Nonclassical splicing mutations in the coding and noncoding regions of the ATM Gene: maximum entropy estimates of splice junction strengths

Ataxia-telangiectasia (A-T) is an autosomal recessive neurological disorder caused by mutations in the ATM gene. Classical splicing mutations (type I) delete entire exons during pre-mRNA splicing. In this report, we describe nine examples of nonclassical splicing mutations in 12 A-T patients and compare cDNA changes to estimates of splice junction strengths based on maximum entropy modeling. These mutations fall into three categories: pseudoexon insertions (type II), single nucleotide changes within the exon (type III), and intronic changes that disrupt the conserved 3' splice sequence and lead to partial exon deletion (type IV). Four patients with a previously reported type II (pseudoexon) mutation all shared a common founder haplotype. Three patients with apparent missense or silent mutations actually had type III aberrant splicing and partial deletion of an exon. Five patients had type IV mutations that could have been misinterpreted as classical splicing mutations. Instead, their mutations disrupt a splice site and use another AG splice site located nearby within the exon; they lead to partial deletions at the beginning of exons. These nonclassical splicing mutations create frameshifts that result in premature termination codons. Without screening cDNA or using accurate models of splice site strength, the consequences of these genomic mutations cannot be reliably predicted. This may lead to further misinterpretation of genotype-phenotype correlations and may subsequently impact upon gene-based therapeutic approaches.     

DHPLC screening of ATM gene in Italian patients affected by ataxia-telangiectasia: fourteen novel ATM mutations

The gene for ataxia-telangiectasia (A-T:MIM: #208900), ATM, spans about 150 kb of genomic DNA and is composed of 62 coding exons. ATM mutations are found along the entire coding sequence of the gene, without evidence of mutational hot spots. Using DNA as the starting material, we used denaturing high performance liquid chromatography (DHPLC) technique to search for ATM gene mutations. Initially, DHPLC was validated in a retrospective study of 16 positive control samples that included 19 known mutations; 100% of mutations were detected. Subsequently, DHPLC was used to screen for mutations a cohort of 22 patients with the classical form of A-T. A total of 27 different mutations were identified on 38 of the 44 alleles, corresponding to a 86% detection rate. Fourteen of the mutations were novel. In addition, 15 different variants and polymorphisms of unknown functional significance were found. The high incidence of new and individual A-T mutations in our cohort of patients demonstrates marked mutational heterogeneity of A-T in Italy and corroborate the efficiency of DHPLC as a method for the mutation screening of A-T patients.     

Deletions of NF1 gene and exons detected by multiplex ligation-dependent probe amplification

To estimate the contribution of single and multi-exon NF1 gene copy-number changes to the NF1 mutation spectrum, we analysed a series of 201 Italian patients with neurofibromatosis type 1 (NF1). Of these, 138 had previously been found, using denaturing high-performance liquid chromatography or protein truncation test, to be heterozygous for intragenic NF1 point mutations/deletions/insertions, and were excluded from this analysis. The remaining 63 patients were analysed using multiplex ligation-dependent probe amplification (MLPA), which allows detection of deletions or duplications encompassing >or=1 NF1 exons, as well as entire gene deletions. MLPA results were validated using real-time quantitative PCR (qPCR) or fluorescent in situ hybridisation. MLPA screening followed by real-time qPCR detected a total of 23 deletions. Of these deletions, six were single exon, eight were multi-exon, and nine were of the entire NF1 gene. In our series, deletions encompassing >or=1 NF1 exons accounted for approximately 7% (14/201) of the NF1 gene mutation spectrum, suggesting that screening for these should now be systematically included in genetic testing of patients with NF1.     

Duchenne肌营养不良症患者及携带者的基因缺失和重复突变检测

目的利用多重连接依赖探针PCR扩增技术检测Duchenne肌营养不良症（Duchenne muscular dystrophy，DMD）患者及其可能的女性携带者的dystrophin基因的缺失、重复突变。方法利用多重连接依赖探针PCR扩增对32例DMD患者及其27个可能的女性携带者的dystrophin基因缺失、重复进行检测。结果32个先证者中，共检测出了24例DMI）患者具有一个或多个外显子的缺失，l例DMD患者具有重复突变，l例患者为第19外显子的无义突变（R768X），6例没有检测出缺失、重复突变的先证者可能是点突变所致。17个先证者的18位女性亲属具有和先证者相同的缺失、重复突变。结论多重连接依赖探针PCR扩增技术可用于检测DMD基因的缺失、重复突变，可以检测DMD基因女性携带者的基因杂合情况，在检测DMD基因缺失和重复方面，具有一定的应用价值。     

