Igor Stuparević

The epigenetic processes of meiosis in male mice are broadly affected by the widely used herbicide atrazine.

BackgroundEnvironmental factors such as pesticides can cause phenotypic changes in various organisms, including mammals. We studied the effects of the widely used herbicide atrazine (ATZ) on meiosis, a key step of gametogenesis, in male mice.MethodsGene expression pattern was analysed by Gene–Chip array. Genome-wide mapping of H3K4me3 marks distribution was done by ChIP-sequencing of testis tissue using Illumina technologies. RT-qPCR was used to validate differentially expressed genes or differential peaks.ResultsWe demonstrate that exposure to ATZ reduces testosterone levels and the number of spermatozoa in the epididymis and delays meiosis. Using Gene-Chip and ChIP-Seq analysis of H3K4me3 marks, we found that a broad range of cellular functions, including GTPase activity, mitochondrial function and steroid-hormone metabolism, are affected by ATZ. Furthermore, treated mice display enriched histone H3K4me3 marks in regions of strong recombination (double-strand break sites), within very large genes and reduced marks in the pseudoautosomal region of X chromosome.ConclusionsOur data demonstrate that atrazine exposure interferes with normal meiosis, which affects spermatozoa production.

Binding assay for incorporation of alkali-extractable proteins in the Saccharomyces cerevisiae cell wall

Yeasts have developed three different ways of attaching proteins to cell wall glucan. Some proteins are bound to β‐1,3‐glucan non‐covalently, while others are attached covalently, through GPI‐anchor and β‐1,6‐glucan, or directly to β‐1,3‐glucan by alkali‐labile ester linkage between the γ‐carboxyl groups of glutamic acid and the hydroxyl groups of glucoses (Pir proteins). In order to obtain further insight into the binding mechanism, a novel, simple binding assay for Pir‐family proteins was developed. It has been shown that PIR, as well as SCW4 mutants, can bind externally added Ccw5p to their cell walls. A study of appropriate binding conditions revealed the requirement of the native conformation of Ccw5p. The presence of EDTA blocked the binding of Ccw5p, indicating the cation dependence of the reaction. Both wild‐type and mutant cells showed enhanced binding of the Ccw5p in 0.6 M KCl. After disruption of all Pir genes (CCW5, CCW6, CCW7 and CCW8), 67 kDa protein still remained in NaOH extract. SCW4 disruption in the ccw5ccw6ccw7ccw8 mutant resulted in disappearance of the 67 kDa band from the extract, indicating that Scw4p could also be covalently linked to the cell wall by a so‐far unidentified alkali‐labile linkage. Copyright

The conserved histone deacetylase Rpd3 and its DNA binding subunit Ume6 control dynamic transcript architecture during mitotic growth and meiotic development

It was recently reported that the sizes of many mRNAs change when budding yeast cells exit mitosis and enter the meiotic differentiation pathway. These differences were attributed to length variations of their untranslated regions. The function of UTRs in protein translation is well established. However, the mechanism controlling the expression of distinct transcript isoforms during mitotic growth and meiotic development is unknown. In this study, we order developmentally regulated transcript isoforms according to their expression at specific stages during meiosis and gametogenesis, as compared to vegetative growth and starvation. We employ regulatory motif prediction, in vivo protein-DNA binding assays, genetic analyses and monitoring of epigenetic amino acid modification patterns to identify a novel role for Rpd3 and Ume6, two components of a histone deacetylase complex already known to repress early meiosis-specific genes in dividing cells, in mitotic repression of meiosis-specific transcript isoforms. Our findings classify developmental stage-specific early, middle and late meiotic transcript isoforms, and they point to a novel HDAC-dependent control mechanism for flexible transcript architecture during cell growth and differentiation. Since Rpd3 is highly conserved and ubiquitously expressed in many tissues, our results are likely relevant for development and disease in higher eukaryotes.

Integrated RNA- and protein profiling of fermentation and respiration in diploid budding yeast provides insight into nutrient control of cell growth and development

