Biogenic production of DMSP and its degradation to DMS—their roles in the global sulfur cycle

Dimethyl sulfide(DMS) is the most abundant form of volatile sulfur in Earth's oceans, and is mainly produced by the enzymatic clevage of dimethylsulfoniopropionate(DMSP). DMS and DMSP play important roles in driving the global sulfur cycle and may affect climate. DMSP is proposed to serve as an osmolyte, a grazing deterrent, a signaling molecule, an antioxidant, a cryoprotectant and/or as a sink for excess sulfur. It was long believed that only marine eukaryotes such as phytoplankton produce DMSP. However, we recently discovered that marine heterotrophic bacteria can also produce DMSP, making them a potentially important source of DMSP. At present, one prokaryotic and two eukaryotic DMSP synthesis enzymes have been identified.Marine heterotrophic bacteria are likely the major degraders of DMSP, using two known pathways: demethylation and cleavage.Many phytoplankton and some fungi can also cleave DMSP. So far seven different prokaryotic and one eukaryotic DMSP lyases have been identified. This review describes the global distribution pattern of DMSP and DMS, the known genes for biosynthesis and cleavage of DMSP, and the physiological and ecological functions of these important organosulfur molecules, which will improve understanding of the mechanisms of DMSP and DMS production and their roles in the environment.     

The dysfunction of ATPases due to impaired mitochondrial respiration in phosgene-induced pulmonary edema

Phosgene is a toxic gas that is widely used in modern industry, and its inhalation can cause severe pulmonary edema. There is no effective clinical treatment because the mechanism of phosgene-induced pulmonary edema still remains unclear. Many studies have demonstrated that the Na⁺/K⁺-ATPase plays a critical role in clearing pulmonary edema and the inhibition of Na⁺/K⁺-ATPase protein expression has been found in many other pulmonary edema models. In the present study, after the mice were exposed to phosgene, there was serious pulmonary edema, indicating the dysfunction of the ATPases in mice. However, in vitro enzyme study showed that there were increases in the activities of the Na⁺/K⁺-ATPase and Ca²⁺-ATPase. Further investigation showed that the ATP content and mitochondrial respiratory control ratio (RCR) in the lungs decreased significantly. The oxidative stress product, malondialdehyde (MDA), increased while the antioxidants (GSH, SOD, and TAC) decreased significantly. These results indicate that mitochondrial respiration is the target of phosgene. The dysfunction of ATPases due to impaired mitochondrial respiration may be a new mechanism of phosgene-induced pulmonary edema.     

Studies on the Chemical Constituents of Pyrus Communis

An aqueous extract of the twigs of Pyrus communis L. var. sativa (DC) DC. showed inhibitory effect against S-180. Compounds were isolated from the twigs of P. communis and eight of them were identified as nonacosane (Ⅰ), lupeol (Ⅲ), β-sitosterol (Ⅳ), betulin (Ⅴ), betulinic acid (Ⅵ), daucosterol (Ⅶ), hydroquinone (Ⅷ) and arbutin (Ⅸ) by MS, NMR, IR, UV and some chemical techniques. It was showed that the compounds Ⅲ, Ⅳ, Ⅴ, Ⅵ, Ⅷ and Ⅸ possessed some bacteriostatic activities on Escherichia coli, Salmonella typhi, Shigclla flexneri and Staphylococus aureus. Primary pharmacology tests showed that Ⅷ had inhibitory effect against S-180 (47.5%).     

烟草甲clip丝氨酸蛋白酶基因的克隆及其对外源激素和免疫胁迫的表达响应(英文)

