两个遗传性非患肉性结直肠癌家系中MLH1和MSH2基因的突变检测

目的 确定两个遗传性非息肉性结直肠癌(hereditary nonpolyposis colorectal cancer,HNPCC)家系的致病基因,选择MLH1基因和MSH2基因进行突变检测.方法 采用聚合酶链反应结合DNA直接测序法,对两个遗传性非息肉性结直肠癌家系的患者进行MLH1基因和MSH2基因的突变检测;发现变异后,采用PCR-限制性片段长度多态性或直接测序法鉴定此变异是否属于突变.结果 在家系A的患者中发现了位于MLH1基因第3外显子内的新突变c.243_244 insA;在家系B的患者中发现了MSH2基因第7外显子内的c.1215_1218dupCCGA突变,这两个突变都导致了编码蛋白的提前终止.结论 MLH1基因的c.243_244insA突变和MSH2基因的c.1215_1218dupCCGA突变分别是导致家系A和家系B发生遗传性非息肉性结直肠癌的致病突变.     

中国人遗传性非息肉病性结直肠癌错配修复基因大片段缺失研究

目的了解中国人遗传性非息肉病性结直肠癌(hereditary nonpolyposis colorectal cancer．HNPCC)家系中MSH和MLH1基因大片段缺失情况及特点，以进一步完善中国人HNPCC家系遗传检测内容。方法取14个符合中国人HNPCC诊断标准的HNPCC家系肿瘤先证者外周血DNA，用荧光标记多重PCR技术结合GeneScan分析系统检测MSH2和MLH1基因大片段缺失。结果14例患者中有1例检测到MSH2基因第1～7外显子缺失，该家系另1例大肠癌患者和3个家系成员有同样的基因片段缺失。结论中国人HNPCC家系错配修复基因大片段缺失可能以MSH2比较常见。建议在中国人HNPCC家系遗传检测中常规包含错配修复基因大片段缺失检测。     

MLH1、MSH2基因 mRNA突变分析与遗传性非息肉性结直肠癌的基因诊断

目的检测胚系MLH1和MSH2基因mRNA突变，确立遗传性非息肉性结直肠癌（hereditary nonpolyposis colorectal cancer，HNPCC）家系。方法收集符合Amsterdam标准Ⅱ的12个家系14名家庭成员外周血，用特异引物和耐热性逆转录酶特异地逆转录MLH1和MSH2的RNA；利用长模板PCR扩增酶扩增逆转录产物（cDNA）；测序分析扩增产物。提取外周血的DNA，设计与利用上述方法检测出突变对应外显子的特异性引物，利用Taq DNA聚合酶扩增测序，以检测上述方法的有效性。结果利用基于外周血mRNA的方法，在6个家系中检出6个胚系突变，4个MLH1突变和2个MSH2突变，MLH1突变分别位于第8、12、16和第19外显子；MSH2突变分别位于第1和第2外显子。利用基于外周血DNA的方法，上述突变均在MLH1和MSH2相应的外显子中得到验证。突变类型为4个错义突变、1个同义突变和1个非编码区突变；其中5个突变国际上尚未报道；6个突变中有5个为病理性，分布于5个不同家系，该5个家系被确诊为HNPCC家系。结论基于外周血MLH1和MSH2 mRNA异常的检测能确诊HNPCC家系；该方法敏感、省时、节约成本。     

中国人遗传性非息肉病性结直肠癌MSH6基因胚系突变的测序研究

目的探讨中国人遗传性非息肉病性结直肠癌(hereditary nonpolyposis colorectal cancer,HNPCC)家系中MSH6基因胚系突变。方法采用PCR-直接测序的方法检测39个无胚系MSH2及MLH1基因突变、符合不同临床标准的中国人HNPCC家系先证者MSH6基因各外显子胚系突变;对137名正常人胚系基因组DNA进行错义突变相应外显子的测序分析。应用Envision二步法检测有突变的先证者肿瘤组织MSH6蛋白表达。结果在39个HNPCC先证者中共发现6个MSH6基因的胚系突变,分别位于第4、6、9和第10外显子;突变类型为4个错义突变、1个无义突变、1个剪接区的插入突变;对4个错义突变的相应外显子的测序分析显示:137名正常人胚系基因组DNA5例具有第6外显子1163密码子处的c.3488A>T的错义突变,约占3.65%(5/137),为单核苷酸多态性(single nucleotide polymorphism,SNP);其余错义突变在正常人群中均未发现。在6例有MSH6基因胚系突变家系的肿瘤组织中免疫组化染色除1例为SNP的肿瘤组织MSH6蛋白阳性表达外,其余均为阴性表达。经过查询国际HNPCC突变数据库及SNP数据库证实上述突变中5个为国际上尚未报道的病理性突变,1个为新发现的SNP。结论MSH6基因胚系突变在符合不同临床标准的中国人HNPCC中均起一定作用,对无MSH2及MLH1基因胚系突变的先证者行MSH6基因胚系突变的测序分析对确诊HNPCC家系是必要的。     

