Levels Of Population Differentiation Research Articles

Genome-wide SNP variation reveals genetic structure and high levels of diversity in a global survey of wild and farmed Pacific white shrimp

Domestication and subsequent artificial selection of Pacific white shrimp (Penaeus vannamei) commenced around 1980 and the species is now the most widely farmed crustacean in the world. We documented generally high levels of genetic diversity within 21 globally distributed farmed populations using 44,522 SNP collected using an Illumina SNP chip. The sample set also included 86 wild P. vannamei, facilitating investigation of within population diversity and the extent of divergence between wild shrimp. This revealed weak population structure amongst wild populations from Panama, Honduras, Guatemala and Colombia (FST range 0–3 %) and more significant divergence between those and the wild Mexican animals that should be considered a distinct subpopulation. Comparison between wild and farmed global populations showed low to moderate levels of population differentiation (FST < 6 %) with farmed Asian populations most divergent. Interestingly, SNP chip data documented a marked absence of widespread reduction in the diversity in farmed populations when compared with their wild relatives. To ensure the results were not influenced by ascertainment bias, whole genome sequencing was used to identify 4.13 M SNP in a subset of both farmed and wild shrimp. Observed levels of nucleotide diversity in wild (π = 1.95 × 10−4) and farmed animals (π = 2.05 × 10−4) were similar, suggesting that broad and repeated introductions of wild shrimp have likely contributed to the domestication process. A search for selection sweeps identified a small collection of outlier regions (38 intervals spanning 2.1 Mb) and 20 protein coding genes. The results represent a broad snapshot of the genetic diversity and divergence that exists within this important aquaculture species.

Comparison of Genetic Structures Among Sympatric, Red-Listed Salt-Marsh Snails in Mainland Japan (Gastropoda: Ellobiidae).

Melampus "sincaporensis," Auriculastra "duplicata", and Ellobium chinense are Red-Listed snail species of the family Ellobiidae that co-occur on salt marshes in mainland Japan. Here, we report the genetic diversity and population structures of the former two taxa in comparison with our previous data on E. chinense for the evaluation of connectivity and conservation values of their local populations. Analyses of 655-bp or 652-bp sequences of the mitochondrial cytochrome c oxidase subunit I gene showed the highest genetic diversity and panmictic structure for M. sp. cf. sincaporensis throughout its geographic range in Japan, whereas they showed the highest level of genetic subdivision for A. sp. cf. duplicata. Our laboratory observation of egg masses and planktotrophic larvae of A. "duplicata" and reference to previous ontogenetic data for the species of Melampus suggested differences in their fecundity and pelagic larval duration, which apparently have led to the contrasting levels of population differentiation in the study species. Particular need of conservation efforts was identified for the isolated population of A. "duplicata" in the Ise-Mikawa Bay area to avoid local extinction and shrinking of the species' geographic range. In addition, we present molecular and morphological evidence that individuals of A. "duplicata" from mangrove swamps in the northern part of Okinawa Island represent an independent, surviving lineage of a different species.

Clonality and limited population diversity of Fusarium circinatum in Colombia

AbstractFusarium circinatum is an important fungal pathogen of Pinus species utilized in commercial forestry worldwide. In Colombia, it was first found on nursery plants and later in plantations associated with basal cankers on young trees. In this study, we explored the population diversity of the pathogen in Colombia by analyzing 136 isolates collected from diseased nursery plants (2005–2007) and plantation trees (2017 and 2020). These were sourced from different geographical regions and Pinus species. Genotyping was performed using 10 microsatellite markers, while mating types were identified with PCRs targeting the MAT1 locus. Using microsatellites, a total of 33 multilocus haplotypes were detected. Genetic diversity indices showed low levels of diversity in both the overall collection and in specific collection groupings. The data also suggested that a small number of isolates had unique origins in the country (p &lt; .05), and relatively low levels of population differentiation were detected between the nursery and plantation collections. All the isolates were scored as having the MAT1‐1 mating type, and no evidence for the random association among microsatellite alleles (p = .0001) was found. Overall, these data suggest that F. circinatum was introduced into Colombia a small number of times, likely on seed for nursery production. Furthermore, the data also indicate that the pathogen has spread from nurseries to the plantations via asexual reproduction and on asymptomatic plants. This has resulted in a highly clonal F. circinatum population in Colombia that has resulted from accidental introductions of the pathogen into a production nursery.

