miRiad roles for the miR-17-92 cluster in development and disease

MicroRNAs (miRNAs) encoded by the miR-17-92 cluster and its paralogs are known to act as oncogenes. Expression of these miRNAs promotes cell proliferation, suppresses apoptosis of cancer cells, and induces tumor angiogenesis. New work reveals essential functions for these miRNAs not only in tumor formation but also during normal development of the heart, lungs, and immune system.     

miR-17-92基因簇microRNAs对哺乳动物器官发育及肿瘤发生的调控

microRNAs(miRNAs)是近年发现的一种高度保守的非编码小RNA, 它们通过抑制靶基因mRNA的翻译或将其降解, 在转录后水平调控基因的表达, 参与调控哺乳动物多个器官的发育过程和人类疾病的发生。miR-17-92基因簇是一个高度保守的基因簇, 编码miR-17-5p、miR-17-3p、miR-18a、miR-19a、miR-20a、miR-19b-1和miR-92-1等7个miRNAs。大量证据表明, miR-17-92基因簇miRNAs参与了心、肺、免疫系统的发育、血管生长及前脂肪细胞的分化等过程。此外, miR-17-92基因簇miRNAs在多种肿瘤中高表达, 能作为致癌基因诱发淋巴瘤和血管化肿瘤的发生, 但它也可以作为抑癌基因抑制乳腺癌细胞的增殖。文章对miR-17-92基因簇miRNAs在哺乳动物器官发育及肿瘤发生中的作用进行综述     

鸡miR-17-92基因簇上游调控区功能分析

miR-17-92基因簇(miR-17-92 cluster)在细胞增殖、分化、凋亡、动物发育以及肿瘤发生等过程中发挥重要作用。目前,人和小鼠等哺乳动物miR-17-92基因簇的转录调控已有深入研究,但该基因簇在鸡等鸟类中的转录调控研究还未见报道,主要原因在于鸟类miR-17-92基因簇上游的基因组序列都存在一个gap,且该基因簇启动子的位置和序列也还不清楚。为此,本研究采用染色体步移的方法获得鸡miR-17-92基因簇上游gap区序列,并采用生物信息学分析和报告基因及截短突变技术开展该gap区的功能分析。染色体步移分析发现,鸡miR-17-92基因簇上游gap区全长1704 bp,GC含量达80.11%。生物信息学分析显示,鸡miR-17-92基因簇上游gap区内1段200 bp的序列与人、牛、小鼠等9种动物miR-17-92基因簇上游序列保守性较高,且该区域为人和小鼠等哺乳动物miR-17-92基因簇宿主基因的核心启动子区。将克隆的gap区序列插入pGL3 basic荧光素酶报告基因载体,构建成启动子荧光素酶报告基因载体pGL3-cMIR17HG(-4228/-2506)。荧光素酶报告基因活性分析表明,pGL3-cMIR17HG(-4228/-2506)报告基因的活性是pGL3 basic空载体活性的417倍,证明所克隆的gap区片段是鸡miR-17-92基因簇宿主基因的启动子。为进一步分析该启动子的结构和功能,构建gap区片段的5°端缺失突变(缺失448 bp)和3°端缺失突变(缺失894 bp)的荧光素酶报告基因载体。与pGL3-cMIR17HG(-4228/-2506)相比,5°端和3°端缺失突变分别使启动子报告基因活性降低19.82%和60.14%。这些数据提示,鸡miR-17-92基因簇宿主基因启动子的重要调控区位于-3400/-2506。本研究结果为进一步开展鸡miR-17-92基因簇的转录调控奠定了基础。     

Mapping and expression studies of the mir17-92 cluster on pig Chromosome 11

We have identified the first porcine microRNA (miRNA) cluster (the mir17-92 cluster) and localized it to the q-arm of pig Chromosome 11. The miRNA cluster was found by sequence similarity search with human miRNA sequences against the pig genomic data generated within the Sino-Danish pig genome project. The resulting data contained three complete and two incomplete miRNA precursors of seven miRNAs from the human mir17-92 cluster. Because there is a 100% sequence identity between the four pig miRNAs and the corresponding human miRNAs, the sequences of three unavailable pig miRNAs were derived from the human data. The expression profiles of seven studied miRNAs were analyzed by hybridization to Northern blots containing five porcine tissues: cerebellum, cortex, hippocampus, kidney, and liver. In order to determine the localization of the mir17-92 cluster in the pig genome, we mapped it by PCR in the porcine somatic cell hybrid (SCH) panel and in the INRA-University of Minnesota (INRA-UMN) porcine radiation hybrid (IMpRH) panel. The PCR results enabled us to localize this cluster to the q-arm of pig Chromosome 11 and map it in relation to two microsatellites. Our study presents the first expression analyses of miRNAs in pig and adds information for further functional studies in this species.     

