Genetic analysis of contiguous X-chromosome deletion syndrome encompassing the BTK and TIMM8A genes

Patients with X-linked agammaglobulinemia (XLA) can present with sensorineural deafness. This can result from a gross deletion that not only involved the Bruton's tyrosine kinase (BTK) gene, but also TIMM8A, mutations in which underlie the Mohr-Tranebj?rg syndrome (MTS). We analyzed the genomic break points observed in three XLA-MTS patients and compared these with deletions break points from XLA patients. Patient 1 had a 63-kb deletion with break points in intron 15 of BTK and 4?kb upstream of TAF7L. Patients 2 and 3 had 149.7 and 196?kb deletions comprising BTK, TIMM8A, TAF7L and DRP2. The break points in patients 1 and 3 were located in Alu and endogenous retrovirus (ERV) repeats, whereas the break points in patient 2 did not show involvement of transposable elements. Comparison of gross deletion sizes and involvement of transposable elements in XLA and XLA-MTS patients from the literature showed preferential involvement of Alu elements in smaller deletions (<10?kb). These results show further insights into the molecular mechanisms underlying gross deletions in patients with primary immunodeficiency.     

The Delta>15 Kb deletion French Canadian founder mutation in familial hypercholesterolemia: rapid polymerase chain reaction-based diagnostic assay and prevalence in Quebec

Approximately one in 500 individuals in Western population has autosomal dominant familial hypercholesterolemia due to mutations in the low-density lipoprotein receptor (LDLR) gene. Screening for these mutations is hampered by their large number, except in founder populations. We identified the breakpoint of the >15 kb deletion involving the LDLR gene promoter and exon 1, responsible for more than 60% of French Canadian hypercholesterolemia cases, as well as the breakpoint of the 5 kb deletion of exons 2 and 3 that accounts for an additional 5% of cases. Both deletions appear to be because of homologous recombination by unequal crossing-over between the left arms of Alu repeats. Using RepeatMasker, we determined that 55% of the LDLR gene is composed of Alu elements; thus, it is not surprising that most LDLR rearrangements involve at least one Alu. Furthermore, we developed a rapid polymerase chain reaction-based assay for the French Canadian-1 (>15 kb) and French Canadian-5 (5 kb) hypercholesterolemia alleles. Screening a representative population sample of 943 French Canadian youths whose LDL cholesterol levels were above the 50th percentile allowed us to estimate the prevalence of the >15 kb allele as 0.11% (95% confidence interval, 0.03-0.38).     

Characterization of breakpoint sequences of five rearrangements in L1CAM and ABCD1 (ALD) genes

Mutations in L1CAM are responsible for X-linked hydrocephalus, whereas those in the ALD gene (ABCD1) cause adrenoleukodystrophy. In both genes, most of the mutations reported so far are short-length mutations and only a few patients with larger rearrangements have been documented. We have characterized three intragenic deletions of the ALD gene at the molecular level and describe here the first two L1CAM rearrangements resulting in deletion of several exons in one case and about 50 kb, including the entire gene, in the second case. At both breakpoints of an ALD deletion, Alu repeats have been found and, additionally, a short Alu region of approximately 130 bp was inserted, suggesting that this rearrangement is the result of a more complex non-allelic homologous recombination event. Only one Alu element was present at the breakpoint of the second ALD rearrangement, including a 26-bp Alu core sequence that was suggested to be a recombinogenic hot spot. These data suggest the involvement of an Alu core sequence-stimulated non-homologous recombination as a possible cause for this rearrangement. Short direct repeats were identified at all putative mispaired sequences in the L1CAM breakpoints and at both breakpoints of the third ALD deletion characterized, suggesting non-homologous (illegitimate) recombination as the molecular mechanism by which these latter deletions occurred. In conclusion, our results indicate that highly repetitive elements as well as short direct repeats are frequently involved in the formation of ALD and L1CAM gene rearrangements.     