Development and application of microsatellite markers in Hippophae rhamnoides subsp. sinensis Rousi (Hippophae rhamnoides L.) based on transcriptome sequencing.

Hippophae rhamnoides subsp. sinensis Rousi is a cold- and drought-tolerant pioneer species with significant economic and ecological value. Evaluating its genetic diversity and population structure is of great importance for guiding the development and utilization of resources. In this study, a total of 41,804 SSRs were generated by transcriptome sequencing of Hippophae rhamnoides subsp. sinensis Rousi. Among the different SSR motif types, mononucleotide repeats (26,972) were the most abundant, followed by trinucleotides, tetranucleotides, and pentanucleotides. 200 pairs of SSR primers were selected to detect polymorphisms, of which 15 pairs primers were selected as validated polymorphic SSRs used for genetic diversity and population structure analysis. A total of 63 alleles were identified with 15 pairs primers, with Nei's genetic diversity index ranged from 0.27 to 0.83 (average: 0.54), and the expected heterozygosity ranged from 0.16 to 0.73 (average: 0.46). The polymorphism information content ranged from 0.23 to 0.81 (average: 0.48). Genetic structure analyses showed that the 10 populations could be broadly categorized into two groups. AMOVA denoted that genetic variations primarily originated from within the populations, with minimal differences observed between the groups, accounting for only 7% of the total genetic variation. This implies that mutation in H. rhamnoides subsp. sinensis Rousi mainly occurred within the populations. The results showed that the 10 populations of H. rhamnoides subsp. sinensis Rousi are rich in genetic diversity, with low levels of population differentiation and a high degree of gene exchange, which should be taken into consideration for the future work of germplasm resource preservation and seedling breeding.

Genetic and morphological differentiation among populations of the narrowly endemic and karst forest-adapted Pilea pteridophylla (Urticaceae)

In this study, the influence of geographic isolation on the levels of morphological and genetic differentiation among populations of the karst forest-adapted Pilea pteridophylla (Urticaceae) was evaluated. Based on our results, there is a strong morphological differentiation among the only two know populations of Pilea pteridophylla. Both populations can be clearly differentiated based on vegetative and reproductive characters, and the observed variation is geographically structured. Moreover, our genetic data from the chloroplast genome show strong levels of population differentiation and no shared haplotypes were observed between populations. Also, our estimation of divergence times supports a long-term isolation hypothesis between populations. Based on our results, dispersal seed limitation, long-term forest isolation and topographic heterogeneity (local adaptation) are related to high levels of endemism and species turnover in the mountain karst forests of Mexico.

Genomic analysis of Nigerian indigenous chickens reveals their genetic diversity and adaptation to heat-stress

Indigenous poultry breeds from Africa can survive in harsh tropical environments (such as long arid seasons, excessive rain and humidity, and extreme heat) and are resilient to disease challenges, but they are not productive compared to their commercial counterparts. Their adaptive characteristics are in response to natural selection or to artificial selection for production traits that have left selection signatures in the genome. Identifying these signatures of positive selection can provide insight into the genetic bases of tropical adaptations observed in indigenous poultry and thereby help to develop robust and high-performing breeds for extreme tropical climates. Here, we present the first large-scale whole-genome sequencing analysis of Nigerian indigenous chickens from different agro-climatic conditions, investigating their genetic diversity and adaptation to tropical hot climates (extreme arid and extreme humid conditions). The study shows a large extant genetic diversity but low level of population differentiation. Using different selection signature analyses, several candidate genes for adaptation were detected, especially in relation to thermotolerance and immune response (e.g., cytochrome P450 2B4-like, TSHR, HSF1, CDC37, SFTPB, HIF3A, SLC44A2, and ILF3 genes). These results have important implications for conserving valuable genetic resources and breeding improvement of chickens for thermotolerance.

Disentangling the contemporary and historical effects of landscape on the population genomic variation of two bird species restricted to the highland forest enclaves of northeastern Brazil.

