GENETIC VARIATION AND POPULATION GENETIC STRUCTURE OF MUSKRAT, ONDATRA ZIBETHICUS, AT DIFFERENT SPATIAL SCALES

Laurence, Sophie

19 March 2014

Understanding the factors and processes that influence intraspecific genetic variation are essential to better understand evolutionary processes. In this research, I examined patterns of gene flow and their effects on the distribution of genetic variation and spatial genetic structuring at different spatial scales. I used a combination of population genetics, spatial analysis, morphometrics and phylogeography in order to understand the patterns of genetic variation and their resulting phenotypic variations in a semi-aquatic species, the muskrat (Ondatra zibethicus).

Genetic variation

Population genetic structure

Muskrat

Genetic diversity and population genetic structure in the South African commercially important shark species, the common smoothhound (Mustelus mustelus)

Maduna, Simo Njabulo

12 1900

Thesis (MSc)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: Deciphering patterns of intraspecies population genetic structuring in commercially important shark species is essential for an integrated fisheries management approach to conservation of regional biodiversity. The common smoothhound shark, Mustelus mustelus, is an overexploited, commercially and recreationally important shark species in South Africa. Considering the vulnerable status of the common smoothhound shark and due to very limited available genetic information, this study aimed to develop molecular markers, assess patterns of genetic diversity and population connectivity along the South African coast using multilocus data generated from 12 microsatellite markers and the mitochondrial gene, NADH dehydrogenase subunit 4 (ND4). The cross-species amplification of microsatellites proved useful for genetic diversity and population genetic analysis of the common smoothhound shark. These microsatellites could aid in the molecular characterisation of other endemic and cosmopolitan species and provide valuable tools for the conservation of potentially threatened or exploited shark species. For the microsatellite data, moderate levels of genetic diversity based on the heterozygosity, allelic richness and haplotype diversity were found in a total of 144 individuals sampled across eight study populations. Estimates for pairwise population differentiation, F-statistics, AMOVA and factorial correspondence analysis (FCA) indicated significant genetic structure within and between west- and east coast populations. Additionally, Bayesian clustering analyses detected two putative ancestral gene pools, supporting the presence of a biogeographic barrier at the Cape Agulhas region and therefore genetic discontinuity between the Indian and Atlantic Ocean samples. On the contrary, mitochondrial data indicated that common smoothhound shark is genetically homogenous with substantial interoceanic gene flow. Such conflicting signals found between nuclear and mitochondrial DNA (mitonuclear discordance) can be attributed to a number of factors and could simply be due to the inherent differences in marker properties or an indication of sex biased dispersal. Despite an indication of an expanding common smoothhound shark population based on both marker types, a contemporary genetic bottleneck may have gone undetected as genetic divergence was very low in some of the study populations. Nonetheless, contemporary restriction to gene flow and historical demographics such as range expansion are proposed as the most likely forces explaining genetic structure in present-day common smoothhound sharks in South Africa. For future sustainable exploitation of common smoothhound shark, the possible existence of two genetically differentiated populations and observed asymmetric gene flow along the South African coast should be taken into consideration. It is also recommended that in the future further evaluations of finescale genetic structure and seasonal migration patterns in this commercially important species are conducted in order to allow integration of this knowledge into existing fisheries management practices. / AFRIKAANSE OPSOMMING: Die ontsyfering van patrone van intraspesie populasie genetiese struktuur in kommersieel belangrike haai spesies is noodsaaklik vir 'n geïntegreerde bestuursbenadering tot visserue en bewaring van plaaslike biodiversiteit. Die hondhaai, Mustelus mustelus, is 'n oorbenutte, kommersiële en sporthengelary belangrike haai spesie in Suid-Afrika. Met inagneming van die kwesbare status van die hondhaai en as gevolg van baie beperkte beskikbare genetiese inligting, het hierdie studie gepoog om molekulêre merkers te ontwikkel, asook om die patrone van genetiese diversiteit en populasie struktuur te ondersoek langs die Suid- Afrikaanse kus deur middel van multilokus data gegenereer uit 12 mikrosatelliet merkers en die mitokondriale geen, NADH dehidrogenase subeenheid 4 (ND4). Die kruis-spesie amplifisering van mikrosatelliete was nuttig vir genetiese diversiteit en populasie genetiese analise van die hondhaai. Hierdie mikrosatelliete kan moontlik help met die molekulêre karakterisering in ander inheemse en kosmopolitaanse spesies en kan as waardevolle hulpmiddels dien in die bewaring van potensieel bedreigde en oorbenutte haai spesies. Vir die mikrosatelliet data is matige vlakke van genetiese diversiteit gevind gebaseer op heterosigositeit, alleliese rykheid en haplotipe diversiteit gevind in 'n totaal van 144 individue getoets oor agt studie populasies. Skattings vir paarsgewyse populasie differensiasie, Fstatistieke, AMOVA en faktoriale ooreenstemming analise het betekenisvolle genetiese struktuur aangedui binne en tussen wes- en ooskus populasies. Daarbenewens, het Bayesian groepering analise twee potensiele voorvaderlike geenpoele waargeneem, ter ondersteuning van die teenwoordigheid van 'n biogeografiese versperring by die Cape Agulhas gebied en dus genetiese diskontinuïteit tussen die Indiese en Atlantiese Oseaan monsters. In teenstelling het die mitokondriale data aangedui dat hierdie haai spesie geneties homogeen is met aansienlike interoseaniese geenvloei. Sulke teenstrydige tekens tussen kern en mitokondriale DNS (mitokern onenigheid) kan toegeskryf word aan 'n aantal faktore en kan eenvoudig wees as gevolg van die inherente verskille in merker eienskappe of 'n aanduiding van geslags sydigeverspreiding. Ten spyte van 'n aanduiding van 'n groeiende hondhaai populasie gebaseer op beide merker tipes, kon 'n hedendaagse genetiese bottelnek onopgemerk gegaan het aangesien genetiese divergensie baie laag was in sommige van die studie populasies. Nietemin, hedendaagse restriksie van geenvloei en historiese demografie soos verbreding van reeks voorkoming word voorgestel as die mees waarskynlike dryfkragte wat genetiese struktuur in die hedendaagse hondhaaie in Suid-Afrika verduidelik. Vir toekomstige volhoubare benutting van die spesie, moet die moontlike bestaan van twee geneties verskillende populasies en waargenome asimmetriese geenvloei langs die Suid-Afrikaanse kus in ag geneem word. Vir die toekoms word dit ook aanbeveel dat verdere evaluerings van fyn-skaal genetiese struktuur en seisoenale migrasie patrone in hierdie kommersiël belangrike spesie uitgevoer word om die integrasie van hierdie kennis in die bestaande bestuur van visserye praktyke toe te laat. / National Research Foundation (NRF)

