Repeated evolution of similar phenotypes is a widespread phenomenon found throughout the living world and it can proceed through the same or different genetic mechanisms. Cave animals with their convergent traits such as eye and pigment loss, as well as elongated appendages, are a striking example of the evolution of similar phenotypes. Yet, few cave species are amenable to genetic crossing and mapping techniques making it challenging to determine the genetic mechanisms causing their similar phenotypes. To address this limitation, we have been developing Asellus aquaticus, a freshwater isopod crustacean, as a genetic model. Many of its cave populations originate from separate colonization events and thus independently evolved their similar cave-related phenotypes, which differ from the still existent ancestral-like surface populations. In our prior work, we identified genomic regions responsible for eye and pigment loss in a single cave population from Slovenia. In this study, we examined another, independently evolved cave population, also from Slovenia, and asked whether the same or different genomic regions are responsible for eye and pigment loss in the two cave populations. We generated F2 and backcross hybrids with a surface population, genotyped them for the previously identified genomic regions, and performed a complementation test by crossing individuals from the two cave populations. We found out that the same genomic regions are responsible for eye and pigment loss and that at least one of the genes causing pigment loss is the same in both cave populations. Future studies will identify the actual genes and mutations, as well as examine additional cave populations to see if the same genes are commonly associated with eye and pigment loss in this species.
COBISS.SI-ID: 4837455
Species that successfully colonized subterranean environments are subject to two opposing selection processes. Stringent abiotic factors select for convergent adaptations, such as loss of eyes and pigments, while interspecific competition drives between-species divergence. Subterranean species can resolve opposing selection by adaptation to physically different microhabitats. Yet, species frequently co-occur in physically homogeneous subterranean habitats, like interstitial. These co-occurrences in such a narrow ecological context can be explained either by equalizing mechanisms, in which neither of the co-occurring species has a competitive advantage, or by more complex niche models that include species’ differentiation along a trophic niche axis. We tested these hypotheses using the amphipod genus Niphargus. We analysed Europe-wide co-occurrence records of Niphargus species from interstitial habitats, split into six independent large-scale regions. Firstly, we addressed whether species’ pairwise co-occurrences are random using a probabilistic model. Secondly, we tested whether species cluster into distinct functional–morphological groups and whether ecologically or phylogenetically distinct species are more likely to co-occur. We found that 68% of species co-occurrences were not different from random expectation, indicating that most species had access to most sites within each region. The remaining 32% co-occurred either significantly more or less often than expected by chance. Cluster analysis of functional morphological characters showed that interstitial species belong to two feeding types, micro- and macrofeeders, likely representing two peaks of the interstitial adaptive landscape, and hinting that niche divergence, as a mechanism allowing coexistence, is favoured. Finally, we found that the number of co-occurrences increases with increasing differentiation of functional morphology, but not phylogenetic differences. We conclude that ecological differentiation may be important in shaping such interstitial communities.
COBISS.SI-ID: 4970831
We tested the hypothesis that sympatry among closely related species is possible only in the absence of interspecific competition. The model system was a clade of subterranean amphipods, genus Niphargus (Crustacea: Amphipoda) from Dinaric Karst. The analyses employed phylogenetic reconstructions, species delimitations and modelling competition using phylogeny and species distributions as well as reconstruction of historical dispersal. The clade comprises six species, which classify into two ecomorphs. Species of the same ecomorph are parapatric or allopatric, whereas species belonging to different ecomorphs overlap their ranges. The phylo-spatial reconstructions suggest that the shift from allopatry to sympatry is associated with relaxation of competitive interactions. Reconstruction of species past dispersal implies that sympatry is of secondary origin. Interspecific competition presumably controls evolutionary and ecological dynamics in subterranean environments in a similar way as in more familiar surface environments.
COBISS.SI-ID: 4969039