Your search keyword '"Demographic History"' showing total 427 results

1. Phylogenetic conflict between species tree and mitochondrial gene trees in Murininae (Mammalia, Chiroptera) and validation of the genus Harpiola.

Author

Wang, Xiaoyun, Liang, Xiaoling, Li, Yannan, Csorba, Gábor, Hu, Yibo, He, Kai, Wu, Yi, and Yu, Wenhua

Abstract

The subfamily Murininae is renowned for its inherent taxonomic challenges associated with sampling difficulties and morphological similarities. At present, three genera are acknowledged within the subfamily; however, their phylogenetic interrelations and systematic classification remain debated. In this study, the separation of Harpiola at the genus level was robustly supported by our phylogenomic analyses based on the mitochondrial genome, coding sequences (CDSs) and ultraconserved elements (UCEs) from 12 individuals covering all three genera of Murininae. Notably, a distinctive mito‐nuclear discordance emerged, with the nuclear genealogy ((Harpiocephalus, Harpiola), Murina) contrasting with the mitochondrial genealogy (Harpiocephalus, (Harpiola, Murina)). The integration of these findings with inferences of demographic history reveals that dramatic environmental changes during the Pleistocene glacial and inter‐glacial cycles have shaped the current distribution of Murininae. Moreover, the detection of extensive gene flow between ancient lineages of Harpiola and Murina suggests that an ancestral ‘ghost’ Murina lineage may have contributed its mitochondrial DNA, along with a limited portion of nuclear DNA, to Harpiola in a bygone hybridization zone. In addition to molecular analyses, we employed traditional and geometric morphometric analyses of skulls to differentiate the three genera. Harpiocephalus is readily distinguishable, but Harpiola and certain species of Murina exhibit overlapping characteristics both morphometrically and geometrically which may be the outcome of ancient introgression events. This finding highlights the importance of fine‐scale morphological distinctions within the latter genera, which may be the outcome of ancient introgression events. [ABSTRACT FROM AUTHOR]

Published

2024

2. Demographic History and Adaptive Evolution of Indo‐Pacific Bottlenose Dolphins (Tursiops aduncus) in Western Australia.

Author

Marfurt, Svenja M., Chabanne, Delphine B. H., Wittwer, Samuel, Bizzozzero, Manuela R., Allen, Simon J., Gerber, Livia, Nicholson, Krista, and Krützen, Michael

Subjects

*BIOLOGICAL evolution, *LAST Glacial Maximum, *GENETIC variation, *OUTLIER detection, *WATER clusters, *BOTTLENOSE dolphin, *MARINE mammals

Abstract

Demographic processes can substantially affect a species' response to changing ecological conditions, necessitating the combined consideration of genetic responses to environmental variables and neutral genetic variation. Using a seascape genomics approach combined with population demographic modelling, we explored the interplay of demographic and environmental factors that shaped the current population structure in Indo‐Pacific bottlenose dolphins (Tursiops aduncus) along the Western Australian coastline. We combined large‐scale environmental data gathered via remote sensing with RADseq genomic data from 133 individuals at 19 sampling sites. Using population genetic and outlier detection analyses, we identified three distinct genetic clusters, coinciding with tropical, subtropical and temperate provincial bioregions. In contrast to previous studies, our demographic models indicated that populations occupying the paleo‐shoreline split into two demographically independent lineages before the last glacial maximum (LGM). A subsequent split after the LGM 12—15 kya gave rise to the Shark Bay population, thereby creating the three currently observed clusters. Although multi‐locus heterozygosity declined from north to south, dolphins from the southernmost cluster inhabiting temperate waters had higher heterozygosity in potentially adaptive loci compared to dolphins from subtropical and tropical waters. These findings suggest ongoing adaptation to cold‐temperate waters in the southernmost cluster, possibly linked to distinct selective pressures between the different bioregions. Our study demonstrated that in the marine realm, without apparent physical boundaries, only a combined approach can fully elucidate the intricate environmental and genetic interactions shaping the evolutionary trajectory of marine mammals. [ABSTRACT FROM AUTHOR]

Published

2024

3. Lineage Differentiation and Genomic Vulnerability in a Relict Tree From Subtropical Forests.

Author

Zhu, Xian‐Liang, Wang, Jing, Chen, Hong‐Feng, and Kang, Ming

Abstract

The subtropical forests of East Asia are renowned for their high plant diversity, particularly the abundance of ancient relict species. However, both the evolutionary history of these relict species and their capacity for resilience in the face of impending climatic changes remain unclear. Using whole‐genome resequencing data, we investigated the lineage differentiation and demographic history of the relict and endangered tree, Bretschneidera sinensis (Akaniaceae). We employed a combination of population genomic and landscape genomic approaches to evaluate variation in mutation load and genomic offset, aiming to predict how different populations may respond to climate change. Our analysis revealed a profound genomic divergence between the East and West lineages, likely as the result of recurrent bottlenecks due to climatic fluctuations during the glacial period. Furthermore, we identified several genes potentially linked to growth characteristics and hypoxia response that had been subjected to positive selection during the lineage differentiation. Our assessment of genomic vulnerability uncovered a significantly higher mutation load and genomic offset in the edge populations of B. sinensis compared to their core counterparts. This implies that the edge populations are likely to experience the most significant impact from the predicted climate conditions. Overall, our research sheds light on the historical lineage differentiation and contemporary genomic vulnerability of B. sinensis. Broadening our understanding of the speciation history and future resilience of relict and endangered species such as B. sinensis, is crucial in developing effective conservation strategies in anticipation of future climatic changes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Evolution history and the importance of genomic diversity facing climate change. The case of Agave marmorata Roezl., a microendemic agave used for mezcal production.

Author

Ruiz‐Mondragón, Karen Y., Klimova, Anastasia, Valiente‐Banuet, Alfonso, Lira, Rafael, and Eguiarte, Luis E.

Subjects

*CLIMATE change models, *SINGLE nucleotide polymorphisms, *GENETIC variation, *WILD plants, *ENDEMIC species

Abstract

Social Impact Statement: For hundreds of years, Agave marmorata plants have been used in the production of alcoholic beverages in Mexico. This species is very important in small‐scale rural economies because it is a large plant, yielding five liters of mezcal. However, the production of these beverages takes place when it reaches its reproductive stage, which takes up to 35 years. Due to its slow maturation and high demand, it is considered an endangered species. Therefore, as a conservation strategy, this study proposes the creation of nurseries, genetic breeding programs, and demographic monitoring of wild populations to counteract the extraction of wild plants and, the conservation of the genetic diversity. Summary: Agave marmorata Roezl., is an endemic species distributed in the states of Oaxaca and Puebla, Mexico, and locally is widely used to produce mezcal.We assessed the genomic diversity and differentiation using the RADseq method and 29,101 high‐quality single nucleotide polymorphisms (SNPs) in wild plants and grown under three different management types (cultivated, plants used as live fences, and young plants growing in nurseries). We examined the demographic history and used species distribution modeling to understand the future of A. marmorata under scenarios of climate change.We found high levels of genomic diversity (HS = 0.229) and moderate levels of inbreeding (FIS = 0.106 and Fhat3 = 0.190). The cultivated samples harbored less genetic diversity than the wild plants. Furthermore, we estimated low differentiation between cultivated and wild localities (FST = 0.037). In the wild samples, we identified two main genetic groups, one in the East and another in the West of its distribution area. This genetic structure possibly derived from a population contraction during the Pleistocene (~216,879.75 BP) and the formation of two refugia in small areas with climatic stability. Furthermore, the demographic reconstruction indicated that A. marmorata went through a recent population expansion event, with a large current Ne (Ne = 8,009). The future climate change models indicated contrasting possible changes in its distribution range, from an increase to the reduction of its suitable habitat, differences related to model parametrization, and future levels of CO2 production.We propose conservation measures for the different management types of the species while also considering the biotic and abiotic interactions of Agave marmorata. [ABSTRACT FROM AUTHOR]

Published

2024

5. Habitat fragmentation strongly restricts gene flow in endangered ectomycorrhizal fungal populations: Evidence from Rhizopogon togasawarius, specific to Pseudotsuga japonica, across the entire distribution range.

Author

Abe, Hiroshi, Gan, Lu, Murata, Masao, and Nara, Kazuhide

Subjects

*FUNGAL genetics, *GENETIC drift, *POPULATION differentiation, *FRAGMENTED landscapes, *GENETIC variation

Abstract

Habitat fragmentation reduces gene flow, causing genetic differentiation and diversity loss in endangered species through genetic drift and inbreeding. However, the impact of habitat fragmentation on ectomycorrhizal (ECM) fungi remains unexplored, despite their critical roles in forest ecosystems. Here, we investigated the population genetic structure and the demographic history of Rhizopogon togasawarius, the ECM fungus specifically colonizing the host tree Pseudotsuga japonica, across its entire distribution range (>200 km). These two species are designated as endangered species on the IUCN Red List since they are found only in small, fragmented forests in Japan. We analysed 236 R. togasawarius individuals from five remaining populations across the Kii Peninsula and the Shikoku Island, separated by a sea channel. Simple sequence repeat analyses using 20 loci revealed strong genetic differentiation among populations (FST = 0.255), even significant in the nearest population pair separated by a distance of only 8 km (FST = 0.075), indicating extremely limited gene flow between populations. DIYABC‐RF analyses implied that population divergence occurred approximately 6000 generations ago between the two regions, and nearly 1500 generations ago between the nearest populations within Shikoku Island, related to past climate events. Because of prolonged genetic isolation, significant inbreeding was confirmed in four of five populations, where effective population sizes became very small (Ne = 9.0–58.0). Although evaluation of extinction risks for microorganisms is challenging, our conservation genetic results indicated that habitat fragmentation increases extinction risk through population genetic mechanisms, and therefore should not be overlooked in biodiversity conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2024

6. Contrasting Genomic Diversity and Inbreeding Levels Among Two Closely Related Falcon Species With Overlapping Geographic Distributions.

Author

Martin, Audrey M., Johnson, Jeff A., Berry, Robert B., Carling, Matthew, and Martínez del Rio, Carlos

Abstract

ABSTRACT Genomic resources are valuable to examine historical demographic patterns and their effects to better inform management and conservation of threatened species. We evaluated population trends and genome‐wide variation in the near‐threatened Orange‐breasted Falcon (Falco deiroleucus) and its more common sister species, the Bat Falcon (F. rufigularis), to explore how the two species differ in genomic diversity as influenced by their contrasting long‐term demographic histories. We generated and aligned whole genome resequencing data for 12 Orange‐breasted Falcons and 9 Bat Falcons to an annotated Gyrfalcon (F. rusticolus) reference genome that retained approximately 22.4 million biallelic autosomal SNPs (chromosomes 1–22). Our analyses indicated much lower genomic diversity in Orange‐breasted Falcons compared to Bat Falcons. All sampled Orange‐breasted Falcons were significantly more inbred than the sampled Bat Falcons, with values similar to those observed in island‐mainland species comparisons. The distribution of runs of homozygosity showed variation suggesting long‐term low population size and the possibility of bottlenecks in Orange‐breasted Falcons contrasting with consistently larger populations in Bat Falcons. Analysis of genetic load suggests that Orange‐breasted Falcons are less likely to experience inbreeding depression than Bat Falcons due to reduced inbreeding load but are at elevated risk from fixation of deleterious gene variants and perhaps a reduced adaptive potential. These genomic analyses highlight differences in the historical demography of two closely related species that have influenced their current genomic diversity and should result in differing strategies for their continued conservation. [ABSTRACT FROM AUTHOR]

Published

2024

7. Population genomics of seal lice provides insights into the postglacial history of northern European seals.

Author

Sromek, Ludmila, Johnson, Kevin P., Kunnasranta, Mervi, Ylinen, Eeva, Virrueta Herrera, Stephany, Andrievskaya, Elena, Alexeev, Vyacheslav, Rusinek, Olga, Rosing‐Asvid, Aqqalu, and Nyman, Tommi

Subjects

*RINGED seal, *GRAY seal, *GENETIC variation, *CLIMATE change, *LICE, *SUBSPECIES, *GENE flow

Abstract

Genetic analyses of host‐specific parasites can elucidate the evolutionary histories and biological features of their hosts. Here, we used population‐genomic analyses of ectoparasitic seal lice (Echinophthirius horridus) to shed light on the postglacial history of seals in the Arctic Ocean and the Baltic Sea region. One key question was the enigmatic origin of relict landlocked ringed seal populations in lakes Saimaa and Ladoga in northern Europe. We found that that lice of four postglacially diverged subspecies of the ringed seal (Pusa hispida) and Baltic gray seal (Halichoerus grypus), like their hosts, form genetically differentiated entities. Using coalescent‐based demographic inference, we show that the sequence of divergences of the louse populations is consistent with the geological history of lake formation. In addition, local effective population sizes of the lice are generally proportional to the census sizes of their respective seal host populations. Genome‐based reconstructions of long‐term effective population sizes revealed clear differences among louse populations associated with gray versus ringed seals, with apparent links to Pleistocene and Holocene climatic variation as well as to the isolation histories of ringed seal subspecies. Interestingly, our analyses also revealed ancient gene flow between the lice of Baltic gray and ringed seals, suggesting that the distributions of Baltic seals overlapped to a greater extent in the past than is the case today. Taken together, our results demonstrate how genomic information from specialized parasites with higher mutation and substitution rates than their hosts can potentially illuminate finer scale population genetic patterns than similar data from their hosts. [ABSTRACT FROM AUTHOR]

Published

2024

8. A comparison of genomic diversity and demographic history of the North Atlantic and Southwest Atlantic southern right whales.

