心肌电兴奋传导速度对心律失常影响的仿真研究

心电场是由心肌的电活动产生的。心肌细胞的电特性及心肌细胞间的传导关系决定了体表电位的分布及心电图的变化。心肌电兴奋传导速度则是影响心肌间兴奋传导关系的重要参数之一。由于很难通过实验方法来人为改变电兴奋传导速度,因而临床上有关该参数对心律影响的定量知识相当缺乏。本文采用真实三雏躯干模型及心脏模型,对心肌电兴奋传导速度与心律变化的关系进行定量仿真研究。结果表明,兴奋传导速度决定了整个心电图的变化,而局部普通心肌的传导速度在相当范围内变化似乎对心电图影响不明显,但传导速度超过一定范围后可能产生突变。     

军医大学学员坚毅性评价的内隐效应及脑电特征研究

目的:探寻军医大学学员内隐层面对自我和他人坚毅性评价的特点及脑电特征,为全面、客观的评估个体的坚毅性提供理论依据和客观指标。方法:使用E-Prime2.0参照经典内隐联想范式编制内隐联想-坚毅测验,对100名军医大学学员施测坚毅量表(Grit O),选取高、低坚毅水平被试(各20名)进行内隐联想-坚毅测验,并记录脑电,分析两组被试的内隐效应及主要脑电成分。结果:计算内隐效应D值,t检验显示高坚毅组(0.55±0.36)显著低于低坚毅组(0.87±0.49),t=-2.257,P0.05,Cohen'd=0.74。两组被试均诱发明显的N400和LPP,高坚毅组中N400在任务状态下主效应显著,F(1,17)=8.528,P0.05,η2=0.334,且在电极位置上主效应显著,F(10,170)=8.207,P0.001,η2=0.326。LPP在任务状态下主效应显著,F(1,17)=5.471,P0.05,η2=0.243,且在电极位置上主效应显著,F(10,170)=18.479,P0.001,η2=0.521;低坚毅组中N400在任务状态下主效应显著,F(1,17)=10.051,P0.05,η2=0.372,且在电极位置上主效应显著,F(10,170)=8.223,P0.001,η2=0.326,LPP在任务状态下主效应不显著。结论:1.军医大学学员坚毅性评价的内隐效应显著,即均倾向于认为自我的坚毅性高,他人的坚毅性低,通过问卷法评估坚毅性时应考虑坚毅评价的内隐效应。2.高、低坚毅性军医大学学员坚毅性内隐评价时的主要脑电成分N400、LPP存在差异,N400可作为坚毅性内隐评价符合程度的判断指标。3.内隐效应及N400可以作为对军医大学学员坚毅性评价时的客观指标。     

Synthesis and structure–activity relationship study of pyrazolo[3,4-d]pyrimidines as tyrosine kinase RET inhibitors

Three series of pyrazolo[3,4-d]pyrimidine derivatives were synthesized and evaluated as RET kinase inhibitors. Compounds 23a and 23c were identified to show significant activity both in the biochemical and the BaF3/CCDC6-RET cell assays. Compound 23c was found to significantly inhibit RET phosphorylation and down-stream signaling in BaF3/CCDC6-RET cells, confirming its potent cellular RET-targeting profile. Different from other RET inhibitors with equal potency against KDR that associated with severe toxicity, 23c did not show significant KDR-inhibition even at the concentration of 1 μM. These results demonstrated that 23c is a potent and selective RET inhibitor.     

OsCESA9 conserved‐site mutation leads to largely enhanced plant lodging resistance and biomass enzymatic saccharification by reducing cellulose DP and crystallinity in rice

Genetic modification of plant cell walls has been posed to reduce lignocellulose recalcitrance for enhancing biomass saccharification. Since cellulose synthase (CESA) gene was first identified, several dozen CESA mutants have been reported, but almost all mutants exhibit the defective phenotypes in plant growth and development. In this study, the rice (Oryza sativa) Osfc16 mutant with substitutions (W481C, P482S) at P‐CR conserved site in CESA9 shows a slightly affected plant growth and higher biomass yield by 25%–41% compared with wild type (Nipponbare, a japonica variety). Chemical and ultrastructural analyses indicate that Osfc16 has a significantly reduced cellulose crystallinity (CrI) and thinner secondary cell walls compared with wild type. CESA co‐IP detection, together with implementations of a proteasome inhibitor (MG132) and two distinct cellulose inhibitors (Calcofluor, CGA), shows that CESA9 mutation could affect integrity of CESA4/7/9 complexes, which may lead to rapid CESA proteasome degradation for low‐DP cellulose biosynthesis. These may reduce cellulose CrI, which improves plant lodging resistance, a major and integrated agronomic trait on plant growth and grain production, and enhances biomass enzymatic saccharification by up to 2.3‐fold and ethanol productivity by 34%–42%. This study has for the first time reported a direct modification for the low‐DP cellulose production that has broad applications in biomass industries.     