Identification of intragenic deletions and duplication in the FLCN gene in Birt-Hogg-Dubé syndrome

Birt-Hogg-Dubé syndrome (BHDS), caused by germline mutations in the folliculin (FLCN) gene, predisposes individuals to develop fibrofolliculomas, pulmonary cysts, spontaneous pneumothoraces, and kidney cancer. The FLCN mutation detection rate by bidirectional DNA sequencing in the National Cancer Institute BHDS cohort was 88%. To determine if germline FLCN intragenic deletions/duplications were responsible for BHDS in families lacking FLCN sequence alterations, 23 individuals from 15 unrelated families with clinically confirmed BHDS but no sequence variations were analyzed by real-time quantitative PCR (RQ-PCR) using primers for all 14 exons. Multiplex ligation-dependent probe amplification (MLPA) assay and array-based comparative genomic hybridization (aCGH) were utilized to confirm and fine map the rearrangements. Long-range PCR followed by DNA sequencing was used to define the breakpoints. We identified six unique intragenic deletions in nine patients from six different BHDS families including four involving exon 1, one that spanned exons 2-5, and one that encompassed exons 7-14 of FLCN. Four of the six deletion breakpoints were mapped, revealing deletions ranging from 5688 to 9189 bp. In addition, one 1341 bp duplication, which included exons 10 and 11, was identified and mapped. This report confirms that large intragenic FLCN deletions can cause BHDS and documents the first large intragenic FLCN duplication in a BHDS patient. Additionally, we identified a deletion "hot spot" in the 5'-noncoding-exon 1 region that contains the putative FLCN promoter based on a luciferase reporter assay. RQ-PCR, MLPA and aCGH may be used for clinical molecular diagnosis of BHDS in patients who are FLCN mutation-negative by DNA sequencing.     

High proportion of large genomic STK11 deletions in Peutz-Jeghers syndrome

Germline mutations in the STK11 gene have been identified in 10-70% of patients with Peutz-Jeghers syndrome (PJS), an autosomal-dominant hamartomatous polyposis syndrome. A second locus was assumed in a large proportion of PJS patients. To date, STK11 alterations comprise mainly point mutations; only a small number of large deletions have been reported. We performed a mutation analysis for the STK11 gene in 71 patients. Of these, 56 met the clinical criteria for PJS and 12 were presumed to have PJS because of mucocutaneous pigmentation only or bowel problems due to isolated PJS polyps. No clinical information was available for the remaining three patients. By direct sequencing of the coding region of the STK11 gene, we identified point mutations in 37 of 71 patients (52%). We examined the remaining 34 patients by means of the multiplex ligation-dependent probe amplification (MLPA) method, and detected deletions in 17 patients. In four patients the deletion extended over all 10 exons, and in eight patients only the promoter region and exon 1 were deleted. The remaining deletions encompassed exons 2-10 (in two patients), exons 2-3, exons 4-5, or exon 8. When only patients who met the clinical criteria for PJS are considered, the overall mutation detection rate increases to 94% (64% point mutations and 30% large deletions). No mutation was identified in any of the 12 presumed cases. In conclusion, we found that approximately one-third of the patients who met the clinical PJS criteria exhibited large genomic deletions that were readily detectable by MLPA. Screening for point mutations and large deletions by direct sequencing or MLPA, respectively, increased the mutation detection rate in the STK11 gene up to 94%. There may be still other mutations in the STK11 gene that are not detectable by the methods applied here. Therefore, it is questionable whether a second PJS locus exists at all.     

Hereditary nonpolyposis colorectal cancer: pitfalls in deletion screening in MSH2 and MLH1 genes

Hereditary nonpolyposis colorectal cancer (HNPCC) is caused by a deficiency in DNA mismatch repair in consequence of germline mutations mainly in the genes MSH2 and MLH1. Around 10% of patients suspected of HNPCC are identified with large genomic deletions that cannot be detected by conventional methods of mutation screening. The recently developed multiplex ligation-dependent probe amplification (MLPA) proved to be an easy to perform method for deletion detection and is reliable when more than one exon is deleted. We show that, in some cases, apparent deletions of single exons may actually result from single base substitutions or small insertions/deletions in the hybridisation sequence of MLPA probes. We conclude that single exon deletions, detected by MLPA or multiplex PCR, should be validated with additional methods.     

