Eph家族蛋白在阿尔茨海默症等神经精神疾病中的作用

促红细胞生成素产生肝细胞(erythropoietin-producing hepatomocellular, Eph)受体是受体酪氨酸激酶家族中数量最多的成员。Eph受体与其配体肝配蛋白(Eph receptor-interacting proteins, ephrin)被统称为Eph家族蛋白,通过独特的双向信号传递在调控正常学习和记忆中扮演重要角色。近年大量的研究发现,Eph家族蛋白在多种神经精神疾病中发挥复杂而又重要的作用,主要是通过改变突触效能,参与神经元形态发生和调控基因表达等方式影响上述疾病的进程。然而,目前靶向Eph家族蛋白对阿尔茨海默症(Alzheimer’s disease, AD)、焦虑症及恐惧症等疾病进行治疗的研究却为数甚微。同时,单纯以β样淀粉蛋白为靶点的抗AD药物开发均遭遇瓶颈。因此,探索Eph家族蛋白在上述疾病中的具体作用变得十分迫切。本文综述了Eph家族蛋白在AD、焦虑症和恐惧症中的最新研究进展,旨在为靶向Eph家族蛋白治疗相关疾病提供新的思路。     

Eph-Ephrin双向信号转导途径在眼部血管新生中的作用

Eph/Ephrin家族是受体酪氨酸激酶家族中的最大亚族,在生理和病理性血管形成中起重要作用。眼部血管生成是糖尿病视网膜病、早产儿视网膜等眼部疾病致盲的重要因素,Eph和Ephrin基因在上述眼部疾病中有不同程度表达改变。Eph受体及其配体Ephrin之间的双向信号机制是Eph-Ephrin发挥功能的主要方式。本文就Eph-Ephrin双向信号机制在眼部血管新生中的作用进行综述。     

二聚化:受体酪氨酸激酶活化的重要机制

受体酪氨酸激酶家族是一类具有内源性蛋白酪氨酸激酶活性的生长因子受体。它们具有相似的分子结构 ,其配体介导的受体活化主要是通过二聚化的机制来实现的。配体介导同源或异源的受体二聚化 ,不同的配体以不同的机制介导受体的二聚化。本文介绍了受体酪氨酸激酶家族不同亚类受体在其配体介导下二聚化的机制 ,并着重介绍了表皮生长因子受体家族各成员间的异二聚化及其引起的胞内信号转导途径的多样化     

二聚化：受体酶氨酸激酶活化的重要机制

受体酪氨酸激酶家族是一类具有内源性蛋白酪氨酸激酶活性的生长因子受体。它们具有相似的分子结构,其配体介导的受体活化主要是通过二聚化的机制来实现的。配体介导同源或异源的受体二聚化,不同的配体以不同的机制介导受体的二聚化。本文介绍了受体酪氨酸激酶家族不同亚类受体在其配体介导下二聚化的机制,并着重介绍了表皮生长因子受体家族各成员间的异二聚化及其引起的胞内信号转导途径的多样化。     

Eph受体家族及其配体的信号转导途径及功能

Eph受体是已知最大的酪氨酸蛋白激酶受体家族,Eph受体和其膜附着型配体（ephrin）在发育过程中呈现不同的表达模式,近来研究证明,Eph受体和其配体在包括神经网络形成,神经管和轴旁中胚层的成型（patterning）,细胞迁移导向和轴突路径导引,血管形成等许多的发育过程中起重要作用.Eph受体及其配体也与肿瘤发生有关,因此深入分析这些分子尤其在肿瘤细胞生长中的功能而应用于治疗具有重要的临床意义.     

酪氨酸激酶受体Eph亚族的研究进展

酪氨酸激酶受体（RTK）参与细胞生长、分化、胚胎发育及细胞内信号传递等过程,具有相当重要的生理功能.目前已发现50多种RTK基因分属于14种亚族,Eph亚族是其中最大的家族,由14个基因组成,一些基因主要在脑的发育中表达,另一些则在各种组织中广泛表达.最近该亚族胞外配体的发现为深入研究其生理功能打下基础.综述了Eph亚族成员的来源、表达及其配体的研究概况.     

