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.     

Eph-ephrin与突触可塑性

Eph受体酪氨酸激酶及其配体ephrin广泛参与神经系统的发育,如轴突导向、细胞迁移、体节形成和血管生成。最近研究显示的Ephephrin在突触的定位提示其与突触可塑性有关。Ephephrin对成年神经系统的可塑性、学习和记忆,以及神经损伤后的再生可能具有重要的调节作用。     

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。     

轴突导向分子及受体结构与功能进展

在神经发育过程中,轴突导向分子引导轴突选择正确途径,从而成功到达靶区.近年有关轴突导向分子及其受体的研究进展迅速,主要介绍了Netrin-DCC和UNC5, semaphorin-neuropilins和plexins, Slit-robo, Eph受体酪氨酸激酶及其配体的结构和功能.     

Eph-ephrin介导反向信号传递的研究进展

双向信号传递是细胞间通讯领域中新近阐明的机制,酪氨酸激酶受体-配体(Eph-ephrin)介导的双向信号传递是此机制中的一个重要代表.Eph酪氨酸激酶家族受体及其配体ephrin家族成员是在神经发育、血管新生等方面起重要作用的分子,通过Eph向细胞内传递的信号称为正向信号,通过其配体ephrin的信号称为反向信号.Ephrin家族又可根据分子结构分为2个亚家族,其中ephrinB为跨膜蛋白,可通过酪氨酸磷酸化依赖和PDZ结合结构域介导2种方式向胞内传递反向信号,活化FAK、JNK、Wnt等信号通路,ephrinA为糖基磷脂酰肌醇锚定蛋白,也具有反向信号传递功能.     

Eph家族蛋白在学习记忆中作用的研究进展

作为大脑最基本和重要的功能之一,学习记忆始终是脑科学研究的热点领域。尽管相关研究已经取得了很大进展,但其具体机制尚不完全清楚。能产生促红细胞生成素的肝癌细胞(eryth-ropoietin-producing hepatocellular carcinoma cell,Eph)受体与其配体肝配蛋白被统称为Eph家族蛋白,其分布十分广泛且功能复杂。越来越多的研究表明,Eph家族蛋白能够调控包括突触发生及突触可塑性等多种细胞行为,在学习记忆中发挥不可或缺的作用。本文重点介绍Eph家族蛋白对学习记忆的作用并对其可能的作用机制进行概述。     

表皮生长因子受体(EGFR)的细胞内信号传导

表皮生长因子受体（EGFR）是一种存在于细胞表面的多功能跨膜蛋白分子,具有酪氨酸蛋白激酶活性,EGFR与配体结合后启动细胞内信号传导通路,不同的通路之间存在交叉对话（Cross-talks）共同完成细胞生理功能.对EGFR的深入研究,不仅可阐明细胞生长和发育等重要的生命过程,而且在医药和工业上也将有广泛的应用.     

甾体激素受体功能特异性的结构基础

甾体激素受体家族包括雌激素受体、雄激素受体等五个亚家族,在机体组织细胞的生长分化、发育生殖、内环境稳定等几乎所有生理过程中都起着重要的作用。研究甾体激素受体亚家族的特异性可以加深对该家族功能的理解,并且具有潜在的临床应用价值。采用进化踪迹方法对该家族的配体结合域（LBD）进行分析,探讨了决定亚家族功能特异性的结构基础。结果表明,甾体激素受体的各亚家族可能同相应的内源性配体存在着共进化关系;配体结合处的踪迹残基决定了受体－配体间的氢键作用和疏水相互作用模式并导致了亚家族的配体结合特异性。上述结论可用于甾体激素受体的配体结合特异性的改造以及新型组织选择性配体（如选择性雌激素受体调节剂,SERM）的设计。     

Delta样配体4与血管生成

Notch信号转导途径参与了许多重要的发育过程,如神经发育、血管形成等,最近的一系列研究表明Notch受体与邻近细胞配体--Delta样配体4（Dll-4）共同参与了新生血管的生长和分支,通过抑制血管内皮顶端细胞的形成,细胞密度、位置以及行为方式的调节,而有效促进血管内皮细胞的正常分化和血管网的及时形成.Dll4在血管生成过程中的作用为相关疾病发生机制的理解、临床诊断及治疗提供了重要的帮助.     

