EphA2和E-cadherin在乳腺癌中的表达及其与患者预后的关系

目的探讨EphA2和E-cadherin在乳腺癌中的表达并分析两者表达与预后的关系。方法采用免疫组织化学SP法检测EphA2和E-cadherin在90例乳腺癌和20例乳腺良性病变组织中的表达,分析两者的表达情况与疾病的临床病理特征之间的关系及两种蛋白间的相关性。并分析90例乳腺癌患者的随访资料,判断EphA2和E-cadherin的表达与患者预后的关系。结果EphA2与E-cadherin在乳腺癌中阳性表达率分别为83.3%和35.6%,两者表达均与与肿瘤大小无关(P0.05);EphA2蛋白的阳性表达与组织学分级,临床分期,有无淋巴结转移有关(P0.05),而与病理类型无关(P0.05);E-cadherin蛋白的阳性表达与病理类型,组织学分级,临床分期,有无淋巴结转移有关(P0.05)。乳腺癌中EphA2和E-cadherin的蛋白表达呈负相关(r=-0.291,P0.05)。K-M法单因素分析显示EphA2蛋白的阳性表达患者5年生存率低于阴性患者(P0.05);E-cadherin蛋白的阳性表达患者5年生存率高于阴性患者(P0.05)。结论E-phA2和E-cadherin在乳腺癌中分别高表达和低表达,且均与乳腺癌预后密切相关,对判断乳腺癌的预后有重要预测意义。     

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。     

E-cadherin 在肿瘤治疗中的研究进展

E-cadherin 参与形成细胞间黏附性连接,是胚胎发育过程中的一个关键因子。越来越多的研究表明,E-cadherin 在肿瘤的发生发 展过程中也发挥了至关重要的作用。在生物体内,E-cadherin 的表达和功能受到多个水平、多重因素的调控,而 E-cadherin 又可以影响 多条重要信号通路的活性,参与到多种生理病理过程中。E-cadherin 下调造成细胞间黏附性连接减少、极性减弱,细胞由上皮样转变为间 质样,这一变化是上皮间质转化（EMT）的重要标志之一。E-cadherin 与多种肿瘤的发生有一定的相关性。同时 E-cadherin 下调所引起 的 EMT 促进肿瘤细胞的迁移运动,肿瘤细胞侵袭力增强,促进转移的发生。近年来,大量研究关注到 E-cadherin 对肿瘤细胞的耐药及干 细胞特性的获得都有影响。综述 E-cadherin 在肿瘤发生发展中的作用,探讨以 E-cadherin 为靶点的肿瘤治疗的现状及展望。     

上皮–间质转化在肿瘤侵袭、转移及化疗耐药中的研究进展

肿瘤细胞转移是造成癌症患者死亡的主要原因,上皮–间质转化(epithelialmesenchymal transition,EMT)使肿瘤细胞由上皮细胞转化为间质细胞,维持上皮细胞黏附的E-钙黏蛋白(E-cadherin)表达下调,破坏细胞间连接、获得侵袭与转移的能力,此过程受多种生长因子的调节。最新研究发现,肿瘤细胞发生EMT使其获得抗凋亡与耐受化疗药物的能力。该文旨在概述EMT在肿瘤转移与耐药性中的作用。     

Slug和E-cadherin在非小细胞肺癌恶性胸水细胞中的表达变化

目的研究锌指转录因子Slug、E-cadherin和Vimentin在非小细胞肺癌恶性胸水细胞中的表达。方法应用免疫细胞化学和western blot检测Slug、E-cadherin和Vimentin在非小细胞肺癌胸水中的表达。结果在121例非小细胞肺癌胸水中,Slug、E-cadherin和Vimentin的阳性表达率分别为35.5%(43/121)、71.9%(87/121)和39.71%(48/121),在非小细胞肺癌细胞中Slug和E-cadherin阳性表达率均高于正常胸水,Slug表达的增强通常伴随E-cadherin表达下调及Vimentin表达的增强。结论 Slug与E-cadherin在胸水中非小细胞肺癌细胞中的表达呈负相关,在胸水中提取非小细胞肺癌细胞,研究Slug和E-cadherin,Vimentin的表达及其在上皮间质转化中的调节作用对探讨肿瘤细胞在人体中的转移进展很有意义。     

