Genomic rearrangements of the APC tumor-suppressor gene in familial adenomatous polyposis

Germline mutations of the adenomatous polyposis coli (APC) tumor-suppressor gene result in the hereditary colorectal cancer syndrome familial adenomatous polyposis (FAP). Almost all APC mutations that have been identified are single-nucleotide alterations, small insertions, or small deletions that would truncate the protein product of the gene. No well-characterized intragenic rearrangement of APC has been described, and the prevalence of this type of mutation in FAP patients is not clear. We screened 49 potential FAP families and identified 26 different germline APC mutations in 30 families. Four of these mutations were genomic rearrangements resulting from homologous and nonhomologous recombinations mediated by Alu elements. Two of these four rearrangements were complex, involving deletion and insertion of nucleotides. Of these four rearrangements, one resulted in the deletion of exons 11 and 12 and two others resulted in either complete or partial deletion of exon 14. The fourth rearrangement grossly altered the sequence within intron 14. Although this rearrangement did not affect any coding sequence of APC at the genomic DNA level, it caused inappropriate splicing of exon 14. These rearrangements were initially revealed by analyzing cDNAs and could not have been identified by using mutation detection methods that screened each exon individually. The identification of a rearrangement that did not alter any coding exons yet affected the splicing further underscores the importance of using cDNA for mutation analysis. The identification of four genomic rearrangements among 30 mutations suggests that genomic rearrangements are frequent germline APC mutations.     

Identification of genomic deletions of the APC gene in familial adenomatous polyposis by two independent quantitative techniques

Large deletions in the APC (adenomatous polyposis coli) gene, causing familial adenomatous polyposis (FAP), cannot easily be detected by conventional mutation-detection techniques. Therefore, we have developed two independent quantitative methods for the detection of large deletions, encompassing one or more exons, of APC. Multiplex ligation-dependent probe amplification (MLPA) is performed in one reaction for the initial quantification of all APC exon copy numbers. Subsequently, quantitative real-time PCR (QRT-PCR) is used to verify the results obtained in the MLPA reaction. The identification of a deletion of the whole APC gene in a patient with classical FAP is described. The mutation was detected with the two quantitative methods and further verified on chromosomal level by the use of FISH (fluorescence in situ hybridization) on metaphase spreads. Furthermore, a large deletion covering exons 11-13 of the APC gene was detected in two apparently unrelated families. This deletion was further verified and characterized with long-range PCR. The MLPA test ensures a sensitive high-throughput screening for large deletions of the APC gene and can easily be implemented in the diagnostic testing for FAP.     

Different familial adenomatous polyposis phenotypes resulting from deletions of the entire APC exon 15

Germline mutations of the adenomatous polyposis coli ( APC) gene cause familial adenomatous polyposis (FAP), an autosomal, dominantly inherited disease that predisposes patients to colorectal cancer. The APC gene is composed of 15 coding exons and encodes an open reading frame of 8.5 kb. The 3' 6.5 kb of the APCopen reading frame is encoded by a single exon, exon 15. Most identified APC mutations are at the 5' half of the APC open reading frame and are nucleotide substitutions and small deletions or insertions that result in truncation of the APC protein. Very few well-characterized gross alterations of APC have been reported. Patients with FAP typically develop hundreds to thousands of colorectal tumors beginning in their adolescence. A subgroup of patients with FAP who develop fewer tumors at an older age have what is called attenuated FAP (AFAP). Accumulating evidence indicates that patients carrying germline APC mutations in the first four coding exons, in the alternatively spliced region of exon 9, or in the 3' half of the coding region usually develop AFAP. We characterized two germline APC alterations that deleted the entire APC exon 15 as the result of 56-kb and 73-kb deletions at the APC locus. A surprising finding was that one proband had the typical FAP phenotype, whereas the other had a phenotype consistent with that of AFAP.     

