DNA array-based method for detection of large rearrangements in the BRCA1 gene

In most families with multiple cases of breast and ovarian cancer, the cancer appears to be associated with germline alterations in BRCA1 or BRCA2. However, somatic mutations in BRCA1 and BRCA2 in sporadic breast and ovarian tumors are rare, even though loss of heterozygosity in BRCA1 and BRCA2 loci in these tumors appears frequently. This may be attributed to mutation detection assays that detect alterations in the coding regions and splice site junctions, but that miss large gene rearrangements. To look specifically for mutations such as large gene rearrangements that span several kilobases (kb) of genomic DNA, we have developed a fluorescence DNA microarray assay. This assay rapidly and simultaneously screens for such rearrangements along the entire gene. In our screen of 15 malignant ovarian tumors, we found one sample with a novel 3-kb deletion encompassing exon 17 of BRCA1 that leads to a frameshift mutation. This deletion was not detected in the corresponding constitutive DNA. Our results indicate that, whereas somatic mutations in BRCA1 appear to be rare in ovarian cancers, the search for large gene rearrangements should be included in any BRCA1 mutational analysis. Furthermore, the method described in this report has the potential to screen clinical tumor samples for genomic rearrangements simultaneously in a large number of cancer-associated genes.     

Complex germline rearrangement of BRCA1 associated with breast and ovarian cancer

Germline mutations in BRCA1 predispose to breast and ovarian cancer. Most germline BRCA1 mutations are small insertions, deletions, or single base pair (bp) substitutions. These mutation classes are rarely found as somatic mutations in BRCA1. On the other hand, somatic deletions of multiple mega-base pairs (Mb) including BRCA1, as reflected by loss of heterozygosity, occur frequently in both inherited and sporadic breast and ovarian cancers. To determine whether deletions or rearrangements of hundreds to thousands of bps might contribute to inherited mutation in BRCA1, we developed a Long PCR strategy for screening the entire genomic BRCA1 locus in high-risk families. We evaluated genomic DNA from one high-risk family of European ancestry with BRCA1-linked cancer in which no genomic mutations had been detected using conventional methods. Long PCR revealed a complex mutation, g.12977 ins10 del1039 (based on GenBank L78833), comprising an inverted duplication and deletion in BRCA1 that removes portions of exon 3 and intron 3, including the 5' splice site for intron 3. As a result of the deletion, exon 3 is skipped, leading to a truncated protein and disease predisposition. Unlike previously reported large germline deletions in BRCA1, neither breakpoint resides within an Alu element. The g.12977 ins10 del1039 mutation was not detected among 11 other breast cancer families, nor among 406 breast cancer patients unselected for family history.     

Search for large genomic alterations of the BRCA1 gene in a Finnish population

Mutations in the BRCA1 and BRCA2 genes are known to predispose to breast cancer. In Finland, however, only 21% of all breast cancer families have mutations in these genes. Recent studies have shown that large genomic alterations of BRCA1 are common in many countries. Because such alterations will be missed in conventional mutation screening strategies, we decided to screen Finnish breast and ovarian cancer families for genomic alterations by using a multiplex polymerase chain reaction method. The most characteristic features of BRCA1-related breast cancer were used to select patients, namely (1) both breast and ovarian cancer in the family (48 patients), (2) four or more breast cancers in family (22 patients), or (3) young age (< or =40 years) of onset (58 patients). A total of 128 patients were included in the study. All exons of BRCA1 were analyzed but no alterations were found. This study excludes the frequent occurrence of large genomic alterations in the BRCA1 gene in Finland. Here, again, Finland differs from other countries with a mixed population structure. Our results are in agreement with the common hypothesis that there are still unknown breast cancer susceptibility gene(s) that are responsible for breast cancer predisposition.     