沉默FOXQ1可逆转SW480细胞的上皮-间质转化

FOXQ1是FOX家族的的重要成员之一,其参与了多种人类肿瘤的上皮间质转化(epithelial- mesenchymal transition,EMT).本研究设计合成了FOXQ1基因的shRNA（short hairpin RNA）,用此转染SW480细胞,通过显微镜观察细胞形态,Transwell小室、细胞黏附试验检测转移能力及黏附能力,以探索FOXQ1与结直肠癌细胞EMT的关系.结果显示,沉默FOXQ1后,SW480细胞顶底极性及细胞间紧密连接增加,侵袭、迁移的细胞数目减少,同种黏附能力增加,异种黏附能力降低.进一步的机制研究表明,沉默FOXQ1基因可以导致SW480细胞的上皮标志因子E-cadherin表达显著增高,而间质细胞标志因子N-cadherin、Vimentin及MMP2表达均降低.以上结果表明,沉默FOXQ1基因可以逆转SW480细胞EMT,其机制可能与E-cadherin的上调和N cadherin、Vimentin、MMP2的下调有关,这为进一步研究FOXQ1在结直肠癌发生发展中的作用提供实验基础.     

钙黏附素和β- 连接素与宫颈上皮内瘤变进展的关系

目的:观察钙黏附素(E-cadherin)和β-连接素(β-catenin)在不同级别宫颈上皮内瘤变组织中的表达,探讨其与宫颈上皮内瘤变进展的关系。方法:采用免疫组化法检测51例宫颈组织病理存档石蜡包埋组织钙黏附素(E-cadherin)和β-连接素(β-catenin)的表达,阳性信号采用图像分析仪进行定量分析。结果:E-cadherin在柱状上皮移位组及CIN I组、CIN II组、CIN III组中的平均光密度值(AOD)分别为:0.0866±0.0392、0.073±0.0122、0.0467±0.0056、0.0396±0.0097;β-catenin在柱状上皮移位组及CIN I组、CIN II组、CIN III组中的平均光密度值(AOD)分别为:0.1101±0.0116、0.1016±0.0108、0.0711±0.0062、0.0515±0.0091。随着CIN病变的升级,钙黏附素和β-连接素的表达均呈下降趋势,二者的平均光密度值(AOD)正相关(r=2.546,P=0.018<0.05)。结论:钙黏附素、β-连接素与宫颈上皮内瘤变的进展相关,在估计CIN的预后中有一定意义。     

白细胞介素-8与肿瘤免疫逃逸

IL-8是趋化因子CXC家族的一员,是一种多细胞来源的细胞因子,在细胞的多种炎症反应中起调节作用,并且在自身免疫性疾病中也发挥重要作用。IL-8通过与细胞膜上的CXC趋化因子受体CXCR1和CXCR2相互作用,激活偶联的G蛋白,由G蛋白进一步激活PLC、AC、PLD、PI3K、JAK2及Ras等信号分子,从而调控基因表达、细胞增殖和分化、细胞代谢、细胞运动及血管生成等多种细胞生命过程。IL-8在多种恶性肿瘤细胞中表达量升高,其高表达与肿瘤细胞增殖、迁移、侵袭、血管生成及上皮间充质转化有密切联系。肿瘤免疫逃逸是肿瘤细胞产生和转移过程中的主要特征之一,肿瘤细胞可以通过多种机制使得人体免疫系统无法对其进行正常的识别和攻击,从而导致肿瘤细胞在体内存活,并且不断增殖和转移,而肿瘤细胞、免疫细胞以及肿瘤微环境中其他相关组分均可以促进肿瘤免疫逃逸。IL-8作为一种炎性趋化因子,已被证明在肿瘤免疫逃逸中具有重要作用,其可通过诱导肿瘤细胞PD-L1表达、抑制肿瘤细胞凋亡、促进肿瘤细胞EMT进程、促进肿瘤微环境血管生成、招募免疫抑制性细胞等五个方面介导肿瘤免疫逃逸。IL-8中和抗体和CXCR1/2拮抗剂在抗肿瘤治疗方面已经显示出较好的治疗效果。     

