae-Festucetum weberbaueri, 4. Hypochaerido mucidaeValerianetum nivalis, 5. Paronychio ubinensis-Hypochaeridetum mucidae, 6. Hypochaerido mucidae-Paronychietum muschleri, 7. Community of Asplenium triphyllum and Polystichium orbiculatum, 8. Baccharido tricuneatae-Puyetum raimondii senecionetosum ferreyrae, 9. B.-P. ageratinetosum sternbergianae, 10. B.-P. lupinetosum cuzcensis, 11. B.-P. calamagrostietosum heterophyllae, 12. Sisyrinchio rigidifolii-Parastrephietum quadrangularis, 13. Community of Misbrookea strigosissima and Stipa ichu, 14. Community of Plagiobothrys humilis and Stipa ichu, 15. Baccharido caespitosae-Azorelletum diapensioidis. Reference studies: 16. Parastrephio lucidae-Festucetum orthophyllae (Galán de Mera el al. 2009), 17. Baccharido tricuneatae-Puyetum raimondii (Galán de Mera et al. 2009), 18. Parastrephio quadrangularis-Festucetum dolichophyllae (Galán de Mera et al. 2011), 19. P.-F. agrostietosum gelidae (Galán de Mera et al. 2011), 20. P.-F. festucetosum orthophyllae (Galán de Mera et al. 2011), 21. Parastrephio lucidae-Festucetum orthophyllae deyeuxietosum cabrerae (Galán de Mera et al. 2011), 22. Wernerio aretioidis-Parastrephietum lucidae (Azorello compactae-Festucion orthophyllae) (Luebert & Gajardo 2005), 23. Parastrephio lucidae-Festucetum orthophyllae (Galán de Mera el al. 2003), 24. Parastrephio lucidae-Festucetum orthophyllae azorellietosum compactae (Galán de Mera el al. 2003), 25. Senecio nutantis-Parastrephietum quadrangularis (Galán de Mera et al. 2011), 26. Parastrephietum lepidophyllo-quadrangularis (Luebert & Gajardo 2005), 27. Mutisio lanigerae-Polylepidetum tarapacanae (Polylepidion tomentello-tarapacanae) (Luebert & Gajardo 2005), 28. Muhlenbergio fastigatae-Parastrephietum lepidophyllae (Navarro 1993), 29. Acantholippio salsoloidis-Lampayetum castellani (Navarro 1993), 30. Diplostephio tacorensis-Parastrephietum lepidophyllae (Galán de Mera et al. 2003), 31. Chuquirago rotundifoliae-Polylepidetum rugulosae (Polylepidion tomentello-tarapacanae) (Luebert & Gajardo 2005).

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Column no. 1 2 3 4 5 6 7 Number of relevĂŠs 6 10 6 9 15 8 4 Number of species 32 27 41 22 46 19 15 Argyrochosmetea niveae & Salpichroetalia glandulosae Luzula racemosa 100 60 100 . 73 100 4 Salpichroa glandulosa 33 100 100 44 . . 2 Belloa schultzii . 50 33 . 60 38 . Ribes brachybothrys . 70 . 100 . . 2 Peperomia scutellaefolia 67 . 100 100 . 88 . Bomarea dulcis . 50 . 67 20 . 3 Senecio sublutescens . . 100 . . 88 4 Cheilanthes pilosa . . . . . 100 . Pellaea ternifolia 83 . . . . . . I. Argyrochosmo niveae-Neowerdermannion peruvianae Argyrochosma nivea 83 40 67 . . . . Neowerdermannia 33 20 100 . . . . peruviana Phacelia pinnatifida . 50 50 . . . . 1. Plantagini sericeae-Plazietum daphnoidis Plazia daphnoides 100 . . . . . . Plantago sericea 83 . . . 7 . . Cheilanthes scariosa 67 . . . . . . Cheilanthes myriophylla 50 . . . . . . Polypodium pycnocarpum 50 . . . . . . Aa mathewsii 33 . . . . . . 2. Phacelio secundae-Ribesetum brachybothryos Phacelia secunda . 100 . . . . . 3. Neowerdermannio peruvianae-Festucetum weberbaueri Festuca weberbaueri . . 67 . . . . Asplenium peruvianum . . 67 . 13 . . Echeveria peruviana 17 . 50 . . . . Elaphoglossum minutum . . 50 . . . . Campyloneurum am. . 33 . . . . phostenon II. Hypochaerido mucidae-Loricarion graveolentis Hypochaeris mucida . . . 100 67 88 . Belloa kunthiana . . . 100 93 100 . Loricaria graveolens . . . 11 27 100 2 4. Hypochaerido mucidae-Valerianetum nivalis Valeriana nivalis . . . 100 . . . Senecio sp. . 10 . 78 . . . Gnaphalium polium . . . 67 . . .

