Your search keyword '"Anne Veillet"' showing total 9 results

1. Diversification processes in Gerp's mouse lemur demonstrate the importance of rivers and altitude as biogeographic barriers in Madagascar's humid rainforests

Author

Tobias van Elst, Dominik Schüßler, Romule Rakotondravony, Valisoa S. T. Rovanirina, Anne Veillet, Paul A. Hohenlohe, Jonah H. Ratsimbazafy, Rodin M. Rasoloarison, Solofonirina Rasoloharijaona, Blanchard Randrianambinina, Miarisoa L. Ramilison, Anne D. Yoder, Edward E. Louis Jr., and Ute Radespiel

Subjects

coalescent, diversification, Madagascar, Microcebus, phylogeography, RAD sequencing, Ecology, QH540-549.5

Abstract

Abstract Madagascar exhibits exceptionally high levels of biodiversity and endemism. Models to explain the diversification and distribution of species in Madagascar stress the importance of historical variability in climate conditions which may have led to the formation of geographic barriers by changing water and habitat availability. The relative importance of these models for the diversification of the various forest‐adapted taxa of Madagascar has yet to be understood. Here, we reconstructed the phylogeographic history of Gerp's mouse lemur (Microcebus gerpi) to identify relevant mechanisms and drivers of diversification in Madagascar's humid rainforests. We used restriction site associated DNA (RAD) markers and applied population genomic and coalescent‐based techniques to estimate genetic diversity, population structure, gene flow and divergence times among M. gerpi populations and its two sister species M. jollyae and M. marohita. Genomic results were complemented with ecological niche models to better understand the relative barrier function of rivers and altitude. We show that M. gerpi diversified during the late Pleistocene. The inferred ecological niche, patterns of gene flow and genetic differentiation in M. gerpi suggest that the potential for rivers to act as biogeographic barriers depended on both size and elevation of headwaters. Populations on opposite sides of the largest river in the area with headwaters that extend far into the highlands show particularly high genetic differentiation, whereas rivers with lower elevation headwaters have weaker barrier functions, indicated by higher migration rates and admixture. We conclude that M. gerpi likely diversified through repeated cycles of dispersal punctuated by isolation to refugia as a result of paleoclimatic fluctuations during the Pleistocene. We argue that this diversification scenario serves as a model of diversification for other rainforest taxa that are similarly limited by geographic factors. In addition, we highlight conservation implications for this critically endangered species, which faces extreme habitat loss and fragmentation.

Published

2023

2. Hybridization and range expansion in tamarisk beetles (Diorhabda spp.) introduced to North America for classical biological control

Author

Amanda R. Stahlke, Ellyn V. Bitume, Zeynep A. Özsoy, Dan W. Bean, Anne Veillet, Meaghan I. Clark, Eliza I. Clark, Patrick Moran, Ruth A. Hufbauer, and Paul A. Hohenlohe

Subjects

biological control, de novo genome assembly, hybridization, invasion genomics, RADseq, range expansion, Evolution, QH359-425

Abstract

Abstract With the global rise of human‐mediated translocations and invasions, it is critical to understand the genomic consequences of hybridization and mechanisms of range expansion. Conventional wisdom is that high genetic drift and loss of genetic diversity due to repeated founder effects will constrain introduced species. However, reduced genetic variation can be countered by behavioral aspects and admixture with other distinct populations. As planned invasions, classical biological control (biocontrol) agents present important opportunities to understand the mechanisms of establishment and spread in a novel environment. The ability of biocontrol agents to spread and adapt, and their effects on local ecosystems, depends on genomic variation and the consequences of admixture in novel environments. Here, we use a biocontrol system to examine the genome‐wide outcomes of introduction, spread, and hybridization in four cryptic species of a biocontrol agent, the tamarisk beetle (Diorhabda carinata, D. carinulata, D. elongata, and D. sublineata), introduced from six localities across Eurasia to control the invasive shrub tamarisk (Tamarix spp.) in western North America. We assembled a de novo draft reference genome and applied RADseq to over 500 individuals across laboratory cultures, the native ranges, and the introduced range. Despite evidence of a substantial genetic bottleneck among D. carinulata in N. America, populations continue to establish and spread, possibly due to aggregation behavior. We found that D. carinata, D. elongata, and D. sublineata hybridize in the field to varying extents, with D. carinata × D. sublineata hybrids being the most abundant. Genetic diversity was greater at sites with hybrids, highlighting potential for increased ability to adapt and expand. Our results demonstrate the complex patterns of genomic variation that can result from introduction of multiple ecotypes or species for biocontrol, and the importance of understanding them to predict and manage the effects of biocontrol agents in novel ecosystems.

