Notch的结构、功能和相关信号通路

Notch是广泛存在于细胞表面介导细胞间信号传递的一类高度保守的受体蛋白。Notch信号通路是通过细胞间相互作用来调节生物体生长发育的一个十分保守的信号通路。Notch信号通路在脊椎动物和无脊椎动物的发育过程中,对细胞命运的决定、神经系统的发育、器官的形成及体节的发生都有重要的作用。特别是在免疫系统和肿瘤发生中也起着极为重要的作用。目前,Notch信号已经成为发育生物学、细胞生物学、免疫学及血液学等多个领域的研究热点之一。本文就Notch信号通路的组成、调节作用机制及该通路与个体发育之间的联系作一综述。     

Notch信号通路与血液系统和白血病形成

Notch基因编码着一类进化上高度保守的跨膜受体蛋白家族,其信号通路是由Notch受体、Notch配体、CSL DNA结合蛋白组成。该信号通路能够调节淋巴细胞的发育和分化过程,介导心血管系统的形成,参与肿瘤的发生和发展。近年来有研究表明,Notch信号通路在造血作用及白血病的发生过程中起关键作用。本文综述了Notch信号通路在淋巴细胞及造血干细胞的发育和分化中的作用,进一步探讨了其对造血作用和白血病发生发展的调节,以期能够对临床造血疾病的治疗提供帮助。     

表皮生长因子样重复序列糖基化对Notch信号通路的作用

Notch受体是一类存在于多细胞生物中进化上高度保守的跨膜蛋白受体,其介导的信号通路在组织器官的生长发育中起重要作用。糖基化修饰是一类重要的影响多信号通路的蛋白翻译后修饰。Notch受体胞外域的表皮生长因子样重复序列（EGF-R）存在多种糖基化修饰如O-葡聚糖、O-岩藻糖聚糖、O- N-乙酰氨基葡萄糖,这些糖基化修饰可以促进或抑制Notch信号通路。本文主要阐述表皮生长因子样重复序列（EGF-R）的主要糖基化以及对Notch信号通路的影响和其异常导致相关的疾病。     

Notch信号转导与调控

Notch是一个进化上十分保守的跨膜受体蛋白家族,它可以通过与表达配体的相邻细胞间的相互作用转导信号,从而决定动物系统发育过程中多种细胞的“命运”.Notch信号转导过程包括Notch受体与配体的结合、Notch受体的酶切活化、可溶性NICD转移至细胞核并与CSL DNA结合蛋白相互作用,从而调控靶基因的表达.Notch活性水平、时间和空间分布受到包括配体、蛋白质转运、泛素化降解等多水平内源性和外源性诱导因素的调节.系统介绍了Notch信号转导通路的分子组成、Notch信号激活的生化机制、Notch信号的多水平调节以及与部分相关疾病的关系.     

Notch信号:一个新型代谢调节因子

Notch信号通路进化上非常保守,广泛表达于脊椎动物和无脊椎动物中。Notch信号通路由受体、配体、CSL-DNA结合蛋白等组成,在细胞的增殖、分化和凋亡中发挥重要的调控作用。近年来发现,Notch信号作为一个新型的代谢调节因子,在骨骼肌细胞和脂肪细胞稳态、脂肪肝、糖尿病及糖尿病肾病中发挥重要的调节作用。本文就Notch信号在细胞的稳态及一些代谢性疾病中的调节作用及其分子机制作一综述。     

Notch 信号通路与Neuralized蛋白

Notch信号通路在脊椎动物和无脊椎动物许多组织的发育过程和细胞间通讯中都发挥了关键的作用,包括调控细胞命运,调节细胞迁移,分化和增殖.Notch信号通路由Notch受体及其跨膜配体如Delta（Dl）和Serrate组成.Neuralized 蛋白（Neur）编码1个E3泛素连接酶,是Notch配体D1内吞所必需的.Neur蛋白包括3个从线虫到人高度保守的结构域：2个Neur同源重复结构域（NHR1和NHR2）和1个C端RING结构域.本文就Notch信号通路主要元件和Neru的结构与功能及其关系进行综述.     