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Column no. 1 2 3 4 5 6 7 8 9 Number of relevĂŠs 6 10 6 9 15 8 4 15 19 Number of species 32 27 41 22 46 19 15 96 96 5. Paronychio ubinensis-Hypochaeridetum mucidae Paronychia ubinensis . . . . 67 . . . . Spergularia andina . . . . 47 . . 13 . Nototriche foetida . . . . 40 . . . . Chaetanthera peruviana . . . . 27 . . . . 6. Hypochaerido mucidae-Paronychietum muschleri Paronychia muschleri . . . . . 88 . . . Draba sp. . . . . . 50 . . . 7. Community of Asplenium triphyllum and Polystichum orbiculatum Asplenium triphyllum . . . . . . 4 . . Stellaria weddellii . . . . . . 4 . . Polystichum orbiculatum . . . . . 13 3 . 21 Descurainia athrocarpa . . . . . . 1 . . Calamagrostietea vicunarum Calamagrostis vicunarum . . . . 47 88 . 40 11 Parastrephietalia quadrangularis Parastrephia quadrangula- . . . . 33 . . 100 58 ris Tetraglochin cristatum . . . . 20 . . 7 37 Cumulopuntia boliviana . . . . . . . 67 53 subsp. ignescens Baccharis tricuneata . . . . 20 . . 93 90 Festuca dolichophylla . . . . 40 . . 93 79 Plantago sericea var. . . . . 40 . . 7 58 lanuginosa Gomphrena meyeniana . . 33 . . . . 47 16 Chersodoma jodopappa . 40 83 . 40 . . 87 79 Ephedra rupestris . 20 . . . . . . 11 +Azorello compactae-Festucion orthophyllae Tarasa nototrichoides . . . . . . . 40 63 Conyza deserticola . . . . . . . 20 42 Lobivia maximiliana . . . 11 33 . . 47 68 Geranium sessiliflorum . . . . . . . 47 37 Belloa longifolia . . . . . . . 27 16 Oxalis calachaccensis . . . . . . . 7 21 Lepechinia meyenii . . . . . . . 20 37 Philibertia lysimachioides . . 17 . . . . . 21 Wahlenbergia peruviana . . . . 20 . . 7 . Clinopodium bolivianum . . 33 . . . . 53 42

phyto_45_4_0365_0398_montesinos_0006.indd 388

. . . .

29 57 57 . 14 . 43 14 86 57 . . . 29 100 29 . .

60 70 90 80 60 . 10 . 60 80 30 . . . . . 40 .

100 85 25 20 20 15 40 50 20 .

20 65 50

75 50 20

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27 4 19

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75 . .

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100 4

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26 8 39

80 13 100 .

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33 .

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388 Daniel B. Montesinos-TubĂŠe et al.

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Column no. 1 2 3 4 5 6 7 Number of relevĂŠs 6 10 6 9 15 8 4 Number of species 32 27 41 22 46 19 15 Azorella compacta . 30 . . . . . 8. Baccharido tricuneatae-Puyetum raimondii Puya raimondii . . . . . . . Mutisia orbignyana . . . . . . . Lupinus paruroensis . . . . . . . Alstroemeria pygmaea . . . . . . . Baccharis genistelloides . . . . . . . Lophopappus tarapacanus 33 . . . . . . Euphorbia huanchahana . . . . . . . 8.1 senecionetosum ferreyrae Ageratina azangaroensis . . . . . . . Senecio ferreyrae . . . . . . . Stevia macbridei . . . . . . . Bomarea involucrosa . . . . . . . 8.2 ageratinetosum sternbergianae Ageratina sternbergiana . . . . . . . Weberbauera peruviana . . . . . . . Stevia mandonii . 30 . . . . . Festuca orthophylla . . . . . . . 8.4 lupinoetosum cuzcensis Lupinus cuzcensis . . . . . . . Oxalis nubigena . . . . . . . Senecio nutans . . . . . . . Olsynium junceum . . . . . . . Calamagrostis violacea . . . . . . . Gnaphalium dombeyanum . . . . . . . Lupinus sp. 1 . . . . . . . 8.3 calamagrostietosum heterophyllae Viola micranthella . . . . . . . Poa gymnantha . . . . . . . Calamagrostis hetero. . . . . . . phylla Stipa obtusa . . . . . . . 9. Sisyrinchio rigidifoli-Parastrephietum quadrangulare Sisyrinchium rigidifolium . . 50 . . . . Silene genovevae . . . . . . . Bartsia melampyroides . . . . . . . Oenothera nana . . . . . . . Astragalus arequipensis . . . . . . .

9 19 96 . 74 37 26 . 11 26 . . . . . 63 74 74 11 . . . . . . . . . . . 16 . . . .

8 15 96 . 87 73 33 53 20 20 40 87 67 53 40

phyto_45_4_0365_0398_montesinos_0006.indd 389

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12 20 88 .

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100 20 86 . 71 .

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23 9 32 .

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26 8 39 89

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. 7 13 . . 17 .

30 30 82 .

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31 4 35 .

The Puna vegetation of Moquegua, South Peru 389

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Column no. 1 2 3 4 5 6 7 Number of relevĂŠs 6 10 6 9 15 8 4 Number of species 32 27 41 22 46 19 15 10. Community of Misbrookea strigosissima and Stipa ichu Misbrookea strigosissima . . . . . . . Stenomesson sp. . . . . . . . Belloa sp.1 . . . . . . . Senecio rhizocephalus . . . . . . . Perezia coerulescens . . . . . . . 11. Community of Plagiobothrys humilis and Stipa ichu Plagiobothrys humilis . . . . . . . Urtica echinata . . . . . . . Arenaria sp. . . . . . . . +Calamagrostion minimae Calandrinia acaulis . . . . 7 38 . Lupinus ananeanus . . . . 73 . . 12. Baccharido caespitosae-Azorelletum diapensioidis Azorella diapensioides . . . . . . . Baccharis caespitosa . . . . . . . Calamagrostis curvula . . . . . . . Senecio humillimus . . . . . . . Sisyrinchium brevipes . . . . . . . Pycnophyllum molle . . . . . . . Crassuletea connatae Muhlenbergia peruviana 67 . . . 80 . . Crassula connata 67 . . . . . . Tagetes multiflora 67 . . . . . . Mancoa hispida . . . . . . . Echinopsio-Proustietea Vasquezia oppositifolia 33 . 100 . . . . Viguiera procumbens . . 67 . . . . Paronychia setigera . . . . . . . Gnaphalium lacteum . . . . 27 . . Caiophora cirsiifolia . . 33 . . . . Dunalia spinosa . . 33 . . . . Soncho-Bidentetea pilosi Trifolium amabile . . . . . . . Polypodio-Tillandsietea Tillandsia capillaris 67 40 . . . . . Companions Stipa ichu 67 60 100 . . . .