Molecular nature of chromosome 5q loss in colorectal tumors and desmoids from patients with familial adenomatous polyposis

Summary Familial adenomatous polyposis (FAP), which includes familial polyposis coli (FPC) and the Gardner syndrome (GS), is a genetically determined premalignant disease of the colon inherited by a locus (APC) mapping within 5q15–q22. To elucidate the role of 5q loss in FAP tumorigenesis, we analysed 51 colorectal tumors and seven desmoids from 19 cases of FPC and five GS patients, as well as 15 sporadic colon cancers. RFLP analysis revealed a high incidence of allelic deletion in hereditary colon cancers as well as in sporadic colon cancers with a peak at the APC locus. APC loss resulted primarily from interstitial deletion or mitotic recombination. Combined tumor and pedigree analysis in a GS family revealed loss of normal 5q alleles in three tumors, including a desmoid tumor, which suggests the involvement of hemizygosity or homozygosity of the defective APC gene in colon carcinogenesis and, possibly, in extracolonic neoplasms associated with FAP.     

Attenuated familial adenomatous polyposis due to a mutation in the 3′ part of the APC gene. A clue for understanding the function of the APC protein

The identification of germline mutations in a large number of clinically well-characterised patients with familial adenomatous polyposis (FAP) has allowed the unravelling of several genotype-phenotype relationships that can now be interpreted in the light of the structure and functional domains of the adenomatous polyposis coli (APC) protein. An attenuated phenotype has been found to be associated with mutations at the 5 end of the gene, while a severe clinical expression was found in patients with the most common mutation at codon 1309. So far, only few mutations in the 3 half of the gene have been published. We report on two families with a rather mild phenotype due to a frameshift mutation at codon 1597. These families may represent a clue for defining a 5 border for the occurrence of a second region of attenuated FAP that is localised in the 3 part of the APC gene. We propose a model to explain the relationship between the severity of the disease and the size of the mutant APC protein.     

Topoisomerase-I- and Alu-mediated genomic deletions of the APC gene in familial adenomatous polyposis

Germline mutation in the adenomatous polyposis coli (APC) gene results in familial adenomatous polyposis (FAP), a heritable form of colorectal cancer. We have previously reported two novel mutations that delete exons 11 and 14 of the APC gene, respectively, at the cDNA level without any splice junction defects at the genomic level. We describe here the precise breakpoints of the two mutations and the possible mechanisms leading to the genomic rearrangement. The first rearrangement is most likely a topoisomerase-I-mediated non-homologous recombination resulting in a 2-kb deletion that deletes exon 11 of the APC gene. Both 5' and 3' breakpoints have two topoisomerase I recognition sites and runs of pyrimidines within the 10-bp sequences in their vicinity. Further, the 3' breakpoint has an adenine-thymidine-rich region. This is probably the first report of a topoisomerase-I-mediated germline mutation in a tumor suppressor gene. The second rearrangement is most likely an Alu-Alu homologous recombination resulting in a 6-kb deletion encompassing exon 14. The Alu elements at the 5' and 3' breakpoints include the 26-bp core sequence thought to stimulate recombination. In both rearrangements, partial sequences from the long interspersed nuclear element family are in the vicinity of the breakpoints. Other than serving as markers for regions of DNA damage, their precise role in the recombination events, if any, is unclear. Both deletions result in truncated APC proteins missing the beta-catenin- and axin-binding domains, resulting in severe polyposis and cancer.     

Identification of APC gene mutations in Italian adenomatous polyposis coli patients by PCR-SSCP analysis

The APC gene is a putative human tumor-suppressor gene responsible for adenomatous polyposis coli (APC), an inherited, autosomal dominant predisposition to colon cancer. It is also implicated in the development of sporadic colorectal tumors. The characterization of APC gene mutations in APC patients is clinically important because DNA-based tests can be applied for presymptomatic diagnosis once a specific mutation has been identified in a family. Moreover, the identification of the spectrum of APC gene mutations in patients is of great interest in the study of the biological properties of the APC gene product. We analyzed the entire coding region of the APC gene by the PCR–single-strand conformation polymorphism method in 42 unrelated Italian APC patients. Mutations were found in 12 cases. These consist of small (5–14 bp) base-pair deletions leading to frameshifts; all are localized within exon 15. Two of these deletions, a 5-bp deletion at position 3183–3187 and a 5-bp deletion at position 3926–3930, are present in 3/42 and 7/42 cases of our series, respectively, indicating the presence of mutational hot spots at these two sites.     

