基因工程抗体研究进展

随着对分子生物学研究和抗体分子结构功能的深入研究,利用细胞工程和遗传工程对抗体分子进行改建并赋予其新的功能,进而开发了新的抗体应用领域,使单克隆抗体技术又向前发展了一步.基因工程抗体是按人类设计所重新组装的新型抗体分子,可保留或增加天然抗体的特异性和主要生物学活性,去除或减少无关结构,从而可克服单克隆抗体在临床应用方面的缺陷.     

Germ cell-specific Atg7 knockout results in primary ovarian insufficiency in female mice

Primary ovarian insufficiency (POI) is a common cause of infertility in around 1–2% of women aged <40 years. However, the mechanisms that cause POI are still poorly understood. Here we showed that germ cell-specific knockout of an essential autophagy induction gene Atg7 led to subfertility in female mice. The subfertility of Atg7 deletion females was caused by severe ovarian follicle loss, which is very similar to human POI patients. Further investigation revealed that germ cell-specific Atg7 knockout resulted in germ cell over-loss at the neonatal transition period. In addition, our in vitro studies also demonstrated that autophagy could protect oocytes from over-loss by apoptosis in neonatal ovaries under the starvation condition. Taken together, our results uncover a new role for autophagy in the regulation of ovarian primordial follicle reservation and hint that autophagy-related genes might be potential pathogenic genes to POI of women.Primary ovarian insufficiency (POI), also known as premature ovarian failure (POF), is an ovarian defect characterized by the premature depletion of ovarian follicles before the age of 40 years. POI is a common cause of infertility in women, affecting 1–2% of individuals aged <40 years and 0.1% of individuals aged <30 years.¹ Potential etiologies for POI are highly heterogeneous, which include iatrogenic, infectious, autoimmune, metabolic, chromosomal and genetic factors.² At present, about 25% of all forms of POF can be classified as iatrogenic and are related to cancer treatment, but >50% of the cases remain idiopathic. Though the pathogenic mechanism remains unexplained in the majority of the cases, several observations support a prevalent role of genetic mechanisms in the pathogenesis of idiopathic POI. It has been reported that mutations in FMR1, BMP-15, GDF-9, FOCL2, FSHR, LHR, INHA, GALT and AIRE are associated with POI.^{3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13} The genetic information of POI is very useful for family counseling, because it can predict the female relatives who may be at higher risk for POI and fertility loss in young age. The female carriers will be able to plan their conception before ovarian failure occurs. This requirement is becoming more and more important, because women nowadays tend to conceive ever more frequently in their thirties and forties,¹⁰ when the risk of POI in the general population is about 1–2%. However, still few genes could be identified that can explain a substantial proportion of the cases of POI.An important phenotype of POI is infertility, thus POI patients do not have large family histories, and therefore are difficult to study using traditional genetic methods, such as linkage analysis. Animal models of POI have been successfully used to identify candidate genes in this disease. The disruption of meiosis-specific genes, Bcl-2 family apoptotic-related genes, Pten-PI3K-Akt-Foxo3 pathway and Tsc1/2-mTOR signaling pathway result in POI-like phenotype in mice.^{14, 15, 16, 17} However, as a complex disorder, the genetic etiologies of POI still need to be further investigated to better understand the underlying molecular mechanisms.Macroautophagy (hereafter referred to as autophagy) is the primary intracellular catabolic mechanism for degrading and recycling long-lived proteins and organelles, which is evolutionarily conserved from yeast to mammals.¹⁸ During autophagy, isolation membrane enwraps parts of the cytoplasm and intracellular organelles, and fuse with each other forming a double membrane structure, known as the autophagosome. Then the outer membrane of the autophagosome fuses with the lysosome to form autolysosome, in which the cytoplasm-derived materials are degraded by resident hydrolases.¹⁹ The primary function of autophagy is to allow cells or organisms to survive nutrient starvation conditions by recycling either proteins or other cellular components. This process is important for cells to adapt their metabolism to starvation caused by decreased extracellular nutrients or by decreased intracellular metabolite concentrations. In addition to nutrient supply and adaptation to stress conditions, a number of observations have revealed that autophagy also functions in many physiological processes in mammalian systems, such as cell death, antiaging mechanisms, innate immunity, development and tumor suppression.^{20, 21, 22, 23, 24, 25}From the discovery of the molecular mechanism underlying autophagy, it was found that autophagy is required for the reproductive process in budding yeast.²⁶ In mammals, fertilization induces massive autophagy to degrade maternal proteins and messenger RNAs, and autophagy functions as a major nutrient-providing system for embryos before their implantation.²⁷ Our recent work indicates that autophagy is required for acrosome biogenesis during spermatogenesis in mice, thus essential to male fertility.²⁴ However, whether autophagy is involved in female gametogenesis or not is still unknown. Here, we showed that germ cell-specific knockout of an essential autophagy induction gene Atg7 led to POI in female mice, and the numbers of the oocytes and follicles were significantly declined in the adult mutant mice. Further investigation revealed that autophagy protected oocytes over-loss during the neonatal transition period. Our results suggest that autophagy-related genes might be pathogenic genes to POI.     

