FHL2 蛋白在肿瘤中的转录调控及其分子生物学机制

FHL2是仅有四个半LIM结构域(FHL)蛋白家族的成员,目前在FHL蛋白家族中研究最为广泛。FHL2作为重要的衔接蛋白和支架蛋白,主要通过LIM结构域介导蛋白分子间的相互作用以实现其生物学功能。Fhl2基因在转录水平受多种肿瘤相关基因的调控,如p53,血清应答因子等。FHL2与恶性肿瘤的关系是近年来的研究热点,目前认为FHL2能够作为癌蛋白及抑癌蛋白通过不同机制广泛影响乳腺癌、胃肠道肿瘤、肝癌、前列腺癌等肿瘤的发生发展,并且在不同肿瘤中的表达具有组织特异性。本文就FHL2的结构特点、功能、转录调控及与肿瘤的关系几个方面展开综述,从而明确FHL2在不同肿瘤中所发挥的作用及其分子生物学机制将会为治疗相关肿瘤提供新的干预靶点。     

Protein-protein interaction of FHL2, a LIM domain protein preferentially expressed in human heart, with hCDC47

In the yeast two-hybrid library screening, the heart-specific FHL2 protein was found to interact with hCDC47. In vitro interaction study between FHL2 protein and hCDC47 was demonstrated. From the results of domain studies by the yeast two-hybrid assay, the second and third LIM domains in conjunction with the first half LIM domain of FHL2 were identified to be important in binding with hCDC47. Besides, in Northern blot hybridization of human cancer cell lines, the highest FHL2 mRNA expression was detected in colorectal adenocarcinoma SW480 and HeLa cell S3. Our results imply that FHL2 protein may associate with cancer development and may act as a molecular adapter to form a multicomplex with hCDC47 in the nucleus, thus it plays an important role in the specification or maintenance of the terminal differentiated phenotype of heart muscle cells.     

FHL2转录激活结构域的定位

LIM蛋白家族成员FHL2 (fourandhalfLIMdomainprotein)在转录调节、细胞凋亡及肿瘤的发生发展中都起着重要作用。利用GAL4转录因子中的DNA结合结构域 (DBD)和含有与DBD结合序列的荧光素酶报告基因(GAL4 LUC)构建了哺乳动物细胞转录激活系统 ,并利用该系统定位了FHL2的转录激活结构域。首先将GAL4 DBD序列以正确读框插入到pcDNA3载体的多克隆位点中 ,构建成真核表达载体pDBD ,再将野生型FHL2及其不同片段以正确读框与pDBD中GAL4 DBD序列融合 ,构建成野生型FHL2及其缺失突变体表达载体。将这些表达载体分别瞬时转染 2 93T胚胎肾细胞 ,野生型FHL2及其缺失突变体都得到了表达。利用GAL4 荧光素酶报告基因对野生型FHL2及其不同突变体的转录激活活性检测表明 ,在 2 93T胚胎肾细胞和乳腺癌MCF 7细胞中 ,野生型FHL2具有转录激活活性 ,缺失N端半个LIM结构域使FHL2转录激活活性降低 ,缺失C末端第二个LIM结构域对FHL2的转录激活功能影响不大 ,缺失C末端最后一个LIM结构域则使FHL2的转录激活功能完全丧失 ,而C末端缺失 2个LIM结构域使FHL2转录激活活性又有所恢复。这说明FHL2C末端最后一个LIM结构域对其转录激活功能是必需的 ,而C末端第二个LIM结构域可能对FHL2的转录激活功能有负调控作用 ,这种负调控作用取决于     

Downregulation and antiproliferative role of FHL3 in breast cancer

Four and a half LIM domain (FHL) protein 3 is a member of the FHL protein family that plays roles in the regulation of signal transduction, cell adhesion, survival, and mobility. FHL3 has been implicated in the development and progression of liver cancer. However, the biological function of FHL3 in other cancers remains unclear. Here, we show that FHL3 is downregulated in breast cancer patients. Using small interfering RNA (siRNA) knockdown and/or overexpression experiments, we demonstrated that FHL3 suppressed anchorage-dependent and -independent growth of human breast cancer cells. The antiproliferative effects of FHL3 on breast cancer cell growth were associated with both the G1 and the G2/M cell cycle arrest, which was accompanied by a marked inhibition of the G1-phase marker cyclin D1 and the G2/M-phase marker cyclin B1 as well as the induction of the cyclin dependent kinase inhibitor p21 (WAF1/CIP1), a negative regulator of cell cycle progression at G1 and G2. These results suggest that FHL3 may play a role in the development and progression of breast cancer, and thereby may be a potential target for human breast cancer gene therapy.     

