Stéphanie Baert-Desurmont

2009 Version of the Chompret Criteria for Li Fraumeni Syndrome

in 474FrenchfamiliessuggestiveofLFS,including232familiesfulfillingtheChompret criteria; obtained a mutation detection rate of 29% (67of232families);andestimatedthesensitivityandspecificityoftheChompret criteria to be 82% and 58%, respectively. We also pro-posedextendingtheChompretcriteriatocovertheclinicalpresen-tation of the 82 families in which we identified germline

Impact of the MDM2 SNP309 and p53 Arg72Pro polymorphism on age of tumour onset in Li-Fraumeni syndrome

Li-Fraumeni syndrome, resulting from p53 (TP53) germline mutations, represents one of the most devastating genetic predispositions to cancer. Recently, the MDM2 SNP309 (T→G variation) was shown to be associated with accelerated tumour formation in p53 mutation carriers. The impact of the common p53 codon 72 polymorphism on cancer risk remains controversial. We therefore investigated the effect of these two polymorphisms in 61 French carriers of the p53 germline mutation. The mean age of tumour onset in MDMD2 SNP309 G allele carriers (19.6 years) was significantly different from that observed in patients homozygous for the T allele (29.9 years, p<0.05). For the p53 codon 72 polymorphism, the mean age of tumour onset in Arg allele carriers (21.8 years) was also different from that of Pro/Pro patients (34.4 years, p<0.05). We observed a cumulative effect of both polymorphisms because the mean ages of tumour onset in carriers of the MDM2G and p53Arg alleles (16.9 years) and those with the MDM2T/T and p53Pro/Pro genotypes (43 years) were clearly different (p<0.02). Therefore, our results confirm the impact of the MDM2 SNP309 G allele on the age of tumour onset in germline p53 mutation carriers, and suggest that this effect may be amplified by the p53 72Arg allele. Polymorphisms affecting p53 degradation therefore represent one of the rare examples of modifier genetic factors identified to date in mendelian predispositions to cancer.

Next-generation sequencing for the diagnosis of hereditary breast and ovarian cancer using genomic capture targeting multiple candidate genes

To optimize the molecular diagnosis of hereditary breast and ovarian cancer (HBOC), we developed a next-generation sequencing (NGS)-based screening based on the capture of a panel of genes involved, or suspected to be involved in HBOC, on pooling of indexed DNA and on paired-end sequencing in an Illumina GAIIx platform, followed by confirmation by Sanger sequencing or MLPA/QMPSF. The bioinformatic pipeline included CASAVA, NextGENe, CNVseq and Alamut-HT. We validated this procedure by the analysis of 59 patients’ DNAs harbouring SNVs, indels or large genomic rearrangements of BRCA1 or BRCA2. We also conducted a blind study in 168 patients comparing NGS versus Sanger sequencing or MLPA analyses of BRCA1 and BRCA2. All mutations detected by conventional procedures were detected by NGS. We then screened, using three different versions of the capture set, a large series of 708 consecutive patients. We detected in these patients 69 germline deleterious alterations within BRCA1 and BRCA2, and 4 TP53 mutations in 468 patients also tested for this gene. We also found 36 variations inducing either a premature codon stop or a splicing defect among other genes: 5/708 in CHEK2, 3/708 in RAD51C, 1/708 in RAD50, 7/708 in PALB2, 3/708 in MRE11A, 5/708 in ATM, 3/708 in NBS1, 1/708 in CDH1, 3/468 in MSH2, 2/468 in PMS2, 1/708 in BARD1, 1/468 in PMS1 and 1/468 in MLH3. These results demonstrate the efficiency of NGS in performing molecular diagnosis of HBOC. Detection of mutations within other genes than BRCA1 and BRCA2 highlights the genetic heterogeneity of HBOC.