Src激酶的功能研究新进展

Src激酶家族是具有酪氨酸蛋白激酶活性的蛋白质,作为连接许多细胞外和细胞内重要信号途径的膜结合开关分子,Src激酶在受体介导的信号传递及细胞间通讯中具中心调节作用。最近发现它在淋巴因子介导的细胞存活及血管内皮生长因子介导的血管发生中也具有重要作用。     

Eph/ephrin对树突棘的调控与中枢神经系统疾病

树突棘是神经元树突上的功能性突起结构,通常作为突触后成份与投射来的轴突共同构成完整的突触连接。树突棘的形态与结构具有明显的可塑性,其变化通常会引起突触功能的改变。Eph受体酪氨酸激酶家族分子与其配体ephrin都是重要的神经导向因子,同时对树突棘结构也有直接的调控作用。Eph受体的活化可以促进树突棘的发生并影响树突棘的形态及内部结构;而Eph受体的异常也往往会损害正常的突触功能,甚至导致许多与树突棘结构异常相关的神经系统病变的发生。     

支架蛋白Gab2信号调控与乳腺癌

Gab2是支架蛋白Gabs家族中的重要成员.该家族蛋白通过介导膜受体与信号转运蛋白间的偶联及各信号分子间的整合参与信号传导.作为支架蛋白,Gab2可被酪氨酸激酶磷酸化激活,接受胞外多种因子刺激,招募富含SH2结构域的信号转运分子,活化下游SHP2/Ras/ERK和PI3K/AKT等一系列信号传导途径,在细胞增殖、分化、...     

促红细胞生成素产生肝细胞受体A2(EphA2)SAM结构域对激酶结构域的脂质体结合能力与激酶活性的调控研究

促红细胞生成素产生肝细胞受体(Eph receptor) 是受体酪氨酸激酶(RTK)家族中最大的亚家族,其介导的双向信号传导对细胞的形态、黏附、运动、增殖、生存及分化都有重要的调控作用。EphA2是Eph受体家族中一个被广泛研究的重要亚型,在白内障和乳腺癌等病理发生过程中发挥了重要作用。既往研究发现:EphA2受体的激酶结构域可结合细胞膜,其激酶活性受磷脂膜的调控,但是相邻的SAM结构域对激酶结构域与脂膜的相互作用以及激酶活性的影响尚不清楚。在此项研究中,通过与磷酸酶PTP1B1-301活性片段共表达的方式,表达、纯化了EphA2受体的胞内段激酶-SAM串联结构域,通过比较胞内段激酶-SAM串联结构域与单独激酶结构域的脂质体结合能力,以及测定对应的激酶活性,发现:EphA2受体胞内段的SAM结构域使其激酶结构域与脂质体(4 mg/mL)的结合能力增强约6倍(P＜0.001);磷酸化后的EphA2胞内段激酶-SAM串联结构域结合脂质体(4 mg/mL)的能力比非磷酸化的胞内段激酶-SAM串联结构域提高2.5倍(P＜0.05);而结合脂质体后,激酶结构域的激酶活性也被进一步提高,从而形成正反馈。综上所述,本研究的发现提示:EphA2胞内段的酪氨酸激酶结构域与相邻的SAM结构域可形成一个完整的结构功能单位,其激酶活性和脂质体结合能力与单独的激酶结构域相比都形成了明显的差异,我们的这一发现对进一步理解Eph受体家族其他亚型的激酶结构域的活性调控提供了参考与思路。     

Ephrin-B reverse signaling is mediated by a novel PDZ-RGS protein and selectively inhibits G protein-coupled chemoattraction

Transmembrane B ephrins and their Eph receptors signal bidirectionally. However, neither the cell biological effects nor signal transduction mechanisms of the reverse signal are well understood. We describe a cytoplasmic protein, PDZ-RGS3, which binds B ephrins through a PDZ domain, and has a regulator of heterotrimeric G protein signaling (RGS) domain. PDZ-RGS3 can mediate signaling from the ephrin-B cytoplasmic tail. SDF-1, a chemokine with a G protein-coupled receptor, or BDNF, act as chemoattractants for cerebellar granule cells, with SDF-1 action being selectively inhibited by soluble EphB receptor. This study reveals a pathway that links reverse signaling to cellular guidance, uncovers a novel mode of control for G proteins, and demonstrates a mechanism for selective regulation of responsiveness to neuronal guidance cues.     