Mustelus mustelus

Genetic diversity

Population genetic structure

Demographic history

UCTD

Population structuring and dispersal in the highly pelagic Leach's storm-petrel : implications for the EU population

Bicknell, Anthony William James

January 2011

Dispersal is a fundamental process that shapes many aspects of population ecology and evolution. Dramatic local population declines brought about by anthropogenic-driven changes to ecological processes are unfortunately becoming ubiquitous and increasing the urgency to understand dispersal behaviour in many species. For species where direct methods of tracking movement and dispersal are unsuitable, other indirect methods need to be employed to understand and characterise these behaviours. The steep population decline, due to predation, at the largest EU population of Leach’s storm-petrels Oceanodroma leucorhoa (St Kilda, Scotland), and the potential part immigrant birds have in buffering this threat, highlighted the need to understand dispersal and connectivity of widely spaced colonies in this species. The implications for the persistence of local colonies and the wider population of Leach’s storm-petrels could then be assessed. A population genetic analysis of 9 colonies across the North Pacific and Atlantic distribution, using two DNA markers (mtDNA control region and microsatellites), revealed ocean basin differentiation (Global ST = 0.32 P <0.0001, Global FST = 0.04, P <0.0001) but also identified a migrant individual in the Pacific population (STRUCTURE migrant assignment). The Atlantic population was found to be genetically homogenous, with patterns of historical and contemporary gene flow, indicating that long-distance effective dispersal is prevalent in Leach’s storm-petrels within the ocean basin. Bayesian stable isotope analysis of carbon and nitrogen (13C & 15N) provides evidence for natal dispersal as an important dispersal mechanism, and reveals movement of immature birds between colonies during the breeding season as a likely mechanism to promote inter-colony exchange and gene flow. Stable isotope comparison also identified mixing on wintering grounds as another possible influence on dispersal. The potential for immigrant birds to offset the loss caused by predation at the St Kilda colony is supported by these studies, and will likely help the persistence of the colony in the short-term. However, future viability is debateable considering the evidence for both avian and mammalian predation. This research provides a better understanding of the extent and mechanism of dispersal in the Leach’s storm-petrel, which is important to predict the potential impact of environmental change and, where possible, implement effective population management for this species.

