NORE1A,a homologue of RASSF1A tumour suppressor gene is inactivated in human cancers

We recently demonstrated that RASSF1A, a new tumour-suppressor gene located at 3p21.3 is frequently inactivated by promoter region hypermethylation in a variety of human cancers including lung, breast, kidney and neuroblastoma. We have identified another member of the RASSF1 gene family by in silico sequence analysis using BLAST searches. NORE1 located at 1q32.1 exists in three isoforms (NORE1Aalpha, NORE1Abeta and NORE1B). Both NORE1A and NORE1B isoforms have separate CpG islands spanning their first exons. NORE1Aalpha Produces a 418 aa protein containing a Ras-association (RA) domain and a diacylglycerol (DAG) binding domain. NORE1Abeta produces a C-terminal truncation of the RA domain. NORE1B also contains the RA domain but not the DAG domain. NORE1 is the human homologue of the mouse Ras effector Nore1. No inactivating somatic mutations were found in lung tumour lines; however, NORE1A promoter region CpG island was hypermethylated in primary tumours and tumour cell lines. NORE1A promoter was methylated in 10/25 breast, 4/40 SCLC, 3/17 NSCLC, 1/6 colorectal and 3/9 kidney tumour cell lines, while NORE1B promoter was unmethylated in the same tumour cell lines. While 24% (6/25) of primary NSCLC underwent NORE1A methylation, methylation in SCLC was a rare event (0/22); (P = 0.0234). NORE1A expression in tumour cell lines was reactivated after treatment with a demethylating agent. There was no correlation between NORE1A and RASSF1A methylation status in NSCLC. Our results demonstrate that NORE1A is inactivated in a subset of human cancers by CpG island promoter hypermethylation, and in lung cancer this hypermethylation may be histological type specific.     

NORE1A sensitises cancer cells to sorafenib-induced apoptosis and indicates hepatocellular carcinoma prognosis

NORE1A, identified as a Ras effector, is frequently silenced in human cancers and has been implicated in tumour progression. Reports showing that NORE1A may function as a tumour suppressor have been emerging. However, to date, its expression and relevant significance in hepatocellular carcinoma (HCC) remain elusive. In this study, we examined the expression of NORE1A in HCC cell lines and a cohort of 250 HCC samples. We found that both the mRNA and the protein levels of NORE1A were noticeably downregulated in 14 fresh HCC tissues, compared to corresponding paracarcinoma tissues. Furthermore, NORE1A in tumours was decreased in 72.4 % (181/250) of HCC patients. Low NORE1A expression was significantly associated with poor differentiation (P?=?0.003), advanced stage (P?=?0.002), high level of serum AFP (P?<?0.001), vascular invasion (P?=?0.034) and incomplete involucrum (P?=?0.018). Multivariate analysis revealed that NORE1A was an independent poor prognostic factor for both overall survival (hazard ratio (HR) 0.622, 95 % confidence interval (95 % CI) 0.405–0.956, P?=?0.030) and recurrence-free survival (HR 0.613, 95 % CI 0.390–0.964, P?=?0.034). Moreover, low NORE1A expression in advanced-stage HCC predicted disease relapse. In addition, NORE1A overexpression reduced cell viability, inhibited colony formation, and attenuated cell invasion in vitro. Further study demonstrated that NORE1A was capable of sensitising cancer cells to sorafenib-induced apoptosis via the activation of the Mst-1/Akt pathway. Collectively, our data suggest that NORE1A may be a promising prognostic biomarker and therapeutic target in HCC.     

