Recombination hotspot in NF1 microdeletion patients.

Neurofibromatosis type 1 (NF1) patients that are heterozygous for an NF1 microdeletion are remarkable for an early age at onset and an excessive burden of dermal neurofibromas. Microdeletions are predominantly maternal in origin and arise by unequal crossover between misaligned NF1REP paralogous sequence blocks which flank the NF1 gene. We mapped and sequenced the breakpoints in several patients and designed primers within each paralog to specifically amplify a 3.4 kb deletion junction fragment. This assay amplified a deletion junction fragment from 25 of the 54 unrelated NF1 microdeletion patients screened. Sequence analysis demonstrated that each of the 25 recombination events occurred in a discrete 2 kb recombination hotspot within each of the flanking NF1REPs. Two recombination events were accompanied by apparent gene conversion. A search for recombination-prone motifs revealed a chi-like sequence; however, it is unknown whether this element stimulates recombination to occur at the hotspot. The deletion-junction assay will facilitate the prospective identification of patients with NF1 microdeletion at this hotspot for genotype-phenotype correlation studies and diagnostic evaluation.     

Extended runs of homozygosity at 17q11.2: an association with type‐2 NF1 deletions?

Large deletions in the NF1 gene region at 17q11.2 are caused by nonallelic homologous recombination (NAHR). The recurrent type‐2 NF1 deletions span 1.2 Mb, with breakpoints in the SUZ12 gene and SUZ12P. Type‐2 NF1 deletions occur preferentially during mitosis and are associated with somatic mosaicism. A panel of 16 type‐2 NF1 deletions was used as a model system in which to investigate whether extended homozygosity across 17q11.2 might be associated with somatic deletion. Using SNP arrays, a 3.2 Mb interval encompassing the NF1 deletion region was found to harbor runs of homozygosity (ROHs) in different human populations. However, ROHs ≥500 kb directly flanking the NF1 deletion region on both sides were not found to occur disproportionately in NF1 patients harboring type‐2 deletions compared to controls. Although low allelic diversity in 17q11.2 is unlikely to be a key factor in promoting NAHR‐mediated somatic type‐2 deletions, a specific ROH of 588 kb (roh1), located some 525 kb proximal to the deletion interval, was found to occur more frequently (P=0.012) in the type‐2 deletion patients compared with controls. We postulate that roh1 may act remotely, via an as yet unknown mechanism, to increase the frequency of somatic recombination between the distally duplicated SUZ12 sequences. Hum Mutat 30:1–10, 2010. © 2010 Wiley‐Liss, Inc.     

A novel third type of recurrent NF1 microdeletion mediated by nonallelic homologous recombination between LRRC37B‐containing low‐copy repeats in 17q11.2

Large microdeletions encompassing the neurofibromatosis type‐1 (NF1) gene and its flanking regions at 17q11.2 belong to the group of genomic disorders caused by aberrant recombination between segmental duplications. The most common NF1 microdeletions (type‐1) span 1.4‐Mb and have breakpoints located within NF1‐REPs A and C, low‐copy repeats (LCRs) containing LRRC37‐core duplicons. We have identified a novel type of recurrent NF1 deletion mediated by nonallelic homologous recombination (NAHR) between the highly homologous NF1‐REPs B and C. The breakpoints of these ～1.0‐Mb (“type‐3”) NF1 deletions were characterized at the DNA sequence level in three unrelated patients. Recombination regions, spanning 275, 180, and 109‐bp, respectively, were identified within the LRRC37B‐P paralogues of NF1‐REPs B and C, and were found to contain sequences capable of non‐B DNA formation. Both LCRs contain LRRC37‐core duplicons, abundant and highly dynamic sequences in the human genome. NAHR between LRRC37‐containing LCRs at 17q21.31 is known to have mediated the 970‐kb polymorphic inversions of the MAPT‐locus that occurred independently in different primate species, but also underlies the syndromes associated with recurrent 17q21.31 microdeletions and reciprocal microduplications. The novel NF1 microdeletions reported here provide further evidence for the unusually high recombinogenic potential of LRRC37‐containing LCRs in the human genome. Hum Mutat 31:742–751, 2010. © 2010 Wiley‐Liss, Inc.     

