Genetic diversity of pod traits in local populations of Medicago ciliaris L.

Land-use intensity (LUI) is assumed to impact the genetic structure of organisms. While effects of landscape structure on the genetics of local populations have frequently been analysed, potential effects of variation in LUI on the genetic diversity of local populations have mostly been neglected. In this study, we used six polymorphic microsatellites to analyse the genetic effects of variation in land use in the highly abundant grasshopper Chorthippus parallelus . We sampled a total of 610 individuals at 22 heterogeneous grassland sites in the Hainich-Dün region of Central Germany. For each of these grassland sites we assessed habitat size, LUI (combined index of mowing, grazing and fertilization), and the proportion of grassland adjoining the sampling site and the landscape heterogeneity (the latter two factors within a 500 m buffer zone surrounding each focal site). We found only marginal genetic differentiation among all local populations and no correlation between geographical and genetic distance. Habitat size, LUI and landscape characteristics had only weak effects on most of the parameters of genetic diversity of C. parallelus ; only expected heterozygosity and the grasshopper abundances were affected by interacting effects of LUI, habitat size and landscape characteristics. The lack of any strong relationships between LUI, abundance and the genetic structure might be due to large local populations of the species in the landscape, counteracting local differentiation and potential genetic drift effects.

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The spatial genetic structure of bank vole (Myodes glareolus) and yellow-necked mouse (Apodemus flavicollis) populations: The effect of distance and habitat barriers

Animal Biology ◽

10.1163/157075609x437691 ◽

2009 ◽

Vol 59 (2) ◽

pp. 169-187 ◽

Cited By ~ 19

Author(s):

Michal Kozakiewicz ◽

Alicja Gryczyńska–Siemiątkowska ◽

Hanna Panagiotopoulou ◽

Anna Kozakiewicz ◽

Robert Rutkowski ◽

...

Keyword(s):

Genetic Diversity ◽

Genetic Structure ◽

Bank Vole ◽

Microsatellite Loci ◽

Myodes Glareolus ◽

Apodemus Flavicollis ◽

Island Populations ◽

Local Populations ◽

Bank Vole Myodes Glareolus ◽

Yellow Necked Mouse

AbstractHabitat barriers are considered to be an important factor causing the local reduction of genetic diversity by dividing a population into smaller sections and preventing gene flow between them. However, the “barrier effect” might be different in the case of different species. The effect of geographic distance and water barriers on the genetic structure of populations of two common rodent species – the yellow-necked mouse (Apodemus flavicollis) and the bank vole (Myodes glareolus) living in the area of a lake (on its islands and on two opposite shores) was investigated with the use of microsatellite fragment analysis. The two studied species are characterised by similar habitat requirements, but differ with regard to the socio-spatial structure of the population, individual mobility, capability to cross environmental barriers, and other factors. Trapping was performed for two years in spring and autumn in north-eastern Poland (21°E, 53°N). A total of 160 yellow-necked mouse individuals (7 microsatellite loci) and 346 bank vole individuals (9 microsatellite loci) were analysed. The results of the differentiation analyses (FST and RST) have shown that both the barrier which is formed by a ca. 300 m wide belt of water (between the island and the mainland) and the actual distance of approximately 10 km in continuous populations are sufficient to create genetic differentiation within both species. The differences between local populations living on opposite lake shores are the smallest; differences between any one of them and the island populations are more distinct. All of the genetic diversity indices (the mean number of alleles, mean allelic richness, as well as the observed and expected heterozygosity) of the local populations from the lakeshores were significantly higher than of the small island populations of these two species separated by the water barrier. The more profound “isolation effect” in the case of the island populations of the bank vole, in comparison to the yellow-necked mouse populations, seems to result not only from the lower mobility of the bank vole species, but may also be attributed to other differences in the animals' behaviour.

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A serendipitous journey from finance to science

Pacific Conservation Biology ◽

10.1071/pc18019 ◽

2018 ◽

Vol 24 (3) ◽

pp. 244

Author(s):

Linda Broadhurst

Keyword(s):

Genetic Diversity ◽

High Genetic Diversity ◽

Local Populations

This paper describes my serendipitous journey from university to the finance sector and back to university and a significant career highlight – shifting the emphasis on collecting seed from small local populations for restoration programs in favour of collecting seed with high genetic diversity.

