Mitochondrial Genome Instability in Yeast Cytoplasmic Hybrids.

Unlike most animals, some fungi, including baker's yeast, inherit mitochondrial DNA (mtDNA) from both parents. When haploid yeast cells fuse, they form a heteroplasmic zygote, whose offspring retain one or the other variant of mtDNA. Meanwhile, some mutant mtDNA (), with large deletions in the nucleotide sequence, can displace wild-type () mtDNA.

Tyrosol induces multiple drug resistance in yeast .

In yeast, multiple (pleiotropic) drug resistance (MDR) transporters efflux xenobiotics from the cytoplasm to the environment. Additionally, upon the accumulation of xenobiotics in the cells, MDR genes are induced. At the same time, fungal cells can produce secondary metabolites with physico-chemical properties similar to MDR transporter substrates.

Role of Dead Cells in Collective Stress Tolerance in Microbial Communities: Evidence from Yeast.

A substantial part of yeast life cycle takes place in the communities where the cells are surrounded by their own clones. Meanwhile, yeast cell fitness depends not only on its own adaptations but also on the processes in the neighboring cells. Moreover, even if a cell loses its clonogenic ability, it is still capable of protecting surrounding cells that are still alive.

Heterogeneity of Starved Yeast Cells in IF Levels Suggests the Role of This Protein .

In mitochondria, a small protein IF suppresses the hydrolytic activity of ATP synthase and presumably prevents excessive ATP hydrolysis under conditions of energy deprivation. In yeast , IF homologs are encoded by two paralogous genes: and . expression is known to aggravate the deleterious effects of mitochondrial DNA (mtDNA) depletion.

Attenuated ADP-inhibition of FF ATPase mitigates manifestations of mitochondrial dysfunction in yeast.

Proton-translocating FF ATP synthase (F-ATPase) couples ATP synthesis or hydrolysis to transmembrane proton transport in bacteria, chloroplasts, and mitochondria. The primary function of the mitochondrial FF is ATP synthesis driven by protonmotive force (pmf) generated by the respiratory chain. However, when pmf is low or absent (e.

Adaptive Role of Cell Death in Yeast Communities Stressed with Macrolide Antifungals.

Microorganisms cooperate with each other to protect themselves from environmental stressors. An extreme case of such cooperation is regulated cell death for the benefit of other cells. Dying cells can provide surviving cells with nutrients or induce their stress response by transmitting an alarm signal; however, the role of dead cells in microbial communities is unclear.

Do Multiple Drug Resistance Transporters Interfere with Cell Functioning under Normal Conditions?

Eukaryotic cells rely on multiple mechanisms to protect themselves from exogenous toxic compounds. For instance, cells can limit penetration of toxic molecules through the plasma membrane or sequester them within the specialized compartments. Plasma membrane transporters with broad substrate specificity confer multiple drug resistance (MDR) to cells.

Protonophore FCCP provides fitness advantage to PDR-deficient yeast cells.

Pleiotropic drug resistance (PDR) plasma membrane transporters mediate xenobiotic efflux from the cells and thereby help pathogenic microorganisms to withstand antimicrobial therapies. Given that xenobiotic efflux is an energy-consuming process, cells with upregulated PDR can be sensitive to perturbations in cellular energetics. Protonophores dissipate proton gradient across the cellular membranes and thus increase ATP spendings to their maintenance.

The Role of LAM Genes in the Pheromone-Induced Cell Death of S. cerevisiae Yeast.

Lam1-4 proteins perform non-vesicular transport of sterols from the plasma membrane to the endoplasmic reticulum. Disruption of their function leads to an increase in the content of sterols in the plasma membrane. In mammals, homologs of Lam proteins are responsible for the internalization of plasma cholesterol.

Mitochondrial dynamics in yeast with repressed adenine nucleotide translocator AAC2.

The mitochondrial network structure dynamically adapts to cellular metabolic challenges. Mitochondrial depolarisation, particularly, induces fragmentation of the network. This fragmentation may be a result of either a direct regulation of the mitochondrial fusion machinery by transmembrane potential or an indirect effect of metabolic remodelling.

Genes Contribute to Environmental Stress Tolerance but Sensibilize Yeast Cells to Azoles.

Lam proteins transport sterols between the membranes of different cellular compartments. In the gene family consists of three pairs of paralogs. Because the function of paralogous genes can be redundant, the phenotypes of only a small number of gene deletions have been reported; thus, the role of these genes in yeast physiology is still unclear.

Deletion of CDR1 reveals redox regulation of pleiotropic drug resistance in Candida glabrata.

Microbial cells sense the presence of xenobiotics and, in response, upregulate genes involved in pleiotropic drug resistance (PDR). In yeast, PDR activation to a major extent relies on the transcription factor Pdr1. In addition, many xenobiotics induce oxidative stress, which may upregulate PDR independently of Pdr1 activity.

Replicative aging as a source of cell heterogeneity in budding yeast.

While deviations from the optimal phenotype are deleterious, increased variation can prevent population extinction under severe stresses. Cell division asymmetry is an important source of microbial phenotypic heterogeneity. A consecutive set of asymmetric divisions can cause the gradual accumulation of deleterious factors and, at late stages, the death of old pole (mother) cells.

Drug susceptibility testing of slowly growing non-tuberculous mycobacteria using slomyco test-system.

Objective: The objective of the research was to assess the susceptibility of the slowly growing nontuberculous mycobacteria strains to the antimicrobial drugs used for mycobaterioses treatment using SLOMYCO test system.