Investigating the impact of landscape features on patterns of genetic variation is crucial to understand spatially dependent evolutionary processes. Here, we assess the population genomic variation of two bird species (Conopophaga cearae and Sclerurus cearensis) through the Caatinga moist forest enclaves in northeastern Brazil. To infer the evolutionary dynamics of bird populations through the Late Quaternary, we used genome-wide polymorphism data obtained from double-digestion restriction-site-associated DNA sequencing (ddRADseq), and integrated population structure analyses, historical demography models, paleodistribution modeling, and landscape genetics analyses. We found the population differentiation among enclaves to be significantly related to the geographic distance and historical resistance across the rugged landscape. The climate changes at the end of the Pleistocene to the Holocene likely triggered synchronic population decline in all enclaves for both species. Our findings revealed that both geographic distance and historical connectivity through highlands are important factors that can explain the current patterns of genetic variation. Our results further suggest that levels of population differentiation and connectivity cannot be explained purely on the basis of contemporary environmental conditions. By combining historical demographic analyses and niche modeling predictions in a historical framework, we provide strong evidence that climate fluctuations of the Quaternary promoted population differentiation and a high degree of temporal synchrony among population size changes in both species.

Traditional Management of Maize in the Sierra Sur, Oaxaca, Maintains Moderate Levels of Genetic Diversity and Low Population Differentiation Among Landraces

Oaxaca is one of the areas of early maize diversification, with 28 to 35 recognized agronomic races. Campesinos (farmers) cultivate at least ten different races in the Los Loxicha region. There is evidence of introgression between them; however, some traditional practices have promoted further differentiation evidenced by the presence of different landraces, clearly recognized by various morphological and phenological characteristics. Therefore, moderate levels of genetic diversity and low levels of population differentiation are expected. Seven communities belonging to two municipalities were selected in 2005. In total, 140 semistructured interviews were administered, inquiring about cultural practices, which included questions about maize seed, ear, and cob management and selection and maize cultivation. Based on interviews and permissions, 30 maize plants from each of 28 fields (milpas) with maize crop belonging to five landraces (Conejo, Hueso, Tablita, Tepecente, and Pinto) were sampled. From the 82 ISSR loci amplified, Hueso and Conejo exhibited the highest and lowest number of loci (70 and 56 loci, respectively); 72% of loci analyzed in the five populations were polymorphic. The Hueso landrace presented the highest percentage of polymorphism (73%) and Conejo the lowest (54%). The expected heterozygosity (HeT) for the five landraces was 0.225 ± 0.032, and the genetic diversity of Nei (HST) was 0.225 ± 0.034. The population differentiation values obtained with GST indicated that Tablita and Hueso were the least differentiated, while the most differentiated were Pinto and Tepecente. STRUCTURE analysis identified two genetically differentiated groups (k = 2), consistent with the length of their agricultural cycle (number of days until flowering). UPGMA analysis showed that milpas belonging to the same landrace and with a specific agricultural cycle length were grouped, regardless of their geographic distribution. These results indicate that traditional management of maize in the Los Loxicha region, particularly as it relates to the selection of ears and seeds and control of the agricultural cycle, maintains a balance between morphological differentiation, moderate levels of genetic diversity and gene flow, and low levels of population differentiation. This has contributed to the high richness and low evenness of agronomic races reported for the mountainous regions of the Sierra Madre del Sur and for Oaxaca.

Considerable gene flow in troglomorphic cockroach species across a vast subterranean landscape

