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The vascular flora of Sardinia has been investigated for more than 250 years, with particular attention to the endemic component due to their phylogeographic and conservation interest. However, continuous changes in the floristic composition through natural processes, anthropogenic drivers or modified taxonomical attributions require constant updating. We checked all available literature, web sources, field, and unpublished data from the authors and acknowledged external experts to compile an updated checklist of vascular plants endemic to Sardinia. Life and chorological forms as well as the conservation status of the updated taxa list were reported. Sardinia hosts 341 taxa (15% of the total native flora) endemic to the Tyrrhenian Islands and other limited continental territories; 195 of these (8% of the total native flora) are exclusive to Sardinia. Asteraceae (50 taxa) and Plumbaginaceae (42 taxa) are the most representative families, while the most frequent life forms are hemicryptophytes (118 taxa) and chamaephytes (106 taxa). The global conservation status, available for 201 taxa, indicates that most endemics are under the ‘Critically Endangered’ (25 taxa), ‘Endangered’ (31 taxa), or ‘Least Concern’ (90 taxa) IUCN categories. This research provides an updated basis for future biosystematics, taxonomic, biogeographical, and ecological studies and in supporting more integrated and efficient policy tools.

Despite the increasing interest in elevational patterns in biodiversity, few studies have investigated variations in life forms and biogeographical composition, especially in the Mediterranean biome. We investigated elevational patterns in species richness, biogeographical composition (chorotypes) and life forms (Raunkiaer classification) along an elevational gradient in a Mediterranean mountain (Central Italy). We found a general hump-shaped pattern of species richness, which can be explained by harsher conditions at the lowest and highest elevations. This pattern is distinctly related to prevalence at mid elevations of species with European and Euro-Asiatic distribution, which are favored by a temperate climate. Phanerophytes and geophytes (which are mainly associated with woods) were concentrated at mid elevations where woodlands prevail. Hemicryptophytes increased with elevation, consistently with their ability to cope with high altitude climatic conditions. Mediterranean species declined with elevation because they are negatively affected by decreasing temperatures. Chamaephytes showed a U-shaped pattern, suggesting they are able to cope with arid and cold conditions at the extremes of the gradient. Endemics increased with elevation because of their association with mountainous areas as key places for endemism evolution. These results illustrate how elevational patterns in species richness, biogeographical composition and life forms are interrelated and demonstrate reciprocal insights for understanding current vegetation settings.

The abandonment of agricultural lands triggers a secondary succession of plant species which implies important changes in soil quality. Annual Mediterranean grasslands are known to be persistent on abandoned agriculture lands in the western Mediterranean. We used plant taxonomic and functional approaches to determine the role of Mediterranean grasslands as an indicator of changes in ecosystem biodiversity and functionality. We tested the hypothesis that Mediterranean grasslands are a suitable model for monitoring biodiversity and soil fertility in a secondary succession. Soil and vegetation features on 21 permanent plots were monitored in 2016 and 2020. Numerical classifications based on floristic composition showed two different plant communities independently of the sampling year: early-stage grasslands in the first post-abandonment decade and late-stage grasslands after the first post-abandonment decade. Generalized linear model and redundancy analysis also revealed differences in growth forms, functional traits and soil functionality between communities. Late-stage grasslands was characterized by enriched bryophyte coverage and an impoverishment in hemicryptophytes and plant latex segregators growing on soils with a higher hydrolase enzyme activity and TOC content compared to early-stage grassland. Our results suggest that annual Mediterranean grasslands growing on siliceous soils denoting a mature-stage succession, and floristically characterized by the symbiont plant with Ascomycota, Tuberaria guttata, and a high bryophyte cover, are worthy of recognition for conservation.

