Oxidative Stress Induced Inflammation Initiates Functional Decline of Tear Production

Oxidative damage and inflammation are proposed to be involved in an age-related functional decline of exocrine glands. However, the molecular mechanism of how oxidative stress affects the secretory function of exocrine glands is unclear. We developed a novel mev-1 conditional transgenic mouse model (Tet-mev-1) using a modified tetracycline system (Tet-On/Off system). This mouse model demonstrated decreased tear production with morphological changes including leukocytic infiltration and fibrosis. We found that the mev-1 gene encodes Cyt-1, which is the cytochrome b₅₆₀ large subunit of succinate-ubiquinone oxidoreductase in complex II of mitochondria (homologous to succinate dehydrogenase C subunit (SDHC) in humans). The mev-1 gene induced excessive oxidative stress associated with ocular surface epithelial damage and a decrease in protein and aqueous secretory function. This new model provides evidence that mitochondrial oxidative damage in the lacrimal gland induces lacrimal dysfunction resulting in dry eye disease. Tear volume in Tet-mev-1 mice was lower than in wild type mice and histopathological analyses showed the hallmarks of lacrimal gland inflammation by intense mononuclear leukocytic infiltration and fibrosis in the lacrimal gland of Tet-mev-1 mice. These findings strongly suggest that oxidative stress can be a causative factor for the development of dry eye disease.     

Dehydroabietic acid, a phytochemical, acts as ligand for PPARs in macrophages and adipocytes to regulate inflammation

Obesity is characterized by an enhanced infiltration of macrophages to adipose tissues, which is closely associated with the low-grade inflammatory state and obesity-related pathologies such as type 2 diabetes and cardiovascular diseases. We showed here that dehydroabietic acid (DAA) is a potent PPARα/γ dual activator. Furthermore, we examined the anti-inflammatory effects of DAA in stimulated macrophages and in the coculture of macrophages and adipocytes. DAA significantly suppressed the production of proinflammatory mediators such as MCP-1, TNF-α, and NO in stimulated RAW 264 macrophages and in the coculture of RAW 264 macrophages and 3T3-L1 adipocytes. These results suggest that DAA is a valuable medicinal and food component for improving inflammatory changes associated with obesity-related diabetes.     

Synthesis of chondroitin sulfate E octasaccharide in a repeating region involving an acetamide auxiliary

Chondroitin sulfate E repeating octasaccharide was effectively synthesized in a stereocontrolled manner by adopting an acetamide-type disaccharide unit. In the tetrasaccharide synthesis we isolated a characteristic glycosyl imidate as a reactive intermediate. An acetamide auxiliary involves the glycosylation mechanism.     

Gene expression and sensitivity in response to copper stress in rice leaves

Gene expression in response to Cu stress in rice leaves was quantified using DNA microarray (Agilent 22K Rice Oligo Microarray) and real-time PCR technology. Rice plants were grown in hydroponic solutions containing 0.3 (control), 10, 45, or 130 microM of CuCl(2), and Cu accumulation and photosynthesis inhibition were observed in leaves within 1 d of the start of treatment. Microarray analysis flagged 305 Cu-responsive genes, and their expression profile showed that a large proportion of general and defence stress response genes are up-regulated under excess Cu conditions, whereas photosynthesis and transport-related genes are down-regulated. The Cu sensitivity of each Cu-responsive gene was estimated by the median effective concentration value (EC50) and the range of fold-changes (F) under the highest (130 microM) Cu conditions (|log(2)F|(130)). Our results indicate that defence-related genes involved in phytoalexin and lignin biosynthesis were the most sensitive to Cu, and that plant management of abiotic and pathogen stresses has overlapping components, possibly including signal transduction.     

Substrate recognition and binding by RseP, an Escherichia coli intramembrane protease

Escherichia coli RseP belongs to the S2P family of intramembrane cleaving proteases. RseP catalyzes proteolytic cleavage of the membrane-bound anti-sigma(E) protein RseA as an essential step in transmembrane signal transduction in the sigma(E) extracytoplasmic stress response pathway. RseP cleaves transmembrane segments of membrane proteins, but the molecular mechanisms of its substrate recognition and proteolytic action remain largely unknown. Here we analyzed interaction between RseP and substrate membrane proteins. Co-immunoprecipitation assays showed that helix-destabilizing residues in a substrate transmembrane segment, which were previously shown to be required for efficient proteolysis of the substrate by RseP, stabilize the substrate-RseP interaction. Substitutions of certain amino acid residues, including those evolutionarily conserved, in the third transmembrane region (TM3) of RseP weakened the RseP-substrate interaction. Specific combinations of Cys substitutions in RseP TM3 and in the RseA transmembrane segment led to the formation of disulfide bonds upon oxidation, suggesting that TM3 of RseP directly binds the substrate. These results provide insights into the mechanism of membrane protein proteolysis by RseP.     

