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Original scientific paper

https://doi.org/10.37427/botcro-2022-027

An Asphodelus ramosus dominated plant community in Montenegro: fringe or grassland?

Milica Stanišić-Vujačić ; University of Montenegro, Faculty of Natural Sciences and Mathematics, Džordža Vašingtona bb, 81000 Podgorica, Montenegro
Danijela Stešević ; University of Montenegro, Faculty of Natural Sciences and Mathematics, Džordža Vašingtona bb, 81000 Podgorica, Montenegro
Sead Hadžiablahović ; Environmental Protection Agency of Montenegro, IV Proleterske 19, 81000 Podgorica, Montenegro
Danka Caković ; University of Montenegro, Faculty of Natural Sciences and Mathematics, Džordža Vašingtona bb, 81000 Podgorica, Montenegro
Urban Šilc ; ZRC SAZU, Institute of Biology, Novi trg 2, 1000 Ljubljana, Slovenia


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Abstract

Our phytosociological study in Montenegro (Ćemovsko polje) deals with the syntaxonomy of arid grasslands in the Adriatic region and, in particular, different interpretations of plant communities dominated by Asphodelus ramosus. The main aims of this study were to contribute to knowledge of the composition of dry grasslands dominated by Asphodelus ramosus in Montenegro and to compare instances of Asphodelus ramosus dominated vegetation along the Adriatic. Our vegetation dataset included 82 phytosociological relevés: 17 from our recent field work and 72 relevés of South European Asphodelus ramosus communities. Ordination analysis (NMDS) was used for comparison of Asphodelus ramosus dominated communities in the Adriatic region. The Asphodelus ramosus community from Montenegro was classified into Bromo erecti-Chrysopogonetum grylli. The analysis revealed two distinct vegetation groups: grassland communities of the vegetation class Festuco-Brometea from Montenegro, Croatia and Albania, and edge vegetation of the new class Charybdido pancratii-Asphodeletea ramosi from Italy. Comparison with similar vegetation types shows high similarity with associations on the eastern Adriatic coast, where they are treated as grassland communities belonging to the alliance Chrysopogono grylli-Koelerion splendentis, order Scorzoneretalia villosae, class Festuco-Brometea.

Keywords

Asphodelus ramosus, Bromo erecti-Chrysopogonetum grylli, dry grasslands, Festuco-Brometea, Montenegro

Hrčak ID:

269975

URI

https://hrcak.srce.hr/269975

Publication date:

1.4.2022.

Visits: 1.475 *




Introduction

Secondary dry grassland communities in the Mediterranean have a zoo-anthropogenic origin; they have developed over centuries or even millennia of traditional land use, featuring practices such as mowing, grazing, temporary abandonment of arable fields, and/or other disturbance regimes (Apostolova et al. 2014,Valkó et al. 2018). Mediterranean and sub-Mediterranean dry grasslands are considered to be among the floristically richest vegetation types (Apostolova et al. 2014) and, at the same time, a very important habitat for endangered, rare and endemic species, so they are included in the list of Habitats of European Interest (Council Directive 92/43/EEC on the conservation of natural habitats and of wild fauna and flora, 1992), as well as the European Red List of Habitats (Janssen et al. 2016). Compared to other parts of Europe, dry grasslands of the Balkan peninsula are still well preserved (Apostolova et al. 2014).

The Balkan peninsula is well known for its rich flora and well-preserved vegetation, because it was a glacial refuge for animal and plant species (Griffiths et al. 2004). Its biodiversity is considered to be among the highest in Europe (Apostolova et al. 2014). The peninsula is characterized by the presence of a broad spectrum of dry grasslands (e.g.,Horvat et al. 1974,Jovanović et al. 1986,Apostolova et al. 2014,Terzi 2015,Aćić et al. 2015,Matevski et al. 2018). In some Balkan countries (Slovenia, Serbia, Bulgaria, Croatia, North Macedonia), dry grassland vegetation has been intensively researched (Apostolova et al. 2014,Matevski et al. 2018). In contrast to these countries, research into this type of vegetation in Montenegro has considerable discontinuity, and comprenhensive studies, especially in the sub-Mediterranean and Mediterranean region, are rare (Pulević and Bulić 2012).

In our study, we focused on research into Asphodelus ramosus-dominated vegetation. Asphodelus ramosus is a species native to the Mediterranean and Macaronesian regions: southern Europe, northern Africa, the Middle East, Mediterranean islands and Canary Islands. It can be found in forest edges and grasslands, generally on basic soils of a certain depth, forming very dense populations in grazed areas, from the coast up to 1000 m, occasionally reaching 2150 m in the mountain systems of North Africa (Diaz-Lifante and Valdés 1996). It is unpalatable for grazing animals.

Research into plant communities dominated by Asphodelus spp. (and Asphodelus ramosus in particular) has become very intensive in recent years, especially in the western and central Mediterranean (Allegrezza et al. 2015,Biondi et al. 2016,2017). In the Balkan peninsula, similar vegetation has been described from Albania (Fanelli et al. 2015) and Croatia (Horvatić 1934,1939,1963,Šegulja 1969,1970,Hećimović 1984,Jasprica and Ruščić 2013,Jasprica et al. 2016).

Today, there are different opinions about the syntaxonomical classification of Asphodelus ramosus dominated vegetation in Europe and its position in the landscape (as grasslands or fringe (saum) communities). In the eastern Adriatic, these communities have been classified within the grassland class Festuco-Brometea, while in the central and western Adriatic, they have been classified as heliophilous edge vegetation of Trifolio-Geranietea sanguinei (Biondi et al. 2014,Allegrezza et al. 2015) or recently into a new class Charybdido pancratii-Asphodeletea ramosi Biondi et al. 2016 (Biondi et al. 2016,2017).

The aim of this study was to (i) contribute to knowledge of the composition of dry grasslands dominated by Asphodelus ramosus in Montenegro and (ii) compare examples of Asphodelus ramosus dominated vegetation along the Adriatic and its syntaxonomical classification and classification into Natura 2000 habitat types.

