Dynamic genome plasticity during unisexual reproduction in the human fungal pathogen Cryptococcus deneoformans.

Genome copy number variation occurs during each mitotic and meiotic cycle and it is crucial for organisms to maintain their natural ploidy. Defects in ploidy transitions can lead to chromosome instability, which is a hallmark of cancer. Ploidy in the haploid human fungal pathogen Cryptococcus neoformans is exquisitely orchestrated and ranges from haploid to polyploid during sexual development and under various environmental and host conditions. However, the mechanisms controlling these ploidy transitions are largely unknown. During C. deneoformans (formerly C. neoformans var. neoformans, serotype D) unisexual reproduction, ploidy increases prior to the onset of meiosis, can be independent from cell-cell fusion and nuclear fusion, and likely occurs through an endoreplication pathway. To elucidate the molecular mechanisms underlying this ploidy transition, we identified twenty cell cycle-regulating genes encoding cyclins, cyclin-dependent kinases (CDK), and CDK regulators. We characterized four cyclin genes and two CDK regulator genes that were differentially expressed during unisexual reproduction and contributed to diploidization. To detect ploidy transition events, we generated a ploidy reporter, called NURAT, which can detect copy number increases via double selection for nourseothricin-resistant, uracil-prototrophic cells. Utilizing this ploidy reporter, we showed that ploidy transition from haploid to diploid can be detected during the early phases of unisexual reproduction. Interestingly, selection for the NURAT reporter revealed several instances of segmental aneuploidy of multiple chromosomes, which conferred azole resistance in some isolates. These findings provide further evidence of ploidy plasticity in fungi with significant biological and public health implications.

The CovR response regulator of group A streptococcus (GAS) acts directly to repress its own promoter.

The CovR/S (CsrR/S) two component system is a global regulator of virulence gene expression in the group A streptococcus (GAS, Streptococcus pyogenes). The response regulator, CovR, regulates about 15% of the genes of GAS, including its own operon. Using in vitro DNA binding assays with purified CovR protein, we found that CovR binds a DNA fragment including the covR promoter (Pcov). DNaseI footprint analyses showed that phosphorylation of CovR enhanced and extended the protected regions. The proposed CovR consensus binding sequence (ATTARA) was present at most, but not all protected regions. The effect of replacing the two thymine residues in the consensus binding sequence (CB) with guanine residues was evaluated both in vitro and in vivo. Most, but not all, CB mutations reduced binding of CovR in vitro. Using a transcriptional reporter introduced in single copy into the GAS chromosome, we found that mutations at each CB completely or partially relieved CovR-mediated repression in vivo. This suggests that CovR regulation of Pcov is direct. Further support for this conclusion comes from use of an in vitro GAS transcription system in which CovR was sufficient to mediate repression of Pcov. This repression was enhanced by phosphorylation of the protein. In addition, we found that the CovR binding region overlapping the promoter was essential for wild type repression of Pcov both in vitro and in vivo, suggesting that promoter occlusion is a primary mechanism of Pcov repression by CovR.