Ancient mitochondrial pseudogenes reveal hybridization between distant lineages in the evolution of the Rupicapra genus.

Mitochondrial pseudogenes (numts) inserted in the nuclear genome are frequently found in population studies. Its presence is commonly connected with problems and errors when they are confounded with true mitochondrial sequences. In the opposite side, numts can provide valuable phylogenetic information when they are copies of ancient mitochondrial lineages. We show that Rupicapra individuals of different geographic origin from the Cantabrian Mountains to the Apennines and the Caucasus share a nuclear COI fragment. The numt copies are monophyletic, and their pattern of differentiation shows two outstanding features: a long evolution as differentiated true mitochondrial lineage, and a recent integration and spread through the chamois populations. The COI pseudogene is much older than the present day mitochondrial clades of Rupicapra and occupies a basal position within the Rupicapra-Ammotragus-Arabitragus node. Joint analysis of this numt and a cytb pseudogene with a similar pattern of evolution places the source mitochondrial lineage as a sister branch that separated from the Ammotragus-Arabitragus lineage 6millionyearsago (Mya). The occurrence of this sequence in the nucleus of chamois suggests hybridization between highly divergent lineages. The integration event seems to be very recent, more recent than the split of the present day mtDNA lineages of Rupicapra (1.9Mya). This observation invites to think of the spread across the genus by horizontal transfer through recent male-biased dispersal.

Multilocus Intron Trees Reveal Extensive Male-Biased Homogenization of Ancient Populations of Chamois (Rupicapra spp.) across Europe during Late Pleistocene.

The inferred phylogenetic relationships between organisms often depend on the molecular marker studied due to the diverse evolutionary mode and unlike evolutionary histories of different parts of the genome. Previous studies have shown conflicting patterns of differentiation of mtDNA and several nuclear markers in chamois (genus Rupicapra) that indicate a complex evolutionary picture. Chamois are mountain caprine that inhabit most of the medium to high altitude mountain ranges of southern Eurasia. The most accepted taxonomical classification considers two species, R. pyrenaica (with the subspecies parva, pyrenaica and ornata) from southwestern Europe and R. rupicapra (with the subspecies cartusiana, rupicapra, tatrica, carpatica, balcanica, asiatica and caucasica) from northeastern Europe. Phylogenies of mtDNA revealed three very old clades (from the early Pleistocene, 1.9 Mya) with a clear geographical signal. Here we analyze a set of 23 autosomal introns, comprising 15,411 nucleotides, in 14 individuals covering the 10 chamois subspecies. Introns offered an evolutionary scenario that contrasts with mtDNA. The nucleotidic diversity was 0.0013± 0.0002, at the low range of what is found in other mammals even if a single species is considered. A coalescent multilocus analysis with *BEAST indicated that introns diversified 88 Kya, in the late Pleistocene, and the effective population size at the root was lower than 10,000 individuals. The dispersal of some few migrant males should have rapidly spread trough the populations of chamois, given the homogeneity of intron sequences. The striking differences between mitochondrial and nuclear markers can be attributed to strong female philopatry and extensive male dispersal. Our results highlight the need of analyzing multiple and varied genome components to capture the complex evolutionary history of organisms.

The shared mitochondrial genome of Rupicapra pyrenaica ornata and Rupicapra rupicapra cartusiana: old remains of a common past.

Mitochondrial DNA (mtDNA) has largely been used for species delimitation. However, mtDNA introgression across species boundaries can lead to inconsistent phylogenies. Partial sequences of the mitochondrial genome in the chamois, genus Rupicapra, show the presence of three well differentiated clades, West (mtW), Central (mtC) and East (mtE), each with a geographically restricted distribution. The complete mtDNAs of the clades mtW and mtE (main representatives of the two currently considered species R. pyrenaica and R. rupicapra respectively) have been reported. In the present study, we sequenced the clade mtC present in populations from both species inhabiting the central area of Europe: the Apennines (R. pyrenaica ornata) and the Chartreuse Mountains (R. rupicapra cartusiana). The phylogenetic comparison with the genomes of Caprini highlights the ancient presence of chamois in Europe relative to the fossil record, and the old age of the chamois clade mtC that was split from the clade mtW in the early Pleistocene. The separation of R. pyrenaica ornata and R. rupicapra cartusiana female lineages was recent, dating of the late Pleistocene. Our data represent an example of mtDNA introgression of resident females of Chartreuse Mountains into immigrant males of R. rupicapra due to male-biased migration and female phylopatry.

Evolution of the melanocortin-1 receptor gene (MC1R) in chamois (Rupicapra spp.).