DHPLC analysis of adenomatous polyposis coli (APC) mutations using ready-to-use APC plates: simple detection of multiple base pair deletion mutations

The adenomatous polyposis coli (APC), which is the susceptible gene for familial adenomatous polyposis (FAP) and sporadic colorectal cancer, spans 15 exons. The open reading frame of APC is 8529 bp, which encodes 2843 amino acids. Conventional genetic screening involves extensive time as well as high cost and labor. Thus, we developed a novel APC ready-to-use plate for high-throughput mutational analysis by denaturing high performance liquid chromatography (DHPLC). To prepare the ready-to-use APC plate, all 38 primer pairs and PCR mixtures were aliquoted into individual wells of a 96-well plate, and frozen at -20 degrees C until use. All 38 PCR primers were designed to be amplified at the same temperature (52 degrees C). We examined a total of 27 FAP patient samples with APC germline mutations (17 for multiple bp deletions, 1 for 1 bp deletion, 9 for nonsense mutations) and 50 APC-negative noncarriers. All 17 multiple bp deletion mutations were detected during the initial 50 degrees C running analysis and thus ruled out for further analyses. All other mutations were clearly detected under specific optimized conditions. More than 50% of the APC germline mutations were multiple base pair deletions and efficiently selected by omitting time-consuming partial denaturing conditions.     

Eight novel inactivating germ line mutations at the APC gene identified by denaturing gradient gel electrophoresis.

Familial adenomatous polyposis (FAP) is a dominantly inherited condition predisposing to colorectal cancer. The recent isolation of the responsible gene (adenomatous polyposis coli or APC) has facilitated the search for germ line mutations in affected individuals. Previous authors have used the RNase protection assay and the single-strand conformation polymorphisms procedure to screen for mutations. In this study we used denaturing gradient gel electrophoresis (DGGE). DGGE analysis of 10 APC exons (4, 5, 7, 8, 9, 10, 12, 13, 14, and part of 15) in 33 unrelated Dutch FAP patients has led to the identification of eight novel germ line mutations resulting in stop codons or frameshifts. The results reported here indicate that (1) familial adenomatous polyposis is caused by an extremely heterogeneous spectrum of point mutations; (2) all the mutations found in this study are chain terminating; and (3) DGGE represents a rapid and sensitive technique for the detection of mutations in the unusually large APC gene. An extension of the DGGE analysis to the entire coding region in a sufficient number of clinically well-characterized, unrelated patients will facilitate the establishment of genotype-phenotype correlations. On the other hand, the occurrence of an extremely heterogeneous spectrum of mutations spread throughout the entire length of the large APC gene among the FAP patients indicates that this approach may not be useful as a rapid presymptomatic diagnostic procedure in a routine laboratory. Nevertheless, the above DGGE approach has incidentally led to the identification of a common polymorphism in exon 13. Such intragenic polymorphisms offer a practical approach to a more rapid procedure for presymptomatic diagnosis of FAP by linkage analysis in informative families.     

Exclusion of the APC gene as the cause of a variant form of familial adenomatous polyposis (FAP)

Familial adenomatous polyposis (FAP) is a premalignant disease inherited as an autosomal dominant trait, characterized by hundreds to thousands of polyps in the colorectal tract. Recently, the syndrome has been shown to be caused by mutations in the APC (adenomatous polyposis coli) gene located on chromosome 5q21. We studied two families that both presented a phenotype different than that of the classical form of FAP. The most important findings observed in these two kindreds are (a) low and variable number of colonic polyps (from 5 to 100) and (b) a slower evolution of the disease, with colon cancer occurring at a more advanced age than in FAP in spite of the early onset of intestinal manifestations. To determine whether mutations of the APC gene are also responsible for this variant syndrome, linkage studies were performed by using a series of markers both intragenic and tightly linked to the APC gene. The results provide evidence for exclusion of the APC gene as the cause of the variant form of polyposis present in the two families described.     