上皮间质转化介导肿瘤转移的分子机制

上皮间质转化(epithelial-mesenchymal transition, EMT)是上皮细胞上皮样特征减少并获得间充质细胞特性的生理过程。EMT是肿瘤细胞侵袭转移所必要的初始步骤, EMT过程中上皮细胞失去细胞极性和细胞黏附能力,并获得迁移和侵袭性。在EMT过程中,肿瘤细胞频繁出现E-钙黏蛋白(E-cadherin)功能的丧失, N-钙黏蛋白(N-cadherin)、波形蛋白(vimentin)及基质金属蛋白酶(matrix metalloproteinases, MMPs)表达水平的上调,β-连环蛋白(β-catenin)从细胞膜到细胞核的重新定位。EMT相关转录因子Twist、Snail及Zeb家族的异常高表达均经促进EMT而介导肿瘤细胞的侵袭转移。     

上皮间充质转化促进肿瘤细胞干性获得的研究进展

上皮间充质转化是上皮细胞丢失细胞极性和细胞黏附,而获得间充质细胞迁移和侵袭特性的生物学过程.肿瘤干细胞是存在于肿瘤中具有自我更新和异质性分化能力的一小群细胞,在肿瘤的发生发展过程中起重要的作用.上皮间充质转化(EMT)与肿瘤的转移密切相关,而近几年的研究表明,EMT也可以促进肿瘤细胞获得干细胞的特性,因此使肿瘤治疗更困难,本文对EMT促肿瘤干细胞形成机制及其对临床治疗意义的研究进展作一综述.     

E-cadherin regulates the function of the EphA2 receptor tyrosine kinase.

EphA2 is a member of the Eph family of receptor tyrosine kinases, which are increasingly understood to play critical roles in disease and development. We report here the regulation of EphA2 by E-cadherin. In nonneoplastic epithelia, EphA2 was tyrosine-phosphorylated and localized to sites of cell-cell contact. These properties required the proper expression and functioning of E-cadherin. In breast cancer cells that lack E-cadherin, the phosphotyrosine content of EphA2 was decreased, and EphA2 was redistributed into membrane ruffles. Expression of E-cadherin in metastatic cells restored a more normal pattern of EphA2 phosphorylation and localization. Activation of EphA2, either by E-cadherin expression or antibody-mediated aggregation, decreased cell-extracellular matrix adhesion and cell growth. Altogether, this demonstrates that EphA2 function is dependent on E-cadherin and suggests that loss of E-cadherin function may alter neoplastic cell growth and adhesion via effects on EphA2.     

An ephrin mimetic peptide that selectively targets the EphA2 receptor

Eph receptor tyrosine kinases represent promising disease targets because they are differentially expressed in pathologic versus normal tissues. The EphA2 receptor is up-regulated in transformed cells and tumor vasculature where it likely contributes to cancer pathogenesis. To exploit EphA2 as a therapeutic target, we used phage display to identify two related peptides that bind selectively to EphA2 with high affinity (submicromolar K(D) values). The peptides target the ligand-binding domain of EphA2 and compete with ephrin ligands for binding. Remarkably, one of the peptides has ephrin-like activity in that it stimulates EphA2 tyrosine phosphorylation and signaling. Furthermore, this peptide can deliver phage particles to endothelial and tumor cells expressing EphA2. In contrast, peptides corresponding to receptor-interacting portions of ephrin ligands bind weakly and promiscuously to many Eph receptors. Bioactive ephrin mimetic peptides could be used to selectively deliver agents to Eph receptor-expressing tissues and modify Eph signaling in therapies for cancer, pathological angiogenesis, and nerve regeneration.     

Small molecules can selectively inhibit ephrin binding to the EphA4 and EphA2 receptors