AbstractAimThere has been growing interest in non‐cave subterranean habitats and their influence on the evolution of troglomorphic (i.e. ‘subterranean adapted’) species. Studies on the diversification of aquatic subterranean organisms in these habitats generally support the ‘subterranean island’ hypothesis, whereby isolated subterranean refuges lead to patterns of short‐range endemism. However, their terrestrial counterparts have received less attention. We aimed to elucidate the applicability of the ‘subterranean island’ hypothesis to terrestrial subterranean fauna through genetic analyses of two widespread troglomorphic cockroach species. To investigate the influence of subterranean biogeography, we also analysed a closely related species that inhabits ‘classic’ cave environments to represent a contrasting biogeographic comparison.LocationPilbara region, Western Australia, and the Chillagoe‐Mungana Caves, Queensland (Australia).TaxaCave cockroach species: Nocticola cockingi, Nocticola quartermainei and Nocticola australiensis.MethodsWe used DArTseq to generate genome‐wide SNPs in 78 samples, and Sanger sequencing to generate 16S mtDNA data. We then applied various population genomic analyses to characterize the distribution of genetic diversity within the three study species.ResultsWe identified distinct genetic clusters within the two Pilbara species; however, there appeared to be a notable lack of discernible population differentiation across large parts of their range (&gt;135 km), opposing the subterranean island hypothesis. The highest level of population differentiation in the three study species was between the two caves in Queensland, ~3 km apart.Main ConclusionsThe Pilbara subterranean habitat appeared to be conducive to gene flow across relatively large distances, contrasting high levels of endemism observed in other subterranean taxa within the region. The disparate patterns of gene flow among the Pilbara and Queensland study species emphasize the significance of differing subterranean habitats on patterns of dispersal and vicariance. These inferences will inform conservation genetic management of these species, and may help elucidate the evolutionary paradox of widespread subterranean fauna.

Holocentric repeat landscapes: From micro-evolutionary patterns to macro-evolutionary associations with karyotype evolution.

Repetitive elements can cause large-scale chromosomal rearrangements, for example through ectopic recombination, potentially promoting reproductive isolation and speciation. Species with holocentric chromosomes, that lack a localized centromere, might be more likely to retain chromosomal rearrangements that lead to karyotype changes such as fusions and fissions. This is because chromosome segregation during cell division should be less affected than in organisms with a localized centromere. The relationships between repetitive elements and chromosomal rearrangements and how they may translate to patterns of speciation in holocentric organisms are though poorly understood. Here, we use a reference-free approach based on low-coverage short-read sequencing data to characterize the repeat landscape of two independently evolved holocentric groups: Erebia butterflies and Carex sedges. We consider both micro- and macro-evolutionary scales to investigate the repeat landscape differentiation between Erebia populations and the association between repeats and karyotype changes in a phylogenetic framework for both Erebia and Carex. At a micro-evolutionary scale, we found population differentiation in repeat landscape that increases with overall intraspecific genetic differentiation among four Erebia species. At a macro-evolutionary scale, we found indications for an association between repetitive elements and karyotype changes along both Erebia and Carex phylogenies. Altogether, our results suggest that repetitive elements are associated with the level of population differentiation and chromosomal rearrangements in holocentric clades and therefore likely play a role in adaptation and potentially species diversification.

Genetic survey extension of the threatened Iberian Arnica montana L. revealed the presence of divergent plastid lineages and highly structured populations in northern Spain

Iberian populations of Arnica montana L. (Asteraceae) represent a valuable resource both for conservation and pharmaceutical industry. Previous genetic analyses pointed out the presence of different genetic groups, but a wide region is still genetically unexplored. In order to fill this scientific gap, the present study analysed a wider sampling area along the northern Iberian Peninsula. Nuclear (i.e. microsatellite loci) and plastid DNA (cpDNA) molecular markers were used to assess the levels of genetic diversity and the population structure in 16 locations, eight analysed for the first time in the present study and eight representative of the different genetic groups previously identified. The two divergent cpDNA groups previously described were found, but their distribution was extended and refined. Thus, one of the groups (suggested as ancestral) was predominantly distributed in adjacent zones of the Cantabrian coasts while the other (more related to Central-European populations) was predominant in inner Cantabrian regions and Pyrenees. Genetic diversity with microsatellite loci (He = 0.280) was in accordance with the figures previously described, with a high level of population differentiation (FST > 0.500) identifying the presence of up to five population genetic units. Genetic and geographical distances were not related (no isolation-by-distance pattern identified), suggesting an important effect of genetic drift. Finally, due to the conservation and evolutionary interest of the populations analysed, different management actions useful for the maintenance of wild A. montana resources are provided.

