上皮细胞向间充质细胞转变在肝癌进程中的作用

上皮细胞向间充质细胞转变(epithelial to mesenchymal transition,EMT)是细胞通过瞬时去分化为间充质表型,导致上皮细胞的可塑性发生变化的多步骤的生物学过程。EMT及其逆转MET多数发生在胚胎发生形态发生过程中。近期更多的证据显示EMT参与肝纤维化和肝癌进程。在肝癌转移的早期阶段,细胞由于E-钙粘蛋白的消融而丧失细胞-细胞接触抑制,迁移能力增强,得以扩散到周围或远处组织,故EMT在肝癌转移的早期阶段中起关键作用。此外,由于EMT的增强诱导剂如转移生长因子(transforming growth factor-β,TGF-β)具有协调肝纤维化及肝癌进程的作用,故肝癌进程中上皮细胞的可塑性研究显得尤为重要。在本综述中,作者将阐述EMT-MET在肝癌进程中的重要性,及EMT在肝癌进程中的作用机制。同时,概述最近在识别影响重要EMT转录因子的临床诊治方面取得的进展。     

Tbx18通过下调EMT信号分子参与调控心脏发育

转录因子Tbx18(Tbx18)在小鼠胚胎心外膜上皮细胞表达并调控心外膜上皮细胞向心系细胞分化.上皮间充质转化(EMT)过程是器官发育和形成的重要机制.为阐述Tbx18通过调控下游EMT关键信号分子参与心外膜上皮细胞分化和心脏发育,本研究运用Tbx18-Cre/Rosa26R-EYFP双杂合基因敲入小鼠和免疫荧光共聚焦,证实Tbx18+心系细胞和EMT关键信号分子Snail1、Smad、Slug、Twist在发育后期胚鼠心外膜和心外膜下间充质发生共聚焦.同时还发现,Tbx18在胚鼠不同发育阶段的表达模式和Tbx18+心系细胞内上述EMT关键信号分子的表达模式相似.Tbx18和EMT关键信号分子在发育心脏存在相似的时空表达模式,因此,它们之间可能存在相互调控作用.运用Tbx18突变技术揭示了Tbx18突变型胚鼠心脏EMT关键信号分子表达水平均较野生型显著下调,直接证实了上述4个EMT信号分子是Tbx18的可能靶点.理解Tbx18参与心脏发育的下游靶点有助于改善成年心脏损伤后的再生修复.     

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.     

心脏发育过程中的细胞命运转变及命运决定

胚胎发育过程中,心脏发生起源于生心中胚层(cardiac mesoderm)。在小鼠早期胚胎(E6.5),上胚体(epiblast)在低浓度Nodal诱导下, Eomes出现并激活Mesp1表达。Mesp1作为主调控者(master regulator),激活一系列生心关键转录因子及生心特异基因的表达,促进生心祖细胞的特化及生心区(cardiac field)的形成。之后的心脏形态发生涉及细胞命运的转变,包括流出道分隔过程中神经嵴细胞向间充质细胞转变、内皮细胞向间充质转变及房室通道发育过程中的内皮细胞向间充质转变。最新的研究表明,流出道在分隔成为主动脉和肺动脉根部之前,其中的细胞命运已经被预先设定。此综述文章重点探讨生心祖细胞特化、细胞命运转变与命运预先设定等方面的新进展,调控机制及争议问题。     

利用胚胎干细胞分化的拟胚体研究小鼠早期胚胎发育过程

小鼠胚胎干细胞(ES细胞)具有分化的全能性已经得到广泛共识。ES细胞在体外分化所形成的拟胚体在结构上能够模仿早期胚胎发育过程,包括在内细胞团表面形成内胚层、柱状上皮细胞的分化,以及中央空腔的形成。本文介绍利用拟胚体研究小鼠早期胚胎发育过程中各个胚胎阶段的发育、细胞程序性死亡的发生及TGF-β信号在胚胎发育过程中的作用。     