Non-SH2/PDZ reverse signaling by ephrins

Great strides have been made regarding our understanding of the processes and signaling events influenced by Eph/ephrin signaling that play a role in cell adhesion and cell movement. However, the precise mechanisms by which these signaling events regulate cell and tissue architecture still need further resolution. The Eph/ephrin signaling pathways and the ability to regulate cell-cell adhesion and motility constitutes an impressive system for regulating tissue separation and morphogenesis (Pasquale, 2005, 2008 [1,2]). Moreover, the de-regulation of this signaling system is linked to the promotion of aggressive and metastatic tumors in humans [2]. In the following section, we discuss some of the interesting mechanisms by which ephrins can signal through their own intracellular domains (reverse signaling) either independent of forward signaling or in addition to forward signaling through a cognate receptor. In this review we discuss how ephrins (Eph ligands) "reverse signal" through their intracellular domains to affect cell adhesion and movement, but the focus is on modes of action that are independent of SH2 and PDZ interactions.     

Membrane‐mediated regulation of vascular identity

Vascular diseases span diverse pathology, but frequently arise from aberrant signaling attributed to specific membrane‐associated molecules, particularly the Eph‐ephrin family. Originally recognized as markers of embryonic vessel identity, Eph receptors and their membrane‐associated ligands, ephrins, are now known to have a range of vital functions in vascular physiology. Interactions of Ephs with ephrins at cell‐to‐cell interfaces promote a variety of cellular responses such as repulsion, adhesion, attraction, and migration, and frequently occur during organ development, including vessel formation. Elaborate coordination of Eph‐ and ephrin‐related signaling among different cell populations is required for proper formation of the embryonic vessel network. There is growing evidence supporting the idea that Eph and ephrin proteins also have postnatal interactions with a number of other membrane‐associated signal transduction pathways, coordinating translation of environmental signals into cells. This article provides an overview of membrane‐bound signaling mechanisms that define vascular identity in both the embryo and the adult, focusing on Eph‐ and ephrin‐related signaling. We also discuss the role and clinical significance of this signaling system in normal organ development, neoplasms, and vascular pathologies. Birth Defects Research (Part C) 108:65–84, 2016. © 2016 Wiley Periodicals, Inc.     

Coexpressed EphA receptors and ephrin-A ligands mediate opposing actions on growth cone navigation from distinct membrane domains

Contact-dependent signaling between membrane-linked ligands and receptors such as the ephrins and Eph receptor tyrosine kinases controls a wide range of developmental and pathological processes. Paradoxically, many cell types coexpress both ligands and receptors, raising the question of how specific signaling readouts are achieved under these conditions. Here, we studied the signaling activities exerted by coexpressed EphA receptors and GPI-linked ephrin-A ligands in spinal motor neuron growth cones. We demonstrate that coexpressed Eph and ephrin proteins segregate laterally into distinct membrane domains from which they signal opposing effects on the growth cone: EphAs direct growth cone collapse/repulsion and ephrin-As signal motor axon growth/attraction. This subcellular arrangement of Eph-ephrin proteins enables axons to discriminate between cis- versus trans-configurations of ligand/receptor proteins, thereby allowing the utilization of both Ephs and ephrins as functional guidance receptors within the same neuronal growth cone.     

EphB/ephrinB Signaling in Cell Adhesion and Migration

Eph receptors and their ligands, ephrins, represent the largest group of the receptor tyrosine kinase (RTK) family, and they mediate numerous developmental processes in a variety of organisms. Ephrins are membrane-bound proteins that are mainly divided into two classes: A class ephrins, which are linked to the membrane by a glycosylphosphatidylinositol (GPI) linkage, and B class ephrins, which are transmembrane ligands. Based on their domain structures and affinities for ligand binding, the Eph receptors are also divided into two groups. Trans-dimerization of Eph receptors with their membrane-tethered ligands regulates cell-cell interactions and initiates bidirectional signaling pathways. These pathways are intimately involved in regulating cytoskeleton dynamics, cell migration, and alterations in cellular dynamics and shapes. The EphBs and ephrinBs are specifically localized and modified to promote higher-order clustering and initiate of bidirectional signaling. In this review, we present an in-depth overview of the structure, mechanisms, cell signaling, and functions of EphB/ephrinB in cell adhesion and migration.     

Eph receptor-ephrin bidirectional signals that target Ras and Rho proteins

The ability of cells to respond to their surrounding environment and relay signals to the cell interior is essential for numerous processes during the development and maintenance of tissues. Eph receptors and their membrane-bound ligands, the ephrins, are unique in the receptor tyrosine kinase family in that their signaling is bidirectional, through both the receptor and the ligand. Eph receptors and ephrins are essential for a variety of biological processes, and play a particularly important role in regulating cell shape and cell movement. Recent data have linked Eph receptor-ephrin signaling complexes to the Ras and Rho families of small molecular weight GTPases and also to heterotrimeric G proteins. Understanding the signaling networks involved is an important step to understand the molecular basis for normal and defective cell-cell communication through Eph receptors and ephrins.     

