Asymmetric Strand Segregation: Epigenetic Costs of Genetic Fidelity?

Asymmetric strand segregation has been proposed as a mechanism to minimize effective mutation rates in epithelial tissues. Under asymmetric strand segregation, the double-stranded molecule that contains the oldest DNA strand is preferentially targeted to the somatic stem cell after each round of DNA replication. This oldest DNA strand is expected to have fewer errors than younger strands because some of the errors that arise on daughter strands during their synthesis fail to be repaired. Empirical findings suggest the possibility of asymmetric strand segregation in a subset of mammalian cell lineages, indicating that it may indeed function to increase genetic fidelity. However, the implications of asymmetric strand segregation for the fidelity of epigenetic information remain unexplored. Here, I explore the impact of strand-segregation dynamics on epigenetic fidelity using a mathematical-modelling approach that draws on the known molecular mechanisms of DNA methylation and existing rate estimates from empirical methylation data. I find that, for a wide range of starting methylation densities, asymmetric—but not symmetric—strand segregation leads to systematic increases in methylation levels if parent strands are subject to de novo methylation events. I found that epigenetic fidelity can be compromised when enhanced genetic fidelity is achieved through asymmetric strand segregation. Strand segregation dynamics could thus explain the increased DNA methylation densities that are observed in structured cellular populations during aging and in disease

Repeated evolution of self-compatibility for reproductive assurance

Sexual reproduction in eukaryotes requires the fusion of two compatible gametes of opposite sexes or mating types. To meet the challenge of finding a mating partner with compatible gametes evolutionary mechanisms such as hermaphroditism and self-fertilisation have repeatedly evolved. Combining insight from comparative genomics, computer simulations and experimental evolution in fission yeast, we shed light on the conditions promoting separate mating types or self-compatibility by mating-type switching. Analogous to multiple independent transitions between switchers and non-switchers in natural populations mediated by structural genomic changes, novel switching genotypes were readily evolving under selection in experimental populations. Detailed fitness measurements accompanied by computer simulations show the benefits and costs of switching during sexual and asexual reproduction governing the occurrence of both strategies in nature. Our findings illuminate the trade-off between the benefits of reproductive assurance and its fitness costs under benign conditions governing the evolution of self-compatibility

The Clr1 Locus Regulates the Expression of the Cryptic Mating-Type Loci of Fission Yeast

The mat2-P and mat3-M loci of fission yeast contain respectively the plus (P) and minus (M) mating-type information in a transcriptionally silent state. That information is transposed from the mat2 or mat3 donor locus via recombination into the expressed mating-type locus (mat1) resulting in switching of the cellular mating type. We have identified a gene, named clr1 (for cryptic loci regulator), whose mutations allow expression of the mat2 and mat3 loci. clr1 mutants undergo aberrant haploid meiosis, indicative of transcription of the silent genes. Production of mRNA from mat3 is detectable in clr1 mutants. Furthermore, the ura4 gene inserted near mat3, weakly expressed in wild-type cells, is derepressed in clr1 mutants. The clr1 mutations also permit meiotic recombination in the 15-kb mat2-mat3 interval, where recombination is normally inhibited. The clr1 locus is in the right arm of chromosome II. We suggest that clr1 regulates silencing of the mat2 and mat3 loci, and participates in establishing the ``cold spot'' for recombination by organizing the chromatin structure of the mating-type region

The Mechanism of Fission Yeast Mating Type Interconversion: Seal/Replicate/Cleave Model of Replication across the Double-Stranded Break Site at Mat1

The interconversion of cell type in the fission yeast, Schizosaccharomyces pombe, is initiated by a double-stranded break (DSB) found at the mating type locus (mat1). A heritable site- and strand-specific DNA ``imprinting'' event at mat1 was recently hypothesized to be required to make the mat1 locus cleavable, and the DSB was suggested to be produced one generation before the actual switching event. It is known that only one cell among four granddaughters of a cell ever switches, and the sister of the recently switched cell switches efficiently in consecutive cell divisions. The feature of consecutive switching creates a major difficulty of having to replicate chromosomes possessing the DSB. The mat1 cis-acting leaky mutation, called smt-s, reduces the level of the DSB required for switching and is shown here to be a 27-bp deletion located 50 bp away from the cut site. Determination of the pattern and frequency of switching of the mutant allele by cell lineage studies has allowed us to conclude the following: (1) the chromosome with the DSB is sealed and replicated, then one of the specific chromatids is cleaved again to generate switching-competent cells in consecutive cell divisions and (2) the smt-s mutation affects DNA cleavage and not the hypothesized DNA imprinting step