Genetic variation and Wolbachia infection status of the lycaenid butterfly Zizina emelina (Lepidoptera, Lycaenidae) from Korean populations

• We found 4 novel mitochondrial haplotypes in Zizina emelina emelina from Korea. • Korean samples had a single nuclear haplotype, which is also in Japanese Z. emelina. • Differentiation between Japanese and Korean populations of Z. emelina is minimal. The lycaenid butterfly Zizina emelina emelina (de l’Orza) (previously Zizina otis emelina ; Lepidoptera, Lycaenidae) has populations distributed across Japan and Korea. Zizina emelina is listed on Japan’s Red List as an endangered species, owing to the loss of its principal plant food and habitat. Researchers previously investigated the genetic diversity and structure in Japanese populations by using mitochondrial and nuclear DNA analyses alongside their Wolbachia infection status to consider the conservation strategy. In this study, we investigated the genetic variation and Wolbachia infection status of Korean populations and compared our findings with these traits in the Japanese populations. Four novel mitochondrial haplotypes were found in the Korean populations, whereas nuclear DNA analysis revealed one new haplotype and another that matched the one reported previously in Japan. The two known strains of Wolbachia in the Japanese populations were also found in the Korean ones. Mitochondrial DNA analysis demonstrated that no gene flow had occurred between the Japanese and Korean populations. The fact that they share the same nuclear haplotype and Wolbachia strains, however, indicates a low level of population differentiation between the two.

Incipiently social carpenter bees (Xylocopa) host distinctive gut bacterial communities and display geographical structure as revealed by full-length PacBio 16S rRNA sequencing.

The gut microbiota of bees affects nutrition, immunity and host fitness, yet the roles of diet, sociality and geographical variation in determining microbiome structure, including variant-level diversity and relatedness, remain poorly understood. Here, we use full-length 16S rRNA amplicon sequencing to compare the crop and gut microbiomes of two incipiently social carpenter bee species, Xylocopa sonorina and Xylocopa tabaniformis, from multiple geographical sites within each species' range. We found that Xylocopa species share a set of core taxa consisting of Bombilactobacillus, Bombiscardovia and Lactobacillus, found in >95% of all individual bees sampled, and Gilliamella and Apibacter were also detected in the gut of both species with high frequency. The crop bacterial community of X. sonorina comprised nearly entirely Apilactobacillus with occasionally abundant nectar bacteria. Despite sharing core taxa, Xylocopa species' microbiomes were distinguished by multiple bacterial lineages, including species-specific variants of core taxa. The use of long-read amplicons revealed otherwise cryptic species and population-level differentiation in core microbiome members, which was masked when a shorter fragment of the 16S rRNA (V4) was considered. Of the core taxa, Bombilactobacillus and Bombiscardovia exhibited differentiation in amplicon sequence variants among bee populations, but this was lacking in Lactobacillus, suggesting that some bacterial genera in the gut may be structured by different processes. We conclude that these Xylocopa species host a distinctive microbiome, similar to that of previously characterized social corbiculate apids, which suggests that further investigation to understand the evolution of the bee microbiome and its drivers is warranted.

Population and conservation genetics using RAD sequencing in four endemic conifers from South America

The emblematic conifer flora of Chile has experienced wide-scale habitat loss and fragmentation. Coupled with the complex topography of the region, this leads to a prediction of high levels of genetic drift and isolation resulting in strong population differentiation, and the potential for negative genetic consequences. To address the degree to which these predictions are realised, we conducted a comparative population genetic survey in four endemic conifers from South America, each of conservation concern and with a restricted distribution area. Between seven and ten populations per species were sampled, covering their entire natural distribution in Chile. We used restriction site-associated DNA markers (RAD-seq), with de novo assembly and optimisation, to accommodate the large and complex genome of conifers. The main finding was low levels of genetic structure in all four conifer species (FST = 0.017–0.062). This pattern was strikingly consistent across all four species. These results are likely due to the extreme longevity of individuals restricting divergence due to genetic drift. Thus, despite the currently highly fragmented ranges of these conifer species, we did not detect evidence for high levels of population differentiation and genetic isolation. This suggests some resilience to negative genetic impacts of habitat fragmentation, and the longevity of the individual trees may provide considerable buffering capacity. We recommend follow-up studies focusing on genotyping the seedling generation, to assess whether there is any evidence for the early warning of genetic isolation and/or elevated inbreeding in the currently established cohorts.

