Rooted sound in my background of field- and lab-based methods, AfterTheIce brings together the state of the art genomic methods championed by the Center for GeoGenetics (Denmark), my main host institution, and the profound knowledge on natural history of grasshoppers by the Universidad Autónoma de Madrid (Spain), the host for my secondment.
To build a complete gene catalogue for a species lacking a reference genome we have used RNA-sequencing methodologies to reconstruct all the protein coding genes in the grasshopper species. By using whole genome sequencing at low coverage, we could identify ~12,000 single copy genes with ~750,000 neutral mutations that are appropriate for population genomic analysis. Using this novel genomic toolkit we were able to infer the demographic history of this species. Our major findings are that: 1) the two subspecies have diverged some ~113,180 generations ago, predating the last glacial maximum, 2) after secondary contact, the hybrid zone has been permeable to gene flow, working as a bridge between the two, putatively “pure”, subspecies. A manuscript reporting these results is currently under preparation.
To determine the genes targeted by selection in natural hybrid zones we have sampled two independent transects across the hybrid zone. We developed a DNA capture approach that selects for all the ~12,000 single copy genes identified earlier. In the future, this methodology will allow us to identify which genes are currently being exchanged between subspecies, and most importantly which genes cannot be exchanged, i.e. are involved in genetic barriers between emerging species.
To determine if those same genes are implicated in hybrid male sterility we have started an experimental breeding program of these grasshoppers in controlled laboratory conditions. We successfully were able to grow larvae in the lab to adulthood, make crosses, and get eggs of F1 generation. In the future, this will allow us to explicitly test if genes resistant to gene flow in natural hybrid zones are implicated in hybrid male sterility and gonad dysfunction, using histology and gene expression studies.
Most of the results that are specific of the grasshopper system have been presented to the scientific community in conferences and workshops and to the general public in actions on the field site (Spain) and in the host institution (Denmark). The general methodology on how to develop genomic tools for non-model organisms lacking reference genomes have already been disseminated in two peer-reviewed papers (Pereira et al. 2016, da Fonseca et al 2016).