Current topics in biochemical research最新文献

Alcohol abuse and dependence in humans causes an extreme shift in metabolism for which the human brain is not evolutionarily prepared. Oxidation of ethanol and acetaldehyde are not regulated, making ethanol a dominating metabolic substrate that prevents the activity of enzymes from oxidizing their usual endogenous substrates. The enzymes required to oxidize ethanol across the variety of affected tissues all produce acetaldehyde which is then converted to acetate by aldehyde dehydrogenases (ALDHs). ALDHs are NAD+-dependent enzymes, and mitochondrial ALDH2 is likely the primary contributor to ethanol-derived acetaldehyde clearance in cells. Metabolism of alcohol has several adverse effects on mitochondria including increased free radical levels, hyperacetylation of mitochondrial proteins, and excessive mitochondrial fragmentation. This review discusses the role of astrocytic and neuronal mitochondria in ethanol metabolism that contributes to the acute and chronic changes in mitochondrial function and morphology, that might promote tolerance, dependence and withdrawal. We also propose potential modes of therapeutic intervention to reduce the toxicity of chronic alcohol consumption.

The MiT/TFE family of proteins are important regulators of a number of metabolic processes. One of their most important roles is activating the autophagy pathway in the setting of nutrient deprivation or buildup of toxic metabolites. Their proper and improper functioning in this role has been linked to several types of disease, including cancer and multiple forms of neurodegeneration. In this review we will briefly outline what is known about individual family members' roles in regulating autophagy across a variety of contexts.

β-caryophyllene (BCP) exhibits anti-proliferative properties in cancer cells. Here, we examine the hypothesis that BCP induces membrane remodeling. Our data show that high concentrations of BCP increase membrane permeability of human breast cells (hBrC) causing detachment and cell death. At a sub-lethal concentration of BCP, we show that BCP induces a striking upregulation of genes involved in cholesterol biosynthesis, including the gene that encodes for HMGCoA reductase (HMGCR), the rate-determining step in cholesterol biosynthesis. In addition, stearoyl-CoA desaturase (SCD) is also upregulated which would lead to the enhanced formation of monounsaturated fatty acids, specifically oleate and palmitoleate from stearoyl CoA and palmitoyl CoA, respectively. These fatty acids are major components of membrane phospholipids and cholesterol esters. Together, these data suggest that cells respond to BCP by increasing the synthesis of components found in membranes. These responses could be viewed as a repair mechanism and/or as a mechanism to mount resistance to the cytotoxic effect of BCP. Blocking HMGCR activity enhances the cytotoxicity of BCP, suggesting that BCP may provide an additional therapeutic tool in controlling breast cancer cell growth.

Upon binding to insulin, the β-subunit of insulin receptor (IR) is phosphorylated and instantly activates intracellular signaling. A defect in this process causes the development of several metabolic disorders including non-insulin-dependent diabetes, such as type 2 and gestational diabetes mellitus (GDM). Under diabetic conditions the phosphorylation of IR in placenta, but not in platelets, is impaired. Interestingly the cellular distribution of the serotonin transporter (SERT), which utilizes the insulin signaling for posttranslational modification, shows tissue-type-dependent variation: SERT function is impaired in GDM-associated placenta, but not in platelets. In order to understand the correlation between IR, SERT and their tissue-type-dependent features, we tested an association between SERT and IR and whether this association affects the phosphorylation of IR. Using various approaches, we demonstrated a physical association between the Carboxyl terminal of SERT and the β-subunit of IR. This association was found on the plasma membrane of the placenta and the platelets. Next, the contribution of the SERT-IR association to the phosphorylation of IR was analyzed in heterologous and endogenous expression systems following insulin-treatment. The in vivo impact of SERT-IR association on the phosphorylation of IR was explored in placenta and platelets of SERT gene knockout (KO) mice. The IR phosphorylation was significantly downregulated only in the placenta, but not in platelets of SERT-KO mice. These findings are supported by time course experiments, which demonstrate that the phosphorylation of IR occurs vis-a-vis IR-SERT association, and at least one of the IR binding domains is identified as the carboxyl-terminus of SERT. These findings suggest an important role for IR-SERT association in maintaining the phosphorylation of IR and regulating the insulin signaling in placenta.