Author

Crossman, Carla A., Fontaine, Michael C., and Frasier, Timothy R.

Subjects

*WHOLE genome sequencing, *CONSERVATION genetics, *WHALING, *POPULATION genetics, *GENETIC variation, *INBREEDING

Abstract

Right whales (genus Eubalaena) were among the first, and most extensively pursued, targets of commercial whaling. However, understanding the impacts of this persecution requires knowledge of the demographic histories of these species prior to exploitation. We used deep whole genome sequencing (~40×) of 12 North Atlantic (E. glacialis) and 10 Southwest Atlantic southern (E. australis) right whales to quantify contemporary levels of genetic diversity and infer their demographic histories over time. Using coalescent‐ and identity‐by‐descent–based modelling to estimate ancestral effective population sizes from genomic data, we demonstrate that North Atlantic right whales have lived with smaller effective population sizes (Ne) than southern right whales in the Southwest Atlantic since their divergence and describe the decline in both populations around the time of whaling. North Atlantic right whales exhibit reduced genetic diversity and longer runs of homozygosity leading to higher inbreeding coefficients compared to the sampled population of southern right whales. This study represents the first comprehensive assessment of genome‐wide diversity of right whales in the western Atlantic and underscores the benefits of high coverage, genome‐wide datasets to help resolve long‐standing questions about how historical changes in effective population size over different time scales shape contemporary diversity estimates. This knowledge is crucial to improve our understanding of the right whales' history and inform our approaches to address contemporary conservation issues. Understanding and quantifying the cumulative impact of long‐term small Ne, low levels of diversity and recent inbreeding on North Atlantic right whale recovery will be important next steps. [ABSTRACT FROM AUTHOR]

Published

2024

9. Mitochondrial Genetic Diversity and Demographic History of Critically Endangered Oreochromis karongae (Trewavas, 1941) Along Lake Nyasa, Tanzania.

Author

Nehemia, Alex and Mwakalesi, Alinanuswe J.

Subjects

*ENDANGERED species listing, *CYTOCHROME oxidase, *ENDANGERED species, *GENETIC variation, *FISH as food

Abstract

Fish provide food and income opportunities for millions of people in Lake Nyasa, also known as Lake Malawi in Malawi and Lake Niassa in Mozambique. Oreochromis karongae (Trewavas, 1941), which is native to Lake Nyasa, Lake Malombe and the Shire River, is at the verge of extinction and has been listed as critically endangered species by the International Union for Conservation of Nature (IUCN), primarily due to overfishing. Using 632 bp of partial mitochondrial cytochrome oxidase subunit I (COI) sequences from 115 samples, this work aims to assess the population genetic status and demographic history of this species to better manage and advance its conservation. The analysis of molecular variance (AMOVA) revealed a low and non‐significant genetic differentiation index across the populations under study (ΦST = 0.003, p = 0.278), indicating a lack of population genetic structure. Phylogenetic analysis, grouped together all COI haplotypes of O. karongae from the six sampled sites. Nonetheless, the results showed signs of population expansion from a historic bottleneck, consistent with most data from the Western Indian Ocean Fauna. The findings from this study could be used to improve management and conservation strategies for critically endangered O. karongae in Lake Nyasa. [ABSTRACT FROM AUTHOR]

Published

2024

10. Demographic History and Inbreeding in Two Declining Sea Duck Species Inferred From Whole‐Genome Sequence Data.

Author

Cádiz, María I., Tengstedt, Aja Noersgaard Buur, Sørensen, Iben Hove, Pedersen, Emma Skindbjerg, Fox, Anthony David, and Hansen, Michael M.

Subjects

*MATING grounds, *MARKOV spectrum, *ANTHROPOGENIC effects on nature, *ENDANGERED species, *WILDLIFE conservation, *INBREEDING

Abstract

Anthropogenic impact has transitioned from threatening already rare species to causing significant declines in once numerous organisms. Long‐tailed duck (Clangula hyemalis) and velvet scoter (Melanitta fusca) were once important quarry sea duck species in NW Europe, but recent declines resulted in their reclassification as vulnerable on the IUCN Red List. We sequenced and assembled genomes for both species and resequenced 15 individuals of each. Using analyses based on site frequency spectra and sequential Markovian coalescence, we found C. hyemalis to show more historical demographic stability, whereas M. fusca was affected particularly by the Last (Weichselian) Glaciation. This likely reflects C. hyemalis breeding continuously across the Arctic, with cycles of glaciation primarily shifting breeding areas south or north without major population declines, whereas the more restricted southern range of M. fusca would lead to significant range contraction during glaciations. Both species showed evidence of declines over the past thousands of years, potentially reflecting anthropogenic pressures with the recent decline indicating an accelerated process. Analysis of runs of homozygosity (ROH) showed low but nontrivial inbreeding, with FROH from 0.012 to 0.063 in C. hyemalis and ranging from 0 to 0.047 in M. fusca. Lengths of ROH suggested that this was due to ongoing background inbreeding rather than recent declines. Overall, despite demographically important declines, this has not yet led to strong inbreeding and genetic erosion, and the most pressing conservation concern may be the risk of density‐dependent (Allee) effects. We recommend monitoring of inbreeding using ROH analysis as a cost‐efficient method to track future developments to support effective conservation of these species. [ABSTRACT FROM AUTHOR]

Published

2024

11. Climatic fluctuations, geographic features, and evolutionary forces: Shaping high genomic diversity and local adaptation in Muntiacus reevesi.

Author

Chen, Guotao, Sun, Zhonglou, Shi, Wenbo, Wang, Hui, Shi, Guohui, Hu, Yibo, Fan, Huizhong, Wu, Qi, and Zhang, Baowei

Subjects

*BIOLOGICAL evolution, *POPULATION differentiation, *POPULATION genetics, *GENETIC variation, *CLIMATE change

Abstract

Aim: Genetic diversity is crucial for species adaptability. Understanding the mechanisms behind its formation and maintenance is essential for effective conservation. Recent studies have demonstrated that despite experiencing severe population bottlenecks, Muntiacus reevesi retains high genetic diversity and continues its northward migration, indicative of ongoing adaptive evolution. However, our comprehension of this phenomenon remains incomplete. The objective of this study is to explore the mechanisms underlying the formation of high genetic diversity and the genomic characteristics associated with local adaptation, using M. reevesi as a case study. Location: Southern China. Methods: We analysed resequencing data from 62 genomes and identified 29,124,081 high‐quality single‐nucleotide polymorphisms (SNPs). We used population genetics, demographic history, population differentiation, gene flow analysis software, and genotype‐environment association (GEA) models to assess the factors that have contributed to high genetic diversity and environmental adaptability in the historical climate and geographical context. Results: The study identified that during Pleistocene climatic fluctuations, M. reevesi diverged into eastern (DB and WJW populations) and western lineages (WL, BA, and QL populations), all displayed high genetic diversity. Historically, M. reevesi maintained large effective populations, but contemporary human‐induced threats have led to a significant decline. Population differentiation models suggest distinct expansion pathways for eastern and western lineages, resulting in population admixture, with mountain corridors facilitating gene flow and maintaining high genetic diversity. Additionally, environmental‐genotype analysis revealed local adaptation in the QL‐BA population, highlighting candidate adaptive genes (ME3 and PRKG1) potentially linked to cold adaptation and foraging behaviour. Conclusion: This study enhances our understanding of the mechanisms behind the high genetic diversity and environmental adaptability of M. reevesi, offering insights into how bottleneck populations maintain diversity, crucial for biogeographic research and conservation strategies for similar species. [ABSTRACT FROM AUTHOR]

Published

2024

12. Forest genomics in the Caucasus through the lens of its dominant tree species – Fagus orientalis.

Author

Capblancq, Thibaut, Sękiewicz, Katarzyna, and Dering, Monika

Subjects

*GENETIC load, *LAST Glacial Maximum, *GENETIC variation, *GLACIATION, *TEMPERATE forests

Abstract

The last glacial period is known to have greatly influenced the demographic history of temperate forest trees, with important range contractions and post‐glacial expansions that led to the formation of multiple genetic lineages and secondary contact zones in the Northern Hemisphere. These dynamics have been extensively studied for European and North American species but are still poorly understood in other temperate regions of rich biodiversity such as the Caucasus. Our study helps filling that gap by deciphering the genomic landscapes of F. orientalis across the South Caucasus. The use of genome‐wide data confirmed a past demographic history strongly influenced by the Last Glacial Maximum, revealing two disjunct glacial refugia in the Colchis and Hyrcanian regions. The resulting patterns of genetic diversity, load and differentiation are not always concordant across the region, with genetic load pinpointing the location of the glacial refugia more efficiently than genetic diversity alone. The Hyrcanian forests show depleted genetic diversity and substantial isolation, even if long‐distance gene flow is still present with the main centre of diversity in the Greater Caucasus. Finally, we characterize a strong heterogeneity of genetic diversity and differentiation along the species chromosomes, with noticeably a first chromosome showing low diversity and weak differentiation. [ABSTRACT FROM AUTHOR]

Published

2024

13. Biogeography of larches in eastern Siberia – using single nucleotide polymorphisms derived by genotyping by sequencing.

Author

Haupt, Sarah, Bernhardt, Nadine, Killing, Stefanie, Meucci, Stefano, Herzschuh, Ulrike, Zakharov, Evgenii S., Harpke, Dörte, Pestryakova, Luidmila A., and Kruse, Stefan

Subjects

*SINGLE nucleotide polymorphisms, *LAST Glacial Maximum, *BIOGEOGRAPHY, *LARCHES, *PHYLOGEOGRAPHY, *TAIGAS

Abstract

The present distribution of Siberian boreal forests that are dominated by larches (Larix spp.) is influenced, to an unknown extent, by glacial history. Knowing the past treeline dynamics can improve our understanding of future treeline shifts under changing climate. Here, we study patterns in the genetic variability of Siberian Larix to help unravel biogeographic migration routes since the Last Glacial Maximum (LGM). We infer the spatial distribution and the postglacial demographic history of Larix using genome‐wide single nucleotide polymorphisms (SNPs) derived through genotyping by sequencing (GBS) from 130 individuals sampled across eastern Siberia. Our analysis gives statistical support for two or three clusters, spanning from western to eastern Siberia. These clusters reveal a genetic structure influenced by isolation resulting from geographical distance, barriers imposed by geographic features, and distinct glacial histories. Assuming three clusters, our demographic inference indicates that the common ancestor of the current Larix populations existed in northeast Siberia well before the LGM. This suggests that Larix persisted in the northern region throughout previous glacials. Our genetic studies suggest that Larix likely survived the cold LGM in northern refugia, enabling a fast colonization of Siberia. Instead of complete repopulation from southern areas postglacially, the northernmost Larix expansion during the Holocene seems to have benefitted from refugial populations ahead of the treeline. Present‐day migration is expected to be slow initially, due to the absence of current refugial populations in the far north, in contrast to the early‐Holocene situation. [ABSTRACT FROM AUTHOR]

Published

2024

14. Pushed waves, trailing edges, and extreme events: Eco‐evolutionary dynamics of a geographic range shift in the owl limpet, Lottia gigantea.

