Alpha-galactosidase A gene rearrangements causing Fabry disease. Identification of short direct repeats at breakpoints in an Alu-rich gene

Fabry disease, an inborn error of glycosphingolipid catabolism, results from mutations in the X-linked gene encoding the lysosomal enzyme, alpha-galactosidase A (EC 3.2.1.22). Six alpha-galactosidase A gene rearrangements that cause Fabry disease were investigated to assess the role of Alu repetitive elements and short direct and/or inverted repeats in the generation of these germinal mutations. The breakpoints of five partial gene deletions and one partial gene duplication were determined by either cloning and sequencing the mutant gene from an affected hemizygote, or by polymerase chain reaction amplifying and sequencing the genomic region containing the novel junction. Although the alpha-galactosidase A gene contains 12 Alu repetitive elements (representing approximately 30% of the 12-kilobase (kb) gene or approximately 1 Alu/1.0 kb), only one deletion resulted from an Alu-Alu recombination. The remaining five rearrangements involved illegitimate recombinational events between short direct repeats of 2 to 6 base pairs (bp) at the deletion or duplication breakpoints. Of these rearrangements, one had a 3' short direct repeat within an Alu element, while another was unusual having two deletions of 1.7 kb and 14 bp separated by a 151-bp inverted sequence. These findings suggested that slipped mispairing or intrachromosomal exchanges involving short direct repeats were responsible for the generation of most of these gene rearrangements. There were no inverted repeat sequences or alternating purine-pyrimidine regions which may have predisposed the gene to these rearrangements. Intriguingly, the tetranucleotide CCAG and the trinucleotide CAG (or their respective complements, CTGG and CTG) occurred within or adjacent to the direct repeats at the 5' breakpoints in three and four of the five alpha-galactosidase A gene rearrangements, respectively, suggesting a possible functional role in these illegitimate recombinational events. These studies indicate that short direct repeats are important in the formation of gene rearrangements, even in human genes like alpha-galactosidase A that are rich in Alu repetitive elements.     

Non-recurrent 17p11.2 deletions are generated by homologous and non-homologous mechanisms

Several recurrent common chromosomal deletion and duplication breakpoints have been localized to large, highly homologous, low-copy repeats (LCRs). The mechanism responsible for these rearrangements, viz., non-allelic homologous recombination between LCR copies, has been well established. However, fewer studies have examined the mechanisms responsible for non-recurrent rearrangements with non-homologous breakpoint regions. Here, we have analyzed four uncommon deletions of 17p11.2, involving the Smith–Magenis syndrome region. Using somatic cell hybrid lines created from patient lymphoblasts, we have utilized a strategy based on the polymerase chain reaction to refine the deletion breakpoints and to obtain sequence data at the deletion junction. Our analyses have revealed that two of the four deletions are a product of Alu/Alu recombination, whereas the remaining two deletions result from a non-homologous end-joining mechanism. Of the breakpoints studied, three of eight are located in LCRs, and five of eight are within repetitive elements, including Alu and MER5B sequences. These findings suggest that higher-order genomic architecture, such as LCRs, and smaller repetitive sequences, such as Alu elements, can mediate chromosomal deletions via homologous and non-homologous mechanisms. These data further implicate homologous recombination as the predominant mechanism of deletion formation in this genomic interval.     

Analysis of 22 deletion breakpoints in dystrophin intron 49

Over 60% of Duchenne and Becker muscular dystrophies are caused by deletions spanning tens or hundreds of kilobases in the dystrophin gene. The molecular mechanisms underlying the loss of DNA at this genomic locus are not yet understood. By studying the distribution of deletion breakpoints at the genomic level, we have previously shown that intron 49 exhibits a higher relative density of breakpoints than most dystrophin introns. To determine whether the mechanisms leading to deletions in this intron preferentially involve specific sequence elements, we sublocalized 22 deletion endpoints along its length by a polymerase-chain-reaction-based approach and, in particular, analyzed the nucleotide sequences of five deletion junctions. Deletion breakpoints were homogeneously distributed throughout the intron length, and no extensive homology was observed between the sequences adjacent to each breakpoint. However, a short sequence able to curve the DNA molecule was found at or near three breakpoint junctions.     