9 19 96 . . . . . . . . 47 . . . . . . . 68 37 79 21 16 16 11 5 . . 21 21 74

8 15 96 . . . . . . . .

phyto_45_4_0365_0398_montesinos_0006.indd 390

. . . . . . . . 33 27 53 . 7 . 27 27 . . 13 . 80

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12 20 88

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13 9 28

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23 9 32

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24 11 38

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25 5 22

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13 13 . . . .

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26 8 39

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31 4 35

390 Daniel B. Montesinos-TubĂŠe et al.

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Column no. Number of relevĂŠs Number of species Belloa piptolepis Galium corymbosum Nassella inconspicua Hypochaeris meyeniana Cardionema ramosissimum Oxalis megalorrhiza Spergularia fasciculata Bartsia peruviana Cerastium subspicatum Hieracium streptochaetum Bromus catharticus Woodsia montevidensis Cheilanthes pruinata Cystopteris fragilis Calceolaria lobata Bartsia crenoloba Gamochaeta purpurea Solanum bukasovii Bowlesia lobata Valeriana interrupta Achyrocline alata Valeriana radicata Senecio evacoides Hypochaeris chillensis Quinchamalium procumbens Brayopsis calycina Achyrocline ramosissima Descurainia depressa Aristeguietia ballii Paronychia andina Coreopsis fasciculata Brayopsis monimocalyx Ourisia muscosa Gilia laciniata Bidens andicola Microsteris gracilis

2 10 27 40 20 20 . . 30 . . . . 40 . . 20 . . . . . 30 . . . . . . . 30 . . . . . . . .

1 6 32 17 67 . . 67 67 17 . . 83 . . 100 . . . . . . 50 . . . . .

phyto_45_4_0365_0398_montesinos_0006.indd 391

. . . . . 33 . . . . .

. 100 . 100 83 100 . . . . .

67 67 50 . . 100 67 100 . 50 . . . 83 . 33 . . . .

3 6 41 33 67 . 67 50

. . . . 100 . . . . . .

. . . 100 . . 100 78 . . . . 67 100 78 . . . . .

4 9 22 100 . 100 . .

13 13 . 7 100 . 20 27 . . .

13 . . . 60 27 . 67 . . 60 13 . . . . 13 . . .

5 15 46 100 53 67 80 27

. . . . . . 25 . . . .

. . . 75 75 38 . . . . . . . . . . . . . .

6 8 19 100 . . . .

. . . . . . . . . . .

. . . 3 . 4 3 . 2 3 . . . . . . . . . .

7 4 15 . . . . .

. 60 . 27 7 . . . . 53 20

47 . 47 47 87 53 80 93 . 13 47 40 27 20 73 7 . . 47 27

8 15 96 67 100 20 7 60

. 58 11 32 11 . . . . 63 .

53 32 21 37 100 63 16 95 . 37 79 26 11 63 73 26 . . 47 .

9 19 96 68 68 95 74 63

. 10 . . . . . 30 60 10 100

. . 20 . 70 40 40 40 . 30 50 . . 20 . . 40 . 20 .

10 10 57 60 100 100 100 10

. 100 . . . . . . 86 . 86

14 . . . 86 . . 57 . . 57 71 14 71 43 . . . 86 .

11 7 52 14 100 86 71 14

. 15 20 . . . . . 70 50 .

65 20 20 30 30 40 30 60 . . 40 15 . 90 . . . 15 85 10

12 20 88 65 95 70 45 20

. . . . . . . . . . 100

. . . . . . . . . . . . . 56 . . . . . .

13 9 28 78 . 100 100 .

. . 11 . . . . . . . .

. . . . . . . . . . . . . . . . . . . .

14 9 15 67 . . 11 .

50 . . . 40 . . . . . .

. . . 20 20 . 20 . 30 . 40 20 . 20 . . . 40 . .

15 10 56 50 . . 70 40

. . . . . . . . . . .

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16 3 15 1 . . . .

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. . . . . . . 14 . . . . . . . . . . . .

17 7 37 14 . . . .

. . . . . 75 . . 13 . .

. . . . . 38 . . . . . . . . . . . . 13 13

18 8 45 . 13 . . .

. . . . . 60 . . . . .

. . . . . 20 . . . . . . . . . . . 20 . .

19 5 26 . . . . .

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20 6 33 . . . . .

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21 6 18 . . . . .

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22 9 24 . . . . .

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23 9 32 22 . . . .

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24 11 38 36 . . . .

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25 5 22 . . . . .

. . . . . . . . . . .

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26 8 39 13 . . 13 .

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27 4 19 . . . . .

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28 9 57 . . . . 67

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29 8 38 . . . . 25

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. . . . . . . 7 . . . . . . . . . 7 . 17

30 30 82 10 . . . .

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31 4 35 . . . . 1

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Column no. 1 2 3 Number of relevĂŠs 6 10 6 Number of species 32 27 41 Cheilanthes arequipensis . . . Arenaria digyna . . . Perezia pungens . . . Senecio candolleii . . . Laennecia artemisioides . . . Calceolaria inamoena . . . Galinsoga mandonii . . . Gnaphalium americanum . . . Cyperus seslerioides . . . Facelis plumosa . . . Ephedra americana . . . Vicia andicola . . . Galium aparine . . . Species not found in the present study Parastrephia lucida . . . Senecio spinosus . . . Poa candamoana . . . Nassella brachyphylla . . . Chuquiraga rotundifolia . . . Polylepis rugulosa . . . Diplostephium tovarii . . . Nassella pubiflora . . . Astragalus garbancillo . . . Parastrephia lepidophylla . . . Baccharis buxifolia . . . Diplostephium tacorense . . . Calceolaria xerophila . . . Mutisia hastata . . . Senecio phylloleptus . . . Deyeuxia heterophylla . . . Plantago linearis . . . Opuntia soehrensii . . . Nassella mucronata . . . Bartsia elongata . . . Vulpia megalura . . . Bidens pilosa . . . Nassella depauperata . . . Hordeum muticum . . .

