Adaptive regrowth in respiratory deficient strain of yeast Saccharomyces cerevisiae due to deletion of YKU70 gene

It is known that significant causes of malignant tumors are destabilization of the nuclear genome and mitochondrial dysfunction. Adaptive regrowth in yeast colonies (the appearance of cell subpopulations more adapted to unfavorable conditions under conditions of the death of the original culture) is used as a model of the initial stages of carcinogenesis. To study the features of the formation of adaptive regrowth, a reparationdefective and respiratory-deficient yeast strain of Saccharomyces cerevisiae was created. The thermosensitive mutation in the yku70 gene was used as an inducer of nuclear genome instability (at 37 оC it causes cell cycle arrest due to a reduction of the length of telomeric regions of chromosomes). Damage to the mitochondrial DNA of the ∆yku70 strain led to its respiratory deficiency (petite mutation). The isolated petite mutant ∆yku70 strain was cultured at optimal 28 оC and restrictive 37 оC temperatures, the state of the cell suspension was evaluated by light and fluorescence microscopy, to determine the viability of cells was used the analysis of microcolonies growth. Isolation of adaptive regrowth clones and analysis of their properties by the method of serial dilutions were conducted. To assess the genome stability of selected clones of adaptive regrowth, PCR analysis of the microsatellite sequences YOR267C, SC8132X, SCPTSY7 was conducted. When culturing the petite mutant of the strain ∆yku70 at a restrictive temperature of 37 оC for 7 days, the formation of viable subpopulations was detected, which can overcome the arrest of the cell cycle in the G2 / M phase. Further analysis of the isolated clones of adaptive regrowth showed that they differ in cell survival at restrictive temperature, resistance to UV radiation and the ability to form adaptive regrowth on colonies. In the analysis of microsatellite repeats in adaptive regrowth clones, no manifestations of instability of the studied sequences were detected.

Dynamics of Mitochondrial RNA-Binding Protein Complex in Trypanosoma brucei and Its Petite Mutant under Optimized Immobilization Conditions

ABSTRACT There are a variety of complex metabolic processes ongoing simultaneously in the single, large mitochondrion of Trypanosoma brucei . Understanding the organellar environment and dynamics of mitochondrial proteins requires quantitative measurement in vivo . In this study, we have validated a method for immobilizing both procyclic stage (PS) and bloodstream stage (BS) T. brucei brucei with a high level of cell viability over several hours and verified its suitability for undertaking fluorescence recovery after photobleaching (FRAP), with mitochondrion-targeted yellow fluorescent protein (YFP). Next, we used this method for comparative analysis of the translational diffusion of mitochondrial RNA-binding protein 1 (MRP1) in the BS and in T. b. evansi . The latter flagellate is like petite mutant Saccharomyces cerevisiae because it lacks organelle-encoded nucleic acids. FRAP measurement of YFP-tagged MRP1 in both cell lines illuminated from a new perspective how the absence or presence of RNA affects proteins involved in mitochondrial RNA metabolism. This work represents the first attempt to examine this process in live trypanosomes.

A Candida albicans Petite Mutant Strain with Uncoupled Oxidative Phosphorylation Overexpresses MDR1 and Has Diminished Susceptibility to Fluconazole and Voriconazole

ABSTRACT We showed that a Candida albicans petite mutant in which oxidative phosphorylation is uncoupled was eightfold more resistant to fluconazole and voriconazole than SC5314 but equally susceptible to ketoconazole, itraconazole, and amphotericin B. Strain P5 significantly overexpressed MDR1, which likely accounts for the decreased drug susceptibility.

Transcription-Dependent DNA Transactions in the Mitochondrial Genome of a Yeast Hypersuppressive Petite Mutant

ABSTRACT Mitochondrial DNA (mtDNA) of Saccharomyces cerevisiaecontains highly conserved sequences, called rep/ori, that are associated with several aspects of its metabolism. Theserep/ori sequences confer the transmission advantage exhibited by a class of deletion mutants called hypersuppressive petite mutants. In addition, because they share features with the mitochondrial leading-strand DNA replication origin of mammals, rep/ori sequences have also been proposed to participate in mtDNA replication initiation. Like the mammalian origins, where transcription is used as a priming mechanism for DNA synthesis, yeast rep/ori sequences contain an active promoter. Although transcription is required for maintenance of wild-type mtDNA in yeast, the role of the rep/ori promoter as a cis-acting element involved in the replication of wild-type mtDNA is unclear, since mitochondrial deletion mutants need neither transcription nor a rep/ori sequence to maintain their genome. Similarly, transcription from the rep/oripromoter does not seem to be necessary for biased inheritance of mtDNA. As a step to elucidate the function of the rep/oripromoter, we have attempted to detect transcription-dependent DNA transactions in the mtDNA of a hypersuppressive petite mutant. We have examined the mtDNA of the well-characterized petite mutant a-1/1R/Z1, whose repeat unit shelters the rep/ori sequenceori1, in strains carrying either wild-type or null alleles of the nuclear genes encoding the mitochondrial transcription apparatus. Complex DNA transactions were detected that take place around GC-cluster C, an evolutionarily conserved GC-rich sequence block immediately downstream from the rep/ori promoter. These transactions are strictly dependent upon mitochondrial transcription.