The structure of the human LIM protein ACT gene and its expression in tumor cell lines

We describe the human ACT genomic and cDNA sequence which like its murine counterpart contains the defining secondary structure of the FHL (Four-and-a-Half LIM-domain) LIM-protein family. The coding region of the human ACT gene spans five exons. This distribution is very similar to the FHL1 gene and includes the arrangement of split codons across exon boundaries suggesting that these genes share a common ancestor. The human ACT gene was not detected by Northern analysis in the adult testis although this is the only known site of expression found with its murine counterpart. However, the human ACT gene was found to be expressed in a panel of human tumor cell lines derived from squamous cell carcinomas, melanomas, and leukemias. Interestingly, FHL1, FHL2, and FHL3 were also found to be expressed in some of these cell lines and the results suggest an important role for FHLs in tumor biology.     

FHL2参与调控MCF-7细胞周期

目的：研究FHL2对细胞周期阻滞的影响。方法：应用pSR-GFP/Neo载体构建FHL2-siRNA干扰载体,转染MCF-7细胞,G418筛选稳定细胞系,通过流式细胞仪检测离子辐射后细胞周期的变化。结果：利用设计的FHL2-siRNA干扰载体能够干扰细胞中FHL2的表达;当离子辐射后,FHL2敲除细胞G2/M期阻滞的程度比野生型细胞显著降低。结论：FHL2参与调控MCF-7细胞离子辐射后细胞周期G2/M期阻滞。     

放射诱导基因FHL2在人群中表达水平的检测

目的：分析FHL2基因在健康人群个体间表达的差异,评估FHL2作为一种新的辐射生物剂量计的可行性。方法：收集20例健康人血液样本,提取白细胞RNA进行反转录,以β-actin作为内参,利用实时定量PCR方法,检测人群中FHL2基因相对表达水平,并分析其差异。结果：FHL2和β-actin基因的实时定量PCR熔解曲线均为单峰,所得到的Ct值与相应的PCR产物呈良好的线性关系;20例血液标本中FHL2表达水平之间存在较大差异,且其表达水平与性别无关。结论：公认的放射诱导基因FHL2可能不适合作为辐射生物剂量计。     

IGF2‐derived miR‐483‐3p associated with Hirschsprung's disease by targeting FHL1

HSCR (Hirschsprung's disease) is a serious congenital defect, and the aetiology of it remains unclear. Many studies have highlighted the significant roles of intronic miRNAs and their host genes in various disease, few was mentioned in HSCR although. In this study, miR‐483‐3p along with its host gene IGF2 (Insulin‐like growth factor 2) was found down‐regulated in 60 HSCR aganglionic colon tissues compared with 60 normal controls. FHL1 (Four and a half LIM domains 1) was determined as a target gene of miR‐483‐3p via dual‐luciferase reporter assay, and its expression was at a higher level in HSCR tissues. Here, we study cell migration and proliferation in human 293T and SH‐SY5Y cell lines by performing Transwell and CCK8 assays. In conclusion, the knockdown of miR‐483‐3p and IGF2 both suppressed cell migration and proliferation, while the loss of FHL1 leads to opposite outcome. Furthermore, miR‐483‐3p mimics could rescue the negative effects on cell proliferation and migration caused by silencing IGF2, while the FHL1 siRNA may inverse the function of miR‐483‐3p inhibitor. This study revealed that miR‐483‐3p derived from IGF2 was associated with Hirschsprung's disease by targeting FHL1 and may provide a new pathway to understand the aetiology of HSCR.     