DNA Sequences Proximal to Human Mitochondrial DNA Deletion Breakpoints Prevalent in Human Disease Form G-quadruplexes,a Class of DNA Structures Inefficiently Unwound by the Mitochondrial Replicative Twinkle Helicase

Mitochondrial DNA deletions are prominent in human genetic disorders, cancer, and aging. It is thought that stalling of the mitochondrial replication machinery during DNA synthesis is a prominent source of mitochondrial genome instability; however, the precise molecular determinants of defective mitochondrial replication are not well understood. In this work, we performed a computational analysis of the human mitochondrial genome using the “Pattern Finder” G-quadruplex (G4) predictor algorithm to assess whether G4-forming sequences reside in close proximity (within 20 base pairs) to known mitochondrial DNA deletion breakpoints. We then used this information to map G4P sequences with deletions characteristic of representative mitochondrial genetic disorders and also those identified in various cancers and aging. Circular dichroism and UV spectral analysis demonstrated that mitochondrial G-rich sequences near deletion breakpoints prevalent in human disease form G-quadruplex DNA structures. A biochemical analysis of purified recombinant human Twinkle protein (gene product of c10orf2) showed that the mitochondrial replicative helicase inefficiently unwinds well characterized intermolecular and intramolecular G-quadruplex DNA substrates, as well as a unimolecular G4 substrate derived from a mitochondrial sequence that nests a deletion breakpoint described in human renal cell carcinoma. Although G4 has been implicated in the initiation of mitochondrial DNA replication, our current findings suggest that mitochondrial G-quadruplexes are also likely to be a source of instability for the mitochondrial genome by perturbing the normal progression of the mitochondrial replication machinery, including DNA unwinding by Twinkle helicase.     

242 breakpoints in the 200-kb deletion-prone P20 region of the DMD gene are widely spread.

Using whole cosmids as probes, we have mapped 242 DMD/BMD deletion breakpoints located in the major deletion hot spot of the DMD gene. Of these, 113 breakpoints were mapped more precisely to individual restriction enzyme fragments in the distal 80 kb of the 170-kb intron 44. An additional 12 breakpoints are distributed over the entire region, with no significant local variation in frequency. Furthermore, deletion sizes vary and are not influenced by the positions of the breakpoints. This argues against a predominant role of one or a few specific sequences in causing frequent rearrangements. It suggests that structural characteristics or a more widespread recombinogenic sequence makes this region so susceptible to deletion. Our study revealed several RFLPs, one of which is a 300-bp insertion/deletion polymorphism. Abnormally migrating junction fragments are found in 81% of the precisely mapped deletions and are highly valuable in the diagnosis of carrier females.     

Evidence for non-homologous end joining and non-allelic homologous recombination in atypical NF1 microdeletions

NF1 microdeletion syndrome is caused by haploinsufficiency of the NF1 gene and of gene(s) located in adjacent flanking regions. Most of the NF1 deletions originate by non-allelic homologous recombination between repeated sequences (REP-P and -M) mapped to 17q11.2, while the remaining deletions show unusual breakpoints. We performed high-resolution FISH analysis of 18 NF1 microdeleted patients with the aims of mapping non-recurrent deletion breakpoints and verifying the presence of additional recombination-prone architectural motifs. This approach allowed us to obtain the sequence of the first junction fragment of an atypical deletion. By conventional FISH, we identified 16 patients with REP-mediated common deletions, and two patients carrying atypical deletions of 1.3 Mb and 3 Mb. Following fibre-FISH, we identified breakpoint regions of 100 kb, which led to the generation of several locus-specific probes restricting the atypical deletion endpoint intervals to a few kilobases. Sequence analysis provided evidence of small blocks of REPs, clustered around the 1.3-Mb deletion breakpoints, probably involved in intrachromatid non-allelic homologous recombination (NAHR), while isolation and sequencing of the 3-Mb deletion junction fragment indicated that a non-homologous end joining (NHEJ) mechanism is implicated.M. Venturin and C. Gervasini contributed equally to the study     

Two direct repeats cause most human mtDNA deletions

Mitochondrial DNA (mtDNA) deletions are a common cause of human mitochondrial disease and also occur as part of normal aging. However, it is unknown how the deletions actually occur. To gain further insight, we studied the sequences that flank 263 different human mtDNA deletions. The distribution of deletion breakpoints did not correspond to the basic parameters of wild-type mtDNA that are thought to predispose to deletion formation. But there was a striking correspondence to the position of two 13-bp direct repeats beginning at nucleotides 8470 and 13 447. The vast majority of different mtDNA deletions appear to be related to these two repeats, suggesting a common mechanism related to mtDNA replication.     

Recombination via flanking direct repeats is a major cause of large-scale deletions of human mitochondrial DNA

Large-scale deletions of mitochondrial DNA (mtDNA) have been described in patients with progressive external ophthalmoplegia (PEO) and ragged red fibers. We have determined the exact deletion breakpoint in 28 cases with PEO, including 12 patients already shown to harbor an identical deletion; the other patients had 16 different deletions. The deletions fell into two classes. In Class I (9 deletions; 71% of the patients), the deletion was flanked by perfect direct repeats, located (in normal mtDNA) at the edges of the deletion. In Class II (8 deletions; 29% of patients), the deletions were not flanked by any obviously unique repeat element, or they were flanked by repeat elements which were located imprecisely relative to the breakpoints. Computer analysis showed a correlation between the location of the deletion breakpoints and sequences in human mtDNA similar to the target sequence for Drosophila topoisomerase II. It is not known how these deletions originate, but both slipped mispairing and legitimate recombination could be mechanisms playing a major role in the generation of the large mtDNA deletions found in PEO.     