Revisiting the phylogeny of Wolbachia in Collembola

The endosymbiont Wolbachia has been detected in a few parthenogenetic collembolans sampled in Europe and America, including three species of Poduromorpha, two species of Entomobryomorpha, and two species of Neelipleona. Based on 16S rRNA and ftsZ gene sequences, most of the Wolbachia infecting parthenogenetic collembolans were characterized as members of supergroup E and showed concordant phylogeny with their hosts. However, the two neelipleonan symbionts form another unique group, indicating that Wolbachia has infected parthenogenetic collembolans multiple times. In this study, five parthenogenetic collembolan species were identified as hosts of Wolbachia, and four new Wolbachia strains were reported for four collembolan species sampled in China, respectively, including a neelipleonan strain from Megalothorax incertus (wMinc). Our results demonstrated that the Wolbachia multilocus sequence typing (MLST) system is superior to the 16S rRNA + ftsZ approach for phylogenetic analyses of collembolan Wolbachia. The MLST system assigned these Wolbachia of parthenogenetic collembolans to supergroup E as a unique clade, which included wMinc, supporting the monophyletic origin of Wolbachia in parthenogenetic collembolan species. Moreover, our data suggested supergroup E as one of the most divergent lineages in Wolbachia and revealed the discrepancy between the phylogenies of Wolbachia from parthenogenetic collembolans and their hosts, which may result from the high level of genetic divergence between collembolan Wolbachia, in association with the geographic differentiation of their hosts, or the possible horizontal transmission of Wolbachia between different collembolan species.     

重组人白细胞介素6的制备

我们采用本院基础医学研究所组建的ＩＬ-６工程菌Ｅ．ｃｏｉｌＤＨ５ａ（ｐＢＶ-ｈｌＬ－６）,在选定的培养基及ｐＨ值下,采用３０升发酵罐进一步观察了工程菌的生长和ｒＩＬ－６的表达,确定了发酵工艺条件。在此条件下连续进行了三批次的培养试验。结果表明,工程首的生长密度达到２．５１±０．０２ｇ［干重］／Ｌ［发酵液］,ｒＩＬ-６产率为１８２．４±２．０ｍｇ／ｇ［干重］。ｒＩＬ-６以包涵体形式表达于大肠杆菌细胞中,破菌后选用非离子型去垢剂或尿素等变性剂提取包涵体中的杂蛋白,可使ｒＩＬ-６的纯度达到７０．１±１．３％,收率为７１．９±１．９％。洗涤后的包涵体,经过凝胶柱纯化和复性,ｒＩＬ-６纯度达到９５％以上,柱纯化的收率为７２．３±０．９％;采用依赖ＩＬ-６,小鼠杂交瘤细胞系７ＴＤ１及ＭＴＴ比色法测定生物活性,ｒＩＬ-６比活性达２×１０８Ｕ／ｍｇ。     

类产碱假单胞菌杀虫蛋白的激光拉曼光谱研究

类产碱假单胞菌是一种新发现的昆虫病原微生物,其代谢产生的杀虫蛋白对蝗虫具有较强的毒杀作用,经由杀虫蛋白的水和重水溶液的拉曼光谱,按照Lippert的方法计算它的二级结构含量,β折叠含量为58%,无规卷曲为34%,侧链C—C—S—S—C—C构型为反式-扭曲-反式.它的酪氨酸残基大部分暴露在分子表面,小部分埋藏在疏水环境中.并讨论了杀虫蛋白结构有可能导致的杀虫机理.     

Simultaneous knockout of Slo3 and CatSper1 abolishes all alkalization- and voltage-activated current in mouse spermatozoa

During passage through the female reproductive tract, mammalian sperm undergo a maturation process termed capacitation that renders sperm competent to produce fertilization. Capacitation involves a sequence of changes in biochemical and electrical properties, the onset of a hyperactivated swimming behavior, and development of the ability to undergo successful fusion and penetration with an egg. In mouse sperm, the development of hyperactivated motility is dependent on cytosolic alkalization that then results in an increase in cytosolic Ca²⁺. The elevation of Ca²⁺ is thought to be primarily driven by the concerted interplay of two alkalization-activated currents, a K⁺ current (KSPER) composed of pore-forming subunits encoded by the Kcnu1 gene (also termed Slo3) and a Ca²⁺ current arising from a family of CATSPER subunits. After deletion of any of four CATSPER subunit genes (CATSPER1–4), the major remaining current in mouse sperm is alkalization-activated KSPER current. After genetic deletion of the Slo3 gene, KSPER current is abolished, but there remains a small voltage-activated K⁺ current hypothesized to reflect monovalent flux through CATSPER. Here, we address two questions. First, does the residual outward K⁺ current present in the Slo3 ^−/− sperm arise from CATSPER? Second, can any additional membrane K⁺ currents be detected in mouse sperm by patch-clamp methods other than CATSPER and KSPER? Here, using mice bred to lack both SLO3 and CATSPER1 subunits, we show conclusively that the voltage-activated outward current present in Slo3 ^−/− sperm is abolished when CATSPER is also deleted. Any leak currents that may play a role in setting the resting membrane potential in noncapacitated sperm are likely smaller than the pipette leak current and thus cannot be resolved within the limitation of the patch-clamp technique. Together, KSPER and CATSPER appear to be the sole ion channels present in mouse sperm that regulate membrane potential and Ca²⁺ influx in response to alkalization.