氧对滋养细胞侵入的调节作用

胚胎在子宫内的植入过程包括粘附、迁移和侵入等步骤 ,其中源自胚胎滋养外胚层的绒毛外滋养层细胞对子宫基质的合理侵入 ,是决定能否正常妊娠的关键。人类胚胎植入部位及胎盘组织内氧含量的变化持续从受孕至分娩的全过程 ,在此期间与滋养细胞侵入相关的一些指标随氧环境的变化而改变 ,提示氧对滋养细胞的侵入过程起一定调节作用。1.早孕组织的氧含量变化在人类胎盘发育的早期 ,来自胚泡的滋养细胞突破子宫上皮细胞及其基底膜 ,侵入下层的子宫基质 ,逐步形成绒毛。根据其位置及功能的不同 ,绒毛可分为漂浮绒毛和固定绒毛两种 ,前者负责胚胎与…     

蛋白激酶H11基因在小鼠子宫中的表达及其性激素调节

为研究蛋白激酶H11基因在生殖系统中的作用,我们采用半定量RT-PCR和原位杂交方法,研究了蛋白激酶H11基因在小鼠中的组织特异性表达,在妊娠初始期胚胎植入位点、妊娠期子宫和胎盘以及正常动情周期子宫中的表达及其受性激素的调节。结果发现:蛋白激酶H11基因在小鼠多种组织中都有表达,在卵巢及子宫等一些生殖相关的组织中表达水平较高;妊娠初始期,蛋白激酶H11基因在小鼠子宫内膜植入位点处有明显的高表达,其mRNA定位于腔上皮细胞和基质细胞中。在动情周期中,蛋白激酶H11基因在动情前期子宫中表达水平较低;卵巢切除模型显示雌激素和孕激素均可显著上调蛋白激酶H11基因的表达。以上结果提示蛋白激酶H11可能参与了胚胎植入过程中腔上皮细胞凋亡和基质细胞增殖与蜕膜化以及动情周期小鼠子宫内膜细胞的功能调节[动物学报51(3):462-468,2005]。     

谷胱甘肽-硫-转移酶M2基因在小鼠生殖器官中的表达

利用半定量RT-PCR和原位杂交的方法检测Gstm2基因在成年雄性和雌性小鼠生殖器官中的表达,并初步评价其在生殖过程中的作用。在雄性小鼠的睾丸、附睾、输精管和雌性小鼠的卵巢、输卵管、子宫、胎盘中,半定量RT-PCR的方法均检测到Gstm2的表达,在胎盘中表达水平较低,其余组织表达水平较高。利用原位杂交的方法在睾丸的间质细胞检测出较强的信号,在附睾中有微弱的信号,而输精管上皮细胞没有检测到信号;在输卵管上皮细胞和妊娠第3d的子宫上皮细胞中检出较强的信号。由于Gstm2在RNA水平在小鼠的生殖器官中广泛表达,因此我们推测Gstm2可能在小鼠精子发生、睾酮合成、精子的成熟和运输、卵子的发生和运输、胚胎着床等生殖过程中发挥作用,此结果为深入研究Gstm2在生殖生理中的功能打下基础。     

胚胎肾分支形态发生调控因素

胚胎肾发育最初阶段是中肾导管尾端在胶质细胞源性神经营养因子诱导下向背侧长出输尿管芽,而后成纤维细胞生长因子、肝细胞生长因子、骨形成蛋白、基质金属蛋白酶、整合素和粘附分子相继表达,作用于输尿管芽和间充质细胞,诱导分支形态发生,包括输尿管芽向间充质侵入、延伸以及间充质细胞向上皮转化。上述这些分子在功能上存在部分重叠与拮抗,维持细胞增殖和分化的平衡,从而保证输尿管芽形成正常的分支结构。本文对肾脏发育时期分支形态发生的调控因素进行综述。     