Author

Nielsen, Erica S., Walkes, Samuel, Sones, Jacqueline L., Fenberg, Phillip B., Paz‐García, David A., Cameron, Brenda B., Grosberg, Richard K., Sanford, Eric, and Bay, Rachael A.

Subjects

*LAST Glacial Maximum, *MARINE heatwaves, *LATITUDE, *MARINE invertebrates, *CLIMATE change

Abstract

As climatic variation re‐shapes global biodiversity, understanding eco‐evolutionary feedbacks during species range shifts is of increasing importance. Theory on range expansions distinguishes between two different forms: "pulled" and "pushed" waves. Pulled waves occur when the source of the expansion comes from low‐density peripheral populations, while pushed waves occur when recruitment to the expanding edge is supplied by high‐density populations closer to the species' core. How extreme events shape pushed/pulled wave expansion events, as well as trailing‐edge declines/contractions, remains largely unexplored. We examined eco‐evolutionary responses of a marine invertebrate (the owl limpet, Lottia gigantea) that increased in abundance during the 2014–2016 marine heatwaves near the poleward edge of its geographic range in the northeastern Pacific. We used whole‐genome sequencing from 19 populations across >11 degrees of latitude to characterize genomic variation, gene flow, and demographic histories across the species' range. We estimated present‐day dispersal potential and past climatic stability to identify how contemporary and historical seascape features shape genomic characteristics. Consistent with expectations of a pushed wave, we found little genomic differentiation between core and leading‐edge populations, and higher genomic diversity at range edges. A large and well‐mixed population in the northern edge of the species' range is likely a result of ocean current anomalies increasing larval settlement and high‐dispersal potential across biogeographic boundaries. Trailing‐edge populations have higher differentiation from core populations, possibly driven by local selection and limited gene flow, as well as high genomic diversity likely as a result of climatic stability during the Last Glacial Maximum. Our findings suggest that extreme events can drive poleward range expansions that carry the adaptive potential of core populations, while also cautioning that trailing‐edge extirpations may threaten unique evolutionary variation. This work highlights the importance of understanding how both trailing and leading edges respond to global change and extreme events. [ABSTRACT FROM AUTHOR]

Published

2024

15. Genetic structure and demographic history of Anguilla bicolor from Tanzania based on mitochondrial cytochrome oxidase I sequence: Implications for effective management and conservation strategies.

Author

Elmy, Farhiya Ismail, Gaspare, Lydia, Mfilinge, Prosper Laurent, and Lusana, James Leonard

Subjects

POPULATION differentiation, MITOCHONDRIA, GENE flow, HAPLOTYPES, WATERSHEDS, FISHERY management, CYTOCHROME oxidase

Abstract

A genetic analysis was conducted on Anguilla bicolor from Tanzania using the mitochondrial COI region. The study aimed to understand the population genetic structure and demographic history of A. bicolor. In this study, 42 samples of A. bicolor were collected from the Lower Rufiji River Basin and Pangani River in Tanzania between January and June 2023. The mtDNA COI sequences of 65 A. bicolor from various Indo‐Pacific countries were retrieved from GenBank. 2.The findings revealed an overall high haplotype diversity (0.83 ± 0.033) and moderate nucleotide diversity (0.63% ± 0.000).A limited genetic differentiation between populations was observed (FST = −0.00322, p = 0.0494), indicating gene flow, leading to an absence of population structure. The haplotype network tree also supported a panmictic stock in the Indo‐Pacific region with 44 haplotypes clustered around three principal haplotypes.Furthermore, the significantly overall negative values of both Tajima's D (−2.27, p = 0.002) and Fu's Fs (−26.36, p = 0.000) and the multimodal mismatch distribution suggested the presence of multiple demographic events in A. bicolor populations.Given the lack of substantial genetic structure among populations, managing the fishery as a single‐stock unit is advised, aligning with the current fisheries management practices in Tanzania. It is also crucial to ensure habitat quality along migratory paths to facilitate genetic exchange and long‐term species viability. [ABSTRACT FROM AUTHOR]

Published

2024

16. Evolutionary radiation of the Eurasian Pinus species under pervasive gene flow.

Author

Zhao, Wei, Gao, Jie, Hall, David, Andersson, Bea Angelica, Bruxaux, Jade, Tomlinson, Kyle W., Drouzas, Andreas D., Suyama, Yoshihisa, and Wang, Xiao‐Ru

Subjects

*GENE flow, *PINE, *CLIMATIC zones, *SPECIES, *RADIATION, *PINACEAE

Abstract

Summary: Evolutionary radiation, a pivotal aspect of macroevolution, offers valuable insights into evolutionary processes. The genus Pinus is the largest genus in conifers with c. 90% of the extant species emerged in the Miocene, which signifies a case of rapid diversification. Despite this remarkable history, our understanding of the mechanisms driving radiation within this expansive genus has remained limited.Using exome capture sequencing and a fossil‐calibrated phylogeny, we investigated the divergence history, niche diversification, and introgression among 13 closely related Eurasian species spanning climate zones from the tropics to the boreal Arctic.We detected complex introgression among lineages in subsection Pinus at all stages of the phylogeny. Despite this widespread gene exchange, each species maintained its genetic identity and showed clear niche differentiation. Demographic analysis unveiled distinct population histories among these species, which further influenced the nucleotide diversity and efficacy of purifying and positive selection in each species.Our findings suggest that radiation in the Eurasian pines was likely fueled by interspecific recombination and further reinforced by their adaptation to distinct environments. Our study highlights the constraints and opportunities for evolutionary change, and the expectations of future adaptation in response to environmental changes in different lineages. [ABSTRACT FROM AUTHOR]

Published

2024

17. Multiple introductions of divergent lineages and admixture conferred the high invasiveness in a widespread weed (Hypochaeris radicata).

Author

Lee, Soo‐Rang, Choi, Tae‐Young, and Son, Dong‐Chan

Subjects

*NOXIOUS weeds, *GENETIC variation, *BIOLOGICAL invasions, *WEEDS, *DEMOGRAPHIC change

Abstract

Biological invasion consists of spatially and temporally varying stages, accompanied by ecological and evolutionary changes. Understanding the genomics underlying invasion dynamics provides critical insights into the geographic sources and genetic diversity, contributing to successful invasions across space and time. Here, we used genomic data and model‐based approaches to characterize the invasion dynamics of Hypochaeris radicata L., a noxious weed in Korea. Genetic diversity and assignment patterns were investigated using 3563 SNPs of 283 individuals sampled from 22 populations. We employed a coalescent‐based simulation method to estimate demographic changes for each population and inferred colonization history using both phylogenetic and population genetic model‐based approaches. Our data suggest that H. radicata has been repeatedly been introduced to Korea from multiple genetic sources within the last 50 years, experiencing weak population bottlenecks followed by subsequent population expansions. These findings highlight the potential for further range expansion, particularly in the presence of human‐mediated dispersal. Our study represents the first population‐level genomic research documenting the invasion dynamics of the successful worldwide invader, H. radicata, outside of Europe. [ABSTRACT FROM AUTHOR]

Published

2024

18. The phylogenetic relationship and demographic history of rhesus macaques (Macaca mulatta) in subtropical and temperate regions, China.

Author

Zhou, Yanyan, Tian, Jundong, Han, Mengya, and Lu, Jiqi

Subjects

*RHESUS monkeys, *MACAQUES, *ANIMAL diversity, *GLACIATION, *PLEISTOCENE Epoch

Abstract

Pleistocene climatic oscillations exerted significant influences on the genetic structure and demography of rhesus macaque (Macaca mulatta) in eastern China. However, the evolutionary history of rhesus macaques in subtropical and temperate China remained unclear and/or controversial. Herein, we analyzed the autosomes, mitochondrial genomes, and Y‐chromosomes from 84 individuals of Chinese rhesus macaque. The results revealed that (1) all individuals were clustered into pan‐west and pan‐east genetic groups, which exhibited Shaanxi Province as the northernmost region of western dispersal route of rhesus macaques in China; (2) in subtropical and temperate China, rhesus macaques were divided into four lineages (TH, DB, HS, and QL), and their divergence times corresponded to the Penultimate Glaciation (300–130 kya) and Last Glaciation (70–10 kya), respectively; (3) the individuals from Mt. Taihangshan (TH) are closely related to individuals from Mt. Dabashan (DB) in the autosomal tree, rather than individuals from Mt. Huangshan (HS) as indicated by the mitogenome tree, which supports the hypothesis that the ancestral rhesus macaques radiated into Mt. Taihangshan from Mt. Huangshan via Mt. Dabashan; and (4) the demographic scenario of the four lineages showed the ancestral rhesus macaques bottleneck and expansion corresponding to the suitable habitat reduction and expansion, which confirmed they had experienced northward recolonization and southward retreat events from Mt. Huangshan area via Northern China Plain to Northernmost China along with Pleistocene glacial cycles. This study provides a new insight into understanding how Pleistocene glaciation has influenced faunal diversity in subtropical and temperate China, especially for those exhibiting differential patterns of sex dispersal. [ABSTRACT FROM AUTHOR]

Published

2024

19. Living on the edge—Genomic and ecological delineation of cryptic lineages in the high‐elevation specialist Erebia nivalis.

Author

Augustijnen, Hannah, Patsiou, Theofania, Schmitt, Thomas, and Lucek, Kay

Subjects

*GENETIC variation, *GLOBAL warming, *INSECT conservation, *ALTITUDES, *SPECIES distribution

Abstract

Cold‐adapted species at high elevations may be especially impacted by global warming since they may be limited in their capacity to adapt to changing conditions or may be prevented from shifting their distributions upwards if no suitable habitats are available.The latter may be true for Erebia nivalis, a high‐elevation specialist that mainly occurs in the Austrian Alps and on few mountaintops in Switzerland, where its taxonomic and conservation status remains unclear.We aimed to clarify the relationships among geographically isolated populations of E. nivalis using whole‐genome resequencing data to reconstruct population connectivity and phylogenetic relationships. We inferred current and historical effective population sizes and combined these with tests for ecological differentiation based on available occurrence data to re‐evaluate the conservation status of E. nivalis.Our results confirm that Swiss and Austrian E. nivalis should be considered different evolutionarily significant units for conservation purposes, as they are marked by moderate genomic differentiation, distinct demographic histories and a difference in the abiotic conditions of their habitats.In both Austria and Switzerland, we found rapid uphill range shifts over the last decades, little population connectivity, low current effective population sizes and low genetic diversity. The above, combined with the low dispersal capacity of this 2‐year lifecycle species and its need to overwinter under snow, which is rapidly retreating from several regions of the Alps, leads us to suggest that the status of E. nivalis should be updated to 'Vulnerable' or 'Endangered' in the European, Swiss and Austrian Red Lists. [ABSTRACT FROM AUTHOR]

Published

2024

20. Local adaptation and demographic history of vulnerable conifer Cephalotaxus oliveri in southern China.

Author

Liu, Han‐Jing, Li, Ming‐Hui, Wang, Zhen, Wang, Ting, and Su, Ying‐Juan

Subjects

*POPULATION differentiation, *FOREST management, *LAST Glacial Maximum, *GENE expression, *GENETIC variation, *PHYSIOLOGICAL adaptation

Abstract

Having a comprehensive understanding of genetic differentiation, responses to environmental change and demographic history is critical for genetic improvement and conservation efforts. Forest trees are an excellent resource for understanding population differentiation and adaptive genetic variation due to their ability to adapt to different climates and environments. Cephalotaxus oliveri is a relict conifer endemic to China. In this study, we generated transcriptome data and identified 17 728 high‐quality single‐nucleotide polymorphisms (SNPs) from 18 populations. We found significant negative correlations between expression diversity and nucleotide diversity within and among populations, suggesting that gene expression and nucleotide diversity have a reciprocal relationship when the species adapts to the environment. The analyses of population structure showed that C. oliveri displayed a striking genetic structure with four groups. BayeScEnv and RDA methods detected the signatures of local adaptation, and identified that 738 outlier SNPs were associated with precipitation, temperature and soil conditions across heterogeneous environmental conditions. Approximate Bayesian computation analyses showed that the first and second divergence occurred in the late Miocene (c. 10.075 million years ago [Ma]) and the middle Pleistocene transition (c. 0.815 Ma), respectively. Ecological niche modeling of C. oliveri revealed signs of westward expansion after the last glacial maximum, while it was predicted to experience significant range contractions in future climate change scenarios. Geographical factors and environmental factors in southern China have played a critical role in establishing the current genetic diversity and population structure of C. oliveri. This study provides an important reference for forest resource management and conservation for C. oliveri. [ABSTRACT FROM AUTHOR]

Published

2024

21. Genomic insights on conservation priorities for North Sea houting and European lake whitefish (Coregonus spp.)

Author

Tengstedt, Aja Noersgaard Buur, Liu, Shenglin, Jacobsen, Magnus W., Gundlund, Camilla, Møller, Peter Rask, Berg, Søren, Bekkevold, Dorte, and Hansen, Michael M.

