RASSF1A: A potential novel therapeutic target against cardiac hypertrophy

Cardiac hypertrophy is a key risk factor for chronic heart failure. Current treatments predominantly focus on both reducing the peripheral vascular resistance and activating nerve-humoral system. However, these efforts can't reverse cardiac hypertrophy fundamentally. Ras association domain family 1 isoform A (RASSF1A) is a regulatory tumor suppressor whose inactivation by inappropriate promoter methylation has been implicated in the development of many human cancers. Recently, there have been a number of studies investigating the roles of RASSF1A in the pathophysiology of cardiac hypertrophy. In this review, we focus on the present progresses of cardiac RASSF1A under physiological and pathological conditions, trying to systematically elucidate how the RASSF1A-mediated signal pathways contribute to the maintenance of normal cardiac myocyte structure and function and lead to the regression of pathological cardiac hypertrophy. These pathways exert multiple functions such as regulating cardiac contractility, physiologically increasing stability of microtubule, preventing cardiac dysfunction, attenuating interstitial fibrosis and mediating cell apoptosis. These specific roles are highly relevant with cardiac hemodynamics and therapeutic strategies, indicating RASSF1A may have the potential to reverse pathological cardiac hypertrophy thus prevent heart failure fundamentally.     

ZEB1‐AS1: A crucial cancer‐related long non‐coding RNA

Long non‐coding RNAs (lncRNAs) recently emerge as a novel class of non‐coding RNAs (ncRNAs) with larger than 200 nucleotides in length. Due to lack an obvious open reading frame, lncRNAs have no or limited protein‐coding potential. To date, accumulating evidence indicates the vital regulatory function of lncRNAs in pathological processes of human diseases, especially in carcinogenesis and development. Deregulation of lncRNAs not only alters cellular biological behavior, such as proliferation, migration and invasion, but also represents the poor clinical outcomes. Zinc finger E‐box binding homeobox 1 antisense 1 (ZEB1‐AS1), an outstanding cancer‐related lncRNA, is identified as an oncogenic regulator in diverse malignancies. Dysregulation of ZEB1‐AS1 has been demonstrated to exhibit a pivotal role in tumorigenesis and progression, suggesting its potential clinical value as a promising biomarker or therapeutic target for cancers. In this review, we make a summary on the current findings regarding the biological functions, underlying mechanisms and clinical significance of ZEB1‐AS1 in cancer progression.     

LncRNA NR2F2‐AS1 promotes tumourigenesis through modulating BMI1 expression by targeting miR‐320b in non‐small cell lung cancer

Recently, long noncoding RNAs (lncRNAs) are attracting wide attention in the field of cancer research because of its important role in cancer diagnosis and prognosis. But studies on the biological effects and relevant mechanisms of lncRNAs in non‐small cell lung cancer (NSCLC) remain few and need to be enriched. Our study discussed the expression and biological effects of LncRNA NR2F2‐AS1, and further explored its possible molecular mechanisms. As a result, elevated expression of NR2F2‐AS1 was detected in NSCLC tissues and cells and was remarkably associated with the tumor, node, metastasis (TNM) stage and the status of lymphatic metastasis of patients. Down‐regulated NR2F2‐AS1 contributed to the promotion of cell apoptosis and the inhibition of cell proliferation and invasion in A549 and SPC‐A‐1 cells in vivo and vitro. Through bioinformatics analysis, NR2F2‐AS1 functions as a ceRNA directly binding to miR‐320b, BMI1 was a direct target of miR‐320b. Combined with the following cellular experiments, the data showed that NR2F2‐AS1 may influence the NSCLC cell proliferation, invasion and apoptosis through regulating miR‐320b targeting BMI1.     