APC mutation in the alternatively spliced region of exon 9 associated with late onset familial adenomatous polyposis

Germ-line mutations in the adenomatous polyposis coli (APC) gene are responsible for familial adenomatous polyposis (FAP). Genotype-phenotype correlation studies in patients with FAP have demonstrated associations of certain variants of the disease with mutations at specific sites within the APC gene. In a large FAP family, we identified a frameshift mutation located in the alternatively spliced region of exon 9. Phenotypic studies of affected family members showed that the clinical course of FAP was delayed, with gastrointestinal symptoms and death from colorectal carcinoma occurring on average 25 and 20 years later than usual, respectively. The numbers of colorectal adenomas differed markedly among affected individuals and the location of colorectal cancer lay frequently in the proximal colon. Our findings suggest that the exon 9 mutation identified in the pedigree is associated with late onset of FAP. The atypical phenotype may be explained by the site of the mutation in the APC gene. Analysis of the APC protein product indicated that the exon 9 mutation did not result in a detectable truncated APC protein. Given the location of the mutation within an alternatively spliced exon of APC, it is conceivable that normal APC proteins are produced from the mutant allele by alternative splicing.     

The familial adenomatous polyposis region exhibits many different haplotypes

In the present study, we used five different polymorphic markers to construct the haplotype at the adenomatous polyposis coli (APC) locus in families with familial adenomatous polyposis (FAP) and in the normal Italian population. Non-ambiguous haplotypes were reconstructed from 246 normal chromosomes and 65 FAP chromosomes. In the control population, the four polymorphisms intragenic to APC gave rise to 16 haplotypes, the most common of which (II and XV) accounted for over 50% of all chromosomes. In FAP patients, 13 haplotypes were found but their distribution was not statistically different from normal subjects. Eighty complete chromosomal haplotypes (many fewer than the theoretical maximum of 208) for the five polymorphic sites assayed were observed in the control population, 35 being found in the FAP patients. We compared the distribution of these haplotypes within the two groups; no statistically significant differences between normal and FAP chromosomes were found. The elevated heterogeneity of FAP chromosomes was clearly confirmed by the observation that 19 patients who carried one or other of the two most common APC mutations (nt 3183 and nt 3927) showed 18 different haplotypes. On the basis of these results, we were not able to identify a founder FAP chromosome. Various mechanisms are presented to explain this observation. Received: 5 November 1997 / Accepted: 3 February 1998     

Genetic linkage map of six polymorphic DNA markers around the gene for familial adenomatous polyposis on chromosome 5.

A genetic linkage map of six polymorphic DNA markers close to the gene (APC) for familial adenomatous polyposis (FAP) on chromosome 5q is reported. One hundred fifty-five typed members of nine FAP kindred provided more than 90 meioses for linkage analysis. A number of crucial recombination events have been identified which are informative at three or more loci, allowing confident ordering of parts of the map. There was no evidence of genetic heterogeneity, with all families showing linkage of at least one chromosome 5 marker to the gene. Recombination data and two-point linkage analysis support a locus order of centromere-pi 227-C11P11-ECB27-L5.62-APC-EF5.44-YN5.48-telomer e, although EF5.44 could lie in the interval L5.62-APC or ECB27-L5.62. No recombinants were identified between APC and either EF5.44 or YN5.48, but published deletion mapping in colorectal carcinomas and linkage analysis in FAP suggest that YN5.48 is 1-3 cM from APC. The present study suggests that YN5.48 and L5.62 delineate a small region of chromosome 5 within which the EF5.44 locus lies very close to the APC gene. These data not only allow use of flanking markers for presymptomatic diagnosis of FAP but also provide a high-density map of the region for isolation of the APC gene itself and for further assessment of the role of chromosome 5 deletions in the biology of sporadic colorectal cancer.     

