Enhanced meiotic recombination on the smallest chromosome of Saccharomyces cerevisiae

Abstract

Chromosome I is the smallest chromosome in Saccharomyces cerevisiae and contains a DNA molecule that is only 250 kilobases (kb). Approximately 75% of this DNA molecule has been cloned. A restriction map for the entire DNA molecule from chromosome I was determined and most of its genetically mapped genes were located on this physical map. Based on the average rate of recombination (centimorgans/kb) found for other S. cerevisiae chromosomes, the outermost markers on the genetic map of chromosome I were expected to be close to the ends of the DNA molecule. While the rightmost genetic marker was 3 kb from the end, the leftmost marker, CDC24, was located near the middle of the left arm, suggesting that the genetic map would be much longer. To extend the genetic map, a copy of the S. cerevisiae URA3 gene was integrated in the outermost cloned region located 32 kb centromere distal to CDC24, and the genetic map distance between these two genes was determined. The new marker substantially increased the genetic map length of chromosome I. In addition, we determined the relationship between physical and genetic map distance along most of the length of the chromosome. Consistent with the longer genetic map, the average rate of recombination between markers on chromosome I was greater than 50% higher than the average found on other yeast chromosomes. Owing to its small size, it had been estimated that approximately 5% of the chromosome I homologues failed to undergo meiotic recombination. New measurements of the zero-crossover class indicated that the enhanced rate of recombination ensures at least one genetic exchange between virtually every pair of chromosome I homologues.