Authors
Christian T. Smit,h
Anton Antonovich,
William D. Templin,
Carita M. Elfstrom,
Shawn R. Narum,
Lisa W. Seeb
Report Reference
#Transactions
of the American Fisheries Society
(2007) 136:1674-1687
Publication Date
29 Nov
2007
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Impacts
of Marker Class Bias Relative to Locus-Specific Variability on Population
Inferences in Chinook Salmon: A Comparison of Single-Nucleotide Polymorphisms
with Short Tandem Repeats and Allozymes
Abstract |
| Single-nucleotide
polymorphisms (SNPs) exhibit several attributes that make them appealing
as a class of genetic markers for applications in ecology and evolution.
Two commonly cited limitations of SNPs in this capacity are that ascertainment
bias and natural selection may shape allele frequencies of these markers,
thus biasing estimates of population structure. The impacts of ascertainment
bias and selection on estimates of population parameters have been
demonstrated in a few model species, but their impacts relative to
locus-specific variability and other potential complications on structure
inferences in wild populations are unclear. We examined 22 allozymes,
9 short tandem repeats (STRs), and 41 SNPs in approximately 1,300
Chinook salmon Oncorhynchus tshawytscha representing 16 collections.
We used plots of the genetic differentiation index FST
versus heterozygosity and sequence criteria to identify SNPs that
might be under natural selection. We then calculated several measures
of population structure based on the three marker sets and a subset
of the SNPs from which loci identified as likely targets of natural
selection had been removed. Correlation of genetic distances between
collections was stronger between allozymes and SNPs than between either
of these markers and STRs, suggesting that the influences of marker
class bias (e.g., selection and ascertainment bias) were smaller than
impacts of locus-specific effects. Divergence estimates between SNP
ascertainment populations were not significantly higher when based
on SNPs than when based on other markers. Overall divergence (FST)
was higher for SNPs than for allozymes; however, the choice of FST
estimator influenced the relative values for STRs and SNPs. Estimates
of within-population diversity based on allozymes and STRs correlated
better with each other than with estimates based on SNPs; such estimates
based on SNPs were relatively low for collections from populations
outside the geographic coverage of the SNP ascertainment sample. |
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(172
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