基于转录组测序的Cd胁迫下芹菜细胞自噬相关基因的筛选

细胞自噬是植物逆境应答过程中最常见的保护机制之一。动物中,自噬相关基因抵御镉(Cd)毒害的功能研究较清楚,但植物却知之甚少。文中以芹菜品种‘皇后’为试材,采用外源Cd(终浓度为0、2、4、8mg/L)添加营养液水培处理,利用转录组测序(RNA-seq)技术筛选细胞自噬相关差异基因并进行q RT-PCR验证。结果表明Cd胁迫对芹菜植株产生了明显的毒害作用,并与浓度间产生了量效关系。在筛选的8个差异表达的自噬相关基因中,ATG8a、ATG8f、ATG13、AMPK-1、AMPK-2基因随Cd浓度升高表达上调,ATG12、VPS30和VPS34则先上调后下降,说明自噬相关基因可能通过表达上调增加了自噬小体结构以抵御Cd毒性作用;而高浓度Cd(8mg/L)可能超出芹菜的耐受范围,导致多个自噬基因又出现表达下调趋势。以上结果有助于后期自噬相关基因的功能研究,为进一步探讨芹菜对Cd胁迫的耐性机制提供参考依据。     

双特异抗体的研究进展

双特异抗体是指可以同时结合两个不同抗原或一个抗原不同表位的特殊抗体,目前已有3个双特异抗体批准上市,还有很多个双特异抗体处于临床或临床前研究阶段。文中就双特异抗体的发现、制备方法、结构类型和设计策略、作用机制以及目前研究现状进行综述。     

果胶甲酯酶的结构与功能研究进展

果胶甲酯酶(PME)是一种重要的果胶酶,其水解果胶中的甲酯基从而释放甲醇并降低果胶的甲酯化程度。目前在食品加工、茶饮料、造纸等生产工艺中有着广泛的应用前景。随着对PME的深入研究,已报道了几种不同来源的酶晶体结构,对这些已获得的晶体结构进行分析发现,PME属于右手平行β-螺旋结构,其催化残基为2个保守的天冬氨酸和1个谷氨酰胺残基,并且在催化过程中分别起到了一般酸碱、亲核试剂以及稳定中间体的作用。同时对其底物特异性进行分析,初步了解其底物与活性位点的识别机制。文中针对这几个相关方面进行了系统的综述。     

象山港网箱养殖区沉积物的古菌空间分布

对象山港网箱养殖区及其周边沉积物中古菌群落的空间分布进行研究,应用基于16S rRNA基因的T-RFLP(末端限制性片段多态性分析)技术分析象山港网箱养殖区及其周边不同深度沉积物中古菌的群落结构和多样性,并构建克隆文库进行系统发育学分析。测定沉积物各项理化因子,通过PCA和RDA分析了古菌群落分布及其与环境因子之间的关系。结果表明,泉古菌是港口沉积物中的优势古菌群,占古菌群落的50%以上。网箱养殖区沉积物的古菌群落结构较非养殖区简单,多样性降低。非养殖区古菌群落随深度呈现有规律的变化。营养盐类和pH是造成养殖区域古菌群落结构区别于非养殖区域的主要环境因素。     

Cytoplasmic domain and enzymatic activity of ACE2 are not required for PI4KB dependent endocytosis entry of SARS-CoV-2 into host cells

The recent COVID-19 pandemic poses a global health emergency. Cellular entry of the causative agent SARS-CoV-2 is mediated by its spike protein interacting with cellular receptor-human angiotensin converting enzyme 2 (ACE2). Here, by using lentivirus based pseudotypes bearing spike protein, we demonstrated that entry of SARS-CoV-2 into host cells was dependent on clathrin-mediated endocytosis, and phosphoinositides played essential roles during this process. In addition, we showed that the intracellular domain and the catalytic activity of ACE2 were not required for efficient virus entry. Finally, we showed that the current predominant Delta variant, although with high infectivity and high syncytium formation, also entered cells through clathrin-mediated endocytosis. These results provide new insights into SARS-CoV-2 cellular entry and present proof of principle that targeting viral entry could be an effective way to treat different variant infections.     

红松阔叶混交林林隙光量子通量密度、气温和空气相对湿度的时空分布格局

以小兴安岭原始红松阔叶混交林林隙为研究对象,通过对林隙内光量子通量密度(PPFD)、气温和空气相对湿度进行连续观测,比较其间的时空分布格局.结果表明：晴天和阴天阔叶红松林林隙的PPFD日最大值均出现在11:00—13:00,晴天林隙内各个时段最大值出现位置不同,日最大值出现在林隙北侧林冠边缘处;而阴天各个时段最大值均处于林隙的中心.林隙内月平均PPFD 为6月最高、9月最低,极差7月最大.林隙内晴天气温的峰值出现在9:00—15:00,而阴天气温峰值在15：00—19：00,均位于林隙中心南8 m.5:00—9:00林隙各点阴天的气温都高于晴天,9:00—19:00则相反.月平均气温为6月最高、9月最低.晴天和阴天空气相对湿度的峰值均出现在5:00—9:00,日最大值在林隙西侧林冠边缘处,且阴天的相对湿度始终大于晴天.月平均相对湿度为7月最高、6月最低.晴天PPFD的异质性大于阴天,而气温和相对湿度的异质性则不明显.生长季内不同月份PPFD、气温和空气相对湿度的最大值所处位置不同.PPFD和气温的月均值在林隙中心及附近变化梯度较大,而相对湿度的月均值则在林隙边缘变化梯度较大.     