Material and methods
Study area

Ćemovsko polje is a part of Zetska ravnica plain in Montenegro, between the rivers Morača, Cijevna and Ribnica. It covers 165 km2 and extends from Podgorica, the capital of Montenegro, to Skadar Lake. The altitude of the investigated area ranges from 12 to 30 m a.s.l. During the Pleistocene period, moraine material eroded from the mountains was carried along the rivers Morača and Cijevna into the area of Ćemovsko polje (Radojičić 2015). The dominant types of soil are eutric cambisol and rendzina, which are formed on fluvio-glacial deposits, and consequently are often shallow and skeletoid (Burić et al. 2017). The area of Ćemovsko polje has a Mediterranean climate with hot summers – Csa (Burić and Micev 2008). A grassland ecosystem is dominant in this area. The studied Asphodelus ramosus-dominated vegetation occurs in pastures used for grazing by cattle and sheep. A significant area of Ćemovsko polje is occupied by vineyards and plantations of peach and other kinds of fruit (Radojičić 2015). The area investigated has also recently been heavily impacted by urbanization (Burić et al. 2017).

Although many floristic studies have been performed in the area of Ćemovsko polje (Černjavski et al. 1949,Hadžiablahović 2010, 2018,Stešević et al. 2014), the vegetation has remained poorly studied (Černjavski et al. 1949,Hadžiablahović 2018). Potential natural vegetation of the wider area of Podgorica and Lake Skadar is Apulian-southeast Adriatic meso-supra-Mediterranean Quercus trojana forests with Pistacia species (Bohn et al. 2000-2003) or precisely Macedonian oak forest ‘Quercetum trojanae montenegrinum Blečić et Lakušić 1975’ (recte: Quercetum trojanae Em 1958). Illyrian sub-Mediterranean rocky grasslands on shallow calcareous soils of the alliance Chrysopogono grylli-Koelerion splendentis Horvatić 1973 prevail in the area of Ćemovsko polje (Hadžiablahović 2010).

Sampling and data analysis

From April to June 2019, we sampled Asphodelus ramosus-dominated plant communities on Ćemovsko polje according to the Braun-Blanquet method (Braun-Blanquet 1964). We made 17 relevés and the size of plots was 25 m2. The minimum distance between plots was 100 m. The minimum coverage value of Asphodelus ramosus for it to be considered dominant was 25%. Each plot was visited in April and again in June. Cover values of species and total vegetation cover are based on the summer aspect (Tab. 1, Appendix 1). GPS coordinates were recorded for each plot (Appendix 2). All relevés made during fieldwork and relevés from the literature were entered into the Turboveg (Hennekens and Schaminée 2001) database. Relevés from the literature were used for comparison with vegetation data from our fieldwork (Appendix 3).

We obtained characteristic species of the association Bromo erecti-Chrysopogonetum grylli according to Horvatić (1963). Diagnostic taxa of alliance and order were assigned according to Terzi (2015), while the diagnostic taxa of classes were determined according to Terzi (2015) for the class Festuco-Brometea, Mucina et al. (2016) for other classes and Biondi et al. (2016) for the class Charybdido pancratii-Asphodeletea ramosi.

Non-metric multidimensional scaling (NMDS,Kruskal 1964) was used to examine the overall variation in the species composition in the whole relevé dataset. Hellinger transformation of percentage cover values (5=87.5%, 4=62.5%, 3= 37.5%, 2=12.5%, 1=2.5%, +=0.5%, r=0.1%) was used and Bray-Curtis as a measure of dissimilarity. NMDS was performed using the R package ‘vegan’ (Oksanen et al. 2017). For ecological interpretation of vegetation patterns, ecological indicator values (Pignatti et al. 2005) were passively projected onto the NMDS graph. Weighted by species cover, mean indicator values were calculated for each relevé using JUICE software (Tichý 2002).

The nomenclature of taxa is in accordance with Euro+Med (2006) and the nomenclature of higher syntaxa according to Mucina et al. (2016).The taxonomy of Asphodelus ramosus species was sometimes ambiguous. Previously, the species Asphodelus microcarpus Viv. was accepted as valid by many authors but, after a taxonomic revision of the genus Asphodelus in the western Mediterranean (Diaz-Lifante and Valdés 1996), it has been considered a synonym of Asphodelus ramosus L. (Euro+Med 2006).

