GROWTH AND ORGANIC OSMOLYTES OF GEOGRAPHICALLY DIFFERENT ISOLATES OF MICROCOLEUS CHTHONOPLASTES (CYANOBACTERIA) FROM BENTHIC MICROBIAL MATS:RESPONSE TO SALINITY CHANGE1

The comparative growth and osmotic acclimation often culture strains of the marine benthic cyanobacterium Microcoleus chthonoplastes Thuret isolated from microbial mats in Germany, Spain, Egypt, the United States, Mexico, Chile, and Australia were investigated in salinities ranging from freshwater to twice seawater. All isolates showed a broad growth versus salinity response consistent with the dominance of this species in intertidal and hypersaline microbial communities. Growth optima, salinity preferences, and maximum growth rates differed for each isolate and could be related to the habitat from which they were isolated. This is most obvious when comparing strains from brackish habitats with those from a hypersaline lake. While the former isolates exhibited sharply pronounced growth optima under hyposaline conditions, cultures from the hypersaline environment grew best in salinity more than double seawater. The major low-molecular weight organic compounds present in all M. chthonoplastes strains were the carbohydrates glycosylglycerol and trehalose. This was proven by using ¹³C-nuclear magnetic resonance spectroscopy. Glycosylglycerol was synthesized and accumulated with increasing salinities, indicating its role as an osmolyte. In contrast, trehalose was present in relatively high concentrations under hyposaline conditions only. Differences in the patterns of growth versus salinity, as well as in those of osmotic acclimation among the M. chthonoplastes isolates, point to the development of different physiological ecotypes within the species.     

Errata

Human erythrocytes were exposed to oxidative stress by iodate and periodate. Oxidation causes a time- and concentration-dependent increase in membrane permeability for hydrophilic molecules and ions. The induced leak discriminates nonelectrolytes on the basis of molecular size and exhibits a very low activation energy (E_a = 1–4 kcal · mol^?1). These results are reconcilable with the formation of aqeous pores. The pore size was approximated to be between 0.45 and 0.6 nm. This increase in permeability is reversible upon treatment with dithioerythritol. Blocking of membrane thiol groups with N-ethylmaleimide protects the membranes against leak formation. The oxidation causes dithioerythritol-reversible modification of membrane proteins as indicated by the gel electrophoretic behavior. These modifications can also be suppressed by blocking the membrane thiol groups with N-ethylmaleimide. About half of the membrane methionine is oxidized to acid hydrolysis-stable derivatives. A fast saturating increase in diene conjugation was observed in whole cells but not in isolated membranes, with only minor degradation of fatty acid chains. The oxidation of cell membrane lipids as well as oxidation of cell surface carbohydrates are not involved in leak formation. Taken together with earlier data (Deuticke, B., Poster, B., Lütkemeier, P., and Haest, C.W.M. (1983) Biochim. Biophys. Acta 731, 196–210), these findings indicate that formation of disulfide bonds by different oxidative mechanisms results in leaks with similar properties.     

Temperature thresholds for germination in 20 short‐range endemic plant species from a Greenstone Belt in southern Western Australia

• The study of climate‐driven effects on seed traits such as germination has gained momentum over the past decade as the impact of global warming becomes more apparent on the health and survival of plant diversity.
• Seed response to warming was evaluated in a suite of short‐range endemic species from the biodiverse Greenstone Belt of southern Western Australia. The temperature dimensions for germination in 20 woody perennials were identified using small unreplicated samples over 6 weeks on a temperature gradient plate (constant and fluctuating temperatures between 5 and 40 °C). These data were subsequently modelled against current and forecast (2070) mean monthly minimum and maximum temperatures to illustrate seasonal changes to germination timing and final percentage germination.
• All but one species attained full germination in at least one cell on the gradient plate. Modelling of the data suggested only minimal changes to percentage germination despite a forecast rise in diurnal temperatures over the next 50 years. Nine species were predicted to experience declines of between <1% and 7%, whilst 11 species were predicted to increase their germination by <1% to 3%. Overall, the speed of germination is predicted to increase but the timing of germination for most species shifts seasonally (both advances and delays) as a result of changing diurnal temperatures.
• The capacity of this suite of species to cope with warmer temperatures during a critical early life stage shows a degree of adaptation to heterogeneous environments. Predicting the effects of global change on terrestrial plant communities is crucial to managing and conserving plant diversity.