Screening for large rearrangements of the BRCA1 gene in German breast or ovarian cancer families using semi-quantitative multiplex PCR method

Since the identification of the breast and ovarian cancer susceptibility genes BRCA1 and BRCA2, a large number of different germline mutations in both genes have been found by conventional PCR-based mutation detection methods. Complex germline rearrangements such as those reported in the BRCA1 gene are often not detectable by these standard diagnostic techniques. To detect large deletions or duplications encompassing one or more exons of the BRCA1 gene and in order to estimate the frequency of BRCA1 rearrangements in German breast or ovarian cancer families, a semi-quantitative multiplex PCR method was developed and applied to DNA samples of patients from families negatively tested for disease causing mutations in the BRCA1 and BRCA2 coding regions by direct sequencing. Out of 59 families analysed, one family was found to carry a rearrangement in the BRCA1 gene (duplication of exon 13). The results indicate that the semi-quantitative multiplex PCR method is useful for the detection of large rearrangements in the BRCA1 gene and therefore represents an additional valuable tool for mutation analysis of BRCA1 and BRCA2.     

MLPA screening in the BRCA1 gene from 1,506 German hereditary breast cancer cases: novel deletions, frequent involvement of exon 17, and occurrence in single early-onset cases

We present a comprehensive analysis of 1,506 German families for large genomic rearrangements (LGRs) in the BRCA1 gene and of 450 families in the BRCA2 gene by the multiplex ligation-dependent probe amplification (MLPA) technique. A total of 32 pathogenic rearrangements in the BRCA1 gene were found, accounting for 1.6% of all mutations, but for 9.6% of all BRCA1 mutations identified in a total of 1,996 families, including 490 with small pathogenic BRCA1/2 mutations. Considering only high risk groups for hereditary breast/ovarian cancer, the prevalence of rearrangements is 2.1%. Interestingly, deletions involving exon 17 of the BRCA1 gene seem to be most frequent in Germany. Apart from recurrent aberrations like del ex17, dupl ex13, and del ex22, accounting for more than 50% of all BRCA1 LGRs, we could fully characterize 11 novel deletions. Moreover, one novel deletion involving exons 1-7 and one deletion affecting the entire BRCA1 gene were identified. All rearrangements were detected in families with: 1) at least two breast cancer cases prior to the age of 51 years; 2) breast and ovarian cancer cases; 3) ovarian cancer only families with at least two ovarian cancer cases; or 4) a single breast cancer case prior to the age of 36 years, while no mutations were detected in breast cancer only families with no or only one breast cancer case prior to the age of 51 years. Analysis for gross rearrangements in 412 high-risk individuals, revealed no event in the BRCA2 gene and only two known CHEK2 mutations. However, in an additional 38 high-risk families with cooccurrence of female breast/ovarian and male breast cancer, one rearrangement in the BRCA2 gene was found. In summary, we advise restricting BRCA1 MLPA screening to those subgroups that revealed LGRs and recommend BRCA2 MLPA screening only for families presenting with cooccurrence of female and male breast cancer.     

Real-time PCR-based gene dosage assay for detecting BRCA1 rearrangements in breast-ovarian cancer families

BRCA1 and BRCA2 germline mutations, mainly point mutations and other small alterations, are responsible for most hereditary cases of breast-ovarian cancer. However, the observed frequency of BRCA1 alterations is lower than that predicted by linkage analysis. Several large BRCA1 rearrangements have been identified with a variety of technical approaches in some families. We have developed a gene dosage assay based on real-time quantitative PCR and used it to extensively analyze 91 French families of breast-ovarian cancer in which no BRCA1 or BRCA2 point mutations was identified. This gene dosage method calculates the copy number of each BRCA1 exon to readily detect one, two, and three or more copies of BRCA1 target exons. In the series of 91 families at high risk of carrying BRCA1 mutations, we detected seven large rearrangements of the BRCA1 gene by using this real-time PCR approach. This simple, rapid, and semiautomated real-time quantitative polymerase chain reaction (PCR) assay is a promising alternative technique to Southern blot, bar code analysis on combed DNA, quantitative multiplex PCR of short fluorescent fragments, and cDNA length analysis for the detection of large rearrangements. Therefore, this technique should be considered as a powerful diagnostic method for breast/ovarian cancer susceptibility in clinical and research genetic surveys.     

