Diversity of the clinical presentation of the MMR gene biallelic mutations.

Constitutional mismatch repair-deficiency, due to biallelic mutations of MMR genes, results in a tumour spectrum characterized by leukaemias, lymphomas, brain tumours and adenocarcinomas of the gastro-intestinal tract, occurring mostly in childhood. We report here two families illustrating the phenotypic diversity associated with biallelic MMR mutations. In the first family, two siblings developed six malignancies including glioblastoma, lymphoblastic T cell lymphoma, rectal and small bowel adenocarcinoma with onset as early as 6 years of age. We showed that this dramatic clinical presentation was due to the presence of two complex genomic PMS2 deletions in each patient predicted to result into complete PMS2 inactivation. In the second family, the index case presented with an early form of Lynch syndrome with colorectal adenocarcinomas at ages 17 and 20 years, and urinary tract tumours at the age of 25 years. We identified in this patient two MSH6 mutations corresponding to a frameshift deletion and an in frame deletion. The latter was not predicted to result into complete inactivation of MSH6. These reports show that the clinical expression of biallelic MMR mutations depends on the biological impact of the second MMR mutation and that, in clinical practice, the presence of a second MMR mutation located in trans should also be considered in patients suspected to present a Lynch syndrome with an unusual early-onset of tumours.

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 Lynch's 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.

Biological effects of four PSEN1 gene mutations causing Alzheimer disease with spastic paraparesis and cotton wool plaques.

We describe the biological consequences on PSEN1 exons 8 or 9 splicing and Abeta peptides production of four PSEN1 mutations associated with a phenotypic variant of Alzheimer disease, which includes cotton wool plaques and spastic paraparesis (CWP/SP). Two of these mutations (c.869-22_869-23ins18 and c.871A > C, p.T291P) are novel mutations located in intron 8 and exon 9, respectively. The c.869-22_869-23ins18 mutation caused exon 9 skipping whereas the c.871A > C (p.T291P) mutation showed only a modest effect on exon 9 skipping. The previously reported E280G and P264L mutations, located in exon 8, had no effect on mRNA splicing. Infection of cells with mutant T291P, E280G, or P264L cDNAs caused a variable increase in secreted Abeta42. We conclude that none of the previously proposed mechanisms, i.e. exceptionally large increases in secreted Abeta42 levels or loss of PSEN1 exons 8 or 9, provides complete explanation of the CWP/SP phenotype.

The 5' region of the MSH2 gene involved in hereditary non-polyposis colorectal cancer contains a high density of recombinogenic sequences.

MSH2 rearrangements are involved in approximately 10% of hereditary non-polyposis colorectal cancer (HNPCC) families, and in most of the rearrangements, exon 1 is deleted. We scanned by quantitative multiplex polymerase chain reaction (PCR) of short fluorescent fragments (QMPSF) 200 kb of genomic sequences upstream of the MSH2 transcription initiation site in 21 HNPCC families with exon 1 deletions. This QMPSF scan revealed 12 distinct 5' breakpoints located up to 200 kb upstream of the MSH2 transcription initiation site. Sequencing analysis of the rearranged allele in 17 families revealed that most of the deletions (15/17) resulted from homologous Alu-mediated recombination. QMPSF and sequencing analysis in these 21 families led us to detect the presence of 20 distinct 5' breakpoints. In 14 out of 15 Alu-mediated recombinations, we found, either within the identical region in which the recombination had probably occurred or in its vicinity, the 26-bp Alu core sequence containing the recombinogenic Chi-like motif. Compared to the equivalent regions of other human genes, the MSH2 upstream region was found to contain a high density of Alu repeats (30% within 228 kb and 43% within 50 kb), most of which belong to the old Alu S subfamilies. In conclusion, this study demonstrates the heterogeneity of the breakpoints within the MSH2 upstream region and reveals the remarkable density of recombinogenic Alu sequences in this region.

Analysis of the allele-specific expression of the mismatch repair gene MLH1 using a simple DHPLC-Based Method.