Long non‐coding RNA SNAI3‐AS1 promotes the proliferation and metastasis of hepatocellular carcinoma by regulating the UPF1/Smad7 signalling pathway

Emerging evidence has indicated that deregulation of long non‐coding RNAs (lncRNAs) can contribute to the progression of human cancers, including hepatocellular carcinoma (HCC). However, the role and exact mechanism of most lncRNAs in tumours remains largely unknown. In the current study, we found a novel long non‐coding RNA termed SNAI3‐AS1 which was generally up‐regulated in HCC tissues compared with normal control. Higher expression of SNAI3‐AS1 was significantly correlated with shorter overall survival of HCC patients. Knockdown of SNAI3‐AS1 inhibited the proliferation and metastasis of HCC cells in vitro, whereas overexpression of SNAI3‐AS1 promoted the proliferation and metastasis of HCC cells. Further investigations showed that SNAI3‐AS1 could affect HCC tumorigenesis by binding up‐frameshift protein 1 (UPF1), regulating Smad7 expression and activating TGF‐β/Smad pathway. Functionally, SNAI3‐AS1 promoted HCC growth and metastasis by inducing tumour epithelial to mesenchymal transition (EMT). Taken together, these findings showed that SNAI3‐AS1 promotes the progression of HCC by regulating the UPF1 and activating TGF‐β/Smad pathway.     

Dynamics of RASSF1A/MOAP-1 association with death receptors

RASSF1A is a tumor suppressor protein involved in death receptor-dependent apoptosis utilizing the Bax-interacting protein MOAP-1 (previously referred to as MAP-1). However, the dynamics of death receptor recruitment of RASSF1A and MOAP-1 are still not understood. We have now detailed recruitment to death receptors (tumor necrosis factor receptor 1 [TNF-R1] and TRAIL-R1/DR4) and identified domains of RASSF1A and MOAP-1 that are required for death receptor interaction. Upon TNF-alpha stimulation, the C-terminal region of MOAP-1 associated with the death domain of TNF-R1; subsequently, RASSF1A was recruited to MOAP-1/TNF-R1 complexes. Prior to recruitment to TNF-R1/MOAP-1 complexes, RASSF1A homodimerization was lost. RASSF1A associated with the TNF-R1/MOAP-1 or TRAIL-R1/MOAP-1 complex via its N-terminal cysteine-rich (C1) domain containing a potential zinc finger binding motif. Importantly, TNF-R1 association domains on both MOAP-1 and RASSF1A were essential for death receptor-dependent apoptosis. The association of RASSF1A and MOAP-1 with death receptors involves an ordered recruitment to receptor complexes to promote cell death and inhibit tumor formation.     

BRAF mutation and RASSF1A expression in thyroid carcinoma of southern Italy

Aim of this work is to provide a detailed comparison of clinical‐pathologic features between well‐differentiated and poorly differentiated tumors according to their BRAF and RASSF1A status. We analyzed RASSF1A methylation by MSP and BRAF mutation by LCRT‐PCR with LightMix® kit BRAF V600E in neoplastic thyroid tissues. Immunohistochemical evaluation of RASSF1A expression was also performed by standard automated LSAB‐HRP technique. An overall higher degree of RASSF1A over‐expression than normal thyroid parenchyma surrounding tumors (P < 0.05) has been found in all malignant well‐differentiated lesions. Moreover, statistically significant higher levels of RASSF1A expression were observed in differentiated cancers associated to an inflammatory autoimmune background (P = 0.01). Amplifiable DNA for LC PCR with LightMix® kit BRAF V600E was obtained in nine PTCs, four FVPTCs, five ATCs, and one control. The V600E mutation was found in 13 of 18 (72%) tumors. BRAF was mutated in 6 of 9 (66%) classical PTC, in 2 of 4 (50%) follicular variant PTC and in all ACs (100%). The overall frequency of RASSF1A promoter methylation observed was 20.5% (9 cases out 44). Hypermethylation of RASSF1A in primary tumors was variable according to histotypes ranging from100% (5/5) in ACs to only 12.5% (4/32) in PTCs. We show a correlation between RASSF1A methylation status and RASSF1A protein expression. Finally, we conclude that BRAF V600E mutation and RASSF1A methylation were pathogenetic event restricted to a subgroup of PTC/FVPTCs in early stage and to clinically aggressive ATCs. J. Cell. Biochem. 114: 1174–1182, 2013. © 2012 Wiley Periodicals, Inc.     

