Population structure of the predatory mite Neoseiulus womersleyi in a tea field based on an analysis of microsatellite DNA markers

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Abstract

The predatory mite Neoseiulus womersleyi (Schicha) (Acari: Phytoseiidae) is an important natural enemy of the Kanzawa spider mite, Tetranychus kanzawaki Kishida (Acari: Tetranychidae), in tea fields. Attraction and preservation of natural enemies by habitat management to reduce the need for acaricide sprays is thought to enhance the activity of N. womersleyi. To better conserve N. womersleyi in the field, however, it is essential to elucidate the population genetic structure of this species. To this end, we developed ten microsatellite DNA markers for N. womersleyi. We then evaluated population structure of N. womersleyi collected from a tea field, where Mexican sunflower, Tithonia rotundifolia (Mill.), was planted to preserve N. womersleyi. Seventy-seven adult females were collected from four sites within 200 m. The fixation indexes F _ST among subpopulations were not significantly different. The kinship coefficients between individuals did not differ significantly within a site as a function of the sampling dates, but the coefficients gradually decreased with increasing distance. Bayesian clustering analysis revealed that the population consisted of three genetic clusters, and that subpopulations within 100 m, including those collected on T. rotundifolia, were genetically similar to each other. Given the previously observed population dynamics of N. womersleyi, it appears that the area inhabited by a given cluster of the mite did not exceed 100 m. The estimation of population structure using microsatellite markers will provide valuable information in conservation biological control.

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Most cited references 38

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There is abundant geographic variation in both morphology and gene frequency in most species. The extent of geographic variation results from a balance of forces tending to produce local genetic differentiation and forces tending to produce genetic homogeneity. Mutation, genetic drift due to finite population size, and natural selection favoring adaptations to local environmental conditions will all lead to the genetic differentiation of local populations, and the movement of gametes, individuals, and even entire populations--collectively called gene flow--will oppose that differentiation. Gene flow may either constrain evolution by preventing adaptation to local conditions or promote evolution by spreading new genes and combinations of genes throughout a species' range. Several methods are available for estimating the amount of gene flow. Direct methods monitor ongoing gene flow, and indirect methods use spatial distributions of gene frequencies to infer past gene flow. Applications of these methods show that species differ widely in the gene flow that they experience. Of particular interest are those species for which direct methods indicate little current gene flow but indirect methods indicate much higher levels of gene flow in the recent past. Such species probably have undergone large-scale demographic changes relatively frequently.

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Author and article information

Contributors

: hinomoto@affrc.go.jp

Journal

Journal ID (nlm-ta): Exp Appl Acarol

Title: Experimental & Applied Acarology

Publisher: Springer Netherlands (Dordrecht )

ISSN (Print): 0168-8162

ISSN (Electronic): 1572-9702

Publication date (Electronic): 13 July 2010

Publication date PMC-release: 13 July 2010

Publication date (Print): January 2011

Volume: 53

Issue: 1

Pages: 1-15

Affiliations

[1 ]Natural Enemies Laboratory, Insect Interaction Research Unit, Division of Insect Sciences, National Institute of Agrobiological Sciences, Tsukuba, Ibaraki, 305-8634 Japan

[2 ]Mie Prefecture Agricultural Research Institute, Kameyama, Mie, 519-0104 Japan

[3 ]Mie Prefectural Agricultural College, Matsusaka, Mie, 515-2316 Japan

Article

Publisher ID: 9384

DOI: 10.1007/s10493-010-9384-6

PMC ID: 2992129

PubMed ID: 20625919

SO-VID: f6129e42-4fd2-4115-bf64-0a8120ef5a67

History

Date received : 24 December 2009

Date accepted : 27 June 2010

Custom metadata

ScienceOpen disciplines: Entomology

Keywords: natural enemy,neoseiulus womersleyi,conservation biological control,genetic markers,dispersal,kinship coefficients

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ScienceOpen disciplines: Entomology

Keywords: natural enemy, neoseiulus womersleyi, conservation biological control, genetic markers, dispersal, kinship coefficients

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