Your search keyword '"Kallimanis, Athanasios S."' showing total 3 results

1. How Does Habitat Diversity Affect the Species-Area Relationship?

Author

Kallimanis, Athanasios S., Mazaris, Antonis D., Tzanopoulos, Joseph, Halley, John M., Pantis, John D., Sgardelis, Stefanos P., and McGill, Brian

Published

2008

2. Can we predict the number of plant species from the richness of a few common genera, families or orders?

Author

Mazaris, Antonios D., Kallimanis, Athanasios S., Tzanopoulos, Joseph, Sgardelis, Stefanos P., and Pantis, John D.

Subjects

*BIODIVERSITY, *PLANT diversity, *PLANT species, *PLANT species diversity, *PLANT classification, *TAXONOMISTS, *PLANT taxonomists, *BIOLOGICAL classification

Abstract

1. Halting biodiversity loss, a major environmental challenge, relies on the understanding of species richness patterns. The assessment of species richness is often hampered by limited taxonomic knowledge and the general dearth of trained systematists. Research has shown that we can predict the number of species in a community by the number of higher order taxonomic units present. Here, we test whether we need to know all the genera, families or orders in order to do so. Further, the number of common species in a region is a good predictor of total richness and we test if this predictability translates to using higher taxa. 2. We used data from 240 sites from the Natura 2000 network of protected areas in Greece, including 5148 plant species and subspecies, which are grouped in 1113 genera 174 families and 56 orders. We correlated species richness with the number of common genera, families or orders present. The analysis was repeated using the number of the most speciose higher orders instead of the most common. 3. We found that we do not need to know all higher order taxa present, in order to predict species richness. If we know how many out of the 30 most common orders are present, we can reliably predict the number of species. Similar results were obtained if we know how many of the 60 most common families or 200 most common genera are present. 4. Equally good results were obtained using the same numbers of the most speciose higher orders. 5. Synthesis and applications. Our analysis demonstrates that species richness can be predicted from the number of common or more speciose genera, families and orders present. These predictions hold without complete sampling of these higher taxa. The implication is that we need only limited systematic knowledge, resources and effort in order to predict species richness. Assuming these findings hold in other taxonomic groups and in other regions, we argue that the uncertainty introduced by limited knowledge of the systematics ... [ABSTRACT FROM AUTHOR]

Published

2010

3. Plant trait filtering is stronger in the herb layer than in the tree layer in Greek mountain forests.

Author

Mastrogianni, Anna, Chytrý, Milan, Kallimanis, Athanasios S., and Tsiripidis, Ioannis

Subjects

*MOUNTAIN forests, *CONIFEROUS forests, *COMMUNITY forests, *DECIDUOUS plants, *MULTIDIMENSIONAL scaling, *VASCULAR plants

Abstract

• Empirical test of functional differentiation of forests at a regional scale. • Functional identity but not diversity differentiates forest community types. • Decoupled functional diversity and identity patterns highlight their complementarity. We studied the differentiation among plant communities of deciduous broadleaved and mountain coniferous forests in terms of functional diversity and identity at a regional scale (northern and central Greece). We asked if patterns of functional differentiation among communities are consistent between the overstorey and understorey layers and if they can be influenced by deep past environmental conditions. Functional Richness (FRic) and Functional Dispersion (FDis), as well as their standardized effect sizes, were employed to assess the multivariate functional diversity of the community types. In contrast, single-trait Community Weighted Means (CWMs) were used as surrogates of functional identity. The aforementioned indices were calculated for three datasets, namely all the vascular plant taxa found in individual vegetation plots (total community), all phanerophyte (tree and shrub) taxa (overstorey) and all non-phanerophyte vascular plant taxa (understorey). We found that community types and especially four broad forest types (beech, ravine, pine and oak forests) are well differentiated in terms of functional composition (identity), as indicated by Non-Metric Multidimensional Scaling (NMDS). After conducting an NMDS for the three datasets, functional identity based on the total floristic composition was found to be the best discriminator of the studied communities. However, contrasting patterns were found for some specific traits or their categories between overstorey and understorey layers. The patterns of functional diversity of the community types (based on multivariate indices), revealed by calculating the standardized effect sizes of FRic and FDis based on the richness null model, did not differ substantially from random expectations for most of the studied community types when the dataset of all the vascular plant taxa was analyzed. However, the patterns revealed for the overstorey layer differed from those for the understorey layer. For the latter layer, the clustered structure was revealed in many community types based on the ses.FDis metric. Indications of deep past influence on the functional composition were found for certain community types (i.e. ravine forests) based on single-trait metrics, but no indication of such influence was found based on multivariate indices. Our findings highlight the complementarity and the additive explanatory value of the simultaneous use of single- and multi-trait approaches and their application to different layers in forests. [ABSTRACT FROM AUTHOR]

Published

2021