Abstract

Population genomics analysis holds great potential for informing conservation of endangered populations. We focused on a controversial case of European whitefish (Coregonus spp.) populations. The endangered North Sea houting is the only coregonid fish that tolerates oceanic salinities and was previously considered a species (C. oxyrhinchus) distinct from European lake whitefish (C. lavaretus). However, no firm evidence for genetic‐based salinity adaptation has been available. Also, studies based on microsatellite and mitogenome data suggested surprisingly recent divergence (c. 2500 years bp) between houting and lake whitefish. These data types furthermore have provided no evidence for possible inbreeding. Finally, a controversial taxonomic revision recently classified all whitefish in the region as C. maraena, calling conservation priorities of houting into question. We used whole‐genome and ddRAD sequencing to analyse six lake whitefish populations and the only extant indigenous houting population. Demographic inference indicated post‐glacial expansion and divergence between lake whitefish and houting occurring not long after the Last Glaciation, implying deeper population histories than previous analyses. Runs of homozygosity analysis suggested not only high inbreeding (FROH up to 30.6%) in some freshwater populations but also FROH up to 10.6% in the houting prompting conservation concerns. Finally, outlier scans provided evidence for adaptation to high salinities in the houting. Applying a framework for defining conservation units based on current and historical reproductive isolation and adaptive divergence led us to recommend that the houting be treated as a separate conservation unit regardless of species status. In total, the results underscore the potential of genomics to inform conservation practices, in this case clarifying conservation units and highlighting populations of concern. [ABSTRACT FROM AUTHOR]

Published

2024

22. C4 photosynthesis provided an immediate demographic advantage to populations of the grass Alloteropsis semialata.

Author

Sotelo, Graciela, Gamboa, Sara, Dunning, Luke T., Christin, Pascal‐Antoine, and Varela, Sara

Subjects

*CARBON 4 photosynthesis, *PLANT evolution, *PALEOCLIMATOLOGY

Abstract

Summary: C4 photosynthesis is a key innovation in land plant evolution, but its immediate effects on population demography are unclear. We explore the early impact of the C4 trait on the trajectories of C4 and non‐C4 populations of the grass Alloteropsis semialata.We combine niche models projected into paleoclimate layers for the last 5 million years with demographic models based on genomic data.The initial split between C4 and non‐C4 populations was followed by a larger expansion of the ancestral C4 population, and further diversification led to the unparalleled expansion of descendant C4 populations. Overall, C4 populations spread over three continents and achieved the highest population growth, in agreement with a broader climatic niche that rendered a large potential range over time. The C4 populations that remained in the region of origin, however, experienced lower population growth, rather consistent with local geographic constraints. Moreover, the posterior transfer of some C4‐related characters to non‐C4 counterparts might have facilitated the recent expansion of non‐C4 populations in the region of origin.Altogether, our findings support that C4 photosynthesis provided an immediate demographic advantage to A. semialata populations, but its effect might be masked by geographic contingencies. [ABSTRACT FROM AUTHOR]

Published

2024

23. Global genetic diversity and historical demography of the Bull Shark.

Author

Postaire, Bautisse D., Devloo‐Delva, Floriaan, Brunnschweiler, Juerg M., Charvet, Patricia, Chen, Xiao, Cliff, Geremy, Daly, Ryan, Drymon, J. Marcus, Espinoza, Mario, Fernando, Daniel, Glaus, Kerstin, Grant, Michael I., Hernandez, Sebastian, Hyodo, Susumu, Jabado, Rima W., Jaquemet, Sébastien, Johnson, Grant, Naylor, Gavin J. P., Nevill, John E. G., and Pathirana, Buddhi M.

Subjects

*DEMOGRAPHY, *GENETIC variation, *PREDATORY aquatic animals, *WHOLE genome sequencing, *SHARKS, *NUCLEOTIDE sequencing, *MOBILE genetic elements

Abstract

Aim: Biogeographic boundaries and genetic structuring have important effects on the inferences and interpretation of effective population size (Ne) temporal variations, a key genetics parameter. We reconstructed the historical demography and divergence history of a vulnerable coastal high‐trophic shark using population genomics and assessed our ability to detect recent bottleneck events. Location: Western and Central Indo‐Pacific (IPA), Western Tropical Atlantic (WTA) and Eastern Tropical Pacific (EPA). Taxon: Carcharhinus leucas (Müller & Henle, 1839). Methods: A DArTcap™ approach was used to sequence 475 samples and assess global genetic structuring. Three demographic models were tested on each population, using an ABC‐RF framework coupled with coalescent simulations, to investigate within‐cluster structure. Divergence times between clusters were computed, testing multiple scenarios, with fastsimcoal. Ne temporal variations were reconstructed with STAIRWAYPLOT. Coalescent simulations were performed to determine the detectability of recent bottleneck under the estimated historical trend for datasets of this size. Results: Three genetic clusters corresponding to the IPA, WTA and EPA regions were identified, agreeing with previous studies. The IPA presented the highest genetic diversity and was consistently identified as the oldest. No significant within‐cluster structuring was detected. Ne increased globally, with an earlier onset in the IPA, during the last glacial period. Coalescent simulations showed that weak and recent bottlenecks could not be detected with our dataset, while old and/or strong bottlenecks would erase the observed ancestral expansion. Main Conclusions: This study further confirms the role of marine biogeographic breaks in shaping the genetic history of large mobile marine predators. Ne historical increases in Ne are potentially linked to extended coastal habitat availability. The limited within‐cluster population structuring suggests that Ne can be monitored over ocean basins. Due to insufficient amount of available genetic data, it cannot be concluded whether overfishing is impacting Bull Shark genetic diversity, calling for whole‐genome sequencing. [ABSTRACT FROM AUTHOR]

Published

2024

24. A renewed glance at the Palearctic golden eagle: Genetic variation in space and time.

Author

Karabanina, Ekaterina, Lansink, Gerhardus M. J., Ponnikas, Suvi, and Kvist, Laura

Subjects

*GOLDEN eagle, *GENETIC variation, *POPULATION genetics, *PALEARCTIC, *MITOCHONDRIAL DNA, *CHLOROPLAST DNA

Abstract

Anthropogenic pressures on nature have been causing population declines for centuries. Intensified persecution of apex predators, like the golden eagle, resulted in population bottlenecks during the 19th and 20th centuries. To study population genetics and demographic history of the golden eagle throughout its distribution, we collected museum samples from previously underrepresented regions, such as Russia and Central Asia. We used 12 microsatellite loci and a fragment of the mitochondrial DNA control region to re‐evaluate phylogeography of Eurasian golden eagles and study the impacts of the population bottleneck. Our results revealed a north–south genetic gradient, expressed by the difference between Mediterranean and Holarctic lineages, as well as genetically distinct Northern Europe and Central Asia and Caucasus regions. Furthermore, Northern Europe exhibited the lowest, whereas Central Asia and Caucasus had the highest genetic diversity. Although golden eagles maintained relatively high genetic diversity, we detected genetic signatures of the recent bottleneck, including reduced genetic diversity and a decline in the effective female population size around the year 1975. Our study improves the knowledge of the genetic composition of Eurasian golden eagles and highlights the importance of understanding their historical population dynamics in the face of ongoing and future conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2024

25. Reconstructing the complex colonisation histories of lizards across Mediterranean archipelagos.

Author

Sherpa, Stéphanie, Salvi, Daniele, Silva‐Rocha, Iolanda, Capblancq, Thibaut, Paris, Josephine R., Carretero, Miguel Angel, and Ficetola, Gentile Francesco

Subjects

*ARCHIPELAGOES, *LACERTIDAE, *COLONIZATION (Ecology), *LIZARDS, *GENE flow

Abstract

Aim: The Mediterranean Basin is a global biodiversity hotspot and has one of the longest histories of human–biota interactions. Islands host a large fraction of Mediterranean diversity and endemism, but the relative importance of natural versus human‐mediated colonisation processes in shaping the distribution and genetic structure of Mediterranean island fauna remains poorly understood. Here, we combine population genomics, demographic models and palaeoshoreline reconstructions to establish the island‐colonisation dynamics of wall lizards in Mediterranean archipelagos. Location: Four Mediterranean archipelagos in Italy and Croatia. Taxon: The wall lizard Podarcis siculus. Methods: We used ddRAD sequencing to genotype 140 lizards from 23 island and mainland populations. Analyses of admixture and site frequency spectra were used to reconstruct population structure, demographic history and variation of gene flow through time. Genomic results were integrated with palaeogeographical reconstructions and were compared to archaeological evidence of human presence on these islands. Results: Although many island populations of this species are assumed to be non‐native, we find that many islands were colonised long before any known human settlements (230,000–12,000 years ago). This natural colonisation most likely occurred through land bridges during glacial marine regression or by over‐sea rafting. On the other hand, islands distant from the continent were often colonised recently, and some of the estimated island colonisation times match historical records of human arrival. We also determine that long‐established island populations generally show lower genetic diversity compared to proximate mainland populations, contrary to recently colonised islands that must have experienced higher rates of post‐colonisation gene flow. Main Conclusion: Our integrated approach provides us with the power to accurately quantify the origin, timing and mode of island colonisation. This framework helps to clarify the biogeographical and evolutionary history of island populations, with important implications for conservation and management of island biodiversity. [ABSTRACT FROM AUTHOR]

Published

2024

26. Genomic evidence for climatic adaptation in Fejervarya multistriata.

Author

Lei, Zhaoxia, Yan, Chaochao, Jin, Long, Li, Jiatang, Yan, Chengzhi, and Liao, Wenbo

Subjects

*CLIMATE change adaptation, *NATURAL selection, *PHYSIOLOGICAL adaptation, *GENETIC variation, *INTERGLACIALS, *AMPHIBIAN populations, *COLD adaptation, *CLIMATE change

Abstract

Aim: Genetic diversity driven by natural selection contributes to population divergence in amphibians, thus facilitating local adaptation to climate change. Understanding the mechanisms of genetic adaptation is one of the important issues in evolutionary biology. This study set out to reveal drivers responsible for intraspecific divergence in Fejervarya multistriata and further investigate the potential involvement of selected genes in responding to climate challenges. Location: China. Method: To identify adaptive traits associated with climate change, we conducted genome RAD‐seq of 300 F. multistriata individuals from 15 locations across a bio‐geographical range with gradual climatic variation in China. Results: The results indicate a substantial genetic diversity among populations of F. multistriata and highlight specific genes and pathways that likely contribute to intraspecific divergence. The demographic history of F. multistriata can be traced back to the last interglacial period, during which elevated temperatures may have led to a significant decline in effective population size. The analysis of genome‐climate association identified five candidate genes (BMP2K, NRAP, ZW10, MYH1 and PLB1) potentially involved in local climate adaptation. Main Conclusions: Our findings have shed light on the genetic mechanisms of local adaptation to climate change in F. multistriata, thereby aiding in determining the possible fate of populations under future climate change. [ABSTRACT FROM AUTHOR]

Published

2024

27. Exploring coral speciation: Multiple sympatric Stylophora pistillata taxa along a divergence continuum on the Great Barrier Reef.

