A population genetics model with recombination hotspots that are heterogeneous across the population

Abstract: Both sperm typing and linkage disequilibrium patterns from large population genetic data sets have demonstrated that recombination hotspots are responsible for much of the recombination activity in the human genome. Sperm typing has also revealed that some hotspots are heterogeneous in the population; and linkage disequilibrium patterns from the chimpanzee have implied that hotspots change at least on the separation time between these species. We propose a population genetics model, inspired by the double-stra… Show more

“…This is because under these conditions the standard mutation-selection balance assumption that selection is a much stronger force than mutation is violated: the total strength of selection in this model is on the order of b H 3 ðs À t=2Þ, which may be quite small under reasonable parameter values. One consequence of this is that it potentially allows for hotspot polymorphisms to be maintained deterministically; however, because this tends to occur when selection is weak, drift may be more important than selection under these parameter values (Calabrese 2007;Coop and Myers 2007). A comparison of these approximate results to the exact solutions, along with confirmation through numerical results, can be found in the supplemental material.…”

“…Unlike recent stochastic models (Calabrese 2007;Coop and Myers 2007), it allows for the fixation of very-hot hotspots, assuming selection is strong enough (in fact, very-hot modifiers are more likely to fix under a given selection strength than less-hot modifiers; see Figure 3). Of course, this model requires several simplifying assumptions.…”

“…The continued existence of recombination hotspots in the face of this biased gene conversion has been termed the ''hotspot conversion paradox'' (Boulton et al 1997). 1 This paradox has been addressed in several recent theoretical studies (Boulton et al 1997;Pineda-Krch and Redfield 2005;Calabrese 2007;Coop and Myers 2007), but a general solution to the problem remains elusive. Simulation studies show that selection favoring DSBs can counteract the process of biased gene conversion and slow or stop the loss of a hotspot, but only if there is a strong fitness benefit directly associated with activity at the hotspot itself (Boulton et al 1997;Pineda-Krch and Redfield 2005).…”

“…Given that the conversion paradox is likely to be at its strongest when a hot allele is rare (so that the hot allele is always found in heterozygotes and is therefore constantly being lost to conversion), explaining the spread of a new hotspot is more difficult than explaining the existence of an old one. Recent theoretical studies exploring the action of genetic drift on modifiers undergoing biased gene conversion suggest that only when the force of conversion (that is, the product of the DSB rate and the probability that the control allele is converted when a DSB occurs) is weak can a hotspot spread or be maintained at high frequency (Calabrese 2007;Coop and Myers 2007). That is, very-hot cis-controlled hotspots act essentially as strongly deleterious mutations, which almost never fix due to drift.…”

“…Theoretical approaches to the hotspot conversion paradox to date have consisted of simulations of finite populations (Boulton et al 1997;Pineda-Krch and Redfield 2005) and diffusion approximations focusing on the stochastic fate of hotspots (Calabrese 2007;Coop and Myers 2007). Here, I present an analytical model of the deterministic processes underlying the evolution of a single recombination hotspot, to clearly define the conditions under which selection can overcome the effects of biased gene conversion and allow the maintenance of an existing hotspot and/or the spread of a new one.…”

A Combination of cis and trans Control Can Solve the Hotspot Conversion Paradox

“…This is because under these conditions the standard mutation-selection balance assumption that selection is a much stronger force than mutation is violated: the total strength of selection in this model is on the order of b H 3 ðs À t=2Þ, which may be quite small under reasonable parameter values. One consequence of this is that it potentially allows for hotspot polymorphisms to be maintained deterministically; however, because this tends to occur when selection is weak, drift may be more important than selection under these parameter values (Calabrese 2007;Coop and Myers 2007). A comparison of these approximate results to the exact solutions, along with confirmation through numerical results, can be found in the supplemental material.…”

“…Unlike recent stochastic models (Calabrese 2007;Coop and Myers 2007), it allows for the fixation of very-hot hotspots, assuming selection is strong enough (in fact, very-hot modifiers are more likely to fix under a given selection strength than less-hot modifiers; see Figure 3). Of course, this model requires several simplifying assumptions.…”

“…The continued existence of recombination hotspots in the face of this biased gene conversion has been termed the ''hotspot conversion paradox'' (Boulton et al 1997). 1 This paradox has been addressed in several recent theoretical studies (Boulton et al 1997;Pineda-Krch and Redfield 2005;Calabrese 2007;Coop and Myers 2007), but a general solution to the problem remains elusive. Simulation studies show that selection favoring DSBs can counteract the process of biased gene conversion and slow or stop the loss of a hotspot, but only if there is a strong fitness benefit directly associated with activity at the hotspot itself (Boulton et al 1997;Pineda-Krch and Redfield 2005).…”

“…Given that the conversion paradox is likely to be at its strongest when a hot allele is rare (so that the hot allele is always found in heterozygotes and is therefore constantly being lost to conversion), explaining the spread of a new hotspot is more difficult than explaining the existence of an old one. Recent theoretical studies exploring the action of genetic drift on modifiers undergoing biased gene conversion suggest that only when the force of conversion (that is, the product of the DSB rate and the probability that the control allele is converted when a DSB occurs) is weak can a hotspot spread or be maintained at high frequency (Calabrese 2007;Coop and Myers 2007). That is, very-hot cis-controlled hotspots act essentially as strongly deleterious mutations, which almost never fix due to drift.…”

“…Theoretical approaches to the hotspot conversion paradox to date have consisted of simulations of finite populations (Boulton et al 1997;Pineda-Krch and Redfield 2005) and diffusion approximations focusing on the stochastic fate of hotspots (Calabrese 2007;Coop and Myers 2007). Here, I present an analytical model of the deterministic processes underlying the evolution of a single recombination hotspot, to clearly define the conditions under which selection can overcome the effects of biased gene conversion and allow the maintenance of an existing hotspot and/or the spread of a new one.…”

A Combination of cis and trans Control Can Solve the Hotspot Conversion Paradox

References

The use of plasmodes as a supplement to simulations: A simple example evaluating individual admixture estimation methodologies