Synthesis and silencing properties of siRNAs possessing lipophilic groups at their 3'-termini

Short-interfering RNAs (siRNAs) conjugated with lipophilic groups at their 3'-termini were synthesized. The properties of the synthesized siRNAs were examined in detail, and it was found that at low concentrations, their silencing abilities were dependent on the positions of the modifications and the types of organic molecules attached. Although the modification of siRNAs with palmitic acid or oleic acid at the 3'-end slightly reduced their silencing activities, siRNAs had enough abilities to induce RNAi at 10 nM concentrations. On the other hand, the modification of siRNAs with cholesterol at the 3'-end of the passenger strand was tolerated; however, the modification at the guide strand significantly reduces its silencing activity. The siRNAs modified with the lipophilic groups did not possess ability to penetrate the plasma membranes of HT-1080 cells without the transfection reagent. However, the results described in this report will aid in designing novel siRNAs with cell membrane-permeable molecules.     

Mutagenesis of uracil-DNA glycosylase deficient mutants of the extremely thermophilic eubacterium Thermus thermophilus

Thermus thermophilus is an extremely thermophilic, aerobic, and gram-negative eubacterium that grows optimally at 70-75 degrees C, pH 7.5. In extremely high temperature environment, DNA damages in cells occur at a much higher frequency in thermophiles than mesophiles such as E. coli. When temperature rises, the deamination of cytosine residues in double-strand DNA is expected to increase greatly. T. thermophilus HB27 has two putative uracil-DNA glycosylase genes (udgA and udgB). Expression level of udgA gene was 2-3 times higher than that of udgB at 70, 74, and 78 degrees C when it was monitored by beta-glucosidase reporter assay. We developed hisD(3110), hisD(3113), hisD(3115), and hisD(174) marker allele that can specifically detect G:C-->A:T, C:G-->A:T, T:A-->A:T, and A:T-->G:C base-substitutions, respectively, by His(+) reverse mutations. We then disrupted udgA and udgB by thermostable kanamycin-resistant gene (htk) or pyrE gene insertion in each hisD background, and their spontaneous His(+) reversion frequencies were compared. A udgA,B double mutant showed a pronounced increase in G:C-->A:T reversion frequency compared with each single udg mutant, udgA or udgB. Estimated mutation rates of the udgA,B mutant cultured at 60, 70, and 78 degrees C were about 2, 12, and 117 His(+)/10(8)/generation, respectively. At 70 degrees C culture, increased ratio of the mutation rate compared with the udg(+) strain was 12-fold in udgA, 3-fold in udgB, and 56-fold in udgA,B mutant. On the other hand, no difference was observed in other mutations of C:G-->A:T, T:A-->A:T, and A:T-->G:C between udgA,B double mutant and the parent udg(+) strain. The present results indicated that gene products of udgB as well as udgA functioned in vivo to remove uracil in DNA and prevent G:C-->A:T transition mutations.     

Structural and quantitative evidence of α2–6-sialylated <Emphasis Type="Italic">N</Emphasis>-glycans as markers of the differentiation potential of human mesenchymal stem cells

Human somatic stem cells such as mesenchymal stem cells (hMSCs) have the capacity to differentiate into mesenchymal tissue lineages and to alter immune regulatory functions. As such, they hold promise for use in stem cell-based therapies. However, no method is currently available to evaluate the actual differentiation capacity of hMSCs prior to cell transplantation. Previously, we performed a comprehensive glycan profiling of adipose-derived hMSCs using high-density lectin microarray and demonstrated that α2–6-sialylation is a marker of the differentiation potential of these cells. Nevertheless, no information was available about the structural details of these of α2–6-sialylated glycans. Here we used high performance liquid chromatography (HPLC) analysis combined with mass spectrometry (MS) to perform a structural and quantitative glycome analysis targeting both N- and O-glycans derived from early (with differentiation ability) and late (without differentiation ability) passages of adipose tissue-derived hMSCs. Findings in these cells were compared with those from human induced pluripotent stem cells (hiPSCs), human dermal fibroblasts (hFibs) and cartilage tissue-derived chondrocytes. A higher percentage of α2–6-sialylated N-glycans was detected in early passage cells (24–28 % of sialylated N-glycans) compared with late passage cells (13–15 %). A major α2–6-sialylated N-glycan structure detected in adipose-derived hMSCs was that of mono-sialylated biantennary N-glycan. Similar results were obtained for the cartilage tissue-derived chondrocytes, Yub621c (28 % for passage 7 and 5 % for passage 28). In contrast, no significant differences were observed between early and late passage hMSCs with respect to α2–6-sialylated O-glycan percentages. These results demonstrate that levels of α2–6-sialylated N-glycans, but not O-glycans, could be used as markers of the differential potential of hMSCs.