Tab. 1 Phytosociological table of the association Bromo erecti-Chrysopogonetum grylli in Ćemovsko polje (Montenegro).
Relevé number1234567891011121314151617Presence (%)
Plot size (m2)25
Vegetation cover (%)8060807075606075606570706060606060
Bromo erecti-Chrysopogonetum grylli
Asphodelus ramosus4343433334333343417
Chrysopogono grylli-Koelerion splendentis
Bupleurum veronense+++..+.+..+.+++..9
Carduus nutans subsp. micropterus.+.+...+.....+...4
Scorzoneretalia villosae
Chrysopogon gryllus12232212.1322221.15
Eryngium amethystinum++1.1+1++.11+111115
Koeleria lobata+++.+1..+.1.+11+112
Seseli montanum subsp. tommasinii1...+.+.+..1..+1.7
Satureja subspicata...+....+2...22.+6
Festuca stricta subsp. sulcata...+.+.12..+.....5
Medicago prostrata+.........1+.+...4
Plantago holosteum.+++.......+.....4
Bunium alpinum subsp. montanum..+.....++....+..4
Scorzonera villosa..1+....++.......4
Festuco-Brometea
Sanguisorba minor32322+12+1222112117
Poa bulbosa11121221++1+2112117
Teucrium capitatum+11++1112+12+221117
Hypericum perforatum++++++.1+.+++++1+15
Hippocrepis ciliata+.1.+1+..1+++++++13
Centaurea deusta++..+++31+1111.3.13
Leontodon crispus..+++...11111.1++11
Ranunculus millefoliatus.+++...++..+1++.+10
Convolvulus cantabrica+...212...111+.1.9
Petrorhagia saxifraga...+++++..++..++.9
Linum tenuifolium.++..+..1..+++..+8
Anthyllis vulneraria subsp. polyphylla..+.++..+++++....8
Carex caryophyllea...1......1++111.7
Podospermum laciniatum++.++...........+5
Bothriochloa ischaemum.......+1+1...1..5
Anacamptis morio.+.++.....+......4
Trifolium campestre.+....+..+.....+.4
Ophrys sphegodes......+.+.....+..3
Cuscuta epithymum subsp. epithymum....+.....++.....3
Thymus striatus........+....++..3
Leopoldia comosa.+......+.......+3
Chenopodietea
Avena barbata++++111..2..1..++11
Valantia muralis..1.+....1....+.+5
Scandix pecten-veneris.......++..+.....3
Stipo-Trachynietea distachyae
Sideritis romana subsp. purpurea++1++1++++++++++117
Crepis sancta11++1111+1++...1+14
Arenaria leptoclados1.+1+++.....++++.10
Polygala monspeliaca.++.+++..++..+.1+10
Ornithogalum collinum+...+++1+.112....9
Tordylium apulum...+.+++..+.....+6
Petrorhagia dubia..++...+....+....4
Filago germanica+....+.....+....+4
Ononis reclinata+...++.........+.4
Trachynia distachya..+.+......1.....3
Neatostema apulum............1++..3
Helianthemetea guttati
Helianthemum salicifolium1+1+1122+1111.11.15
Crupina vulgaris+++.++1.1+++++...12
Asterolinon linum-stellatum+1+++11.....++1+.11
Galium divaricatum11++.+.+.....+.++9
Plantago bellardii+.....++.+..1++..7
Linaria pelisseriana.+.+...++.......+5
Filago gallica.+...+......+.+..4
Aira elegantissima...+.........+.++4
Trifolium stellatum+.+.+............3
Poetea bulbosae
Anthoxanthum odoratum+2.1+++.++..++.1+12
Trifolium subterraneum+1.1+.++..1.+..1110
Plantago lanceolata.++1...+++.....++8
Leontodon tuberosus..+++.+1+........6
Herniaria glabra............++++.4
Prospero autumnale..+.........+..+.3
Trifolium nigrescens.+.......1......+3
Sedo-Scleranthetea
Cerastium pumilum subsp. glutinosum++.111.+....1++1+11
Viola kitaibeliana11++++.+.+..++...10
Clinopodium acinos..+.+.1...+++++..8
Draba verna+..+........++++.6
Artemisietea vulgaris
Daucus guttatus+++++11..2+.+..++12
Scolymus hispanicus.++1.+11+++...+1.11
Tyrimnus leucographus1..+.++1.+.....++8
Potentilla recta...+1.+1.....+...5
Sisymbrietea
Geranium columbinum++.++++++++.++.++14
Erodium cicutarium+..1...1..++1++.19
Bromus squarrosus1.....1+..1.+.+..6
Papaveretea rhoedis
Euphorbia exigua+...+11.++++11+++13
Sherardia arvensis++..++1.+...+..++9
Anagallis arvensis..++++1.+1.....+.8
Sonchus oleraceus++...++..++.+....7
Euphorbia helioscopia........+..++..+.4
Euphorbia taurinensis............+++..3
Molinio-Arrhenatheretea
Serapias vomeracea..+.......++.+.+.5
Hypochaeris radicata.+.+..........++15
Ononido-Rosmarinetea
Carlina corymbosa..+.1+1..++11+..110
Lygeo sparti-Stipetea tenacissimae
Anacamptis papilionacea+++++.+++11111+1+16
Anemone hortensis22222121+11....2.12
Other species
Cynodon dactylon.++++++.+1+++++++15
Allium guttatum subsp. sardoum+1.1+.++..+.+.+++11
Cerastium ligusticum subsp. trichogynum21+11...+..1.11..9
Silene italica.+++++....+1.1...8
Alkanna tinctoria.....+....11111..6
Hainardia cylindrica......1.....++...3
Trifolium scabrum.........+.++....3
Results

The Asphodelus ramosus plant community from Ćemovsko polje (Montenegro) is represented by 17 relevés in the phytosociological table (Tab. 1). The dominant species of the association are Asphodelus ramosus and Chrysopogon gryllus, while the most frequent species are Asphodelus ramosus, Sanguisorba minor, Poa bulbosa, Teucrium capitatum, Sideritis romana subsp. purpurea, and Anacamptis papilionacea. Asphodelus ramosus is also considered to be the only characteristic species of the association. The community develops in two clear phenological aspects. In the spring aspect (Fig. 2A), the dominant species is Asphodelus ramosus, while in summer (Fig. 2B), dominance is taken by the tall grass Chrysopogon gryllus. The spring aspect is also characterised by high frequency and coverage of Anemone hortensis, Poa bulbosa and Sanguisorba minor, and the summer one by Bupleurum veronense and Teucrium capitatum.

In addition to the species characteristic for the class Festuco-Brometea, there are several species of annual and ephemeral grasslands of the classes Stipo-Trachynietea distachyae and Helianthemetea guttate, and seasonal perennial and ephemeroid pastures of the class Poetea bulbosae, all indicating the Mediterranean and grassland character of the studied plant community. The impact of grazing is evident from the many ruderal species: Avena barbata, Scandix pecten-veneris, Daucus guttatus, Scolymus hispanicus, Bromus squarrosus, Euphorbia exigua, Sonchus oleraceus (Tab. 1). The studied stands constitute an open grassland community, which develops on stony soil and is used for grazing (cattle and sheep). Total vegetation coverage is 60 – 80% in the summer aspect. Stones and pebbles have dimensions of up to 20 cm and their cover is 5 – 40%. If the stones are removed and these areas are used for mowing, the vegetation changes into dry grasslands of the alliance Vulpio-Lotion (Hadžiablahović 2018).

Using various numerical classifications, we tried to classify the association Bromo erecti-Chrysopogonetum grylli into subassociations. This kind of vegetation is fairly uniform in the study area, and there were no ecologically evident/logical subunits.

A comparison of the studied Asphodelus community from Montenegro with Asphodelus ramosus-dominated communities from around the Adriatic (Fig. 1) revealed two distinct vegetation groups (Tab. 2,Fig. 3). Communities from Albania, Croatia and Montenegro form one group, with abundant grassland species of the class Festuco-Brometea, which are not present in the second group of edge communities from Italy. Two dimensional solution of the NMDS ordination attained a minimum stress of 0.21. The NMDS ordination clearly distinguishes the two groups along gradients of nutrients, light and soil reaction. Edge communities from Italy thrive on more nutrient-rich, shaded sites (Fig. 3).

Based on floristic composition and all the comparative analyses, we decided to classify the studied stands dominated by Asphodelus ramosus into the already described grassland association Bromo erecti-Chrysopogonetum grylli.

