Article

Outcrossing and the maintenance of males within C. elegans populations.

Center for Ecology and Evolutionary Biology, University of Oregon, Eugene, OR 97403, USA.
The Journal of heredity (impact factor: 2.05). 03/2010; 101 Suppl 1:S62-74. DOI:10.1093/jhered/esq003 pp.S62-74
Source: PubMed

ABSTRACT Caenorhabditis elegans is an androdioecious nematode with both hermaphrodites and males. Although males can potentially play an important role in avoiding inbreeding and facilitating adaptation, their existence is evolutionarily problematic because they do not directly generate offspring in the way that hermaphrodites do. This review explores how genetic, population genomic, and experimental evolution approaches are being used to address the role of males and outcrossing within C. elegans. Although theory suggests that inbreeding depression and male mating ability should be the primary determinants of male frequency, this has yet to be convincingly confirmed experimentally. Genomic analysis of natural populations finds that outcrossing occurs at low, but not negligible levels, and that observed patterns of linkage disequilibrium consistent with strong selfing may instead be generated by natural selection against outcrossed progeny. Recent experimental evolution studies suggest that males can be maintained at fairly high levels if populations are initiated with sufficient genetic variation and/or subjected to strong natural selection via a change in the environment. For example, as reported here, populations adapting to novel laboratory rearing and temperature regimes maintain males at frequencies from 5% to 40%. Laboratory and field results still await full reconciliation, which may be facilitated by identifying the loci underlying among-strain differences in mating system dynamics.

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Keywords

experimental evolution approaches
 
facilitating adaptation
 
full reconciliation
 
Genomic analysis
 
inbreeding depression
 
linkage disequilibrium consistent
 
mating system dynamics
 
natural populations
 
natural selection
 
novel laboratory rearing
 
observed patterns
 
outcrossed progeny
 
population genomic
 
populations
 
populations adapting
 
primary determinants
 
Recent experimental evolution studies
 
strong natural selection
 
sufficient genetic variation
 
temperature regimes