Exclusion of large deletions and other rearrangements in BRCA1 and BRCA2 in Finnish breast and ovarian cancer families

In the Finnish population, identified mutations in BRCA1 and BRCA2 account for a less than expected proportion of hereditary breast and ovarian cancer. All previous studies performed in our country have concentrated on finding germ-line mutations in the coding and splice-site regions of these two genes. Therefore, we wanted to use a different methodological approach and search for large genomic rearrangements, to exclude the possibility of biased BRCA1 and BRCA2 mutation spectra due to known limitations of the previously used PCR-based detection methods. Our results support earlier notions that other genes than BRCA1 and BRCA2 will explain a majority of the still unexplained cases of hereditary susceptibility to breast and ovarian cancer.     

Prevalence of BRCA1 genomic rearrangements in a large cohort of Italian breast and breast/ovarian cancer families without detectable BRCA1 and BRCA2 point mutations

The presence of genomic rearrangements of the BRCA1 gene in breast and/or ovarian cancer families has been intensively investigated in patients from various countries over the last years. A number of different rearrangements have been reported by several studies that clearly document the involvement of this mutation type in genetic predisposition to breast and ovarian cancer. Population-specific studies are now needed to evaluate the prevalence of genomic rearrangements before deciding whether to include ad hoc screening procedures into standard diagnostic mutation detection approaches. Indeed, the vast majority of the studies have been performed on small, highly selected, sample sets because of the limitations imposed by the laborious technical approaches. Moreover, prevalence figures are likely to differ across different countries according to the ethnic origin of each specific population. Here we analyze a large cohort of 653 Italian probands, negative for BRCA1 and BRCA2 point mutations, gathered from four National Institutions. We report the identification of BRCA1 genomic rearrangements in 12 independent families. Noteworthy, half of the probands carry mutations that recur in more than one Italian family. Considering the whole spectrum of Italian BRCA1 gene rearrangements identified thus far in consecutive patients, we estimate that alterations of this type account for 19% (95% CI: 0.11 < 0.19 < 0.28) of the BRCA1 mutation positive families. We conclude that the search for major genomic rearrangements is essential for an accurate and comprehensive BRCA1 mutation detection strategy in Italy.     

Contribution of BRCA1 and BRCA2 mutations to inherited ovarian cancer

A total of 283 epithelial ovarian cancer families from the United Kingdom (UK) and the United States (US) were screened for coding sequence changes and large genomic alterations (rearrangements and deletions) in the BRCA1 and BRCA2 genes. Deleterious BRCA1 mutations were identified in 104 families (37%) and BRCA2 mutations in 25 families (9%). Of the 104 BRCA1 mutations, 12 were large genomic alterations; thus this type of change represented 12% of all BRCA1 mutations. Six families carried a previously described exon 13 duplication, known to be a UK founder mutation. The remaining six BRCA1 genomic alterations were previously unreported and comprised five deletions and an amplification of exon 15. One of the 25 BRCA2 mutations identified was a large genomic deletion of exons 19-20. The prevalence of BRCA1/2 mutations correlated with the extent of ovarian and breast cancer in families. Of 37 families containing more than two ovarian cancer cases and at least one breast cancer case with diagnosis at less than 60 years of age, 30 (81%) had a BRCA1/2 mutation. The mutation prevalence was appreciably less in families without breast cancer; mutations were found in only 38 out of 141 families (27%) containing two ovarian cancer cases only, and in 37 out of 59 families (63%) containing three or more ovarian cancer cases. These data indicate that BRCA1 and BRCA2 are the major susceptibility genes for ovarian cancer but that other susceptibility genes may exist. Finally, it is likely that these data will be of clinical importance for individuals in families with a history of epithelial ovarian cancer, in providing accurate estimates of their disease risks.     

Gross rearrangements in BRCA1 but not BRCA2 play a notable role in predisposition to breast and ovarian cancer in high-risk families of German origin