5 15 46 . . . . . . . . 47 . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4 9 22 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

phyto_45_4_0365_0398_montesinos_0006.indd 392

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6 8 19 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7 4 15 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

8 15 96 . . 40 . 7 47 27 27 53 20 7 . 7 . . . . . . . . . . . . . . . . . . . . . . . .

9 19 96 37 . . . . 16 42 32 74 79 11 . 21 . . . . . . . . . . . . . . . . . . . . . . . .

10 10 57 . . . . . 10 . . . 30 . . 10 . . . . . . . . . . . . . . . . . . . . . . . .

11 7 52 . . . . 86 14 43 . 100 29 . . . . . . . . . . . . . . . . . . . . . . . . . . .

12 20 88 . 25 60 . . . 45 15 40 25 . 20 . . . . . . . . . . . . . . . . . . . . . . . . .

13 9 28 . . . . 100 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

14 9 15 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

15 10 56 . 80 10 30 20 . . . . . . . . 1 . . . 1 1 2 3 1 2 . . . . . . . . . . . . . .

16 3 15 . . . . . . . . . . . . . . . 14 43 29 . 57 86 . . 57 29 29 29 29 . . 29 . . . . . .

17 7 37 . . . . . 14 . . . . . . . . 25 50 . . . . 25 . . . . . . . 13 25 13 38 25 38 25 13 13

18 8 45 . . 25 . . . . . 13 . . . . . 40 100 . . . . . . . . . . . . 20 20 . 60 40 . . . .

19 5 26 . . 20 . . . . . . . . . . . 33 83 . . . . 17 . . . . . . . 67 . . 83 . . . . .

20 6 33 . . . . . . . . . . . . . 100 33 17 . . . . . . . . . . . . . . . . . . . . .

21 6 18 . . . . . . . . . . . . . 100 11 . . . . . . . . . . . . . . . . . . . . . .

22 9 24 . . . . . . . . . . . . . 67 56 11 11 . . . . . . . . . . . . . . . . . . . .

23 9 32 . . . . . . . . . . . . . 9 9 . 9 . . . . . . . . . . . . . . . . . . . .

24 11 38 . . . . . . . . . . . . . . 20 . . . . . . . 100 . . . . . . . . . . . . . .

25 5 22 . . . . . . . . . . . . . . 13 13 . . 25 . . . . 13 . . . . 25 . . . . . . . .

26 8 39 . . . . . . . . . . . . . 3 . . . . . . . . . . . . . . . . . . . . . . .

27 4 19 . . . . . . . . . . . . . . . . . . . . . 22 . . . . . . 22 . . 11 . . . 56 22

28 9 57 . . . . 22 . . . 11 . 11 . . . . . . . . . . 63 . . . . . . . . . . . . . . .

29 8 38 . . . . . . . . . . 38 . . . 7 3 . 20 . . 13 . . . 53 . . . . 7 40 . . 3 . . .

30 30 82 . . . . . 7 . . . . . . . . . . . 4 3 . 1 . 1 . . . . . . . 2 . . . . . .

31 4 35 . . . . . . . . . . . . .

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Column no. Number of relevĂŠs Number of species Paranephelius ovatus Bartsia camporum Agrostis gelida Lupinus saxatilis Deyeuxia cabrerae Nototriche argentea Astragalus sp. Adesmia patancana Perezia ciliosa Baccharis incarum Nototriche obcuneata Dissanthelium peruvianum Arenaria serpens Nassella nardoides Nassella asplundii Deyeuxia intermedia Festuca rigescens Calamagrostis breviaristata Werneria aretioides Ephedra breana Adesmia melanthes Tarasa tenella Schkuhria pusilla Gnaphalium cheiranthifolium Stipa holwayi Heterosperma nana Muhlenbergia fastigata Hoffmannseggia minor Euphorbia ovalifolia Distichlis humilis Bromus uniloides Oxalis bisfracta Plagiobothrys congestus Aristida asplundii Ombrophytum subterraneum Geranium sp.

2 10 27 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1 6 32 . . . . . . . . . . . . . . . . . . . . . . . .

phyto_45_4_0365_0398_montesinos_0006.indd 393

. . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

3 6 41 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

4 9 22 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

5 15 46 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

6 8 19 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

7 4 15 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

8 15 96 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

9 19 96 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

10 10 57 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

11 7 52 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

12 20 88 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

13 9 28 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

14 9 15 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

15 10 56 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

16 3 15 . . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

17 7 37 . 29 . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

18 8 45 75 . . . . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

19 5 26 60 . 100 40 . . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

20 6 33 17 50 . . 17 . . . . . . . . . . . . .

. . . . . . . . . . .

. . . . . .

21 6 18 . . . . 100 . . . . . . . . . . . 33 .

. . . . . . . . . . .

100 . . . . .

22 9 24 . . . . . 22 22 22 22 11 . . . . . . . 78

. . . . . . . . . . .

33 . . . . .

23 9 32 . . . . . . . . . 11 22 22 22 . . . . .

. . . . . . . . . . .

. . . . . .

24 11 38 . . . . . . . . . 100 . . . 9 9 9 . .

. . . . . . . . . . .

. 40 40 . . .

25 5 22 . . . . . . 20 . . 60 . . . 20 . . . 60

. . . . . . . . . . .

. . . . . .

26 8 39 . . . 38 . . . . . . . . . . . . 13 13

. . . . . . . . . . .

2 . 1 . . .

27 4 19 . . . . . . . . . 2 . . . . . . . 1

33 22 78 44 33 33 22 22 22 22 22

. . . 11 67 44

28 9 57 . . . . . . . . . 56 . . . 11 . . . 33

13 13 . . . . . . . . .

. . . 25 75 13

29 8 38 . . . . . . . . . 50 . . . 88 . . . 13

. . . . . . . . . . .