Quantitative measures of allele-specific gene expression allow the indirect detection of mutations or sequence variants in regulatory elements or in other non-coding regions that may result in significant physiological or pathological changes of gene expression and may contribute to Mendelian or multifactorial disorders. We have devised a simple method, based on RT-PCR and single nucleotide primer extension (SNuPE) with unlabelled dideoxynucleotides, followed by DHPLC (denaturing high performance liquid chromatography). We established optimal conditions for separation of the extended products corresponding to the alleles of the c.655A>G (p.Ile219Val) SNP, which is the most frequent exonic polymorphism of MLH1. We then genotyped 99 unrelated control subjects and measured the allele-specific MLH1 expression in the 40 heterozygous controls found in this group. This method allowed us to define a narrow range of normal biallelic expression of MLH1, each allele contributing between 44.7% and 55.3% of the total expression. We then measured the allele-specific expression in hereditary nonpolyposis colorectal cancer (HNPCC) patients with MLH1 mRNAs bearing different stop-codon or frame-shift mutations, or in-frame deletions, in order to detect the effects of nonsense-mediated mRNA decay (NMD). Defects that induce mRNA instability were identified unambiguously and the data were consistent with current models of NMD. This study provides a sensitive tool to identify indirectly MLH1 defects that may escape detection in genomic DNA screenings but result in a quantitative change at the mRNA level.

Complete germline deletion of the STK11 gene in a family with Peutz-Jeghers syndrome.

Peutz-Jeghers syndrome (PJS, MIM175200) is an autosomal-dominant inherited disorder characterised by multiple gastrointestinal hamartomatous polyps, melanin spots of the oral mucosa and digits, and an increased risk for various neoplasms. The PJS results from germline alterations of the STK11/LKB1 tumour suppressor gene, located on 19p13.3, and encoding a serine/threonine kinase. The detection of STK11 germline mutations, in only 50-70% of PJS families, has suggested a genetic heterogeneity of the disease. We report the case of a family with typical features of PJS, including gastrointestinal hamartomatous, breast cancers and melanin spots of the oral mucosa. Quantitative multiplex PCR of short fluorescent fragments (QMPSF) of the 19p13 region allowed us to identify an approximately 250 kb heterozygous deletion removing entirely the STK11 locus. This report, which constitutes the first description of a complete germline deletion of STK11, shows that the presence of such large genomic deletions should be considered in PJS families without detectable point mutations of STK11.

Screening for TP53 rearrangements in families with the Li-Fraumeni syndrome reveals a complete deletion of the TP53 gene.

The absence of detectable germline TP53 mutations in a fraction of families with Li-Fraumeni syndrome (LFS) has suggested the involvement of other genes, but this hypothesis remains controversial. The density of Alu repeats within the TP53 gene led us to search genomic rearrangements of TP53 in families without detectable TP53 mutation. To this aim, we adapted the quantitative multiplex PCR of short fluorescent fragments (QMPSF) method to the analysis of the 11 exons of TP53. We analysed 98 families, either fulfilling (six families) or partially meeting (92 families) the criteria for LFS, and in which classical methods had failed to reveal TP53 alterations. We identified, in a large family fulfilling the criteria for LFS, a complete heterozygous deletion of TP53. Additional QMPSF analyses indicated that this deletion, which partially removed the centromeric FLJ10385 locus, covered approximately 45 kb. This deletion was shown to result from a complex rearrangement involving two distinct Alu-mediated recombinations. We conclude that TP53 germline rearrangements occur as rare events, but must be considered in LFS families without detectable point TP53 mutation.

MSH2 in contrast to MLH1 and MSH6 is frequently inactivated by exonic and promoter rearrangements in hereditary nonpolyposis colorectal cancer.

To estimate the relative frequency of mismatch repair genes, rearrangements in hereditary nonpolyposis colorectal cancer (HNPCC) families without detectable mutations in MSH2 or MLH1, we have analyzed by multiplex PCR of short fluorescent fragments MSH2, MLH1, and MSH6 in 61 families, either fulfilling Amsterdam criteria or including cases of multiple primary cancers belonging to the HNPCC spectrum. We detected 13 different genomic rearrangements of MSH2 in 14 families (23%), whereas we found no rearrangement of MLH1 and MSH6. Analysis of 31 other families, partially meeting Amsterdam criteria, revealed no additional rearrangement of MSH2. All of the MSH2 rearrangements, except one, corresponded to genomic deletions involving one or several exons. In 8 of 13 families with a MSH2 genomic deletion, the MSH2 promoter was also deleted, and the 5' breakpoint was located either within or upstream the MSH2 gene. This study demonstrates the heterogeneity of MSH2 exonic and promoter rearrangements and shows that, in HNPCC families without detectable MSH2 or MLH1 point mutation, one must consider the presence of MSH2 genomic rearrangements before the involvement of other mismatch repair genes. The simplicity and rapidity of their detection, using fluorescent multiplex PCR, led us to recommend to begin the molecular analysis in HNPCC by screening for MSH2 rearrangements.