鸡mir-17-92基因簇的结构、功能及其调控

mir-17-92基因簇(mir-17-92 cluster)是脊椎动物的一个保守miRNA基因簇,在哺乳动物细胞增殖、分化、凋亡及发育等多种生物学过程中起重要的调控作用.同时,mir- 17-92基因簇又是一个癌基因,在多种肿瘤中表达.尽管对mir-17-92基因簇的研究非常广泛,但其作用机制还不完全清楚.鸡mir- 17-92基因簇的结构组成特点、功能及其作用机制尚未见研究报道.该文根据同一miRNA基因簇的miRNAs在功能上相关的特点,以鸡mir- 17-92基因簇序列为研究对象,采用生物信息学研究方法和手段,开展了鸡mir- 17-92基因簇的基因组结构、miRNAs序列组成、靶生物学过程和信号通路以及miRNAs结合位点分布特点等分析研究.结果发现,鸡mir- 17-92基因簇调控MAPK、Wnt和TGF-β等多个重要细胞信号通路;miRNA结合位点分布分析显示,该miRNA基因簇多个成员共同作用于同一个靶基因,提示该基因簇的miRNAs成员以组合和协同的方式调控靶基因.该研究为深入了解mir-17-92基因簇如何调控癌症和发育中的关键细胞过程奠定了基础.     

MicroRNA-17-92与肿瘤

microRNA是一类在生物体中广泛表达的、非编码调节性小分子RNA(约22～24nt).它们一经问世,即被发现参与多种疾病的发生.miR-17-92及其旁系同源序列就是其中之一,它们已被证实在肺、心脏及免疫系统的正常发育及肿瘤形成中均起到重要作用.本文从miR-17-92及其旁系同源序列在不同肿瘤组织中的表达及其在肿瘤发生中的分子机制,对这一基因簇与肿瘤发生的关系进行综述.     

鸡miR-17-92基因簇靶基因ZFPM2的鉴定及功能分析

miR-17-92基因簇在哺乳动物的许多生理和病理过程中发挥重要作用。本实验室前期研究发现,miR-17-92基因簇促进鸡前脂肪细胞的增殖,但其作用机制尚不清楚。为了揭示miR-17-92基因簇促进鸡前脂肪细胞增殖的作用机制,本研究采用CCK-8细胞增殖检测方法分析干扰ZFPM2对前脂肪细胞的影响,结果发现,干扰ZFPM2能显著促进鸡前脂肪细胞的增殖(P<0.01);与CCK-8分析结果相一致,干扰ZFPM2可致使细胞增殖标志基因PCNA、Ki67、Cyclin D1的mRNA表达量明显升高(P<0.01或P<0.05)。进一步对鸡ZFPM2基因进行生物信息学分析,发现该基因mRNA的3′UTR有两个区域存在miR-17-92基因簇4个成员(miR-17-5p、miR-20a、miR-19a及miR-19b)的潜在结合位点。为验证miR-17-92基因簇是否靶作用于鸡ZFPM2基因,构建了鸡ZFPM2基因3′UTR区的荧光素酶报告基因载体(野生型)(psi-CHECK2-ZFPM2-3′UTR-WT)及其突变型的荧光素酶报告基因载体(psi-CHECK2-ZFPM2-3′UTR-MUT)。报告基因活性分析显示,过表达mi-17-92基因簇能极显著地抑制野生型ZFPM2的报告基因活性(P<0.01);转染miR-17-5p、miR-20a及miR-19a的抑制剂均能显著地提高野生型ZFPM2报告基因的活性(P<0.01或 P<0.05),但这些抑制剂对突变型ZFPM2报告基因的活性无明显影响。qRT-PCR分析发现,miR-17-5p、miR-19a及miR-20a的抑制剂能显著提高内源性ZFPM2基因mRNA的表达水平(P<0.01或P<0.05)。共转染分析发现,尽管差异不显著,但miR-17-5p和miR-19a的抑制剂均倾向于降低ZFPM2干扰片段的促细胞增殖作用。本研究结果表明：miR-17-92基因簇成员miR-17-5p、miR-20a、miR-19a及miR-19b靶作用于ZFPM2;miR-17-92基因簇至少部分通过抑制ZFPM2基因表达从而促进鸡前脂肪细胞的增殖。     

Expression of members of the Fgf family and their receptors during midfacial development