591.7

Comparisons of the biological and genetic characteristics of the Mulloway Argyrosomus japonicus (Sciaenidae) in different regions of Western Australia

bryn_farmer@hotmail.com, Bryn Farmer

January 2008

The research conducted for this thesis has produced quantitative data on the biology and population genetic structure of the Mulloway Argyrosomus japonicus in Western Australia, where this sciaenid is recreationally and commercially fished. These data were used 1) to test various hypotheses regarding the relationship between key biological characteristics of A. japonicus and both latitude and environmental variables, 2) to investigate the population structure and genetic characteristics of populations of A. japonicus on the west and south coasts of Western Australia and to assess the relationships between these populations and those of A. japonicus in eastern Australia and South Africa, and 3) to consider the implications of the biological and genetic results for management.

Mulloway

Sciaenidae

growth

maturity

spawning period

habitat

population genetic structure

inbreeding

latitude

Testing the role of Baja California generating biodiversity: A test case characterizing the population genetic structure of Cassin's auklet (Ptychoramphus aleuticus)

Wallace, Sarah

28 September 2012

Characterizing the population genetic structure of a species can provide insight into isolating effects of local adaptation and genetic drift, and homogenizing effects of gene flow. The relative interplay between gene flow and genetic drift can indicate whether multiple conservation units are needed to preserve biodiversity. Baja California, Mexico is a biodiversity hotspot where many individuals are genetically differentiated from conspecific individuals breeding elsewhere. Cassin’s auklet (Ptychoramphus aleuticus), a zooplanktivorous seabird, breeds in colonies along the Pacific coast of North America. One subspecies, P. a. australe, is described from Baja California and another, P. a. aleuticus, is described from the rest of its range to the Aleutian Islands, Alaska. Many of the colonies throughout its range have been declining in numbers likely as a result of decreases in food availability in cold-water upwellings along the coast. The mitochondrial control region and eleven nuclear microsatellites were analyzed using programs based on coalescent and Bayesian theory to determine how the southern subspecies compares genetically to the main subspecies. First, population genetic structure was characterized throughout Cassin’s auklet’s breeding range using pairwise genetic differentiation indices, hierarchical analysis of variance, statistical parsimony and Bayesian clustering methods. The two subspecies were genetically differentiated but individuals breeding in the Channel Islands were more genetically similar to P. a. australe individuals. Population genetic differentiation was not evident within the two genetic groups. Second, gene flow between the two genetic groups was estimated using coalescent and Bayesian methods. Significant gene flow was estimated from the northern group (Aleutian Islands to Southeast Farallon Islands) into the southern group (Channel Islands to San Benito Island) but not from the southern group into the northern group since the time of divergence, possibly as a result of the non-breeding distribution. Results show that the two genetic populations diverged recently and the populations have experienced a recent population change in size. Restrictions in home range and foraging range may cause population genetic differentiation, resulting in two distinct management units. Genetic differentiation of the southern population provides support for Baja California and southern California being a biodiversity hotspot. / Thesis (Master, Biology) -- Queen's University, 2012-09-28 14:02:24.007

seabird

Baja California

gene flow

conservation

Cassin's auklet

population genetic structure

Population structure and genetic diversity of Southeast Queensland populations of the Wallum Froglet, Crinia Tinnula (Tschudi)

Renwick, Juanita

January 2006

Genetic diversity is a fundamental attribute that contributes to a species evolutionary survival. In recent times, conservation managers have recognized the need to preserve genetic diversity of declining species, and have also acknowledged the utility of genetic markers for describing genetic and ecological relationships within and among populations. Information obtained from genetic studies can be used in conjunction with information on population demography, land use patterns and habitat distribution to develop effective management strategies for the conservation of species in decline. The wallum froglet, Crinia tinnula, is one of Australia's smallest habitat specialist anurans. In recent years there has been a dramatic decrease in population numbers of this species. The habitat to which C.tinnula is endemic ('wallum' habitat) is restricted to low coastal plains along the southeast Queensland and northern New South Wales coastline. As human populations in this region expanded, the coastal areas have undergone significant development and large areas of wallum habitat have been cleared. The effect has been to convert once largely continuous patches of coastal heathland in to a matrix of small habitat patches within an area undergoing rapid urban expansion. This study aimed to document levels and patterns of genetic diversity and to define the population structure of C.tinnula populations within southeast Queensland, with the objective of defining possible conservation management units for this species. Results from 12S and COI mitochondrial markers clearly showed that two distinct evolutionary lineages of C.tinnula are present within southeast Queensland. The high level of divergence between lineages and strict geographic partitioning suggests long term isolation of C.tinnula populations. It is hypothesized that ancestral C.tinnula populations were once confined to wallum habitat refugia during the Pliocene resulting in phylogeographic delineation of 'northern' and 'southern' C.tinnula clades. Populations within each geographic region show evidence of range contraction and expansion, with subsequent restricted gene flow. Levels of genetic diversity appear, largely, to be the product of historical associations rather than contemporary gene flow. A revision of the current systematics of C.tinnula is required to ensure that discrete population groups are recognized as distinct evolutionary lineages and will therefore be protected accordingly.