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Biodiversity Along Core–Periphery Clines

Biodiversity in Drylands ◽

10.1093/oso/9780195139853.003.0008 ◽

2005 ◽

Author(s):

Sergei Volis ◽

Salit Kark

Keyword(s):

Genetic Diversity ◽

Species Diversity ◽

Biological Diversity ◽

Morphological Diversity ◽

Spatial Location ◽

Convention On Biological Diversity ◽

Conservation Priorities ◽

Past Century ◽

Geographical Patterns ◽

Local Populations

The study of biodiversity has received wide attention in recent decades. Biodiversity has been defined in various ways (Gaston and Spicer, 1998, Purvis and Hector 2000, and chapters in this volume). Discussion regarding its definitions is dynamic, with shifts between the more traditional emphasis on community structure to emphasis on the higher ecosystem level or the lower population levels (e.g., chapters in this volume, Poiani et al. 2000). One of the definitions, proposed in the United Nations Convention on Biological Diversity held in Rio de Janeiro (1992) is “the diversity within species, between species and of ecosystems.” The within-species component of diversity is further defined as “the frequency and diversity of different genes and/or genomes . . .” (IUCN 1993) as estimated by the genetic and morphological diversity within species. While research and conservation efforts in the past century have focused mainly on the community level, they have recently been extended to include the within-species (Hanski 1989) and the ecosystem levels. The component comprising within-species genetic and morphological diversity is increasingly emphasized as an important element of biodiversity (UN Convention 1992). Recent studies suggest that patterns of genetic diversity significantly influence the viability and persistence of local populations (Frankham 1996, Lacy 1997, Riddle 1996, Vrijenhoek et al. 1985). Revealing geographical patterns of genetic diversity is highly relevant to conservation biology and especially to explicit decision-making procedures allowing systematic rather than opportunistic selection of populations and areas for in situ protection (Pressey et al. 1993). Therefore, studying spatial patterns in within-species diversity may be vital in defining and prioritizing conservation efforts (Brooks et al. 1992). Local populations of a species often differ in the ecological conditions experienced by their members (Brown 1984, Gaston 1990, Lawton et al. 1994). These factors potentially affect population characteristics, structure, and within-population genetic and morphological diversity (Brussard 1984, Lawton 1995, Parsons 1991). The spatial location of a population within a species range may be related to its patterns of diversity (Lesica and Allendorf 1995). Thus, detecting within-species diversity patterns across distributional ranges is important for our understanding of ecological and evolutionary (e.g., speciation) processes (Smith et al. 1997), and for the determination of conservation priorities (Kark 1999).

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Geographical Gradients of Genetic Diversity and Differentiation among the Southernmost Marginal Populations of Abies sachalinensis Revealed by EST-SSR Polymorphism

Forests ◽

10.3390/f11020233 ◽

2020 ◽

Vol 11 (2) ◽

pp. 233 ◽

Cited By ~ 1

Author(s):

Keiko Kitamura ◽

Kentaro Uchiyama ◽

Saneyoshi Ueno ◽

Wataru Ishizuka ◽

Ikutaro Tsuyama ◽

...

Keyword(s):

Genetic Diversity ◽

Genetic Variation ◽

Local Population ◽

Distribution Center ◽

Population History ◽

Peripheral Populations ◽

Abies Sachalinensis ◽

Marginal Populations ◽

Local Populations ◽

Longitudinal Gradients

Research Highlights: We detected the longitudinal gradients of genetic diversity parameters, such as the number of alleles, effective number of alleles, heterozygosity, and inbreeding coefficient, and found that these might be attributable to climatic conditions, such as temperature and snow depth. Background and Objectives: Genetic diversity among local populations of a plant species at its distributional margin has long been of interest in ecological genetics. Populations at the distribution center grow well in favorable conditions, but those at the range margins are exposed to unfavorable environments, and the environmental conditions at establishment sites might reflect the genetic diversity of local populations. This is known as the central-marginal hypothesis in which marginal populations show lower genetic variation and higher differentiation than in central populations. In addition, genetic variation in a local population is influenced by phylogenetic constraints and the population history of selection under environmental constraints. In this study, we investigated this hypothesis in relation to Abies sachalinensis, a major conifer species in Hokkaido. Materials and Methods: A total of 1189 trees from 25 natural populations were analyzed using 19 EST-SSR loci. Results: The eastern populations, namely, those in the species distribution center, showed greater genetic diversity than did the western peripheral populations. Another important finding is that the southwestern marginal populations were genetically differentiated from the other populations. Conclusions: These differences might be due to genetic drift in the small and isolated populations at the range margin. Therefore, our results indicated that the central-marginal hypothesis held true for the southernmost A. sachalinensis populations in Hokkaido.