Materials And Methods: We assessed 363 NTM strains: 177 MAC (161 M. avium, 16 M.

Penetrating cations induce pleiotropic drug resistance in yeast.

Substrates of pleiotropic drug resistance (PDR) transporters can induce the expression of corresponding transporter genes by binding to their transcription factors. Penetrating cations are substrates of PDR transporters and theoretically may also activate the expression of transporter genes. However, the accumulation of penetrating cations inside mitochondria may prevent the sensing of these molecules.

The contribution of Saccharomyces cerevisiae replicative age to the variations in the levels of Trx2p, Pdr5p, Can1p and Idh isoforms.

Asymmetrical division can be a reason for microbial populations heterogeneity. In particular, budding yeast daughter cells are more vulnerable to stresses than the mothers. It was suggested that yeast mother cells could also differ from each other depending on their replicative age.

A Comparison of the Sensititre MycoTB Plate, the Bactec MGIT 960, and a Microarray-Based Molecular Assay for the Detection of Drug Resistance in Clinical Mycobacterium tuberculosis Isolates in Moscow, Russia.

Background: The goal of this study was to compare the consistency of three assays for the determination of the drug resistance of Mycobacterium tuberculosis (MTB) strains with various resistance profiles isolated from the Moscow region.

Methods: A total of 144 MTB clinical isolates with a strong bias toward drug resistance were examined using Bactec MGIT 960, Sensititre MycoTB, and a microarray-based molecular assay TB-TEST to detect substitutions in the rpoB, katG, inhA, ahpC, gyrA, gyrB, rrs, eis, and embB genes that are associated with resistance to rifampin, isoniazid, fluoroquinolones, second-line injectable drugs and ethambutol.

Results: The average correlation for the identification of resistant and susceptible isolates using the three methods was approximately 94%.

[Comparing performance of "TB-BIOCHIP", "Xpert MTB/RIF" and "genotype MTBDRplus" assays for fast identification of mutations in the Mycobacterium tuberculosis complex in sputum from TB patients].

The frequency of mutations causing drug resistance in MTB isolates were studied in the respiratory material obtained from TB-patients in the Moscow Region. In izoniazid-resistant isolates, the most prevalent mutation was found to be the Ser315Thr substitution in the katG gene (15.8%) whereas the most frequent mutations in multidrug-resistant isolates were Ser531Leu and Ser315Thr in the rpoB and katG genes (26.

Analysis of mutations in the gyrA and gyrB genes and their association with the resistance of Mycobacterium tuberculosis to levofloxacin, moxifloxacin and gatifloxacin.

The purpose of the present study was to analyse mutations in the gyrA and gyrB genes of Mycobacterium tuberculosis and define the possible correlation between these mutations and resistance to levofloxacin (LVX), moxifloxacin (MFX) and gatifloxacin (GAT), based on their MICs. One hundred and forty-two M. tuberculosis clinical isolates were collected from pulmonary tuberculosis patients in the Moscow region.

[Use of molecular-biological microchip TB-BIOCHIP-2 for detecting of Mycobacterium tuberculosis with multidrug resistance to fluoroquinolones in patients with new detected and chronic tuberculosis].

At present the left-handed "respiratory" quinolones such as moxifloxacin and levofloxacin are the most promising drugs for therapy of multidrug resistant tuberculosis (MDR). Fast and specific diagnostics of sensitivity of M. tuberculosis (MBT) with MDR to this group of drugs is required for timely prescription of adequate chemotherapy and its correction in case of MBT resistance to fluoroquinolones.

[Investigation of Mycobacterium tuberculosis sensitivity to fluoroquinolone, by revealing gyrA gene mutations].

The resistance of Mycobacterium tuberculosis (MBT) to fluoroquinolones is associated with the mutations concentrated in the gyrA gene that is a structural gene of a gyrase A subunit. Detection of mutations in this portion of the gene allows the sensitivity of MBT to this group of drugs to be rapidly determined.

[The characteristics of the sensitivity of Mycobacterium tuberculosis to rifampicin and isoniazid through determination of mutations in the genes rpoB, katG, inhA, oxyR, and kasA by different molecular biological assays].

Two hundred and two patients with different forms of pulmonary tuberculosis were examined to study the characteristics of sensitivity with the signs of multidrug resistance to rifampicin and isoniazid, by using a microbiological assay of the absolute concentrations and determining mutations in the genes rpoB, katG, inhA, oxyR, and kasA, by employing different molecular biological assays. Mycobacterium tuberculosis (MBT) DNA was isolated from both a diagnostic material (such as sputum, bronchial secretion), and clinical MBT isolates. By showing a higher sensitivity and a higher specificity, as cultural techniques, molecular biological assays of MBT drug sensitivity in patients with tuberculosis were ascertained to accelerate its diagnosis until the patient was admitted to a clinic.

[New technologies in the determination of drug susceptibility in Mycobacterium tuberculosis].

A variety of mutations in the genes rpoB, katG, inhA, ahpC, kasA was studied by using different molecular biological methods (conformational polymorphism of single-chain fragments, heteroduplex analysis, biochips) in rifampicin- and isoniazid-resistant Mycobacterium tuberculosis (MBT) strains isolated from patients with pulmonary tuberculosis. Twenty-nine mutation combinations were identified in the MBT strains. The use of biochips is the most promising method for identifying the type of mutations responsible for the simultaneous resistance to rifampicin and isoniazid.