Notch 信号通路与淋巴细胞发育

Notch 信号通路为一广泛应用且高度保守的信号转导途径,决定多能祖细胞的分化方向,其中在共同淋巴祖细胞向 T 淋巴细胞或 B 淋巴细胞分化选择中具有决定性作用 . Notch 信号通路参与淋巴细胞的发育过程,促进 Tαβ细胞的形成、诱导处女型 T 细胞变为调节型 T 细胞、阻止 CD4+T 细胞向 Th1 类型分化,以及增加外周免疫器官边缘区 B 细胞的数量 . 在分析 Notch 蛋白结构的基础上,综合最新进展,系统阐明了 Notch 信号通路的组成、作用机制、参与的淋巴细胞发育过程以及所起的作用 .     

昆虫Notch信号通路研究进展

Notch信号通路由Notch受体、Notch配体(DSL蛋白)、CSL［C promoter binding factor-1 (CBF1), Suppressor of hairless (Su(H)), Lag-1］转录因子、其他效应子和Notch调节分子构成,在动物组织的发育和器官的细胞命运决定中起着基础性的作用。从1917年在果蝇Drosophilia中被发现以来,基于昆虫Notch信号通路的研究一直十分活跃,证实了其在昆虫中主要行使胚胎及器官的发育调控、细胞增殖及细胞周期调控等作用。Notch基因位点的突变能够导致果蝇在胚胎期死亡,且翅发生缺失;Notch胞内域(intracellular domain of Notch, NICD)的表达会影响果蝇、蟑螂等昆虫卵巢卵泡细胞的发育;Delta可以介导昆虫体节形成以及神经系统正常发育;Su(H)以转录因子的形式发挥功能,主要影响昆虫细胞的细胞周期进程;Fringe在果蝇、家蚕Bombyx mori等昆虫的翅发育过程中起关键作用。此外Notch信号通路与Hippo信号通路、Wnt信号通路和EGFR信号通路等存在相互作用,表明其不作为一个单线形式而是复杂的网络结构参与昆虫的生命进程。近年来对Notch信号通路的研究已经从昆虫扩展到人类重大疾病、肿瘤医学和分子治疗中。鉴于Notch信号通路的高度保守性,昆虫Notch信号通路的研究成果不仅对昆虫发育机制的解析起着关键作用,还可为其他动物的研究乃至人类疾病的研究提供重要的参考和新思路。     

Notch信号途径及其调控

Notch是一个进化上十分保守的跨膜受体蛋白家族,对无脊椎动物和脊椎动物发育过程中的细胞命运决定起重要作用。一条重要的Notch信号途径涉及Notch的“三步蛋白质水解”活化。许多相关分子和体内生化过程参与Notch信号途径调控。调控发生在不同水平,包括Notch-配体互作、受体和配体的运输、泛素化降解等。现就Notch受体、Notch信号途径及其所受的不同水平的调控进行综述。     

Notch信号通路的研究现状

Notch信号通路是一条进化上十分保守的信号转导系统。Notch受体通过与配体的相互作用转导细胞信号,从而在细胞增殖、分化、凋亡中发挥重要的调控作用。Notch信号通路平衡细胞增殖、分化、凋亡的重要性提示其可能与肿瘤细胞的异常调控相关。近来研究发现,在许多肿瘤细胞系中存在notch基因的异常活化,且失控的Notch信号与肿瘤细胞的生长调控相关。文章综述了就新近有关Notch信号通路的生理功能及其对肿瘤细胞的调控作用。     

Notch signaling in the mammalian respiratory system,specifically the trachea and lungs,in development,homeostasis, regeneration,and disease