A total of 226 index cases from high-risk hereditary breast and ovarian cancer families of German origin who had tested negative for small nucleotide alterations in BRCA1 and BRCA2 were analyzed for gross genomic rearrangements at the two gene loci by the multiplex ligation-dependent probe amplification technique. Six large genomic alterations were identified in BRCA1, while no gross rearrangements were found in BRCA2. The six BRCA1 mutations included two novel mutations including a deletion of exon 5, and a deletion comprising exons 5-7, as well as three distinct gross alterations previously reported, including a deletion of exons 1A, 1B, and 2, two duplications of exon 13, and a deletion of exon 17. To understand the mechanisms underlying the genomic rearrangements within the BRCA1 gene and to provide a simple PCR-based assay for further diagnostic applications, we have defined the molecular breakpoints of the deletion/insertion mutations. In all cases, our data point to a mechanism by which illegitimate crossing over between stretches of direct repeat sequences as small as 9 base pairs (bp) and up to 188 bp may have occurred. Overall, we provide evidence that gross rearrangements within the BRCA1 gene locus may be as frequent as 3% in primarily mutation-negative tested high-risk familial breast and ovarian cancer of German ancestry, while large alterations involving the BRCA2 locus do not appear to play a significant role in disease etiology. These findings have important implications for genetic counseling and testing of high-risk breast and ovarian cancer families.     

Genomic rearrangements account for more than one-third of the BRCA1 mutations in northern Italian breast/ovarian cancer families

The recent identification of major genomic rearrangements in breast and breast/ovarian cancer families has widened the mutational spectrum of the BRCA1 gene, thus increasing the number of informative patients who can benefit from molecular screening. Numerous types of alterations have been identified in different populations with variable frequencies, probably due to both ethnic diversity and the technical approach employed. In fact, although several methods have been successfully used to detect large genomic deletions and insertions, most are laborious, time-consuming, and of variable sensitivity. In order to estimate the contribution of BRCA1 genomic rearrangements to breast/ovarian cancer predisposition in Italian families, we applied, for the first time as a diagnostic tool, the recently described multiplex ligation-dependent probe amplification (MLPA) methodology. Among the 37 hereditary breast/ovarian cancer (HBOC) families selected, all had a high prior probability of BRCA1 mutation, and 15 were previously shown to carry a mutation in either the BRCA2 (five families) or BRCA1 gene (10 families, including one genomic rearrangement). The application of BRCA1-MLPA to the remaining 22 uninformative families allowed the identification of five additional genomic rearrangements. Moreover, we observed that loss of constitutive heterozygosity of polymorphic markers in linkage disequilibrium is predictive of such BRCA1 alterations. By means of this approach, we demonstrate that BRCA1 genomic deletions account for more than one-third (6/15) of the pathogenic BRCA1 mutations in our series. We therefore propose to systematically include MLPA in the BRCA1 mutational analysis of breast/ovarian cancer families.     

Risk estimation as a decision-making tool for genetic analysis of the breast cancer susceptibility genes. EC Demonstration Project on Familial Breast Cancer

For genetic counselling of a woman on familial breast cancer, an accurate evaluation of the probability that she carries a germ-line mutation is needed to assist in making decisions about genetic-testing. We used data from eight collaborating centres comprising 618 families (346 breast cancer only, 239 breast or ovarian cancer) recruited as research families or counselled for familial breast cancer, representing a broad range of family structures. Screening was performed in affected women from 618 families for germ-line mutations in BRCA1 and in 176 families for BRCA2 mutations, using different methods including SSCP, CSGE, DGGE, FAMA and PTT analysis followed by direct sequencing. Germ-line BRCA1 mutations were detected in 132 families and BRCA2 mutations in 16 families. The probability of being a carrier of a dominant breast cancer gene was calculated for the screened individual under the established genetic model for breast cancer susceptibility, first, with parameters for age-specific penetrances for breast cancer only [7] and, second, with age-specific penetrances for ovarian cancer in addition [20]. Our results indicate that the estimated probability of carrying a dominant breast cancer gene gives a direct measure of the likelihood of detecting mutations in BRCA1 and BRCA2. For breast/ovarian cancer families, the genetic model according to Narod et al. [20] is preferable for calculating the proband's genetic risk, and gives detection rates that indicate a 50% sensitivity of the gene test. Due to the incomplete BRCA2 screening of the families, we cannot yet draw any conclusions with respect to the breast cancer only families.     

Using gene carrier probability to select high risk families for identifying germline mutations in breast cancer susceptibility genes.