. . . . . .

30 30 82 . . . . . . . . . 50 . 3 . . 53 23 3 .

. . . . . . . . . . .

. 3 . . . .

31 4 35 . . . . . . . . . 4 . . . . . . . .

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Column no. Number of relevĂŠs Number of species Solanum sinuatirecurvum Nassella linearifolia Gomphrena umbellata Lampaya castellani Acantholippia salsoloides Verbena seriphioides Opuntia glomerata Fabiana densa Stipa curviseta Senecio potosianus Gutierrezia gilliesii Fabiana stephanii Opuntia corotilla Baccharis boliviensis Corryocactus brevistylus Franseria fruticosa Opuntia sphaerica Tarasa operculata

1 6 32 . . . . . . . . . . . . . . . . . .

2 10 27 . . . . . . . . . . . . . . . . . .

3 6 41 . . . . . . . . . . . . . . . . . .

4 9 22 . . . . . . . . . . . . . . . . . .

5 15 46 . . . . . . . . . . . . . . . . . .

6 8 19 . . . . . . . . . . . . . . . . . .

7 4 15 . . . . . . . . . . . . . . . . . .

8 15 96 . . . . . . . . . . . . . . . . . .

9 19 96 . . . . . . . . . . . . . . . . . .

10 10 57 . . . . . . . . . . . . . . . . . .

11 7 52 . . . . . . . . . . . . . . . . . .

12 20 88 . . . . . . . . . . . . . . . . . .

13 9 28 . . . . . . . . . . . . . . . . . .

14 9 15 . . . . . . . . . . . . . . . . . .

15 10 56 . . . . . . . . . . . . . . . . . .

16 3 15 . . . . . . . . . . . . . . . . . .

17 7 37 . . . . . . . . . . . . . . . . . .

18 8 45 . . . . . . . . . . . . . . . . . .

19 5 26 . . . . . . . . . . . . . . . . . .

20 6 33 . . . . . . . . . . . . . . . . . .

21 6 18 . . . . . . . . . . . . . . . . . .

22 9 24 . . . . . . . . . . . . . . . . . .

23 9 32 . . . . . . . . . . . . . . . . . .

24 11 38 . . . . . . . . . . . . . . . . . .

25 5 22 . . . . . . . . . . . . . 20 . . . .

26 8 39 . . . . . . . . . . . . . . . . . .

27 4 19 . . . . . . . . . . . . . . . . . .

28 9 57 22 67 33 . . . . . . . . . . . . . . .

29 8 38 . 25 25 100 88 88 63 63 63 38 25 . . 13 . . . .

30 30 82 . . . . . . . . . . . 47 33 23 33 33 30 30

31 4 35 . . . . . . . . . . . . . 4 . . . .

394

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Other species: In 1 Oreocereus hendriksenianus 17, Puya ferruginea 17, Triniochloa stipoides 17; in 2 Saxifraga magellanica 10; in 3 Descurainia myriophylla 17, Paronychia weberbaueri 20, Senecio klattii 20; in 4 Belloa sp.2, Perezia ciliosa 22; in 5 Aristida adscencionis 13, Cerastium sp. 13; in 8 Aphanes andicola 20, Ephedra americana 7, Eragrostis nigricans 7, Escallonia myrtilloides 13, Philibertia solanoides 13, Solanum chamaesarachidium 13, Solanum fragile 7, Triniochloa stipoides 20; in 9 Adesmia spinosissima 16, Bougueria nubicola 16, Castilleja laciniata 11, Ephedra americana 11, Eragrostis nigricans 11, Escallonia myrtilloides 11, Geranium core-core 11, Solanum fragile 11; in 10 Solanum fragile 10; in 12 Adesmia miraflorensis 15, Adesmia spinosissima 15, Astragalus micranthellus 20, Chondrosum simplex 15, Eragrostis nigricans 10, Geranium core-core 15, Plantago sp. 20, Perezia sublyrata 20, Lobivia sp. 20, Hedeoma mandoniana 15, Ophioglossum crotalophoroides 15, Valeriana coarctata 5; Vicia andicola 20; in 15 Junellia minima 20, Perezia pinnatifida 10, Nototriche anthemidifolia 20, N. pedicularifolia 10, Oreomyrrhis andicola 10, Pycnophyllum glomeratum 10 Oxalis eriolepis 20, Sisyrinchium jamesonii 20, Aa rosei 10; in 16 Avena sp. 1; in 17 Xenophyllum poposum 17, Opuntia floccosa 14, Bomarea uniflora 14, Solanum sp. 14, Buddleia coriacea 14, Plantago sericea subsp. sericans 14; in 18 Solanum acaule 13, Lepidium chichicara 13, Erodium cicutarium 13, Schkuhria multiflora 13; in 19 Lupinus microphyllus 20; in 20 Senecio graveolens 17, Dissanthelium macusaniense 17, Lupinus microphyllus 17, Mutisia arequipensis 17, Erigeron incanus 17, Hypochaeris eriolaena 17; in 21 Pycnophyllum weberbaueri 17, Poa aequigluma 17, Deyeuxia brevifolia 17, Pycnophyllum sp. 17; in 22 Werneria sp. 11, Senecio graveolens 11, Deyeuxia nardifolia 11, Nototriche sp. 11, Gamochaeta sp. 11, Werneria glaberrima 11; in 23 Echinopsis huotii 11, Bartsia diffusa 11, Plantago monticola 11, Dissanthelium calycinum 11, Werneria pectinata 11, Astragalus pusillus 11, Werneria sp. 11; in 24 Xenophyllum poposum 18, Bartsia diffusa 11, Dielsiochloa floribunda 9, Werneria apiculata 9, Dissanthelium calycinum 9, Werneria pectinata 9, Anatherostipa rigidiseta 9, Aciachne pulvinata 9, Caiophora superba 9, Oxalis pachyrrhiza 9, Hypochaeris taraxacoides 9; in 25 Paronychia microphylla 20, Deyeuxia sp. 20, Stipa leptostachya 20; in 26 Astragalus uniflorus 13, Senecio rudbeckiifolius 13, Stipa annua 13, Perezia multiflora 13, Anthochloa lepidula 13, Senecio adenophylloides 13, Tephrocactus lagopus 13, Senecio graveolens 13, Erigeron incanus 13; in 27 Polylepis tarapacana 4, Chersodoma candida 2, Senecio zoellneri 1, Stipa venusta 1, Nototriche sp. 1, Adesmia melanthes 1; in 28 Hypochaeris elata 11, Conyza deserticola 11, Neowerdermannia vorwerkii 11, Tarasa tarapacana 11, Plantago orbignyana 11, Festuca humilior 11, Verbena sp. 11, Gnaphalium badium 11, Calycera pulvinata 11, Opuntia boliviana 11; in 29 Taraxacum officinale 13, Capsella bursa-pastoris 13, Opuntia steiniana 13, Senecio vulgaris 13, Lupinus sp. 13, Perezia sp. 13, Opuntia boliviana 13; in 30 Junellia juniperina 20, Polylepis besserii 20, Spergularia congestifolia 20, Grindelia boliviana 17, Hypochaeris taraxacoides 17, Oreocereus tacnaensis 17, Plantago monticola 17, Brassicaceae 17, Balbisia meyeniana 13, Junellia arequipense 13, Bromus lanatus 13, Eragrostis weberbaueri 13, Senecio adenophyllus 10, Echinopsis huotii 10, Opuntia subulata 7, Bartsia diffusa 7, Oreocereus hempelianus 7, Anatherostipa rigidiseta 7, Oritrophium peruvianum 7, Paronychia microphylla 3, Chersodoma arequipensis 3, Stipa nardoides 3, Proustia foliosa 3, Glandularia laciniata 3, Polyachyrus sphaerocephalus 3, Ophryosporus heptanthus 3, Baccharis latifolia 3, Stipa sp. 3, Dielsiochloa floribunda 3, Dissanthelium breve 3, Senecio richii 3, Solanum peruvianum 3, Viguiera procumbens 3, Euphorbia sp. 3, Senecio clivicolus 3, Bidens triplinervia 3, Mutisia acuminata 3, Ophryosporus peruvianus 3; in 31 Calceolaria pulchella 4, Fabiana ramulosa 4, Opuntia echinacea 4, Quinchamalium chilense 4, Opuntia berteroi 2, Neoporteria sp. 2, Junellia seriphioides 2, Lupinus oreophilus 1, Diplostephium cinereum 1, Mutisia hamata 1, Chenopodium petiolare 1, Mutisia lanigera 1, Stipa sp. 1, Senecio olivaceobracteatus 1, Descurainia sp. 1, Sisyrinchium sp. 1, Plantago monticola 1.