PurposeHerbaceous plants are important components of temperate forest structure and its functioning, however, their impacts on arbuscular mycorrhizal fungi (AMF) remain largely unexplored. We studied the influence of forest herbaceous plant species on AMF abundance, morphospecies richness, and community composition in soil.MethodsWe tested the influence of plant species identity in an outdoor mesocosm experiment, using two soils, differing in physicochemical properties, planted with four plant species of contrasting traits related to morphology, phenology, reproduction, and ecology; the hemicryptophyte, summer-green Aegopodium podagraria, and spring ephemeral geophytes comprising Allium ursinum, Anemone nemorosa, and Ficaria verna. The plants were grown on both soils in four monocultures, in a combination of A. podagraria and A. ursinum, and a mixture of all four species.ResultsAegopodium podagraria and A. ursinum promoted AMF abundance and diversity the most. Higher AMF root colonization and/or soil concentrations of AMF structural and storage markers 16:1ω5 PLFA and NLFA, as well as higher AMF spore and morphospecies numbers were found in the A. podagraria and A. ursinum monocultures and mixture. The short period of photosynthetic activity of A. ursinum due to rapid leaf decay does not negatively affect the symbiosis with AMF. Although A. nemorosa and F. verna are mycorrhizal, their effect on AMF in soil was weak.ConclusionsThe plant impact on AMF may be related to the differences in plant coverage and the character of their interactions with AMF. The herbaceous plants can form niches in soil differing in AMF abundance and diversity.

Human activities and climate change accelerate habitat loss and fragmentation, threatening medicinal plants and rare species that play important roles in maintaining ecosystem balance. However, the lack of comprehensive and reliable data on their spatial distribution has restricted effective conservation management efforts. This study provides a comprehensive ecological assessment of the endangered high-altitude medicinal plant Aconitum heterophyllum , examining its ecological interactions, environmental drivers, and projected distribution under climate change in Azad Jammu and Kashmir, Pakistan. A total of 129 plant taxa comprising 46 families were recorded from all sampling plots with Asteraceae, Ranunculaceae, and Polygonaceae being dominant. The most common life form was herb (88.37%), hemicryptophytes (57.36%) and microphylls (55.81%), which is an indication of the ecological niche of cold and alpine conditions. Hierarchical clustering and indicator species analysis grouped the sites in three specific plant communities, namely, Abies pindrow–Viburnum grandiflorum–Achillea millefolium (AVA), Swertia petiolataIris–Iris kashmiriana–Potentilla nepalensis (SIP), and Pedicularis pectinate–Juncus himalensis–Parnassia nubicola (PJP). SIP plots located at mid-altitudes (2900–3100 m) showed the highest abundance of A. heterophyllum , whereas AVA (lower altitudes) and PJP (higher altitudes) exhibited moderate to low abundance. Non-metric Multidimensional Scaling (NMDS) and beta-diversity analyses confirmed significant floristic turnover among associations, with the PJP group displaying greater internal heterogeneity. Canonical Correspondence Analysis (CCA) identified altitude as the most influential variable (pseudo-F = 9.0, p  = 0.002), strongly shaping the composition of associated plant communities. A generalized linear model (GLM) demonstrated a significant negative relationship between A. heterophyllum abundance and altitude ( p  = 0.0089), confirming a mid-altitude ecological optimum. Species distribution modeling using MaxEnt (AUC = 0.996) identified summer temperature (bio5) and precipitation (bio18) as the dominant climatic constraints. Currently suitable habitats are narrowly distributed above 2700 m. Future projections suggest limited upslope shifts under SSP-245, whereas SSP-585 indicates substantial altitudinal and latitudinal expansion. However, increased fragmentation and thermal stress may threaten population stability. These findings highlights the species’ ecological specialization and vulnerability to climate change, emphasizing the need for integrated conservation strategies combining current ecological baselines, topographic mapping, and forward-looking climatic risk assessment.

Mobility is highly species-specific and individual species mobility can be predicted by species traits, yet this topic remains largely understudied. We analyzed data on species presences/absences in permanent subplots (1m × 1m) within 15 main plots 10m × 10m) over 24 years originating from a grassland biodiversity experiment in Czechia. Plots differed in initial species richness and composition. We estimated mean individual species persistence and searched for any relationship with individual species traits. We also tested the effect of sowing richness/composition on species persistence and community mobility. Our results show that individual species have very different mobilities which vary in time and can be predicted by species traits, most importantly by leaf traits, clonal traits, and traits characterizing species life forms. Trait syndrome corresponding to the traveler part of the mobility gradient typically includes annuals having a taproot, long-lasting seedbank, and high SLA. Trait syndrome of sitters includes perennial hemicryptophytes with effective clonal reproduction and transient seedbank. Importantly, trait association with species mobility is spatial scale dependent, whereas studies on the spatial scale of 0.01m2 show that clonality increases mobility, in our case clonality increases the persistence of species in 1m2 units. In contrast with an evident linkage between mobility and traits, the effect of community richness/composition on species/community mobility was weak and detectable in the very first years of the experiment only.