Status of RASSF1A in uveal melanocytes and melanoma cells

RASSF1A gene, found at the 3p21.3 locus, is a tumor suppressor gene frequently hypermethylated in human cancers. In this study, we report that compared with melanocytes in normal choroid, RASSF1A is downregulated in uveal melanoma samples and in uveal melanoma cell lines. LOH at 3p21.3 was detected in 50% of uveal melanoma. Moreover, methylation of the RASSF1A promoter was detected in 35 of 42 tumors (83%) and RASSF1A was also weakly expressed at the mRNA level. These data indicate that LOH at the RASSF1A locus or RASSF1A promoter methylation may partly account for the suppression of RASSF1A expression observed in uveal melanoma. Furthermore, following ectopic expression in three RASSF1A-deficient melanoma cell lines (OCM-1, Mel270, and 92.1), RASSF1A weakly reduces cell proliferation and anchorage-independent growth of uveal melanoma cells without effect on ERK1/2 activation, cyclin D1 and p27(Kip1) expression. This study explored biological functions and underlying mechanisms of RASSF1A in the ERK1/2 pathway in normal uveal melanocytes. We showed that siRNA-mediated depletion of RASSF1A increased ERK1/2 activation, cyclin D1 expression, and also decreased p27(Kip1) expression in normal uveal melanocytes. Moreover, that the depletion of RASSF1A induced senescence-associated β-galactosidase activity and increased p21(Cip1) expression suggests that RASSF1A plays a role in the escape of cellular senescence in normal uveal melanocytes. Interestingly, we found that RASSF1A was epigenetically inactivated in long-term culture of uveal melanocytes. Taken together, these data show that depletion of RASSF1A could be an early event observed during senescence of normal uveal melanocytes and that additional alterations are acquired during malignant transformation to uveal melanoma.     

Tumor suppressor RASSF1A promoter: p53 binding and methylation

Oncogenes and tumor suppressors work in concert to regulate cell growth or death, which is a pair of antagonist factors for regulation of tumorigenesis. Here we show promoter characteristic of tumor suppressor RASSF1A, which revealed a p53 binding site in the distal and a GC-rich region in the proximal promoter region of RASSF1A, in despite of TATA box-less. The GC-rich region, which is ～300 bp upstream from the RASSF1A ATG, showed the strongest promoter activity in an assay of RASSF1A-driving GFP expression. Methylation analysis of the CpG island showed that 78.57% of the GC sties were methylated in testis tumor samples compared with methylation-less in normal testis. Hypermethylation of the GC-rich region is associated with RASSF1A silencing in human testis tumors. In addition, electrophoretic mobility shift assay indicated that p53 protein bound to the RASSF1A promoter. Further chromatin immunoprecipitation confirmed p53 binding to the RASSF1A. Moreover, p53 binding to the promoter down-regulated RASSF1A expression. These results suggest that p53 protein specifically binds to the RASSF1A promoter and inhibits its expression. Our results provide new insight into the mechanism of action of tumor suppressors and may be a starting point for development of new approaches to cancer treatment.     

Long non‐coding RNA DBH‐AS1 promotes cancer progression in diffuse large B‐cell lymphoma by targeting FN1 via RNA‐binding protein BUD13

Diffuse large B‐cell lymphoma (DLBC) is a subtype of lymphoma with the worst prognosis. Existing treatment methods are not effective enough due to its high occurrence of metastasis. Therefore, identification of effective therapeutic targets is becoming increasingly important. In this research, long non‐coding RNA dopamine β hydroxylase antisense RNA 1 (DBH‐AS1) was found to be upregulated in DLBC tissues and cells. Knockdown of DBH‐AS1 suppressed the proliferation, migration, and invasion of cancer cells. Afterwards, RNA‐binding protein BUD13 homolog (BUD13) was found to be upregulated in cancer tissues and cells while binding to DBH‐AS1. Fibronectin 1 (FN1) was the downstream messenger RNA (mRNA) of BUD13. FN1 was upregulated in DLBC and was positively correlated with DBH‐AS1. Further rescue assays proved that DBH‐AS1 mediated FN1 expression by recruiting BUD13. In the meantime, BUD13 stabilized FN1 mRNA to promote FN1 expression. In this way, DBH‐AS1/BUD13/FN1 axis was confirmed. A set of rescue assays proved that DBH‐AS1 regulated DLBC progression via BUD13 and FN1. The function and mechanism of DBH‐AS1 were investigated for the first time in DLBC. DBH‐AS1 might become a therapeutic target in lymphoma treatment in the future.     

