Use of Allelic Frequencies to Describe Population Structure

Allendorf, Fred W.; Phelps, Stevan R.

doi:10.1139/f81-203

Cited by 335 publications

(228 citation statements)

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“…10 6 km 2 ), and owing to its heterogeneous hydrographical structure (McGillicuddy et al 2001;Knights 2003), the mating patterns and the dispersal of larvae to the coasts of Europe may not be completely random. Thus, the differences observed among glass eel samples from 2002 may well be the consequence of the eels caught at different sites in Europe being derived from different (finite) sets of parents (Allendorf & Phelps 1981;Waples 1998). This might also explain the IBD signal for cohort 2000, which was mainly a result of the fact that the distant Yugoslavian sample differed slightly from the other samples belonging to this cohort.…”

Section: Discussionmentioning

confidence: 99%

Panmixia in the European eel: a matter of time…

et al. 2005

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The European eel (Anguilla anguilla L.) has been a prime example of the panmixia paradigm because of its extraordinary adaptation to the North Atlantic gyral system, semelparous spawning in the Sargasso Sea and long trans-oceanic migration. Recently, this view was challenged by the suggestion of a genetic structure characterized by an isolation-by-distance (IBD) pattern. This is only likely if spawning subpopulations are spatially and/or temporally separated, followed by non-random larval dispersal. A limitation of previous genetic work on eels is the lack of replication over time to test for temporal stability of genetic structure. Here, we hypothesize that temporal genetic variation plays a significant role in explaining the spatial structure reported earlier for this species. We tested this by increasing the texture of geographical sampling and by including temporal replicates. Overall genetic differentiation among samples was low, highly significant and comparable with earlier studies (F ST Z0.0014; p!0.01). On the other hand, and in sharp contrast with current understandings, hierarchical analyses revealed no significant inter-location genetic heterogeneity and hence no IBD. Instead, genetic variation among temporal samples within sites clearly exceeded the geographical component. Our results provide support for the panmixia hypothesis and emphasize the importance of temporal replication when assessing population structure of marine fish species.

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Section: Discussionmentioning

confidence: 99%

Panmixia in the European eel: a matter of time…

et al. 2005

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“…If fish remain in the vicinity of their hatching location until maturity (see for example, Allendorf and Phelps, 1981;Hansen et al, 1997), most individuals collected in those two small lakes could likely be derived from a small number of progenitors only. Mating could then be biased toward relatives if most dispersal opportunities are restricted to the close surroundings of the lakes.…”

Section: Discussionmentioning

confidence: 99%

Heterozygote deficiencies in small lacustrine populations of brook charr Salvelinus Fontinalis Mitchill (Pisces, Salmonidae): a test of alternative hypotheses

et al. 2002

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Empirical studies of natural populations have commonly reported departures from Hardy-Weinberg expected proportions of heterozygote individuals. Recent advances in statistical population genetics now offer the potential to exploit individual multilocus genotypic information to test more rigorously for possible sources of heterozygote deficiencies. In a previous study in lacustrine brook charr (Salvelinus fontinalis), we reported stronger deficits in small than in large lakes. In the present paper, we propose a methodology for empirically testing alternative hypotheses to identify the cause of the deficits observed in three of the smallest lakes (85, 109 and 182 ha) analysed. First, as in several salmonid species, brook charr may exhibit a trophic polymorphism in north temperate lakes. If morphs are genetically divergent, indiscriminate sampling of both forms would result in less heterozygote individuals than expected

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“…Theory predicts, assuming no selection, that one successful migrant per generation is sufficient to prevent differentiation caused by genetic drift between populations (Nei 1987). Nevertheless, significant differentiation in natural populations can occur with up to 10 migrants per generation (Allendorf & Phelps 1981). In B. glaciale, the reported gene flow value (17 per generation) may still be regarded as very small when compared to very large population sizes of the species (adjusted estimate up to 12 million individuals in Masfjorden alone, Kaartvedt & al.…”

Section: Discussionmentioning

confidence: 99%

Population genetic structure of the glacier lanternfish,Benthosema glaciale(Myctophidae) in Norwegian waters

Suneetha¹,

Salvanes²

2001

Sarsia

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It is hypothesised that the fjords with restricted water circulation may partially isolate fish populations living there. The pelagic life history stages of the mesopelagic lanternfish may potentially subject to dispersal over vast areas, preventing population subdivision. In the present paper, we test the hypothesis of no geographic population genetic structure of B. glaciale in Norwegian waters. Fish samples from six different locations, including five western fjords were analysed using allozyme electrophoresis. Among the 17 loci analysed, nine loci were polymorphic by 0.99 criterion. Deviation from the global (pooled sample) HW equilibrium was detected at two loci, AAT-2* and PGM*, in terms of heterozygote deficiency, indicating a possible population subdivision in the area studied. Supporting such postulate, the allele frequencies at several loci were found significantly different, consequently rejecting the null hypothesis. The individual fjord samples were different from the offshore sample, and some between-fjord heterogeneity in allele frequencies was also found. However, Wright's F ST value was apparently low, but significantly different from zero, indicating a low level of population differentiation in the area studied. Partial isolation of fjord units of B. glaciale as a possible mechanism for genetic differentiation is discussed.

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Use of Allelic Frequencies to Describe Population Structure

Cited by 335 publications

References 0 publications

Panmixia in the European eel: a matter of time…

Panmixia in the European eel: a matter of time…

Heterozygote deficiencies in small lacustrine populations of brook charr Salvelinus Fontinalis Mitchill (Pisces, Salmonidae): a test of alternative hypotheses

Population genetic structure of the glacier lanternfish,Benthosema glaciale(Myctophidae) in Norwegian waters

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