Appendix 2 Typus relevés of all newly described associations and subassociations. Plantagini sericeae-Plazietum daphnoidis ass. nov. Supplement S1, Rel. number 5, altitude 3820 m, slope 60°, aspect SW, rocks 90%, stones 1%, vegetation cover 30%, number of species 22. Plantago sericea 3, Plazia daphnoides 3, Stipa ichu 3, Coreopsis fasciculata 2, Oreocereus hendriksenianus 2, Triniochloa stipoides 2, Aa mathewsii 1, Argyrochosma nivea 1, Cardionema ramosissimum 1, Cheilanthes myriophylla 1, Cheilanthes pruinata 1, Cheilanthes scariosa 1, Galium corymbosum 1, Hieracium streptochaetum 1, Luzula racemosa 1, Muhlenbergia peruviana 1, Oxalis megalorrhiza 1, Pellaea ternifolia 1, Peperomia scutellaefolia 1, Polypodium pycnocarpum 1, Tillandsia capillaris 1, Vasquezia oppositifolia 1. Phacelio secundae-Ribesetum brachybothryos ass. nov. Supplement S1, Rel. number 9, altitude 4500 m, slope 60°, aspect SE, rocks 15%, stones 80%, vegetation cover 25%, number of species 14. Ribes brachybothrys 5, Salpichroa glandulosa 4, Tillandsia capillaris 4, Chersodoma jodopappa 2, Phacelia pinnatifida 2, Argyrochosma nivea 1, Belloa piptolepis 1, Bromus catharticus 1, Cystopteris fragilis 1, Galium corymbosum 1, Neowerdermannia peruviana 1, Oxalis megalorrhiza 1, Phacelia secunda 1, Valeriana interrupta 1. Neowerdermannio peruvianae-Festucetum weberbaueri ass. nov. Supplement S1, Rel. number 19, altitude 3960 m, Slope 70°, aspect SE, rocks 85%, stones 10%, vegetation cover 45%, number of species 31. Achyrocline ramosissima 3, Aristeguietia ballii 3, Festuca weberbaueri 3, Neowerdermannia peruviana 3, Salpichroa glandulosa 3, Bromus catharticus 2, Chersodoma jodopappa 2, Clinopodium bolivianum 2, Senecio sublutescens 2, Stipa ichu 2, Viguiera procumbens 2, Achyrocline alata 1, Argyrochosma nivea 1, Asplenium peruvianum 1, Belloa piptolepis 1, Bowlesia lobata 1, Campyloneurum amphostenon 1, Cardionema ramosissimum 1, Cheilanthes pruinata 1, Coreopeschweizerbart_xxx

