Chromatin repair after oxidative stress: Role of PARP-mediated proteasome activation

Oxidative stress is an inevitable process in the nucleus, especially in antitumor chemotherapy, and adaptation by defense mechanisms seems to be one element in the development of long-term resistance to many chemotherapeutic drugs. In this study, a potential chromatin repair mechanism during oxidative stress was investigated in HT22 cells. The 20S proteasome has been shown to be largely responsible for the degradation of oxidatively modified histone proteins in the nucleus. Poly(ADP-ribosyl)ation reactions also play an important role in DNA repair as a consequence of oxidative damage and single-strand breaks. Such a reaction may occur also with the 20S proteasome—with a known increase in enzymatic activity—and also with histones—reducing their proteolytic susceptibility as shown for the first time here. After hydrogen peroxide treatment of HT22 cells, degradation of the model peptide substrate suc-LLVY-MCA and degradation of oxidized histones by nuclear proteasome increased. During the removal of protein carbonyls, single-strand breaks and 8-hydroxy-2′-deoxyguanosine, proteasome, and poly(ADP-ribose) polymerase-1 enzymes were shown to play tightly interacting roles. Our results following the repair of oxidative damage show the proteolytic activation of proteasome concerning poly(ADP-ribosyl)ation together with a decline in poly(ADP-ribosyl)ation of oxidized histones, leading to a selective recognition of oxidatively modified histones.     

Integration of Metabolic Modeling and Phenotypic Data in Evaluation and Improvement of Ethanol Production Using Respiration-Deficient Mutants of Saccharomyces cerevisiae

Flux balance analysis and phenotypic data were used to provide clues to the relationships between the activities of gene products and the phenotypes resulting from the deletion of genes involved in respiratory function in Saccharomyces cerevisiae. The effect of partial or complete respiratory deficiency on the ethanol production and growth characteristics of hap4Δ/hap4Δ, mig1Δ/mig1Δ, qdr3Δ/qdr3Δ, pdr3Δ/pdr3Δ, qcr7Δ/qcr7Δ, cyt1Δ/cyt1Δ, and rip1Δ/rip1Δ mutants grown in microaerated chemostats was investigated. The study provided additional evidence for the importance of the selection of a physiologically relevant objective function, and it may improve quantitative predictions of exchange fluxes, as well as qualitative estimations of changes in intracellular fluxes. Ethanol production was successfully predicted by flux balance analysis in the case of the qdr3Δ/qdr3Δ mutant, with maximization of ethanol production as the objective function, suggesting an additional role for Qdr3p in respiration. The absence of similar changes in estimated intracellular fluxes in the qcr7Δ/qcr7Δ mutant compared to the rip1Δ/rip1Δ and cyt1Δ/cyt1Δ mutants indicated that the effect of the deletion of this subunit of complex III was somehow compensated for. Analysis of predicted flux distributions indicated self-organization of intracellular fluxes to avoid NAD⁺/NADH imbalance in rip1Δ/rip1Δ and cyt1Δ/cyt1Δ mutants, but not the qcr7Δ/qcr7Δ mutant. The flux through the glycerol efflux channel, Fps1p, was estimated to be zero in all strains under the investigated conditions. This indicates that previous strategies for improving ethanol production, such as the overexpression of the glutamate synthase gene GLT1 in a GDH1 deletion background or deletion of the glycerol efflux channel gene FPS1 and overexpression of GLT1, are unnecessary in a respiration-deficient background.     

Theoretical and Experimental Study of DNA Helix-Coil Transition in Acidic and Alkaline Medium

Abstract

The theoretical approach to the calculation of the influence of selective binding of small ligands on DNA helix-coil transition has been described in the previous paper (Lando D.Yu., J. Biomol. Struct. Dyrt., (1994)). In the present paper that method is used for the study of DNA protonation and deprotonation in acidic and alkaline medium by theoretical analysis of pH effect on DNA heat denaturation.

The mechanism of DNA protonation in acidic medium and pK values of nucleotides are well known. It gave us an opportunity to check the theory without any fitting of pK values. A good agreement between experimental and calculated functions T_m(pH) and ΔT(pH) (melting temperature and melting range width) obtained for acidic medium proved the validity of the theory. However, for alkaline medium there was not even qualitative agreement when the agreed-upon mechanism of deprotonation was considered. Looking into the cause of the discrepancy, we have studied the DNA melting for different mechanisms of deprotonation by calculation of T_m(pH) and ΔT(pH). As a result, it has been established that the discrepancy is due to deprotonation of bonded GC base pairs of helical DNA regions (pK= 11).

It was shown that the early known protonation and newly found deprotonation of helical DNA essentially stabilised double helix in alkaline and acidic medium.     

T cell dynamics during induction of tolerance and suppression of experimental allergic encephalomyelitis

The cell dynamics associated with induction of peripheral T cell tolerance remain largely undefined. In this study, an in vivo model was adapted to two-photon microscopy imaging, and T cell behavior was analyzed on tolerogen-induced modulation. FcγR-deficient (FcγR(-/-)) mice were unable to resist or alleviate experimental allergic encephalomyelitis when treated with Ig-myelin oligodendrocyte glycoprotein (MOG) tolerogen, an Ig carrying the MOG35-55 peptide. However, when FcγR(+/+) dendritic cells (DCs) are adoptively transferred into FcγR(-/-) mice, uptake and presentation of Ig-MOG occurs and the animals were able to overcome experimental allergic encephalomyelitis. We then fluorescently labeled FcγR(+/+) DCs and 2D2 MOG-specific TCR-transgenic T cells, transferred them into FcγR(-/-) mice, administered Ig-MOG, and analyzed both T cell-DC contact events and T cell motility. The results indicate that tolerance takes place in lymphoid organs, and surprisingly, the T cells do not become anergic but instead have a Th2 phenotype. The tolerant Th2 cells displayed reduced motility after tolerogen exposure similar to Th1 cells after immunization. However, the Th2 cells had higher migration speeds and took longer to exhibit changes in motility. Therefore, both Th1 immunity and Th2 tolerance alter T cell migration on Ag recognition, but the kinetics of this effect differ among the subsets.     

Genetic structure and diversity analysis revealed by AFLP on different Echinochloa spp. from northwest Turkey

Rice is one of the most economically important cereal crops in the world. The genus Echinochloa is the most competitive and difficult to control weeds in the rice fields. Improving the knowledge on the genetic diversity and structure of Echinochloa spp. can supply crucial information for designing effective management strategies for weed control in rice breeding. In the study, 28 Echinochloa spp. genotypes were subjected to the analysis of genetic diversity using four amplified fragment length polymorphism selective primer combinations. The number of polymorphic fragments per primer combination detected ranged from 28 to 50 bands with an average of 41.5 bands. Average polymorphic information content (PIC) was 0.26 in overall primer combinations. E_ACA-M_CAG primer combination showed the highest PIC (0.52) which can be a good candidate primer combination to verify genetic diversity in Echinochloa spp. The unweighted pair-group method of the arithmetic average and principal coordinate analysis showed a clear distinction among the genotypes and the genotypes divided into three clusters in the dendrogram results. A model-based structure analysis revealed the presence of two populations. The accessions were clearly assigned to a single population in which >70 % of their inferred ancestry was derived from one of the model-based populations. However, three genotypes (10.7 %) in the sample were categorized as having admixed ancestry. The study showed that genetic variation and population structure are determined among genotypes collected from different locations. High level of genetic variation in both intra and inter species was detected.