Dancing with the dead: Eph receptors and their kinase-null partners

Eph receptor tyrosine kinases and their ligands, ephrins, are membrane proteins coordinating a wide range of biological functions both in developing embryos and in adult multicellular organisms. Numerous studies have implicated Eph receptors in the induction of opposing responses, including cell adhesion or repulsion, support or inhibition of cell proliferation and cell migration, and progression or suppression of multiple malignancies. Similar to other receptor tyrosine kinases, Eph receptors rely on their ability to catalyze tyrosine phosphorylation for signal transduction. Interestingly, however, Eph receptors also actively utilize three kinase-deficient receptor tyrosine kinases, EphB6, EphA10, and Ryk, in their signaling network. The accumulating evidence suggests that the unusual flexibility of the Eph family, allowing it to initiate antagonistic responses, might be partially explained by the influence of the kinase-dead participants and that the exact outcome of an Eph-mediated action is likely to be defined by the balance between the signaling of catalytically potent and catalytically null receptors. We discuss in this minireview the emerging functions of the kinase-dead EphB6, EphA10, and Ryk receptors both in normal biological responses and in malignancy, and analyze currently available information related to the molecular mechanisms of their action in the context of the Eph family.     

Signal transfer by Eph receptors

The Eph receptors are a unique family of receptor tyrosine kinases that enforce cellular position in tissues through mainly repulsive signals generated upon cell-cell contact. Together, Eph receptors and their membrane-anchored ligands. the ephrins, are key molecules for establishing tissue organization through signaling pathways that control axonal projection, cell migration, and the maintenance of cellular boundaries. Through their SH2 (Src Homology 2) and PDZ (postsynaptic density protein, disks large, zona occludens) domains, several signaling molecules have been demonstrated to interact with the activated cytoplasmic domain of Eph receptors by using the yeast two-hybrid system and in vitro biochemical assays. Most proteins found to interact with Eph receptors are well-known regulators of cytoskeletal organization and cell adhesion, and also cell proliferation. Promoting growth, however, does not appear to be a primary role of Eph receptors. Explaining which signaling interactions identified for the Eph receptors have physiological significance, how Eph receptor signaling cascades are propagated, and characterizing the intrinsic signaling properties of the ephrins are all exciting questions currently being investigated.     

Eph receptor and ephrin function in breast,gut, and skin epithelia

Epithelial cells are tightly coupled together through specialized intercellular junctions, including adherens junctions, desmosomes, tight junctions, and gap junctions. A growing body of evidence suggests epithelial cells also directly exchange information at cell-cell contacts via the Eph family of receptor tyrosine kinases and their membrane-associated ephrin ligands. Ligand-dependent and -independent signaling via Eph receptors as well as reverse signaling through ephrins impact epithelial tissue homeostasis by organizing stem cell compartments and regulating cell proliferation, migration, adhesion, differentiation, and survival. This review focuses on breast, gut, and skin epithelia as representative examples for how Eph receptors and ephrins modulate diverse epithelial cell responses in a context-dependent manner. Abnormal Eph receptor and ephrin signaling is implicated in a variety of epithelial diseases raising the intriguing possibility that this cell-cell communication pathway can be therapeutically harnessed to normalize epithelial function in pathological settings like cancer or chronic inflammation.     

Eph receptor and ephrin function in breast,gut, and skin epithelia

Epithelial cells are tightly coupled together through specialized intercellular junctions, including adherens junctions, desmosomes, tight junctions, and gap junctions. A growing body of evidence suggests epithelial cells also directly exchange information at cell-cell contacts via the Eph family of receptor tyrosine kinases and their membrane-associated ephrin ligands. Ligand-dependent and -independent signaling via Eph receptors as well as reverse signaling through ephrins impact epithelial tissue homeostasis by organizing stem cell compartments and regulating cell proliferation, migration, adhesion, differentiation, and survival. This review focuses on breast, gut, and skin epithelia as representative examples for how Eph receptors and ephrins modulate diverse epithelial cell responses in a context-dependent manner. Abnormal Eph receptor and ephrin signaling is implicated in a variety of epithelial diseases raising the intriguing possibility that this cell-cell communication pathway can be therapeutically harnessed to normalize epithelial function in pathological settings like cancer or chronic inflammation.