Author

Meziere, Zoe, Popovic, Iva, Prata, Katharine, Ryan, Isobel, Pandolfi, John, and Riginos, Cynthia

Subjects

*SYMPATRIC speciation, *CORALS, *CORAL bleaching, *CORAL reefs & islands, *CORAL reef restoration, *REEFS, *NUMBERS of species

Abstract

Understanding how biodiversity originates and is maintained are fundamental challenge in evolutionary biology. Speciation is a continuous process and progression along this continuum depends on the interplay between evolutionary forces driving divergence and forces promoting genetic homogenisation. Coral reefs are broadly connected yet highly heterogeneous ecosystems, and divergence with gene flow at small spatial scales might therefore be common. Genomic studies are increasingly revealing the existence of closely related and sympatric taxa within taxonomic coral species, but the extent to which these taxa might still be exchanging genes and sharing environmental niches is unclear. In this study, we sampled extensively across diverse habitats at multiple reefs of the Great Barrier Reef (GBR) and comprehensively examined genome‐wide diversity and divergence histories within and among taxa of the Stylophora pistillata species complex. S. pistillata is one of the most abundant and well‐studied coral species, yet we discovered five distinct taxa, with wide geographic ranges and extensive sympatry. Demographic modelling showed that speciation events have occurred with gene flow and that taxa are at different stages along a divergence continuum. We found significant correlations between genetic divergence and specific environmental variables, suggesting that niche partitioning may have played a role in speciation and that S. pistillata taxa might be differentially adapted to different environments. Conservation actions rely on estimates of species richness, population sizes and species ranges, which are biased if divergent taxa are lumped together. As coral reefs are rapidly degrading due to climate change, our study highlights the importance of recognising evolutionarily distinct and differentially adapted coral taxa to improve conservation and restoration efforts aiming at protecting coral genetic diversity. [ABSTRACT FROM AUTHOR]

Published

2024

28. Applying genomic approaches to identify historic population declines in European forest bats.

Author

Razgour, Orly, Montauban, Cecilia, Festa, Francesca, Whitby, Daniel, Juste, Javier, Ibáñez, Carlos, Rebelo, Hugo, Afonso, Sandra, Bekaert, Michael, Jones, Gareth, Williams, Carol, and Boughey, Katherine

Subjects

*FOREST declines, *DEMOGRAPHIC change, *WILDLIFE conservation, *GENETIC variation, *BATS, *ANIMAL populations, *INBREEDING, *ENDANGERED species

Abstract

Anthropogenically driven environmental changes over recent centuries have led to severe declines of wildlife populations. Better tools are needed to assess the magnitude and consequences of these declines. Anecdotal evidence suggests European bat populations have suffered substantial declines in the past centuries. However, there is little empirical evidence of these declines that can be used to put more recent population trends into historic context.This study is a collaboration between academics and conservation practitioners to develop molecular approaches capable of providing evidence of historic population changes that can inform conservation status assessments and management. We generated a genomic dataset of 46,872 SNPs for the Western barbastelle, Barbastella barbastellus, a regionally Vulnerable bat species, including colonies from across the species' British and Iberian ranges. We used a combination of landscape genetics and model‐based inference of demographic history to identify both evidence of population size changes and possible drivers of these changes.Levels of genetic diversity increased and inbreeding decreased with increasing broadleaf woodland cover around the colony. Genetic connectivity was impeded by artificial lights and facilitated by rivers and broadleaf woodland cover.The demographic history analysis showed that both the northern and southern British barbastelle populations have declined by 99% over the past 330–548 years. These declines may be linked to the loss of large oak trees and native woodlands due to shipbuilding during the early colonial period.Synthesis and applications. Genomic approaches can provide a better understanding of the conservation status of threatened species, within historic and contemporary contexts, and inform their conservation management. Our findings of will directly influence the definition of the Favourable Conservation Status of the barbastelle, in turn influencing considerations of the conservation of the species in development plans. Knowledge gained will also help set species recovery targets. Policymakers are interested in using our approach for other species. This study shows how we can bridge the implementation gap between genomic research and direct conservation applications. There is an urgent need to carry out such collaborative studies for other priority species to enable informed species recovery interventions via policy mechanisms and project delivery. [ABSTRACT FROM AUTHOR]

Published

2024

29. Genome sequences and population genomics provide insights into the demographic history, inbreeding, and mutation load of two 'living fossil' tree species of Dipteronia.

Author

Feng, Yu, Comes, Hans Peter, Chen, Jun, Zhu, Shanshan, Lu, Ruisen, Zhang, Xinyi, Li, Pan, Qiu, Jie, Olsen, Kenneth M., and Qiu, Yingxiong

Subjects

*GENETIC drift, *LAST Glacial Maximum, *NUCLEOTIDE sequencing, *QUATERNARY Period, *GENOMICS, *INBREEDING

Abstract

SUMMARY: 'Living fossils', that is, ancient lineages of low taxonomic diversity, represent an exceptional evolutionary heritage, yet we know little about how demographic history and deleterious mutation load have affected their long‐term survival and extinction risk. We performed whole‐genome sequencing and population genomic analyses on Dipteronia sinensis and D. dyeriana, two East Asian Tertiary relict trees. We found large‐scale genome reorganizations and identified species‐specific genes under positive selection that are likely involved in adaptation. Our demographic analyses suggest that the wider‐ranged D. sinensis repeatedly recovered from population bottlenecks over late Tertiary/Quaternary periods of adverse climate conditions, while the population size of the narrow‐ranged D. dyeriana steadily decreased since the late Miocene, especially after the Last Glacial Maximum (LGM). We conclude that the efficient purging of deleterious mutations in D. sinensis facilitated its survival and repeated demographic recovery. By contrast, in D. dyeriana, increased genetic drift and reduced selection efficacy, due to recent severe population bottlenecks and a likely preponderance of vegetative propagation, resulted in fixation of strongly deleterious mutations, reduced fitness, and continuous population decline, with likely detrimental consequences for the species' future viability and adaptive potential. Overall, our findings highlight the significant impact of demographic history on levels of accumulation and purging of putatively deleterious mutations that likely determine the long‐term survival and extinction risk of Tertiary relict trees. Significance Statement: The evolution of mutation load is a key genetic factor affecting species survival. Here we showed contrast patterns of mutation load of two 'living fossil' tree species. Our results highlight the significant impact of demographic history on levels of accumulation and purging of putatively deleterious mutations that likely determine the long‐term survival and extinction risk of Tertiary relict trees. [ABSTRACT FROM AUTHOR]

Published

2024

30. Genetic signatures of lineage fusion closely resemble population decline.

Author

Garrick, Ryan C.

Subjects

*DEMOGRAPHIC change, *HAPLOTYPES, *RESOURCE allocation

Abstract

Accurate interpretation of the genetic signatures of past demographic events is crucial for reconstructing evolutionary history. Lineage fusion (complete merging, resulting in a single panmictic population) is a special case of secondary contact that is seldom considered. Here, the circumstances under which lineage fusion can be distinguished from population size constancy, growth, bottleneck, and decline were investigated. Multi‐locus haplotype data were simulated under models of lineage fusion with different divergence versus sampling lag times (D:L ratios). These pseudo‐observed datasets also differed in their allocation of a fixed amount of sequencing resources (number of sampled alleles, haplotype length, number of loci). Distinguishability of lineage fusion versus each of 10 untrue non‐fusion scenarios was quantified based on six summary statistics (neutrality tests). Some datasets were also analyzed using extended Bayesian skyline plots. Results showed that signatures of lineage fusion very closely resemble those of decline—high distinguishability was generally limited to the most favorable scenario (D:L = 9), using the most sensitive summary statistics (FS and ZnS), coupled with the optimal sequencing resource allocation (maximizing number of loci). Also, extended Bayesian skyline plots often erroneously inferred population decline. Awareness of the potential for lineage fusion to carry the hallmarks of population decline is critical. [ABSTRACT FROM AUTHOR]

Published

2023

31. Evolutionary response of cold‐adapted chasmophytic plants to Quaternary climatic oscillations in the Mountains of Central Asia (a world hotspot of biodiversity).

Author

Nobis, Marcin, Klichowska, Ewelina, Vintsek, Lizaveta, Wróbel, Anna, Nobis, Agnieszka, Zalewska‐Gałosz, Joanna, and Nowak, Arkadiusz

Subjects

*GLOBAL warming, *POPULATION differentiation, *CLIMATE change, *MOLECULAR clock, *OSCILLATIONS, *COLD adaptation, *BIODIVERSITY

Abstract

Aim: Past climatic oscillations are the main driving force of evolutionary changes in alpine species. Species' response to paleoclimatic oscillations is crucial in forecasting their future response in face of climate warming. The aim of this research is to explore the effect of climatic fluctuations on the evolutionary history, demography, and distribution of high‐mountain bellflowers (Campanula lehmanniana complex), the flagship and taxonomically problematic members of chasmophytic vegetation within an underexplored biodiversity hotspot, the Mountains of Central Asia. Location: Central Asia (Tian Shan, Alai and Zeravshan‐Hissar Mountains). Methods: We used molecular data (ITS, cpDNA, DArTseq‐based SNPs) of 262 individuals (70 for the phylogeny reconstruction, and 247 from 31 localities for population studies). We analysed the data using phylogenetic and molecular clock reconstructions, coalescent simulations, and ecological niche modelling. Results: Tertiary isolation between the Tian‐Shanian and Pamir‐Alaian populations led to the differentiation of the two main lineages (~5–6 Mya) corresponding to C. eugeniae and C. lehmanniana, whereas further Quaternary isolation into subregions led to intraspecific genetic differentiation, which starts almost simultaneously for both species (~2.7–1.5 Mya). The relatively small genetic admixture among populations indicates rare historic events of connectivity. In response to Holocene warming, the analysed species experienced a substantial decline in effective population size. Currently, the distribution of both taxa is highly influenced by precipitation in the coldest and driest quarters. Main Conclusions: Our results highlight a general principle that glacial–interglacial cycles and contemporary island‐like habitats distribution, shape the genomic variation of high‐mountain species. The similar declining demographic trend of examined taxa may suggest the overall response to ongoing climate warming. The results underline also the urgent need for conservation action in alpine regions to preserve their biodiversity. [ABSTRACT FROM AUTHOR]

Published

2023

32. Population genetics and ecological niche modelling provide insights into management strategies of the herbivorous pest Phytomyza horticola (Diptera: Agromyzidae).

Author

Liang, Yongxuan, Du, Sujie, Jin, Zhenan, Xu, Shiyun, Wan, Weijie, Zhong, Yujun, Li, Qiao, Zhou, Qiong, Guo, Jianyang, and Liu, Wanxue

Subjects

*ECOLOGICAL genetics, *ECOLOGICAL niche, *PHYLOGEOGRAPHY, *POPULATION genetics, *ECOLOGICAL models, *LAST Glacial Maximum, *WAKEFULNESS

Abstract

Aim: Research on population genetic patterns and potential distribution dynamics can provide insights into the development of pest management strategies. Herein, we integrated population genetic analyses with the climatic niche approach to investigate spatial population genetic variations and potential geographical distribution (PGD) of the herbivorous pest Phytomyza horticola. We also analysed its population response patterns to both late Pleistocene climatic events and future climate change. Location: China. Methods: We analysed the patterns of genetic diversity distribution in 29 populations from 19 regions across China using three mitochondrial (COI, COII and Cytb) genes as markers. We estimated demographic histories using neutrality tests, mismatch distributions and Bayesian skyline plots. Changes in PGD were assessed using an ecological niche model. Results: High genetic diversity was found in most populations, and the northern population exhibited higher haplotype diversity. The population genetic structure included the Tibet lineage and a large lineage comprising the remaining populations. Demographic analyses indicated that rapid population expansion occurred during the cold Last Glacial Maximum. In addition, our projections suggested that P. horticola currently has a vast PGD in China, for which the human influence index was the strongest variable. Large areas of cold northern regions were highly suitable for its survival. Under future global warming, highly suitable habitats will shift towards the higher latitudes. Main conclusions: P. horticola is widely distributed across varied environments, which may be attributed to its high degree of genetic variation. Human activities likely facilitated the current PGD and the frequent gene flow that homogenized differentiation among most populations. In addition, P. horticola exhibits strong adaptability to cold climates and environments from the past to the future. Considering future climatic changes, prevention and control should focus on high‐latitude regions, and vigilance regarding human‐mediated pest dispersals and outbreaks should be maintained. [ABSTRACT FROM AUTHOR]

Published

2023

33. Molecular phylogeography and historical demography of a widespread herbaceous species from eastern North America, Podophyllum peltatum.