Germline mutations in the 3′ part of APC exon 15 do not result in truncated proteins and are associated with attenuated adenomatous polyposis coli

Familial adenomatous polyposis (FAP) is an inherited predisposition to colorectal cancer characterized by the development of numerous adenomatous polyps predominantly in the colorectal region. Germline mutations in the adenomatous polyposis coli (APC) gene are responsible for most cases of FAP. Mutations at the 5′ end of APC are known to be associated with a relatively mild form of the disease, called attenuated adenomatous polyposis coli (AAPC). We identified a frameshift mutation in the 3′ part of exon 15, resulting in a stop codon at 1862, in a large Dutch kindred with AAPC. Western blot analysis of lymphoblastoid cell lines derived from affected family members from this kindred, as well as from a previously reported Swiss family carrying a frameshift mutation at codon 1987 and displaying a similar attenuated phenotype, showed only the wild-type APC protein. Our study indicates that chain-terminating mutations located in the 3′ part of APC do not result in detectable truncated polypeptides and we hypothesize that this is likely to be the basis for the observed AAPC phenotype. Received: 18 June 1996 / Revised: 8 July 1996     

家族性腺瘤息肉病的遗传病因学研究进展

家族性腺瘤息肉病(FAP)是第二常见的遗传性结直肠癌综合征,多在青春期发病,发病率约1/10000,主要临床表现为大肠中多发的腺瘤性息肉,是一种结直肠癌的癌前病变,如果不予治疗,几乎100%的患者会发展成为结直肠癌。一直以来,FAP被认为是一种常染色体显性遗传疾病,发病由APC基因胚系突变引起。根据临床特点的不同,FAP患者可以分为经典型FAP(CFAP)和轻表型FAP(AFAP)。然而近年来,在一些无APC基因胚系突变的FAP患者中发现了Mut YH基因的双等位基因突变。这种由于Mut YH基因双等位基因突变而无APC生殖突变所引起的临床综合征定义为Mut YH基因相关性息肉病[2](MAP)。MAP为常染色体隐性遗传,是一种特殊类型的FAP。另外,很多研究表明,APC基因的突变位点与结肠腺瘤病的严重程度、癌变的风险程度和某些肠外表现相关。MAP的发现和对FAP基因型-表型相关性的研究,完善了对FAP遗传病因学的认识,对于FAP患者及高危亲属的合理防治和预后具有重要的意义。     

Novel germline mutations in the APC gene and their phenotypic spectrum in familial adenomatous polyposis kindreds

Among 23 germline mutations identified in the APC screening of 45 familial adenomatous polyposis (FAP) patients, we have found 10 different novel frameshift mutations in 11 apparently unrelated patients. In two cases, an additional missense mutation was detected. One previously described as a causative germline mutation (S2621C), associated with a 1-bp insertion (4684insA) on the opposite allele, did not segregate with the FAP phenotype in the family and was therefore considered as being non-pathogenic. The other (Z1625H) was located 2 codons before a 1-bp deletion (4897delC). Both mutations were transmitted together from an FAP father to his affected son. The FAP phenotype of these 10 novel truncating mutations was clinically documented within their kindreds. Important variability was observed in the phenotype. Interestingly, we noted that a mutation (487insT) localized at the boundary of the 5’ attenuated APC phenotype region in two unrelated families resulted in classical polyposis. A clear-cut genotype-phenotype correlation could be drawn in only two instances. In one family, a 4684insA mutation led to a mild polyposis associated with early inherited osteomas and, in the family bearing the double mutation (Z1625H+4897delC), the phenotype was obviously a 3′ attenuated type. Our data illustrate the wide genetic and phenotypic heterogeneity of this condition between and within the families, making the establishment of correlations complex and any prediction in this disease difficult, although targeting the mutation site may be helpful in some specific cases. Received: 11 February 1997 / Accepted: 11 April 1997     

Genotype-phenotype correlation between position of constitutional APC gene mutation and CHRPE expression in familial adenomatous polyposis

Mutations in the adenomatous polyposis coli (APC) gene are responsible for the disease familial adenomatous polyposis (FAP), a dominantly inherited predispostion to colorectal cancer. The most common extra-colonic manifestation is congenital hypertrophy of the retinal pigment epithelium (CHRPE), expressed in up to 90% of FAP kindreds. Chain-terminating APC mutations were characterised in 26 unrelated FAP patients. Results show that CHRPE expression is determined by the length of truncated protein product. CHRPE is therefore the first extracolonic manifestation of FAP to be shown to be under the control of the APC mutation site and should facilitate the detection of constitutional APC mutations in FAP kindreds.     