缺失型杜氏肌营养不良症缺失热区内含子断裂点分子结构特点的对比分析

目的 对比分析缺失型杜氏肌营养不良症(Duchenne muscular dystrophy，DMD)缺失热区第46号和51号外显子缺失后形成的连接片段的断裂点的分子结构特点，以研究DMD基因外显子的缺失机理。方法 多重引物PCR法鉴定缺失型DMD患者，分别克隆第46、51号外显子缺失后形成的连接片段，测定断裂点侧翼的核苷酸序列。结果第46号外显子缺失后，5’端断裂点位于45号内含子的AT富含区内。3’端断裂点位于46号内含子的中等重复序列(medium reiteration repeats，MERl)内。连接片段有两个bp的连接同源序列ta，局部无小的缺失、插入和碱基的置换。第51号外显子缺失后，5’端断裂点位于50号内含子的人类类转座因子(transposon-like human elements，THEl)序列内。3’端短裂点位于51号内含子L2序列内。连接片段有3个bp的连接同源序列cta，局部无小的缺失、插入和碱基的置换。第46、51号外显子缺失后连接片段的断裂点的二级结构分析示断裂点均位于单链发夹环的非匹配区。结论 对比第46、51号外显子缺失后形成的连接片段，其断裂点的共同特征是均位于重复序列，这些重复序列形成的单链发夹结构，使DNA结构具有不稳定性，易于断裂并导致外显子缺失。     

Different molecular mechanisms underlie genomic deletions in the MLH1 Gene

In this study we examined a series of 52 patients belonging to hereditary nonpolyposis colorectal cancer (HNPCC) or HNPCC-related families, all who had previously tested negative for mismatch repair (MMR) gene point mutations. Southern blot mutational screening of MLH1 and MSH2 genes was carried out with the aim of detecting large genomic rearrangements and of identifying the molecular mechanisms underlying the inactivation of the MMR genes. Three patients had abnormal restriction patterns and were found to carry distinct MLH1 internal deletions. Long-range PCRs identified the loss of DNA tracts spanning exon 6 (about 2.4 kb in proband A-AV20 and 0.8 kb in proband A-PD5) and exon 3 (about 2.5 kb in proband R-RM2). In A-AV20 the breakpoints occurred into identical 33-bp regions in introns 5 and 6 and a mechanism of classical Alu-mediated homologous recombination was evident. Also, in patient A-PD5 the breakpoints were located in these introns, but without direct involvement of repetitive sequences. In patient R-RM2 the breakpoints were located within repetitive L1 elements with poor homology in intron 2 and 3 and the rearranged allele was characterized by a complex insertion deletion (delCCinsACATAGTA), giving rise to a palindromic CTTAACATAGTATGTTAAG sequence in proximity of the fusion site. This study confirms that genomic rearrangements are an important component of the spectrum of MMR mutations. Although Alu repeats are likely to be implicated in the majority of cases, different molecular mechanisms may also be responsible for the observed MLH1 intragenic deletions. In particular, HNPCC resulting from L1-mediated recombination has been identified as a novel mechanism for MMR inactivating mutation.     

Frequent site-specific mit− deletions at cryptic exon-intron junctions in the COX1 gene of yeast mtDNA

A class of large site-specific deletions (del-B) occurs with exceptionally-high frequencies of 10^-3 in the mitochondrial COX1 gene of Mn²⁺-treated yeast cells. This work shows that del-B deletions are associated with COX1 intron aI1. All five deletion mutants studied have their upstream end at the authentic 3 splice site of this intron. The deletion ends 8.2 kb downstream in intron aI5b. This downstream deletion-end constitutes a potentially-cryptic 5 splice site for intron aI1. The coincidences of the del-B deletion-ends with authentic and cryptic RNA splice sites suggest that the group-II intron aI1, and/or the RNA maturase encoded in it, plays an active role in this exceptionally-frequent, site-specific deletion process.     