沉默PPP3CA对后肾间充质细胞MET转化、凋亡、增殖及迁移的影响

肾脏是人体重要器官,肾脏发育对肾脏的形成和功能至关重要,其中后肾间充质细胞 (Metanephric mesenchyme,MM) 间质-上皮转化 (Mesenchymal-epithelial transition,MET) 是肾单位形成的关键环节。qRT-PCR和Western blotting实验检测蛋白质磷酸酶3催化亚基α (Protein phosphatase 3 catalytic subunit alpha,PPP3CA) 在不同状态MM细胞株mK3、mK4中的表达谱及对MET标志蛋白调控作用;采用慢病毒包装方式构建稳定敲低PPP3CA的mK4细胞株;采用CCK-8、EdU实验、细胞划痕实验、流式细胞技术分别检测PPP3CA对上皮样后肾间充质细胞株mK4细胞生长、迁移、凋亡的调控作用。PPP3CA在mK4细胞中表达量较间质样后肾间充质细胞mK3更高,敲低PPP3CA后,检测MET标志物及细胞生物学行为,结果显示敲低PPP3CA显著上调上皮细胞标志物E-cadherin表达,促进MET过程,且促进细胞凋亡,抑制细胞增殖和迁移。此外,敲低PPP3CA促进ERK1/2磷酸化,提示PPP3CA生物学功能的调控机制可能与其去磷酸化ERK1/2蛋白相关。以上结果提示PPP3CA在MM细胞MET转化和生物学行为调节中发挥重要功能,为发现和解析肾发育过程中潜在的关键调节因子提供了新的理论基础。     

Reprogramming during epithelial to mesenchymal transition under the control of TGFβ

Epithelial-mesenchymal transition (EMT) refers to plastic changes in epithelial tissue architecture. Breast cancer stromal cells provide secreted molecules, such as transforming growth factor β (TGFβ), that promote EMT on tumor cells to facilitate breast cancer cell invasion, stemness and metastasis. TGFβ signaling is considered to be abnormal in the context of cancer development; however, TGFβ acting on breast cancer EMT resembles physiological signaling during embryonic development, when EMT generates or patterns new tissues. Interestingly, while EMT promotes metastatic fate, successful metastatic colonization seems to require the inverse process of mesenchymal-epithelial transition (MET). EMT and MET are interconnected in a time-dependent and tissue context-dependent manner and are coordinated by TGFβ, other extracellular proteins, intracellular signaling cascades, non-coding RNAs and chromatin-based molecular alterations. Research on breast cancer EMT/MET aims at delivering biomolecules that can be used diagnostically in cancer pathology and possibly provide ideas for how to improve breast cancer therapy.     

Reprogramming during epithelial to mesenchymal transition under the control of TGFβ

Epithelial-mesenchymal transition (EMT) refers to plastic changes in epithelial tissue architecture. Breast cancer stromal cells provide secreted molecules, such as transforming growth factor β (TGFβ), that promote EMT on tumor cells to facilitate breast cancer cell invasion, stemness and metastasis. TGFβ signaling is considered to be abnormal in the context of cancer development; however, TGFβ acting on breast cancer EMT resembles physiological signaling during embryonic development, when EMT generates or patterns new tissues. Interestingly, while EMT promotes metastatic fate, successful metastatic colonization seems to require the inverse process of mesenchymal-epithelial transition (MET). EMT and MET are interconnected in a time-dependent and tissue context-dependent manner and are coordinated by TGFβ, other extracellular proteins, intracellular signaling cascades, non-coding RNAs and chromatin-based molecular alterations. Research on breast cancer EMT/MET aims at delivering biomolecules that can be used diagnostically in cancer pathology and possibly provide ideas for how to improve breast cancer therapy.     