中国汉族和韩国朝鲜族非患肉性结直肠癌家系临床及遗传学表型的比较分析

目的 分析和比较汉族和朝鲜族遗传性非息肉性结直肠癌(hereditary nonpolyposis colorectal cancer,HNPCC)家系的临床及遗传学表型的异同点.方法 收集31个中国的汉族家系和63个韩国的朝鲜族家系先证者和家系成员的各项临床资料,对先证者外周血DNA进行相关基因hMLH和hMSH2的种系突变检测.应用聚合酶链反应-单链构象多态性分析或变性高效液相色谱法筛查突变,对结果异常的样本进行DNA测序.结果 31个汉族家系中共发生136例次恶性肿瘤,其中结直肠癌106例次,占所有肿瘤患者的77.9%,诊断年龄平均为(48.6±29.0)岁;其次为胃癌共14例.经突变检测,31例汉族先证者中有7例被检出含有hMLH1(3个)或hMSH2(4个)基因的病理性突变,总突变率为22.6%.其中错义突变2个、无义突变2个、移码突变2个、大片段缺失1个.63个朝鲜族家系中共发生293例次恶性肿瘤,其巾结直肠癌242例次,占所有肿瘤患者的82.6%,诊断年龄平均为(45.9±11.0)岁;胃癌同样也是第2大常见肿瘤类型,共发生21例.63例朝鲜族先证者中有19例被检测出含有hMLH1(17个)或hMSH2(2个)基因的突变,总突变率为30.2%.其中12个为移码突变,5个为错义突变,1个为无义突变,1个为剪接位点的碱基改变导致异常剪接.结论 (1)汉族与朝鲜族HNPCC家系在临床表现上相似,均有发病年龄轻、以远端结肠癌和直肠癌多见、多原发大肠癌发生率较两方国家低、肠外肿瘤以胃癌最多见等特点.(2)遗传表型方面,汉族与朝鲜族HNPCC家系的总突变率相似,但均低于西方国家的报道.两个种族的家系中的突变基因、突变类型和突变分布上存在差异及各自的特征.     

HNPCC发病中错配修复基因错义突变功能分析的研究进展

遗传性非息肉性结直肠癌(HNPCC)为最常见的常染色体显性遗传病之一，发病的直接原因为患者携带错配修复基因的胚系突变，其中错义突变约占已检突变的三分之一。因此建立有效的错义突变功能评估体系，确定检出突变的病因学作用具有重要意义。基于对错配修复系统功能的认识，目前对其基因编码蛋白质的功能研究，取得了突破性进展，主要从两个方面入手：（1）分析其功能活动过程中存在的蛋白质之间的相互作用，（2）分析错配修复基因功能活动的结果。     

遗传性非息肉病性结直肠癌的分子生物学研究

目的：探索遗传性非息肉病性结直肠癌（HNPCC）基因突变规律。方法：用聚合酶链式反应和PCR-SSCP对9例HN-PCC患者及其家系成员4例政审对照的hMSH2、hHLH1基因进行检测。结果：9例来自不同家庭的患者中,7例出现电泳条带异常;4例来自上述家系的无症状成员,其中2例出现电泳条带异常。结论：聚合酶链式反应和PCR-SSCP联合应用,可用于 hMSH2、hMLH1基因突变的检测。     

中国人家族性结直肠癌错配修复基因大片段变异分析

目的分析中国人家庭性结直肠癌错配修复基因大片段变异的特点。方法 采用多重连接探针扩增技术，分析32例具有家庭史结直肠癌、20例散发性结直肠癌患者错配修复基因MSH2的16个外显子、MLH1的19个外显子及7个其它基因外显子的拷贝数。研究工作包括：（1）双盲法分析阴性和阳性对照样本，完成方法学可靠性检验；（2）分析结直肠癌患者外周血细胞DNA，筛查MSH2和MLH1基因大片段变异。结果 多重连接探针扩增技术分析系统稳定检出阳性对照样本的DNA大片段缺失；在3/32（9.4%）具有家庭聚集性结直肠癌患者中检出遗传性MSH2基因DNA大片段缺失。而在20例散发性结直肠癌患者未检出这类突变。结论 中国人家族性结直肠癌患者中错配修复基因的大片段变异是频发事件，对此类患者的遗传检测应包含错配修复基因大片段变异的筛查。     