Absence of cutaneous neurofibromas in an NF1 patient with an atypical deletion partially overlapping the common 1.4 Mb microdeleted region

The majority of neurofibromatosis type 1 (NF1) microdeletions in 17q11.2 span approximately 1.4 Mb and have breakpoints that lie within the proximal and distal NF1-low copy repeats, termed NF1-REPs. Less frequent are patients with atypical deletions and non-recurring breakpoints. NF1 patients with gross deletions have been reported to manifest a more severe clinical phenotype than NF1 patients with intragenic mutations, and display early onset and extensive growth of neurofibromas. It has been suggested that the deletion of a neighboring gene or genes in addition to the NF1 gene may modify the expression of the disease, particularly with regard to the high burden of cutaneous neurofibromas. Thus, atypical deletions partially overlapping with the common 1.4 Mb microdeletion interval could prove useful in identifying possible genetic modifiers in the NF1 gene region whose haploinsufficiency might promote neurofibroma growth. Here we report a 20-year-old female who has an atypical deletion with a proximal breakpoint in NF1 intron 21 and a distal deletion breakpoint in the ACCN1 gene. The deletion spans 2.7 Mb and was mediated by an intrachromosomal non-homology-driven mechanism, for example, non-homologous end-joining (NHEJ). Remarkably, this patient did not exhibit cutaneous neurofibromas. However, genotype-phenotype comparisons in this and other previously reported patients with atypical deletions partially overlapping the commonly deleted 1.4 Mb interval do not identify a specific deleted region that is associated with increased neurofibroma growth.     

Identification of novel deletion breakpoints bordered by segmental duplications in the NF1 locus using high resolution array-CGH

Background

Segmental duplications flanking the neurofibromatosis type 1 (NF1) gene locus on 17q11 mediate most gene deletions in NF1 patients. However, the large size of the gene and the complexity of the locus architecture pose difficulties in deletion analysis. We report the construction and application of the first NF1 locus specific microarray, covering 2.24 Mb of 17q11, using a non‐redundant approach for array design. The average resolution of analysis for the array is ∼12 kb per measurement point with an increased average resolution of 6.4 kb for the NF1 gene.

Methods

We performed a comprehensive array‐CGH analysis of 161 NF1 derived samples and identified heterozygous deletions of various sizes in 39 cases. The typical deletion was identified in 26 cases, whereas 13 samples showed atypical deletion profiles.

Results

The size of the atypical deletions, contained within the segment covered by the array, ranged from 6 kb to 1.6 Mb and their breakpoints could be accurately determined. Moreover, 10 atypical deletions were observed to share a common breakpoint either on the proximal or distal end of the deletion. The deletions identified by array‐CGH were independently confirmed using multiplex ligation‐dependent probe amplification. Bioinformatic analysis of the entire locus identified 33 segmental duplications.

Conclusions

We show that at least one of these segmental duplications, which borders the proximal breakpoint located within the NF1 intron 1 in five atypical deletions, might represent a novel hot spot for deletions. Our array constitutes a novel and reliable tool offering significantly improved diagnostics for this common disorder.     

Novel rearrangement of chromosome band 22q11.2 causing 22q11 microdeletion syndrome-like phenotype and rhabdoid tumor of the kidney

The 22q11.2 microdeletion syndrome is the most frequent microdeletion syndrome in humans, yet its genetic basis is complex and is still not fully understood. Most patients harbor a 3-Mb deletion (typically deleted region [TDR]), but occasionally patients with atypical deletions, some of which do not overlap with each other and/or the TDR, have been described. Microduplication of the TDR leads to a phenotype similar, albeit not identical, to the deletion of this region. Here we present a child initially suspected of having 22q11 microdeletion syndrome, who in addition developed a fatal malignant rhabdoid tumor of the kidney. Detailed cytogenetic and molecular analyses revealed a complex de novo rearrangement of band q11 of the paternally derived chromosome 22. This aberration exhibited two novel features. First, a microduplication of the 22q11 TDR was associated with an atypical 22q11 microdeletion immediately telomeric of the duplicated region. Second, this deletion was considerably larger than previously reported atypical 22q11 deletions, spanning 2.8 Mb and extending beyond the SMARCB1/SNF5/INI1 tumor suppressor gene, whose second allele harbored a somatic frameshift-causing sequence alteration in the patient's tumor. Two nonallelic homologous recombination events between low-copy repeats (LCRs) could explain the emergence of this novel and complex mutation associated with the phenotype of 22q11 microdeletion syndrome.     