Premise Despite intensive research, the pathways and driving forces behind the evolution of derived woodiness on oceanic islands remain obscure. The genus Daucus comprises mostly herbs (therophytes, hemicryptophytes) with few rosette treelets (chamaephytes) endemic to various Macaronesian archipelagos, suggesting their independent evolution. To elucidate the evolutionary pathways to derived woodiness, we examined phylogenetic relationships and the habit and secondary xylem evolution in Daucus and related taxa. Methods Sixty taxa were surveyed for molecular markers, life history, and habit traits. Twenty‐one species were considered for wood anatomical characters. A dated phylogeny was estimated using Bayesian methods. The evolution of selected traits was reconstructed using parsimony and maximum likelihood. Results Daucus dispersed independently to the Canary Islands (and subsequently to Madeira), Cape Verde, and the Azores in the late Miocene and Pleistocene. Life span, reproductive strategy, and life form were highly homoplastic; the ancestor of Daucus was probably a monocarpic, biennial hemicryptophyte. Rosette treelets evolved independently in the Canarian‐Madeiran lineage and in Cape Verde, the latter within the last 0.13 Myr. Treelets and hemicryptophytes did not differ in wood anatomy. Pervasive axial parenchyma in wood occurred more often in polycarpic rather than monocarpic species. Conclusions Life span and life form in Daucus are evolutionarily labile and may change independently of wood anatomy, which is related to plant reproductive strategy rather than to life form. Insular woodiness may evolve rapidly (as demonstrated in D. bischoffii), and in Daucus, it does not seem to be an adaptation to lower the risk of xylem embolism.

In order to evaluate the diversity, endemism, distribution and conservation of the genus Euphorbia in SW Asian countries, we generated an updated and annotated checklist of 249 taxa belonging to the current accepted four Euphorbia subgenera, 30 sections and five subsections, based on floristic compilations followed by extensive verification of nearly 24,000 herbarium vouchers from the region. We also provide updated distribution maps for 247 of the 249 taxa treated. The predominant group is Euphorbia subg. Esula , with 19 sections and 184 taxa (176 species), followed by subg. Chamaesyce (six sections, 32 species), subg. Euphorbia (two sections, 21 species) and subg. Athymalus (three sections, 12 species). Turkey, Iran and Syria are the most diverse countries, with 102, 92 and 50 species, respectively. The richest concentration of Euphorbia species in SW Asia are the eastern part of the Mediterranean region in Lebanon with 27–34 taxa; Alborz, Zagros (Iran), Lesser Caucasus, and Anti-Taurus (S Turkey) with 21–27 taxa each are the second richest areas. The highest number of endemics occurs in Iran (21 taxa), followed by Turkey (12 taxa) and Yemen (7 taxa). All 134 endemic and subendemic taxa were evaluated by the IUCN Red List categories and criteria. Among the known Euphorbia species in the region, 10 of them (4.4%) are adventive. Life-form spectra show that the majority of species (80.7%) are hemicryptophytes, therophytes and chamaephytes. Twelve new records are reported here for Iran, Afghanistan, Oman, Pakistan, Qatar and Turkey, six synonyms and three sectional transfers are suggested.

