食气梭菌的研究进展

食气梭菌是一类主要的化能自养微生物,可利用二氧化碳(CO_2)和一氧化碳(CO)合成多种化学品和燃料,具有良好的工业应用前景。天然的食气梭菌吸收、固定和转化一碳气体速率较慢,能量代谢效率低且高值产物种类少。近年来,随着组学、分子遗传学工具以及生化分析技术的快速发展,食气梭菌的生理代谢特点及其相关分子机制、代谢工程设计、改造和发酵工艺等方面都得到广泛而深入的研究。本文针对近年来食气梭菌的研究进展进行了梳理和总结,以期能为这类重要工业微生物的基础和应用研究,以及一碳气体的生物转化利用提供参考。     

单分子实时测序及其在微生物表观遗传学中的应用

表观遗传学对于微生物的生命进程起着重要作用。由限制-修饰系统调控的DNA修饰参与微生物的免疫防御系统,无限制-修饰系统调控的DNA修饰通过调控基因表达影响表型。然而,表观遗传信息还没有被常规地作为DNA信息收集分析。基于对DNA合成反应的动力学分析,单分子实时测序技术可以在获得基本序列数据的同时实现对被修饰核苷酸的检测。这个技术为微生物中已知DNA修饰的研究提供了新的平台,也为新型DNA修饰的发现做好准备。本文综述了单分子实时测序技术及其在微生物表观遗传学中的应用。     

动物线粒体核质基因互作的研究进展

线粒体是重要的细胞器,为细胞的生命活动提供能量,线粒体的正常功能是核基因和线粒体基因共同作用维持的结果。线粒体DNA是动物细胞内唯一存在的核外遗传物质,线粒体DNA与核基因的相互作用维持着线粒体和线粒体内膜呼吸链氧化磷酸化的正常功能状态。本文就线粒体核质基因互作在人类疾病、衰老、细胞凋亡、氯霉素抗性、ANT、MnSOD、mtTFA的研究进展进行了综述。 Abstract：Mitochondria is the essential element for a cell,in which generates energy.The normal functions of a mitochondria are controlled by both mitochondrial genome and nuclear genome.Mitochondrial DNA is the only genome in the cytoplasmy of a cell,it encodes essential components of oxidative phosphorylation(OXPHOS)in mitochondrial inner membrane,generating cellular energy in the main form of adenosine triphosphate(ATP).In this paper,we reviewed the research development on interactions of nuclear and mitochondrial genes,including human disease and aging,apoptosis,chloromycetin resistance,ANT,MnSOD and mtTFA.     

Metabolic engineering of plant secondary metabolite pathways for the production of fine chemicals

The technology of large-scale plant cell culture is feasible for the industrial production of plant-derived fine chemicals. Due to low or no productivity of the desired compounds the economy is only in a few cases favorable. Various approaches are studied to increase yields, these encompass screening and selection of high producing cell lines, media optimization, elicitation, culturing of differentiated cells (organ cultures), immobilization. In recent years metabolic engineering has opened a new promising perspectives for improved production in a plant or plant cell culture.     

Oxidative stress triggered by aluminum in plant roots

Aluminum (Al) is a major growth-limiting factor for plants in acid soils. The primary site of Al accumulation and toxicity is the root meristem, and the inhibition of root elongation is the most sensitive response to Al. Al cannot catalyze redox reactions but triggers lipid peroxidation and reactive oxygen species (ROS) production in roots. Furthermore, Al causes respiration inhibition and ATP depletion. Comparative studies of Al toxicity in roots with that in cultured plant cells suggest that Al causes dysfunction and ROS production in mitochondria, and that ROS production, but not lipid peroxidation, seems to be a determining factor of root-elongation inhibition by Al.     

成熟促进因子对克隆重构胚核重编程的调控

成熟促进因子(maturation promoting factor,MPF)由催化亚单位P34cdc2和调节亚单位cyclin组成,对细胞周期的调控起着重要作用。目前,在核移植研究中发现：供体核在MPF的作用下发生核膜破裂(nuclear envelop breakdown．NEBD)和早熟染色体凝集(premature chromosome condensation,PCC),促进了核、质蛋白质因子的交换,有利于核重编程的进行。PCC还会对供体核的倍性及形态产生影响。     

白蜡虫碱性磷酸酶功能基团的研究

白蜡ricerus pela雌成虫经匀浆,正丁醇抽提,硫酸铵分段盐析,SephadexG-150凝胶过滤等步骤,得到比活力为136.65U/mg蛋白酶制品,用苯甲基磺酰氟、N-溴代琥珀酰亚胺、三硝基苯磺酸、二巯基苏糖醇、对氯汞苯甲酸、琥珀酸酐、溴乙酸、碘乙酸等化学修饰剂在一定条件下选择修饰白蜡虫碱性磷酸酶的几种氨基酸残基,并测定酶活力变化。结果表明：苯甲基磺酰氟、N-溴代琥珀酰亚胺、三硝基苯磺酸、琥珀酸酐、二巯基苏糖醇的修饰能显著抑制酶的活力,活力的降低与修饰剂的浓度有关,氯汞苯甲酸、溴乙酸、碘乙酸的修饰对酶的抑制作用影响较小。初步认为：丝氨酸、赖氨酸和色氨酸残基是白蜡虫碱性磷酸酶的必需功能基团,部分二硫键也是酶的催化功能所必需的。