Familial neurofibromatosis 1 microdeletions: Cosegregation with distinct facial phenotype and early onset of cutaneous neurofibromata

A notable subset of the recent literature on the disorder neurofibromatosis type 1 (NF1) describes patients with NF1, facial anomalies, and other unusual findings. We describe a molecular re-evaluation of two such families reported previously by Kaplan and Rosenblatt [1985], who suggested that their NF1 manifestations, facial phenotype, and other findings could result from a disorder distinct from NF1. Submicroscopic deletions involving the NF1 gene were identified in both families by fluorescent in situ hybridization and analysis of somatic cell hybrids. Affected subjects of the first family were heterozygous for a microdeletion of approximately 2 Mb, which included the entire NF1 gene and flanking contiguous sequences. The family was remarkable for cosegregation of the NF1 microdeletion with facial abnormalities and a pattern of early onset of cutaneous neurofibromata upon transmission from an affected mother to her three affected children. The propositus of the second family carried a deletion that at the least involved NF1 exon 2 through intron 27, which is ≥ 200 kilobases in length. Because all persons in the family were deceased, the size of the deletion could not be determined precisely. Facial anomalies were observed in the propositus and his NF1-affected mother and sister. The data from these families support our hypothesis, which was initially based solely on sporadic deletion cases, that deletion of the entire NF1 gene, or in conjunction with deletion of unknown contiguous genes, causes the facial anomalies and early onset of neurofibromata observed in this subset of NF1 patients. In addition, other features observed in the persons in these families suggest that some NF1 microdeletion patients may be at increased risk for connective tissue abnormalities and/or neoplasms. Am. J. Med. Genet. 73:197–204, 1997. © 1997 Wiley-Liss, Inc.     

Deletion of VCX-A due to NAHR plays a major role in the occurrence of mental retardation in patients with X-linked ichthyosis

X-linked ichthyosis (XLI) is often associated with a recurrent microdeletion at Xp22.31 due to non-allelic homologous recombination between the CRI-S232 low-copy repeat regions flanking the STS gene. The clinical features of these patients may include mental retardation (MR) and the VCX-A gene has been proposed as the candidate MR gene. Analysis of DNA from four XLI patients with MR by array-comparative genomic hybridization (array-CGH) on a 150 kb resolution X chromosome-specific array revealed a 1.5 Mb interstitial microdeletion with breakpoints in the CRI-S232 repeat sequences, each of which harbors a VCX gene. We demonstrate that the recombination sites in all four cases are situated in the 1 kb repeat unit 2 region present at the 3' ends of the VCX-A and VCX-B genes thereby deleting VCX-A and VCX-B1 but not VCX-B and VCX-C. Array-CGH with DNA of an XLI patient with MR and an inherited t(X;Y)(p22.31;q11.2) showed an Xpter deletion of 8.0 Mb resulting in the deletion of all four VCX genes and duplication of both VCY homologs. These data confirm the role of VCX-A in the occurrence of MR in XLI patients. Moreover, we propose a VCX/Y teamwork-dependent mechanism for the incidence of mental impairment in XLI patients.     

High resolution deletion analysis of constitutional DNA from neurofibromatosis type 2 (NF2) patients using microarray-CGH

Neurofibromatosis type 2 (NF2) is an autosomal dominant disorder whose hallmark is bilateral vestibular schwannoma. It displays a pronounced clinical heterogeneity with mild to severe forms. The NF2 tumor suppressor (merlin/schwannomin) has been cloned and extensively analyzed for mutations in patients with different clinical variants of the disease. Correlation between the type of the NF2 gene mutation and the patient phenotype has been suggested to exist. However, several independent studies have shown that a fraction of NF2 patients with various phenotypes have constitutional deletions that partly or entirely remove one copy of the NF2 gene. The purpose of this study was to examine a 7 Mb interval in the vicinity of the NF2 gene in a large series of NF2 patients in order to determine the frequency and extent of deletions. A total of 116 NF2 patients were analyzed using high-resolution array-comparative genomic hybridization (CGH) on an array covering at least 90% of this region of 22q around the NF2 locus. Deletions, which remove one copy of the entire gene or are predicted to truncate the schwannomin protein, were detected in 8 severe, 10 moderate and 6 mild patients. This result does not support the correlation between the type of mutation affecting the NF2 gene and the disease phenotype. This work also demonstrates the general usefulness of the array-CGH methodology for rapid and comprehensive detection of small (down to 40 kb) heterozygous and/or homozygous deletions occurring in constitutional or tumor-derived DNA.     