The centrosomal protein RAS association domain family protein 1A (RASSF1A)-binding protein 1 regulates mitotic progression by recruiting RASSF1A to spindle poles

The protein RAS association domain family protein 1A (RASSF1A), which is encoded by a gene that is frequently silenced in many types of sporadic tumor, functions in mitosis as a regulator of the anaphase-promoting complex (APC). With the use of a yeast two-hybrid screen, we identified a human protein, previously designated C19ORF5, that interacts with RASSF1A. This protein, here redesignated RASSF1A-binding protein 1 (RABP1), contains two microtubule-associated protein domains, and its association with RASSF1A was confirmed in mammalian cells by immunoprecipitation and immunofluorescence analyses. RABP1 was found to be localized to the centrosome throughout the cell cycle in a manner dependent on its microtubule-associated protein domains. Ectopic expression of RABP1 induced both stabilization of mitotic cyclins and mitotic arrest at prometaphase in a RASSF1A-dependent manner. It also increased the extent of association between RASSF1A and Cdc20. Conversely depletion of RABP1 by RNA interference prevented both the localization of RASSF1A to the spindle poles as well as its binding to Cdc20, resulting in premature destruction of mitotic cyclins and acceleration of mitotic progression. These findings indicate that RABP1 is required for the recruitment of RASSF1A to the spindle poles and for its inhibition of APC-Cdc20 activity during mitosis.     

骨肉瘤中RASSF1A基因的甲基化状态研究

目的：分析骨肉瘤组织中RASSF1A基因甲基化状况。方法：运用甲基化特异性PCR（MSP）分别检测44例骨肉瘤组织及相应的癌旁组织中RASSF1A基因启动子甲基化状态并分析其临床病理意义。结果：骨肉瘤组织中RASSF1A基因异常甲基化率（61.4%）显著高于癌旁正常骨组织中RASSF1A基因的异常甲基化率（20.5%）,二者之间差异具有统计学意义（P〈0.05）。RASSF1A基因异常甲基化导致组织中RASSF1A基因mRNA和蛋白表达水平均显著降低。另外,RASSF1A基因异常甲基化和肿瘤组织分化程度及全身有无转移情况有相关性（P值分别为0.022和0.016）,而与患者年龄、性别、肿瘤位置及大小等临床特征无关（P值分别为0.6944,0.977,0.786和0.831）。结论：RASSF1A基因启动子高甲基化可能是导致其在骨肉瘤中表达水平降低的分子机制之一,有望成为骨肉瘤早期辅助诊断的一个重要分子标志物。     

The tumour suppressor RASSF1A is a novel substrate of PKC

Ras association domain family 1A (RASSF1A) is a tumour suppressor that contains an amino-terminal cysteine-rich region, similar to the diacylglycerol (DAG)-binding domain (C1 domain) found in the protein kinase C (PKC) family of proteins, and a carboxy-terminal Ras-association (RA) domain. In the present study, RASSF1A was identified as a substrate for PKC. Using classical biochemical approaches, it was established that S197 and S203 within the RA domain of RASSF1A are phosphorylated by PKC in vitro and in vivo. Unlike the WT protein, the S197, 203D double mutant of RASSF1A failed to modulate microtubule organization and perinuclear vimentin collapse. By contrast, the equivalent AA mutant of RASSF1A phenocopied the WT protein. These findings indicate that PKC phosphorylation of RASSF1A regulates its ability to reorganize the microtubule network.     

