Power of Neutrality Tests to Detect Bottlenecks and Hitchhiking

The power of several neutrality tests to reject a simple bottleneck model is examined in a coalescent framework. Several tests are considered including some relying on the frequency spectrum of mutations and some reflecting the linkage disequilibrium structure of the data. We evaluate the effect of the age and of the strength of the bottleneck, and their interaction. We contrast two qualitatively different bottleneck effects depending on their strength. In genealogical terms, during severe bottlenecks, all lineages coalesce leading to a star-like gene genealogy of the sample. Some time after the bottleneck, once new mutations have arisen, they tend to show an excess of rare variants and a slight excess of haplotypes. On the contrary, more moderate bottlenecks allow several lineages to survive the demographic crash, leading to a balanced genealogy with long internal branches. Soon after the event, data tend to show an excess of intermediate frequency variants and a deficit of haplotypes. We show that for moderate sequencing efforts, severe bottlenecks can be detected only after an intermediate time period has allowed for mutations to occur, preferably by frequency spectrum statistics. Moderate bottlenecks can be more easily detected for more recent events, especially using haplotype statistics. Finally, for a single locus, the bottleneck results closely approximate those of a simple hitchhiking model. The main difference concerns the frequency distribution of mutations and haplotypes after moderate perturbations. Hitchhiking increases the number of rare ancestral mutations and leads to a more predominant major haplotype class. Thus, despite a number of common features between the two processes, hitchhiking cannot be strictly modeled by bottlenecks.

[1]  N. Barton,et al.  Genetic hitchhiking. , 2000, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[2]  J. Fay,et al.  A human population bottleneck can account for the discordance between patterns of mitochondrial versus nuclear DNA variation. , 1999, Molecular biology and evolution.

[3]  Yun-Xin Fu,et al.  New statistical tests of neutrality for DNA samples from a population. , 1996, Genetics.

[4]  Simon Tavaré,et al.  Linkage disequilibrium: what history has to tell us. , 2002, Trends in genetics : TIG.

[5]  R. Hudson,et al.  A test of neutral molecular evolution based on nucleotide data. , 1987, Genetics.

[6]  J. Wall,et al.  Unusual haplotype structure at the proximal breakpoint of In(2L)t in a natural population of Drosophila melanogaster. , 1999, Genetics.

[7]  J. Wall,et al.  Coalescent simulations and statistical tests of neutrality. , 2001, Molecular biology and evolution.

[8]  C. Strobeck Average Number of Nucleotide Differences in a Subpopulation: A Test for Population Sample From Subdivision a Single , 1987 .

[9]  Thomas Wiehe,et al.  The Effect of Strongly Selected Substitutions on Neutral Polymorphism: Analytical Results Based on Diffusion Theory , 1992 .

[10]  W Stephan,et al.  The hitchhiking effect on the site frequency spectrum of DNA polymorphisms. , 1995, Genetics.

[11]  G. A. Watterson On the number of segregating sites in genetical models without recombination. , 1975, Theoretical population biology.

[12]  J. Felsenstein,et al.  Estimating effective population size from samples of sequences: inefficiency of pairwise and segregating sites as compared to phylogenetic estimates. , 1992, Genetical research.

[13]  Molly Przeworski,et al.  The signature of positive selection at randomly chosen loci. , 2002, Genetics.

[14]  F. Depaulis,et al.  Neutrality tests based on the distribution of haplotypes under an infinite-site model. , 1998, Molecular biology and evolution.

[15]  R. Hudson,et al.  Statistical properties of the number of recombination events in the history of a sample of DNA sequences. , 1985, Genetics.

[16]  J K Kelly,et al.  A test of neutrality based on interlocus associations. , 1997, Genetics.

[17]  J. Wall,et al.  A comparison of estimators of the population recombination rate. , 2000, Molecular biology and evolution.

[18]  J. Hein,et al.  Recombination and the molecular clock. , 2000, Molecular biology and evolution.

[19]  F J Ayala,et al.  Evidence for positive selection in the superoxide dismutase (Sod) region of Drosophila melanogaster. , 1994, Genetics.

[20]  F. Depaulis,et al.  Detecting Selective Sweeps with Haplotype Tests , 2005 .

[21]  C. Strobeck,et al.  Average number of nucleotide differences in a sample from a single subpopulation: a test for population subdivision. , 1987, Genetics.

[22]  Jeffrey D. Wall,et al.  Recombination and the power of statistical tests of neutrality , 1999 .

[23]  Justin C. Fay,et al.  Hitchhiking under positive Darwinian selection. , 2000, Genetics.

[24]  N. Barton,et al.  Detecting bottlenecks and selective sweeps from DNA sequence polymorphism. , 2000, Genetics.

[25]  W. Ewens The sampling theory of selectively neutral alleles. , 1972, Theoretical population biology.

[26]  Nicholas H. Barton,et al.  The effect of hitch-hiking on neutral genealogies , 1998 .

[27]  Y. Fu,et al.  Statistical tests of neutrality of mutations against population growth, hitchhiking and background selection. , 1997, Genetics.

[28]  W. Li,et al.  Statistical tests of neutrality of mutations. , 1993, Genetics.

[29]  F. Depaulis,et al.  Haplotype tests using coalescent simulations conditional on the number of segregating sites. , 2001, Molecular biology and evolution.

[30]  F. Tajima Statistical method for testing the neutral mutation hypothesis by DNA polymorphism. , 1989, Genetics.