Identifying environmental factors associated with the genetic structure of the New Zealand scallop: linking seascape genetics and ecophysiological tolerance

<p>Knowledge about the population genetic structure of species and the factors shaping such patterns is crucial for effective management and conservation. The complexity of New Zealand’s marine environment presents a challenge for management and the classification of its marine biogeographic areas. As such, it is an interesting system to investigate marine connectivity dynamics and the evolutionary processes shaping the population structure of marine species. An accurate description of spatial and temporal patterns of dispersal and population structure requires the use of tools capable of incorporating the variability of the mechanisms involved. However, these techniques are yet to be broadly applied to New Zealand marine organisms. This study used genetic markers to assess the genetic variation of the endemic New Zealand scallop, Pecten novaezelandiae, at different spatial and temporal scales. A multidisciplinary approach was used integrating genetic with environmental data (seascape genetics) and hydrodynamic modelling tools. P. novaezelandiae supports important commercial, recreational and customary fisheries but there is no previous information about its genetic structure. Therefore, twelve microsatellite markers were developed for this study (Chapter 2). Samples (n=952) were collected from 15 locations to determine the genetic structure across the distribution range of P. novaezelandiae. The low genetic structure detected in this study is expected given the recent evolutionary history, the large reproductive potential and the pelagic larval duration of the species (approximately 3 weeks). A significant isolation by distance signal and a degree of differentiation from north to south was apparent, but this structure conflicted with some evidence of panmixia. A latitudinal genetic diversity gradient was observed that might reflect the colonisation and extinction events and insufficient time to reach migration-drift equilibrium during a recent range expansion (Chapter 3). A seascape genetic approach was used to test for associations between patterns of genetic variation in P. novaezelandiae and environmental variables (three geospatial and six environmental variables). Although the geographic distance between populations was an important variable explaining the genetic variation among populations, it appears that levels of genetic differentiation are not a simple function of distance. Evidence suggests that some environmental factors such as freshwater discharge and suspended particulate matter can be contributing to the patterns of genetic differentiation of P. novaezelandiae in New Zealand (Chapter 4). Dispersal of P. novaezelandiae was investigated at a small spatial and temporal scale in the Coromandel fishery using genetic markers integrated with hydrodynamic modelling. For the spatial analysis, samples (n=402) were collected in 2012 from 5 locations and for the temporal analysis samples (n=383) were collected in 2012 and 2014 from 3 locations. Results showed small but significant spatial and temporal genetic differentiation, suggesting that the Coromandel fishery does not form a single panmictic unit with free gene flow and supporting a model of source-sink population dynamics (Chapter 5). The importance of using multidisciplinary approaches at different spatial and temporal scales is widely recognized as a means to better understand the complex processes affecting marine connectivity. The outcomes of this study highlight the importance of incorporating these different approaches, provide vital information to assist in effective management and conservation of P. novaezelandiae and contribute to our understanding of evolutionary processes shaping population structure of marine species.</p>

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Spatial and temporal genetic structure of the New Zealand scallop Pecten novaezelandiae: A multidisciplinary perspective

10.26686/wgtn.17009846 ◽

2021 ◽

Author(s):

◽

Catarina Nunes Soares Silva

Keyword(s):

