Detection of Frameshift Mutations of the Transforming Growth Factor β Receptor Ⅱ in Gastric Cancers with Microsatellite Instability

OBJECTIVE To study the relationship among microsatellite instability （MSI）, frameshift mutations （FM） of the transforming growth factor β receptor Ⅱ （TGF β R Ⅱ）, methylation state of the hMLH1 promoter and hMLH1 protein expression level in gastric cancers, and to explore their relationship to gastric carcinogenesis. METHODS DNA was isolated from 101 gastric specimens and 5 microsatellite loci were detected. PCR, electrophoresis on denatured polyacrylamide gels and silver staining were performed to detect the MSI. The FMs of TGFβR Ⅱ were also screened with the same method. HMLH1 methylation was analyzed by methylation specific PCR （MSP） and sequencing. HMLH1 protein expression was detected using immunohistochemistry. RESULTS The incidence of MSIs was 53.7% and 0% in the cancers and normal tissues, respectively, with the frequency of MSIs being significantly higher in the gastric cancers compared to the normal gastric tissues （P〈0.05）. The frequency of hMLH1 methylation was 41.5%（17/41） in the gastric cancers and 0%（0/60） in the normal group. Decreased hMLH1 expression was observed in 94.1%（16/17） of cases exhibiting methylation. FMs of TGFβR Ⅱ were identified in 5 （62.5%） of the 8 samples with MSIH. In contrast, FMs were not found in MSI-L or microsatellite stable （MSS） cases. CONCLUSION MSIs and FMs of TGFβR Ⅱ may play an important role in gastric carcinogenesis. HMLH1 methylation is an important modification of the DNA which results in inactivation of hMLH1 and mismatch repair defects which lead to MSls and FMs of TGFβR Ⅱ.     

Microsatellite instability and gene mutations in transforming growth factor-beta type II receptor are absent in small bowel carcinoid tumors

BACKGROUND: Microsatellite instability (MSI) with concomitant mutations in the coding region of transforming growth factor-beta type II receptor (TGFbetaRII) results in an aberrant growth-regulatory phenotype in colorectal carcinomas. The authors postulated that a similar mechanism occurred during the malignant evolution of small bowel carcinoid tumors. METHODS: Mutational analysis of two coding regions in the TGFbetaRII gene associated with MSI and BAT-26 within intron 5 of the mismatch repair gene, hMSH2, was undertaken in small bowel carcinoids (n = 14), lymph node metasasis (n = 1) and liver metastases (n = 5). Quantitative PCR analysis [TAQMAN, Applied Biosystems, Foster City, CA] was then undertaken to examine gene alterations in mismatch repair genes (hMLH1 and hMSH2) in small bowel carcinoids (n = 7) and matched normal mucosa (n = 5). Staining was then analyzed using quantitative tissue array profiling (AQUA analysis) in a small bowel EC carcinoid tissue microarray (n = 55 tumors) with immunostaining against TGFbetaRII and MSH2. RESULTS: Mutational examination of the TFGbetaRII gene and BAT-26 demonstrated that MSI was not present in any carcinoid material. Q RT-PCR analysis demonstrated statistically significant increased message levels of hMSH2 but not hMLH1 in carcinoid tumors. Quantitative analysis of membrane TGFbetaRII immunostaining using AQUA demonstrated that TGFbetaRII expression was down-regulated (P < 0.0002) in thirty-three primary small bowel carcinoids that exhibited lymph node and liver metastases compared to normal mucosa. AQUA analysis of nuclear MSH2 immunostaining demonstrated no differences for MSH2 between normal tissue and carcinoid tumor metastasis. Small bowel carcinoids characterized by variable expression of TGFbetaRII, did not exhibit MSI and had no differences in MSH2 expression. CONCLUSIONS: The molecular events leading to the formation of carcinoid tumors in the small bowel were different from those resulting in epithelial carcinomas. The usually slow-growing and relatively nonaggressive carcinoid tumors had variable expression of TGFbetaRII but were associated with the retention of mismatch repair protein function and a microsatellite-stable phenotype.     

