Jack P. Jenuth scite author profile

Mitochondrial DNA (mtDNA) is maternally inherited in mammals. Despite the high genome copy number in mature oocytes (10(5)) and the relatively small number of cell divisions in the female germline, mtDNA sequence variants segregate rapidly between generations. To investigate the molecular basis for this apparent paradox we created lines of heteroplasmic mice carrying two mtDNA genotypes. We show that the pattern of segregation can be explained by random genetic drift occurring in early oogenesis, and that the effective number of segregating units for mtDNA is approximately 200 in mice. These results provide the basis for estimating recurrence risks for mitochondrial disease due to pathogenic mtDNA mutations and for predicting the rate of fixation of neutral mtDNA mutations in maternal lineages.

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Tissue-specific selection for different mtDNA genotypes in heteroplasmic mice

Jenuth

1997

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Mammalian mitochondrial DNA (mtDNA) is a highly polymorphic, high-copy-number genome that is maternally inherited. New mutations in mtDNA segregate rapidly in the female germline due to a genetic bottleneck in early oogenesis and as a result most individuals are homoplasmic for a single species of mtDNA. Sequence variants thus accumulate along maternal lineages without genetic recombination. Most of the extant variation in mtDNA in mammalian populations has been assumed to be neutral with respect to selection; however, comparisons of the ratio of replacement to silent nucleotide substitutions between species suggest that the evolution of mammalian mtDNA is not strictly neutral. To test directly whether polymorphic mtDNAs behave as neutral variants, we examined the segregation of two different mtDNA genotypes in the tissues of heteroplasmic mice. We find evidence for random genetic drift in some tissues, but in others strong, tissue-specific and age-related, directional selection for different mtDNA genotypes in the same animal. These surprising data suggest that the coding sequence of mtDNA may represent a compromise between the competing demands of different tissues and point to the existence of unknown, tissue-specific nuclear genes important in the interaction between the nuclear and mitochondrial genomes.

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Secondary loss of deoxyguanosine kinase activity in purine nucleoside phosphorylase deficient mice

Snyder

Jenuth

Dilay

et al. 1994

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

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Point mutations at the purine nucleoside phosphorylase locus impair thymocyte differentiation in the mouse

Snyder

Jenuth

Mably

et al. 1997

Proc. Natl. Acad. Sci. U.S.A.

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Three point mutations on the Np b allele of the purine nucleoside phosphorylase locus in the mouse have been recovered by male germ cell mutagenesis. The mutants were backcrossed, 12-14 generations, and are designated in increasing order of severity of enzyme deficiency and phenotype: B6-NPE, Met-87 3 Lys; B6-NPF, Ala-228 3 Thr; and B6-NPG, Trp-16 3 Arg. A marked decline in total cell numbers per thymus occurs between 2 and 3 months for the more severe B6-NPF and B6-NPG mutants (35% and 52%, respectively) and by 8 months for the less severe B6-NPE mutation. The thymocyte population is thereafter characterized by a 3-or 8-fold expanded precursor, CD4؊ CD8 ؊ double-negative population and 15% or 55% reduced CD4 ؉ CD8 ؉ double-positive cells for the B6-NPF and B6-NPG strains, respectively. Spleen lymphocyte Thy-1 ؉ cells are reduced by 50% and spleen lymphocyte response to T cell mitogen and interleukin 2 is reduced by 80%. Increases of thymocyte dGTP pools of 5-and 2.5-fold for B6-NPF and B6-NPG mutants, respectively, are observed. The purine nucleoside phosphorylase-deficient mouse exhibits age-dependent progressive perturbations in thymocyte differentiation, reduced numbers of thymocytes, and reduced splenic T cell numbers and response. The progressive T cell deficit is similar to the human disorder.

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Jack P. Jenuth

Random genetic drift in the female germline explains the rapid segregation of mammalian mitochondrial DNA

Tissue-specific selection for different mtDNA genotypes in heteroplasmic mice

Secondary loss of deoxyguanosine kinase activity in purine nucleoside phosphorylase deficient mice

Point mutations at the purine nucleoside phosphorylase locus impair thymocyte differentiation in the mouse

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