Oxidation of biological molecules with age and induced oxidative stress in different growth phases of Saccharomyces cerevisiae.

One of the mechanistic approaches for explaining ageing is the oxidative stress theory of ageing. Saccharomyces cerevisiae has been used as a model to study ageing due to many factors. We have attempted to investigate if the differential ability to withstand oxidative stress can be correlated with their lifespans. In all the four strains studied (AP22, 699, 8C, and SP4), there was no age-associated increases in lipid peroxidation levels measured as thiobarbituric acid reactive substances (TBARS). Under induced oxidative stress conditions, there was an increased TBARS level in both the ages assessed with a quantum-fold increase in the stationary phase cells of AP22. In contrast, the late stationary phase cells of 8C exhibited the least susceptibility to induced oxidative stress. The level of TBARS in both exponential and late stationary phase cells of 699 was overall more than that in the other three strains. Protein carbonylation increased with age in 8C and 699. Induced stress increased carbonylation in the exponential cells of SP4 and 699 and the stationary phase cells of all four strains. Protein carbonylation data indicate that the AP22 cells exhibit decreased protein carbonylation vis-à-vis the other strains. Induced stress data showed that while the exponential cells of 699 are susceptible, the late stationary phase cells of 699 are most resistant. Western blotting analysis using anti-HNE antibodies showed two proteins of molecular mass ~ 56 and ~ 84 kDa that were selectively modified with age in all the strains. Under induced stress conditions, an additional protein of ~ 69 kDa was oxidized. Our investigation shows that the difference in lifespan between the four strains of S. cerevisiae may be regulated by oxidative stress. Knowledge of the identity of the oxidized proteins will significantly facilitate a better understanding of the effect of oxidative stress conditions on the cells of S. cerevisiae.

Protein extraction from Saccharomyces cerevisiae at different growth phases.

Saccharomyces cerevisiae is an established model organism with a well characterized genome. However, this model presents a unique problem due to a very resistant cell wall which develops in the late stationary phase resulting in sub-optimal extraction of proteins from such cells using majority of the cell lysis protocols. In this study, several methods from the literature with modifications thereof for lysis of S. cerevisiae cells were analyzed for their suitability for redox proteomics and biological activity studies of both exponential and late stationary phase cultures. The protocols applied are glass bead lysis, sonication, their combinations, alkali extraction, hot-SDS extraction methods and their modifications. The glass bead lysis method showed low yield but could be convenient in cases where in vitro processing steps post extraction is required or if only hydrophilic proteins are of interest. Hot-SDS and alkali extraction protocols yielded higher amount of proteins and these methods are potentially suitable for Western blotting and redox proteomic studies but allow no post-processing treatment(s) on the extracts which may be required for aging- and oxidative stress-related or other studies.

Role of Catalase in Oxidative Stress- and Age-Associated Degenerative Diseases.

Reactive species produced in the cell during normal cellular metabolism can chemically react with cellular biomolecules such as nucleic acids, proteins, and lipids, thereby causing their oxidative modifications leading to alterations in their compositions and potential damage to their cellular activities. Fortunately, cells have evolved several antioxidant defense mechanisms (as metabolites, vitamins, and enzymes) to neutralize or mitigate the harmful effect of reactive species and/or their byproducts. Any perturbation in the balance in the level of antioxidants and the reactive species results in a physiological condition called "oxidative stress." A catalase is one of the crucial antioxidant enzymes that mitigates oxidative stress to a considerable extent by destroying cellular hydrogen peroxide to produce water and oxygen. Deficiency or malfunction of catalase is postulated to be related to the pathogenesis of many age-associated degenerative diseases like diabetes mellitus, hypertension, anemia, vitiligo, Alzheimer's disease, Parkinson's disease, bipolar disorder, cancer, and schizophrenia. Therefore, efforts are being undertaken in many laboratories to explore its use as a potential drug for the treatment of such diseases. This paper describes the direct and indirect involvement of deficiency and/or modification of catalase in the pathogenesis of some important diseases such as diabetes mellitus, Alzheimer's disease, Parkinson's disease, vitiligo, and acatalasemia. Details on the efforts exploring the potential treatment of these diseases using a catalase as a protein therapeutic agent have also been described.

Syntheses of taiwaniaquinone F and taiwaniaquinol A via an unusual remote C-H functionalization.

A protecting-group-free route to (-)-taiwaniaquinone F based on a ring contraction and subsequent aromatic oxidation of a sugiol derivative is reported. In addition, the first synthesis of (+)-taiwaniaquinol A is reported via short time exposure of (-)-taiwaniaquinone F to sunlight triggering a remote C-H functionalization. The hypothesis that the biogenesis of some methylenedioxy bridged natural products could proceed via similar nonenzymatic mechanisms is presented.

Enantioselective nitroso-Diels-Alder reaction and its application for the synthesis of (-)-peracetylated conduramine A-1.

Cu(I)-catalyzed enantioselective nitroso-Diels-Alder reactions (NDA reactions) of 2-nitrosopyridine with various dienes are presented. The [CuPF(6)(MeCN)(4)]/Walphos-CF(3) catalyst system is best suited to catalyze the NDA reaction of various dienes by using 2-nitrosopyridine as a dienophile. In most of the cases studied, cycloadducts are obtained in quantitative yield with very good to excellent enantioselectivities. Based on DFT calculations, a model to explain the stereochemical outcome of the NDA reaction is presented. Finally, an efficient short synthesis of (-)-peracetylated conduramine A-1 by applying the enantioselective NDA reaction as a key step is described.