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Genetic diversity of Taraxacum officinale Wigg. local populations in the habitats of Nizhniy Tagil different in the level of technogenic load

10.18699/biogenevo-2018-03 ◽

2018 ◽

pp. 9-9

Keyword(s):

Genetic Diversity ◽

Taraxacum Officinale ◽

Local Populations

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GENIC HETEROZYGOSITY AND PROTEIN POLYMORPHISM AMONG LOCAL POPULATIONS OF OENOTHERA BIENNIS

Genetics ◽

10.1093/genetics/79.3.477 ◽

1975 ◽

Vol 79 (3) ◽

pp. 477-491

Author(s):

Donald A Levin

Keyword(s):

Genetic Diversity ◽

Genetic Structure ◽

Gene Frequency ◽

Genetic Variance ◽

Polymorphic Locus ◽

Cook County ◽

Oenothera Biennis ◽

Polymorphic Loci ◽

Local Populations ◽

The Mean

ABSTRACT Twenty enzyme loci were studied in 44 Illinois populations of Oenothera biennis; four were polymorphic. Most of the variation was distributed between populations. Fifty-nine percent of the populations had one genotype, 27% two genotypes and the remaining 16% from three to five genotypes; the average was 1.50. The proportion of genetic diversity present in single populations is.38 of that present in the state. Members of single populations were uniformly heterozygous for 1 to 4 loci. The mean heterozygosity per population ranged from 0 to 20%. For Illinois populations collectively, heterozygosity averaged 4.5%. There was much gene frequency heterogeneity between populations. The true standardized genetic variance among populations for alleles at polymorphic loci varied from.40 to.78. Populations from Cook County were much more similar inter se than those downstate, had fewer genotypes and polymorphic loci, and had less heterozygosity than downstate populations. The mean normalized genetic identity among Cook County populations was.987 versus.947 for downstate populations. The mean number of genotypes per population in Cook County was 1.06 versus 2.40 in downstate populations. There was only one polymorphic locus in Cook County, VLP. The genetic structure of Oe. biennis suggests that single populations are colonized by one, or at best a few individuals. Cook County populations are judged to be less variable than downstate populations because the mean age of the populations probably is less than that of those downstate.

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Patterns of genetic diversity in the sumac gall aphid, Melaphis rhois

Genome ◽

10.1139/g91-117 ◽

1991 ◽

Vol 34 (5) ◽

pp. 757-762 ◽

Cited By ~ 28

Author(s):

Paul D. N. Hebert ◽

Terrie L. Finston ◽

Robert Foottit

Keyword(s):

Genetic Diversity ◽

Life Cycle ◽

Gene Flow ◽

Gene Frequency ◽

Dispersal Ability ◽

Pest Species ◽

Prior Work ◽

Local Populations ◽

Important Interaction ◽

Plant Characteristics

In contrast to prior work on aphids, which has focused on pest species, the present study involved the analysis of genetic diversity in Melaphis rhois, a species that employs sumac and moss as alternate hosts. The life cycle involves a spring migration to sumac, with each sexual female producing a single offspring, which elicits a gall and subsequently proliferates clonally within it. Allozyme surveys at 52 sites in Ontario and Quebec established the absence of migration among galls and indicated that this species shares the low level of genetic diversity found in pest aphids. Genotypic frequencies in local populations of M. rhois showed frequent heterozygote deficits, suggesting the prevalence of inbreeding. Gene frequency divergence among populations was exceptionally pronounced, providing further evidence that gene flow was restricted. The unusual genetic attributes of this species suggest the important interaction among host-plant characteristics and the dispersal ability of aphids and their genetic systems.Key words: aphid, Melaphis, parthenogenesis, allozyme, cyclic parthenogen.

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