Published

2022

3. Identification of Gastrointestinal Microbiota in Hawaiian Green Turtles ()

Author

Karla J McDermid, Ronald P Kittle, Anne Veillet, Sophie Plouviez, Lisa Muehlstein, and George H Balazs

Subjects

Evolution, QH359-425

Abstract

Green turtles ( Chelonia mydas ) have a hindgut fermentation digestive tract, which uses cellulolytic microbes to break down plant matter in the cecum and proximal colon. Previous studies on bacterial communities of green turtles have not identified in situ hindgut microbiota, and never before in Hawaiian green turtles, which comprise an isolated metapopulation. Fresh samples using sterile swabs were taken from five locations along the gastrointestinal tracts of eight green turtles that had required euthanization. Bacteria were cultured, aerobically and anaerobically, on nutrient agar and four differential and selective media. Samples at three sections along the gastrointestinal tracts of two green turtles were analyzed using 16S metagenomics on an Ion Torrent Personal Genome Machine. More than half of the 4 532 104 sequences belonged to the phylum Firmicutes, followed by Bacteroidetes and Proteobacteria, which are characteristic of herbivore gut microbiota. Some microbiota variation existed between turtles and among gastrointestinal sections. The 16S sequence analysis provided a better representation of the total gastrointestinal bacterial community, much of which cannot be cultured using traditional microbial techniques. These metagenomic analyses serve as a foundation for a better understanding of the microbiome of green turtles in the Hawaiian Islands and elsewhere.

Published

2020

4. Hybridization and range expansion in tamarisk beetles ( Diorhabda spp.) introduced to North America for classical biological control

Author

Amanda R. Stahlke, A. Zeynep Ozsoy, Daniel W. Bean, Anne Veillet, Paul A. Hohenlohe, Ellyn Bitume, Patrick J. Moran, Meaghan I. Clark, Eliza I. Clark, and Ruth A. Hufbauer

Subjects

Evolution, Ecology, Range (biology), Biological pest control, food and beverages, biological control, RADseq, Biology, de novo genome assembly, QH359-425, Genetics, invasion genomics, General Agricultural and Biological Sciences, hybridization, range expansion, Ecology, Evolution, Behavior and Systematics

Abstract

With the global rise of human‐mediated translocations and invasions, it is critical to understand the genomic consequences of hybridization and mechanisms of range expansion. Conventional wisdom is that high genetic drift and loss of genetic diversity due to repeated founder effects will constrain introduced species. However, reduced genetic variation can be countered by behavioral aspects and admixture with other distinct populations. As planned invasions, classical biological control (biocontrol) agents present important opportunities to understand the mechanisms of establishment and spread in a novel environment. The ability of biocontrol agents to spread and adapt, and their effects on local ecosystems, depends on genomic variation and the consequences of admixture in novel environments. Here, we use a biocontrol system to examine the genome‐wide outcomes of introduction, spread, and hybridization in four cryptic species of a biocontrol agent, the tamarisk beetle (Diorhabda carinata, D. carinulata, D. elongata, and D. sublineata), introduced from six localities across Eurasia to control the invasive shrub tamarisk (Tamarix spp.) in western North America. We assembled a de novo draft reference genome and applied RADseq to over 500 individuals across laboratory cultures, the native ranges, and the introduced range. Despite evidence of a substantial genetic bottleneck among D. carinulata in N. America, populations continue to establish and spread, possibly due to aggregation behavior. We found that D. carinata, D. elongata, and D. sublineata hybridize in the field to varying extents, with D. carinata × D. sublineata hybrids being the most abundant. Genetic diversity was greater at sites with hybrids, highlighting potential for increased ability to adapt and expand. Our results demonstrate the complex patterns of genomic variation that can result from introduction of multiple ecotypes or species for biocontrol, and the importance of understanding them to predict and manage the effects of biocontrol agents in novel ecosystems.

Published

2021

5. Hybridization and range expansion in tamarisk beetles (Diorhabda spp.) introduced to North America for classical biological control

Author

Meaghan I. Clark, Paul A. Hohenlohe, Daniel W. Bean, Anne Veillet, Ellyn Bitume, E. I. Clark, Patrick J. Moran, Ruth A. Hufbauer, A. Z. Ozsoy, and Amanda R. Stahlke

Subjects

Genetic diversity, Species complex, Population bottleneck, Genetic drift, Range (biology), Ecology, Genetic variation, Introduced species, Biology, biology.organism_classification, Diorhabda carinata