Genotoxic stress leads to centrosome amplification in breast cancer cell lines that have an inactive G1/S cell cycle checkpoint

Centrosome amplification plays a key role in the origin of chromosomal instability during cancer development and progression. In this study, breast cancer cell lines with different p53 backgrounds were used to investigate the relationship between genotoxic stress, G(1)/S cell cycle checkpoint integrity, and the development of centrosome amplification. Introduction of DNA damage in the MCF-7 cell line by treatment with hydroxyurea (HU) or daunorubicin (DR) resulted in the arrest of both G(1)/S cell cycle progression and centriole duplication. In these cells, which carry functional p53, HU treatment also led to nuclear accumulation of p53 and p21(WAF1), retinoblastoma hypophosphorylation, and downregulation of cyclin A. MCF-7 cells carrying a recombinant dominant-negative p53 mutant (vMCF-7(DNp53)) exhibited a shortened G(1) phase of the cell cycle and retained a normal centrosome phenotype. However, these cells developed amplified centrosomes following HU treatment. The MDA-MB 231 cell line, which carries mutant p53 at both alleles, showed amplified centrosomes at the outset, and developed a hyperamplified centrosome phenotype following HU treatment. In cells carrying defective p53, the development of centrosome amplification also occurred following treatment with another DNA damaging agent, DR. Taken together, these findings demonstrate that loss of p53 function alone is not sufficient to drive centrosome amplification, but plays a critical role in this process following DNA damage through abrogation of the G(1)/S cell cycle checkpoint. Furthermore, these studies have important clinical implications because they suggest that breast cancers with compromised p53 function may develop centrosome amplification and consequent chromosomal instability following treatment with genotoxic anticancer drugs.     

Roles of cyclins A and E in induction of centrosome amplification in p53-compromised cells

Abnormal amplification of centrosomes, which occurs frequently in cancers, leads to high frequencies of mitotic defect and chromosome segregation error, profoundly affecting the rate of tumor progression. Centrosome amplification results primarily from overduplication of centrosomes, and p53 is involved in the regulation of centrosome duplication partly through controlling the activity of cyclin-dependent kinase (CDK) 2-cyclin E, a kinase complex critical for the initiation of centrosome duplication. Thus, loss or mutational inactivation of p53 leads to an increased frequency of centrosome amplification. Moreover, the status of cyclin E greatly influences the frequency of centrosome amplification in cells lacking functional p53. Here, we dissected the roles of CDK2-associating cyclins, namely cyclins E and A, in centrosome amplification in the p53-negative cells. We found that loss of cyclin E was readily compensated by cyclin A for triggering the initiation of centrosome duplication, and thus the centrosome duplication kinetics was not significantly altered in cyclin E-deficient cells. It has been shown that cells lacking functional p53, when arrested in either early S-phase or late G(2) phase, continue to reduplicate centrosomes, resulting in centrosome amplification. In cells arrested in early S phase, cyclin E, but not cyclin A, is important in centrosome amplification, whereas in the absence of cyclin E, cyclin A is important for centrosome amplification. In late G(2)-arrested cells, cyclin A is important in centrosome amplification irrespective of the cyclin E status. These findings advance our understandings of the mechanisms underlying the numeral abnormality of centrosomes and consequential genomic instability associated with loss of p53 function and aberrant expression of cyclins E and A in cancer cells.     

CpG island promoter hypermethylation of the Ras-effector gene NORE1A occurs in the context of a wild-type K-ras in lung cancer

Imbalance of the Ras signaling pathway is a major hallmark of human cancer. In this context, activating point mutations of the K-ras oncogene are a common feature of many tumor types. The discovery of methylation-mediated silencing of the Ras-effector homologue RASSF1A has revealed another way by which this cellular pathway may be altered. Inactivation by hypermethylation of a RASSF1A homologue, NORE1A, has recently been observed in human cancers. If both K-ras and NORE1A act in the same pathway, simultaneous molecular lesions in the two genes in the same tumor should be a rare event. To test whether this inverse association exists, we have analysed the K-ras mutational status and NORE1A CpG island hypermethylation of 61 non-small-cell lung carcinomas and the methylation status of the two other Ras effectors, RASSF1A and HRASLS. No association was found between the methylation status of NORE1A, RASSF1A and HRASLS or the status of K-ras with respect to the latter two genes. However, our results demonstrate that the epigenetic alteration of NORE1A is confined to lung tumors with a wild-type K-ras: 88% (15 of 17) of the tumors with NORE1 hypermethylation did not harbor a K-ras mutation (P=0.008, Fisher's exact test). Thus, the mutual exclusivity of the epigenetic and genetic alterations in the two genes of the Ras pathway suggests that they play a critical and cooperative role in human tumorigenesis.     

