经典Wnt信号通路在牙齿发育中的研究新进展

经典Wnt信号通路是参与胚胎及器官发育的四大信号传导途径之一,在牙齿发育中扮演了重要的角色。本文对其中的β-catenin,Left,Ape,Axin2这4个关键因子在牙齿发育中研究的新进展做了简要的概述：β-catenin在间充质中会调控多个信号,影响牙上皮和间充质相互作用;Left会和Tcf家族一道调控上皮细胞命运;Ape能抑制多余牙齿的形成;Axin2在牙晚期发育中影响牙本质的形成。通过这些因子的研究,希望人们能在牙齿再生等生物医学工程上有新的突破。     

Wnt/β-catenin信号通路与肝癌

肝细胞癌是常见的恶性肿瘤,其发病机制尚未完全明确。Wnt信号通路与人体内多种病理生理过程相关,其中肝癌的发生、发展可能与经典的Wnt/β-catenin信号通路密切相关。Wnt/β-catein信号通路通过表达癌症相关基因、激活肝星状细胞、调控肝干细胞行为、促进肝癌细胞侵袭转移等方式调控肝癌的发生、发展。Wnt/β-catein信号通路在肝癌发生、发展中的作用有望为肝癌研究提供新的思路。     

经典Wnt 信号通路在牙齿发育中的研究新进展

经典Wnt信号通路是参与胚胎及器官发育的四大信号传导途径之一,在牙齿发育中扮演了重要的角色。本文对其中的β-catenin,Lef1,Apc,Axin2这4个关键因子在牙齿发育中研究的新进展做了简要的概述:β-catenin在间充质中会调控多个信号,影响牙上皮和间充质相互作用;Lef1会和Tcf家族一道调控上皮细胞命运;Apc能抑制多余牙齿的形成;Axin2在牙晚期发育中影响牙本质的形成。通过这些因子的研究,希望人们能在牙齿再生等生物医学工程上有新的突破。     

Wnt/β-catenin信号通路与干细胞衰老

Wnt/β-catenin信号通路作为一条进化保守的信号通路,有着广泛的生物学作用。研究发现,Wnt/β-catenin信号通路与干细胞衰老之间存在联系。激活Wnt/β-catenin信号通路可导致干细胞发生衰老变化,而抑制Wnt/β-catenin信号通路可延缓干细胞的衰老。本文对Wnt/β-catenin信号通路与干细胞衰老之间的关系及其作用机制作一综述。     

Kindlin家族调控Wnt/β-catenin信号通路的研究进展

Kindlin家族属于新型的局灶性黏附蛋白家族,是由三个进化上具有高度保守性和同源性的蛋白质(Kindlin-1、2和3)组成,在整合素调节、细胞基质黏附和信号转导中发挥重要作用。尽管由三个不同的基因编码,Kindlin家族成员有相似的结构和序列,在C端均含有1个FERM结构域。Wnt/β-catenin信号通路是生物体中普遍存在的调节细胞增殖和细胞分化的重要信号通路之一,在生长发育等生理过程和肿瘤等病理过程中发挥着重要作用。越来越多研究显示,Kindlin家族成员通过调控Wnt/β-catenin信号通路参与包括肿瘤在内的许多疾病的发生和发展过程。因此,该文围绕Kindlin家族的结构、主要功能以及调控Wnt/β-catenin信号通路等方面的研究进展进行综述。     

BATF2对Wnt信号通路影响的研究

摘要wnt信号通路在各种生物体内高度进化保守,与癌症的发生发展密切相关。BATF2是一个新近发现的基因,研究表明其具有抑癌基因的作用。目前,BATF2与wnt信号通路的关系尚不清楚,该文用荧光素酶报告基因检测、Real－timePCR和Western blot发现BATF2能影响wnt信号通路。过表达BArF2可明显下调TCF4／p－catenin的转录活性和Wnt信号通路下游基因的表达,可以下调细胞核中的β-caenin。推测BATF2可能通过下调细胞核中的p－catenin来实现对wnt信号通路的下调。上述结果为抑制Wnt信号通路用于肿瘤治疗提供了一定的依据。     

Wnt/β-catenin信号通路在宫颈癌形成中的作用机制

<正>宫颈癌是常见妇科恶性肿瘤之一,发病率居妇科恶性肿瘤前列,严重威胁女性的健康与生命安全。在全球女性中,宫颈癌为第三大常见肿瘤,是导致肿瘤相关死亡的第四大病因。据最新统计显示,宫颈癌每年新发生病例约52万,死亡病例约28万,其中86%发生在发展中国家[1]。我国每年新发生病例约14万,并逐渐呈年轻化及上升趋势[2]。随着分子生物学方法在肿瘤发生发展研究中的应用,越来越多的基因和信号通路被证明与肿瘤的形成相关,其中Wnt/β-catenin     

经典WNT信号通路与哺乳动物肺器官发育

肺器官发育是上皮和问充质相互作用的过程,由多条信号通路共同调控。已知经典WNT信号通路对细胞的增殖、凋亡和分化起着重要的调控作用,在小鼠等模式生物上研究发现,它也参与了哺乳动物肺器官发育的调控过程。综述近年来经典WNT信号通路成员在哺乳动物肺器官发育过程中的表达变化、作用功能及表达异常可能诱发的肺部疾病,以期为研究经典WNT信号通路调控人类肺器官发育的分子机制及相关肺部疾病的诊治奠定基础。     

Wnt信号通路与神经干细胞

神经干细胞增殖、分化机制的研究为神经系统疾病治疗提供了新的途径,具有巨大的潜在应用价值和理论研究意义。业已发现,Wnt信号通路对神经干细胞的增殖发挥着决定性作用,但新近的研究却表明Wnt信号能够明显促进神经干细胞向神经元分化,这种不同的表现可能与神经干细胞的内在特点、周围环境及靶基因的不同有关。本文试从Wnt信号通路及其在调控神经干细胞的增殖、分化中的作用加以综述。     