Population Structure ◽

Genetic Variation ◽

New Zealand ◽

Genetic Structure ◽

Genetic Differentiation ◽

Marine Species ◽

Effective Management ◽

Spatial And Temporal Scales ◽

Marine Connectivity ◽

Management And Conservation

<p>Knowledge about the population genetic structure of species and the factors shaping such patterns is crucial for effective management and conservation. The complexity of New Zealand’s marine environment presents a challenge for management and the classification of its marine biogeographic areas. As such, it is an interesting system to investigate marine connectivity dynamics and the evolutionary processes shaping the population structure of marine species. An accurate description of spatial and temporal patterns of dispersal and population structure requires the use of tools capable of incorporating the variability of the mechanisms involved. However, these techniques are yet to be broadly applied to New Zealand marine organisms. This study used genetic markers to assess the genetic variation of the endemic New Zealand scallop, Pecten novaezelandiae, at different spatial and temporal scales. A multidisciplinary approach was used integrating genetic with environmental data (seascape genetics) and hydrodynamic modelling tools. P. novaezelandiae supports important commercial, recreational and customary fisheries but there is no previous information about its genetic structure. Therefore, twelve microsatellite markers were developed for this study (Chapter 2). Samples (n=952) were collected from 15 locations to determine the genetic structure across the distribution range of P. novaezelandiae. The low genetic structure detected in this study is expected given the recent evolutionary history, the large reproductive potential and the pelagic larval duration of the species (approximately 3 weeks). A significant isolation by distance signal and a degree of differentiation from north to south was apparent, but this structure conflicted with some evidence of panmixia. A latitudinal genetic diversity gradient was observed that might reflect the colonisation and extinction events and insufficient time to reach migration-drift equilibrium during a recent range expansion (Chapter 3). A seascape genetic approach was used to test for associations between patterns of genetic variation in P. novaezelandiae and environmental variables (three geospatial and six environmental variables). Although the geographic distance between populations was an important variable explaining the genetic variation among populations, it appears that levels of genetic differentiation are not a simple function of distance. Evidence suggests that some environmental factors such as freshwater discharge and suspended particulate matter can be contributing to the patterns of genetic differentiation of P. novaezelandiae in New Zealand (Chapter 4). Dispersal of P. novaezelandiae was investigated at a small spatial and temporal scale in the Coromandel fishery using genetic markers integrated with hydrodynamic modelling. For the spatial analysis, samples (n=402) were collected in 2012 from 5 locations and for the temporal analysis samples (n=383) were collected in 2012 and 2014 from 3 locations. Results showed small but significant spatial and temporal genetic differentiation, suggesting that the Coromandel fishery does not form a single panmictic unit with free gene flow and supporting a model of source-sink population dynamics (Chapter 5). The importance of using multidisciplinary approaches at different spatial and temporal scales is widely recognized as a means to better understand the complex processes affecting marine connectivity. The outcomes of this study highlight the importance of incorporating these different approaches, provide vital information to assist in effective management and conservation of P. novaezelandiae and contribute to our understanding of evolutionary processes shaping population structure of marine species.</p>

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Significant genetic differences among Heterodera schachtii populations within and among sugar beet production areas

Nematology ◽

10.1163/15685411-00003297 ◽

2020 ◽

Vol 22 (2) ◽

pp. 165-177 ◽

Cited By ~ 1

Author(s):

Rasha Haj Nuaima ◽

Johannes Roeb ◽

Johannes Hallmann ◽

Matthias Daub ◽

Holger Heuer

Keyword(s):

Genetic Variation ◽

Genetic Structure ◽

Population Genetic Structure ◽

Population Genetic ◽

Spatial Scales ◽

Geographic Distance ◽

Heterodera Schachtii ◽

Parasitic Nematodes ◽

Neutral Genetic Variation ◽

Production Areas

Summary Characterising the non-neutral genetic variation within and among populations of plant-parasitic nematodes is essential to determine factors shaping the population genetic structure. This study describes the genetic variation of the parasitism gene vap1 within and among geographic populations of the beet cyst nematode Heterodera schachtii. Forty populations of H. schachtii were sampled at four spatial scales: 695 km, 49 km, 3.1 km and 0.24 km. DGGE fingerprinting showed significant differences in vap1 patterns among populations. High similarity of vap1 patterns appeared between geographically close populations, and occasionally among distant populations. Analysis of spatially sampled populations within fields revealed an effect of tillage direction on the vap1 similarity for two of four studied fields. Overall, geographic distance and similarity of vap1 patterns of H. schachtii populations were negatively correlated. In conclusion, the population genetic structure was shaped by the interplay between the genetic adaptation and the passive transport of this nematode.