Fig. 1 Localities of data used of Asphodelus ramosus-dominated communities. See Tab. 2 for community abbreviations. AL – Albania, BA – Bosnia and Herzegovina, HR – Croatia, IT – Italy, ME – Montenegro, RS – Serbia, SI – Slovenia.
ABC-81-12-f1
Fig. 2 Asphodelus ramosus dominated community on Ćemovsko polje, vicinity of Podgorica, Montenegro. A – spring aspect, B – summer aspect.
ABC-81-12-f2
Fig. 3 NMDS ordination of Asphodelus ramosus-dominated communities from the Adriatic region with passively projected ecological indicator values. Symbols indicate classification into the classes: ● – Festuco-Brometea, ▲ – Artemisietea vularis, ■ – Charybdido pancratii-Asphodeletea ramosi. Numbers indicate centroids of relevés of particular communities (see Tab. 2).
ABC-81-12-f3
Tab. 2 Shortened synoptic table of plant communities with Asphodelus ramosus. The original classification indicated by authors is used. Communities: 1. Bromo erecti-Chrysopogonetum grylli (Montenegro, new relevés from Ćemovsko polje), 2. Asphodelo-Chrysopogonetum grylli (Albania,Fanelli et al. 2015), 3. Bromo-Chrysopogonetum grylli subass. asphodeletosum microcarpi (Croatia,Horvatić 1934), 4. Narcisso tazzettae-Asphodeletum microcarpi (Croatia,Šegulja 1970), 5. Narcisso tazzettae-Asphodeletum microcarpi (Croatia,Hećimović 1984), 6. Narcisso tazzettae-Asphodeletum microcarpi (Croatia,Jasprica et al. 2016), 7. Asphodelus ramosus community (Albania,Fanelli et al. 2015), 8. Charybdido pancratii-Asphodeletum ramosi (Italy,Biondi et al. 2016), 9. Alkanno tinctoriae-Asphodeletum ramosi (Italy,Biondi et al. 2016), 10. Euphorbio characiae-Thapsietum garganicae (Italy,Biondi et al. 2017), 11. Asphodelo ramosi-Feruletum communis (Italy,Biondi et al. 2016), 12. Asphodelino luteae-Feruletum communis (Italy,Biondi et al. 2016).
Plant community123456789101112
Number of relevés1741281033143527
Bromo erecti-Chrysopogonetum grylli
Asphodelus ramosus1002510010010010010010010060100100
Cytisus spinescens..50.........
Narcisso tazzettae-Asphodeletum microcarpi
Narcissus tazetta.25.10070100.7....
Anacamptis papilionacea94..75...21.40.29
Chrysopogono grylli-Koelerion splendentis
Carduus nutans subsp. micropterus2425505050....80.43
Bupleurum veronense53.42.90.67.....
Centaurea cristata...13........
Salvia officinalis.508.........
Scorzoneretalia villosae
Chrysopogon gryllus8810010088.6733.....
Koeleria lobata712567884067......
Plantago holosteum24253388........
Eryngium amethystinum88505888..337.60.57
Salvia pratensis.253388........
Medicago prostrata24.25.........
Festuca valesiaca..8313........
Seseli montanum subsp. tommasinii41...........
Satureja subspicata35...........
Potentilla heptaphylla subsp. australis..8.........
Dorycnium pentaphyllum subsp. germanicum..17.........
Festuco-Brometea
Sanguisorba minor100251788...29.20..
Bothriochloa ischaemum2925.50100.33.....
Bromopsis erecta.2510075.33......
Hippocrepis comosa..1725........
Linum tenuifolium4725863........
Ruta graveolens.251775...36....
Leopoldia comosa18...70......43
Carex caryophyllea4125.50........
Satureja montana.258...33.....
Ranunculus millefoliatus59........20.14
Charybdido pancratii-Asphodeletum ramosi
Carlina corymbosa765010063..3350.8010029
Asparagus acutifolius6255010050..791006010086
Drimia pancration.......100672010057
Anemone hortensis7125.6370..64.805057
Asphodeline lutea.......7.60.100
Thapsia garganica.......57.100.100
Ferula communis.........20100100
Hypochaeris radicata29......2933...
Asphodeline liburnica.......7....
Other
Dactylis glomerata subsp. hispanica.251008850100.9367...
Plantago lanceolata47253310090..29...71
Reichardia picroides.25507510067.43.40.43
Catapodium rigidum6507588100.100.....
Crepis sancta82......4367.10043
Avena barbata65.3350..67.33.10029
Trifolium scabrum1825252550.67.....
Helichrysum italicum.2575509067337....
Paliurus spina-christi2563.....43..100.
Olea europaea17......43..100.
Pinus halepensis........3320..
Discussion

In recent years, several studies on the distribution and dynamics of plant communities with Asphodelus ramosus have been performed, especially in the central and western Mediterranean (Biondi et al. 2016,Biondi et al. 2017). In contrast, this type of vegetation has been poorly studied in Montenegro.

The association Bromo erecti-Chrysopogonetum grylli was described for the first time in Croatia (Island of Pag,Horvatić 1934), with two subassociations (Bromo-Chrysopogonetum grylli dorycnietosum herbacei and Bromo-Chrysopogonetum grylli asphodeletosum microcarpi), and classified in the alliance ‘Chrysopogoneto-Satureion subspicatae Horvat i Horvatić 1934’ (recte: Chrysopogono grylli-Koelerion splendentis), order ‘Brometalia erecti Br. Bl.’ Subsequently, Bromo-Chrysopogonetum grylli asphodeletosum microcarpi was raised by Horvatić (1963) to the rank of association, with the name Asphodelo microcarpi-Chrysopogonetum grylli, and included in the order ‘Scorzonero-Chrysopogonetalia H-ić et Ht (1956) 1958’ (recte: Scorzoneretalia villosae). The association has so far been reported in Montenegro and Albania (Černjavski et al. 1949,Fanelli et al. 2015,Hadžiablahović 2018). In his nomenclatural revision of the order ‘Scorzonero villosae-Chrysopogonetalia grylli Horvatić et Horvat in Horvatić 1963’, Terzi (2011) considered the associations Asphodelo-Chrysopogonetum grylli and Bromo-Chrysopogonetum grylli to be valid, while Terzi (2015) later united them and retained the earlier valid name, Bromo-Chrysopogonetum grylli (cf.Theurillat et al. 2021).