Mutational analysis of transforming growth factor beta receptor type II and DNA mismatch repair genes in sporadic endometrial carcinomas with microsatellite instability

To clarify how microsatellite instability (MI) is involved in carcinogenesis of sporadic endometrial carcinoma, we examined mutations of the transforming growth factor beta receptor type II (TGF beta RII) gene in 32 patients with MI-positive sporadic endometrial carcinoma. Moreover, mutations of 4 DNA mismatch repair (MMR) genes (hPMS1, hPMS2, hMLH1, hMSH2), which are considered to cause MI, were investigated as well. With respect to the TGF beta RII gene, mutations in the 10-bp polyadenine repeat sequence were observed in 7 of 29 informative cases (24%). Concerning MMR genes, a T to C point mutation at the -6 intronic splice acceptor site of exon 13 of hMSH2 was detected in 43% (6/14). However, there was no mutation in any exon of these 4 MMR genes. These results suggest that there is a carcinogenic mechanism via mutation of the TGF beta RII gene in some cases of MI-positive sporadic endometrial carcinoma. It seems unlikely that the unknown MMR genes are responsible for MI. The implication of the mutation at the intronic splice acceptor site in hMSH2 remains to be clarified.     

A dominant negative mutation of transforming growth factor-beta receptor type II gene in microsatellite stable oesophageal carcinoma

Recent investigations revealed microsatellite instability in colon cancers are associated with mutations of the transforming growth factor-beta receptor type II gene (TGF-beta RII) that encodes a transmembrane protein containing an intracellular serine/threonine kinase domain. Activation of TGF-beta receptor type I (RI) and RII by TGF-beta induces nuclear translocation of Smad proteins including Smad2 and Smad4 that have been originally identified as tumour suppressor genes. We have previously reported six cases with microsatellite instability in 32 oesophageal carcinomas. In this study, we analysed genetic mutations of TGF-beta RII, Smad2 and Smad4 in these oesophageal carcinoma tissues and established 16 cell lines. No genetic mutation was detected in any tissues or cell lines except one tissue sample of microsatellite stable oesophageal carcinoma, that is, a mis-sense mutation of glutamic acid to glutamine at codon 526 (E526Q) in the TGF-beta RII serine/threonine kinase domain. Interestingly, the mutant TGF-beta RII E526Q can completely inhibit TGF-beta-induction of nuclear translocation of Smad4 protein in oesophageal carcinoma cells. This mutation of TGF-beta RII that is not associated with microsatellite instability might make a dominant negative effect on TGF-beta signal transduction in oesophageal carcinoma.     

Damage to the transforming growth factor TGF-beta type II receptor gene and microsatellite instability in carcinoma cells of the gastrointestinal tract

In order to compare the frequency of damage to the transforming growth factor TGF-beta receptor type II gene (RII gene) and microsatellite instability (MIN) in oncogenesis of sporadic and hereditary cancer of gastrointestinal tract (GIT), 4 groups of carcinomas were analyzed. They included sporadic gastric (GC), family gastric (FGC), sporadic colorectal (CC) and hereditary nonpolyposis colorectal (HNPCC) carcinomas having appropriate clinical and pathological characteristics. Each group consisted of two types of carcinomas, one of them showing MIN. The RII gene damage occurred in 89% of GC (8 cases out of 9), 86% of CC (6 out of 7), 71% of FGC (5 out of 7), 50% of HNPCC (3 out of 6) for carcinomas coupled with MIN, whereas only in 6% (1 out of 18) of GC and 5% (1 out of 22) of CC for carcinomas without MIN. No damage to RII gene was found in the cases of hereditary carcinomas which did not show MIN though the number of cases analyzed was not sufficient for final conclusions (3 cases of FGC and 3 HNPCC). The data revealed a correlation between the MIN phenotype and mutations in RII gene both for sporadic (p < 0.001) and for hereditary (p < 0.02) cases. For all 4 groups the frequency of RII gene damage was found for early and advanced carcinomas. This suggests that the deficiency of TGF-beta receptor complex in both sporadic and hereditary carcinomas of GIT is revealed at early stages of tumor development and consequently may be responsible for tumor progression. The correlation between RII gene damages and MIN in GIT carcinoma cells suggests that genetic change predetermined the neoplasia of colorectal and gastric epithelium and partially overlapped for both sporadic and hereditary cases.     