     

Temperature and Sweet Taste Integration in Drosophila

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BONZAI Proteins Control Global Osmotic Stress Responses in Plants

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锰作用下PC12细胞的氧化应激机制研究

目的：以鼠嗜铬神经瘤细胞（PC12）为模型,筛选锰对神经细胞增殖抑制作用的时间及剂量,观察锰作用下PC12细胞的氧化应激反应与细胞形态学、生化指标改变和丝裂原活化蛋白激酶pp38（p38MAPKs）的活化表达。方法：用200,400,600,800μmol/LMnCl2的培养液,分别作用对数生长期PC12细胞1,2,3,4d后,用MTT筛选锰的细胞毒性剂量;测定200-600μmol/L MnCl2作用4d后,PC12细胞还原型谷胱甘肽和丙二醛含量;透射电镜观察细胞形态学变化;琼脂糖凝胶电泳检测MnCl2对PC12细胞基因组DNA的影响。western-blot法检测p-p38。结果：MTT实验显示200~800μmol/LMnCl2作用1,2,3,4d对PC12有显著的抑制作用,呈剂量和时间依赖趋势,600μmol/LMnCl2作用4d对PC12的抑制率可达50%以上。200-600μmol/LMnCl2作用于细胞4d后,随着浓度的升高,还原型GSH逐渐降低,MDA的含量逐渐升高;600μmol/LMnCl2作用4d电镜可见细胞凋亡,同样条件下细胞DNA碎片化。Western-blot实验显示600μmol/LMnCl2作用1,2,3,4dp-p38逐渐升高,3d时较对照组增加6.6倍（n=3,p〈0.05）,200,400,600μmol/L MnCl2作用4d时,磷酸化蛋白38（p-p38）也逐渐升高,400μmol/L MnCl2作用4d时较对照组升高了4.7倍（n=3,p〈0.05）。结论：PC12细胞在锰作用下发生氧化应激反应,上调p-p38,诱导细胞凋亡,细胞增殖抑制。     

升温诱发高血压大鼠脑梗塞发病的神经内分泌机制

目的：研究气温骤升导致高血压大鼠发生脑梗塞的神经内分泌机制。方法：采用易卒中型肾血管性高血压（RHRSP）模型,放置于人工模拟气温骤升的高温环境中诱发脑梗塞,检测高温刺激前后大鼠ACTH、CORT、TSH、T3、T4的变化。结果：突然升温使生理组大鼠ACTH和CORT水平表现升高的趋势。模型组高血压大鼠CORT、TSH、T3、T4水平在升温中均呈现升高趋势,但是ACTH水平却明显降低（P〈0.05）。升温后发生脑梗塞大鼠的ACTH和T4水平与升温前比明显下降（P〈0.01）,而TSH水平明显高于升温前水平（P〈0.05）,T3水平不变。结论：高血压机体应激反应系统紊乱,甲状腺刺激素和肾上腺皮质激素的异常波动,是突然高温促发高血压机体脑梗塞发病的重要神经内分泌机制。     

Structure, function and membrane interactions of plant annexins: An update

Knowledge accumulated over the past 15 years on plant annexins clearly indicates that this disparate group of proteins builds on the common annexin function of membrane association, but possesses divergent molecular mechanisms. Functionally, the current literature agrees on a key role of plant annexins in stress response processes such as wound healing and drought tolerance. This is contrasted by only few established details of the molecular level mechanisms that are driving these activities.In this review, we appraise the current knowledge of plant annexin molecular, functional and structural properties with a special emphasis on topics of less coverage in recent past overviews. In particular, plant annexin post-translational modification, roles in polar growth and membrane stabilisation processes are discussed.