Whole-genome resequencing of Chinese pangolins reveals a population structure and provides insights into their conservation

Poaching and trafficking have a substantial negative impact on the population growth and range expansion of the Chinese pangolin (Manis pentadactyla). However, recently reported activities of Chinese pangolins in several sites of Guangdong province in China indicate a promising sign for the recovery of this threatened species. Here, we re-sequence genomes of 15 individuals and perform comprehensive population genomics analyses with previously published 22 individuals. These Chinese pangolins are found to be divided into three distinct populations. Multiple lines of evidence indicate the existence of a newly discovered population (CPA) comprises entirely of individuals from Guangdong province. The other two populations (CPB and CPC) have previously been documented. The genetic differentiation of the CPA and CPC is extremely large (FST = 0.541), which is larger than many subspecies-level differentiations. Even for the closer CPA and CPB, their differentiation (FST = 0.101) is still comparable with the population-level differentiation of many endangered species. Further analysis reveals that the CPA and CPB populations separate 2.5–4.0 thousand years ago (kya), and on the other hand, CPA and CPC diverge around 25–40 kya. The CPA population harbors more runs of homozygosity (ROHs) than the CPB and CPC populations, indicating that inbreeding is more prevalent in the CPA population. Although the CPC population has less mutational load than CPA and CPB populations, we predict that several Loss of Function (LoF) mutations will be translocated into the CPA or CPB populations by using the CPC as a donor population for genetic rescue. Our findings imply that the conservation of Chinese pangolins is challenging, and implementing genetic rescue among the three groups should be done with extreme caution.

Age-Dependent Dispersal and Relatedness in Tiger Sharks (Galeocerdo cuvier)

Understanding dispersal in large marine fauna is necessary for conservation, but movement patterns often vary widely by sex and life stage. In sharks, genetic studies have shown evidence of widespread male-biased dispersal, though tagging and tracking studies on the same populations show both sexes using site fidelity, including philopatry, and moving similar distances. We used a suite of microsatellite loci and DNA samples from 362 previously-tagged tiger sharks (Galeocerdo cuvier) in the northwestern Atlantic, including a large number of residential juveniles, to evaluate reproductive dispersal in light of demographic and published tracking data. We found that lumping size classes together resulted in genetic panmixia across sites, but systematic removal of large individuals showed significant population-level differentiation and three separate population clusters among juveniles less than 260 cm total length. Tests for relatedness found that 8.9% of our sample set was composed of first-order related pairs (N = 16), including several full siblings from different litters, a sign of multi-cycle genetic monogamy which carries implications for effective population size. By mapping genetic assignments of juveniles, we identified a signature of fine-scale genetic structure suggesting broad biparental site fidelity to reproductive habitat in the northeast Gulf of Mexico, which is concordant with both genetic and tracking data. Taken together, these findings demonstrate how lumping individuals from different life stages in genetic studies may obscure fine-scale genetic structure, confounding future conservation efforts.

Genetic diversity analysis of Camellia fascicularis H. T. Chang based on SSR markers

Camellia fascicularis is a Camellia specie with extremely small populations and unique to Yunnan Province. This study aimed to analyze the genetic diversity of C. fascicularis populations using polymorphic SSR markers. Eighty four samples of eight natural populations were tested for genetic diversity using fourteen SSR markers. The numbers of alleles detected at single polymorphic loci using 14 SSR markers were 2–8, and a total of 68 alleles were identified in this study, with an average allele number of 4.8571 per locus. The average Shannon’s information index I was 1.0925, indicating that C. fascicularis has a high diversity. The percentages of polymorphic loci (PPB) of the eight populations of C. fascicularis were 42.86 %−100 %. There were significant differences in genetic parameters among different populations, and the polymorphisms were all high. The gene flow (Nm) values ranged from 0.0503 to 0.9820, with an average value of 0.5440 < 1. Genetic structure analysis showed that the eight C. fascicularis populations were roughly divided into three groups. Genetic variation occurred mainly within populations, with intra-populations genetic variation accounting for 49.95 % of the total variation. It was found that C. fascicularis has a high genetic diversity, and its rich genetic diversity may be due to the diverse habitat diversity of its distribution area and the long evolutionary history of the species. There was almost no gene exchange among natural populations, and the level of population differentiation was low.