Regulation of beta-catenin signaling in the Wnt pathway

beta-Catenin not only regulates cell to cell adhesion as a protein interacting with cadherin, but also functions as a component of the Wnt signaling pathway. The Wnt signaling pathway is conserved in various organisms from worms to mammals, and plays important roles in development, cellular proliferation, and differentiation. Wnt stabilizes cytoplasmic beta-catenin and then beta-catenin is translocated into the nucleus where it stimulates the expression of genes including c-myc, c-jun, fra-1, and cyclin D1. The amounts and functions of beta-catenin are regulated in both the cytoplasm and nucleus. Its molecular mechanisms are becoming increasingly well understood.     

Wnt signaling and dorso-ventral axis specification in vertebrates.

The dorso-ventral axis is specified in vertebrates through the formation of a dorsal signaling center known as the Spemann organizer. This process depends on signal transduction by beta-catenin that can be regulated by secreted Wnt proteins. Recent discoveries of new players in this signaling pathway have narrowed down the search for the initial cues for axis specification in vertebrate embryos.     

The canonical Wnt pathway in embryonic axis polarity

The canonical Wnt pathway plays crucial roles in multiple developmental processes, including in axis specification. Throughout the animal kingdom, this pathway has been reported to drive patterning of axes as different as the animal-vegetal axis in echinoderms to the dorsal-ventral axis in vertebrates. Intriguingly enough, this pathway appears structurally and functionally well conserved during evolution. However, differences between these phyla are observed that explain how a same pathway can mediate establishment of two such apparently distinct axes. This review compares the axis specification processes used in two evolutionarily distant embryos, the sea urchin and Xenopus.     

初级纤毛与Wnt信号通路相关性研究进展

初级纤毛是一类以微管为基础结构的细胞器,其来源于细胞的母中心粒,锚定在细胞膜并如“天线”般突出细胞表面。作为细胞感受器,初级纤毛从环境中接受各种信号,传导至细胞内引起细胞反应。近期的研究表明,初级纤毛对与胚胎发育密切相关的Wnt信号通路的传导起重要作用。纤毛的损害可造成Wnt信号通路的异常,并引起胚胎中多类脏器一系列的病理改变,导致初级纤毛相关疾病的发生。文章主要阐述了初级纤毛与Wnt/β-catenin、Wnt/PCP通路及初级纤毛相关疾病之间的关系,并对初级纤毛相关疾病的治疗进行了初步探讨。对初级纤毛与Wnt信号通路关系的深入研究将有助于人们对该类疾病的进一步诊断和治疗。     

Multiple mechanisms for Wnt11-mediated repression of the canonical Wnt signaling pathway

The effect of a noncanonical Wnt, Wnt11, on canonical Wnt signaling stimulated by Wnt1 and activated forms of LRP5 (low density lipoprotein receptor-related protein-5), Dishevelled1 (Dvl1), and beta-catenin was examined in NIH3T3 cells and P19 embryonic carcinoma cells. Wnt11 repressed Wnt1-mediated activation of LEF-1 reporter activity in both cell lines. However, Wnt11 was unable to inhibit canonical signaling activated by LRP5, Dvl1, or beta-catenin in NIH3T3 cells, although it could in P19 cells. In addition, Wnt11-mediated inhibition of canonical signaling in NIH3T3 cells is ligand-specific; Wnt11 could effectively repress canonical signaling activated by Wnt1, Wnt3, or Wnt3a but not by Wnt7a or Wnt7b. Co-culture experiments with NIH3T3 cells showed that the co-expression of Wnt11 with Wnt1 was not an essential requirement for the inhibition, suggesting receptor competition as a possible mechanism. Moreover, in both cell types, elevation of intracellular Ca(2+) levels, which can result from Wnt11 treatment, led to the inhibition of canonical signaling. This result suggests that Wnt11 might not be able to signal in NIH3T3. Furthermore, P19 cells were found to express both endogenous canonical Wnts and Wnt11. Knockdown of Wnt11 expression using siRNA resulted in increased LEF-1 reporter activity, thus indicating that Wnt11-mediated suppression of canonical signaling exists in vivo.     

The Wnt signaling pathway in retinal degenerations

The retina is a complex tissue composed of multiple interconnected cell layers, highly specialized for transforming light and color into electrical signals perceived by the brain. Damage or death of the primary light-sensing cells, the photoreceptors, results in devastating effects on vision. Despite the identification of numerous mutations that cause inherited retinal degenerations, the cellular and molecular mechanisms leading from the primary mutations to photoreceptor apoptosis are not understood. Wnt signaling has essential regulatory functions in a wide variety of critical developmental processes. Our research and others' have suggested that the Wnt pathway may be involved in retinal degeneration. Wnt ligands regulate developmental death of Drosophila photoreceptors, dysregulated Wnt signaling is involved in neuronal degeneration elsewhere in the central nervous system and Wnts control the expression of pro-survival growth factors in mammalian tissues. Additionally, altered expression of Wnt pathway genes, including the anti-apoptotic Wnt signaling regulator Dickkopf 3 (Dkk3), were observed during photoreceptor loss. This review examines the evidence and develops a model proposing a pro-survival role for Wnt signaling during photoreceptor injury. Because manipulating Wnt signaling has been demonstrated to have therapeutic potential for the treatment of Alzheimers disease, understanding the involvement of Wnts in photoreceptor death will determine whether targeting the Wnt pathway should also be considered as a possible therapeutic strategy for retinal degenerations.