Germline mutations in highly penetrant autosomal dominant genes explain about 5% of all breast cancer, and heritable mutations in the BRCA1 breast and ovarian cancer susceptibility gene account for 2-3% of breast cancer in the general population. Nevertheless, the presence of such mutations is highly predictive of disease development. Since screening for mutations is still technically laborious, we investigated whether the prior probability of being a carrier of a dominant breast cancer susceptibility gene in the youngest affected family member could be used to identify families in which the probability of finding a mutation is sufficiently high. Sixty German families with three or more cases of breast/ovarian cancer with at least two cases diagnosed under the age of 60 were screened for mutations by SSCP/CSGE and subsequent direct sequencing. Thirteen germline truncating/splicing mutations in BRCA1 were found in 33% (6/18) of the breast-ovarian cancer families and in 17% (7/42) of breast cancer only families. All the families showing mutations in BRCA1 had carrier probabilities of 0.65 or higher. In families with prior carrier probabilities above 0.6, the proportion detected was 0.46 in breast-ovarian cancer families and 0.26 in breast cancer only families. The average age at diagnosis of breast or ovarian cancer in families with BRCA1 mutations was 41.9 years and significantly lower than in families without mutations (p < 0.05). Mutation carriers and obligate carriers were also found to have cancers at other sites. The probability of being a susceptibility gene carrier, taking into account the complete pedigree information, allows uniform characterisation of all types of families for identifying those in which mutation analysis for BRCA1/2 is warranted. However, prior probabilities calculated using this method can be reduced when the correlation between genotype and phenotype is imperfect. A larger series of families needs to be investigated in this fashion to provide better estimates of the detection rate for different ranges of carrier probabilities.     

Gene‐panel testing of breast and ovarian cancer patients identifies a recurrent RAD51C duplication

Gene‐panel sequencing allows comprehensive analysis of multiple genes simultaneously and is now routinely used in clinical mutation testing of high‐risk breast and ovarian cancer patients. However, only BRCA1 and BRCA2 are often analyzed also for large genomic changes. Here, we have analyzed 10 clinically relevant susceptibility genes in 95 breast or ovarian cancer patients with gene‐panel sequencing including also copy number variants (CNV) analysis for genomic changes. We identified 12 different pathogenic BRCA1, BRCA2, TP53, PTEN, CHEK2, or RAD51C mutations in 18 of 95 patients (19%). BRCA1/2 mutations were observed in 8 patients (8.4%) and CHEK2 protein‐truncating mutations in 7 patients (7.4%). In addition, we identified a novel duplication encompassing most of the RAD51C gene. We further genotyped the duplication in breast or ovarian cancer families (n = 1149), in unselected breast (n = 1729) and ovarian cancer cohorts (n = 553), and in population controls (n = 1273). Seven additional duplication carries were observed among cases but none among controls. The duplication associated with ovarian cancer risk (3/590 of all ovarian cancer patients, 0.5%, P = .032 compared with controls) and was found to represent a large fraction of all identified RAD51C mutations in the Finnish population. Our data emphasizes the importance of comprehensive mutation analysis including CNV detection in all the relevant genes.     

Novel germline mutations in the BRCA1 and BRCA2 genes in Indian breast and breast-ovarian cancer families

The two major hereditary breast/ovarian cancer predisposition tumor suppressor genes, BRCA1 and BRCA2 that perform apparently generic cellular functions nonetheless cause tissue-specific syndromes in the human population when they are altered, or mutated in the germline. However, little is known about the contribution of BRCA1 and BRCA2 mutations to breast and/or ovarian cancers in the Indian population. We have screened for mutations the entire BRCA1 and BRCA2 coding sequences, and intron-exon boundaries, as well as their flanking intronic regions in sixteen breast or breast and ovarian cancer families of Indian origin. We have also analyzed 20 female patients with sporadic breast cancer regardless of age and family history, and 69 unrelated normal individuals as control. Thus a total of 154 samples were screened for BRCA1 and BRCA2 mutations using a combination of polymerase chain reaction-mediated site directed mutagenesis (PSM), polymerase chain reaction-single stranded conformation polymorphism assay (PCR-SSCP) and direct DNA sequencing of PCR products (DS). Twenty-one sequence variants including fifteen point mutations were identified. Five deleterious pathogenic, protein truncating frameshift and non-sense mutations were detected in exon 2 (c.187_188delAG); and exon 11 (c.3672G>T) [p.Glu1185X] of BRCA1 and in exon 11 (c.5227dupT, c.5242dupT, c.6180dupA) of BRCA2 (putative mutations - four novel) as well as fourteen amino acid substitutions were identified. Twelve BRCA1 and BRCA2 missense variants were identified as unique and novel. In the cohort of 20 sporadic female patients no mutations were found.     