Overexpression of AIB1 negatively affects survival of surgically resected non-small-cell lung cancer patients

BackgroundThe amplified in breast cancer 1 (AIB1) gene has been considered to play an oncogenic role in human cancers, but its clinical/prognostic significance in non-small-cell lung cancer (NSCLC) is still unclear.Patients and methodsThe methods of immunohistochemistry and FISH were utilized to examine protein expression and amplification of AIB1 in 230 informative surgically resected NSCLCs and in 30 samples of normal lung tissues.ResultsOverexpression and amplification of AIB1 were found in 48.3% and 8.2% of NSCLCs, respectively. AIB1 overexpression was associated with AIB1 gene amplification and cell proliferation but not related to estrogen receptor (ER)-α, ER-β, progesterone receptor or androgen receptor status. A positive correlation between AIB1 overexpression and an ascending pathologic node stage in lung adenocarcinoma (ADC) was observed (P = 0.043). Univariate survival analysis demonstrated a significant association of AIB1 overexpression with shortened patient survival, especially for those with stage III disease (P < 0.001). Importantly, AIB1 expression was evaluated as the most significant predictor for survival in multivariate analysis (hazards ratio = 2.069, P < 0.001).ConclusionOverexpression of AIB1 might provide a selective advantage for lymph node metastasis of lung ADC and serve as a useful biomarker for poor prognosis for NSCLC patients.     

WT1在非小细胞肺癌中的表达及其与肺癌细胞增殖的关系

目的:探讨人非小细胞肺癌及其相应癌旁组织中WT1基因(Wilms' tumor gene 1,WT1)的表达,体外研究其与肺癌细胞增殖的关系.方法:应用实时荧光定量PCR法检测79例非小细胞肺癌组织及其相应癌旁组织中WT1 mRNA的表达情况.构建重组质粒pLV-GFP-WT1,并通过脂质体LipofectAMINE 2000将其瞬时转染至非小细胞肺癌H1299细胞中,应用蛋白质印迹法检测转染后H1299细胞中WT1蛋白的表达,CCK-8 (cell counting kit-8)法检测细胞的增殖情况.结果:非小细胞肺癌组织中WT1 mRNA的表达水平高于相应的癌旁组织,差异有统计学意义(P＜0.01).重组质粒pLV-GFP-WT1成功构建,并将其成功转染至H1299细胞中;转染后的H1299细胞中,WT1蛋白的表达水平上调;在pLV-GFP-WT1转染后24、36和48 h时,过表达WT1的H1299细胞增殖率高于对照组,差异有统计学意义(P＜0.05).结论:WT1 mRNA在非小细胞肺癌组织中的表达水平明显高于相应癌旁组织,高表达WT1基因能促进非小细胞肺癌H1299细胞的增殖,提示WT1在非小细胞肺癌中扮演癌基因的角色.     

Breast cancer metastasis suppressor 1 (BRMS1) suppresses metastasis and correlates with improved patient survival in non-small cell lung cancer

Breast cancer metastasis suppressor 1 (BRMS1) is a metastasis suppressor gene in several solid tumors. The role of BRMS1 in non-small cell lung cancer (NSCLC) is not well established. To assess in vitro and in vivo metastatic behavior H1299 NSCLC cells stably expressing BRMS1 or a vector control were created. BRMS1 expression significantly decreases both migration and invasion of NSCLC cells in vitro. Importantly, in flank xenografts, BRMS1 suppresses the formation of pulmonary and hepatic metastases but does not significantly affect primary tumor growth. To evaluate whether BRMS1 is related to the progression of NSCLC, we examined BRMS1 expression in human NSCLC. Both BRMS1 mRNA and protein levels are diminished in NSCLC compared to adjacent non-cancerous lung. BRMS1 expression is also lower in squamous cell carcinoma compared to adenocarcinoma. Moreover, preservation of tumor BRMS1 expression is associated with improved patient survival. Thus, BRMS1 functions as a metastasis suppressor and may be a prognostic indicator for human NSCLC.     