The erythropoietin-producing hepatocellular (Eph) family of receptor tyrosine kinases regulates a multitude of physiological and pathological processes. Despite the numerous possible research and therapeutic applications of agents capable of modulating Eph receptor function, no small molecule inhibitors targeting the extracellular domain of these receptors have been identified. We have performed a high throughput screen to search for small molecules that inhibit ligand binding to the extracellular domain of the EphA4 receptor. This yielded a 2,5-dimethylpyrrolyl benzoic acid derivative able to inhibit the interaction of EphA4 with a peptide ligand as well as the natural ephrin ligands. Evaluation of a series of analogs identified an isomer with similar inhibitory properties and other less potent compounds. The two isomeric compounds act as competitive inhibitors, suggesting that they target the high affinity ligand-binding pocket of EphA4 and inhibit ephrin-A5 binding to EphA4 with K(i) values of 7 and 9 mum in enzyme-linked immunosorbent assays. Interestingly, despite the ability of each ephrin ligand to promiscuously bind many Eph receptors, the two compounds selectively target EphA4 and the closely related EphA2 receptor. The compounds also inhibit ephrin-induced phosphorylation of EphA4 and EphA2 in cells, without affecting cell viability or the phosphorylation of other receptor tyrosine kinases. Furthermore, the compounds inhibit EphA4-mediated growth cone collapse in retinal explants and EphA2-dependent retraction of the cell periphery in prostate cancer cells. These data demonstrate that the Eph receptor-ephrin interface can be targeted by inhibitory small molecules and suggest that the two compounds identified will be useful to discriminate the activities of EphA4 and EphA2 from those of other co-expressed Eph receptors that are activated by the same ephrin ligands. Furthermore, the newly identified inhibitors represent possible leads for the development of therapies to treat pathologies in which EphA4 and EphA2 are involved, including nerve injuries and cancer.     

Activation of EphA receptor tyrosine kinase inhibits the Ras/MAPK pathway

Interactions between Eph receptor tyrosine kinases (RTKs) and membrane-anchored ephrin ligands critically regulate axon pathfinding and development of the cardiovascular system, as well as migration of neural cells. Similar to other RTKs, ligand-activated Eph kinases recruit multiple signalling and adaptor proteins, several of which are involved in growth regulation. However, in contrast to other RTKs, activation of Eph receptors fails to promote cell proliferation or to transform rodent fibroblasts, indicating that Eph kinases may initiate signalling pathways that are distinct from those transmitted by other RTKs. Here we show that stimulation of endogenous EphA kinases with ephrin-A1 potently inhibits the Ras/MAPK cascade in a range of cell types, and attenuates activation of mitogen-activated protein kinase (MAPK) by receptors for platelet-derived growth factor (PDGF), epidermal growth factor (EGF) and vascular endothelial growth factor (VEGF). In prostatic epithelial cells and endothelial cells, but not fibroblasts, treatment with ephrin-A1 inhibits cell proliferation. Our results identify EphA kinases as negative regulators of the Ras/MAPK pathway that exert anti-mitogenic functions in a cell-type-specific manner.     

Cancer somatic mutations disrupt functions of the EphA3 receptor tyrosine kinase through multiple mechanisms

The Eph receptor tyrosine kinases make up an important family of signal transduction molecules that control many cellular processes, including cell adhesion and movement, cell shape, and cell growth. All of these are important aspects of cancer progression, but the relationship between Eph receptors and cancer is complex and not fully understood. Genetic screens of tumor specimens from cancer patients have revealed somatic mutations in many Eph receptors. The most highly mutated Eph receptor is EphA3, but its functional role in cancer is currently not well established. Here we show that many EphA3 mutations identified in lung, colorectal, and hepatocellular cancers, melanoma, and glioblastoma impair kinase activity or ephrin ligand binding and/or decrease the level of receptor cell surface localization. These results suggest that EphA3 has ephrin- and kinase-dependent tumor suppressing activities, which are disrupted by somatic cancer mutations.     

The cystine/glutamate antiporter xCT is a key regulator of EphA2 S897 phosphorylation under glucose-limited conditions

EphA2, which belongs to the Eph family of receptor tyrosine kinases, is overexpressed in a variety of human cancers. Serine 897 (S897) phosphorylation of EphA2 is known to promote cancer cell migration and proliferation in a ligand-independent manner. In this study, we show that glucose deprivation induces S897 phosphorylation of EphA2 in glioblastoma cells. The phosphorylation requires the activity of the cystine/glutamate antiporter xCT and reactive oxygen species (ROS)-dependent ERK and RSK activation. Furthermore, depletion of EphA2 in glioblastoma cells leads to decreased cell viability under glucose starvation. Our results suggest a role of EphA2 in glioblastoma cell viability under glucose-limited conditions.     

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.     

