Cytoplasmic Inheritance in Saccharomyces Cerevisiae: Comparison of Zygotic Mitochondrial Inheritance Patterns

Overview

Journal Mol Gen Genet

Specialties Genetics
Molecular Biology

Date 1976 Mar 30

PMID 775300

Citations 4

Authors

K J Aufderheide

R G Johnson

Affiliations

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Abstract

Mitochondrial movements in Saccharomyces cerevisiae (Sc) zygotes were monitored with phase-contrast microscopy and compared to known mitochondrial inheritance systems. The mitochondria of Sc were convincingly identified by integrated use of phase-contrast, cytochemical and electron microscopic observations. Mitochondria in Sc appear to move by saltatory jumps, which appear to be oriented towards movement of mitochondria into developing buds. Tracking of mitochondria of different genotypes was made possible by positive identification of each mitochondrial population before zygosis, and by the low degree of mixing (less than 10%) of mitochondrial populations before first bud septation. A grande by grande cross demonstrated equal numbers of mitochondria from each haploid moving into the first zygotic bud. A grande by neutral petite cross gave a 2:1 ratio of grande to petite mitochondria. However, a grande by suppressive petite cross gave equal numbers of grande and petite mitochondria. Using drug resistance systems, a comparison was made of highly biased (97%) and moderately biased (71%) chloramphenicol resistant inheritance patterns. In both cases, the ratios of drug resistant to sensitive mitochondria were 1:1. When numbers of mitochondria moving into an individual bud were compared to the phenotypic content of the clone of that bud, no model could be constructed which could predict the latter from the former. The data indicate (with the exception of the neutral petite by grande cross) that the numbers of each mitochondrial type "inserted" into the first zygotic bud are equal, regardless of the degree of asymmetry of inheritance of mitochondrial markers.

Citing Articles

Cytoplasmic mixing in Saccharomyces cerevisiae: Studies on a grande X neutral petite mating and implications for the mechanism of neutrality.

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Partial pedigree analysis of the segregation of yeast mitochondrial genes during vegetative reproduction.

Waxman M, Birk Jr C Curr Genet. 2013; 5(3):171-80.

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Transmission of the yeast mitochondrial genome to progeny: the impact of intergenic sequences.

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The effect of zygotic bud position on the transmission of mitochondrial genes in Saccharomyces cerevisiae.

Strausberg R, Perlman P Mol Gen Genet. 1978; 163(2):131-44.

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