Human-assisted introduction of alien plants is causing ecosystem transformations worldwide and is considered an important threat to biodiversity. We provide a European assessment of habitat levels of invasion in heathlands and scrub and identify successful alien plants and invasion trends across biogeographical regions. We analysed a geographically stratified data set of 24,220 dwarf shrub and scrub vegetation plots sampled across Europe. Among the 6547 vascular plant taxa occurring in these plots, we identified 311 neophytes (4.8%, i.e. alien species introduced in Europe or its sub-regions after 1500 AD) and compared five metrics of the level of invasion in (i) EUNIS habitats, (ii) broad habitat groups and (iii) biogeographical regions of Europe. We related habitat-specific levels of invasion to elevation and climatic variables using generalized linear models. Among neophytes, phanerophytes of non-European origin prevailed. The most frequent neophytes in the plots were Prunus serotina, Robinia pseudoacacia and Quercus rubra among phanerophytes, Impatiens parviflora among therophytes, and Erigeron canadensis and Solidago gigantea among hemicryptophytes. Levels of invasion significantly differed among habitats and biogeographical regions. The most invaded habitat was Macaronesian lowland scrub, followed by riparian scrub, Rubus scrub and forest-clearing scrub of temperate Europe, and coastal dune scrub of the Atlantic region. The levels of invasion were low in the shrublands of the Arctic and Mediterranean regions and decreased with elevation within habitats. Results suggest that insularity, low elevation, frequent disturbances, and high availability or considerable fluctuation of resources promote neophyte invasions in European shrublands.

Egypt is characterized by its hyper-arid desert environment with high temperature, scanty rainfall, high evapotranspiration rate, and patchy scattered precipitation-dependent vegetation. Located in this peculiar ecosystem, the northeastern part of the eastern desert occupies vast areas where this study was conducted. Despite some protection in this area, destruction of plant cover, soil erosion, and degradation of natural habitat are still occurring. Among the complex array of anthropogenic disturbances that directly affect species diversity, over-grazing, road construction, over-collection of plants, salinization, over-cutting, military activities, urbanization, and industrialization were encountered. The aim of this study was to assess the effect on long-lasting anthropopressure on the current floristic and ecological status of the unprotected area in comparison to the protected one. Two areas were chosen for detailed studies: protected (Wadi Degla; WD) and unprotected (Cairo-Suez road, SR). Fourteen soil variables were used to assess the soil–vegetation relationships in the two areas. An assessment of seven human activities (over-grazing, over-collection, introduced species, land degradation, urbanization, solid wastes, and military activities) was carried out at four levels of disturbance intensities. A floristic presence/absence data set of 25 plots × 56 species, including 14 plots for SR and 11 plots for WD, was employed in the analyses. The application of multivariate analysis techniques such as cluster analysis (for classification), indicator species analysis (ISA) and the multi-response permutation procedure (MRPP), canonical correspondence analysis (CCA), and redundancy analysis (RDA) for ordination were performed in the data analysis. Generally, a total of 85 plant species belonging to 68 genera and 30 families was recorded. Asteraceae, Chenopodiaceae, Fabaceae, Zygophyllaceae, Poaceae, Brassicaceae, and Geraniaceae were the largest families, constituting more than 50% of the total flora. Chamaephytes, therophytes, hemicryptophytes, and phanerophytes prevail in the life form spectrum. Chorological analysis showed that the Saharo-Arabian element, whether pure or combined with other chorotypes, dominated the current flora, whereas the Mediterranean chorotype was very poorly represented. Application of cluster analysis yielded eight vegetation groups: I–IV for the Cairo-Suez road, and V–VIII for Wadi Degla. This study indicated the disappearance of several plant communities that were previously of common occurrence such as Retama raetam, Anabasis articulata, Ephedra alata, Artemisia monosperma, Zygophyllum decumbens, Lasiurus hirsutus, and Panicum turgidum. Partial CCA (pCCA) for the unprotected area revealed that most of the variance (45.7%) was attributed to the anthropogenic variables more than soil factors (14.5%). Like what was revealed in other unprotected areas, a clear relationship between anthropogenic pressure and habitat fragmentation was observed. Long-term, intensive human activities caused vegetation degradation, species loss, and a decline in plant richness. Hence, the highest species richness value was recorded in the protected area. Over-grazing, land degradation, and military activities were not correlated with the diversity indices, whereas over-collection of plant species, urbanization, and solid wastes were significantly negatively correlated with both α-diversity and the Shannon–Wiener index. Suitable protection measures should be taken to reduce the anthropogenic pressures in this ecosystem as well as some conservation programs and management plans should be implemented to save biodiversity.