Characterization of the nonallelic homologous recombination hotspot PRS3 associated with type-3 NF1 deletions

Nonallelic homologous recombination (NAHR) is the major mechanism underlying recurrent genomic rearrangements, including the large deletions at 17q11.2 that cause neurofibromatosis type 1 (NF1). Here, we identify a novel NAHR hotspot, responsible for type-3 NF1 deletions that span 1.0 Mb. Breakpoint clustering within this 1-kb hotspot, termed PRS3, was noted in 10 of 11 known type-3 NF1 deletions. PRS3 is located within the LRRC37B pseudogene of the NF1-REPb and NF1-REPc low-copy repeats. In contrast to other previously characterized NAHR hotspots, PRS3 has not developed on a preexisting allelic homologous recombination hotspot. Furthermore, the variation pattern of PRS3 and its flanking regions is unusual since only NF1-REPc (and not NF1-REPb) is characterized by a high single nucleotide polymorphism (SNP) frequency, suggestive of unidirectional sequence transfer via nonallelic homologous gene conversion (NAHGC). By contrast, the previously described intense NAHR hotspots within the CMT1A-REPs, and the PRS1 and PRS2 hotspots underlying type-1 NF1 deletions, experience frequent bidirectional sequence transfer. PRS3 within NF1-REPc was also found to be involved in NAHGC with the LRRC37B gene, the progenitor locus of the LRRC37B-P duplicons, as indicated by the presence of shared SNPs between these loci. PRS3 therefore represents a weak (and probably evolutionarily rather young) NAHR hotspot with unique properties.     

Somatic loss of wild type NF1 allele in neurofibromas: Comparison of NF1 microdeletion and non-microdeletion patients

Neurofibromatosis type I (NF1) is an autosomal dominant familial tumor syndrome characterized by the presence of multiple benign neurofibromas. In 95% of NF1 individuals, a mutation is found in the NF1 gene, and in 5% of the patients, the germline mutation consists of a microdeletion that includes the NF1 gene and several flanking genes. We studied the frequency of loss of heterozygosity (LOH) in the NF1 region as a mechanism of somatic NF1 inactivation in neurofibromas from NF1 patients with and without a microdeletion. There was a statistically significant difference between these two patient groups in the proportion of neurofibromas with LOH. None of the 40 neurofibromas from six different NF1 microdeletion patients showed LOH, whereas LOH was observed in 6/28 neurofibromas from five patients with an intragenic NF1 mutation (P = 0.0034, Fisher's exact). LOH of the NF1 microdeletion region in NF1 microdeletion patients would de facto lead to a nullizygous state of the genes located in the deletion region and might be lethal. The mechanisms leading to LOH were further analyzed in six neurofibromas. In two out of six neurofibromas, a chromosomal microdeletion was found; in three, a mitotic recombination was responsible for the observed LOH; and in one, a chromosome loss with reduplication was present. These data show an important difference in the mechanisms of second hit formation in the 2 NF1 patient groups. We conclude that NF1 is a familial tumor syndrome in which the type of germline mutation influences the type of second hit in the tumors.     