Ephrin-A1 induces c-Cbl phosphorylation and EphA receptor down-regulation in T cells

Eph receptor tyrosine kinases are expressed by T lineage cells, and stimulation with their ligands, the ephrins, has recently been shown to modulate T cell behavior. We show that ephrin-A1 stimulation of Jurkat T cells induces tyrosine phosphorylation of EphA3 receptors and cytoplasmic proteins, including the c-cbl proto-oncogene. Cbl phosphorylation was also observed in peripheral blood T cells. In contrast, stimulation of Jurkat cells with the EphB receptor ligand ephrin-B1 does not cause Cbl phosphorylation. EphA activation also induced Cbl association with Crk-L and Crk-II adapters, but not the related Grb2 protein. Induction of Cbl phosphorylation upon EphA activation appeared to be dependent upon Src family kinase activity, as Cbl phosphorylation was selectively abrogated by the Src family inhibitor 4-amino-5(4-chlorophenyl-7-(tert-butyl)pyrazolo[3,4-d]pyrimidine, while EphA phosphorylation was unimpaired. Ephrin-A1 stimulation of Jurkat cells was also found to cause down-regulation of endogenous EphA3 receptors from the cell surface and their degradation. In accordance with the role of Cbl as a negative regulator of receptor tyrosine kinases, overexpression of wild-type Cbl, but not its 70-Z mutant, was found to down-regulate EphA receptor expression. Receptor down-regulation could also be inhibited by blockage of Src family kinase activity. Our findings show that EphA receptors can actively signal in T cells, and that Cbl performs multiple roles in this signaling pathway, functioning to transduce signals from the receptors as well as regulating activated EphA receptor expression.     

Parcellation of the thalamus into distinct nuclei reflects EphA expression and function

Intercellular signaling via the Eph receptor tyrosine kinases and their ligands, the ephrins, acts to shape many regions of the developing brain. One intriguing consequence of Eph signaling is the control of mixing between discrete cell populations in the developing hindbrain, contributing to the formation of segregated rhombomeres. Since the thalamus is also a parcellated structure comprised of discrete nuclei, might Eph signaling play a parallel role in cell segregation in this brain structure? Analyses of expression reveal that several Eph family members are expressed in the forming thalamus and that cells expressing particular receptors form cellular groupings as development proceeds. Specifically, expression of receptors EphA4 or EphA7 and ligand ephrin-A5 is localized to distinct thalamic domains. EphA4 and EphA7 are often coexpressed in regions of the forming thalamus, with each receptor marking discrete thalamic domains. In contrast, ephrin-A5 is expressed by a limited group of thalamic cells. Within the ventral thalamus, EphA4 is present broadly, occasionally overlapping with ephrin-A5 expression. EphA7 is more restricted in its expression and is largely nonoverlapping with ephrin-A5. In mutant mice lacking one or both receptors or ephrin-A5, the appearance of the venteroposterolateral (VPL) and venteroposteromedial (VPM) nuclear complex is altered compared to wild type mice. These in vivo results support a role for Eph family members in the definition of the thalamic nuclei. In parallel, in vitro analysis reveals a hierarchy of mixing among cells expressing ephrin-A5 with cells expressing EphA4 alone, EphA4 and EphA7 together, or EphA7 alone. Together, these data support a model in which EphA molecules promote the parcellation of discrete thalamic nuclei by limiting the extent of cell mixing.     

SASH1: A Novel Eph Receptor Partner and Insights into SAM-SAM Interactions

The Eph (erythropoietin-producing human hepatocellular) receptor family, the largest subclass of receptor tyrosine kinases (RTKs), plays essential roles in embryonic development and neurogenesis. The intracellular Sterile Alpha Motif (SAM) domain presents a critical structural feature that distinguishes Eph receptors from other RTKs and participates in recruiting and binding downstream molecules. This study identified SASH1 (SAM and SH3 domain containing 1) as a novel Eph receptor-binding partner through SAM-SAM domain interactions. Our comprehensive biochemical analyses revealed that SASH1 selectively interacts with Eph receptors via its SAM1 domain, displaying the highest affinity for EphA8. The high-resolution crystal structure of the EphA8-SASH1 complex provided insights into the specific intermolecular interactions between these proteins. Cellular assays confirmed that EphA8 and SASH1 co-localize and co-precipitate in mammalian cells, with cancer mutations (EphA8 R942H or G978D) impairing this interaction. We demonstrated that SAM-SAM interaction is critical for SASH1-mediated regulation of EphA8 kinase activity, shedding new light on the Eph signaling pathway and expanding our understanding of the molecular basis of the tumor suppressor gene SASH1.