Abstract
Elucidating genetic mechanisms of adaptation is a goal of central importance in evolutionary biology, yet few empirical studies have succeeded in documenting causal links between molecular variation and organismal fitness in natural populations. Here we report a population genetic analysis of a two-locus α-globin polymorphism that underlies physiological adaptation to high-altitude hypoxia in natural populations of deer mice, Peromyscus maniculatus. This system provides a rare opportunity to examine the molecular underpinnings of fitness-related variation in protein function that can be related to a well-defined selection pressure. We surveyed DNA sequence variation in the duplicated α-globin genes of P. maniculatus from high- and low-altitude localities (i) to identify the specific mutations that may be responsible for the divergent fine-tuning of hemoglobin function and (ii) to test whether the genes exhibit the expected signature of diversifying selection between populations that inhabit different elevational zones. Results demonstrate that functionally distinct protein alleles are maintained as a long-term balanced polymorphism and that adaptive modifications of hemoglobin function are produced by the independent or joint effects of five amino acid mutations that modulate oxygen-binding affinity.
Highlights
Many long-standing questions about genetic mechanisms of adaptation remain unanswered due to the difficulty of integrating molecular data with evidence for causal effects on organismal fitness
Accession Numbers The GenBank accession numbers for all sequences discussed in this paper are EF369525– EF370032
Accession Numbers The GenBank (http://www/ncbi.nlm.nih.gov/Genbank) accession numbers for all sequences discussed in this paper are EF369525– EF370032
Summary
Many long-standing questions about genetic mechanisms of adaptation remain unanswered due to the difficulty of integrating molecular data with evidence for causal effects on organismal fitness. Analysis of DNA sequence variation at the underlying genes could guide the identification of specific nucleotide changes that are responsible for functional modifications of biochemical or physiological pathways, and could shed light on the role of natural selection in maintaining the observed variation in protein function [1,2] This approach holds much promise, very few studies have successfully documented a mechanistic link between allelic variation in protein function and fitness-related variation in wholeorganism physiology [3,4,5,6,7]. The three nonrecombinant genotypes exhibit a highly consistent rankorder of blood oxygen affinities when tested under both highand low-altitude conditions: mice with the a0c0/a0c0 genotype exhibit the highest affinity (the most left-shifted oxygen dissociation curve), mice with the a1c1/a1c1 genotype exhibit the lowest affinity (the most right-shifted dissociation curve), and the a0c0/a1c1 double heterozygotes are intermediate [12,13] In these experiments, the wild-derived strains of mice carried different a-globin haplotypes in identical-by-.
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