Difference between revisions of "Boyle et al. 2017"
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I can't help wondering if there could be room for "selfish" allele evolution as a quantitative trait. This is in contrast to most of the thinking I have seen; that selfish alleles must assemble together on a haplotype with suppressed recombination (such as the mouse ''t''-haplotype, [[Silver 1993]]). Otherwise they recombine away from each other and are loose their collective advantage. However, the association of alleles in linkage disequilibrium takes multiple generations to approach equilibrium, even for unlinked freely recombining loci. | I can't help wondering if there could be room for "selfish" allele evolution as a quantitative trait. This is in contrast to most of the thinking I have seen; that selfish alleles must assemble together on a haplotype with suppressed recombination (such as the mouse ''t''-haplotype, [[Silver 1993]]). Otherwise they recombine away from each other and are loose their collective advantage. However, the association of alleles in linkage disequilibrium takes multiple generations to approach equilibrium, even for unlinked freely recombining loci. | ||
− | <math>D_g \approx D_0 e^{-g/2}</math>, where ''g'' is generation and ''D'' is the disequilibrium parameter. | + | <math>D_g \approx D_0 e^{-g/2}</math>, where ''g'' is generation and ''D'' is the disequilibrium parameter. Approximately 39% of the association is lost per generation, so selection would have to overcome that by removing the recombinant types. |
Some unlinked regions in natural populations appear to be in persistent LD ([[Turner et al. 2005]]; [[Hohenlohe et al. 2012]]). Perhaps these could be candidates for selfish allele evolution, particularly if they are associated with reproduction ([[Turner et al. 2005]]). Also, switching between strategies by independent assortment can enhance some types of fitness interactions (and these might be inhibited by increased linkage, [[Reed 2007]]). Even though they are thought of as selfish, multiple alleles acting together to promote their own survival could be seen as an example of the evolution of cooperation. How much of our complex genetic networks, especially those related to gametogenesis and early embryonic development, might be a by product of selfish allele evolution? Also, here is an example of selection driven in-phase coupling of smaller effects despite recombination (https://onlinelibrary.wiley.com/doi/full/10.1111/j.1558-5646.2009.00622.x ). I need to do a literature search and perhaps some simulation of multilocus freely recombining selfish interactions to see if they could evolve. | Some unlinked regions in natural populations appear to be in persistent LD ([[Turner et al. 2005]]; [[Hohenlohe et al. 2012]]). Perhaps these could be candidates for selfish allele evolution, particularly if they are associated with reproduction ([[Turner et al. 2005]]). Also, switching between strategies by independent assortment can enhance some types of fitness interactions (and these might be inhibited by increased linkage, [[Reed 2007]]). Even though they are thought of as selfish, multiple alleles acting together to promote their own survival could be seen as an example of the evolution of cooperation. How much of our complex genetic networks, especially those related to gametogenesis and early embryonic development, might be a by product of selfish allele evolution? Also, here is an example of selection driven in-phase coupling of smaller effects despite recombination (https://onlinelibrary.wiley.com/doi/full/10.1111/j.1558-5646.2009.00622.x ). I need to do a literature search and perhaps some simulation of multilocus freely recombining selfish interactions to see if they could evolve. |
Latest revision as of 09:57, 23 October 2018
Contents
Citation
Boyle, E. A., Li, Y. I., & Pritchard, J. K. (2017). An expanded view of complex traits: from polygenic to omnigenic. Cell, 169(7), 1177--1186.
Links
- https://www.sciencedirect.com/science/article/pii/S0092867417306293
- http://hawaiireedlab.com/pdf/b/boyleetal2017.pdf (internal lab link only)
Published Abstract
A central goal of genetics is to understand the links between genetic variation and disease. Intuitively, one might expect disease-causing variants to cluster into key pathways that drive disease etiology. But for complex traits, association signals tend to be spread across most of the genome—including near many genes without an obvious connection to disease. We propose that gene regulatory networks are sufficiently interconnected such that all genes expressed in disease-relevant cells are liable to affect the functions of core disease-related genes and that most heritability can be explained by effects on genes outside core pathways. We refer to this hypothesis as an “omnigenic” model.
Notes
This is very well written and starts off by placing it in the broad historical overview of understanding the relationship between genotypes and phenotypes. This emphasizes that the results from GWAS suggest that pleiotropy and genetic heterogeneity are widespread and play a very important role in connecting genotype to phenotype (versus classical views like strict Mendalism, Garrod's one gene one function, and the philosophy of genetic dissection, yet these have been very successful approaches).
Figure 3 is a very important result and point to make.
Simply searching for GO enrichment categories in GWAS may be a fundamental mistake.
This brings to mind a number of questions of the importance for the evolution of traits within and between species, and the authors spend some time discussing this.
I can't help thinking that associations from population structure might be inflating the genome-wide effect (and no one knows this better than the last author, Pritchard). This is mentioned on p. 1179, P. 3, "the signals are not driven by confounding from population structure". Also, this would be widely distributed regardless of gene expression levels or chromatin context.
Positive selection on a quantitative phenotype could help distribute the diversity reducing hitchhiking effect over a number of loci, smoothing out the correlation between diversity and rates of recombination seen across the genome of some species (Begun and Aquadro 1992, Stephan 2010).
I can't help wondering if there could be room for "selfish" allele evolution as a quantitative trait. This is in contrast to most of the thinking I have seen; that selfish alleles must assemble together on a haplotype with suppressed recombination (such as the mouse t-haplotype, Silver 1993). Otherwise they recombine away from each other and are loose their collective advantage. However, the association of alleles in linkage disequilibrium takes multiple generations to approach equilibrium, even for unlinked freely recombining loci.
[math]D_g \approx D_0 e^{-g/2}[/math], where g is generation and D is the disequilibrium parameter. Approximately 39% of the association is lost per generation, so selection would have to overcome that by removing the recombinant types.
Some unlinked regions in natural populations appear to be in persistent LD (Turner et al. 2005; Hohenlohe et al. 2012). Perhaps these could be candidates for selfish allele evolution, particularly if they are associated with reproduction (Turner et al. 2005). Also, switching between strategies by independent assortment can enhance some types of fitness interactions (and these might be inhibited by increased linkage, Reed 2007). Even though they are thought of as selfish, multiple alleles acting together to promote their own survival could be seen as an example of the evolution of cooperation. How much of our complex genetic networks, especially those related to gametogenesis and early embryonic development, might be a by product of selfish allele evolution? Also, here is an example of selection driven in-phase coupling of smaller effects despite recombination (https://onlinelibrary.wiley.com/doi/full/10.1111/j.1558-5646.2009.00622.x ). I need to do a literature search and perhaps some simulation of multilocus freely recombining selfish interactions to see if they could evolve.
...to be continued.