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Effects of habitat fragmentation on population genetic structure in the white-footed mouse (Peromyscus leucopus)

Canadian Journal of Zoology ◽

10.1139/z00-201 ◽

2001 ◽

Vol 79 (2) ◽

pp. 285-295 ◽

Cited By ~ 33

Author(s):

Catherine A Mossman ◽

Peter M Waser

Keyword(s):

Genetic Variation ◽

Genetic Structure ◽

Habitat Fragmentation ◽

Genetic Differentiation ◽

Population Genetic Structure ◽

Population Genetic ◽

Peromyscus Leucopus ◽

Marginal Effect ◽

Geographic Scale ◽

White Footed Mouse

Habitat fragmentation may have significant consequences for population genetic structure because geographic distance and physical barriers may impede gene flow. In this study, we investigated whether habitat fragmentation affects fine-scale genetic structure of populations of the white-footed mouse (Peromyscus leucopus). We studied 27 populations of P. leucopus, 17 in continuous forest and 10 in isolated woodlots. Populations were trapped in pairs that were either 500 or 2000 m apart. We estimated genetic variation at eight P. leucopus specific microsatellite DNA loci. We discovered significant genetic variation within all populations, but no significant differences in numbers of alleles or heterozygosity between populations. For given population pairs, we found significant genetic differentiation even at very short distances, based on multilocus FST estimates. The amount of genetic differentiation between population pairs was similar in the two habitats. Distance had a marginal effect on genetic differentiation when comparing paired populations separated by 2000 m with those separated by 500 m. However, at a larger geographic scale, there was no evidence of isolation by distance. This study confirms that microsatellite-based studies have the potential to detect interpopulation differentiation at an extremely local scale, and suggests that habitat fragmentation has surprisingly few effects on P. leucopus genetic structure.

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Does advertisement call variation coincide with genetic variation in the genetically diverse frog taxon currently known as Leptodactylus fuscus (Amphibia: Leptodactylidae)?

Anais da Academia Brasileira de Ciências ◽

10.1590/s0001-37652003000100006 ◽

2003 ◽

Vol 75 (1) ◽

pp. 39-54 ◽

Cited By ~ 25

Author(s):

W. RONALD HEYER ◽

YANA R. REID

Keyword(s):

Genetic Variation ◽

South America ◽

Genetic Differentiation ◽

Related Species ◽

Geographic Distance ◽

Single Species ◽

Advertisement Call ◽

Closely Related Species ◽

Multiple Species ◽

Disturbed Habitats

The frog Leptodactylus fuscus is found throughout much of South America in open and disturbed habitats. Previous study of genetic differentiation in L. fuscus demonstrated that there was lack of genetic exchange among population units consistent with multiple species, rather than a single species. We examine advertisement vocalizations of L. fuscus to determine whether call variation coincides with genetic differentiation. Calls were analyzed for 32 individual frogs from 25 localities throughout the distributional range of L. fuscus. Although there is variation in calls among geographic samples, call variation is not concordant with genetic variation or geographic distance and the call variation observed is less than that typically found among other closely related species of Leptodactylus. This study is an example of the rare pattern of strong genetic differentiation unaccompanied by salient differences in advertisement calls. The relative infrequency of this pattern as currently understood may only reflect the lack of detailed analyses of genetic and acoustic differentiation within population systems currently understood as single species with substantial geographic distributions.

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Genetic structure of marginal populations of white spruce (Piceaglauca) at its northern limit of distribution in Nouveau-Québec

Canadian Journal of Forest Research ◽

10.1139/x89-211 ◽

1989 ◽

Vol 19 (11) ◽

pp. 1371-1379 ◽

Cited By ~ 29

Author(s):

Monique Tremblay ◽

Jean-Pierre Simon

Keyword(s):

Genetic Structure ◽

Genetic Differentiation ◽

Geographic Distance ◽

White Spruce ◽

Gene Exchange ◽

Northern Limit ◽

Marginal Populations ◽

Subarctic Region ◽

Hardy Weinberg Equilibrium ◽

Or Gene

The genetic structure of six marginal populations of white spruce (Piceaglauca (Moench) Voss) located at Richmond Gulf in the subarctic region of Nouveau-Québec, and one southern population located at Kuujjuaraapik (Poste-de-la-Baleine) were analyzed by acrylamide gel electrophoresis for seven enzyme systems. The analysis of 27 loci disclosed an average polymorphism of 76.2% and a level of heterozygosity of 0.319. Data based on Wright's; statistics: indicated a deficiency of heterozygotes for 60% of the loci, as calculated from the Hardy–Weinberg equilibrium. These results, coupled with the very low percentage of filled seeds in cones of all populations, suggest that a certain level of inbreeding or gene exchange among near-neighbour relatives influences the genetic structure of these populations. The genetic differentiation among populations is relatively high for a conifer [Formula: see text] and is not correlated with geographic distance. The age of trees, covering a period of 400 years affected by climatic changes, does not contribute to the genetic differentiation of the populations.