Breakpoint junctions of chromosome 9p deletions in two human glioma cell lines.

Interstitial deletions of the short arm of chromosome 9 are associated with glioma, acute lymphoblastic leukemia, melanoma, mesothelioma, lung cancer, and bladder cancer. The distal breakpoints of the deletions (in relation to the centromere) in 14 glioma and leukemia cell lines have been mapped within the 400 kb IFN gene cluster located at band 9p21. To obtain information about the mechanism of these deletions, we have isolated and analyzed the nucleotide sequences at the breakpoint junctions in two glioma-derived cell lines. The A1235 cell line has a complex rearrangement of chromosome 9, including a deletion and an inversion that results in two breakpoint junctions. Both breakpoints of the distal inversion junction occurred within AT-rich regions. In the A172 cell line, a tandem heptamer repeat was found on either side of the deletion breakpoint junction. The distal breakpoint occurred 5' of IFNA2; the 256 bp sequenced from the proximal side of the breakpoint revealed 95% homology to long interspersed nuclear elements. One- and two-base-pair overlaps were observed at these junctions. The possible role of sequence overlaps, and repetitive sequences, in the rearrangement is discussed.     

A Chinese G gamma + (A gamma delta beta)zero thalassemia deletion: comparison to other deletions in the human beta-globin gene cluster and sequence analysis of the breakpoints.

A clone was isolated that contains the deletion junction region from an individual with a deletion associated with Chinese G gamma + (A gamma delta beta)zero thalassemia. A clone containing the normal DNA corresponding to the 3' breakpoint of this deletion was also isolated. Portions of these two clones were sequenced and compared to the region in the A gamma-globin gene where the 5' breakpoint occurs. This comparison reveals that the breakage and reunion event was nonhomologous and that it probably involved the insertion of 36-41 bases of DNA belonging to the L1 (KpnI) family of repetitive DNA. Genomic mapping revealed that the DNA on the 3' side of this deletion is closely linked in normal DNA to the 3' breakpoints of two different large deletions that are associated with hereditary persistence of fetal hemoglobin (HPFH). We cloned and mapped 35 kbp of normal DNA from this region (greater than 45 kbp downstream of the human beta-globin gene) that contains the 3' breakpoints of the Chinese thalassemia and the two HPFH deletions. An endogenous retrovirus-like element and several other repetitive sequences are located within this region. We show that the Chinese thalassemia deletion is greater than 80 kbp in length and differs in size from the two HPFH deletions by less than 6%. We also show that the Chinese thalassemia deletion is at least 40 kbp larger than several other deletions associated with a very similar phenotype.     

Molecular Analysis of a Deletion Hotspot in the NRXN1 Region Reveals the Involvement of Short Inverted Repeats in Deletion CNVs

NRXN1 microdeletions occur at a relatively high frequency and confer increased risk for neurodevelopmental and neurobehavioral abnormalities. The mechanism that makes NRXN1 a deletion hotspot is unknown. Here, we identified deletions of the NRXN1 region in affected cohorts, confirming a strong association with the autism spectrum and other neurodevelopmental disorders. Interestingly, deletions in both affected and control individuals were clustered in the 5′ portion of NRXN1 and its immediate upstream region. To explore the mechanism of deletion, we mapped and analyzed the breakpoints of 32 deletions. At the deletion breakpoints, frequent microhomology (68.8%, 2–19 bp) suggested predominant mechanisms of DNA replication error and/or microhomology-mediated end-joining. Long terminal repeat (LTR) elements, unique non-B-DNA structures, and MEME-defined sequence motifs were significantly enriched, but Alu and LINE sequences were not. Importantly, small-size inverted repeats (minus self chains, minus sequence motifs, and partial complementary sequences) were significantly overrepresented in the vicinity of NRXN1 region deletion breakpoints, suggesting that, although they are not interrupted by the deletion process, such inverted repeats can predispose a region to genomic instability by mediating single-strand DNA looping via the annealing of partially reverse complementary strands and the promoting of DNA replication fork stalling and DNA replication error. Our observations highlight the potential importance of inverted repeats of variable sizes in generating a rearrangement hotspot in which individual breakpoints are not recurrent. Mechanisms that involve short inverted repeats in initiating deletion may also apply to other deletion hotspots in the human genome.     