Epigenetic inactivation of RASSF1A in lung and breast cancers and malignant phenotype suppression

BACKGROUND: The recently identified RASSF1 locus is located within a 120-kilobase region of chromosome 3p21.3 that frequently undergoes allele loss in lung and breast cancers. We explored the hypothesis that RASSF1 encodes a tumor suppressor gene for lung and breast cancers. METHODS: We assessed expression of two RASSF1 gene products, RASSF1A and RASSF1C, and the methylation status of their respective promoters in 27 non-small-cell lung cancer (NSCLC) cell lines, in 107 resected NSCLCs, in 47 small-cell lung cancer (SCLC) cell lines, in 22 breast cancer cell lines, in 39 resected breast cancers, in 104 nonmalignant lung samples, and in three breast and lung epithelial cultures. We also transfected a lung cancer cell line that lacks RASSF1A expression with vectors containing RASSF1A complementary DNA to determine whether exogenous expression of RASSF1A would affect in vitro growth and in vivo tumorigenicity of this cell line. All statistical tests were two-sided. RESULTS: RASSF1A messenger RNA was expressed in nonmalignant epithelial cultures but not in 100% of the SCLC, in 65% of the NSCLC, or in 60% of the breast cancer lines. By contrast, RASSF1C was expressed in all nonmalignant cell cultures and in nearly all cancer cell lines. RASSF1A promoter hypermethylation was detected in 100% of SCLC, in 63% of NSCLC, in 64% of breast cancer lines, in 30% of primary NSCLCs, and in 49% of primary breast tumors but in none of the nonmalignant lung tissues. RASSF1A promoter hypermethylation in resected NSCLCs was associated with impaired patient survival (P =.046). Exogenous expression of RASSF1A in a cell line lacking expression decreased in vitro colony formation and in vivo tumorigenicity. CONCLUSION: RASSF1A is a potential tumor suppressor gene that undergoes epigenetic inactivation in lung and breast cancers through hypermethylation of its promoter region.     

Non-small-cell lung cancers with kinase domain mutations in the epidermal growth factor receptor are sensitive to ionizing radiation

Non-small cell lung cancers (NSCLCs) bearing mutations in the tyrosine kinase domain (TKD) of the epidermal growth factor receptor (EGFR) often exhibit dramatic sensitivity to the EGFR tyrosine kinase inhibitors gefitinib and erlotinib. Ionizing radiation (IR) is frequently used in the treatment of NSCLC, but little is known how lung tumor-acquired EGFR mutations affect responses to IR. Because this is of great clinical importance, we investigated and found that clonogenic survival of mutant EGFR NSCLCs in response to IR was reduced 500- to 1,000-fold compared with wild-type (WT) EGFR NSCLCs. Exogenous expression of either the L858R point mutant or the DeltaE746-E750 deletion mutant form of EGFR in immortalized human bronchial epithelial cells, p53 WT NSCLC (A549), or p53-null NSCLC (NCI-H1299) resulted in dramatically increased sensitivity to IR. We show that the majority of mutant EGFR NSCLCs, including those that contain the secondary gefitinib resistance T790M mutation, exhibit characteristics consistent with a radiosensitive phenotype, which include delayed DNA repair kinetics, defective IR-induced arrest in DNA synthesis or mitosis, and pronounced increases in apoptosis or micronuclei. Thus, understanding how activating mutations in the TKD domain of EGFR contribute to radiosensitivity should provide new insight into effective treatment of NSCLC with radiotherapy and perhaps avoid emergence of single agent drug resistance.     

