RESUMO
Background: Genomic resource development for non-model organisms is rapidly progressing, seeking to uncover molecular mechanisms and evolutionary adaptations enabling thriving in diverse environments. Limited genomic data for bat species hinder insights into their evolutionary processes, particularly within the diverse Myotis genus of the Vespertilionidae family. In Mexico, 15 Myotis species exist, with three-M. vivesi, M. findleyi, and M. planiceps-being endemic and of conservation concern. Methods: We obtained samples of Myotis vivesi, M. findleyi, and M. planiceps for genomic analysis. Each of three genomic DNA was extracted, sequenced, and assembled. The scaffolding was carried out utilizing the M. yumanensis genome via a genome-referenced approach within the ntJoin program. GapCloser was employed to fill gaps. Repeat elements were characterized, and gene prediction was done via ab initio and homology methods with MAKER pipeline. Functional annotation involved InterproScan, BLASTp, and KEGG. Non-coding RNAs were annotated with INFERNAL, and tRNAscan-SE. Orthologous genes were clustered using Orthofinder, and a phylogenomic tree was reconstructed using IQ-TREE. Results: We present genome assemblies of these endemic species using Illumina NovaSeq 6000, each exceeding 2.0 Gb, with over 90% representing single-copy genes according to BUSCO analyses. Transposable elements, including LINEs and SINEs, constitute over 30% of each genome. Helitrons, consistent with Vespertilionids, were identified. Values around 20,000 genes from each of the three assemblies were derived from gene annotation and their correlation with specific functions. Comparative analysis of orthologs among eight Myotis species revealed 20,820 groups, with 4,789 being single copy orthogroups. Non-coding RNA elements were annotated. Phylogenomic tree analysis supported evolutionary chiropterans' relationships. These resources contribute significantly to understanding gene evolution, diversification patterns, and aiding conservation efforts for these endangered bat species.
Assuntos
Quirópteros , Genoma , Genômica , Filogenia , Animais , México , Genoma/genética , Quirópteros/genética , Genômica/métodosRESUMO
BACKGROUND: The harsh conditions of high-altitude environments are known to drive the evolution of physiological and morphological traits in endothermic animals. These conditions are expected to result in the adaptive evolution of protein coding genes encoded in mitochondrial genomes that are vital for the oxidative phosphorylation pathway. In this study, we formally tested for signatures of adaptive evolution on mitochondrial protein coding genes in Tapirus pinchaque and other odd-toed ungulates inhabiting high-elevation environments. RESULTS: The AT-rich mitochondrial genome of T. pinchaque is 16,750 bp long. A phylomitogenomic analysis supports the monophyly of the genus Tapirus and families in the Perissodactyla. The ratio of non-synonymous to synonymous substitutions demonstrated that all mitochondrial genes undergo purifying selection in T. pinchaque and other odd ungulates living at high elevations. Over this negative background selection, Branch Models suggested that cox3 and nad6 might be undergoing stronger purifying selection than other mitochondrial protein coding genes. Furthermore, Site Models suggested that one and four sites in nad2 and nad5, respectively, could be experiencing positive selection. However, these results were supported by Likelihood Ratio Tests but not Bayesian Empirical Bayes posterior probabilities. Additional analyses (in DataMonkey) indicated a relaxation of selection strength in nad6, evidence of episodic diversifying selection in cob, and revealed episodic positive/diversifying selection signatures for two sites in nad1, and one site each in nad2 and nad4. CONCLUSION: The mitochondrial genome of T. pinchaque is an important genomic resource for conservation of this species and this study contributes to the understanding of adaptive evolution of mitochondrial protein coding genes in odd-toed ungulates inhabiting high-altitude environments.
Assuntos
Altitude , Genoma Mitocondrial , Animais , Teorema de Bayes , Perissodáctilos/genética , Proteínas MitocondriaisRESUMO
In the species-rich family Phyllostomidae, the genus Macrotus ('big eared' bats) contains only two species; Macrotus waterhousii, distributed in western, central, and southern Mexico, Guatemala and some Caribbean Islands, and Macrotus californicus, distributed in the southwestern USA, and in the Baja California peninsula and the state of Sonora in Mexico. In this study, we sequenced and assembled the mitochondrial genome of Macrotus waterhousii and characterized in detail this genome and that of the congeneric M. californicus. Then, we examined the phylogenetic position of Macrotus in the family Phyllostomidae based on protein coding genes (PCGs). The AT-rich mitochondrial genomes of M. waterhousii and M. californicus are 16,792 and 16,691 bp long, respectively, and each encode 13 PCGs, 22 tRNA genes, 2 rRNA genes, and a putative non-coding control region 1,336 and 1,232 bp long, respectively. Mitochondrial synteny in Macrotus is identical to that reported before for all other cofamilial species. In the two studied species, all tRNAs exhibit a 'typical' cloverleaf secondary structure with the exception of trnS1, which lacks the D arm. A selective pressure analysis demonstrated that all PCGs are under purifying selection. The CR of the two species feature three domains previously reported in other mammals, including bats: extended terminal associated sequences (ETAS), central (CD), and conserved sequence block (CSB). A phylogenetic analysis based on the 13 mitochondrial PCGs demonstrated that Macrotus is monophyletic and the subfamily Macrotinae is a sister group of all remaining phyllostomids in our analysis, except Micronycterinae. The assembly and detailed analysis of these mitochondrial genomes represents a step further to continue improving the understanding of phylogenetic relationships within the species-rich family Phyllostomidae.
Assuntos
Quirópteros , Genoma Mitocondrial , Animais , Genoma Mitocondrial/genética , Quirópteros/genética , Filogenia , México , Sequência de BasesRESUMO
Ectophylla alba is a tent-making bat that roosts in mixed-sex clusters comprising adults and offspring. Our goal was to determine the genetic identity of individuals belonging to different roosting groups. We tested the hypothesis of kin selection as a major force structuring group composition. We used 9 microsatellites designed for E. alba to determine the genetic identity and probability of parentage of individuals. We analyzed parentage and kinship using the software ML-Relate, GenAIEx, and Cervus. The obtained relationship probabilities (0.5) revealed a clear maternal relationship between female adults and offspring with allele compatibility, and at least 5 relationships between male adults and pups. We found a low degree of relatedness within roosting groups. Between roosting groups at different sites, the mean probability of a half-sibling relationship ranged from 0.214 to 0.244 and, for full-sibling relationship, from 0.383 to 0.553. Genetically, adult individuals were poorly related within clusters, and kinship as an evolutionary force could not explain group membership.