Author

Wang, Chenxi, Yap, Zhao‐Yan, Wan, Penglei, Chen, Kuangqi, Folk, Ryan A., Damrel, Dixie Z., Barger, Wayne, Diamond, Alvin, Horn, Charles, Landry, Garrie P., Samarakoon, Tharanga, Harvey, Stephanie, Morgan, David R., Qiu, Yingxiong, and Li, Pan

Subjects

*CHLOROPLAST DNA, *DEMOGRAPHY, *PHYLOGEOGRAPHY, *QUATERNARY Period, *GENETIC variation, *DECIDUOUS forests, *GLACIATION

Abstract

Premise: Glacial/interglacial cycles and topographic complexity are both considered to have shaped today's diverse phylogeographic patterns of taxa from unglaciated eastern North America (ENA). However, few studies have focused on the phylogeography and population dynamics of wide‐ranging ENA herbaceous species occurring in forest understory habitat. We examined the phylogeographic pattern and evolutionary history of Podophyllum peltatum L., a widely distributed herb inhabiting deciduous forests of ENA. Methods: Using chloroplast DNA (cpDNA) sequences and nuclear microsatellite loci, we investigated the population structure and genetic diversity of the species. Molecular dating, demographic history analyses, and ecological niche modeling were also performed to illustrate the phylogeographic patterns. Results: Our cpDNA results identified three main groups that are largely congruent with boundaries along the Appalachian Mountains and the Mississippi River, two major geographic barriers in ENA. Populations located to the east of the Appalachians and along the central Appalachians exhibited relatively higher levels of genetic diversity. Extant lineages may have diverged during the late Miocene, and range expansions of different groups may have happened during the Pleistocene glacial/interglacial cycles. Conclusions: Our findings indicate that geographic barriers may have started to facilitate the population divergence in P. peltatum before the Pleistocene. Persistence in multiple refugia, including areas around the central Appalachians during the Quaternary glacial period, and subsequent expansions under hospitable climatic condition, especially westward expansion, are likely responsible for the species' contemporary genetic structure and phylogeographic pattern. [ABSTRACT FROM AUTHOR]

Published

2023

34. The genetic structure and demographic history of Zabelia tyaihyonii, endemic to Korean limestone karst forests, based on genome‐wide SNP markers.

Author

Choi, In‐Su, Han, Eun‐Kyeong, Wojciechowski, Martin F., Heo, Tae‐Im, Park, Jong‐Soo, Yang, Jong‐Cheol, Gantsetseg, Amarsanaa, Cheon, Kyeong‐Sik, Tamaki, Ichiro, and Lee, Jung‐Hyun

Subjects

*KARST, *LIMESTONE, *SINGLE nucleotide polymorphisms, *VICARIANCE, *GENETIC variation, *POPULATION genetics

Abstract

Similar to the global phenomenon, many plant species endemic to Korean limestone karst forests are at risk of extinction due to human intervention. Zabelia tyaihyonii is a familiar shrub, called "Hardy abelia" and "Fragrant abelia" growing in the karst forests of Korea, where it is one of the most threatened species. We investigated the genetic structure and demographic history of Z. tyaihyonii, which allow us to develop appropriate conservation and management strategies. The genetic structure was evaluated using a total of 187 samples from 14 populations, covering the entire distribution of Z. tyaihyonii in South Korea. We utilized 254 and 1753 SNP loci obtained via MIG‐seq (Multiplexed ISSR Genotyping by sequencing) for structure and demographic analyses, respectively. The population demographic modeling was performed with site frequency spectrum. To gain further historical insights, we also employed ENM (Ecological Niche Modeling). We found two distinct clusters (CLI and CLII) of ancient origin (ca. 490 ka). Despite CLII experiencing a more severe bottleneck, both clusters showed similar levels of genetic diversity, indicating mutual historical gene flow. Their historical distribution range seems to have changed very little. We proposed a historical distribution scenario for Z. tyaihyonii, taking into account its intrinsic factors, and emphasized a more complex response to Quaternary climate change beyond simple allopatric speciation models. These findings provide valuable insights for conservation and management strategies for Z. tyaihyonii. [ABSTRACT FROM AUTHOR]

Published

2023

35. Genetic structure and recent population demographic history of Taihangshan macaque (Macaca mulatta tcheliensis), North China.

Author

ZHOU, Yanyan, TIAN, Jundong, and LU, Jiqi

Subjects

*RHESUS monkeys, *MACAQUES, *GENETIC variation, *GENE flow, *HAPLOTYPES, *NINETEENTH century

Abstract

Massive actions have been and are being taken into protecting the world's primates from extinction, while the study of the properties of genetic diversity, demographic history, and ecological relationships will benefit the understanding of the long‐term survival of a species. The Taihangshan macaque (Macaca mulatta tcheliensis), a subspecies of rhesus macaque (Macaca mulatta), is endemic to China and currently restricted to southern Mt. Taihangshan area. Herein, we evaluated the genetic diversity, population structure, and demographic history of this subspecies using mitochondrial (Cytb and high variable region I: HVR I) and nuclear markers (microsatellite loci) of 131 individuals collected from 9 localities covering the distribution range of this subspecies. Both phylogenetic analyses and genetic assignment revealed that the wild populations of Taihangshan macaques could be divided into 2 major highly divergent clades, THS‐east and THS‐west. Low genetic diversity (π: 0.00266 ± 0.00016) but high haplotype diversity (Hd: 0.80352 ± 0.015) were detected in the Taihangshan macaques, particularly in THS‐east. Analyses of demographic history suggested that the Taihangshan macaques experienced first a stable historical population size from Holocene to early 19th century but a subtle decline and then slight growth in the recent 200 years. We suggest that bridging the neighbor populations (i.e. setting corridors) would facilitate the male‐mediated gene flow and subsequently increase the genetic diversity of the Taihangshan macaque populations. [ABSTRACT FROM AUTHOR]

Published

2023

36. Colonialism in South Africa leaves a lasting legacy of reduced genetic diversity in Cape buffalo.

Author

Quinn, Liam, Garcia‐Erill, Genís, Santander, Cindy, Brüniche‐Olsen, Anna, Liu, Xiaodong, Sinding, Mikkel‐Holger S., Heaton, Michael P., Smith, Timothy P. L., Pečnerová, Patrícia, Bertola, Laura D., Hanghøj, Kristian, Rasmussen, Malthe Sebro, de Jager, Deon, Siegismund, Hans R., Albrechtsen, Anders, Heller, Rasmus, and Moltke, Ida

Subjects

*AFRICAN buffalo, *GENETIC variation, *WATER buffalo, *WHOLE genome sequencing, *COLONIES

Abstract

The iconic Cape buffalo has experienced several documented population declines in recent history. These declines have been largely attributed to the late 19th century rinderpest pandemic. However, the effect of the rinderpest pandemic on their genetic diversity remains contentious, and other factors that have potentially affected this diversity include environmental changes during the Pleistocene, range expansions and recent human activity. Motivated by this, we present analyses of whole genome sequencing data from 59 individuals from across the Cape buffalo range to assess present‐day levels of genome‐wide genetic diversity and what factors have influenced these levels. We found that the Cape buffalo has high average heterozygosity overall (0.40%), with the two southernmost populations having significantly lower heterozygosity levels (0.33% and 0.29%) on par with that of the domesticated water buffalo (0.29%). Interestingly, we found that these lower levels are probably due to recent inbreeding (average fraction of runs of homozygosity 23.7% and 19.9%) rather than factors further back in time during the Pleistocene. Moreover, detailed investigations of recent demographic history show that events across the past three centuries were the main drivers of the exceptional loss of genetic diversity in the southernmost populations, coincident with the onset of colonialism in the southern extreme of the Cape buffalo range. Hence, our results add to the growing body of studies suggesting that multiple recent human‐mediated impacts during the colonial period caused massive losses of large mammal abundance in southern Africa. [ABSTRACT FROM AUTHOR]

Published

2023

37. Genomic vulnerability to climate change in Quercus acutissima, a dominant tree species in East Asian deciduous forests.

Author

Yuan, Shuai, Shi, Yong, Zhou, Biao‐Feng, Liang, Yi‐Ye, Chen, Xue‐Yan, An, Qing‐Qing, Fan, Yan‐Ru, Shen, Zhao, Ingvarsson, Pär K., and Wang, Baosheng

Subjects

*DECIDUOUS forests, *OAK, *GENETIC variation, *ENDANGERED species, *SPECIES, *PHYSIOLOGICAL adaptation, *CLIMATE change, *RAIN forests

Abstract

Understanding the evolutionary processes that shape the landscape of genetic variation and influence the response of species to future climate change is critical for biodiversity conservation. Here, we sampled 27 populations across the distribution range of a dominant forest tree, Quercus acutissima, in East Asia, and applied genome‐wide analyses to track the evolutionary history and predict the fate of populations under future climate. We found two genetic groups (East and West) in Q. acutissima that diverged during Pliocene. We also found a heterogeneous landscape of genomic variation in this species, which may have been shaped by population demography and linked selections. Using genotype‐environment association analyses, we identified climate‐associated SNPs in a diverse set of genes and functional categories, indicating a model of polygenic adaptation in Q. acutissima. We further estimated three genetic offset metrics to quantify genomic vulnerability of this species to climate change due to the complex interplay between local adaptation and migration. We found that marginal populations are under higher risk of local extinction because of future climate change, and may not be able to track suitable habitats to maintain the gene–environment relationships observed under the current climate. We also detected higher reverse genetic offsets in northern China, indicating that genetic variation currently present in the whole range of Q. acutissima may not adapt to future climate conditions in this area. Overall, this study illustrates how evolutionary processes have shaped the landscape of genomic variation, and provides a comprehensive genome‐wide view of climate maladaptation in Q. acutissima. [ABSTRACT FROM AUTHOR]

Published

2023

38. Whole‐genome resequencing reveals complex effects of geographical–palaeoclimatic interactions on diversification of moustache toads in East Asia.

Author

Li, Jun, Fu, Chao, Ai, Qingbo, Xie, Siyu, Huang, Chunhua, Zhao, Mian, Fu, Jinzhong, and Wu, Hua

Subjects

*LAST Glacial Maximum, *TOADS, *SPECIES diversity, *PHYLOGEOGRAPHY, *CLIMATE change, *VALLEYS, *GENE flow

Abstract

Geographical features and palaeoclimatic fluctuations are two classical evolutionary forces that shape genetic diversification within species. Fine‐grained analysis of the mechanisms involved through population demographic processes, however, remains limited. Taking advantage of two recently published reference genomes, we resequenced the genomes and examined the evolutionary history of the moustache toads, a group endemic to East Asia where complex topography and fluctuating palaeoclimate are known to have had profound impacts on organisms. Moustache toads probably originated in southeast Yunnan, China, and diversified towards the northwestern of Yunnan, as well as central and eastern China. Further exploration based on three widespread species (Leptobrachium ailaonicum, L. boringii and L. liui) using demographic modelling and species distribution models revealed that mountains and river valleys in East Asia not only functioned as geographical barriers, but also provided dispersal corridors and facilitated continuous migration or post‐glacial secondary contact among moustache toad populations. Furthermore, periodic oscillation of effective population sizes accompanying fluctuations of historical temperature and population contraction at the Last Glacial Maximum support the widespread impact of climatic changes of the Pleistocene on species diversification in East Asia. This impact was moderate for populations of L. ailaonicum and L. boringii in the southwestern mountains but severe for populations of L. liui in the eastern lowland regions of continental East Asia, which is supported by different degrees of change of their effective population sizes. Our findings reveal mechanisms underlying genetic diversification among moustache toads, and highlight the power of genomic data and demographic modelling for examining complex historical population‐level processes and for understanding how geographical and palaeoclimatic factors interactively shape current intraspecific diversity. [ABSTRACT FROM AUTHOR]

Published

2023

39. Cryptic diversity and spatial genetic variation in the coral Acropora tenuis and its endosymbionts across the Great Barrier Reef.