孕烷X受体的研究进展

核受体是一类高度保守的配体依赖性转录因子家族,在哺乳动物发育、繁殖、免疫应答、心血管功能、组织生长、肿瘤形成、外源物清除及糖类和脂质代谢等生理过程中发挥重要作用。机体对外源物质的清除主要是由孕烷X受体等核受雄介导的。孕烷X受体最早是作为外源物感受器而被研究的,可以被大多数亲脂性药物等外源性化合物及一些内源性化合物如胆汁酸等结构差异很大的配体激活,进而与视黄醇类X受体等形成异源二聚体,结合在ER6、XREM等DNA元件上,调控下游靶基因（包括一相代谢酶、二相结合酶及药物转运体等基因）的表达。此外,孕烷X受体在能量代谢和免疫反应中也有重要作用,参与某些代谢疾病的发生发展,且已在动物模型中被证明是Ⅱ型糖尿病、血脂异常、肥胖症和动脉粥样硬化等代谢疾病治疗的有效靶标。我们主要就其发现、结构、组织分布、作用方式、自身表达的调节等方面的最新研究进行综述。     

Eph receptors and ephrins

The Eph receptors are the largest known family of receptor tyrosine kinases. The Eph receptors and their membrane-attached ligands, ephrins, show diverse expression patterns during development. Recent studies have demonstrated that Eph receptors and ephrins play important roles in many developmental processes, including neuronal network formation, the patterning of the neural tube and the paraxial mesoderm, the guidance of cell migration, and vascular formation. In the nervous system, Eph receptors and ephrins have been shown to act as positional labels to establish topographic projections. They also play a key role in pathway finding by axons and neural crest cells. The crucial roles of Eph receptors and ephrins during development suggest involvement of these genes in congenital disorders affecting the nervous system and other tissues. It has also been suggested that Eph receptors and ephrins may be involved in carcinogenesis. It is therefore of clinical importance to further analyse the function of these molecules, as manipulation of their function may have therapeutic applications.     

Roles of Eph receptors and ephrins in segmental patterning

Eph receptor tyrosine kinases and their membrane-bound ligands, ephrins, have key roles in patterning and morphogenesis. Interactions between these molecules are promiscuous, but largely fall into two groups: EphA receptors bind to glycosylphosphatidyl inositol-anchored ephrin-A ligands, and EphB receptors bind to transmembrane ephrin-B proteins. Ephrin-B proteins transduce signals, such that bidirectional signalling can occur upon interaction with the Eph receptor. In many tissues, there are complementary and overlapping expression domains of interacting Eph receptors and ephrins. An important role of Eph receptors and ephrins is to mediate cell contact-dependent repulsion, and this has been implicated in the pathfinding of axons and neural crest cells, and the restriction of cell intermingling between hindbrain segments. Studies in an in vitro system show that bidirectional activation is required to prevent intermingling between cell populations, whereas unidirectional activation can restrict cell communication via gap junctions. Recent work indicates that Eph receptors can also upregulate cell adhesion, but the biochemical basis of repulsion versus adhesion responses is unclear. Eph receptors and ephrins have thus emerged as key regulators that, in parallel with cell adhesion molecules, underlie the establishment and maintenance of patterns of cellular organization.     

Eph and ephrins in epithelial stem cell niches and cancer

The family of Eph tyrosine kinase receptors is an important part of signaling pathways involved in development, tissue homeostasis and tumorigenesis. Binding and activation of the receptors by their ligands, the ephrins, result in bidirectional signaling into both receptor and ligand expressing cells. Adult stem cell niches and tumors frequently express receptors and ligands, although their function is only beginning to be understood. Thus, Eph receptors and ephrins have become important molecules for understanding basic biological processes as well as tumorigenesis, and are promising targets for potential therapeutic intervention in human disease.     

Tissue transglutaminase clusters soluble A-type ephrins into functionally active high molecular weight oligomers

The Eph receptors and their ligands, the ephrins, are thought to act at points of close cell-cell contact to elicit bi-directional signaling in receptor and ligand expressing cells. However, when cultured in vitro, some A-type ephrins are released from the cell surface and it is unclear if these soluble ephrins participate in Eph receptor activation. We show that soluble ephrin A5 is subject to oligomerization. Ephrins A1 and A5 are substrates for a cross-linking enzyme, tissue transglutaminase, which mediates the formation of oligomeric ephrin. Transglutaminase-cross-linked ephrin binds to A-type Eph receptors, stimulates Eph kinase activity, and promotes invasion and migration of HeLa cells. Transglutaminase-mediated oligomerization of soluble ephrin potentially represents a novel mechanism of forward signaling through Eph receptors and may extend the influence of A-type ephrins beyond cell contact mediated signaling.     

Eph and ephrins in epithelial stem cell niches and cancer

The family of Eph tyrosine kinase receptors is an important part of signaling pathways involved in development, tissue homeostasis and tumorigenesis. Binding and activation of the receptors by their ligands, the ephrins, result in bidirectional signaling into both receptor and ligand expressing cells. Adult stem cell niches and tumors frequently express receptors and ligands, although their function is only beginning to be understood. Thus, Eph receptors and ephrins have become important molecules for understanding basic biological processes as well as tumorigenesis, and are promising targets for potential therapeutic intervention in human disease.     