Novel genomic insertion-- deletion in MLH1: possible mechanistic role for non-homologous end-joining DNA repair

Hereditary non-polyposis colorectal cancer (HNPCC) is an inherited cancer syndrome caused by a defect in the mismatch repair pathway. The majority of HNPCC mutations have been detected in MLH1 and MSH2. Most reported mutations are substitutions, small insertions and deletions, but standard methods of mutation analysis do not detect large rearrangements. It is now established that large deletions, insertions and rearrangements account for a significant proportion of MLH1 and MSH2 mutations. We report an unusual rearrangement resulting in the deletion of exons 6, 7 and 8 of MLH1, with the retention of part of intron 6 and insertions of two nucleotides each flanking the retained sequence. The 349-bp-retained sequence is made up of two closely spaced Alu sequences. The mutation was initially detected by protein truncation test and cDNA sequencing. Multiplex ligation-dependent probe amplification confirmed the deletion of three exons. PCR and sequencing were used to characterize the breakpoint. Despite the high density of Alu elements in MLH1, there is no homology at the deletion breakpoints or insertion junctions in this case to suggest that homologous recombination has occurred. We propose a mechanism involving non-homologous end joining to explain the occurrence of this complex deletion.     

A novel complex deletion-insertion mutation mediated by Alu repetitive elements leads to lipoprotein lipase deficiency

Lipoprotein lipase (LPL) deficiency is a rare autosomal recessive inherited disorder, characterized by marked hypertriglyceridemia, eruptive xanthoma, hepatosplenomegaly, recurrent attacks of pancreatitis, and markedly low or absent LPL activity in postheparin plasma. A majority of LPL deficient patients have been reported to have point mutations in the LPL gene; however, we find a complex deletion-insertion mutation by Alu elements, mobile retrotransposons, in a patient with LPL deficiency. This patient suffered from acute pancreatitis, showed chylomicronemia and lacked detectable LPL activity or mass in her postheparin plasma. Southern blot analysis and long-range PCR of the patient's DNA demonstrated a 2.2-kb deletion encompassing exon 2. Sequence analysis revealed (1) a 2.3-kb deletion between an AT-rich region adjacent to an Alu element in intron 1 and another Alu element in intron 2; (2) an insertion of approximately 150bp 5'-truncated Alu sequence with a poly (A) tail at the deletion point. The inserted sequence belongs to Alu Yb9, the youngest subfamily of Alu elements. The deletion occurred at the consensus cleavage site (3'-A|TTTT-5') without target site duplication. These findings indicated that Alu retrotransposition caused the complex deletion-insertion. The patient was homozygous for this complex mutation, which eliminates exon 2 and leads to LPL deficiency. To our knowledge, the patient is the first case with LPL deficiency due to a complex deletion-insertion mediated by Alu repetitive elements.     

Nonrandom distribution of interspersed repeat elements in the BCR and ABL1 genes and its relation to breakpoint cluster regions

The Philadelphia translocation, t(9;22)(q34;q11), is the microscopically visible product of recombination between two genes, ABL1 on chromosome 9 and BCR on chromosome 22, and gives rise to a functional hybrid BCR-ABL1 gene with demonstrated leukemogenic properties. Breakpoints in BCR occur mostly within one of two regions: a 5 kb major breakpoint cluster region (M-Bcr) and a larger 35 kb minor breakpoint cluster region (m-Bcr) towards the 3' end of the first BCR intron. By contrast, breakpoints in ABL1 are reported to occur more widely across a >200 kb region which spans the large first and second introns. The mechanisms that determine preferential breakage sites in BCR, and which cause recombination between BCR and ABL1, are presently unknown. In some cases, Alu repeats have been identified at or near sequenced breakpoint sites in both genes, providing indications, albeit controversial, that they may be relevant. For the present study, we carried out a detailed analysis of genomic BCR and ABL1 sequences to identify, classify, and locate interspersed repeat sequences and to relate their distribution to precisely mapped BCR-ABL1 recombination sites. Our findings confirm that Alu are the most abundant class of repeat in both genes, but that they occupy fewer sites than previously estimated and that they are distributed nonrandomly. r-Scan statistics were applied to provide a measure of repeat distribution and to evaluate extremes in repeat spacing. A significant lack of Alu elements was observed across the major and minor breakpoint cluster regions of BCR and across a 25-kb region showing a high frequency of breakage in ABL1. These findings counter the suggestion that occurrence of Alu at BCR-ABL1 recombination sites is likely by chance because of the high density of Alu in these two genes. Instead, as yet unidentified DNA conformation or nucleotide characteristics peculiar to the preferentially recombining regions, including those Alu elements present within them, more likely influence their fragility.     