陕西食源性沙门氏菌耐药及相关基因

【目的】研究食源性沙门氏菌对常用抗生素的药敏性及相关耐药基因,更好的了解耐药性的产生和传播途径,确保食品安全。【方法】使用the Clinical and Laboratory Standards Institute推荐的琼脂稀释法测定沙门氏菌的药敏性,PCR和基因序列测定方法确定耐药沙门氏菌中整合子及其携带的耐药基因、与头孢菌素抗性相关的基因、沙门氏菌基因岛及与氟喹诺酮类抗生素耐药相关的基因突变。【结果】359株沙门氏菌中,67%的菌株对磺胺甲恶唑产生抗性,对甲氧苄啶/磺胺甲恶唑、四环素、卡那霉素、萘啶酮酸、氨苄西林、阿莫西林/克拉维酸、链霉素、氯霉素和庆大霉素、环丙沙星、头孢曲松、头孢西丁和头孢哌酮的耐药率分别为58%、56%、37%、35%、33%、32%、29%、26%、21%、16%、9%和8%。284株耐药菌中,79%的菌株可抗至少1种抗生素,25.9%可抗10种以上抗生素,2.5%可抗14种抗生素。耐药的Ⅰ类整合子以1.4kb最为常见,携带的耐药基因有aadA1、aadA2、aadA5、tetR、blaPSE-1、blaDHA-1、blaVEB-1、dhfrⅠ、dhfrⅤ、dhfrⅦ和dhfr17等。62株耐头孢曲松和/或头孢哌酮的沙门氏菌中,blaTEM和blaCMY-2基因的检出率分别为51.6%和56.5%。13.6%的沙门氏菌中检出了沙门氏菌基因岛。35株耐氟喹诺酮类抗生素的沙门氏菌的gyrA、parC和parE基因中共检出68个点突变,gyrA基因中常见突变为Ser83Phe、Ser83Tyr、Asp87Gly和Asp87Asn,parC基因中为Ser80Arg。parE基因中检出了Lys441Ile、Lys428Gln、Asp494Asn、Lys428Gln和Gly442Ser突变,这些点突变均为首次在食源性沙门氏菌中检出。【结论】陕西食源性沙门氏菌耐药状况严重,整合子、沙门氏菌基因岛和β-内酰胺酶编码基因的存在及解旋酶和拓扑异构酶基因突变是导致沙门氏菌耐药的重要机制。     

透明颤菌血红蛋白基因表达对金色链霉菌生长代谢的影响

利用四环素抗性基因启动子在金色链霉菌中表达透明颤菌血红蛋白基因。在1m3发酵罐中研究了工程菌株的生长代谢特性。在溶解氧充足的条件下,透明颤菌血红蛋白表达,对金色链霉菌生长代谢未产生明显影响,工程菌株与参比菌株的生长代谢特性基本一致,工程菌株和参比菌株金霉素最终浓度分别为22905u/mL、22896u/mL。在低溶解氧条件下,透明颤菌血红蛋白的表达,可促进金色链霉菌菌体生长、菌丝活力保持和金霉素的合成：工程菌菌体浓度比参比菌株高5％～10％,产物合成提高11.4％。     

Noggin and bFGF cooperate to maintain the pluripotency of human embryonic stem cells in the absence of feeder layers

Human embryonic stem (hES) cells are typically maintained on mouse embryonic fibroblast (MEF) feeders or with MEF-conditioned medium. However, these xenosupport systems greatly limit the therapeutic applications of hES cells because of the risk of cross-transfer of animal pathogens. Here we showed that the bone morphogenetic protein antagonist noggin is critical in preventing differentiation of hES cells in culture. Furthermore, we found that the combination of noggin and basic fibroblast growth factor (bFGF) was sufficient to maintain the prolonged growth of hES cells while retaining all hES cell features. Since both noggin and bFGF are expressed in MEF, our findings suggest that they may be important factors secreted by MEF for maintaining undifferentiated pluripotent hES cells. Our data provide new insight into the mechanism how hES cell self-renewal is regulated. The newly developed feeder-free culture system will provide a more reliable alternative for future therapeutic applications of hES cells.     

A dynamic, architectural plant model simulating resource-dependent growth

BACKGROUND AND AIMS: Physiological and architectural plant models have originally been developed for different purposes and therefore have little in common, thus making combined applications difficult. There is, however, an increasing demand for crop models that simulate the genetic and resource-dependent variability of plant geometry and architecture, because man is increasingly able to transform plant production systems through combined genetic and environmental engineering. MODEL: GREENLAB is presented, a mathematical plant model that simulates interactions between plant structure and function. Dual-scale automaton is used to simulate plant organogenesis from germination to maturity on the basis of organogenetic growth cycles that have constant thermal time. Plant fresh biomass production is computed from transpiration, assuming transpiration efficiency to be constant and atmospheric demand to be the driving force, under non-limiting water supply. The fresh biomass is then distributed among expanding organs according to their relative demand. Demand for organ growth is estimated from allometric relationships (e.g. leaf surface to weight ratios) and kinetics of potential growth rate for each organ type. These are obtained through parameter optimization against empirical, morphological data sets by running the model in inverted mode. Potential growth rates are then used as estimates of relative sink strength in the model. These and other 'hidden' plant parameters are calibrated using the non-linear, least-square method. KEY RESULTS AND CONCLUSIONS: The model reproduced accurately the dynamics of plant growth, architecture and geometry of various annual and woody plants, enabling 3D visualization. It was also able to simulate the variability of leaf size on the plant and compensatory growth following pruning, as a result of internal competition for resources. The potential of the model's underlying concepts to predict the plant's phenotypic plasticity is discussed.