Aberrant Activation of Cell Cycle Regulators, Centrosome Amplification, and Mitotic Defects

The centrosome that functions as a microtubule organizing center of a cell plays a key role in formation of bipolar mitotic spindles. Cells normally have either one (unduplicated) or two (duplicated) centrosomes. However, loss of the mechanisms controlling the numeral integrity of centrosomes leads to centrosome amplification (presence of more than two centrosomes), primarily via overduplication or fragmentation of centrosomes, resulting in defective mitosis and consequentially chromosome instability. Centrosome amplification frequently occurs in various cancers, and is considered as a major cause of chromosome instability. It has recently been found that ROCK2 kinase plays a critical role in promotion of centrosome duplication and amplification. Considering that ROCK2 is activated by Rho protein, and Rho is the immediate downstream target of many growth and hormone receptors, it is possible that such receptors may rather directly affect centrosome duplication and amplification. Indeed, constitutive activation of the receptors known to signal to the Rho pathway leads to promotion of centrosome amplification and chromosome instability in the Rho-ROCK2 pathway-dependent manner. These observations reveal an unexplored, yet important, oncogenic activities of those receptors in carcinogenesis; destabilizing chromosomes through promotion of centrosome amplification via continual activation of the Rho-ROCK2 pathway.     

The expression of BTG1 is downregulated in NSCLC and possibly associated with tumor metastasis

This study aimed to analyze the expression, clinical significance of B cell translocation gene 1 (BTG1) in nonsmall cell lung cancer (NSCLC) and the biological effect in its cell line by BTG1 overexpression. Immunohistochemistry and western blot were used to analyze BTG1 protein expression in 82 cases of NSCLC and 38 cases of normal tissues to study the relationship between BTG1 expression and clinical factors. Recombinant lentiviral vector was constructed to overexpress EMP-1 and then infect NSCLC H1299 cell line. Quantitative real-time RT-PCR and western blot were used to detect the mRNA level and protein of BTG1. 3-[4,5-dimethylthiazol -2-yl]-2,5-diphenyltetrazolium bromide (MTT) assay, cell apoptosis, cell cycles, and migration and invasion assays were also conducted as to the influence of the upregulated expression of BTG1 that might be found on H1299 cells biological effect. The level of BTG1 protein expression was found to be significantly lower in NSCLC tissue than normal tissues (P?<?0.05). Decreased expression of BTG1 was significantly correlated with lymph node metastasis, clinic stage, and histological grade of patients with NSCLC (P?<?0.05). Meanwhile, loss of BTG1 expression correlated significantly with poor overall survival time by Kaplan–Meier analysis (P?<?0.05). The result of biological function show that H1299 cell transfected BTG1 had a lower survival fraction; higher percentage of the G0/G1 phases; higher cell apoptosis; significant decrease in migration and invasion; and lower CyclinD1, Bcl-2, and MMP-9 protein expression compared with H1299 cell untransfected BTG1 (P?<?0.05). BTG1 expression decreased in NSCLC and correlated significantly with lymph node metastasis; clinical stage; histological grade; poor overall survival; cell proliferation; cell cycles; cell apoptosis; and migration and invasion in NSCLC cell by regulating CyclinD1, Bcl-2, and MMP-9 protein expression, suggesting that BTG1 may play important roles as a negative regulator to NSCLC cell.     

Centrosome amplification, chromosome instability and cancer development

During mitosis, two centrosomes form spindle poles and direct the formation of bipolar mitotic spindles, which is an essential event for accurate chromosome segregation into daughter cells. The presence of more than two centrosomes (centrosome amplification), severely disturbs mitotic process and cytokinesis via formation of more than two spindle poles, resulting in an increased frequency of chromosome segregation errors (chromosome instability). Destabilization of chromosomes by centrosome amplification aids acquisition of further malignant phenotypes, hence promoting tumor progression. Centrosome amplification occurs frequently in almost all types of cancer, and is considered as the major contributing factor for chromosome instability in cancer cells. Upon cytokinesis, each daughter cell receives one centrosome, and thus centrosome must duplicate once, and only once, before the next mitosis. If centrosomes duplicate more than once within a single cell cycle, centrosome amplification occurs, which is frequently seen in cells harboring mutations in some tumor suppressor proteins such as p53 and BRCA1. The recent studies have provided critical information for understanding how loss of these proteins allows multiple rounds of centrosome duplication. In this review, how centrosome amplification destabilizes chromosomes, how loss of certain tumor suppressor proteins leads to centrosome amplification, and the role of centrosome amplification in cancer development will be discussed.