Author

Matias, Ambrocio Melvin A., Popovic, Iva, Thia, Joshua A., Cooke, Ira R., Torda, Gergely, Lukoschek, Vimoksalehi, Bay, Line K., Kim, Sun W., and Riginos, Cynthia

Subjects

*CORALS, *ACROPORA, *INTROGRESSION (Genetics), *GENETIC variation, *CORAL bleaching, *SPATIAL variation, *CORAL reefs & islands, *REEFS

Abstract

Genomic studies are uncovering extensive cryptic diversity within reef‐building corals, suggesting that evolutionarily and ecologically relevant diversity is highly underestimated in the very organisms that structure coral reefs. Furthermore, endosymbiotic algae within coral host species can confer adaptive responses to environmental stress and may represent additional axes of coral genetic variation that are not constrained by taxonomic divergence of the cnidarian host. Here, we examine genetic variation in a common and widespread, reef‐building coral, Acropora tenuis, and its associated endosymbiotic algae along the entire expanse of the Great Barrier Reef (GBR). We use SNPs derived from genome‐wide sequencing to characterize the cnidarian coral host and organelles from zooxanthellate endosymbionts (genus Cladocopium). We discover three distinct and sympatric genetic clusters of coral hosts, whose distributions appear associated with latitude and inshore–offshore reef position. Demographic modelling suggests that the divergence history of the three distinct host taxa ranges from 0.5 to 1.5 million years ago, preceding the GBR's formation, and has been characterized by low‐to‐moderate ongoing inter‐taxon gene flow, consistent with occasional hybridization and introgression typifying coral evolution. Despite this differentiation in the cnidarian host, A. tenuis taxa share a common symbiont pool, dominated by the genus Cladocopium (Clade C). Cladocopium plastid diversity is not strongly associated with host identity but varies with reef location relative to shore: inshore colonies contain lower symbiont diversity on average but have greater differences between colonies as compared with symbiont communities from offshore colonies. Spatial genetic patterns of symbiont communities could reflect local selective pressures maintaining coral holobiont differentiation across an inshore–offshore environmental gradient. The strong influence of environment (but not host identity) on symbiont community composition supports the notion that symbiont community composition responds to habitat and may assist in the adaptation of corals to future environmental change. [ABSTRACT FROM AUTHOR]

Published

2023

40. Whole‐genome resequencing reveals recent divergence of geographic populations of the dung beetle Phelotrupes auratus with color variation.

Author

Araki, Yoshifumi and Sota, Teiji

Subjects

*DUNG beetles, *MOUNTAIN forests, *FRAGMENTED landscapes, *GENE flow, *INDIGO, *COLOR, *EYE color, *HABITAT partitioning (Ecology)

Abstract

Knowledge of population divergence history is key to understanding organism diversification mechanisms. The geotrupid dung beetle Phelotrupes auratus, which inhabits montane forests and exhibits three color forms (red, green, and indigo), diverged into five local populations (west/red, south/green, south/indigo, south/red, and east/red) in the Kinki District of Honshu, Japan, based on the combined interpretation of genetic cluster and color‐form data. Here, we estimated the demographic histories of these local populations using the newly assembled draft genome sequence of P. auratus and whole‐genome resequencing data obtained from each local population. Using coalescent simulation analysis, we estimated P. auratus population divergences at ca. 3800, 2100, 600, and 200 years ago, with no substantial gene flow between diverged populations, implying the existence of persistent barriers to gene flow. Notably, the last two divergence events led to three local populations with different color forms. The initial divergence may have been affected by climatic cooling around that time, and the last three divergence events may have been associated with the increasing impact of human activities. Both climatic cooling and increasing human activity may have caused habitat fragmentation and a reduction in the numbers of large mammals supplying food (dung) for P. auratus, thereby promoting the decline, segregation, and divergence of local populations. Our research demonstrates that geographic population divergence in an insect with conspicuous differences in traits such as body color may have occurred rapidly under the influence of human activity. [ABSTRACT FROM AUTHOR]

Published

2023

41. Like a rolling stone: Colonization and migration dynamics of the gray reef shark (Carcharhinus amblyrhynchos).

Author

Lesturgie, Pierre, Braun, Camrin D., Clua, Eric, Mourier, Johann, Thorrold, Simon R., Vignaud, Thomas, Planes, Serge, and Mona, Stefano

Subjects

*COLONIZATION (Ecology), *REEFS, *CORAL reefs & islands, *LONG distance swimming, *SHARKS, *LIFE history theory

Abstract

Designing appropriate management plans requires knowledge of both the dispersal ability and what has shaped the current distribution of the species under consideration. Here, we investigated the evolutionary history of the endangered gray reef shark (Carcharhinus amblyrhynchos) across its range by sequencing thousands of RADseq loci in 173 individuals in the Indo‐Pacific (IP). We first bring evidence of the occurrence of a range expansion (RE) originating close to the Indo‐Australian Archipelago (IAA) where two stepping‐stone waves (east and westward) colonized almost the entire IP. Coalescent modeling additionally highlighted a homogenous connectivity (Nm ~ 10 per generation) throughout the range, and isolation by distance model suggested the absence of barriers to dispersal despite the affinity of C. amblyrhynchos to coral reefs. This coincides with long‐distance swims previously recorded, suggesting that the strong genetic structure at the IP scale (FST ~ 0.56 between its ends) is the consequence of its broad current distribution and organization in a large number of demes. Our results strongly suggest that management plans for the gray reef shark should be designed on a range‐wide rather than a local scale due to its continuous genetic structure. We further contrasted these results with those obtained previously for the sympatric but strictly lagoon‐associated Carcharhinus melanopterus, known for its restricted dispersal ability. Carcharhinus melanopterus exhibits a similar RE dynamic but is characterized by a stronger genetic structure and a nonhomogeneous connectivity largely dependent on local coral reefs availability. This sheds new light on shark evolution, emphasizing the roles of IAA as source of biodiversity and of life‐history traits in shaping the extent of genetic structure and diversity. [ABSTRACT FROM AUTHOR]

Published

2023

42. The importance of well protected forests for the conservation genetics of West African colobine monkeys.

Author

Minhós, Tânia, Borges, Filipa, Parreira, Bárbara, Oliveira, Rúben, Aleixo‐Pais, Isa, Leendertz, Fabien H., Wittig, Roman, Fernandes, Carlos Rodríguez, Marques Silva, Guilherme Henrique Lima, Duarte, Miguel, Bruford, Michael W., Ferreira da Silva, Maria Joana, and Chikhi, Lounès

Subjects

*FOREST conservation, *CONSERVATION genetics, *MONKEYS, *BUSHMEAT hunting, *GENETIC variation, *SHORT tandem repeat analysis, *EVOLUTIONARY algorithms

Abstract

In tropical forests, anthropogenic activities are major drivers of the destruction and degradation of natural habitats, causing severe biodiversity loss. African colobine monkeys (Colobinae) are mainly folivore and strictly arboreal primates that require large forests to subsist, being among the most vulnerable of all nonhuman primates. The Western red colobus Piliocolobus badius and the King colobus Colobus polykomos inhabit highly fragmented West African forests, including the Cantanhez Forests National Park (CFNP) in Guinea‐Bissau. Both species are also found in the largest and best‐preserved West African forest—the Taï National Park (TNP) in Ivory Coast. Colobine monkeys are hunted for bushmeat in both protected areas, but these exhibit contrasting levels of forest fragmentation, thus offering an excellent opportunity to investigate the importance of well‐preserved forests for the maintenance of evolutionary potential in these arboreal primates. We estimated genetic diversity, population structure, and demographic history by using microsatellite loci and mitochondrial DNA. We then compared the genetic patterns of the colobines from TNP with the ones previously obtained for CFNP and found contrasting genetic patterns. Contrary to the colobines from CFNP that showed very low genetic diversity and a strong population decline, the populations in TNP still maintain high levels of genetic diversity and we found no clear signal of population decrease in Western red colobus and a limited decrease in King colobus. These results suggest larger and historically more stable populations in TNP compared to CFNP. We cannot exclude the possibility that the demographic effects resulting from the recent increase of bushmeat hunting are not yet detectable in TNP using genetic data. Nevertheless, the fact that the TNP colobus populations are highly genetically diverse and maintain large effective population sizes suggests that well‐preserved forests are crucial for the maintenance of populations, species, and probably for the evolutionary potential in colobines. Research highlights: West African colobine monkeys inhabiting forests with contrasting levels of preservation exhibit distinct population genetic patterns in terms of their genetic diversity and demographic history.The colobines from the well‐preserved forest of Taï National Park (Ivory Coast) show high levels of genetic diversity, with historically large and stable populations, contrary to the populations from the highly fragmented Cantanhez Forests National Park (Guinea‐Bissau).Despite the increase i in hunting for bushmeat consumption in the two parks, genetic data suggests that the preservation of large forests is crucial for the persistence of these primates and the maintenance of their evolutionary potential. [ABSTRACT FROM AUTHOR]

Published

2023

43. Reconstructing the genetic admixture history of Tai‐Kadai and Sinitic people: Insights from genome‐wide SNP data from South China.

Author

Wang, Meng‐Ge, He, Guang‐Lin, Zou, Xing, Chen, Peng‐Yu, Wang, Zheng, Tang, Ren‐Kuan, Yang, Xiao‐Min, Chen, Jing, Yang, Mei‐Qing, Li, Ying‐Xiang, Liu, Jing, Wang, Fei, Zhao, Jing, Guo, Jian‐Xin, Hu, Rong, Wei, Lan‐Hai, Chen, Gang, Yeh, Hui‐Yuan, and Wang, Chuan‐Chao

Subjects

*SINGLE nucleotide polymorphisms, *RICE farmers, *NEOLITHIC Period, *WATERSHEDS, *AGRICULTURE, *GENE flow

Abstract

South China (SC) was a region with mixed rice–millet farming during the Middle Neolithic period and was also suggested to be the homeland of Tai‐Kadai (TK)‐speaking people. However, the formations of inland TK‐speaking people and southwestern Hans are far from clear due to very few studies on this subject. Here, we reveal the spatiotemporally demographic history of SC by analyzing newly‐generated genome‐wide SNP data of 115 modern southwestern individuals and find that inland TK‐speaking Dongs and Bouyeis have a close genomic affinity to coastal TK/Austronesian (AN)‐speaking people and Neolithic Yangtze River basin (YZRB) farmers, while southwestern Hans and TK‐speaking Gelaos possess a close genomic affinity to Neolithic Yellow River basin (YRB) farmers. Genetic differentiations are identified among TK people from SC and Southeast Asia, and between northern and southern inland Chinese TK people, in which the identified shared genetic ancestry between TK and AN people highlights a common origin of AN/TK groups. Conclusively, our findings indicate that millet farmers deriving from the YRB and rice farmers deriving from the YZRB substantially contribute to the present‐day inland TK speakers and southwestern Hans via a two‐way admixture scenario of bi‐directional gene‐flow events, which facilitates the formation of a modern two‐way genetic admixture profile. [ABSTRACT FROM AUTHOR]

Published

2023

44. New Zealand endemic open‐habitat specialist, the Black‐fronted Tern (Chlidonias albostriatus), experienced population expansion during Pleistocene glaciation and recent decline.

Author

Schlesselmann, Ann‐Kathrin V., Cooper, Jamie, Dussex, Nicolas, and Robertson, Bruce C.