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Genetic variation and dispersal patterns in three varieties of Pinus caribaea (Pinaceae) in the Caribbean Basin

Plant Ecology and Evolution ◽

10.5091/plecevo.2018.1343 ◽

2018 ◽

Vol 151 (1) ◽

pp. 61-76

Author(s):

Virginia Rebolledo Camacho ◽

Lev Jardón Barbolla ◽

Ivón Ramírez Morillo ◽

Alejandra Vázquez-Lobo ◽

Daniel Piñero ◽

...

Keyword(s):

Genetic Variation ◽

Genetic Differentiation ◽

Central America ◽

Migration Rate ◽

Geographic Distance ◽

Caribbean Basin ◽

Pinus Caribaea ◽

The Bahamas ◽

Geological Processes ◽

The Caribbean

Background – Pinus caribaea Morelet comprises three varieties of tropical pines distributed in the Caribbean Basin: P. caribaea var. hondurensis, var. caribaea, and var. bahamensis. The insular and continental distribution of these varieties, as well as the geological processes in the region, have been important factors for analysing evolutionary processes implicated in the diversification of these lineages. In this study, we evaluate the genetic and geographic structure within and between these three varieties in order to infer the possible origin and dispersal routes of these taxa.Methods – We used six polymorphic nuclear microsatellites (nSSR) in fifteen representative populations of the three pine varieties, sampled throughout their natural range in Central America, Cuba and the Bahamas islands.Results – The varieties contain similar levels of genetic variation (mean He = 0.571), with several populations out of Hardy-Weinberg equilibrium, and significant levels of inbreeding (0.097–0.184, P ≤ 0.05). A slight but significant genetic differentiation was found between the varieties (RST = 0.088) and populations (RST= 0.082), and genetic differentiation increased with geographic distance (r2 = 0.263). Distance and Bayesian BAPS analyses generated seven groups; two represented by the two island varieties and the remainder by the Central American populations of var. hondurensis. Migration rate estimates between pairs of groups ranged from M = 0.47 to M = 20.16. Estimates were generally higher from the continent to islands, with the highest migration rate estimated from a continental genetic group to the Cuba island group of var. hondurensis (M = 20.16).Conclusions – This study supports the hypothesis of a recent origin of these pine taxa through the migration of an ancestor from Central America, where the historical demography is associated with events of colonization, expansion and contraction of populations. The genetic variation and differentiation suggest that the three varieties are divergent lineages that currently share allelic variants, indicating that their speciation has not yet completed.

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A strategic sampling design revealed the local genetic structure of cold-water fluvial sculpin: a focus on groundwater-dependent water temperature heterogeneity

10.1101/2021.03.19.435938 ◽

2021 ◽

Author(s):

Souta Nakajima ◽

Masanao Sueyoshi ◽

Shun K. Hirota ◽

Nobuo Ishiyama ◽

Ayumi Matsuo ◽

...

Keyword(s):

Genetic Structure ◽

Low Temperature ◽

Genetic Differentiation ◽

Water Temperature ◽

Sampling Design ◽

Cold Water ◽

Isolation By Distance ◽

Geographic Distance ◽

Sampling Strategy ◽

Genotyping By Sequencing

A key piece of information for ecosystem management is the relationship between the environment and population genetic structure. However, it is difficult to clearly quantify the effects of environmental factors on genetic differentiation because of spatial autocorrelation and analytical problems. In this study, we focused on stream ecosystems and the environmental heterogeneity caused by groundwater and constructed a sampling design in which geographic distance and environmental differences are not correlated. Using multiplexed ISSR genotyping by sequencing (MIG-seq) method, a fine-scale population genetics study was conducted in fluvial sculpin Cottus nozawae, for which summer water temperature is the determinant factor in distribution and survival. There was a clear genetic structure in the watershed. Although a significant isolation-by-distance pattern was detected in the watershed, there was no association between genetic differentiation and water temperature. Instead, asymmetric gene flow from relatively low-temperature streams to high-temperature streams was detected, indicating the importance of low-temperature streams and continuous habitats. The groundwater-focused sampling strategy yielded unexpected results and provided important insights for conservation.