Crinia tinnula

population genetic structure

phylogeography

Pliocene

mitochondrial DNA

12S

COI

wallum

Southeast Queensland

POPULATION GENETICS OF GOLDEN MICE (OCHROTOMYS NUTTALLI) AND WHITE-FOOTED MICE (PEROMYSCUS LEUCOPUS)

Devine, Jill Christine

01 December 2012

Golden mice (Ochrotomys nuttalli) are generally an elusive and rare species throughout their geographic range in the southeastern United States. They are considered to be habitat specialists that prefer dense understory consisting of shrubs and vines. Golden mice are less vagile, and likely disperse shorter distances than other sympatric species such as the white-footed mouse (Peromyscus leucopus). Conversely, white-footed mice are considered habitat generalists that inhabit a variety of habitat types, are more vagile, and disperse farther than golden mice. Because of this it is likely that golden mice have a lower genetic diversity and are more genetically subdivided than white-footed mice. In southern Illinois, golden mice are on the periphery of their range, which is one of the reasons they are on the state-threatened list in Illinois. It has been hypothesized that populations on the periphery of a species range will have more population structure and lower genetic diversity than populations in the core of the range. Tissue samples for golden mice and white-footed mice were collected from 24 sites throughout southern Illinois and 24 sites throughout the golden mouse core range. I analyzed 13 and 10 microsatellite markers as well as 594 and 624 base pairs of the mitochondrial control region for golden mice and white-footed mice, respectively, to characterize and compare the genetic diversity and population structure of both species. Overall haplotype diversity (0.76) and nucleotide diversity (0.20%) was lower in golden mice compared to white footed mice (0.99 and 1.97%). Results of an AMOVA using the mitochondrial control region revealed more subdivision among the 3 populations of golden mice (Φst = 0.099, P < 0.001) than among the 3 populations of white-footed mice (Φst = 0.058, P < 0.001). Microsatellite loci showed a similar trend with overall FST values of 0.027 (P < 0.001) for golden mice and 0.004 (P = 0.137) for white-footed mice. I intended to compare golden mouse individuals from southern Illinois and the core of the range, but too few individuals were collected from the core. More samples need to be collected throughout the core of the range to better understand the population genetics of golden mice in the core of the range compared to the periphery.

genetic diversity

Ochrotomys nuttalli

Peromyscus leucopus

microsatellites

mtDNA

population genetic structure

Behavioural ecology and population genetics of the African wild cat, Felis silvestris Forster 1870, in the southern Kalahari

Herbst, Marna

23 October 2010

Please read the abstract in the section 00front of this document. / Thesis (PhD)--University of Pretoria, 2010. / Zoology and Entomology / unrestricted

African wild cat

Kalahari

South africa

UCTD

Landscape Ecology of Eastern Wild Turkeys in Mississippi

Davis, Annie Moriah

12 August 2016

The effects of landscape structure on wildlife populations have drawn more attention from ecologists and wildlife managers as landscapes have rapidly changed worldwide. The objectives of this study were to (1) conduct a statewide habitat suitability assessment for wild turkeys (Meleagris gallopavo) in Mississippi using machine learning methods; (2) determine landscape-abundance relationships of wild turkeys at 2 spatial scales; and (3) measure genetic distinction of wild turkey populations in Mississippi. I found that habitat suitability for wild turkeys was positively related to amount of forest cover. Wild turkey relative abundance peaked at an optimal hardwood forest proportion of 0.29 and increased with enhanced landscape configuration at the annual dispersal scale, supporting the landscape composition hypothesis. Using microsatellite analysis of 224 birds, I found 3 distinct genetic clusters in Mississippi; however, population genetic differentiation neither fit to the isolation by distance or isolation by resistance models but may have behavioral cues.

Population genetic structure

Machine learning

Landscape-abundance relationship

Habitat suitability model

Habitat management

Rapid divergence of local populations with different color forms in the dung beetle Phelotrupes auratus revealed by population genomics analyses / 集団ゲノム解析で明らかになった食糞性甲虫オオセンチコガネにおける異なる色彩型の地域集団の急速な分化

Araki, Yoshifumi

23 January 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24310号 / 理博第4880号 / 新制||理||1698(附属図書館) / 京都大学大学院理学研究科生物科学専攻 / (主査)教授 曽田 貞滋, 准教授 渡辺 勝敏, 教授 中務 真人 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

genomic analysis

population genetic structure

demographic history

local population

structural coloration

population divergence

dung beetle

400