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sis fasciculata 1, Echeveria peruviana 1, Hypochaeris meyeniana 1, Luzula racemosa 1, Oxalis megalorrhiza 1, Paronychia andina 1, Peperomia scutellaefolia 1, Phacelia pinnatifida 1, Sisyrinchium rigidifolium 1, Spergularia fasciculata 1, Vasquezia oppositifolia 1, Woodsia montevidensis 1. Hypochaerido mucidae-Valerianetum nivalis ass. nov. Supplement S1, Rel. number 24, altitude 4090 m, slope 45°, aspect S, rocks 85%, stones 5%, vegetation cover 30%, number of species 15. Ribes brachybothrys 5, Nassella inconspicua 3, Valeriana nivalis 3, Cerastium subspicatum 2, Gnaphalium polium 2, Hypochaeris mucida 2, Paronychia andina 2, Senecio sp. 2, Valeriana interrupta 2, Belloa kunthiana 1, Belloa piptolepis 1, Bowlesia lobata 1, Cheilanthes pruinata 1, Peperomia scutellaefolia 1, Woodsia montevidensis 1. Paronychio ubinensis-Hypochaeridetum mucidae ass. nov. Supplement S1, Rel. number 34, altitude 4100 m, slope 5°, aspect W, rocks 85%, stones 5%, vegetation cover 25%, number of species 16. Hypochaeris meyeniana 3, Loricaria graveolens 3, Paronychia andina 3, Belloa piptolepis 2, Bartsia crenoloba 1, Belloa kunthiana 1, Bromus catharticus 1, Calamagrostis vicunarum 1, Cardionema ramosissimum 1, Hypochaeris mucida 1, Luzula racemosa 1, Muhlenbergia peruviana 1, Nassella inconspicua 1, Nototriche foetida 1, Paronychia ubinensis 1, Spergularia andina 1. Hypochaerido mucidae-Paronychietum muschleri ass. nov. Supplement S1, Rel. number 49, altitude 4360 m, slope 70°, aspect S, rocks 90%, stones 5%, vegetation cover 20%, number of species 15. Loricaria graveolens 4, Senecio sublutescens 2, Belloa kunthiana 1, Belloa piptolepis 1, Belloa schulzii 1, Brayopsis monimocalyx 1, Calamagrostis vicunarum 1, Calandrinia acaulis 1, Cheilanthes pilosa 1, Draba sp. 1, Hieracium streptochaetum 1, Hypochaeris mucida 1, Luzula racemosa 1, Paronychia muschleri 1, Peperomia scutellaefolia 1. Baccharido tricuneatae-Puyetum raimondii senecionetosum ferreyrae subass. nov. Supplement S2, Rel. number 10, altitude 3860 m, slope 45°, aspect SW, rocks 25%, stones 45%, vegetation cover 75%, number of species 43. Puya raimondii 4, Stipa ichu 4, Baccharis tricuneata 3, Chersodoma jodopappa 3, Clinopodium bolivianum 3, Conyza deserticola 3, Mutisia orbignyana 3, Parastrephia quadrangularis 3, Salpichroa glandulosa 3, Achyrocline ramosissima 2, Bartsia peruviana 2, Bomarea involucrosa 2, Bowlesia lobata 2, Cheilanthes pilosa 2, Cumulopuntia boliviana subsp. ignescens 2, Festuca dolichophylla 2, Hieracium streptochaetum 2, Hypochaeris chillensis 2, Lobivia maximiliana 2, Senecio ferreyrae 2, Senecio sublutescens 2, Solanum bukasovii 2, Stevia macbridei 2, Ageratina azangaroensis 1, Alstroemeria pygmaea 1, Aphanes andicola 1, Bartsia crenoloba 1, Belloa longifolia 1, Belloa piptolepis 1, Bromus catharticus 1, Cheilanthes pruinata 1, Euphorbia huanchahana 1, Galinsoga mandonii 1, Galium corymbosum 1, Gamochaeta purpurea 1, Geranium sessiliflorum 1, Muhlenbergia peruviana 1, Oxalis megalorrhiza 1, Solanum chamaesarachidium 1, Tagetes multiflora 1, Tarasa nototrichoides 1, Vasquezia oppositifolia 1, Woodsia montevidensis 1. Baccharido tricuneatae-Puyetum raimondii ageratinetosum sternbergianae subass. nov. Supplement S2, Rel. number 28, altitude 4170 m, slope 45°, aspect E, rocks 20%, stones 55%, vegetation cover 70%, number of species 47. Puya raimondii 5, Stipa ichu 4, Festuca dolichophylla 3, Achyrocline ramosissima 2, Ageratina sternbergiana 2, Baccharis tricuneata 2, Bartsia crenoloba 2, Belloa piptolepis 2, Clinopodium bolivianum 2, Conyza deserticola 2, Cumulopuntia boliviana subsp. ignescens 2, Ephedra rupestris 2, Geranium sessiliflorum 2, Hypochaeris chillensis 2, Hypochaeris meyeniana 2, Lepechinia meyenii 2, Nassella inconspicua 2, Parastrephia quadrangularis 2, Sisyrinchium rigidifolium 2, Stevia mandonii 2, Aristeguietia ballii 1, Bartsia peruviana 1, Bidens andicola 1, Bowlesia lobata 1, Bromus catharticus 1, Calceolaria inamoena 1, Cerastium subspicatum 1, Cheilanthes pilosa 1, Cheilanthes pruinata 1, Crassula connata 1, Cyperus seslerioides 1, Facelis plumosa 1, Galinsoga mandonii 1, Galium corymbosum 1, Gnaphalium americanum 1, Hieracium streptochaetum 1, Muhlenbergia peruviana 1, Mutisia orbignyana 1, Oxalis calachaccensis 1, Oxalis megalorrhiza 1, Salpichroa glandulosa 1, Spergularia fasciculata 1, Tagetes multiflora 1, Tarasa nototrichoides 1, Valeriana interrupta 1, Vasquezia oppositifolia 1, Weberbauera peruviana 1. Baccharido tricuneatae-Puyetum raimondii lupinetosum cuzcensis subass. nov. Supplement S2, Rel. number 35, altitude 4290 m, slope 30°, aspect NE, rocks 10%, stones 10%, vegetation cover 65%, number of species 36.