Functional significance of a deep intronic mutation in the ATM gene and evidence for an alternative exon 28a

Screening for ATM mutations is usually performed using genomic DNA as a template for PCR amplification across exonic regions, with the consequence that deep intronic sequences are not analyzed. Here we report a novel pseudoexon-retaining deep intronic mutation (IVS28-159A>G; g.75117A>G based on GenBank U82828.1) in a patient with ataxia-telangiectasia (A-T), as well as the identification of a previously unrecognized alternative exon in the ATM gene (exon 28a) expressed in lymphoblastoid cell lines (LCL) derived from normal individuals. cDNA analysis using the A-T patient's LCL showed the retention of two aberrant intronic segments of 112 and 190 nt between exons 28 and 29. Minigenes were constructed to determine the functional significance of two genomic changes in the region of aberrant splicing: IVS28-193C>T (g.75083C>T) and IVS28-159A>G, revealing that: 1) the first is a polymorphism; 2) IVS28-159A>G weakens the 5' splice site of the alternative exon 28a and activates a cryptic 5' splice site (ss) 83 nt downstream; and 3) wild-type constructs also retain a 29-nt segment (exon 28a) as part of both the 112- and 190-nt segments. Maximum entropy estimates of ss strengths corroborate the cDNA and minigene findings. Such mutations may prove relevant in planning therapy that targets specific splicing aberrations.     

Founder Effects for ATM Gene Mutations in Italian Ataxia Telangiectasia Families

We screened ATM gene mutations in 104 Italian Ataxia-Telangiectasia patients from 91 unrelated families (detection rate 90%) and found 21 recurrent mutations in 63 families. The majority (67%) of patients were compound heterozygotes, while 33% were homozygotes. To determine the existence of common haplotypes and potential founder effects, we analyzed five microsatellite markers within and flanking the ATM gene. Haplotype analysis was carried out in 48/63 families harbouring 16 of the 21 recurrent mutations. Forty different haplotypes were detected in the 48 A-T families studied. We found that the majority of patients with the same recurrent mutation originated from the same geographical area. All but one recurrent mutation analyzed displayed a common haplotype suggesting a single origin that then spread to different geographical areas. The high number of different haplotypes does not allow the screening of ATM mutations by haplotype analysis alone in the Italian population. The finding of recurrent public mutations without founder effect suggests the existence of 'mild' hot spots of mutation located along the sequence of the ATM gene.     

Contribution of ABCC6 genomic rearrangements to the diagnosis of pseudoxanthoma elasticum in French patients

Pseudoxanthoma elasticum (PXE) is an autosomal recessive disorder of connective tissues, which manifests with cutaneous, ophthalmologic and cardiovascular findings. PXE is caused by mutations in ABCC6 encoding a multidrug resistance protein (ABCC6, also known as MRP6). ABCC6 mutation detection rate ranges from 55% to 97% and it has been suggested that some of the remaining unidentified mutant alleles could correspond to large genomic rearrangements. In our cohort of 65 French PXE patients analysed for ABCC6 mutations, we identified two novel homozygous ABCC6 exonic deletions (deletions of exons 9-10 and exons 24-27). In order to systematically search for heterozygous genomic rearrangements, we have developed a quantitative multiplex PCR of short fluorescent fragments (QMPSF) approach that screens the 31 exons of ABCC6. We used QMPSF to analyse 13 PXE carrying at least one unidentified mutant, corresponding to 18 unidentified mutated alleles. This led to the detection of three large ABCC6 deletions, and two deletions of a single exon (exon 1 and exon 21). Thus QMPSF identified the causative mutation in 28% (5/18) of the uncharacterized ABCC6 mutant alleles in this cohort.     