Cryptic Genomic Rearrangements in Three Patients with 46,XY Disorders of Sex Development

Background

46,XY disorders of sex development (46,XY DSD) are genetically heterogeneous conditions. Recently, a few submicroscopic genomic rearrangements have been reported as novel genetic causes of 46,XY DSD.

Methodology/Principal Findings

To clarify the role of cryptic rearrangements in the development of 46,XY DSD, we performed array-based comparative genomic hybridization analysis for 24 genetic males with genital abnormalities. Heterozygous submicroscopic deletions were identified in three cases (cases 1–3). A ∼8.5 Mb terminal deletion at 9p24.1–24.3 was detected in case 1 that presented with complete female-type external genitalia and mental retardation; a ∼2.0 Mb interstitial deletion at 20p13 was identified in case 2 with ambiguous external genitalia and short stature; and a ∼18.0 Mb interstitial deletion at 2q31.1–32 was found in case 3 with ambiguous external genitalia, mental retardation and multiple anomalies. The genital abnormalities of case 1 could be ascribed to gonadal dysgenesis caused by haploinsufficiency of DMRT1, while those of case 3 were possibly associated with perturbed organogenesis due to a deletion of the HOXD cluster. The deletion in case 2 affected 36 genes, none of which have been previously implicated in sex development.

Conclusions/Significance

The results indicate that cryptic genomic rearrangements constitute an important part of the molecular bases of 46,XY DSD and that submicroscopic deletions can lead to various types of 46,XY DSD that occur as components of contiguous gene deletion syndromes. Most importantly, our data provide a novel candidate locus for 46,XY DSD at 20p13.     

Presymptomatic direct detection of adenomatous polyposis coli (APC) gene mutations in familial adenomatous polyposis

The recent identification of the familial adenomatous polyposis (FAP) gene (designated as APC) enables conclusive genetic testing of at-risk family members for the specific mutation in families in which the germline gene mutation has been characterized. Presymptomatic molecular diagnosis of FAP was performed by direct direction of mutations in lymphocyte DNA in four families. Each of the families has a different mutation of the APC gene. Twenty-seven offspring of affected individuals (a priori risk of 50%) were tested. Ten of the 27 had already developed clinical features of FAP. Of the remaining seventeen, two had had a negative colon exam at an early age, and nine had never had colon exams (mean age, 12.1±3.1 SD years). Six children from this group (54%) were found to carry their affected parent's mutation. No change in the conventional FAP colon screening regimen is recommended for these children. In contrast, when direct tests indicate that an individual does not have the FAP mutation, we recommended that screening be decreased. Reduction of uncertainty for at-risk FAP family members is an important benefit of genetic testing.     

The type of somatic mutation at APC in familial adenomatous polyposis is determined by the site of the germline mutation: a new facet to Knudson's 'two-hit' hypothesis.

APC is often cited as a prime example of a tumor suppressor gene. Truncating germline and somatic mutations (or, infrequently, allelic loss) occur in tumors in FAP (familial adenomatous polyposis). Most sporadic colorectal cancers also have two APC mutations. Clues from attenuated polyposis, missense germline variants with mild disease and the somatic mutation cluster region (codons 1,250-1,450) indicate, however, that APC mutations might not result in simple loss of protein function. We have found that FAP patients with germline APC mutations within a small region (codons 1,194-1,392 at most) mainly show allelic loss in their colorectal adenomas, in contrast to other FAP patients, whose 'second hits' tend to occur by truncating mutations in the mutation cluster region. Our results indicate that different APC mutations provide cells with different selective advantages, with mutations close to codon 1,300 providing the greatest advantage. Allelic loss is selected strongly in cells with one mutation near codon 1,300. A different germline-somatic APC mutation association exists in FAP desmoids. APC is not, therefore, a classical tumor suppressor. Our findings also indicate a new mechanism for disease severity: if a broader spectrum of mutations is selected in tumors, the somatic mutation rate is effectively higher and more tumors grow.