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Assessment of local genetic structure and connectivity of the common eelgrass Zostera marina for seagrass restoration in northern Europe

Marine Ecology Progress Series ◽

10.3354/meps13658 ◽

2021 ◽

Vol 664 ◽

pp. 103-116

Author(s):

L Martínez-García ◽

B Hansson ◽

J Hollander

Keyword(s):

Climate Change ◽

Genetic Variation ◽

Genetic Structure ◽

Genetic Differentiation ◽

Baltic Sea ◽

Zostera Marina ◽

Anthropogenic Impacts ◽

Ecosystem Functions ◽

Long Distance ◽

Seagrass Meadows

Seagrass meadows are one of the most important habitats in coastal regions since they constitute a multifunctional ecosystem providing high productivity and biodiversity. They play a key role in carbon sequestration capacity, mitigation against coastal erosion and as nursery grounds for many marine fish and invertebrates. However, despite these ecosystem functions and services, seagrass meadows are a threatened ecosystem worldwide. In the Baltic Sea, seagrass meadows have declined rapidly, mainly because of eutrophication, anthropogenic activities and climate change. This decline has the potential to erode the genetic variation and genetic structure of the species. In this study, we assessed how genetic variation and genetic differentiation vary among Zostera marina meadows and with a number of environmental characteristics in the county of Scania in southern Sweden. A total of 205 individuals sampled at 12 locations were analysed with 10 polymorphic microsatellite loci. Results showed that in spite of anthropogenic impacts and climate change pressures, locations of Z. marina possessed high genetic variation and weak genetic differentiation, with 3 major genetic clusters. Long-distance dispersal and/or stepping-stone dispersal was found among locations, with higher migration rates within the west coast. Organic matter, salinity and maximum depth appeared to be factors most strongly associated with the genetic structure and morphological variation of Z. marina. These findings contribute significantly in the identification of potential donor sites and the viability of impacted areas to recover from natural recruitment, for the development of effective transplantation measures of Z. marina in the southern Baltic Sea and temperate regions elsewhere.

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Genetic variation between and within populations of Engelmann spruce and subalpine fir

Genome ◽

10.1139/g90-001 ◽

1990 ◽

Vol 33 (1) ◽

pp. 1-8 ◽

Cited By ~ 21

Author(s):

Kathleen L. Shea

Keyword(s):

Genetic Variation ◽

Genetic Structure ◽

Genetic Differentiation ◽

Colorado Front Range ◽

Abies Lasiocarpa ◽

Front Range ◽

Dispersal Patterns ◽

Subalpine Fir ◽

Engelmann Spruce ◽

Inbreeding Coefficients

The genetic structure of Engelmann spruce (Picea engelmannii) and subalpine fir (Abies lasiocarpa) in two adjacent sites in the Colorado Front Range was examined using allozyme data from 21 loci in spruce and 18 loci in fir. The genetic diversity measures of alleles per locus, percent loci polymorphic, and mean heterozygosity did not differ significantly between or within species. However, the observed heterozygosity (0.126 spruce, 0.081 fir) values suggest that Engelmann spruce is more genetically variable than subalpine fir. Mean inbreeding coefficients were twice as high in fir as in spruce (FIS = 0.154 spruce, 0.341 fir). There were significant differences in allele frequencies in both species between and within sites, and among age-classes, with spatial differences greater than temporal differences. F-statistics showed greater genetic differentiation within (FST = 2.3–2.6% spruce, 2.0–2.8% fir) than between sites (FST = 1.7% spruce, 1.3% fir). Both species had higher FST and genetic distance values, yet lower FIS values, for spatial subdivisions within rather than between sites. This pattern suggests that the size of a spatial subdivision, where maximum gene flow is 54 m, approximates the size of the largest panmictic unit. In contrast with studies on other conifers, these results suggest that factors such as differential selection pressures, seed dispersal patterns, and clumped spatial distribution have resulted in genetic differentiation at the microhabitat level in Engelmann spruce and subalpine fir.Key words: genetic variation, genetic structure, allozymes, Engelmann spruce, subalpine fir, microgeographic differentiation.

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