Comprehensive scanning of the ATM gene with DOVAM-S

Mutation detection at the ATM locus has been difficult because of the large size of the gene (66 exons), the fact that mutations are located throughout the entire gene with no hotspots, and the difficulty of distinguishing mutations from polymorphisms. In this study, the entire coding region (exons 4-65) was scanned, as well as the adjacent intronic regions, using DOVAM-S (Detection Of Virtually All Mutations-SSCP), a robotically-enhanced, multiplexed scanning method that is a highly sensitive modification of SSCP. Forty-three unrelated patients and four obligate carriers were studied. Of the 90 expected mutant alleles, 71 were identified (79%). The mutations included 17 nonsense (24%), 20 frameshift (28%), 20 splice (28%), 10 missense (14%), one in-frame deletion (1%), and three that alter the initiation codon (4%). Among the ataxia-telangiectasia patients, two potentially causative mutations were identified in 30 individuals: 22 had two truncating mutations, four had one truncating and one missense mutation, three had two missense mutations, and one had a truncating mutation and an in-frame deletion of three amino acids. For seven A-T patients and all four obligate carriers, only one truncating mutation was detected. Six of the 43 A-T patients had no detected mutations (14%). Twelve novel mutations and six novel polymorphisms were detected. The results of this complete scan of the ATM coding region showed that 86% of causative ATM mutations were truncating and 14% were missense. DOVAM-S is a rapid, efficient method of performing A-T diagnosis and carrier testing on a clinical time scale.     

Molecular mechanisms underlying large genomic deletions in ornithine transcarbamylase (OTC) gene

Ornithine transcarbamylase deficiency (OTCD) is an X-linked urea cycle error causing hyperammonemia and orotic aciduria. Clinical diagnosis is generally confirmed by mutation detection. However, in ∼20% of the patients, no mutation is found by conventional mutation-searching strategies, which fail to detect deletions spanning at least a whole exon, large rearrangements, or mutations at non-coding regions. To detect large deletions or duplications, we have applied the multiplex ligation-dependent probe amplification (MLPA) methodology to three OTCD patients (two females and one male). MLPA revealed copy number alterations of OTC exons in all of them. The two females were found to be heterozygous for deletions of either exon 2 or exons 6–9, and the male was confirmed to lack all OTC exons. Females' characterization of the deletion breakpoints by long polymerase chain reaction and sequencing revealed the mutations c.78-3544_217-129del5921 and c.541-600_1005 + 1880del10862 corresponding to exon 2 and exon 6–9 deletions, respectively. Examination of the deletion-flanking regions suggests that exon 2 deletion probably resulted from replication slippage facilitated by a secondary structure formed by two inverted Alu repeats, whereas an Alu – Alu homologous recombination was probably responsible for the exon 6–9 deletion. This work contributes to the identification of novel disease-causing mutations in OTCD and increases the knowledge on possible mutational mechanisms generating deletions in OTC .     

Deletion and insertion in vivo somatic mutations in the hypoxanthine phosphoribosyltransferase (hprt) gene of human T-lymphocytes

Deletion and insertion mutations have been found to be a major component of the in vivo somatic mutation spectrum in the hypoxanthine phosphoribosyltransferase (hprt) gene of T-lymphocytes. In apopulation of 172 healthy people (average age, 34; mutant frequency, 10.3 × 10⁻⁶), deletion/in sertion mutations constituted 41% (89) of the 217independent mutations, the remainder being base substitutions. Mutations were identified by multiplex PCR assay of genomic DNA for exon regions, by sequencing cDNA, or sequencing genomic DNA. The deletion and insertion mutations were divided among ±1 to 2 basepair (bp) frameshifts (14%, 30), small deletions and insertions of 3–200 bps (13%, 28), large deletions of one or more exons (12%, 27), and complex events (2%, 4). Frameshift mutations were dominated by −1 bp deletions (21 of 30). Exon 3 contained five frameshift mutations in the run of 6 Gs, the only site in the coding region with multiple frameshift mutations, possibly caused by strand dislocation during replication. Both end points were sequenced for 23 of the 28 small deletions/insertions including two tandem duplication events in exon 6. More small deletions (8/28), pos sibly mediated by trinucleotide repeats, occurred in exon 2 than in the other exons. Large deletions included total gene deletions (6), exon 2 + 3 dele tions (4), and loss of multiple (9) and single exons (8) in genomic DNA. The diverse mutation spectrum indicates that multiple mechanisms operated at many different sequences and provides a resource for examination of deletion mutation. Environ. Mol. Mutagen. 30:371–384, 1997 © 1997 Wiley-Liss, Inc.     

