Mitochondrial DNA Modifies Cognition in Interaction with the Nuclear Genome and Age in Mice

Overview

Journal Nat Genet

Specialty Genetics

Date 2003 Aug 19

PMID 12923532

Citations 82

Authors

Pierre L Roubertoux

Frans Sluyter

Michele Carlier

Brice Marcet

Fatima Maarouf-Veray

Chabane Cherif

Charlotte Marican

Patricia Arrechi

Fabienne Godin

Marc Jamon

Bernard Verrier

Charles Cohen-Salmon

Affiliations

Soon will be listed here.

Abstract

Several lines of evidence indicate an association between mitochondrial DNA (mtDNA) and the functioning of the nervous system. As neuronal development and structure as well as axonal and synaptic activity involve mitochondrial genes, it is not surprising that most mtDNA diseases are associated with brain disorders. Only one study has suggested an association between mtDNA and cognition, however. Here we provide direct evidence of mtDNA involvement in cognitive functioning. Total substitution of mtDNA was achieved by 20 repeated backcrosses in NZB/BlNJ (N) and CBA/H (H) mice with different mtDNA origins. All 13 mitochondrial genes were expressed in the brains of the congenic quartet. In interaction with nuclear DNA (nDNA), mtDNA modified learning, exploration, sensory development and the anatomy of the brain. The effects of mtDNA substitution persisted with age, increasing in magnitude as the mice got older. We observed different effects with input of mtDNA from N versus H mice, varying according to the phenotypes. Exchanges of mtDNA may produce phenotypes outside the range of scores observed in the original mitochondrial and nuclear combinations. These findings show that mitochondrial polymorphisms are not as neutral as was previously believed.

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