In Montenegro, Bromo erecti-Chrysopogonetum grylli was reported by Blečić and Lakušić (1976) in the coastal part of Montenegro, as well as in the vicinity of Podgorica, and by Černjavski et al. (1949) and Hadžiablahović (2018) in the area of Skadar Lake. These publications were not supported with phytosociological studies and it was not possible to make a comparison with our results from Ćemovsko polje. According to Černjavski et al. (1949), Bromo-Chrysopogonetum grylli is developed on stony hills with thin soils, while our researched stands are found in the lowlands of Ćemovsko polje on deeper alluvial soils. According to Černjavski et al. (1949)Bromo-Chrysopogonetum grylli is characterized by many species of shrub vegetation (Paliurus spina-christi, Salvia officinalis, Rubus ulmifolius, Euphorbia veneta, Helichrysum italicum, Ruscus aculeatus, Cyclamen neapolitanum, Arum italicum, Phlomis fruticosa, Cistus villosus, Cistus salviaefolius, Nephrodium filix-mas, Pteridium aqiulinum, etc.) and chasmophytic vegetation (Asplenium trichomanes, Edraianthus tenuifolius, Cardamine glauca, Silene quadridentata, Ceterach officinarum, Sedum album, Moltkea petraea, etc.) that were absent from our stands from Ćemovsko polje. Further investigation of the association Bromo-Chrysopogonetum grylli reported by Černjavski (1949) is needed to determine whether there are differences in relation to our community from Ćemovsko polje.

Fanelli et al. (2015) reported Asphodelo-Chrysopogonetum grylli in Albania in the Buna River protected landscape and it shows high similarity with associations from Montenegro and Croatia. The species Cytisus spinescens, which is a characteristic species of the association (Horvatić 1963) is not present in stands from Montenegro and Albania. Stands from Montenegro are also characterized by an absence of species characteristic of dry grasslands of the classes Festuco-BrometeaSalvia officinalis and Bromopsis erecta.

According to Horvatić (1934,1939), the development and distribution of Bromo-Chrysopogonetum grylli asphodeletosum microcarpi is conditioned by agro-pastoral activities, i.e., moderate grazing. In the case of Ćemovsko polje, it is grazed particularly by sheep and rarely by cattle. Intensive and permanent grazing leads to degradation of this community, which is especially evident from the absence of Asphodelus ramosus from relevés on Rab island (Horvatić 1939). Intensive grazing leads to a higher abundance of shrubs (Helichrysum italicum, Cytisus spinescens, Euphorbia spinosa, Salvia officinalis) (Horvatić 1934), or ruderal and subruderal species (Fanelli et al. 2015). Overgrazed stands can be included in the order Carthametalia lanatae (Artemisietea vulgaris) because of abundant therophytes: Carthamus lanatus, Dasypyrum villosum, Catapodium rigidum, Nigella arvensis, etc. (Fanelli et al. 2015). On the other hand, stands are abandoned, after which succession leads to Rhamno-Paliuretum Trinajstić 1996, or are turned into mowed grasslands of the Vulpio-Lotion Horvatić 1963 alliance (Hadžiablahović 2018).

In several localities in Croatia along the Adriatic coast, similar vegetation types with Asphodelus ramosus have been reported. Narcisso tazettae-Asphodeletum microcarpi was described in Istria (Šegulja 1970). The same association was later reported on the islands of Bobara and Mrkan (Hećimović 1984), Supetar (Jasprica and Ruščić 2013) and Olib (Jasprica et al. 2016). Originally, it was classified into Scorzonerion villosae, but was later moved to Chrysopogono grylli-Koelerion splendentis. Ecological conditions are different to those of Asphodelo ramosi-Chrysopogonetum grylli and it occurs on deep skeletoid soils and under the influence of salt spray (Šegulja 1969). According to Jasprica et al. (2016), the association is considered to be the most thermophilous grassland along the eastern Adriatic coast. The characteristic species of the association are Asphodelus ramosus, Narcissus tezzeta and Orchis papilionacea. Thermophilous grassland communities with domination of Asphodelus ramosus have a distribution along the eastern Adriatic, influenced by the Mediterranean climate.

There is a different situation along the western Adriatic coast, where Asphodelus ramosus-dominated communities are considered to be heliophilous fringe and tall-herb vegetation, which develops after the abandonment of agro-pastoral activities (Tesei et al. 2020). Comprehensive studies on heliophilous edge vegetation have been performed in Italy (Gargano peninsula, central part of the Apennines, northern part of Sardinia) and southern Spain (Biondi et al. 2016, 2017). As a result, a new class of edge vegetation Charybdido pancratii-Asphodeletea ramosi was described, focused on areas with a Mediterranean macrobioclimate (Biondi et al. 2016,2017).

The proposal to update the EuroVegChecklist (Mucina et al. 2016) by adding this new class was provisionally rejected by the European Vegetation Classification Committee of the European Vegetation Survey working group of the International Association of Vegetation Science, due to the lack of evidence concerning a clear floristic delimitation of Charybdido pancratii-Asphodeletea ramosi from Lygeo sparti-Stipetea tenacissimae and Trifolio-Geranietea sanguinei (Biurrun and Willner 2020). Nonetheless, we can accept the existence of a new fringe class replacing Trifolio-Geranietea in the Mediterranean, but we are of the opinion that Bromo erecti-Chrysopogonetum grylli clearly represents grassland vegetation erroneously classified as fringe vegetation by Biondi et al. (2016). This is clearly indicated by the numerous species of Festuco-Brometea present in stands (Tab. 2) from eastern Adriatic Asphodelus-dominated communities. Fringe communities with Asphodelus ramosus from Italy, due to overgrazing, are dominated by monocotyledons, many of them toxic to animals, while in Montenegro these areas represent pastures. Another difference is the presence of shrub species with higher cover in stands of Charybdido-Asphodeletea ramosi (Paliurus spina-christi, Olea europaea, Pinus halepensis), missing in grasslands from the eastern Adriatic.