【目的】作为细胞外信号级联通路的重要组成部分,含有clip结构域的丝氨酸蛋白酶(clip-domain serine proteases, CLIPs)在昆虫发育和先天免疫过程中起着重要作用。本研究旨在克隆烟草甲Lasioderma serricorne CLIP基因,解析其在烟草甲不同发育阶段和幼虫不同组织中的表达模式,分析其在外源激素20-羟基蜕皮酮(20E)和免疫胁迫后的表达特征,为进一步研究其生理功能奠定基础。【方法】采用RT-PCR技术克隆获得烟草甲两个CLIPs基因(LsCLIP1和LsCLIP2)全长cDNA序列,并利用生物信息学软件预测其编码蛋白的结构和特征,利用MEGA 6.06构建昆虫CLIPs系统发育树;利用实时荧光定量PCR(quantitative real-time PCR, qPCR)研究这两个基因在不同发育阶段［低龄幼虫(卵孵化后24 h内)、高龄幼虫(4龄以上)、蛹(化蛹后48 h以上)、早期成虫(化蛹后24 h内)和晚期成虫(化蛹后7 d)］、5龄幼虫不同组织(表皮、脂肪体、肠道和剩余组织)中以及注射20E(120 ng/幼虫)和来源于大肠杆菌Escherichia coli和金黄色葡萄球菌Staphylococcus aureus的肽聚糖(0.2 μL)后4龄幼虫中的表达模式。【结果】克隆获得烟草甲LsCLIP1和LsCLIP2基因的cDNA全序列,其开放阅读框长度均为1 194 bp,编码397个氨基酸。序列分析显示,其氨基酸序列各自具有一个clip结构域和胰蛋白酶结构域。系统发育分析表明,CLIP1和CLIP2都属于subfamily C CLIPs。qPCR结果表明,LsCLIP1和LsCLIP2基因在所检测的各发育阶段和幼虫各组织中均有表达,分别尤以蛹期和表皮中表达量最高;经20E和肽聚糖诱导后,烟草甲幼虫体内LsCLIP1和LsCLIP2基因的表达量明显提高。【结论】推测LsCLIP1和LsCLIP2可能参与了烟草甲的蜕皮发育和对免疫胁迫的应激响应。本研究将为后续研究昆虫CLIPs的分子调控提供参考。     

A major triterpenoid saponin from Gypsophila oldhamiana

A new saponin, gypoldoside A (1), was isolated from the roots of Gypsophila oldhamiana. On the basis of in-depth NMR-spectroscopic and mass-spectrometric analysis, in combination with chemical evidence, its structure was established as 3-O-{beta-D-galactopyranosyl-(1-->2)-[beta-D-xylopyranosyl-(1-->3)]-beta-D-glucuronopyranosyl}quillaic acid 28-[alpha-L-arabinopyranosyl-(1-->2)-alpha-L-arabinopyranosyl-(1-->3)-beta-D-xylopyranosyl-(1-->4)-alpha-L-rhamnopyranosyl-(1-->2)-beta-D-fucopyranosyl] ester. Compound 1 was found to be highly active against three different human cancer cell lines, with IC50 values in the low micromolar range.     

人冠状病毒感染的血清学检测技术进展

人冠状病毒是一类能引起人急性呼吸道感染的病毒,通常引起普通感冒症状,严重者能造成呼吸窘迫综合征甚至死亡。针对人冠状病毒感染的实验室检测,尤其是免疫学检测技术近年来已有大量研究与应用报道。我们简要综述人冠状病毒感染血清学检测技术的最新进展。     

Ancestral niche separation and evolutionary rate differentiation between sister marine flavobacteria lineages

Marine flavobacteria are specialists for polysaccharide degradation. They dominate in habitats enriched with polysaccharides, but are also prevalent in pelagic environments where polysaccharides are less available. These niches are likely occupied by distinct lineages, but evolutionary processes underlying their niche differentiation remain elusive. Here, genomic analyses and physiological assays indicate that the sister flavobacteria lineages Leeuwenhoekiella and Nonlabens likely explore polysaccharide-rich macroalgae and polysaccharide-poor pelagic niches respectively. Phylogenomic analyses inferred that the niche separation likely occurred anciently and coincided with increased sequence evolutionary rate in Nonlabens compared with Leeuwenhoekiella. Further analyses ruled out the known mechanisms likely driving evolutionary rate acceleration, including reduced selection efficiency, decreased generation time and increased mutation rate. In particular, the mutation rates were determined using an unbiased experimental method, which measures the present-day populations and may not reflect ancestral populations. These data collectively lead to a new hypothesis that an ancestral and transient mutation rate increase resulted in evolutionary rate increase in Nonlabens. This hypothesis was supported by inferring that gains and losses of genes involved in SOS response, a mechanism known to drive transiently increased mutation rate, coincided with evolutionary rate acceleration. Our analyses highlight the evolutionary mechanisms underlying niche differentiation of flavobacteria lineages.