The taxonomy of chamois and the effects of historical and evolutionary events on its diversification are still under discussion given that different morphological and genetic features presented partially discordant views. One of the morphological features that differentiate the two currently considered species, Rupicapra pyrenaica (southern chamois) and R. rupicapra (northern chamois) is coat color pattern. The melanocortin-1 receptor gene (MC1R) is related with differences in coloration in different mammals and was analyzed here in a sample of 25 chamois covering the 10 subspecies recognized, three in R. pyrenaica, (parva, pyrenaica and ornata) and seven in R. rupicapra (cartusiana, rupicapra, tatrica, carpatica, balcanica, asiatica and caucasica). Comparison with other caprinae showed that the MC1R gene has evolved under strong purifying selection. Three well differentiated haplotypes were identified: one shared by the seven subspecies of R. rupicapra, other common to the two Iberian chamois, both of the species R. pyrenaica, and a third haplotype, basal in the phylogenetic tree, unique to the subspecies from the Apennines, R. pyrenaica ornata. This pattern of variation, with three conspicuous clades, concurs with previous findings on microsatellites and mtDNA and argues in favor of the old classifications that distinguished the species R. ornata.

Y-chromosome phylogeny in the evolutionary net of chamois (genus Rupicapra).

BACKGROUND: The chamois, distributed over most of the medium to high altitude mountain ranges of southern Eurasia, provides an excellent model for exploring the effects of historical and evolutionary events on diversification. Populations have been grouped into two species, Rupicapra pyrenaica from southwestern Europe and R. rupicapra from eastern Europe. The study of matrilineal mitochondrial DNA (mtDNA) and biparentally inherited microsatellites showed that the two species are paraphyletic and indicated alternate events of population contraction and dispersal-hybridization in the diversification of chamois. Here we investigate the pattern of variation of the Y-chromosome to obtain information on the patrilineal phylogenetic position of the genus Rupicapra and on the male-specific dispersal of chamois across Europe. RESULTS: We analyzed the Y-chromosome of 87 males covering the distribution range of the Rupicapra genus. We sequenced a fragment of the SRY gene promoter and characterized the male specific microsatellites UMN2303 and SRYM18. The SRY promoter sequences of two samples of Barbary sheep (Ammotragus lervia) were also determined and compared with the sequences of Bovidae available in the GenBank. Phylogenetic analysis of the alignment showed the clustering of Rupicapra with Capra and the Ammotragus sequence obtained in this study, different from the previously reported sequence of Ammotragus which groups with Ovis. Within Rupicapra, the combined data define 10 Y-chromosome haplotypes forming two haplogroups, which concur with taxonomic classification, instead of the three clades formed for mtDNA and nuclear microsatellites. The variation shows a west-to-east geographical cline of ancestral to derived alleles. CONCLUSIONS: The phylogeny of the SRY-promoter shows an association between Rupicapra and Capra. The position of Ammotragus needs a reinvestigation. The study of ancestral and derived characters in the Y-chromosome suggests that, contrary to the presumed Asian origin, the paternal lineage of chamois originated in the Mediterranean, most probably in the Iberian Peninsula, and dispersed eastwards through serial funding events during the glacial-interglacial cycles of the Quaternary. The diversity of Y-chromosomes in chamois is very low. The differences in patterns of variation among Y-chromosome, mtDNA and biparental microsatellites reflect the evolutionary characteristics of the different markers as well as the effects of sex-biased dispersal and species phylogeography.

Integrating phylogeographic patterns of microsatellite and mtDNA divergence to infer the evolutionary history of chamois (genus Rupicapra).

BACKGROUND: The chamois, distributed over most of the medium to high altitude mountain ranges of southern Eurasia, provides an excellent model for exploring the effects of historical and evolutionary events on diversification. Populations have been grouped into two species, Rupicapra pyrenaica from southwestern Europe and R. rupicapra from eastern Europe. However, a previous study of cytochrome b revealed that the two proposed species were non-monophyletic. The reconstruction of phylogenetic relationships between animal species often depends on the markers studied. To further elucidate the evolutionary history of chamois, we extended earlier studies by analysing DNA sequences of four mitochondrial regions (ND1, 12S, tRNApro and Control Region) and microsatellites (20 loci) to include all subspecies and cover its entire distribution range. RESULTS: We found discordant microsatellite (musat) and mitochondrial (mt) DNA phylogenies. Mitochondrial phylogenies form three clades, West, Central and East (mtW, mtC and mtE), at variance with taxonomic classification. Our divergence age estimates indicate an initial separation into branches mtW-mtC and mtE 1.7 million years ago (mya), in the late Pliocene-early Pleistocene, quickly followed by the split of clades mtW and mtC. Clade mtW contains haplotypes from the Iberian peninsula and the western Alps, Clade mtC includes haplotypes from the Apennines and the Massif of Chartreuse and Clade mtE comprises populations to the east of the Alps. Divergence among populations within these three major clades is recent (< 0.5 mya). New microsatellite multilocus genotypes added to previously published data revealed differences between every pair of subspecies, forming three well defined groups (musatW, musatC and musatE) also with a strong geographic signature. Grouping does not correspond with the mitochondrial lineages but is closer to morphology and taxonomic classification. Recent drastic reductions in population size can be noted for the subspecies ornata as an extremely low diversity. CONCLUSIONS: The phylogeographic patterns for mtDNA and microsatellites suggest an evolutionary history with limited range contractions and expansions during the Quaternary period and reflect a major effect of the Alpine barrier on west-east differentiation. The contrasting phylogenies for mtDNA and microsatellites indicate events of hybridization among highly divergent lineages in the central area of distribution. Our study points to the importance of reticulate evolution, with periods of isolation and reduction of population size followed by expansions and hybridizations, in the diversification at the level of close species or subspecies.