According to Biondi et al. (2016) the diagnostic species of the newly described class are Asphodelus ramosus subsp. ramosus, A. fistlosus, A. tenuifolius, A. ayardii, Charybdis pancration, C. maritima, C. glaucophylla, C. aphylla, C. hesperia, Thapsia garganica, Asparagus acutifolius, Ornithogalum etruscum subsp. umbratille, Anemone hortensis, Carlina corymbosa, Hypochoeris radicata, Iris planifolia, I. bicapitata, Asphodeline liburnica, A. lutea, Ferula communis, F. communis subsp. cardonae, F. glauca, F. arrigonii and Hermodactylis tuberosus. The diagnostic species group of Charybdido-Asphodeletea should also be revised, since many of them are attributed to other vegetation classes (Festuco-Brometea, Lygeo sparti-Stipetea tenacissimae, Ononido-Rosmarinetea etc.) according to Mucina et al. (2016). Asphodelus ramosus, Anemone hortensis, Carlina corymbosa and Hypochoeris radicata, which are considered to be character species by Biondi et al. (2016), are also very frequent in grassland vegetation of Bromo erecti-Chrysopogonetum grylli.

In terms of Natura 2000 habitat types (Council Directive 92/43/EEC on the conservation of natural habitats and of wild fauna and flora, 1992) there are differences between grassland and fringe communities dominated by Asphodelus ramosus. Heliophilous Asphodelus spp. edge communities in the western and central Mediterranean do not represent any habitats of European Community interest and a progressive increase in Asphodelus spp. cover in grasslands can result in the disappearance of grassland habitat types (Tesei et al. 2020). According to a report of habitat types of Montenegro important for the European Union (Petrović et al. 2019), Bromo erecti-Chrysopogonetum grylli is classified within the Eastern sub-Mediterranean dry grasslands (Scorzoneretalia villosae) habitat type (code 62A0). The same situation applies to Narcisso tazettae-Asphodeletum microcarpi in Croatia (Jasprica et al. 2016).

Syntaxonomical scheme

Based on the analyses performed, the following syntaxonomical scheme is proposed for Asphodelus ramosus-dominated communities in the Adriatic region.

Festuco-Brometea Br.-Bl. et Tx. ex Soó 1947

Scorzoneretalia villosae Kovačević 1959

Chrysopogono grylli-Koelerion splendentis Horvatić 1973

Bromo erecti-Chrysopogonetum grylli Horvatić 1934

Narcisso tazettae-Asphodeletum microcarpi Šegulja 1969

Artemisietea vulgaris Lohmeyer et al. ex von Rochow

Asphodelus ramosus community

Charybdido pancratii-Asphodeletea ramosi Biondi in Biondi et al. 2016

Asphodeletalia ramosi Biondi in Biondi et al. 2016

Charybdido pancratii-Asphodelion ramosi Biondi et al. 2016

Charybdido pancratii-Asphodeletum ramosi Biondi et al. 2016

Alkanno tinctoriae-Asphodeletum ramosi Biondi et al. 2016

Euphorbio characiae-Thapsietum garganicae Biondi et al. 2017

Asphodelo ramosi-Ferulion communis Biondi et al. 2016

Asphodelo ramosi-Feruletum communis Biondi et al. 2016

Asphodelino luteae-Feruletum communis Biondi et al. 2016

Acknowledgments

We thank editor Massimo Terzi and two anonymous reviewers for their work that substantial improved our manuscript. Martin Cregeen kindly checked our English. The research was partly financed by the Slovenian Research Agency (ARRS) through a research program (P1-0236) and bilateral project with Montenegro (BI-ME/16-17-018).

References

 

Aćić, S.; Šilc, U.; Petrović, M, Tomović, G.; Dajić Stevanović, Z., 2015: Classification, ecology and biodiversity of Central Balkan dry grasslands. Tuexenia 35, 329-353.

 

Allegrezza, M.; Biondi, E.; Ballelli, S.; Tesei, G.; Ottaviani, C., 2015: The edge communities of Asphodelus macrocarpus subsp. macrocarpus: the different ecological aspects and a new case study in the central Apennines. Plant Sociology 52, 19-40.

 

Apostolova, I.; Dengler, J.; Di Pietro, R.; Gavilán, R.G.; Tsiripidis, I., 2014: Dry grasslands of Southern Europe: syntaxonomy, management and conservation. Hacquetia 1, 5-18.https://doi.org/10.2478/hacq-2014-0015

 

Biondi, E.; Blasi, C.; Allegrezza, M.; Anzellotti, I.; Azzella, M.; Carli, E.et al., 2014: Plant communities of Italy: The Vegetation Prodrome. Plant Biosystems 48, 728-814.

 

Biondi, E.; Pesaresi, S.; Gaspari, R.; Biscotti, N.; del Viscio, G.; Bonsanto, D.et al., 2017: New contribution to the class Charybdido pancratii-Asphodeletea ramosi Biondi 2016. Plant Sociology 54, 137-144.https://doi.org/10.1080/11263504.2014.948527

 

Biondi, E.; Pesaresi, S.; Gaspari, R.; Biscotti, N.; del Viscio, G.; Bonsanto, D.et al., 2016: Post-abandonment dynamic on Mediterranean and sub-Mediterranean perenial grasslands: the edge vegetation of the new class Charybdido pancratii-Asphodeletea ramosi. Plant Sociology 53, 3-18.

 

Biurrun, L.; Willner, W., 2020: First Report of the European Vegetation Classification Committee. Vegetation Classification and Survey 1, 145-147.https://doi.org/10.3897/VCS/2020/60352

 

Blečić, V.; Lakušić, R., 1976: List of plant communities of Montenegro. Glasnik Republičkog Zavoda za Zaštitu Prirode i Prirodnjačkog Muzeja u Titogradu 9, 57-98.

 

Bohn, U.; Neuhäusl, R.; unter Mitarbeit von Gollub, G.; Hettwer, C.; Neuhäuslová, Z.; Schlüter, H. et al., 2000-2003: Karte dernatürlichen Vegetation Europas, Maßstab 1:2.500.000. Landwirtschaftsverlag, Münster.

 

Braun-Blanquet, J., 1964: Pflanzensoziologie. Grundzüge der Vegetationskunde.. Springer Verlag, Wien.

 

Burić, D.; Micev, S., 2008: Köppen climate classification in Mon- tenegro shown in Walter climate diagram. Hidrometeorološki zavod Crne Gore, Podgorica (in Montenegrin)

 

Burić, M.; Fuštić, B.; Bulajić, P, 2017: Land atlas of Montenegro. Crnogorska Akademija Nauka i Umjetnosti 3, 7-153.