Mutations of the transforming growth factor β type II receptor gene and microsatellite instability in gastric cancer

Forty-three sporadic gastric cancers were analyzed with regard to whether mutations of simple repeated sequences in the transforming growth factor β type II receptor (TβR-II) gene are associated with microsatellite instability (MSI) and gastric carcinogenesis. In 12 of the 43 cancers (28%), MSI was observed at least at 1 of the 2 microsatellite loci. Frameshift mutations of the TβR-II gene, all of which were 1 base deletion of 10 adenine repeats, were detected in 3 of 6 cancers, with MSI at 2 loci. However, mutations were not detected in 6 cancers, with MSI only at 1 locus and 31 cancers without MSI. Moreover, micro-analysis in these cases revealed that the mutant-type alleles of TβR-II were invariably common in different areas within the tumor, in contrast to the markedly variable alleles of microsatellite loci. Our results suggest that frameshift mutation of the TβR-II gene may be a critical event associated with MSI and may contribute to carcinogenesis of the stomach. One of the possible mechanisms of escape from growth control by TGFβ during gastric carcinogenesis could involve frameshift mutations of the TβR-II gene caused by DNA replication errors. © 1996 Wiley-Liss, Inc.     

Novel inactivating mutations of transforming growth factor-beta type I receptor gene in head-and-neck cancer metastases

Carcinoma cell lines are frequently refractory to transforming growth factor-beta (TGF beta)-mediated cell cycle arrest. Whether and how TGF beta signaling is disrupted in the majority of human tumors, however, remains unclear. To investigate whether TGF beta signaling might be disrupted by inactivation of the key signaling molecule, the TGF beta type I (T beta R-I) receptor, and whether or not T beta R-I inactivation is associated with late stage disease, we conducted a comprehensive structural analysis of the T beta R-I gene in fine-needle aspirates of 23 head-&-neck cancer metastases. We encountered 4 different mutations of T beta R-I, 3 of which have not been previously identified. In 1 case, we found a somatic intragenic 4-bp deletion predicting for a truncation of the receptor protein. This is the first example of a true loss-of-function mutation of T beta R-I in a human epithelial neoplasm. In 2 other cases, we identified missense mutations located between the juxtamembrane- and serine-threonine kinase domains. One of these resulted in an alanine-to-threonine substitution (A230T), which disrupts receptor signaling activity by causing rapid protein degradation within the endoplasmatic reticulum. This represents a novel mechanism of inactivation of a TGF beta signaling intermediate. Finally, we identified a serine-to-tyrosine substitution at codon 387 (S387Y) in a metastasis but not in the corresponding primary tumor. We had previously shown this S387Y mutant to be predominantly associated with breast cancer metastases and to have a diminished ability to mediate TGF beta-dependent signaling. In aggregate, these findings provide further support for the hypothesis that inactivation of the TGF beta signaling pathway occurs in a significant subset of human cancers.     

Relation of type II transforming growth factor-beta receptor to hepatic fibrosis and hepatocellular carcinoma

Hepatocarcinogenesis is closely related to hepatic fibrosis. In this study, we investigated the relationship of type II transforming growth factor-beta receptor (T beta RII) to hepatic fibrosis and hepatocellular carcinoma (HCC). In vivo: liver tissues were obtained from 30 patients (10 chronic hepatitis, 7 cirrhosis, 13 HCC). Protein expression and immunolocalization of T beta RII were examined by Western blot analysis and immunohistochemistry. In vitro: T beta RII protein expression in hepatoma cell lines (HepG2, Hep3B, HLE, HLF and Huh7) was examined by Western blot analysis. Next, we transfected T beta RII cDNA to Huh7, and compared the change of cell number and observed the induction of apoptosis after TGF-beta1 treatment using a FACScan flow cytometer. In vivo: T beta RII immunolocalization in liver tissues was significantly decreased in patients with HCC compared with that of patients with chronic hepatitis or liver cirrhosis. In Western blot analysis, T beta RII expression in tissues attenuated in comparison with that in non-tumor tissues in some patients with HCC. In vitro: T beta RII protein expression in HLE, HLF and Huh7 cells was weaker than that in HepG2 and Hep3B cells. In Huh7 cells transfected T beta RII cDNA, cell arrest and apoptosis were obviously induced. These results indicated that human HCC has a reduced expression of T beta RII for TGF-beta1. This may provide a selective growth advantage to HCC to escape the inhibitory growth signals of TGF-beta1, and may be linked with critical steps in the growth of hepatoma cells.     