BRCA1 and BRCA2 mutation analysis in 86 early onset breast/ovarian cancer patients.

Eighty-six women fulfilling specific selection criteria were studied for germline mutations in two breast cancer susceptibility genes, BRCA1 and BRCA2, using the protein truncation test (PTT). Nine germline mutations were identified, six in BRCA1 and three in BRCA2. Of the six BRCA1 mutations, three have previously been described and three are new, and for BRCA2, one is a new mutation and the other two appear to occur at a site that has been described several times. Four kindreds were breast cancer families, one a breast/ovarian cancer family, and the sixth an ovarian cancer family. The three kindreds with BRCA2 mutations were classified as one breast/ovarian cancer family, one breast cancer family, and one family which harboured one early onset breast cancer patient and two melanoma patients. The mutations in BRCA1 were either insertions, deletions, or transitions which all resulted in a premature stop codon. Mutations in BRCA2 were all frameshift mutations as a result of either 2 or 4 bp deletions. Two BRCA2 mutations were identical, suggesting a Swiss founder effect which was confirmed by haplotype sharing. The 10% mutation detection rate is compatible with the relaxed criteria used for patient selection. Considering the relative ease with which coding sequences can be screened by PTT, this assay is useful as a first screen for BRCA1 and BRCA2 mutations.     

Large BRCA1 gene deletions are found in 3% of German high-risk breast cancer families

We have tested for large BRCA1 gene rearrangements in German high-risk breast and ovarian cancer families previously screened negative for point mutations by dHPLC and sequencing. Using the novel MLPA method, two deletions of exons 1A, 1B and 2 and exon 17, respectively, were detected in four out of 75 families investigated in Southern Germany. An identical exon 17 deletion with the same breakpoints and a deletion of exons 1A, 1B and 2 were found by fluorescent multiplex PCR in two out of 30 families investigated in Northern Germany. Combining both populations, genomic rearrangements were found in 6% of the mutation-negative families and 3% of all high-risk families and account for 8% of all BRCA1 mutations. Our data indicate that the exon 17 deletion may be a founder mutation in the German population. The prevalence of BRCA1 gene deletions or duplications in our patients is similar to previous reports from Germany and France. Genomic quantification by MLPA is a useful method for molecular diagnostics in high-risk breast cancer families.     

Germline mutations in the BRCA1 and BRCA2 genes in Turkish breast/ovarian cancer patients

In this study we genotyped Turkish breast/ovarian cancer patients for BRCA1/BRCA2 mutations: protein truncation test (PTT) for exon 11 BRCA1 of and, multiplex PCR and denaturing gradient gel electrophoresis (DGGE) for BRCA2, complemented by DNA sequencing. In addition, a modified restriction assay was used for analysis of the predominant Jewish mutations: 185delAG, 5382InsC, Tyr978X (BRCA1) and 6174delT (BRCA2). Eighty three breast/ovarian cancer patients were screened: twenty three had a positive family history of breast/ovarian cancer, ten were males with breast cancer at any age, in eighteen the disease was diagnosed under 40 years of age, one patient had ovarian cancer in addition to breast cancer and one patient had ovarian cancer. All the rest (n=30) were considered sporadic breast cancer cases. Overall, 3 pathogenic mutations (3/53-5.7%) were detected, all in high risk individuals (3/23-13%): a novel (2990insA) and a previously described mutation (R1203X) in BRCA1, and a novel mutation (9255delT) in BRCA2. In addition, three missense mutations [two novel (T42S, N2742S) and a previously published one (S384F)] and two neutral polymorphisms (P9P, P2532P) were detected in BRCA2. Notably none of the male breast cancer patients harbored any mutation, and none of the tested individuals carried any of the Jewish mutations. Our findings suggest that there are no predominant mutations within exon 11 of the BRCA1 and in BRCA2 gene in Turkish high risk families.