UNLABELLED Diploid budding yeast undergoes rapid mitosis when it ferments glucose, and in the presence of a non-fermentable carbon source and the absence of a nitrogen source it triggers sporulation. Rich medium with acetate is a commonly used pre-sporulation medium, but our understanding of the molecular events underlying the acetate-driven transition from mitosis to meiosis is still incomplete. We identified 263 proteins for which mRNA and protein synthesis are linked or uncoupled in fermenting and respiring cells. Using motif predictions, interaction data and RNA profiling we find among them 28 likely targets for Ume6, a subunit of the conserved Rpd3/Sin3 histone deacetylase-complex regulating genes involved in metabolism, stress response and meiosis. Finally, we identify 14 genes for which both RNA and proteins are detected exclusively in respiring cells but not in fermenting cells in our sample set, including CSM4, SPR1, SPS4 and RIM4, which were thought to be meiosis-specific. Our work reveals intertwined transcriptional and post-transcriptional control mechanisms acting when a MATa/α strain responds to nutritional signals, and provides molecular clues how the carbon source primes yeast cells for entering meiosis. BIOLOGICAL SIGNIFICANCE Our integrated genomics study provides insight into the interplay between the transcriptome and the proteome in diploid yeast cells undergoing vegetative growth in the presence of glucose (fermentation) or acetate (respiration). Furthermore, it reveals novel target genes involved in these processes for Ume6, the DNA binding subunit of the conserved histone deacetylase Rpd3 and the co-repressor Sin3. We have combined data from an RNA profiling experiment using tiling arrays that cover the entire yeast genome, and a large-scale protein detection analysis based on mass spectrometry in diploid MATa/α cells. This distinguishes our study from most others in the field-which investigate haploid yeast strains-because only diploid cells can undergo meiotic development in the simultaneous absence of a non-fermentable carbon source and nitrogen. Indeed, we report molecular clues how respiration of acetate might prime diploid cells for efficient spore formation, a phenomenon that is well known but poorly understood.

Proteolytic processing of the Saccharomyces cerevisiae cell wall protein Scw4 regulates its activity and influences its covalent binding to glucan.

Yeast cell wall contains a number of proteins that are either non-covalently (Scw-proteins), or covalently (Ccw-proteins) bound to β-1,3-glucan, the latter either through GPI-anchors and β-1,6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins). It was shown that a part of Scw4, previously identified among the non-covalently bound cell wall proteins, was covalently attached to wall polysaccharides by a so far unknown alkali sensitive linkage. Thus Scw4 could be released from cell walls by treatments with hot SDS, mild alkali, or β-1,3-glucanases, respectively. It was further shown that non-covalently bound Scw4 (SDS released) underwent the Kex2 proteolytic processing. In this paper it was demonstrated that Scw4 was also processed by yapsins at a position 9 amino acids downstream of the Kex2 cleavage site. Scw4 cleaved at the yapsin site had a markedly lower potential for covalent attachment to glucan. The overproduction of the fully processed form of Scw4 lead to high mortality, particularly in the stationary phase of growth, and to markedly increased cell size. On the other hand, the overproduction of Scw4 processed only by Kex2 or not processed at all had no apparent change in mortality indicating that only the smallest, completely mature form of Scw4 had the activity leading to observed phenotype changes.

The histone deacetylase Rpd3/Sin3/Ume6 complex represses an acetate-inducible isoform of VTH2 in fermenting budding yeast cells

The tripartite Rpd3/Sin3/Ume6 complex represses meiotic isoforms during mitosis. We asked if it also controls starvation‐induced isoforms. We report that VTH1/VTH2 encode acetate‐inducible isoforms with extended 5′‐regions overlapping antisense long non‐coding RNAs. Rpd3 and Ume6 repress the long isoform of VTH2 during fermentation. Cells metabolising glucose contain Vth2, while the protein is undetectable in acetate and during sporulation. VTH2 is a useful model locus to study mechanisms implicating promoter directionality, lncRNA transcription and post‐transcriptional control of gene expression via 5′‐UTRs. Since mammalian genes encode transcript isoforms and Rpd3 is conserved, our findings are relevant for gene expression in higher eukaryotes.

In the quest for new targets for pathogen eradication: the adenylosuccinate synthetase from the bacterium Helicobacter pylori

Abstract Adenylosuccinate synthetase (AdSS) is an enzyme at regulatory point of purine metabolism. In pathogenic organisms which utilise only the purine salvage pathway, AdSS asserts itself as a promising drug target. One of these organisms is Helicobacter pylori, a wide-spread human pathogen involved in the development of many diseases. The rate of H. pylori antibiotic resistance is on the increase, making the quest for new drugs against this pathogen more important than ever. In this context, we describe here the properties of H. pylori AdSS. This enzyme exists in a dimeric active form independently of the presence of its ligands. Its narrow stability range and pH-neutral optimal working conditions reflect the bacterium’s high level of adaptation to its living environment. Efficient inhibition of H. pylori AdSS with hadacidin and adenylosuccinate gives hope of finding novel drugs that aim at eradicating this dangerous pathogen.