Genomic context of paralogous recombination hotspots mediating recurrent NF1 region microdeletion

Recombination between paralogs that flank the NF1 gene at 17q11.2 typically results in a 1.5-Mb microdeletion that includes NF1 and at least 13 other genes. We show that the principal sequences responsible are two 51-kb blocks with 97.5% sequence identity (NF1REP-P1-51 and NF1REP-M-51). These blocks belong to a complex group of paralogs with three components on 17q11.2 and another on 19p13.13. Breakpoint sequencing of deleted chromosomes from multiple patients revealed two paralogous recombination hot spots within the 51-kb blocks. Lack of sequence similarity between these sites failed to suggest or corroborate any putative cis-acting recombinogenic motifs. However, the NF1 REPs showed relatively high alignment mismatch between recombining paralogs, and we note that the NF1REP hot spots were regions of good alignment bordered by relatively large alignment gaps. Statistical tests for gene conversion detected a single significant tract of perfect match between the NF1REPs that was 700 bp long and coincided with PRS2, the predominant recombination hot spot. Tracts of perfect match occurring by chance may contribute to breakpoint localization, but our result suggests that perfect tracts at recombination hot spots may be a result of gene conversion at sites at which preferential pairing occurs for other, as-yet-unknown reasons.     

Spectrum of single- and multiexon NF1 copy number changes in a cohort of 1,100 unselected NF1 patients

Neurofibromatosis type 1 (NF1), the most common tumor-predisposing disorder in humans, is caused by defects in the NF1 tumor-suppressor gene. Comprehensive mutation analysis applying RNA-based techniques complemented with FISH analysis achieves mutation detection rates of approximately 95% in NF1 patients. The majority of mutations are minor lesions, and approximately 5% are total gene deletions. We found 13 single- and/or multiexon deletions/duplications out of 1,050 detected mutations using our RNA-based approach in a cohort of 1,100 NF1 patients and confirmed these changes using multiplex ligation-dependent probe amplification (MLPA). With MLPA, we found another 12 novel multiexon deletion/duplications in 55 NF1 patients for whom analysis with multiple assays had not revealed a NF1 mutation, including 50 previously analyzed comprehensively. The extent of the 22 deletions and 3 duplications varied greatly, and there was no clustering of breakpoints. We also evaluated the sensitivity of MLPA in identifying deletions in a mosaic state. Furthermore, we tested whether the MLPA P122 NF1 area assay could distinguish between type I deletions, with breakpoints in low-copy repeats (NF1-LCRs), and type II deletions, caused by aberrant recombination between the JJAZ gene and its pseudogene. Our study showed that intragenic deletions and/or duplications represent only approximately 2% of all NF1 mutations. Although MLPA did not substantially increase the mutation detection rate in NF1 patients, it was a useful first step in a comprehensive mutation analysis scheme to quickly pinpoint patients with single- or multiexon deletions/duplications as well as patients with a total gene deletion who will not need full sequencing of the complete coding region.     

Unequal interchromosomal rearrangements may result in elastin gene deletions causing the Williams-Beuren syndrome

Williams-Beuren syndrome (WBS) is generally the consequence of an interstitial microdeletion at 7q11.23, which includes the elastin gene, thus causing hemizygosity at the elastin gene locus. The origin of the deletion has been reported by many authors to be maternal in approximately 60% and paternal in 40% of cases. Segregation analysis of grandparental markers flanking the microdeletion region in WBS patients and their parents indicated that in the majority of cases a recombination between grandmaternal and grandpaternal chromosomes 7 at the site of the deletion had occurred during meiosis in the parent from whom the deleted chromosome stemmed. Thus, the majority of deletions were considered a consequence of unequal crossing-over between homologous chromosomes 7 (interchromosomal rearrangement) while in the remaining cases an intrachromosomal recombination (between the chromatids of one chromosome 7) may have occurred. These results suggest that the majority of interstitial deletions of the elastin gene region occur during meiosis, due to unbalanced recombination while a minority could occur before or during meiosis probably due to intrachromosomal rearrangements. The recurrence risk of the interchromosomal rearrangements for sibs of a proband with non-affected parents must be negligible, which fits well with the observation of sporadic occurrence of almost all cases of WBS.      