Uncommon Alu-mediated NF1 microdeletion with a breakpoint inside the NF1 gene

Neurofibromatosis type 1 (NF1) microdeletion syndrome is caused by haploinsufficiency of the NF1 gene and of gene(s) located in adjacent flanking regions. Most of the NF1 deletions originate by nonallelic homologous recombination between repeated sequences (REP-P and -M) mapped to 17q11.2, while a few uncommon deletions show unusual breakpoints. We characterized an uncommon 1.5-Mb deletion of an NF1 patient displaying a mild phenotype. We applied high-resolution FISH analysis allowing us to obtain the sequence of the first junction fragment of an uncommon deletion showing the telomeric breakpoint inside the IVS23a of the NF1 gene. Sequence analysis of the centromeric and telomeric boundaries revealed that the breakpoints were present in the AluJb and AluSx regions, respectively, showing 85% homology. The centromeric breakpoint is localized inside a chi-like element; a few copies of this sequence are also located very close to both breakpoints. The in silico analysis of the breakpoint intervals, aimed at identifying consensus sequences of several motifs usually involved in deletions and translocations, suggests that Alu sequences, probably associated with the chi-like element, might be the only recombinogenic motif directly mediating this large deletion.     

Different molecular mechanisms causing 9p21 deletions in acute lymphoblastic leukemia of childhood

Deletion of chromosome 9p21 is a crucial event for the development of several cancers including acute lymphoblastic leukemia (ALL). Double strand breaks (DSBs) triggering 9p21 deletions in ALL have been reported to occur at a few defined sites by illegitimate action of the V(D)J recombination activating protein complex. We have cloned 23 breakpoint junctions for a total of 46 breakpoints in 17 childhood ALL (9 B- and 8 T-lineages) showing different size deletions at one or both homologous chromosomes 9 to investigate which particular sequences make the region susceptible to interstitial deletion. We found that half of 9p21 deletion breakpoints were mediated by ectopic V(D)J recombination mechanisms whereas the remaining half were associated to repeated sequences, including some with potential for non-B DNA structure formation. Other mechanisms, such as microhomology-mediated repair, that are common in other cancers, play only a very minor role in ALL. Nucleotide insertions at breakpoint junctions and microinversions flanking the breakpoints have been detected at 20/23 and 2/23 breakpoint junctions, respectively, both in the presence of recombination signal sequence (RSS)-like sequences and of other unspecific sequences. The majority of breakpoints were unique except for two cases, both T-ALL, showing identical deletions. Four of the 46 breakpoints coincide with those reported in other cases, thus confirming the presence of recurrent deletion hotspots. Among the six cases with heterozygous 9p deletions, we found that the remaining CDKN2A and CDKN2B alleles were hypermethylated at CpG islands.     

Molecular characterization of germline NF2 gene rearrangements

Neurofibromatosis type 2 (NF2) is an autosomal dominant disease that causes a predisposition to nervous system tumors. Deleterious point mutations have been found in about 55% of NF2 patients, and large genomic deletions account for approximately 33% of NF2 gene alterations. The majority of these deletions are larger than 50 kb, with a breakpoint usually lying outside the NF2 gene. We identified two cases of intragenic deletion with loss of 1.5 and 40 kb, respectively. In both cases, one boundary of the deletion was located in or at the proximity of an SVA sequence in NF2 intron 4. No sequence identity longer than 5 bases and no signal of specific recombination have been evidenced on either side of the deletion breakpoints. These observations are compatible with a nonhomologous recombination being responsible for the genomic deletions. In a third case, a paracentric inversion of chromosome 22 was found. This chromosomal rearrangement breaks the NF2 gene in two parts and carries the first NF2 exon in a juxta-centromeric position. The variability in position of the deletions and the observation of a new chromosomal rearrangement in the NF2 gene underscore the importance of FISH analysis in the molecular diagnosis of NF2.     

Regional assignment of the human loci for uvomorulin (UVO) and chymotrypsinogen B (CTRB) with the help of two overlapping deletions on the long arm of chromosome 16

Using cDNA probes for the human uvomorulin (UVO) and rat chymotrypsinogen B (CTRB) genes, we have analyzed two overlapping interstitial deletions on human chromosome 16q by Southern blot analysis. One deletion, with breakpoints at 16q22.1 and 16q22.3, results in loss of the UVO locus. The second deletion, whose breakpoints are at 16q22.1 and 16q23.2, leads to loss of the CTRB locus. Therefore, UVO resides between both proximal deletion breakpoints within band 16q22.1, whereas CTRB is located between both distal breakpoints at 16q22.3 and 16q23.2.