Members of the FGF family play diverse roles in patterning, cell proliferation and differentiation during embryogenesis. To begin to address their function during craniofacial development we have analyzed the expression of 18 members of the Fgf family (Fgf1-15, -17, -18 and -20) and the four members of the FGF-receptor family in the prospective midfacial region between E9.5 and E11.5 by whole-mount in situ hybridization. We show that at E9.5, Fgf3, -8, -9, -10 and -17 are broadly expressed in midfacial ectoderm. Concomitant with the outgrowth of the nasal processes at E10.5, expression of Fgf3, -8, -9, -10, -15, -17 and -18 was detected in spatially restricted regions of ectoderm at the edge of the nasal pit and at the oral edge of the medial nasal process. Expression of Fgf8, Fgf9, Fgf10 and Fgf17 was still observed in these domains at E11.5. In contrast to the restricted expression patterns of the ligands, FgfR1 and FgfR2 were broadly expressed in facial mesenchyme and ectoderm, respectively, indicating a wide competence of midfacial tissue to respond to FGF signaling.     

microRNA-17 Is the Most Up-Regulated Member of the miR-17-92 Cluster during Early Colon Cancer Evolution

Deregulated microRNAs play a role in the development and progression of colon cancer, but little is known about their tissue and cell distribution in the continuum of normal mucosa through the premalignant adenoma to invasive adenocarcinoma. The aim of this study was to examine the expression pattern of the miR-17-92 cluster (miR-17, miR-18, miR-19, miR-20 and miR-92) as well as miR-21, miR-31, miR-135b, and miR-145 in early clinically diagnosed colon cancer. MicroRNAs were analysed by chromogenic in situ hybridisation in the normal-adenoma-adenocarcinoma sequence of nine adenocarcinomas developed in mucosal colon polyps. Subsequently, the expression of selected microRNAs was validated in 24 mucosal colon cancer polyps. Expression of miR-17 was confined to the epithelial cells, and the expression levels increased in the transitional zone from normal to adenomatous tissue. The miR-17-92 cluster members, miR-19b, miR-20a, and miR-92a, followed the same expression pattern, but miR-17 was the most predominant. An increased expression of miR-21 was found in the tumour-associated stroma with the most dramatic increase from adenoma to adenocarcinoma, while the number of positive miR-145 fibroblast-like cells in the normal lamina propria (stroma) decreased in a stepwise manner throughout the normal-adenoma-adenocarcinoma sequence. It is concluded that the expression of miR-17, miR-21, and miR-145 changes at early stages of the normal-adenoma-adenocarcinoma sequence. Thus, these microRNAs may play a role in the development of colon cancer.     

Targeted deletion reveals essential and overlapping functions of the miR-17 through 92 family of miRNA clusters

miR-17 approximately 92, miR-106b approximately 25, and miR-106a approximately 363 belong to a family of highly conserved miRNA clusters. Amplification and overexpression of miR-1792 is observed in human cancers, and its oncogenic properties have been confirmed in a mouse model of B cell lymphoma. Here we show that mice deficient for miR-17 approximately 92 die shortly after birth with lung hypoplasia and a ventricular septal defect. The miR-17 approximately 92 cluster is also essential for B cell development. Absence of miR-17 approximately 92 leads to increased levels of the proapoptotic protein Bim and inhibits B cell development at the pro-B to pre-B transition. Furthermore, while ablation of miR-106b approximately 25 or miR-106a approximately 363 has no obvious phenotypic consequences, compound mutant embryos lacking both miR-106b approximately 25 and miR-17 approximately 92 die at midgestation. These results provide key insights into the physiologic functions of this family of microRNAs and suggest a link between the oncogenic properties of miR-17 approximately 92 and its functions during B lymphopoiesis and lung development.     

Expression patterns of Slit and Robo family members during vertebrate limb development

Cell interactions involving Notch signaling are required for the demarcation of tissue boundaries in both invertebrate and vertebrate development. Members of the Fringe gene family encode beta-1,3 N-acetyl-glucosaminyltransferases that function to refine the spatial localization of Notch-receptor signaling to tissue boundaries. In this paper we describe the isolation and characterization of the zebrafish (Danio rerio) homologue of the lunatic fringe gene (lfng). Zebrafish lfng is generally expressed in equivalent structures to those reported for the homologous chick and mouse genes. These sites include expression along the A-P axis of the neural tube, within the lateral plate mesoderm, in the presomitic mesoderm and the somites and in specific rhombomeres of the hindbrain; however, within these general expression domains species-specific differences in lfng expression exist. In mouse, Lfng is expressed in odd-numbered rhombomeres, whereas in zebrafish, expression occurs in even-numbered rhombomeres. In contrast to reports in both mouse and chicken embryos showing a kinematic cyclical expression of Lfng mRNA in the presomitic paraxial mesoderm, we find no evidence for a cyclic pattern of expression for the zebrafish lfng gene; instead, the zebrafish lfng is expressed in two static stripes within the presomitic mesoderm. Nevertheless, in zebrafish mutants affecting the correct formation of segment boundaries in the hindbrain and somites, lfng expression is aberrant or lost.