Revisiting Li-Fraumeni Syndrome From TP53 Mutation Carriers

PURPOSE The aim of the study was to update the description of Li-Fraumeni syndrome (LFS), a remarkable cancer predisposition characterized by extensive clinical heterogeneity. PATIENTS AND METHODS From 1,730 French patients suggestive of LFS, we identified 415 mutation carriers in 214 families harboring 133 distinct TP53 alterations and updated their clinical presentation. RESULTS The 322 affected carriers developed 552 tumors, and 43% had developed multiple malignancies. The mean age of first tumor onset was 24.9 years, 41% having developed a tumor by age 18. In childhood, the LFS tumor spectrum was characterized by osteosarcomas, adrenocortical carcinomas (ACC), CNS tumors, and soft tissue sarcomas (STS) observed in 30%, 27%, 26%, and 23% of the patients, respectively. In adults, the tumor distribution was characterized by the predominance of breast carcinomas observed in 79% of the females, and STS observed in 27% of the patients. The TP53 mutation detection rate in children presenting with ACC or choroid plexus carcinomas, and in females with breast cancer before age 31 years, without additional features indicative of LFS, was 45%, 42% and 6%, respectively. The mean age of tumor onset was statistically different (P < .05) between carriers harboring dominant-negative missense mutations (21.3 years) and those with all types of loss of function mutations (28.5 years) or genomic rearrangements (35.8 years). Affected children, except those with ACC, harbored mostly dominant-negative missense mutations. CONCLUSION The clinical gradient of the germline TP53 mutations, which should be validated by other studies, suggests that it might be appropriate to stratify the clinical management of LFS according to the class of the mutation.

Cardiac conduction alterations in a French family with amyloidosis of the finnish type with the p.Asp187Tyr mutation in the GSN gene

Familial amyloidosis of the Finnish type (FAF) is a rare autosomal‐dominant disorder caused by the accumulation of a 71–amino acid amyloidogenic fragment of mutant gelsolin, an actin‐modulating protein. The main symptoms include corneal lattice dystrophy, progressive cranial and peripheral neuropathy, and skin changes. To date, only two mutations in the GSN gene have been described: the p.Asp187Asn mutation in most patients and the p.Asp187Tyr mutation in a Danish and Czech family. We report on the third family with the p.Asp187Tyr mutation and the first French FAF family. Severe cardiac conduction alterations in three patients were mainly caused by cardiac sympathetic denervation. These findings demonstrate the cardiological involvement of the FAF phenotype and suggest that cardiological follow‐up is required in FAF patients. Muscle Nerve, 2006

HLA-A*0201-restricted CEA-derived Peptide CAP1 Is Not a Suitable Target for T-cell-based Immunotherapy

Carcinoembryonic antigen (CEA) is a potential target for antigen-specific immunotherapy, as it is frequently overexpressed in human carcinomas. Moreover, an epitope derived from CEA, designated CAP1 (YLSGANLNL), has been proposed as naturally processed and presented by tumors in the human leukocyte antigen (HLA)-A*0201 context. Our aim was to fully characterize and assess the clinical relevance of the HLA-A*0201-restricted cytotoxic T lymphocyte (CTL) response against CEA. Stable and potent artificial antigen presenting cells (AAPCs) were used to evaluate T-cell response against CEA. These cells efficiently activate CTLs against tumor-derived epitopes after transduction with the antigenic peptides or full-length proteins. We found that AAPCs genetically modified to express CAP1, the agonist peptide CAP1-6D, or the whole CEA protein were not able to activate CAP1-specific CTLs from HLA-A*0201+ healthy donors or patients with colorectal carcinoma, even after multiple stimulations. In addition, we showed that a CAP1-specific T-cell clone, obtained after multiple stimulations of T cells of a HLA-A*0201+ healthy donor in vitro with autologous antigen presenting cells, recognized CEA− HLA-A*0201+ tumors transduced with a minigene encoding CAP1 but failed to react against HLA-A*0201+ tumor cells expressing CEA. Finally, AAPCs expressing the whole CEA protein did not induce any specific CTL response against CEA+ HLA-A*0201+ tumor cells highlighting the potential difficulty of mounting an efficacious T-cell response against this autoantigen. Altogether, our data indicate that CAP1 is not efficiently processed and presented by CEA+ tumor cells, and therefore, is not an appropriate target for T-cell-based immunotherapy.

