The subfamily Lonchorhininae encompasses 6 species of sword-nosed bats (Lonchorhina) and is one of the most problematic lineages in the Neotropical leaf-nosed bats (Phyllostomidae) phylogeny. There are at least 5 different hypotheses to explain when the subfamily diverged from the remaining phyllostomids, but none with robust statistical support. Here, we generated a chromosome painting homology map of Lonchorhina aurita karyotype (2n = 32 and FN = 60) using whole-chromosome probes of Macrotus californicus (MCA; 2n = 40 and FN = 60). We placed the karyotype changes of L. aurita in a phylogenetic context to discuss the most likely branching position of Lonchorhininae based on karyotypic evolution. We show that L. aurita has a derived karyotype with 24 segments homologous to the 20 MCA chromosomes used as probes. Comparative analyses between 7 published painted bats species across 4 phyllostomid subfamilies (Macrotinae, Phyllostominae, Glossophaginae, and Lonchophyllinae) revealed that one inversion (MCA 4inv) and one fusion (MCA 17 + 18) are shared derived features between the karyotypes of L. aurita and species of Phyllostominae not yet observed in other bats. Our data show that chromosomal homology maps may contribute with new insights into a long-standing phylogenetic debate that has endured for decades.
Keywords: FISH; Karyotype evolution; Lonchorhininae; Phyllostomidae.
© 2022 S. Karger AG, Basel.