Abstract

With the global rise of human-mediated translocations and invasions, it is critical to understand the genomic consequences of hybridization and mechanisms of range expansion. Conventional wisdom is that high genetic drift and loss of genetic diversity due to repeated founder effects will constrain introduced species. However, reduced genetic variation can be countered by behavioral aspects and admixture with other distinct populations. As planned invasions, classical biological control (biocontrol) agents present important opportunities to understand the mechanisms of establishment and spread in a novel environment. The ability of biocontrol agents to spread and adapt, and their effects on local ecosystems, depends on genomic variation and the consequences of admixture in novel environments. Here we use a biocontrol system to examine the genome-wide outcomes of introduction, spread, and hybridization in four cryptic species of a biocontrol agent, the tamarisk beetle (Diorhabda carinata, D. carinulata, D. elongata, and D. sublineata), introduced from six localities across Eurasia to control the invasive shrub tamarisk (Tamarix spp.) in western North America. We assembled a de novo draft reference genome and applied RADseq to over 500 individuals from laboratory cultures, the native ranges, and across the introduced range. Despite evidence of a substantial genetic bottleneck among D. carinulata in N. America, populations continue to establish and spread, possibly due to aggregation behavior. We found that D. carinata, D. elongata, and D. sublineata hybridize in the field to varying extents, with D. carinata x D. sublineata hybrids being the most abundant. Genetic diversity was greater at sites with hybrids, highlighting potential for increased ability to adapt and expand. Our results demonstrate the complex patterns of genomic variation that can result from introduction of multiple ecotypes or species for biocontrol, and the importance of understanding them to predict and manage the effects of biocontrol agents in novel ecosystems.

Published

2021

6. Contemporary and historical selection in Tasmanian devils (Sarcophilus harrisii) support novel, polygenic response to transmissible cancer

Author

Anne Veillet, Rodrigo Hamede, Hamish McCallum, Barbara Schönfeld, Amanda R. Stahlke, Austin H. Patton, Alexandra K. Fraik, Mark J. Margres, Soraia Barbosa, Brendan Epstein, Sarah A. Hendricks, Menna E. Jones, Andrew Storfer, and Paul A. Hohenlohe

Subjects

0106 biological sciences, Candidate gene, wildlife disease, Devil facial tumour disease, RAD-capture, Wildlife disease, Biology, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Molecular evolution, Neoplasms, Tasmanian devil, medicine, Animals, Gene, rapid evolution, Research Articles, Selection (genetic algorithm), General Environmental Science, 030304 developmental biology, 0303 health sciences, General Immunology and Microbiology, molecular evolution, Special Feature, Cancer, General Medicine, Genomics, medicine.disease, biology.organism_classification, 3. Good health, Marsupialia, Sarcophilus, conservation genomics, Evolutionary biology, transmissible cancer, Facial Neoplasms, General Agricultural and Biological Sciences, Genetic monitoring

Abstract

Tasmanian devils (Sarcophilus harrisii) are evolving in response to a unique transmissible cancer, devil facial tumour disease (DFTD), first described in 1996. Persistence of wild populations and the recent emergence of a second independently evolved transmissible cancer suggest that transmissible cancers may be a recurrent feature in devils. Here we compared signatures of selection across temporal scales to determine whether genes or gene pathways under contemporary selection (6-8 generations) have also been subject to historical selection (65-85 million years), and test for recurrent selection in devils. First, we used a targeted sequencing approach, RAD-capture, to identify genomic regions subject to rapid evolution in approximately 2,500 devils in six populations as DFTD spread across the species range. We documented genome-wide contemporary evolution, including 186 candidate genes related to cell cycling and immune response. Then we used a molecular evolution approach to identify historical positive selection in devils compared to other marsupials and found evidence of selection in 1,773 genes. However, we found limited overlap across time scales, with historical selection detected in only 16 contemporary candidate genes, and no overlap in enriched functional gene sets. Our results are consistent with a novel, multi-locus evolutionary response of devils to DFTD. Our results can inform management actions to conserve adaptive potential of devils by identifying high priority targets for genetic monitoring and maintenance of functional diversity in managed populations.

Published

2020

7. Identification of Gastrointestinal Microbiota in Hawaiian Green Turtles (Chelonia mydas)

Author

Sophie Plouviez, Karla J. McDermid, Ronald P. Kittle, Lisa Muehlstein, George H. Balazs, and Anne Veillet

Subjects

0106 biological sciences, Digestive bacteria, Zoology, gut microbiome, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Cecum, Plant matter, Genetics, medicine, Proximal colon, next-generation sequencing (NGS), Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Original Research, 0303 health sciences, biology, Gastrointestinal microbiota, biology.organism_classification, Computer Science Applications, medicine.anatomical_structure, marine reptile, 16S rDNA gene, Identification (biology), Digestive tract, Hindgut fermentation, Bacteria

