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. 1985 Dec 16;4(13A):3525–3530. doi: 10.1002/j.1460-2075.1985.tb04112.x

A PIF-dependent recombinogenic signal in the mitochondrial DNA of yeast

Françoise Foury 1, Eric Van Dyck 1
PMCID: PMC554692  PMID: 16453651

Abstract

From their recombination properties, tandem rho- mutants of the mitochondrial genome of Saccharomyces cerevisiae were divided into two categories. In crosses between PIF-independent rho- and rho+ strains, the recombination frequency is low and similar in PIF/pif and pif/pif diploids. In crosses between PIF-dependent rho- and rho+ strains, the recombination frequency is stimulated 10-50 times in PIF/pif diploids and is drastically decreased in pif/pif diploids. These results suggest that a recombinogenic signal is present in the mitochondrial (mt) DNA of PIF-dependent rho- clones. This signal is not recognized in pif mutants. Sequence analysis of a series of small (<300 bp) overlapping tandem rho- genomes located in the ery region of the 21S rRNA gene led us to identify an essential element of this signal within a 41-bp A+T sequence exhibiting over 26 bp a perfect dyad symmetry. However the recombinogenic signal is not sequence-specific since the sequence described above does not characterize PIF-dependent rho- clones located in the oli1 region. Our results rather suggest that the recombinogenic signal is related to the topology of rho- DNA. Denaturated sites in the double helix or cruciform structures elicited by local negative supercoiling might be preferred sites of the initiation of recombination.

Keywords: mtDNA, recombination, yeast, pif mutants

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Selected References

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