Evolutionary inferences about the genus Abax (Coleoptera, Carabidae: Pterostichini) based on molecular data and geographic distribution of taxa.

A molecular analysis of the genus Abax (Pterostichidae) has been carried out based on the sequencing of a mitochondrial cox gene fragment and the nuclear its-2 or 28S genes. The three subgenera which are included within Abax on morphological grounds, namely Abacopercus, Abax s. str. and Pterostichoabax were partially supported. Abacopercus is a monotypic subgenus including A. schueppeli and is sister to the other species of the genus. Pterostichoabax is sister to a clade made up by species of the ‘parallelus’ group (parallelus, carinatus, baenningeri, pilleri, oblongus, and continuus), which are currently members of the subgenus Abax. The other species of this subgenus (parallelepipedus, fiorii, ovalis and pyrenaeus) make up a separate clade, what renders the subgenus Abax as polyphyletic. The geographic framework of these results suggests that the ancestors of Abax appeared in the Carpathian area, where they gave rise to A. schueppeli. Successive cladogenetic events and expansion from the Carpathians to the Alps and the Pyrenees may have originated two main lineages, Abax sensu stricto and Pterostichoabax plus the ‘parallelus’ group. All these lineages have originated a number of species in temperate forests mostly concentrated in the southern axis of Eastern and Central Alps, but all the Pterostichoabax species and two taxa of the parallelus group shifted its habitat into the alpine grass mats above the treeline during one or more ice age times

Hypogean carabid beetles as indicators of global warming?

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Exploring cross-taxon congruence between carabid beetles (Coleoptera: Carabidae) and vascular plants in sites invaded by Ailanthus altissima versus non-invaded sites: the explicative power of biotic and abiotic factors

Ailanthus altissima is one of the most global widespread invasive alien species and its effect as habitat transformer requires detailed investigations. In particular, its invasion in natural ecosystems and its effect on local fauna should be evaluated and described. With this purpose, the identification of surrogate taxa would be an important tool in order to define the impact of this invader on different habitats. Here, we evaluated cross-taxon congruence to quantify the strength of plant species composition in predicting multivariate patterns in carabid beetle assemblages, based on data from 20 sites divided in invaded and non-invaded habitats located in the Karst area, North-east Italy. We considered the habitat type (representing vegetation stages from grassland to forests) in order to evaluate the impact of A. altissima on carabid beetles along the vegetation succession. We found 28 carabid beetles and 173 plant species. Our analyses showed that plant species composition had a valuable predictive accuracy, based on the interplay among environmental variables, soil parameters and vegetation structure. Native vegetation and habitat type were the most important factors influencing carabid beetles and plant species composition. Furthermore, 33% of the total explained variation of carabid beetles assemblages (variance partition based on RDA analysis) was due to the independent effect of environment. We proved cross-taxon congruence between carabid beetles and plants along the successional gradient of vegetation (habitat type). In particular, we attested that both communities present more species differentiation among non-invaded vegetation and, in the meantime, in plots were A. altissima was present, anthropic and disturbed plants and carabid beetles species were prevalent. As a conclusion, plants can be effectively used as a surrogate taxon in the evaluation of the effect of A. altissima invasion in the Karst area