Subjects

COLD adaptation, TERNS, ENDANGERED species, PLEISTOCENE Epoch, CLIMATE change, HUMAN settlements, GLACIATION

Abstract

Understanding how climatic and environmental changes, as well as human activities, induce changes in the distribution and population size of avian species refines our ability to predict future impacts on threatened species. Using multilocus genetic data, we show that the population of a threatened New Zealand endemic open‐habitat specialist, the Black‐fronted Tern Chlidonias albostriatus – in contrast to forest specialists – expanded during the last glacial period. The population has decreased subsequently despite the availability of extensive open habitat after human arrival to New Zealand. We conclude that population changes for open habitat specialists such as Black‐fronted Terns in pre‐human New Zealand were habitat‐dependent, similar to Northern Hemisphere cold‐adapted species, whereas post‐human settlement populations were constrained by predators independent of habitat availability, similar to other island endemic species. [ABSTRACT FROM AUTHOR]

Published

2023

45. Microevolutionary mechanism of high‐altitude adaptation in Tibetan chicken populations from an elevation gradient.

Author

Zhong, Hai‐An, Kong, Xiao‐Yan, Zhang, Ya‐Wen, Su, Yan‐Kai, Zhang, Bo, Zhu, Li, Chen, Hua, Gou, Xiao, and Zhang, Hao

Subjects

*POULTRY breeding, *CHICKENS, *PHYSIOLOGICAL adaptation, *BLOOD coagulation, *ALTITUDES, *PLATEAUS, *MICROEVOLUTION

Abstract

As an indigenous breed, the Tibetan chicken is found in highland regions and shows physiological adaptations to high altitude; however, the genetic changes that determine these adaptations remain elusive. We assumed that the microevolution of the Tibetan chicken occurred from lowland to highland regions with a continuous elevation range. In this study, we analyzed the genome of 188 chickens from lowland areas to the high‐altitude regions of the Tibetan plateau with four altitudinal levels. Phylogenetic analysis revealed that Tibetan chickens are significantly different from other altitude chicken populations. Reconstruction of the demographic history showed that the migration and admixture events of the Tibetan chicken occurred at different times. The genome of the Tibetan chicken was also used to analyze positive selection pressure that is associated with high‐altitude adaptation, revealing the well‐known candidate gene that participates in oxygen binding (HBAD), as well as other novel potential genes (e.g., HRG and ANK2) that are related to blood coagulation and cardiovascular efficiency. Our study provides novel insights regarding the evolutionary history and microevolution mechanisms of the high‐altitude adaptation in the Tibetan chicken. [ABSTRACT FROM AUTHOR]

Published

2022

46. Ancient introgression underlying the unusual mito‐nuclear discordance and coat phenotypic variation in the Moupin pika.

Author

Ge, Deyan, Feijó, Anderson, Wen, Zhixin, Lissovsky, Andrey, Zhang, Dezhi, Cheng, Jilong, Yan, Chaochao, Mu, Danping, Wu, Xinlai, Xia, Lin, Yang, Qisen, and Ericson, Per

Subjects

*PHENOTYPIC plasticity, *MITOCHONDRIAL DNA, *INTROGRESSION (Genetics), *GENE flow, *GENE families, *CYTOCHROME b, *SPECIES diversity, *HABITATS

Abstract

Aim: The mechanisms by which global biodiversity hotspots harbour and conserve high genetic and morphological diversity of endemic species remain unexplored. Relic species of ochotonids in the genus Ochotona are confined to alpine habitats and highly sensitive to environmental changes. We studied the genomic and ecological mechanisms underlying the divergence and adaptive evolution of the Moupin pika (O. thibetana) and its closely related species to infer its diversification, adaptive evolution and demographic history in response to historical and recent environmental changes. Location: Hengduan Mountain Region, China. Methods: We integrated morphological, genomic and ecological data to interpret the phylogeographic structure, adaptive evolution, demographic history and range shift of O. thibetana. Phylogenetic reconstruction was based on Cytochrome b (CYTB), the mitochondrial genome and single‐copy orthologues of the whole genome. Gene flow among extant lineages, as well as from extinct species, was inferred by multiple algorithms. Demographic history was inferred using the pairwise sequential Markovian coalescent and high‐resolution analysis of linkage disequilibrium. We also predicted the range shift of this species by using ecological niche modelling. Results: Phylogenetic reconstruction revealed an unusual mitochondrial lineage of O. thibetana from the western Sichuan Basin, which was named O. qionglaiensis in previous studies. Extensive gene flow was detected among genetic lineages of O. thibetana, which has distinct phenotypic variation in hair thickness and colouration, as well as notable morphological differentiation in external and craniodental measurements. Multiple members of the keratin gene family were identified as introgressed loci from some ancient species to O. thibetana. The Moupin pika underwent dramatic population shrinkage in the late Quaternary, with a clear trend of population growth in approximately the last 70 generations. The potential distribution range of O. thibetana showed a clear trend of expansion in the future. Main conclusions: The unusual mitochondrial phylogenetic pattern of O. thibetana resulted from "extended ghost introgression," a new evolutionary model proposed in the present study, and thus rejected the validity of O. qionglaiensis as an independent species. Ancient introgression of keratin genes likely underlies the prominent coat phenotypic variation among genetic lineages. Clear population growth and range expansion of the Moupin pika in recent generations probably benefitted from recent global warming and vegetation recovery, which not only contributed to the conservation of large mammals but was also beneficial to small mammals endemic to alpine habitats. [ABSTRACT FROM AUTHOR]

Published

2022

47. Genomic insights into inter‐ and intraspecific mating system shifts in Primulina.

Author

Yi, Huiqin, Wang, Jieyu, Wang, Jing, Rausher, Mark, and Kang, Ming

Subjects

*SHIFT systems, *GENETIC load, *GENETIC variation, *FLOWERING of plants, *PLANT evolution, *PLANT genomes

Abstract

The mating system shift from outcrossing to selfing is one of the most frequent evolutionary trends in flowering plants. However, the genomic consequences of this shift remain poorly understood. Specifically, the relative importance of the demographic and genetic processes causing changes in genetic variation and selection efficacy associated with the evolution of selfing is unclear. Here we sequenced the genomes of two Primulina species with contrasting mating systems: P. eburnea (outcrossing) versus P. tabacum (outcrossing, mixed‐mating and selfing populations). Whole‐genome resequencing data were used to investigate the genomic consequences of mating system shifts within and between species. We found that highly selfing populations of P. tabacum display loss of genetic diversity, increased deleterious mutations, higher genomic burden and fewer adaptive substitutions. However, compared with outcrossing populations, mixed‐mating populations did not display loss of genetic diversity and accumulation of genetic load. We find no evidence of population bottlenecks associated with the shift to selfing, which suggests that the genetic effects of selfing on Ne and possibly linked selection, rather than demographic history, are the primary drivers of diversity reduction in highly selfing populations. Our results highlight the importance of distinguishing the relative contribution of mating system and demography on the genomic consequences associated with mating system evolution in plants. [ABSTRACT FROM AUTHOR]

Published

2022

48. Genetic decline and recovery of a demographically rebuilt fishery species.

Author

Hoey, Jennifer A., Able, Kenneth W., and Pinsky, Malin L.

Subjects

*FISHERIES, *FISH surveys, *FREQUENCY spectra, *POPULATION dynamics, *AMPLIFIED fragment length polymorphism

Abstract

The demographic history of a population is important for conservation and evolution, but this history is unknown for many populations. Methods that use genomic data have been developed to infer demography, but they can be challenging to implement and interpret, particularly for large populations. Thus, understanding if and when genetic estimates of demography correspond to true population history is important for assessing the performance of these genetic methods. Here, we used double‐digest restriction‐site associated DNA (ddRAD) sequencing data from archived collections of larval summer flounder (Paralichthys dentatus, n = 279) from three cohorts (1994–1995, 1997–1998 and 2008–2009) along the U.S. East coast to examine how contemporary effective population size and genetic diversity responded to changes in abundance in a natural population. Despite little to no detectable change in genetic diversity, coalescent‐based demographic modelling from site frequency spectra revealed that summer flounder effective population size declined dramatically in the early 1980s. The timing and direction of change corresponded well with the observed decline in spawning stock census abundance in the late 1980s from independent fish surveys. Census abundance subsequently recovered and achieved the prebottleneck size. Effective population size also grew following the bottleneck. Our results for summer flounder demonstrate that genetic sampling and site frequency spectra can be useful for detecting population dynamics, even in species with large effective sizes. [ABSTRACT FROM AUTHOR]

Published

2022

49. Geographic factors and climatic fluctuation drive the genetic structure and demographic history of Cycas taiwaniana (Cycadaceae), an endemic endangered species to Hainan Island in China.

Author

Wu, Li‐Xin, Xu, Hai‐Yan, Jian, Shu‐Guang, Gong, Xun, and Feng, Xiu‐Yan

Subjects

*CLIMATE change, *ENDANGERED species, *PLEISTOCENE Epoch, *NUCLEAR DNA, *CHLOROPLAST DNA, *GENETIC variation

Abstract

Hainan Island had experienced several cold–warm and dry–humid fluctuations since the Late Pleistocene period, resulting in separating and connecting from the mainland several times with the cyclic rise and fall of sea level. The fluctuations can change the biota and ecological environment in the island. Cycas taiwaniana Carruthers is endemic to Hainan Island and is classified as endangered by the International Union for Conservation of Nature (IUCN). To comprehensively understand the genetic dynamics of C. taiwaniana, we sampled 12 wild populations in Hainan Island and one cultivated population in Fujian province, and analyzed the genetic diversity, genetic structure, and demographic history based on the molecular data. Results revealed that C. taiwaniana had relatively low genetic diversity and high genetic differentiation. Haplotypes of C. taiwaniana diversified during the Pleistocene based on the chloroplast DNA (cpDNA) and the concatenated nuclear DNA (nDNA) data. Genetic cluster analyses based on the microsatellite (SSR) data showed that the 12 wild populations were separated into three clusters which could be three evolutionary significant units (ESUs), indicating three basic units of protection were identified. Moreover, we also confirmed the cultivated population FJ derived from the DLS1‐GSL clade. Demographic inference from different data was discordant, but overall, it uncovered that C. taiwaniana had experienced population contraction events twice during the Pleistocene and Holocene, and then expanded recently. Our study elucidated the population genetic characteristics of C. taiwaniana, and guided us to develop targeted conservation and management strategies for this endangered species. [ABSTRACT FROM AUTHOR]

Published

2022

50. Demographic history and gene flow in the peatmosses Sphagnum recurvum and Sphagnum flexuosum (Bryophyta: Sphagnaceae).

Author

Imwattana, Karn, Aguero, Blanka, Duffy, Aaron, and Shaw, A. Jonathan

Subjects

*GENE flow, *LAST Glacial Maximum, *PEAT mosses, *BRYOPHYTES, *PLANT diversity, *PHYLOGEOGRAPHY, *GEOGRAPHY

Abstract

Population size changes and gene flow are processes that can have significant impacts on evolution. The aim of this study was to investigate the relationship of geography to patterns of gene flow and population size changes in a pair of closely related Sphagnum (peatmoss) species: S. recurvum and S. flexuosum. Both species occur in eastern North America, and S. flexuosum also occurs in Europe. Genetic data from restriction‐site‐associated DNA sequencing (RAD‐seq) were used in this study. Analyses of gene flow were accomplished using coalescent simulations of site frequency spectra (SFSs). Signatures of gene flow were confirmed by f4 statistics. For S. flexuosum, genetic diversity of plants in glaciated areas appeared to be lower than that in unglaciated areas, suggesting that glaciation can have an impact on effective population sizes. There is asymmetric gene flow from eastern North America to Europe, suggesting that Europe might have been colonized by plants from eastern North America after the last glacial maximum. The rate of gene flow between S. flexuosum and S. recurvum is lower than that between geographically disjunct S. flexuosum populations. The rate of gene flow between species is higher among sympatric plants of the two species than between currently allopatric S. flexuosum populations. There was also gene flow from S. recurvum to the ancestor S. flexuosum on both continents which occurred through secondary contact. These results illustrate a complex history of interspecific gene flow between S. flexuosum and S. recurvum, which occurred in at least two phases: between ancestral populations after secondary contact and between currently sympatric plants. [ABSTRACT FROM AUTHOR]

Published

2022