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.     

Comparative analysis of vertebrate dystrophin loci indicate intron gigantism as a common feature

The human DMD gene is the largest known to date, spanning > 2000 kb on the X chromosome. The gene size is mainly accounted for by huge intronic regions. We sequenced 190 kb of Fugu rubripes (pufferfish) genomic DNA corresponding to the complete dystrophin gene (FrDMD) and provide the first report of gene structure and sequence comparison among dystrophin genomic sequences from different vertebrate organisms. Almost all intron positions and phases are conserved between FrDMD and its mammalian counterparts, and the predicted protein product of the Fugu gene displays 55% identity and 71% similarity to human dystrophin. In analogy to the human gene, FrDMD presents several-fold longer than average intronic regions. Analysis of intron sequences of the human and murine genes revealed that they are extremely conserved in size and that a similar fraction of total intron length is represented by repetitive elements; moreover, our data indicate that intron expansion through repeat accumulation in the two orthologs is the result of independent insertional events. The hypothesis that intron length might be functionally relevant to the DMD gene regulation is proposed and substantiated by the finding that dystrophin intron gigantism is common to the three vertebrate genes.     

Deletion of the C-terminal end of aspartylgiucosaminidase resulting in a lysosomal accumulation disease: evidence for a unique genomic rearrangement

Aspartyiglucosaminuria (AGU) is an inborn error of glycoproteincatabolism and represents the only known human deficiency ofan amidase, aspartyiglucosaminidase (AGA, EC 3.5.1.26 [EC] ). We reporthere a detailed characterization of a unique 2 kb deletion ofthe AGA gene in a North American AGU patient. To facilitatethe characterization of the deletion, genomic lamda clones spanningthe 3' flanking region of human AGA were isolated and sequenced.The breakpoint of the deletion was determined from the patient'sDNA by sequencing the genomic region containing the novel junction.The rearrangement involved a nonhomologous recombination withonly 2 bp of homology at the deletion breakpoint. The deletion's5' breakpoint was located in the last intron of AGA, thus abolishingthe normal C-terminal exon. This is in contrast to our previousfindings indicating that the deletion in the AGA gene wouldcontain only the complete 3' untranslated region and leave thecoding region intact (1). The unique feature of this deletionis a triplication of 19 thymidine nucleotides of an invertedAlu repeat, which is located at the deletion 3' breakpoint.The analysis of the patient's AGA cONA revealed an open readingframe containing a novel C-terminal exon, coding for a 64 aminoacid sequence, which has no homology to the normal exon 9 ofAGA. This new exon has a functional splice acceptor site atits 5' end, a stop codon, and a polyadenylation signal at the3' end. Expression of the mutant AGA cDNA in COS cells showedthat mutant mRNA is synthesized in equal amounts compared withnormal. However, the mutant polypeptide precursor is not processedinto the mature subunits of AGA, and is totally degraded within24 h of synthesis.     

Genomic rearrangements of hMSH6 contribute to the genetic predisposition in suspected hereditary non-polyposis colorectal cancer syndrome

Methods: Out of 15 HNPCC or HNPCC-like patients who developed tumours with loss of hMSH6 protein expression, we selected three patients who still had no germline mutations after gene sequencing. Genomic DNA of these patients was analysed using PCR based relative quantification of hMSH6 fragments. Indicated exon deletions and amplifications were characterised by long range PCR and sequencing.

