Heteroplasmy and Organelle Gene Dynamics

Heteroplasmy and Organelle Gene Dynamics

Ronald K. Chesser^a,b
^a Department of Genetics, University of Georgia, Athens, Georgia 30602
^b Savannah River Ecology Laboratory, Aiken, South Carolina 29802

Corresponding author: Ronald K. Chesser, Savannah River Ecology Laboratory, P.O. Drawer E, Aiken, SC 29802., chesser{at}srel.edu (E-mail).

Communicating editor: B. S. WEIR

This study assesses factors that influence the rates of changeof organelle gene diversity and the maintenance of heteroplasmy.Losses of organelle gene diversity within individuals via vegetativesegregation during ontogeny are paramount to resultant spatialand temporal patterns. Steady-state losses of organelle variationfrom the zygote to the gametes are determined by the effectivenumber of organelles, which will be approximately equal to thenumber of intracellular organelles if random segregation prevails.Both rapid increases in organelle number after zygote formationand reductions at germ lines will reduce variation within individuals.Terminal reductions in organelles must be to very low copy numbers(<5) for substantial losses in variation to occur rapidly.Nonrandom clonal expansion and vegetative segregation duringgametogenesis may be effective in reducing genetic variationin gametes. If organelles are uniparentally inherited, the asymptoticexpectations for effective numbers of gametes and spatial differentiationwill be identical for homoplasmic and heteroplasmic conditions.The rate of attainment of asymptote for heteroplasmic organelles,however, is governed by the rate of loss of variation duringontogeny. With sex-biased dispersal, the effective number ofgametes is maximized when the proportional contributions ofthe sex having the higher dispersal rate are low.

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