The heterogeneous nature of germline mutations in NF1 patients with malignant peripheral serve sheath tumours (MPNSTs)

Malignant peripheral nerve sheath tumours (MPNSTs) are a major cause of mortality in patients with neurofibromatosis 1 (NF1). We have analysed lymphocyte DNA samples from 30 NF1 patients with MPNSTs to determine their underlying constitutional NF1 gene mutations. Mutations were detected in 27/30 (90%) of these patients. NF1 mutations identified included nonsense, missense, frameshift, splice site mutation and single or multi-exonic deletions and with no obvious clustering of the mutations across the gene. Fourteen of the mutations represent novel gene changes. There did not appear to be any relationship between the mutation type and the level of clinical severity observed. Of the 20 patients with high grade MPNSTs, seven patients had small (<20 bp) and multi-exonic deletions and three had small insertions (<20 bp). Several studies have suggested that NF1 patients with a constitutional 1.5 Mb deletion of the NF1 gene have an increased risk of developing malignant peripheral nerve sheath tumours (MPNSTs). None of our patients had a 1.5 Mb deletion. Larger prospective studies are needed to ascertain whether there is a different spectrum of NF1 mutations in NF1 patients with high grade compared to low grade MPNSTs and of patients with the 1.5Mb deletion, in order to determine the true frequency of MPNST in this sub-group of NF1 patients.     

Molecular studies in 20 submicroscopic neurofibromatosis type 1 gene deletions.

Neurofibromatosis type 1 (NF1) is a common autosomal dominant disorder characterized by a marked variability in expression. A more severe phenotype is frequently observed in the group of patients carrying a large NF1 deletion. To study the extent of the microdeletion in these NF1 patients, we generated a partial physical map of the NF1 flanking region. We describe seven PACs and three new polymorphic dinucleotide repeats located outside the NF1 gene and analyzed 20 unrelated individuals with an NF1 microdeletion in a collaborative study. We detected one individual with a substantially smaller deletion including only the NF1 gene and its three embedded genes. In the other 19 patients, the deletion extended at least 1 Mb. The parental origin of the deletion was determined in 15 individuals and was maternal in 13 and paternal in two cases. The new molecular tools described here can be used to unequivocally diagnose a possible extragenic extension of an NF1 deletion.     

Intrachromosomal mitotic nonallelic homologous recombination is the major molecular mechanism underlying type‐2 NF1 deletions

Nonallelic homologous recombination (NAHR) is responsible for the recurrent rearrangements that give rise to genomic disorders. Although meiotic NAHR has been investigated in multiple contexts, much less is known about mitotic NAHR despite its importance for tumorigenesis. Because type‐2 NF1 microdeletions frequently result from mitotic NAHR, they represent a good model in which to investigate the features of mitotic NAHR. We have used microsatellite analysis and SNP arrays to distinguish between the various alternative recombinational possibilities, thereby ascertaining that 17 of 18 type‐2 NF1 deletions, with breakpoints in the SUZ12 gene and its highly homologous pseudogene, originated via intrachromosomal recombination. This high proportion of intrachromosomal NAHR causing somatic type‐2 NF1 deletions contrasts with the interchromosomal origin of germline type‐1 NF1 microdeletions, whose breakpoints are located within the NF1‐REPs (low‐copy repeats located adjacent to the SUZ12 sequences). Further, meiotic NAHR causing type‐1 NF1 deletions occurs within recombination hotspots characterized by high GC‐content and DNA duplex stability, whereas the type‐2 breakpoints associated with the mitotic NAHR events investigated here do not cluster within hotspots and are located within regions of significantly lower GC‐content and DNA stability. Our findings therefore point to fundamental mechanistic differences between the determinants of mitotic and meiotic NAHR. Hum Mutat 31:1163–1173, 2010. © 2010 Wiley‐Liss, Inc.     

Two regions of homozygous deletion clusters at chromosome band 9p21 in human lung cancer

We examined 149 lung cancer cell lines for homozygous deletions using 24 DNA markers, which were mapped and ordered in chromosome band 9p21, to define the target regions for 9p21 deletions in human lung cancer. Homozygous deletions were detected in 39 (26%) cell lines and clustered at 2 independent regions. One was the region containing the p16/CDKN2A tumor suppressor gene, and this region was deleted in 32 (21%) cell lines. The other was the region containing D9S171, which is the locus approximately 3 Mb proximal to the CDKN2A locus. This region, designated as the D9S171 region, was deleted in 18 (12%) cell lines. Seven of the 18 cell lines had identical minimum deletions of a 17,036 bp sequence located 20 kb distal to the D9S171 locus. However, such a deletion was also observed in the corresponding B-lymphoblastoid cell line from 1 of the 7 cell lines and in 5 (16%) of 32 noncancerous tissues, suggesting that the deletion was a genetic polymorphism. By considering this polymorphism, 11 (7%) cell lines still had deletions at the D9S171 region. Two NSCLC cell lines showed deletions at the D9S171 region and retentions of the CDKN2A locus. Furthermore, an NSCLC cell line showed discontinuous deletions including either the CDKN2A or D9S171 locus. Therefore, the region surrounding the D9S171 locus was defined as another target region for the 9p21 deletions. It is possible that unknown tumor suppressor gene(s) are present in this chromosomal region. Genes Chromosomes Cancer 27:308-318, 2000.     