遗传性非息肉病大肠癌的基因异常

遗传性非息肉病大肠癌（HNPCC）是常染色体显性遗传疾患，也称为Lgnch综合征。推测占全大肠癌的5％一10％。家系内的特征是大肠癌的年青发病，右侧结肠好发，并为多发性癌。把限于患大肠癌的家系分为Lynch综合征I和以子宫体癌等多脏器癌为中心的家系分为Lynch综合征Ⅱ二个亚类。一般群体中其频度为（加上新种系突变）200～400人中有一人，其频度很高。用小随体标记物的基因重排多型的连锁分析，说明HNPCC的病原基因之一存在于第2号染色体短臂。用（CA）。等小随体标记物分析HNPCC患者的场组织，常观察到2—3＃基对的基因重排数与正…     

家族性直肠癌发病机理的线索

遗传性非息肉性结直肠癌(HNPCC)是指连续两代以上至少有3个结直肠癌(CRC)患者,其中一人在50岁以前得到诊断。在两个大家系的研究中,作者已发现该肿瘤的易感性与2号染色体上的一些标志紧密连锁。本文报道于D2S123标志对另外14个小     

Atypical HNPCC owing to MSH6 germline mutations: analysis of a large Dutch pedigree

Hereditary non-polyposis colorectal cancer (HNPCC) is the most common genetic susceptibility syndrome for colorectal cancer. HNPCC is most frequently caused by germline mutations in the DNA mismatch repair (MMR) genes MSH2 and MLH1. Recently, mutations in another MMR gene, MSH6 (also known as GTBP), have also been shown to result in HNPCC. Preliminary data indicate that the phenotype related to MSH6 mutations may differ from the classical HNPCC caused by defects in MSH2 and MLH1. Here, we describe an extended Dutch HNPCC family not fulfilling the Amsterdam criteria II and resulting from a MSH6 mutation. Overall, the penetrance of colorectal cancer appears to be significantly decreased (p<0.001) among the MSH6 mutation carriers in this family when compared with MSH2 and MLH1 carriers (32% by the age of 80 v >80%). Endometrial cancer is a frequent manifestation among female carriers (six out of 13 malignant tumours). Transitional cell carcinoma of the urinary tract is also relatively common in both male and female carriers (10% of the carriers). Moreover, the mean age of onset of both colorectal cancer (MSH6 v MSH2/MLH1 = 55 years v 44/41 years) and endometrial carcinomas (MSH6 v MSH2/MLH1 = 55 years v 49/48 years) is delayed. As previously reported, we confirm that the pattern of microsatellite instability, in combination with immunohistochemical analysis, can predict the presence of a MSH6 germline defect. The detailed characterisation of the clinical phenotype of this kindred contributes to the establishment of genotype-phenotype correlations in HNPCC owing to mutations in specific mismatch repair genes.     

RNA-based mutation analysis identifies an unusual MSH6 splicing defect and circumvents PMS2 pseudogene interference

Heterozygous germline mutations in one of the mismatch repair (MMR) genes MLH1, MSH2, MSH6, and PMS2 cause hereditary nonpolyposis colorectal cancer (HNPCC) or Lynch syndrome, a dominantly inherited cancer susceptibility syndrome. Recent reports provide evidence for a novel recessively inherited cancer syndrome with constitutive MMR deficiency due to biallelic germline mutations in one of the MMR genes. MMR-deficiency (MMR-D) syndrome is characterized by childhood brain tumors, hematological and/or gastrointestinal malignancies, and signs of neurofibromatosis type 1 (NF1). We established an RNA-based mutation detection assay for the four MMR genes, since 1) a number of splicing defects may escape detection by the analysis of genomic DNA, and 2) DNA-based mutation detection in the PMS2 gene is severely hampered by the presence of multiple highly similar pseudogenes, including PMS2CL. Using this assay, which is based on direct cDNA sequencing of RT-PCR products, we investigated two families with children suspected to suffer from MMR-D syndrome. We identified a homozygous complex MSH6 splicing alteration in the index patients of the first family and a novel homozygous PMS2 mutation (c.182delA) in the index patient of the second family. Furthermore, we demonstrate, by the analysis of a PMS2/PMS2CL "hybrid" allele carrier, that RNA-based PMS2 testing effectively avoids the caveats of genomic DNA amplification approaches; i.e., pseudogene coamplification as well as allelic dropout, and will, thus, allow more sensitive mutation analysis in MMR deficiency and in HNPCC patients with PMS2 defects.     