The genetic impact of translocations and habitat fragmentation in chamois (Rupicapra) spp.

The chamois is a useful species with which to investigate the combined genetic impact of habitat fragmentation, over hunting, and translocations. Genetic variation within and between chamois (genus Rupicapra) populations was analyzed in 259 individuals from 16 sampling sites located in Italy, Spain, Slovakia, and the Czech Republic. Two mitochondrial DNA markers (control region and cytochrome b) and 11 nuclear microsatellites were typed. The principal results of this study can be summarized as follows: 1) high and significant differentiation between almost all chamois populations is observed even on a microgeographical scale, probably caused by the patchy distribution of this species, sharp geographical barriers to gene flow, and drift effects related to recent bottlenecks; 2) historical translocation events have left a clear genetic signature, including interspecific hybridization in some Alpine localities; 3) the Apennine subspecies of chamois, Rupicapra pyrenaica ornata, shows a high and similar level of divergence (about 1.5 My) from the Pyrenean (Rupicapra pyrenaica pyrenaica) and the Alpine (Rupicapra rupicapra) chamois; therefore, the specific status of these taxa should be revised. These results confirm the potential of population genetic analyses to dissect and interpret complex patterns of diversity in order to define factors important to conservation and management.

Cytochrome b phylogeography of chamois (Rupicapra spp.). Population contractions, expansions and hybridizations governed the diversification of the genus.

The chamois provides an excellent model for exploring the effect of historical and evolutionary events on diversification. We investigate cytochrome b (cytb) sequences in the 10 recognized subspecies of Rupicapra classified within 2 species: Rupicapra pyrenaica, with the subspecies parva, pyrenaica, and ornata, and Rupicapra rupicapra, with cartusiana, rupicapra, tatrica, carpatica, balcanica, asiatica, and caucasica. A fragment of 349 bp of the cytb was sequenced in 189 individuals. We identified 3 cytb lineages: Clade West in Iberia and Western Alps; Clade Central in the Apennines and the Massif of Chartreuse; and Clade East present in populations to the east of the Alps. The 2 proposed species were polyphyletic; the clades West and Central are represented in both, whereas the Clade East is restricted to R. rupicapra. In contrast to the current systematic, cytb phylogenies suggest the classification of the 10 subspecies of chamois into a single species, R. rupicapra. Phylogeny and geographical distribution of the 3 lineages show the effects of limited latitudinal range expansions, contractions, and hybridizations among highly divergent lineages, along with a major role of the glacial ice sheets of the Alps and the Pyrenees as barriers to gene flow, on the diversification of extant taxa.

Cytochrome b pseudogene originated from a highly divergent mitochondrial lineage in genus Rupicapra.

We have identified a nuclear pseudogene (numt) of cytochrome b (cytb) in chamois. The comparison of a fragment of 402 nucleotides of cytb and the pseudogene between the 2 species Rupicapra rupicapra and Rupicapra pyrenaica allowed direct measurement of relative rates and patterns of evolution. Mitochondrial genes evolved 7 to 12 times faster than their nuclear counterparts. Substitutions in the nucleus include a frameshift and a stop codon. Phylogenetic analysis of nuclear and mitochondrial lineages on Rupicapra and related species showed that the nuclear branch evolved as a functional mitochondrial gene until the split of the 2 species of chamois and as a typical pseudogene later on. We propose that the pseudogene originated from a highly divergent mitochondrial lineage that did not persist in the mitochondrion and transposed to the nucleus in a time close to speciation. The concurrence of highly differentiated lineages at speciation points to hybridization between highly divergent populations.