Multipoint imprinting analysis in sporadic colorectal cancers with and without microsatellite instability

Disrupted imprinting is implicated in certain tumorigenesis. Since aberrant methylation has been described for a majority of microsatellite instability (MSI)-positive sporadic colorectal cancers, we have investigated alteration to the imprinting in 55 sporadic colorectal cancers with or without MSI. Loss of imprinting (LOI) of IGF2 and PEG1/MEST was observed in 42% and 35% of informative cancers, respectively. H19 expression was not detected in 24% of informative cancers. SNRPN and NDN retained monoallelic expression in all the cancers examined. These findings indicate no simultaneous disruption of the imprinted genes. LOI of IGF2 and PEG1/MEST was also observed in colorectal mucosa from almost all the patients with LOI in tumor tissue. Moreover, MSI-positive colorectal cancers exhibit LOI of IGF2 with a high frequency compared to MSI-negative cancers (P=0.013). These observations, consistent with a previous report, establish an association between LOI of IGF2 and MSI in colorectal cancers and provide insight into susceptibility of tumor development.     

Chk1 frameshift mutation in sporadic and hereditary non-polyposis colorectal cancers with microsatellite instability.

AIM: Protein kinase Chk1 (hChk1) is essential in human cells for cell cycle arrest in response to DNA damage, and has been shown to play an important role in the G2/M checkpoint. The BRAF mutations have been suggested to be linked with defective mismatch repair in colorectal cancers. The aim of this study was to investigate whether a frameshift mutation within the Chk1 gene contribute to the development or progression of eastern sporadic and hereditary non-polyposis colorectal cancer (HNPCC) with microsatellite instability (MSI). METHODS: We analyzed MSI using the 6 microsatellite markers and a frameshift mutation in the BRAF gene and in poly(A)9 within the Chk1 gene in 51 sporadic colorectal cancer and 14 HNPCC specimens. RESULTS: Eleven of the 51 sporadic colorectal cancers and all of the 14 HNPCCs were MSI-positive. Chk1 frameshift mutations were observed in 2 and 3 sporadic colon cancers and HNPCC, respectively, whereas no BRAF mutations were detected in these samples. Interestingly, all cases with the Chk1 frameshift mutation had high-frequency MSI. CONCLUSION: These results suggest that the Chk1 gene is a target of genomic instability in MSI-positive colorectal cancers and that the Chk1 framshift mutations might be involved in colorectal tumourigenesis through a defect in response to DNA damage in a subset of sporadic colorectal cancers and HNPCCs.     

微卫星不稳定散发性大肠癌的临床病理特征和DNA倍体研究

目的:探讨微卫星不稳定的散发性大肠癌的临床病理特征及微卫星不稳定表型和DNA倍体类型的关系。方法:对71例散发性大肠癌行BAT25和BAT26两个位点的微卫星不稳定检测和流式细胞术倍体分析,探讨微卫星不稳定状态和临床病理特征及DNA倍体类型的关系。结果:微卫星不稳定的阳性率为9.86%(7/71),微卫星不稳定表型和发病部位、组织学类型及分化程度相关(P<0.05),而与性别、年龄、淋巴结转移和分期无关。微卫星不稳定的散发性大肠癌中右半结肠癌和低分化腺癌的比例高于微卫星稳定者。68例患者检出二倍体和异倍体分别为18和50例,微卫星不稳定表型者5例为二倍体,因此和DNA倍体类型显著相关(P=0.012)。结论:微卫星不稳定的散发性大肠癌好发于右半结肠,具有低分化腺癌的倾向,多为二倍体。     

胃癌组织Ⅱ型β转化生长因子受体基因突变的研究

目的　 β转化生长因子 ( transforming growth factorβ,TGF- β) 型受体 TGF- βR 基因突变是某些肿瘤细胞逃逸 TGF- β生长抑制调控的机制之一。有报道表明 TGF- βR 基因的两个突变热点 ( c DNA70 9- 718,1931- 1936)在人类结肠癌细胞系有高的突变率。据此我们检测了 TGF- βR 基因这两个热点在 4 4例人胃癌组织的改变。方法　组织 DNA提取后进行 PCR- SSCP银染分析 ,将阳性标本进行荧光测序。结果　在 TGF- β R 的 c DNA70 9- 718位点突变率为 6.8% ( 3/ 4 4 ) ,而另一位点 c DNA1931- 1936未发现突变 ( 0 / 4 4 )。结论　TGF- β R 基因在人胃癌组织较之结肠癌具有低的突变率。