Six novel heterozygous MLH1, MSH2, and MSH6 and one homozygous MLH1 germline mutations in hereditary nonpolyposis colorectal cancer

Most hereditary nonpolyposis colorectal cancer (HNPCC) cases are caused by germline mutations of mismatch repair (MMR) genes (i.e., MLH1, MSH2, or MSH6). Here we describe six novel mutations in patients referred for genetic assessment. All of these mutations lead to premature translation termination. Five single base pair deletions lead to frameshift (MLH1: g.38-39insCCCA, g.1971del.T; MSH2: g.163del.C, g.746del.A; MSH6: g.3320del.A) and one nonsense mutation in MSH2 g.1030C>T leads to a stop codon: p.Q344X. In one patient, the previously described MLH1 nonsense mutation g.806C>G was found in a homozygous state. In this patient, the familial histories of both the mother and father suggested HNPCC syndrome. This patient developed colon cancer at 22 years of age, suggesting a more aggressive phenotype. The results of our study provide further insight into the mutational spectrum of MMR genes in HNPCC families.     

Germline mutations in MLH1, MSH2 and MSH6 in Korean hereditary non-polyposis colorectal cancer families

Hereditary non-polyposis colorectal cancer (HNPCC), the most common hereditary colon cancer syndrome, is a dominant disorder caused by germline defects in mismatch repair (MMR) genes. Identification of MMR gene mutations can have direct clinical implications in counseling and management of HNPCC families. We screened 44 HNPCC and 97 suspected HNPCC Korean families for germline mutations in three MMR genes: MLH1, MSH2 and MSH6. We identified twelve novel mutations: nine in MLH1(c.632_633insT, c.808_811delACTT, c.845C>G, c.1625A>C, c.1730+1delG, c.1907T>C, c.1918C>T, c.2104-2A>G and c.2170T>A), two in MSH2 (c.1886A>G, c.1316_1318delCCT) and one in MSH6 (c.3488A>T). In addition, two statically significant cSNPs in MLH1: c.1128T>C ( p=0.008 in HNPCC and p=0.037 in early-onset CRC) and c.2168C>A ( p<0.001 in HNPCC). Interestingly, the most frequent mutation, c.1757_1758insC in MLH1, was a founder mutation inherited from a common Korean ancestor.     

Conventional and tissue microarray immunohistochemical expression analysis of mismatch repair in hereditary colorectal tumors

Immunohistochemistry (IHC) of mismatch repair (MMR) proteins in colorectal tumors together with microsatellite analysis (MSI) can be helpful in identifying families eligible for mutation analysis. The aims were to determine sensitivity of IHC for MLH1, MSH2, and MSH6 and MSI analysis in tumors from known MMR gene mutation carriers; and to evaluate the use of tissue microarrays for IHC (IHC-TMA) of colon tumors in its ability to identify potential carriers of MMR gene mutations, and compare it with IHC on whole slides. IHC on whole slides was performed in colorectal tumors from 45 carriers of a germline mutation in one of the MMR genes. The TMA cohort consisted of 129 colon tumors from (suspected) hereditary nonpolyposis colorectal cancer (HNPCC) patients. Whole slide IHC analysis had a sensitivity of 89% in detecting MMR deficiency in carriers of a pathogenic MMR mutation. Sensitivity by MSI analysis was 93%. IHC can also be used to predict which gene is expected to harbor the mutation: for MLH1, MSH2, and MSH6, IHC on whole slides would have correctly predicted the mutation in 48%, 92%, and 75% of the cases, respectively. We propose a scheme for the diagnostic approach of families with (suspected) HNPCC. Comparison of the IHC results based on whole slides versus TMA, showed a concordance of 85%, 95%, and 75% for MLH, MSH2, and MSH6, respectively. This study therefore shows that IHC-TMA can be reliably used to simultaneously screen a large number of tumors from (suspected) HNPCC patients, at first in a research setting.     