Inter-Specific Genetic Exchange Despite Strong Divergence in Deep-Sea Hydrothermal Vent Gastropods of the Genus Alviniconcha.

Deep hydrothermal vents are highly fragmented and unstable habitats at all temporal and spatial scales. Such environmental dynamics likely play a non-negligible role in speciation. Little is, however, known about the evolutionary processes that drive population-level differentiation and vent species isolation and, more specifically, how geography and habitat specialisation interplay in the species history of divergence. In this study, the species range and divergence of Alviniconcha snails that occupy active Western Pacific vent fields was assessed by using sequence variation data of the mitochondrial Cox1 gene, RNAseq, and ddRAD-seq. Combining morphological description and sequence datasets of the three species across five basins, we confirmed that A. kojimai, A. boucheti, and A. strummeri, while partially overlapping over their range, display high levels of divergence in the three genomic compartments analysed that usually encompass values retrieved for reproductively isolated species with divergences rang from 9% to 12.5% (mtDNA) and from 2% to 3.1% (nuDNA). Moreover, the three species can be distinguished on the basis of their external morphology by observing the distribution of bristles and the shape of the columella. According to this sampling, A. boucheti and A. kojimai form an east-to-west species abundance gradient, whereas A. strummeri is restricted to the Futuna Arc/Lau and North Fiji Basins. Surprisingly, population models with both gene flow and population size heterogeneities among genomes indicated that these three species are still able to exchange genes due to secondary contacts at some localities after a long period of isolation.

Delineating the genetic status of wild Cyprinus carpio as influenced by anthropogenic interventions

The ability of populations to persist and adapt to environmental changes is based on genetic diversity. Substantial empirical data shows that the genetic integrity of natural fish population is being compromised by the effect of anthropogenic interventions and robust environmental conditions. Genetic diversity estimates were obtained for 210 individuals of Cyprinus carpio sampled from six sites of Indus river basin, using 14 microsatellite loci as markers. The results showed a moderate level of genetic diversity in terms of number of alleles (Na), effective number of alleles (Nae) and heterozygosity (H). Significant deviation from Hardy Weinberg equilibrium was observed in 17 out of 84 tests. The pairwise FST values showed a moderate level of population differentiation. AMOVA revealed a significant genetic structuring among the wild populations. The UPGMA dendrogram constructed for analysis of genetic relatedness grouped all the populations into two clusters. The understanding of genetic structure of C. carpio in natural systems would be instrumental in genetic enhancement programs, effective management and sustainable conservation of riverine genetic resources.

Varied diversification patterns and distinct demographic trajectories in Ethiopian montane forest bird (Aves: Passeriformes) populations separated by the Great Rift Valley.

Taxon-specific characteristics and extrinsic climatic and geological forces may both shape population differentiation and speciation. In geographically and taxonomically focused investigations, differentiation may occur synchronously as species respond to the same external conditions. Conversely, when evolution is investigated in taxa with largely varying traits, population differentiation and speciation is complex and shaped by interactions of Earth's template and species-specific traits. As such, it is important to characterize evolutionary histories broadly across the tree of life, especially in geographic regions that are exceptionally diverse and under pressures from human activities such as in biodiversity hotspots. Here, using whole-genome sequencing data, we characterize genomic variation in populations of six Ethiopian Highlands forest bird species separated by a lowland biogeographic barrier, the Great Rift Valley (GRV). In all six species, populations on either side of the GRV exhibited significant but varying levels of genetic differentiation. Species' dispersal ability was negatively correlated with levels of population differentiation. Isolation with migration models indicated varied patterns of population differentiation and connectivity among populations of the focal species. We found that demographic histories-estimated for each individual-varied by both species and population but were consistent between individuals of the same species and sampling region. We found that genomic diversity varied by half an order of magnitude across species, and that this variation could largely be explained by the harmonic mean of effective population size over the past 200,000years. Overall, we found that even in highly dispersive species like birds, the GRV acts as a substantial biogeographic barrier.