The respiratory system has ideal tissue structure and cell types for efficient gas exchange to intake oxygen and release carbon dioxide. This complex system develops through orchestrated intercellular signaling among various cell types, such as club, ciliated, basal, neuroendocrine, AT1, AT2, endothelial, and smooth muscle cells. Notch signaling is a highly conserved cell–cell signaling pathway ideally suited for very short-range cellular communication because Notch signals are transmitted by direct contact with an adjacent cell. Enthusiastic efforts by Notch researchers over the last two decades have led to the identification of critical roles of this signaling pathway during development, homeostasis, and regeneration of the respiratory system. The dysregulation of Notch signaling results in a wide range of respiratory diseases such as pulmonary artery hypertension (PAH), chronic obstructive pulmonary disease (COPD), interstitial pulmonary fibrosis (IPF), and lung cancer. Thus, a deep understanding of the biological functions of Notch signaling will help identify novel treatment targets in various respiratory diseases.     

The regulation of Notch signaling in muscle stem cell activation and postnatal myogenesis

The Notch signaling pathway is an evolutionarily conserved pathway that is critical for tissue morphogenesis during development, but is also involved in tissue maintenance and repair in the adult. In skeletal muscle, regulation of Notch signaling is involved in somitogenesis, muscle development, and the proliferation and cell fate determination of muscle stems cells during regeneration. During each of these processes, the spatial and temporal control of Notch signaling is essential for proper tissue formation. That control is mediated by a series of regulatory proteins and protein complexes that enhance or inhibit Notch signaling by regulating protein processing, localization, activity, and stability. In this review, we focus on the regulation of Notch signaling during postnatal muscle regeneration when muscle stem cells ("satellite cells") must activate, proliferate, progress along a myogenic lineage pathway, and ultimately differentiate to form new muscle. We review the regulators of Notch signaling, such as Numb and Deltex, that have documented roles in myogenesis as well as other regulators that may play a role in modulating Notch signaling during satellite cell activation and postnatal myogenesis.     

Inhibition of Notch Signaling by a γ-Secretase Inhibitor Attenuates Hepatic Fibrosis in Rats

Notch signaling is essential to the regulation of cell differentiation, and aberrant activation of this pathway is implicated in human fibrotic diseases, such as pulmonary, renal, and peritoneal fibrosis. However, the role of Notch signaling in hepatic fibrosis has not been fully investigated. In the present study, we show Notch signaling to be highly activated in a rat model of liver fibrosis induced by carbon tetrachloride (CCl₄), as indicated by increased expression of Jagged1, Notch3, and Hes1. Blocking Notch signaling activation by a γ-secretase inhibitor, DAPT, significantly attenuated liver fibrosis and decreased the expression of snail, vimentin, and TGF-β1 in association with the enhanced expression of E-cadherin. The study in vitro revealed that DAPT treatment could suppress the EMT process of rat hepatic stellate cell line (HSC-T6). Interestingly, DAPT treatment was found not to affect hepatocyte proliferation in vivo. In contrast, DAPT can inhibit hepatocyte apoptosis to some degree. Our study provides the first evidence that Notch signaling is implicated in hepatic fibrogenesis and DAPT treatment has a protective effect on hepatocytes and ameliorates liver fibrosis. These findings suggest that the inhibition of Notch signaling might present a novel therapeutic approach for hepatic fibrosis.     

Mammary development and breast cancer: the role of stem cells

The mammary gland is a highly regenerative organ that can undergo multiple cycles of proliferation, lactation and involution, a process controlled by stem cells. The last decade much progress has been made in the identification of signaling pathways that function in these stem cells to control self-renewal, lineage commitment and epithelial differentiation in the normal mammary gland. The same signaling pathways that control physiological mammary development and homeostasis are also often found deregulated in breast cancer. Here we provide an overview on the functional and molecular identification of mammary stem cells in the context of both normal breast development and breast cancer. We discuss the contribution of some key signaling pathways with an emphasis on Notch receptor signaling, a cell fate determination pathway often deregulated in breast cancer. A further understanding of the biological roles of the Notch pathway in mammary stem cell behavior and carcinogenesis might be relevant for the development of future therapies.