The present study was conducted to evaluate the response of kidneys in Wistar rats following long-term exposure to Al₂O₃ nanomaterials (NMs). To achieve this objective, Al₂O₃ of three different sizes (30 nm, 40 nm and bulk) was orally administered for 28 days to 9 groups of 10 Wistar rats each at the dose of 500, 1000 and 2000 mg/kg/rat. A tenth group of 10 rats received distilled water and served as control. After 28 days of exposure the animals were sacrificed and the serum was collected and tested for the activity levels of creatinine and urea following standard methods. Induction of oxidative stress was also investigated by assessing thiobarbituric acid reactive substances (TBARS) (MDA), protein carbonyl, reduced glutathione (GSH), superoxide dismutase (SOD) and catalase (CAT) activities. A histopathological evaluation was also performed to determine the extent of kidney damage. The results showed that both serum creatinine and serum urea levels increased significantly in the treated rats compared to control animals. The increase was found to be more in Al₂O₃-30 nm treated rats followed by Al₂O₃-40 nm and Al₂O₃-bulk treated rats in a dose-dependent manner. Further administration of Al₂O₃ significantly increased the activities of TBARS, protein carbonyl, catalase and decreased the activities of GSH and SOD in a dose-dependent manner in the kidney of rats compared with the control group. Histopathological evaluation showed significant morphological alterations in kidney tissues of treated rats in accordance with biochemical parameters. Taken together, the results of this study demonstrate that Al₂O₃ is nephrotoxic and its toxicity may be mediated through oxidative stress. Further, the results suggest that prolonged oral exposure to Al₂O₃ NMs has the potential to cause biochemical and histological alterations in kidney of rats at high concentration.

Antigen presentation by class II MHC proteins (MHC-II) is a critical component of the adaptive immune response to foreign pathogens. Our understanding of how antigens are presented has been greatly enhanced by crystallographic studies of MHC-II-peptide complexes, which have shown a canonical extended conformation of peptide antigens within the peptide-binding domain of MHC-II. However, a detailed understanding of the peptide loading process, which is mediated by the accessory molecule HLA-DM (DM), remains unresolved. MHC-II proteins appear to undergo conformational changes during the peptide loading/exchange process that have not been clearly described in a structural context. In the absence of a crystal structure for the DM-MHC-II complex, mutational studies have provided a low resolution understanding as to how these molecules interact. This review will focus on structural and biochemical studies of the MHC-II-peptide interaction, and on studies of the DM-MHC-II interaction, with an emphasis on identifying structural features important for the mechanism of DM mediated peptide catalysis.

PTEN is a tumor suppressor best characterized for its role as a lipid phosphatase in antagonizing the PI3-kinase pathway. Several recent studies have identified proteins that form high molecular weight complexes with PTEN in different subcellular compartments. PTEN is critical for early embryonic development, cell proliferation, cell survival and stem cell function. The discovery of PTEN complex components may help our understanding of its biological functions. In this review, PTEN complex components, functions and their regulation will be discussed.

Glycosylation plays an important role in several types of recognition processes associated with fertilisation and development, allergies, pathological events and cell death. Whereas the amino acid sequence of a protein is fixed by the DNA, the glycosylation abilities depend on enzymes and substrates currently present in the cell.During the last decades our knowledge on glycosylation - the structure of glycans as well as the corresponding biochemical pathways including the responsible enzymes - especially on glycans of mammalian origin increased enormously. The glycosylation capabilities of other species were under investigation only if their glycans were for any reason connected to human life (e.g. some recognition processes of pathogens or allergy on food or plant glycans) or if they were potent candidates for cell culture systems for the expression of therapeutic agents (some insect, yeast and plant cells). However, in the meantime there is an increasing interest also in invertebrate glycosylation.Snails in particular show a broad spectrum of glycosylation abilities within their N-glycosylation pattern. In one case this has been shown to be involved in an intermediate host - parasite recognition process. For other snail species, it was found that they share many structural elements of N-glycans with mammals, plants, insects or nematodes. Sometimes several of these elements are present within one single structure.Here we present an overview of the current knowledge of N-glycosylation of snails, the glycan structures and the corresponding enzymes involved in the biosynthetic glycosylation pathway.