 

Černjavski, P, Grebenščikov O.; Pavlović, Z, 1949: On vegetation and flora of the Skadar lake area. Glasnik Prirodnjačkog Muzeja Srpske zemlje, Beograd 1/2, 5-9 (in Montenegrin).

 

Council Directive 92/43/EEC on the Conservation of natural habitats and of wild fauna and flora, 1992.

 

Diaz-Lifante, Z.; Valdés, B., 1996: Revisión del género Asphodelus (Asphodelaceae) en el Mediterraneo occidental. Boissiera 52, 11-189.

 

Euro+Med, 2006: Euro+Med PlantBase – the information resource for Euro-Mediterranean plant diversity. Retrieved July 22, 2019 from http://ww2.bgbm.org/EuroPlusMed/

 

Fanelli, G.; De Sanctis, M.; Mullaj, A.; Attore, F., 2015: The vegetation of the Buna river protected landscape (Albania). Hacquetia 14, 129-174.https://doi.org/10.1515/hacq-2015-0008

 

Griffiths, H.I.; Kryštofek, B.; Reed, J.M. (eds.), 2004: Balkan biodiversity – pattern and process in the European hotspot. Kluwer Academic Publishers, Dordrecht

 

Hadžiablahović, S., 2010: The vascular flora of Ćemovsko polje. Natura Montenegrina 9, 7-143 (in Montenegrin).

 

Hadžiablahović, S., 2018: The diversity of the flora and vegetation of Lake Skadar/Shkodra. The Handbook of Environmental Chemistry, 203-238. Springer, Cham 80, Switzerland.

 

Hećimović, S., 1984: Vegetation der Inseln Bobara und Mrkan. Acta Botanica Croatica 43, 109-118.

 

Hennekens, S.; Schaminée, J., 2001: TURBOVEG, a comprehensive data base management system for vegetation data. Journal of Vegetation Science 12, 598-591.

 

Horvat, I.; Glavač, V, Ellenberg, H., 1974: Vegetation Sudosteuropas. Geobotanica selecta, Band 4. Gustav Fischer Verlag. Stuttgart.

 

Horvatić, S., 1934: Flora and vegetation of island Pag. Prirodoslovna istraživanja 19, 116-372 (in Croatian).

 

Horvatić, S., 1939: An overview of the vegetation of the island of Rab from aspect of plant sociology. rirodoslovna Istraživanja Jugoslavenske Akademije 22, 1-96 (in Croatian).

 

Horvatić, S., 1963: Vegetation map of the island of Pag, with a review of the vegetation units of the coast of Croatia. Acta Biologica (Zagreb) 4, 3-187 (in Croatian).

 

Janssen, J.A.M.; Rodwell, J.S.; García Criado, M.; Gubbay, S.; Haynes, T.; Nieto, A.et al., 2016: European Red List of Habitats. Part 2. Terrestrial and fresh-water habitats. European Commission, Brussels, 1-40.

 

Jasprica, N.; Milović, M.; Kovačić, S.; Stanković, V., 2016: Phytocoenotic diversity of the NE-Adriatic island of Olib. Plant Sociology 53, 55-81.

 

Jasprica, N.; Ruščić, M., 2013: Flora and vegetation of islet Supetar (Cavtat, South Croatia). Hrvatska misao 46, 111-134 (in Croatian).

 

Jovanović, B.; Lakušić, R.; Rizovski, R.; Trinajstić, I.; Zupančič, M., 1986: Prodromus Phytocoenosum Jugoslaviae: ad mappam vegetationis m 1:200 000. Naučno vijeće vegetacijske karte Jugoslavije, Bribir-Ilok, HR (in Croatian)

 

Kruskal, J.B., 1964: Multidimensional scaling by optimizing goodness of fit to a nonmetric hypothesis. Psychometrika 29, 1-27.https://doi.org/10.1007/BF02289565

 

Matevski, V.; Čarni, A.; Ćušterevska, R.; Kostadinovski, M.; Mucina, L., 2018: Syntaxonomy and biogeography of dry grasslands on calcareous substrates in the central and southern Balkans. Applied Vegetation Science 21, 488-513.https://doi.org/10.1111/avsc.12374

 

Mucina, L.; Bültman, H.; Dierssen, K.; Theurillat, J.-P.; Dengler, J. et al., 2016: Vegetation of Europe: Hierarchical floristic classification system of plant, lichen, and algal communities. Applied Vegetation Science 19, 3-264.https://doi.org/10.1111/avsc.12257

 

Oksanen, J.; Blanchet, F.G.; Kindt, R.; Legendre, P.; Minchin, P.R.; O’Hara, R.B. et al., 2017: Vegan: community ecology package. R Foundation for Statistical Computing, Vienna. Retrieved from http://CRAN.R-project.org/package=vegan

 

Petrović, D.; Hadžiablahović, S.; Vuksanović, S.; Mačić, V.; Milanović, Đ.; Lakušić, D., 2019: Catalogue of habitat types of Monenegro important for European Union. egional Environmental Center Montenegro, Podgorica-Banja Luka-Beograd (in Montenegrin)

 

Pignatti, S.; Menegoni, P.; Pietrosanti, S., 2005: Biondicazione attraverso le piante vascolari. Valori di indi-cazione secondo Ellenberg (Zeigerwerte) per le specie della Flora d’Italia. Braun-Blanquetia 39, 1-97.

 

Pulević, V.; Bulić, Z., 2012: Bibliography on Flora and Vegetation of Montenegro (the third addition). Republički zavod za zaštitu prirode. Special edition. Podgorica. 1-150 (in Montenegrin).

 

Radojičić, B., 2015: Montenegro – Geographical encyclopedic lexicon. Faculty of Philosophy, University of Nikšić (in Montenegrin)

 

Šegulja, N., 1969: A contribution to the knowledge of rocky vegetation in Istria. Acta Botanica Croatica 28, 367-371 (in Croatian).

 

Šegulja, N., 1970: Vegetation of the northeastern part of the Labinština in Istria. Acta Botanica Croatica 29, 157-172.

 

Stešević, D.; Caković, D.; Jovanović, S., 2014: The urban flora of Podgorica (Montenegro, SE Europe): Annotated checklist, distribution atlas, habitats and life-forms, taxonomic, phytogeographical and ecological analysis. Ecologica Montenegrina 4-167 (in Montenegrin).