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.     

Interaction between ephrins/Eph receptors and excitatory amino acid receptors: possible relevance in the regulation of synaptic plasticity and in the pathophysiology of neuronal degeneration

There is increasing evidence that Eph receptors and their transmembrane ligands, named ephrins, interact with glutamate receptors in both developing and adult neurons. EphB receptors interact with proteins that regulate the membrane trafficking of alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) receptor subunits, and both ephrins and EphB receptors have been found to co-localize with N-methyl-d-aspartate (NMDA) receptors and to positively modulate NMDA receptor function. Moreover, pharmacologic activation of ephrin-Bs amplifies group-I metabotropic glutamate receptor signaling through mechanisms that involve NMDA receptors. The interaction with ionotropic or metabotropic glutamate receptors provides a substrate for the emerging role of ephrins and Eph receptors in the regulation of activity-dependent forms of synaptic plasticity, such as long-term potentiation and long-term depression, which are established electrophysiologic models of associative learning. In addition, these interactions explain the involvement of ephrins/Eph receptors in the regulation of pain threshold and epileptogenesis, as well as their potential implication in processes of neuronal degeneration. This may stimulate the search for new drugs that might modulate excitatory synaptic transmission by interacting with the ephrin/Eph receptor system.     

Eph/ephrin signaling in epithelial development and homeostasis

Eph receptors and ephrin ligands are widely expressed during embryonic development with well-defined functions in directing neuronal and vascular network formation. Over the last decade, evidence has mounted that Ephs and ephrins are also actively involved in prenatal and postnatal development of epithelial tissues. Their functions beyond developmental settings are starting to be recognized as well. The diverse functions of Eph/ephrin are largely related to the complementary expression pattern of the Eph receptors and corresponding ephrin ligands that are expressed in adjacent compartments, although overlapping expression pattern also exists in epithelial tissue. The interconnection between Ephs or ephrins and classical cell junctional molecules suggests they may function coordinately in maintaining epithelial structural integrity and homeostasis. This review will highlight cellular and molecular evidence in current literature that support a role of Eph/ephrin systems in regulating epithelial cell development and physiology.     

Eph-modulated cell morphology, adhesion and motility in carcinogenesis

Eph receptor tyrosine kinases (Ephs) and their membrane anchored ephrin ligands (ephrins) form an essential cell-cell communication system that directs the positioning, adhesion and migration of cells and cell layers during development. While less prominent in normal adult tissues, there is evidence that up-regulated expression and de-regulated function of Ephs and ephrins in a large variety of human cancers may promote a more aggressive and metastatic tumour phenotype. However, in contrast to other RTKs, Ephs do not act as classical proto-oncogenes and do not effect cell proliferation or differentiation. Mounting evidence suggests that Eph receptors, through de-regulated re-emergence of their mode of action in the embryo may direct cell movements and positioning during metastasis, invasion and tumour angiogenesis. This review discusses these and other emerging roles of Eph receptors during oncogenesis.     

Ectodomain structures of Eph receptors

Eph receptors, the largest subfamily of receptor tyrosine kinases (RTKs), and their ephrin ligands are important mediators of cell-cell communication that regulate axon guidance, long-term potentiation, and stem cell development, among others. By now, many Eph receptors and ephrins have also been found to play important roles in the progression of cancer. Since both the receptor and the ligand are membrane-bound, their interaction leads to the multimerization of both molecules to distinct clusters within their respective plasma membranes, resulting in the formation of discrete signaling centers. In addition, and unique to Eph receptors and ephrins, their interaction initiates bi-directional signaling cascades where information is transduced in the direction of both the receptor- and the ligand-bearing cells. The Ephs and the ephrins are divided into two subclasses, A and B, based on their affinities for each other and on sequence conservation. Crystal structures and other biophysical studies have indicated that isolated extracellular Eph and ephrin domains initially form high-affinity heterodimers around a hydrophobic loop of the ligand that is buried in a hydrophobic pocket on the surface of the receptor. The dimers can then further arrange by weaker interactions into higher-order Eph/ephrin clusters observed in vivo at the sites of cell-cell contact. Although the hetero-dimerization is a universal way to initiate signaling, other extracellular domains of Ephs are involved in the formation of higher-order clusters. The structures also show important differences defining the unique partner preferences of the two ligand and receptor subclasses, namely, how subclass specificity is determined both by individual interacting residues and by the precise architectural arrangement of ligands and receptors within the complexes.