Case series: 2q33.1 microdeletion syndrome--further delineation of the phenotype

Recurrent deletions of 2q32q33 have recently been reported as a new microdeletion syndrome, clinical features of which include significant learning difficulties, growth retardation, dysmorphic features, thin and sparse hair, feeding difficulties, and cleft or high palate. Haploinsufficiency of one gene within the deleted region, SATB2, has been suggested to be responsible for most of the features of the syndrome. This article describes seven previously unreported patients with deletions at 2q33.1, all partially overlapping the previously described critical region for the 2q33.1 microdeletion syndrome. The deletions ranged in size from 35 kb to 10.4 Mb, with the smallest deletion entirely within the SATB2 gene. Patients demonstrated significant developmental delay and challenging behaviour, a particular behavioural phenotype that seems to be emerging with more reported patients with this condition. One patient in this cohort has a deletion entirely within SATB2 and has a cleft palate, whereas several patients with larger deletions have a high arched palate. In addition, one other patient has significant orthopaedic problems with ligamentous laxity. Interestingly, this patient has a deletion that lies just distal to SATB2. The orthopaedic problems have not been reported previously and are possibly an additional feature of this syndrome. Overall, this report provides further evidence that the SATB2 gene is the critical gene in this microdeletion syndrome. In addition, because the individuals in this study range in age from 3-19 years, these patients will help define the natural progression of the phenotype in patients with this microdeletion.     

Genomic architecture at the Incontinentia Pigmenti locus favours de novo pathological alleles through different mechanisms

IKBKG/NEMO gene mutations cause an X-linked, dominant neuroectodermal disorder named Incontinentia Pigmenti (IP). Located at Xq28, IKBKG/NEMO has a unique genomic organization, as it is part of a segmental duplication or low copy repeat (LCR1-LCR2, >99% identical) containing the gene and its pseudogene copy (IKBKGP). In the opposite direction and outside LCR1, IKBKG/NEMO partially overlaps G6PD, whose mutations cause a common X-linked human enzymopathy. The two LCRs in the IKBKG/NEMO locus are able to recombine through non-allelic homologous recombination producing either a pathological recurrent exon 4-10 IKBKG/NEMO deletion (IKBKGdel) or benign small copy number variations. We here report that the local high frequency of micro/macro-homologies, tandem repeats and repeat/repetitive sequences make the IKBKG/NEMO locus susceptible to novel pathological IP alterations. Indeed, we describe the first two independent instances of inter-locus gene conversion, occurring between the two LCRs, that copies the IKBKGP pseudogene variants into the functional IKBKG/NEMO, causing the de novo occurrence of p.Glu390ArgfsX61 and the IKBKGdel mutations, respectively. Subsequently, by investigating a group of 20 molecularly unsolved IP subjects using a high-density quantitative polymerase chain reaction assay, we have identified seven unique de novo deletions varying from 4.8 to ～115 kb in length. Each deletion removes partially or completely both IKBKG/NEMO and the overlapping G6PD, thereby uncovering the first deletions disrupting the G6PD gene which were found in patients with IP. Interestingly, the 4.8 kb deletion removes the conserved bidirectional promoterB, shared by the two overlapping IKBKG/NEMO and G6PD genes, leaving intact the alternative IKBKG/NEMO unidirectional promoterA. This promoter, although active in the keratinocytes of the basal dermal layer, is down-regulated during late differentiation. Genomic analysis at the breakpoint sites indicated that other mutational forces, such as non-homologous end joining, Alu-Alu-mediated recombination and replication-based events, might enhance the vulnerability of the IP locus to produce de novo pathological IP alleles.