Abstract
In the yeast, Saccharomyces cerevisiae, cell division cycle (CDC) genes have been identified whose products are required for the execution of different steps in the cell cycle. In this study, the fidelity of transmission of a 14-kb circular minichromosome and a 155-kb linear chromosome fragment was examined in cell divisions where specific CDC products were temporarily inactivated with either inhibitors, or temperature sensitive mutations in the appropriate CDC gene. All of the cdc mutants previously shown to induce loss of endogenous linear chromosomes also induced loss of a circular minichromosome and a large linear chromosome fragment in our study (either 1:0 or 2:0 loss events). Therefore, the efficient transmission of these artificial chromosomes depends upon the same trans factors that are required for the efficient transmission of endogenous chromosomes. In a subset of cdc mutants (cdc6, cdc7 and cdc16), the rate of minichromosome loss was significantly greater than the rate of loss of the linear chromosome fragment, suggesting that a structural feature of the minichromosome (nucleotide content, length or topology) makes the minichromosome hypersensitive to the level of function of these CDC gene products. In another subset of cdc mutants (cdc7 and cdc17), the relative rate of 1:0 events to 2:0 events differed for the minichromosome and chromosome fragment, suggesting that the type of chromosome loss event observed in these mutants was dependent upon chromosome structure. Finally, we show that 2:0 events for the minichromosome can occur by both a RAD52 dependent and RAD52 independent mechanism. These results are discussed in the context of the molecular functions of the CDC products.