Results: Genomic rearrangements were identified in two of the three patients. Breakpoint analyses showed an Alu repeat mediated deletion of 13.0 kb affecting the promoter region, exon 1, and exon 2 in one patient, and a duplication of 4.9 kb containing 1.6 kb of the 3' end of exon 4 and exon 5, integrated into intron 5, in the other patient.

Conclusions: Although genomic rearrangements of hMSH6 only play a small role in the spectrum of all mutations predisposing to HNPCC, our results suggest that up to 10–20% of patients with hMSH6 negative tumours harbour germline rearrangements in this gene.

     

Rearrangement in the PITX2 and MIPOL1 genes in a patient with a t(4;14) chromosome

We report the molecular characterization of a patient with mild craniofacial and acallosal central nervous system midline defects and a t(4;14)(q25)(q13) chromosome. With the use of flow sorted chromosomes, the translocation breakpoint junction was defined within a 100 kb region with markers mapping to chromosomes 4q25 and 14q13. Analysis of genomic sequences demonstrated that the breakpoint junction at 14q13 was within the third intron of the 5' untranslated region of the MIPOL1 gene (GI: 22048098). On chromosome 4q25, two breakpoint junctions were found. One was about 47 kb distal to the 5' end of a putative gene (GI: 8923996) with unknown function but with partial similarity to kinases, and a second breakpoint was within the 3' end of the PITX2 gene (GI: 21361182) that resulted in the deletion of exons 6 and 7 of this gene. We also searched for microdeletions in a panel of candidate genes mapping within 2 Mb of the translocation breakpoint junction on chromosomes 4 and 14, however, no evidence for deletions or rearrangements was found. The finding of two breaks on chromosome 4q25 suggests a complex microrearrangement, such as an inversion, in addition to a translocation in this patient.     

A very large spontaneous deletion ataprt locus in CHO cells: Sequence similarities with smallaprt deletions

Spontaneous deletion mutants can be isolated from CHO cell lines heterozygous at the adenine phosphoribosyltransferase locus at frequencies up to 10^–4, i.e., about 100-fold higher than spontaneous point mutations. Indirect evidence has suggested that most deletions were in the megabase range. We have fully characterized one such mutant, Del 155, and shown that it resulted from an illegitimate recombination that took place between overlapping tetranucleotides. Comparisons with sequences of other deletions at various loci revealed a number of similarities, most striking of which was a CHI-like motif found within 6 bp of the upstream breakpoint of Del 155 and breakpoints of 8/21 previously described short deletions at the CHO aprt locus. Homology also existed between the downstream breakpoint of Del 155 and breakpoints of retinoblastoma gene deletions (3/6 cases) and also a 20-bp stretch of an Alu sequence in which breakpoints at the low-density lipoprotein receptor locus have been shown to cluster. The magnitude of the deletion event in Del 155 was assessed by pulsed field (PF) gel analysis and found to be at least 2100 kb long. PF analysis also indicated that the downstream breakpoint was near a region of structural differences between the two chromosomes carrying aprt. These structural differences were probably not implicated in the mechanism of the high frequency event, since no indication of breakpoint clustering among a large collection of mutants was found either by conventional or PF electrophoretic analyses.     

High-frequency deletion event ataprt locus of CHO cells: Detection and characterization of endpoints

Two mechanisms are implicated in generating recessive drug resistance mutants at the adenine phosphoribosyltransferase (aprt) locus of Chinese hamster ovary (CHO) cells, one of which is a spontaneous high-frequency deletion of the entire gene. We have isolated and mapped a 19-kb fragment carrying aprtand its flanking sequences. A Southern blot study of 198 independent deletion mutants revealed that two different mutants have one of their breakpoints within the 19-kb region analyzed. One of these has an upstream breakpoint which could be narrowed down to a 4-b fragment containing repetitive sequences. The other mutant has a breakpoint within a 410-bp sequence located 8.5 kb downstream of the aprtgene and which carries several elements similar to those signaling V-(D) -J joining in immunoglobulin and T-cell receptor gene rearrangements. In each case the other breakpoint lay outside of the analyzed region. These results support the previous indications that the deletions created by this spontaneous event are large.