Deletion of the FHL2 gene attenuates intima‐media thickening in a partially ligated carotid artery ligated mouse model

The four and a half LIM domain protein 2 (FHL2) is a member of the four and a half LIM domain (FHL) gene family, and it is associated with cholesterol‐enriched diet‐promoted atherosclerosis. However, the effect of FHL2 protein on vascular remodelling in response to hemodynamic alterations remains unclear. Here, we investigated the role of FHL2 in a model of restricted blood flow‐induced atherosclerosis. To promote neointimal hyperplasia in vivo, we subjected FHL2^+/+ and FHL2^?/? mice to partial ligation of the left carotid artery (LCA). The expression of p‐ERK and p‐AKT was decreased in FHL2^?/? mice. FHL2 bound to AKT regulated AKT phosphorylation and led to Rac1‐GTP inactivation. FHL2 silencing in human aortic smooth muscle cells down‐regulated the PDGF‐induced phosphorylation of ERK and AKT. Furthermore, FHL2 silencing reduced cytoskeleton conformational changes and caused cell cycle arrest. We concluded that FHL2 is essential for the regulation of arterial smooth muscle cell function. FHL2 modulates proliferation and migration via mitogen‐activated protein kinase (MAPK) and PI3K‐AKT signalling, leading to arterial wall thickening and thus neointimal hyperplasia.     

c-Abl调控FHL2的转录活性

目的：研究c-Abl对FHL2转录活性的调控。方法：应用免疫共沉淀和免疫印迹验证c-Abl与FHL2的相互作用及c-Abl对FHL2的磷酸化作用,并用萤光素酶报告基因研究c-Abl对FHL2转录活性的调控。结果：c-Abl与FHL2结合并磷酸化FHL2,促进FHL2的转录活性,并与FHL2一起促进FHL2下游因子骨钙蛋白的基因启动子活性。结论：c-Abl能促进FHL2的转录活性。     

The LIM-only protein FHL2 interacts with beta-catenin and promotes differentiation of mouse myoblasts

FHL2 is a LIM-domain protein expressed in myoblasts but down-regulated in malignant rhabdomyosarcoma cells, suggesting an important role of FHL2 in muscle development. To investigate the importance of FHL2 during myoblast differentiation, we performed a yeast two-hybrid screen using a cDNA library derived from myoblasts induced for differentiation. We identified beta-catenin as a novel interaction partner of FHL2 and confirmed the specificity of association by direct in vitro binding tests and coimmunoprecipitation assays from cell lysates. Deletion analysis of both proteins revealed that the NH2-terminal part of beta-catenin is sufficient for binding in yeast, but addition of the first armadillo repeat is necessary for binding FHL2 in mammalian cells, whereas the presence of all four LIM domains of FHL2 is needed for the interaction. Expression of FHL2 counteracts beta-catenin-mediated activation of a TCF/LEF-dependent reporter gene in a dose-dependent and muscle cell-specific manner. After injection into Xenopus embryos, FHL2 inhibited the beta-catenin-induced axis duplication. C2C12 mouse myoblasts stably expressing FHL2 show increased myogenic differentiation reflected by accelerated myotube formation and expression of muscle-specific proteins. These data imply that FHL2 is a muscle-specific repressor of LEF/TCF target genes and promotes myogenic differentiation by interacting with beta-catenin.     

Alteration in gene expression profile and biological behavior in human lung cancer cell line NL9980 by nm23-H1 gene silencing

Lung cancer is the leading cause of cancer death in both men and women. Tumor metastasis is an essential aspect of lung cancer progression. nm23-H1 is a metastasis suppressor gene. The molecular mechanism by which nm23-H1 suppresses the metastasis is still unclear. Here, we compared the gene expression profile of human large cell lung cancer cell line NL9980 by nm23-H1 gene silencing with that of negative control cells to comprehensively investigate nm23-H1-mediated changes in gene expression of NL9980 cells. Microarray assay revealed that expression of 733-known genes (1.9%, 733/38,500) were altered in response to nm23-H1 gene silencing, including 466 upregulated genes and 267 downregulated. real-time PCR assay of the expression changes indicated that 81.82% (45/55) of verified genes were consistent with that observed in microarray assay. The upregulated genes included MMP-1, -2, SNAI2, CXCL1, 2, 3, PAI-2, while the downregulated genes included cystatin B, TIMP-2, E-cadherin, centrin-2, all of which have been associated with tumor metastasis. Furthermore, we confirmed by Western blot that the expression of MMP-1 and -2 were significantly increased while that of cystatin B was dramatically decreased in NL9980-nm23-H1 silencing cells. The NL9980-nm23-H1 silencing cells exhibited significantly more S phase growth and invasive ability. Thus, silencing of nm23-H1 gene caused metastasis-related gene expression changes in lung cancer cells. The knockdown of nm23-H1 expression may change the lung cancer cells to a more invasive phenotype through alteration in the expression of a set of genes.