Structure of the human signal peptidase complex reveals the determinants for signal peptide cleavage

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Degradation of indole by enrichment culture and Pseudomonas aeruginosa Gs isolated from mangrove sediment

Microbial degradation of indole was investigated using enrichment culture and Pseudomonas aeruginosa Gs obtained from mangrove sediment of Hong Kong Nature Reserve as inocula. Degradation of indole using this enrichment culture and Ps. aeruginosa Gs was quantified on reversed-phase high-performance liquid chromatography. Initial concentrations of indole affected degradation and the results conformed to the zero-order kinetic model. The optimum pH and salinity were 7.0 and 5‰, respectively, for indole degradation by Ps. aeruginosa Gs. Two major metabolites of indole degradation were detected. This study suggests that indole can be rapidly degraded by indigenous microorganisms of the mangrove environment.     

Metabolically driven equilibrium shift of asymmetric amination of ketones by ω-transaminase using alanine as an amino donor

Removal of a side product to overcome unfavorable equilibrium is a prerequisite for the asymmetric amination of ketones using ω-transaminase (ω-TA). Alanine has been preferred as an amino donor because its deamination product (i.e. pyruvate) is easily removable by several enzymatic methods. Here, we demonstrated that the removal of pyruvate by an innate metabolic pathway could afford equilibrium shift of the ω-TA reactions.     

Enhanced butanol production by eukaryotic Saccharomyces cerevisiae engineered to contain an improved pathway

Compared with ethanol, butanol has more advantageous physical properties as a fuel, and biobutanol is thus considered a promising biofuel material. Biobutanol has often been produced by Clostridium species; however, because they are strictly anaerobic microorganisms, these species are challenging to work with. We attempted to introduce the butanol production pathway into yeast Saccharomyces cerevisiae, which is a well-known microorganism that is tolerant to organic solvents. 1-Butanol was found to be produced at very low levels when the butanol production pathway of Clostridium acetobutylicum was simply introduced into S. cerevisiae. The elimination of glycerol production pathway in the yeast contributed to the enhancement of 1-butanol production. In addition, by the use of trans-enoyl-CoA reductase in the engineered pathway, 1-butanol production was markedly enhanced to yield 14.1 mg/L after 48 h of cultivation.     

Powerful Drosophila screens that paved the wingless pathway

The Wnt/Wingless (Wg) signaling cascade controls a number of biological processes in animal development and adult life; aberrant Wnt/Wg signaling can cause diseases. In the 1980s genes were discovered that encode core Wnt/Wg pathway components: their mutant phenotypes were similar and an outline of a signaling cascade emerged. Over the years our knowledge of this important signaling system increased and more components were uncovered that are instrumental for Wnt/Wg secretion and transduction. Here we provide an overview of these discoveries, the technologies involved, with a particular focus on the important role Drosophila screens played in this process.     

Patient navigation pathway and barriers to treatment seeking in cancer in India: A qualitative inquiry

Cancer is a leading cause of mortality worldwide. Early diagnosis and treatment of cancer may curb the growing burden of the disease. Understanding cancer patients’ navigation pathways for seeking treatment is important in order to facilitate early diagnosis and treatment. With this background we conducted a hospital-based cross-sectional study comprising 68 randomly selected cancer inpatients in a tertiary cancer specialty hospital in Odisha, India, to explore the treatment-seeking pathways of the cancer patients and the barriers and enablers in seeking treatment. Financial constraint is one of the major reasons for the delay in accessing treatment, even when patients are suspected of or diagnosed with cancer. Low awareness of the presenting signs and symptoms of cancer and limited knowledge of the availability of cancer diagnosis and treatment facilities are major factors contributing to delay. Family and friends’ support is found to be the major enabling factor toward seeking treatment. Generation of awareness of cancer among the general population and primary-care practitioners – including those in alternative systems of medicine – is important. Information on diagnostic and treatment services appears to be a felt need.     

Fascin,may the Forked be with you

The FGFR pathway triggers a wide range of key biological responses. Among others, the Breathless (Btl, Drosophila FGFR1) receptor cascade promotes cell migration during embryonic tracheal system development. However, how the actin cytoskeleton responds to Btl pathway activation to induce cell migration has remained largely unclear. Our recent results shed light into this issue by unveiling a link between the actin-bundling protein Singed (Sn) and the Btl pathway. We showed that the Btl pathway regulates sn, which leads to the stabilization of the actin bundles required for filopodia formation and actin cytoskeleton rearrangement. This regulation contributes to tracheal migration, tracheal branch fusion and tracheal cell elongation. Parallel actin bundles (PABs) are usually cross-linked by more than one actin-bundling protein. Accordingly, we have also shown that sn synergistically interacts with forked (f), another actin crosslinker. In this Extra View we extend f analysis and hypothesize how both actin-bundling proteins may act together to regulate the PABs during tracheal embryonic development. Although both proteins are required for similar tracheal events, we suggest that Sn is essential for actin bundle initiation and stiffening, while F is required for the lengthening and further stabilization of the PABs.     

糖原合酶激酶-3，一个信号通路的重要调控因子

糖原合酶激酶-3 (glycogen synthase kinase-3,GSK-3) 是一种多功能的丝氨酸／苏氨酸蛋白激酶,在蛋白质合成、信号传递、细胞增殖、细胞分化、神经功能、肿瘤形成及胚胎发育等众多细胞进程中均扮演重要的角色.GSK-3 能够使多种底物发生磷酸化,并参与胰岛素、Wnt及Hedgehog 等多个信号通路的调控. GSK-3抑制剂在信号通路中能有效地抑制病理情况下GSK-3活性的异常增高,达到治疗的目的.GSK-3的抑制剂将作为一种潜在的药物对治疗糖尿病、阿尔海默茨症、肿瘤等疾病发挥效用.