Long non‐coding RNA NNT‐AS1 sponges miR‐424/E2F1 to promote the tumorigenesis and cell cycle progression of gastric cancer

Long non‐coding RNAs (lncRNAs) have been illustrated to function as important regulators in carcinogenesis and cancer progression. However, the roles of lncRNA NNT‐AS1 in gastric cancer remain unclear. In the present study, we investigate the biological role of NNT‐AS1 in gastric cancer tumorigenesis. Results revealed that NNT‐AS1 expression level was significantly up‐regulated in GC tissue and cell lines compared with adjacent normal tissue and normal cell lines. The ectopic overexpression of NNT‐AS1 indicated the poor prognosis of GC patients. In vitro experiments validated that NNT‐AS1 knockdown suppressed the proliferation and invasion ability and induced the GC cell cycle progression arrest at G0/G1 phase. In vivo xenograft assay, NNT‐AS1 silencing decreased the tumour growth of GC cells. Bioinformatics online program predicted that miR‐424 targeted the 3′‐UTR of NNT‐AS1. Luciferase reporter assay, RNA‐immunoprecipitation (RIP) and RNA pull‐down assay validated the molecular binding within NNT‐AS1 and miR‐424, therefore jointly forming the RNA‐induced silencing complex (RISC). Moreover, E2F1 was verified to act as the target gene of NNT‐AS1/miR‐424, indicating the NNT‐AS1/miR‐424/E2F1 axis. In conclusion, our study indicates that NNT‐AS1 sponges miR‐424/E2F1 to facilitate GC tumorigenesis and cycle progress, revealing the oncogenic role of NNT‐AS1 for GC.     

RG108对肺腺癌A549细胞增殖、凋亡及RASSF1A基因表达的影响

目的探讨DNA甲基转移酶抑制剂RG108对人肺腺癌细胞株A549增殖、凋亡以及对RASSF1A（Ras as-sociation domain proteinfamily1）基因启动子区域甲基化状态、表达的影响。方法用20μmol/L的RG108对A549细胞进行化学干预72h,用MTT法检测细胞生长抑制率;流式细胞术检测细胞周期以及凋亡情况;RT-PCR观察RASSF1A基因mRNA水平变化;Western blot检测RASSF1A蛋白的表达;甲基化特异性PCR（MS-PCR）检测RASSF1A基因启动子区域甲基化状态的改变。结果经RG108干预72h后,A549细胞的抑制率为17.2±0.43%,细胞周期阻滞于G0/G1期,并引起细胞凋亡。RT-PCR和Western blot结果显示在干预组细胞中分别出现RASSF1A基因的DNA条带（329bp）和蛋白质条带（39kD）,而对照组中无相应条带出现。RASSF1A基因启动子区域由甲基化状态转变为非甲基化状态。结论RG108可使RASSF1A基因启动子区域去甲基化,并通过该机制诱导RASSF1A基因在人肺腺癌细胞株A549中表达。     

JKTBP1 is involved in stabilization and IRES-dependent translation of NRF mRNAs by binding to 5' and 3' untranslated regions

Heterogeneous nuclear ribonucleoprotein D-like protein (JKTBP) 1 was implicated in cap-independent translation by binding to the internal ribosome entry site in the 5′ untranslated region (UTR) of NF-κB-repressing factor (NRF). Two different NRF mRNAs have been identified so far, both sharing the common 5′ internal ribosome entry site but having different length of 3′ UTRs. Here, we used a series of DNA and RNA luciferase reporter constructs comprising 5′, 3′ or both NRF UTRs to study the effect of JKTBP1 on translation of NRF mRNA variants. The results indicate that JKTBP1 regulates the level of NRF protein expression by binding to both NRF 5′ and 3′ UTRs. Using successive deletion and point mutations as well as RNA binding studies, we define two distinct JKTBP1 binding elements in NRF 5′ and 3′ UTRs. Furthermore, JKTBP1 requires two distinct RNA binding domains to interact with NRF UTRs and a short C-terminal region for its effect on NRF expression. Together, our study shows that JKTBP1 contributes to NRF protein expression via two disparate mechanisms: mRNA stabilization and cap-independent translation. By binding to 5′ UTR, JKTBP1 increases the internal translation initiation in both NRF mRNA variants, whereas its binding to 3′ UTR elevated primarily the stability of the major NRF mRNA. Thus, JKTBP1 is a key regulatory factor linking two pivotal control mechanisms of NRF gene expression: the cap-independent translation initiation and mRNA stabilization.