[A Test System for Assessment of the Activity of Mutant Cas9 Variants in Saccharomyces cerevisiae].

The key component of the revolutionary Streptococcus pyogenes CRISPR/Cas genome editing technology is the multidomain protein Cas9. However, the specificity of wild type Cas9 is not sufficiently high for editing large genomes of higher eukaryotes, which limits the realization of the potential of genomic editing both in fundamental investigations and in the therapy of genetic diseases. The main way to obtain more specific variants of Cas9 is through mutagenesis followed by characterization of mutant proteins in in vitro or in vivo test systems. The in vitro and some in vivo test systems described in the literature are often labor-intensive and have scaling limitations, which makes it challenging to screen SpCas9 mutant variant libraries. In order to develop a simple method for high-throughput screening of Cas9 mutants in vivo, we characterized three test systems using CRISPR/Cas9-mediated inactivation of the reporter genes, tsPurple, ADE2, and URA3, in the Saccharomyces cerevisiae yeast as a model subject. We measured the activities of high-precision forms of Cas9, evoCas9, and HiFiCas9, and compared them with the wild-type form. ADE2 gene inactivation was found to be the most valid method for the evaluation of Cas9 activity. In the test-system developed, the sensitivity to chromatin structure was demonstrated for the high-fidelity variant of Cas9, HiFiCas9. The proposed test-system can be used for the development of new generation genome editors.

[Rpn4p without the DNA-Binding Domain Provides Saccharomyces cerevisiae Resistance to Oxidative Stress and Cycloheximide].

The ubiquitin-proteasome system is involved in the control of all essential molecular processes under normal conditions and the response of cells to stress. Rpn4p serves as a key transcriptional regulator of the proteasome in Saccharomycetes yeast and is also involved in the cellular response to various stresses. In addition to proteasomal genes, Rpn4 affects the expression of several hundred other genes, including genes involved in DNA repair and oxidative stress response. At the same time, the molecular mechanisms used by Rpn4 in controlling target genes and its functioning as a regulator of the cellular response to stress remain largely unclear. The aim of this work was to determine the Rpn4 domains required to ensure cell resistance to stress. It was shown that the N-terminal and central regions of the protein contain sites required for resistance to all types of stresses. The putative nuclear localization signal does not affect the functioning of Rpn4. Unexpectedly, a protein with the deletion of both zinc finger motifs that form the DNA-binding domain provides yeast resistance to oxidative stress and cycloheximide. Moreover, we showed that Rpn4 can be recruited to the promoter regions of the regulated genes even if they do not contain its binding sites. Based on these data, it can be assumed that Rpn4 is involved in gene regulation and the cellular response to stress due to protein-protein interactions.