应用基因表达谱芯片研究黄药子对小鼠肝脏的毒性机制(简报)

黄药子为薯蓣科植物黄独(Dioscorea bulbifera L．)的块茎,临床常用于治疗甲状腺肿、抗肿瘤、抗炎、抗病毒等。近年来临床上关于黄药子的毒副作用,尤其是对肝、肾的不良反应屡有报道。当黄药子或其代谢物在肝细胞内累积时会直接干扰肝细     

新生儿Fc受体研究进展

新生儿Fc受体(FcRn)是由α链和β链两个亚基以非共价键的形式组成的异源二聚体,在免疫球蛋白IgG转运和代谢中发挥着重要作用.对FcRn的分子结构、转运机制及其功能进行了综述.     

黄鳝生殖干细胞在性逆转生殖发育过程中的变化

应用组织学方法及免疫组织化学技术显示,黄鳝性逆转生殖发育过程中,生殖干细胞(GSCs)定位分布于生殖褶中,黄鳝雌性发育阶段的GSCs分散或成团存在,间性及雄性发育阶段GSCs均区分为A、B两种不同类型,雌性发育阶段GSCs与A、B两类GSCs在超微结构上存在差异。结果表明,生殖褶中GSCs是黄鳝分化生殖腺中唯一具有有丝分裂能力的生殖细胞群,雌性发育阶段GSCs表现出卵原干细胞特征,间性及雄性发育阶段GSCs为精原干细胞。CD49整合素是黄鳝雌性发育阶段GSCs和A类GSCs的表征分子。     

鲑鱼生长激素cDNA的分子克隆和序列分析

从太平洋切奴克鲑鱼(Pacific Chinook Salmon,Oncorthychus tschawytscha)垂体poly(A)~+ RNA构建cDNA文库。按照鲑鱼生长激素(sGH)部分氨基酸序列合成两个寡聚脱氧核苷酸探针,它们分别与编码第1—7和第166—172氨基酸序列互补。用探针筛查cDNA文库,得到了完整的sGH cDNA克隆。cDNA序列已测定,包括编码210个氨基酸的编码序列。其中含有22个氨基酸的信号肽序列和188个氨基酸的成熟GH序列。该克隆还包括了5'端和3'端非翻译区,分别为72个和438个碱基对长。与Chum鲑鱼比较表明,核酸序列和氨基酸序列的同源性分别为97%和99%。     

维生素对体外培养人脐带间充质干细胞生长的影响

该实验以人脐带间充质干细胞（human umbilical cord mesenchymal stem cells,hUCM—SCs）为研究对象,探讨维生素A对其体外培养的影响。结果显示,添加维生素A培养后,hUCMSCs仍维持其本身生物学特性,表达其标记基因CD29、CD44和干细胞标记基因Oct4、Sox2、Nanog。维生素A促进hUCMSCs的体外增殖,上调增殖基因PCNA、C-myc和干细胞标记基因Nanog的表达,下调凋亡基因Bch的表达。该研究证明了维生素A具有促进hUCMSCs增殖和维持其干细胞特性的作用,对继续探索hUCMSCs的体外快速增殖和维生素A对hUCMSCs增殖调控的机理具有重要意义。