 

Terzi, M., 2011: Nomenclatural revision for the order Scorzonero-Chrysopogonetalia. Folia Geobotanica 46, 411-444.https://doi.org/10.1007/s12224-011-9100-2

 

Terzi, M., 2015: Numerical analysis of the order Scorzoneretaliavillosae. Phytocoenologia 45, 11-32.https://doi.org/10.1127/phyto/2015/00097

 

Tesei, G.; D’Ottavio, P.; Toderi, M.; Ottaviani, C.; Pesaresi, S.; Francioni, M. et al., 2020: Restoration strategies for grasslands colonized by Asphodel‐dominant communities. Grassland Science 66, 54-63.https://doi.org/10.1111/grs.12252

 

Theurillat, J-P.; Willner, W.; Fernández‐González, F.; Bültmann, H.; Čarni, A.; Gigante, D., 2021: International Code of Phytosociological Nomenclature. 4th edition. Applied Vegetation Science 24, e12491.

 

Tichý, L., 2002: JUICE, software for vegetation classification. Journal of Vegetation Science 13, 451-453.https://doi.org/10.1111/j.1654-1103.2002.tb02069.x

 

Valkó, O.; Venn, S.; Zmihorski, M.; Biurrun, I.; Labadessa, R.; Loos, J., 2018: The challenge of abandonment for the sustainable management of Palaearctic natural and semi-natural grasslands. Hacquetia 17, 5-16.https://doi.org/10.1515/hacq-2017-0018

Appendix

Appendix 1: Species present in only 1 or 2 relevés from Ćemovsko polje in Table

Asparagus acutifolius 17: +; Catapodium rigidum 6: +; Geranium molle 2: +; Trifolium angustifolium 3: +; Romulea bulbocodium 2: +; Sonchus asper 10: +; Pyrus amygdaliformis 3: 1; Carthamus lanatus 6: +; Salvia verbenaca 16: +; Teucrium chamaedrys 17: +; Geranium purpureum 7: +; Alyssum minus 10: 1; Ajuga chamaepitys 12: +, 16: +; Vicia angustifolia 9: +; Crepis foetida 2: +, 6: +; Tragopogon porrifolius 9: +, 11: 1; Bellis perennis 4: +; Parentucellia latifolia 14: +, 15: +; Aphanes arvensis 8: +, 17: +; Valerianella rimosa 6: +, 8: +; Knautia integrifolia 9: +, 10: +; Stipa pulcherrima 3: +, 4: 1; Cardamine hirsuta 4: +, 17: +; Linum bienne 5: +, 7: +; Trifolium cherleri 3: +, 5: +; Bromus madritensis 7: +, 16: +; Trifolium resupinatum 5: +; Vulpia myuros 10: +; Trigonella gladiata 1: +; Veronica arvensis 17: +; Reseda phyteuma 9: +; Bromus sterilis 11: +; Calepina irregularis 6: +; Bromus hordeaceus 3: +; Orchis ustulata 11: +; Orlaya grandiflora 9: +; Medicago rigidula 5: +; Poa annua 10: +; Hyacinthella dalmatica 5: +; Matthiola incana 15: 1; Lactuca viminea 3: +; Aegilops neglecta 11: +; Alyssum alyssoides 7: +; Alyssum campestre 11: 1; Astragalus illyricus 11: 2, 14: +; Matricaria chamomilla 13: +, 14: +; Onosma echioides 9: 1, 12: +.

Appendix 2: Relevé dates (year/month/day) and coordinates (WGS84 reference system, in decimal degrees).

1. 2019/04/07, 42.3968090, 19.3021110; 2. 2019/04/07, 42.3964610, 19.3030050; 3. 2019/04/07, 42.3960000, 19.3040000; 4. 2019/04/07, 42.3978055, 19.3048888; 5. 2019/04/07, 42.3985277, 19.3019638; 6. 2019/04/07, 42.4001488, 19.3031944; 7. 2019/04/07, 42.4006410, 19.3023280; 8. 2019/04/07, 42.4021890, 19.3049660; 9. 2019/04/07, 42.3880040, 19.2856690; 10. 2019/04/07, 42.3803160, 19.2743840; 11. 2019/04/09, 42.3708888, 19.2303056; 12. 2019/04/09, 42.3728888, 19.2316944; 13. 2019/04/09, 42.3697222, 19.2339166; 14. 2019/04/09, 42.3705580, 19.2360490; 15. 2019/04/09, 42.3709350, 19.2383990; 16. 2019/04/10, 42.4021370, 19.3210555; 17. 2019/04/10, 42.3885277, 19.3110277.

Appendix 3: Relevés from literature sources (name of the plant community, authors, table and number of relevés from original source paper).

1. Bromo-Chrysopogonetum grylli subass. asphodeletosum microcarpi (Horvatić 1934), Tab. 23, rels. 11-16, 18-23; 2. Narcisso tazettae-Asphodeletum microcarpi (Šegulja 1970), Tab. 2, rels. 1–8; 3. Narcisso tazettae-Asphodeletum microcarpi subass. sisymbrietosum officinalis (Hećimović 1984), Tab. 5, rels. 1–10; 4. Narcisso tazettae-Asphodeletum microcarpi (Jasprica and Ruščić 2013), rel. on the page 128; 5. Asphodelus ramosus community (Fanelli et al. 2015), Tab. 41, rels. 15, 70, 492; 6. Asphodelo-Chrysopogonetum grylli (Fanelli et al. 2015), Tab. 25, rels. 31–33; 7. Narcisso tazettae-Asphodeletum microcarpi (Jasprica et al. 2016), Tab. 11, rels. 1–3; 8. Charybdido pancratii-Asphodeletum ramosi (Biondi et al. 2016, Tab. 1, rels. 1–14; 9. Alkanno tinctoriae-Asphodeletum ramosi (Biondi et al. 2016), Tab. 2, rels. 1–3; 10. Asphodelo ramosi-Feruletum communis (Biondi et al. 2016), Tab. 3, rels. 1–2; 11. Asphodelino luteae-Feruletum communis (Biondi et al. 2016), Tab. 4, rels. 1–7; 12. Euphorbio characiae-Thapsietum garganicae (Biondi et al. 2017), Tab. 6, rels. 1–5.


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