Evaluation of Lynch syndrome modifier genes in 748 MMR mutation carriers

Several studies have reported that, in Lynch syndrome resulting from mutations of the mismatch repair (MMR) genes, a CA repeat ≤17 within the IGF1 promoter, SNPs within the xenobiotic metabolizing enzyme gene CYP1A1 and SNPs on 8q23.3 and 11q23.1 modify colorectal cancer (CRC) risk in MMR mutation carriers. We analysed the impact of these polymorphisms on CRC risk in 748 French MMR mutation carriers derived from 359 families. We also analysed the effect of the Novel 1 SNP (18q21), which has recently been shown to increase CRC risk in the general population. We observed a significant difference in the CRC-free survival time between males and females, between MSH2 and MSH6 mutation carriers and between MLH1 and MSH6, indicating that this series is representative of Lynch syndrome. In contrast, the univariate log-rank test, as well as multivariate Cox model analysis controlling for familial aggregation and mutated MMR gene, year of birth and gender showed that the polymorphic alleles tested were not associated with a significant CRC risk increase, neither on the entire sample nor among males and females. This discrepancy with previous reports might be explained both by the genetic heterogeneity between the different populations analysed and the allelic heterogeneity of the MMR mutations. We conclude that genotyping of these polymorphisms is not useful to evaluate CRC risk in MMR mutation carriers and to optimize their clinical follow-up.

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.

Partial duplications of the MSH2 and MLH1 genes in hereditary nonpolyposis colorectal cancer

Numerous reports have highlighted the contribution of MSH2 and MLH1 genomic deletions to hereditary nonpolyposis colorectal cancer (HNPCC) or Lynchs syndrome, but genomic duplications of these genes have been rarely reported. Using quantitative multiplex PCR of short fluorescent fragments (QMPSF), 962 and 611 index cases were, respectively, screened for MSH2 and MLH1 genomic rearrangements. This allowed us to detect, in 11 families, seven MSH2 duplications affecting exons 1–2–3, exons 4–5–6, exon 7, exons 7–8, exons 9–10, exon 11, and exon 15, and three MLH1 duplications affecting exons 2–3, exon 4 and exons 6–7–8. All duplications were confirmed by an independent method. The contribution of genomic duplications of MSH2 and MLH1 to HNPCC can therefore be estimated approximately to 1% of the HNPCC cases. Although this frequency is much lower than that of genomic deletions, the presence of MSH2 or MLH1 genomic duplications should be considered in HNPCC families without detectable point mutations.

Clinical relevance of 8q23, 15q13 and 18q21 SNP genotyping to evaluate colorectal cancer risk.

To determine if the at-risk single-nucleotide polymorphism (SNP) alleles for colorectal cancer (CRC) could contribute to clinical situations suggestive of an increased genetic risk for CRC, we performed a prospective national case–control study based on highly selected patients (CRC in two first-degree relatives, one before 61 years of age; or CRC diagnosed before 51 years of age; or multiple primary CRCs, the first before 61 years of age; exclusion of Lynch syndrome and polyposes) and controls without personal or familial history of CRC. SNPs were genotyped using SNaPshot, and statistical analyses were performed using Pearsons χ2 test, Cochran–Armitage test of trend and logistic regression. We included 1029 patients and 350 controls. We confirmed the association of CRC risk with four SNPs, with odds ratio (OR) higher than previously reported: rs16892766 on 8q23.3 (OR: 1.88, 95% confidence interval (CI): 1.30–2.72; P=0.0007); rs4779584 on 15q13.3 (OR: 1.42, CI: 1.11–1.83; P=0.0061) and rs4939827 and rs58920878/Novel 1 on 18q21.1 (OR: 1.49, CI: 1.13–1.98; P=0.007 and OR: 1.49, CI: 1.14–1.95; P=0.0035). We found a significant (P<0.0001) cumulative effect of the at-risk alleles or genotypes with OR at 1.62 (CI: 1.10–2.37), 2.09 (CI: 1.43–3.07), 2.87 (CI: 1.76–4.70) and 3.88 (CI: 1.72–8.76) for 1, 2, 3 and at least 4 at-risk alleles, respectively, and OR at 1.71 (CI: 1.18–2.46), 2.29 (CI: 1.55–3.38) and 6.21 (CI: 2.67–14.42) for 1, 2 and 3 at-risk genotypes, respectively. Combination of SNPs may therefore explain a fraction of clinical situations suggestive of an increased risk for CRC.