Four novel MSH2 and MLH1 frameshift mutations and occurrence of a breast cancer phenocopy in hereditary nonpolyposis colorectal cancer

Hereditary nonpolyposis colorectal cancer (HNPCC) is caused by mutations of genes encoding for proteins of the mismatch repair (MMR) machinery. The majority of mutations occur in the MLH1 and MSH2 genes, and consist of splice-site, frameshift and nonsense changes, leading to loss of protein function. In this study, we screened 7 HNPCC families for MLH1/MSH2 mutations. Sequence changes were identified in 5 families. Four alterations were novel 1- or 2-bp deletions or insertions causing a frameshift and appearance of premature stop codons (MLH1: c.597-598delGA, c.1520-1521insT; MSH2: c.1444delA, c.119delG). The four small insertions/ deletions were located within stretches of simple repeated sequences. By reviewing the HNPCC mutation database, we found that the majority of 1-2 bp frameshift mutations similarly affects simple repetitive stretches, pointing to DNA polymerase slippage during replication as the most likely source of such errors. We also evaluated microsatellite instability (MSI) in a breast carcinoma (BC) from an MLH1 mutation carrier. While a colon cancer from the same individual showed MSI, the BC specimen was MSI-negative, indicating that development of the latter tumor was unrelated to MMR impairment, despite presence of a constitutional MLH1 mutation. Hum Mutat 17:521, 2001.     

Novel germline mutation (300-305delAGTTGA) in the human MSH2 gene in hereditary non-polyposis colorectal cancer (HNPCC)

Hereditary non-polyposis colorectal cancer (HNPCC) is a common hereditary syndrome characterized by the high incidence and early onset of colorectal cancer. The majority of the HNPCC families carry germline mutations in either the MSH2 or the MLH1 mismatch repair gene. A 46 year-old female patient whose family history fulfilled the Amsterdam criteria for HNPCC was diagnosed with undifferentiated adenocarcinoma of the transverse colon. Recognizing the Lynch 2 syndrome (the existance of multiple HNPCC related cancers in a pedigree), we used polymerase chain reaction followed by direct sequencing to screen the coding regions of both the MSH2 and the MLH1 genes for germline mutations in DNA from the patient. We detected a novel germline mutation (300-305delAGTTGA) in exon 2 of human MSH2. We noted microsatellite instability in four microsatellite loci. Immunohistochemistry showed a lack of expression of the MSH2 gene product in the tumor, suggesting that the mutation is a disease-causing mutation.     

Strategies for screening for hereditary non-polyposis colorectal cancer

Germline mutations in DNA mismatch repair genes (MLH1, MSH2, PMS1, PMS2, and MSH6) predispose to hereditary non-polyposis colorectal cancer (HNPCC). In the absence of pathognomonic clinical features, diagnosis of HNPCC is often based on family history. Microsatellite instability (MSI) analysis has successfully been used for screening colorectal cancer patients for HNPCC. The aim of this study was to evaluate the feasibility of a recently introduced logistical model based on family history data in detecting HNPCC patients with germline mutations. A series of 509 kindreds with a proband with colorectal cancer was studied. MSI analysis and subsequent germline mutation analysis (MLH1 and MSH2) in MSI positive patients had been performed previously. Of the 509 patients, 63 (12%) were MSI positive and 10 (2%) had a germline mutation in MLH1 or MSH2. The power of the logistical model was tested to determine its value in predicting the probability of a germline mutation. The model proposed a high probability in three out of 10 mutation positive cases when data on cancer in first degree relatives were considered (typically three generation pedigrees, consisting, on average, of eight people). Using extended pedigrees and family cancer data in the 10 mutation positive kindreds (an average of 38 family members available), the model suggested high probabilities in seven out of 10 mutation positive cases. We conclude that for the model to predict germline mutation cases, extensive pedigrees and family history data are required. When screening colorectal cancer patients for HNPCC, a model using a combination of family information and MSI has optimal specificity and sensitivity.     

Non-Hodgkin lymphoma related to hereditary nonpolyposis colorectal cancer in a patient with a novel heterozygous complex deletion in the MSH2 gene

Hereditary nonpolyposis colorectal cancer (HNPCC) is an autosomal disorder caused by mutations in DNA mismatch repair (MMR) genes. Tumors of the HNPCC-spectrum are associated with microsatellite instability (MSI) and loss of MMR protein expression. Lymphomas are not considered to be HNPCC-related tumors. We report and analyze a case of an HNPCC patient with three colorectal cancers and a B-cell non-Hodgkin lymphoma. Quantitative multiplex PCR of short fluorescent fragments detected a novel MSH2 rearrangement involving exons 9 and 10, which proved to be the pathogenic cause of the disease in the family. Tumor tissues including the lymphoma showed MSI and loss of MSH2 expression. Multiplex ligation-dependent probe amplification analysis revealed a somatic loss of the wild-type MSH2 allele in the lymphoma. These results support the fact that the total loss of a MMR gene can lead to lymphomagenesis, as seen in biallelic MMR-deficient families and knockout mice. Moreover, this is the first report of a B-cell non-Hodgkin lymphoma with a loss of the MSH2 protein expression, linked to a heterozygous germline MSH2 mutation in an HNPCC family.