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Festuca dolichophylla 4, Lupinus paruroensis 4, Mutisia orbignyana 4, Nassella inconspicua 4, Puya raimondii 4, Stipa ichu 4, Cumulopuntia boliviana subsp. ignescens 3, Parastrephia quadrangularis 3, Baccharis tricuneata 2, Calamagrostis vicunarum 2, Calceolaria lobata 2, Hypochaeris meyeniana 2, Lobivia maximiliana 2, Senecio nutans 2, Alstroemeria pygmaea 1, Bartsia crenoloba 1, Bowlesia lobata 1, Calamagrostis violacea 1, Cheilanthes pruinata 1, Conyza deserticola 1, Crassula connata 1, Euphorbia huanchahana 1, Facelis plumosa 1, Galium corymbosum 1, Gilia laciniata 1, Gnaphalium dombeyanum 1, Hieracium streptochaetum 1, Hypochaeris chillensis 1, Lupinus cuzcensis 1, Microsteris gracilis 1, Muhlenbergia peruviana 1, Olsynium junceum 1, Oxalis nubigena 1, Tagetes multiflora 1, Tarasa nototrichoides 1, Valeriana radicata 1, Woodsia montevidensis 1. Baccharido tricuneatae-Puyetum raimondii calamagrostietosum heterophyllae subass. nov. Supplement S2, Rel. number 49, altitude 4030 m, slope 40°, aspect NW, rocks 10%, stones 10%, vegetation cover 40%, number of species 28. Lupinus paruroensis 5, Puya raimondii 4, Stipa ichu 4, Nassella inconspicua 3, Alstroemeria pygmaea 2, Baccharis tricuneata 2, Calamagrostis heterophylla 2, Cumulopuntia boliviana subsp. ignescens 2, Hieracium streptochaetum 2, Tetraglochin cristatum 2, Achyrocline ramosissima 1, Bowlesia lobata 1, Cheilanthes pruinata 1, Conyza deserticola 1, Cyperus seslerioides 1, Ephedra rupestris 1, Galium corymbosum 1, Gilia laciniata 1, Hypochaeris chillensis 1, Laennecia artemisioides 1, Lepechinia meyenii 1, Microsteris gracilis 1, Muhlenbergia peruviana 1, Parastrephia quadrangularis 1, Poa gymnantha 1, Stipa obtusa 1, Tarasa nototrichoides 1, Viola micranthella 1. Sisyrinchio rigidifolii-Parastrephietum quadrangularis ass. nov. Supplement S3, Rel. number 3, altitude 4040 m, slope 25°, aspect ESE, rocks 20%, stones 15%, vegetation cover 70%, number of species 37. Parastrephia quadrangularis 5, Festuca dolichophylla 4, Stipa ichu 4, Nassella inconspicua 3, Baccharis tricuneata 2, Belloa longifolia 2, Caiophora chuquitensis 2, Cumulopuntia boliviana subsp. ignescens 2, Hieracium streptochaetum 2, Hypochaeris meyeniana 2, Lobivia sp. 2, Philibertia lysimachioides 2, Sisyrinchium rigidifolium 2, Tetraglochin cristatum 2, Arenaria digyna 1, Astragalus arequipensis 1, Bartsia crenoloba 1, Conyza deserticola 1, Crassula connata 1, Cyperus seslerioides 1, Descurainia depressa 1, Facelis plumosa 1, Galium corymbosum 1, Gomphrena meyeniana 1, Hedeoma mandoniana 1, Hypochaeris chillensis 1, Muhlenbergia peruviana 1, Ophioglossum crotalophoroides 1, Oxalis nubigena 1, Perezia coerulescens 1, Plantago sp. 1, Senecio evacoides 1, Tagetes multiflora 1, Tarasa nototrichoides 1, Vicia andicola 1, Viola micranthella 1, Woodsia montevidensis 1. Baccharido caespitosae-Azorelletum diapensioidis ass. nov. Supplement S3, Rel. number 42, altitude 4380 m, slope 10°, aspect SW, rocks 20%, stones 10%, vegetation cover 55%, number of species 19. Azorella diapensioides 4, Pycnophyllum molle 4, Baccharis caespitosa 3, Parastrephia quadrangularis 3, Stipa ichu 3, Baccharis tricuneata 2, Calamagrostis curvula 2, Cumulopuntia boliviana subsp. ignescens 2, Festuca dolichophylla 2, Pycnophyllum glomeratum 2, Tetraglochin cristatum 2, Arenaria digyna 1, Brayopsis calycina 1, Calandrinia acaulis 1, Gomphrena meyeniana 1, Hypochaeris meyeniana 1, Paronychia andina 1, Plantago sericea var. lanuginosa 1, Valeriana nivalis 1.

Electronic supplements Supplementary material associated with this article is embedded in the pdf of this article. The online version of Phytocoenologia is hosted at the journal’s website www.schweizerbart.com/journals/phyto. The publisher does not bear any liability for the lack of usability or correctness of supplementary material. Supplement S1. Chasmophyte communities of the Argyrochosmo niveae-Neowerdermannion peruvianae and Hypochaerido mucidae-Loricarion graveolentis of steep basalt cliffs. Supplement S2. Baccharido tricuneatae-Puyetum raimondii (Azorello-Festucion) and its four subassociations in the Moquegua region. Supplement S3. Grassland communities (Sisyrinchio rigidifolii-Parastrephietum quadrangularis, Azorello-Festucion and Baccharido caespitosae-Azorelletum diapensioidis, Calamagrostion minimae) in the Moquegua region at 3940–4470 m a.s.l. Supplement S4. List of the outlier syntaxa of the Farthest Neighbor Clustering. Please download the electronic supplement and rename the file extension to .zip (For security reasons Adobe does not allow to embed .exe, .zip, .rar etc. files).

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