Abstract

Green turtles ( Chelonia mydas) have a hindgut fermentation digestive tract, which uses cellulolytic microbes to break down plant matter in the cecum and proximal colon. Previous studies on bacterial communities of green turtles have not identified in situ hindgut microbiota, and never before in Hawaiian green turtles, which comprise an isolated metapopulation. Fresh samples using sterile swabs were taken from five locations along the gastrointestinal tracts of eight green turtles that had required euthanization. Bacteria were cultured, aerobically and anaerobically, on nutrient agar and four differential and selective media. Samples at three sections along the gastrointestinal tracts of two green turtles were analyzed using 16S metagenomics on an Ion Torrent Personal Genome Machine. More than half of the 4 532 104 sequences belonged to the phylum Firmicutes, followed by Bacteroidetes and Proteobacteria, which are characteristic of herbivore gut microbiota. Some microbiota variation existed between turtles and among gastrointestinal sections. The 16S sequence analysis provided a better representation of the total gastrointestinal bacterial community, much of which cannot be cultured using traditional microbial techniques. These metagenomic analyses serve as a foundation for a better understanding of the microbiome of green turtles in the Hawaiian Islands and elsewhere.

Published

2020

8. Disease swamps molecular signatures of genetic-environmental associations to abiotic factors in Tasmanian devil (Sarcophilus harrisii) populations

Author

Brendan Epstein, Andrew Storfer, Elisa Lopez-Contreras, Alexandra K. Fraik, Barbara Schönfeld, Menna E. Jones, Hamish McCallum, Amanda R. Stahlke, Samantha J. Kallinen, Joanna L. Kelley, Soraia Barbosa, Mark J. Margres, Paul A. Hohenlohe, Sarah A. Hendricks, Anne Veillet, and Rodrigo Hamede

Subjects

0106 biological sciences, 0301 basic medicine, Linkage disequilibrium, Candidate gene, Adaptation, Biological, Population genetics, Biology, 010603 evolutionary biology, 01 natural sciences, Article, 03 medical and health sciences, Genetics, Animals, Selection, Genetic, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Local adaptation, Abiotic component, 0303 health sciences, Genetic diversity, Biotic component, Genetic Variation, biology.organism_classification, Marsupialia, 030104 developmental biology, Sarcophilus, Evolutionary biology, Host-Pathogen Interactions, Gene-Environment Interaction, Adaptation, General Agricultural and Biological Sciences

Abstract

Landscape genomics studies focus on identifying candidate genes under selection via spatial variation in abiotic environmental variables, but rarely by biotic factors such as disease. The Tasmanian devil (Sarcophilus harrisii) is found only on the environmentally heterogeneous island of Tasmania and is threatened with extinction by a nearly 100% fatal, transmissible cancer, devil facial tumor disease (DFTD). Devils persist in regions of long-term infection despite epidemiological model predictions of species’ extinction, suggesting possible adaptation to DFTD. Here, we test the extent to which spatial variation and genetic diversity are associated with the abiotic environment and/or by DFTD. We employ genetic-environment association (GEAs) analyses using a RAD-capture panel consisting of 6,886 SNPs from 3,286 individuals sampled pre- and post-disease arrival. Pre-disease, we find significant correlations of allele frequencies with environmental variables, including 349 unique loci linked to 64 genes, suggesting local adaptation to abiotic environment. Following DFTD arrival, however, we detected few of the pre-disease candidate loci, but instead frequencies of candidate loci linked to 14 genes correlated with disease prevalence. Loss of apparent signal of abiotic local adaptation following disease arrival suggests swamping by the strong selection imposed by DFTD. Further support for this result comes from the fact that post-disease candidate loci are in linkage disequilibrium with genes putatively involved in immune response, tumor suppression and apoptosis. This suggests the strength GEA associations of loci with the abiotic environment are swamped resulting from the rapid onset of a biotic selective pressure.

Published

2019

9. Polymorphic microsatellites in nēnē, the endangered Hawaiian goose (Branta sandvicensis)

Author

Anne Veillet, Donald K. Price, and Rajesh Shrestha

Subjects

biology, business.operation, education, Endangered species, Zoology, biology.organism_classification, Branta, Canada goose, Goose, biology.animal, Genetics, Waterfowl, Inbreeding depression, Microsatellite, business, Inbreeding, Ecology, Evolution, Behavior and Systematics, Biotechnology

Abstract

The nēnē (Branta sandvicensis) is an endangered Hawaiian goose endemic to the Hawaiian Islands. The nēnē nearly went extinct in the mid-19.00s and the majority of the approximately 1300 individuals currently in Hawai'i are descendants from less than 30 birds. The low adult breeding success and juvenile survival is likely due, in part, to inbreeding depression in wild individuals. Thirty-eight microsatellite primer sets developed in nēnē, Canada goose, and waterfowl species provided 8 polymorphic loci. Four of these polymorphic loci exhibited only two alleles, which is likely a reflection of the high inbreeding in this species.

Published

2011