Two novel variants in the ATM gene causing ataxia‐telangiectasia,including a duplication of 90 kb: Utility of targeted next‐generation sequencing in detection of copy number variation

Ataxia‐telangiectasia (A‐T) is a rare autosomal recessive neurodegenerative disorder characterized by progressive cerebellar ataxia, ocular apraxia, immunodeficiency, telangiectasia, elevated serum α‐fetoprotein concentration, radiosensitivity and cancer predisposition. Classical A‐T is caused by biallelic variants on ATM (ataxia telangiectasia mutated) gene, leading to a loss of function of the protein kinase ATM, involved in DNA damage repair. Atypical presentations can be found in A‐T‐like disease or in Nijmegen breakage syndrome, caused by deficiency of mre11 or nibrin proteins, respectively. In this report, we present the genetic characterization of a 4‐year‐old female with clinical diagnosis of A‐T. Next‐generation sequencing (NGS) revealed two novel heterozygous mutations in the ATM gene: a single‐nucleotide variant (SNV) at exon 47 (NM_000051.3:c.6899G > C; p.Trp2300Ser) and ～90 kb genomic duplication spanning exons 17–61, NG_009830.1:g.(41245_49339)_(137044_147250)dup. These findings were validated by Sanger sequencing and MLPA (multiplex ligation‐dependent probe amplification) analysis respectively. Familial segregation study confirmed that the two variants are inherited, and the infant is a compound heterozygote. Thus, our study expands the spectrum of ATM pathogenic variants and demonstrates the utility of targeted NGS in the detection of copy number variation.     

Unusual Mutations in Btk: An Insertion,a Duplication,an Inversion,and Four Large Deletions

Mutations in Bruton's tyrosine kinase (Btk) result in the immunodeficiency X-linked agammaglobulinemia (XLA). In a previous study of 101 patients with presumed XLA, we identified seven patients with large genomic alterations in Btk. The recent completion of 100 kb of contiguous DNA sequence at the Btk locus has allowed us to characterize these mutations in detail and to identify four different types of alterations. These alterations included a 253-bp retroposon insertion at position +5 within intron 9, an inversion of greater than 48 kb that disrupted Btk between exons 4 and 5, a 12.9-kb duplication including Btk exons 2 to 5, and four deletions ranging from 2.8 to 38 kb in size. The duplication and three of the deletions resulted from unequal crossovers of Alu repeats. Further, three of the deletions terminated within a repeat-rich cluster spanning 30 kb of sequence 3′ of Btk exon 19, suggesting that this region was more susceptible to unequal crossovers than the rest of the Btk gene. These studies describe the first reports of an insertion, an inversion, and a duplication in Btk and demonstrate the utility of large-scale sequencing in the elucidation of disease-causing mutations.     

Large genomic rearrangements in NIPBL are infrequent in Cornelia de Lange syndrome

Cornelia de Lange Syndrome (CdLS) is a multiple congenital anomaly syndrome characterized by a distinctive facial appearance, malformations of the upper limbs, and delay in growth and development. Mutations in NIPBL are associated with CdLS in 27-56% of cases and have been reported as point mutations, small insertions and deletions in coding regions, regulatory regions and at splice junctions. All previous studies used PCR-based exon-scanning methodologies that do not allow detection of large genomic rearrangements. We studied the relative copy number of NIPBL exons in a series of 50 CdLS probands, negative for NIPBL mutations, by multiplex ligation-dependent probe amplification (MLPA). In a single patient, we found a 5.2 kb deletion encompassing exons 41-42 of NIPBL. Our studies indicate that large NIPBL rearrangements do occur in CdLS but are likely to be infrequent events.     

Comparative multiplex dosage analysis detects whole exon deletions at the phenylalanine hydroxylase locus

We have developed quantitative comparative multiplex dosage analysis to detect altered copy number of regions of the phenylalanine hydroxylase gene. Out of 41 alleles (4% of 1,010 PKU chromosomes) on which a mutation had not been characterized previously, this technique has highlighted two novel mutations: deletions of exon 5 and of exon 6 on a total of eight alleles. Restriction-enzyme digestion of genomic DNA and hybridization to an amplified segment of the phenylalanine hydroxylase (PAH) cDNA probe PAH247 established the size of the deletion in five individuals to be between 700 and 900 bases. We also report somatic mosaicism in the parent of an affected child previously shown to have a deletion spanning exons 5 and 6. Finally, we report a putative duplication of a region encompassing exon 6 in an affected individual.