Modulation of the EMT/MET process by pyrrole–imidazole polyamide targeting human transforming growth factor-β1

Transforming growth factor-β1 (TGF-β1) is a potent induction factor for epithelial–mesenchymal transition (EMT). Mesenchymal–epithelial transition (MET), as the inverse process of EMT, has recently been reported to promote the induction of induced pluripotent stem cells (iPSCs). We have developed pyrrole–imidazole (PI) polyamide, a novel gene regulator that targets human TGF-β1, and investigated its effects on the EMT/MET process. PI polyamide targeted to TGF-β1 significantly inhibited the mRNA expression of TGF-β1 and SNAI1 as an EMT marker and increased mRNA and protein expression of E-cadherin in human epithelial cells. To enhance the induction of iPSCs by the MET process, PI polyamide targeted to TGF-β1 was applied to human fibroblasts transfected with exogenous reprogramming factors by Sendai virus vector and grown in human iPSCs. The PI polyamide significantly increased the number of alkaline phosphatase-positive colonies. The expression of undifferentiated markers was also observed in these colonies. These results suggest that PI polyamide targeted to human TGF-β is a novel compound that can control the EMT/MET process of human epithelial cells and enhance the induction of human fibroblasts to iPSCs.     

Epithelial-Mesenchymal Transition in Cancer: A Historical Overview

Epithelial-mesenchymal transitions (EMTs), the acquisition of mesenchymal features from epithelial cells, occur during some biological processes and are classified into three types: the first type occurs during embryonic development, the second type is associated with adult tissue regeneration, and the third type occurs in cancer progression. EMT occurring during embryonic development in gastrulation, renal development, and the origin and fate of the neural crest is a highly regulated process, while EMT occurring during tumor progression is highly deregulated. EMT allows the solid tumors to become more malignant, increasing their invasiveness and metastatic activity. Secondary tumors frequently maintain the typical histologic characteristics of the primary tumor. These histologic features connecting the secondary metastatic tumors to the primary is due to a process called mesenchymal-epithelial transition (MET). MET has been demonstrated in different mesenchymal tumors and is the expression of the reversibility of EMT. EMT modulation could constitute an approach to avoid metastasis. Some of the targeted small molecules utilized as antiproliferative agents have revealed to inhibit EMT initiation or maintenance because EMT is regulated through signaling pathways for which these molecules have been designed.     

上皮间质转化与干细胞自我更新和分化

上皮间质转化(epithelial-mesenchymal transition,EMT)是指上皮细胞失去连接和极性转变为间质细胞的过程,这一现象普遍存在于胚胎发育、创伤愈合、器官纤维化以及肿瘤转移.在胚胎早期发育和晚期发育过程,例如着床、原肠运动、心血管发育等事件中有EMT和间质上皮转化(mesenchymal-ep...     

Epithelial--mesenchymal and mesenchymal--epithelial transitions in carcinoma progression

Like a set of bookends, cellular, molecular, and genetic changes of the beginnings of life mirror those of one of the most common cause of death--metastatic cancer. Epithelial to mesenchymal transition (EMT) is an important change in cell phenotype which allows the escape of epithelial cells from the structural constraints imposed by tissue architecture, and was first recognized by Elizabeth Hay in the early to mid 1980's to be a central process in early embryonic morphogenesis. Reversals of these changes, termed mesenchymal to epithelial transitions (METs), also occur and are important in tissue construction in normal development. Over the last decade, evidence has mounted for EMT as the means through which solid tissue epithelial cancers invade and metastasize. However, demonstrating this potentially rapid and transient process in vivo has proven difficult and data connecting the relevance of this process to tumor progression is still somewhat limited and controversial. Evidence for an important role of MET in the development of clinically overt metastases is starting to accumulate, and model systems have been developed. This review details recent advances in the knowledge of EMT as it occurs in breast development and carcinoma and prostate cancer progression, and highlights the role that MET plays in cancer metastasis. Finally, perspectives from a clinical and translational viewpoint are discussed.