Targeted genomic microarray analysis for identification of chromosome abnormalities in 1500 consecutive clinical cases

OBJECTIVE

To assess the yield of array-based comparative genomic hybridization.

STUDY DESIGN

The results of array comparative genomic hybridization were collected on 1500 consecutive clinical cases sent to our laboratory for a variety of developmental problems. Confirmation fluorescence in situ hybridization of metaphase or interphase cells, depending on the aberration, was performed.

RESULTS

Of the 1500 cases, 134 (8.9%) showed an abnormality: 36 (2.4%) showed polymorphisms or familial variants, 14 (0.9%) showed alterations of unknown clinical significance, and 84 (5.6%) showed clinically relevant genomic alterations. These included subtelomeric deletions and unbalanced rearrangements, microdeletions and reciprocal duplications, rare abnormalities, and low-level trisomy mosaicism.

CONCLUSIONS

A targeted array detects a substantial proportion of abnormalities even in those patients who have already had extensive cytogenetic and/or fluorescence in situ hybridization testing. This study, although not a controlled ascertainment of subjects with specific selection criteria, accurately reflects the reality of clinical cytogenetic practice and provides an estimate of the cytogenetic abnormalities that can be identified with a targeted microarray in a diagnostic laboratory. Microarray analysis likely doubles the current yield of abnormal results detected by conventional cytogenetic analysis.

Evidence for involvement of TRE-2 (USP6) oncogene, low-copy repeat and acrocentric heterochromatin in two families with chromosomal translocations

We report clinical findings and molecular cytogenetic analyses for two patients with translocations [t(14;17)(p12;p12) and t(15;17)(p12;p13.2)], in which the chromosome 17 breakpoints map at a large low-copy repeat (LCR) and a breakage-prone TRE-2 (USP6) oncogene, respectively. In family 1, a 6-year-old girl and her 5-year-old brother were diagnosed with mental retardation, short stature, dysmorphic features, and Charcot-Marie-Tooth disease type 1A (CMT1A). G-banding chromosome analysis showed a der(14)t(14;17)(p12;p12) in both siblings, inherited from their father, a carrier of the balanced translocation. Chromosome microarray and FISH analyses revealed that the PMP22 gene was duplicated. The chromosome 17 breakpoint was mapped within an approximately 383 kb LCR17pA that is known to also be the site of several breakpoints of different chromosome aberrations including the evolutionary translocation t(4;19) in Gorilla gorilla. In family two, a patient with developmental delay, subtle dysmorphic features, ventricular enlargement with decreased periventricular white matter, mild findings of bilateral perisylvian polymicrogyria and a very small anterior commissure, a cryptic duplication including the Miller-Dieker syndrome region was identified by chromosome microarray analysis. The chromosome 17 breakpoint was mapped by FISH at the TRE-2 oncogene. Both partner chromosome breakpoints were mapped on the short arm acrocentric heterochromatin within or distal to the rRNA cluster, distal to the region commonly rearranged in Robertsonian translocations. We propose that TRE-2 together with LCR17pA, located approximately 10 Mb apart, also generated the evolutionary gorilla translocation t(4;19). Our results support previous observations that the USP6 oncogene, LCRs, and repetitive DNA sequences play a significant role in the origin of constitutional chromosome aberrations and primate genome evolution.

American College of Medical Genetics guideline on the cytogenetic evaluation of the individual with developmental delay or mental retardation

The following are the recommendations of the American College of Medical Genetics (ACMG) Professional Practice and Guidelines Committee, which was convened to assist health care professionals in making decisions regarding cytogenetic diagnostic testing and counseling for mental retardation (MR) and developmental delay (DD). This document reviews available evidence concerning the value of conventional and molecular cytogenetic testing for the identification of chromosomal anomalies that play a role in the etiology of MR/DD, and, based on this evidence, specific recommendations for each method of testing are provided.

Microarray detection of a de novo der(X)t(X;11)(q28;p13) in a girl with premature ovarian failure and features of Beckwith-Wiedemann syndrome

We report an 18-year-old girl with premature ovarian failure (POF), tall stature, and urinary incontinence. Chromosome studies including array comparative genomic hybridization showed that she was the carrier of an unbalanced de novo translocation between the X chromosome and chromosome 11, resulting in partial monosomy Xq and partial trisomy 11p. Microsatellite analysis demonstrated that the patient had paternal duplication of 11p13p15.5, which contributed to some of her features consistent with Beckwith-Wiedemann syndrome (BWS). The combined phenotype of BWS and POF suggests that the translocated portion of 11p remains active.

Characterization of a complex rearrangement with interstitial deletions and inversion on human chromosome 1

Deletion of the distal band of the short arm of chromosome 1 (monosomy 1p36) is the most common terminal deletion syndrome, occurring in about 1 in 5000 newborns. Of the 121 subjects ascertained for our study to date, 12 (9.9%) have interstitial deletions, three of which are complex rearrangements showing more than one deletion. Herein we report the characterization of a complex rearrangement with two interstitial deletions in the same chromosome 1p36.33-p36.23. We narrowed and analyzed the breakpoints and junctions between the sequence fragments involved in the rearrangement to determine the structure of this deleted chromosome 1. The analyses of the DNA sequence at the junctions showed additional complexity: an inversion and a third de-novo interstitial deletion. We reconstructed this complex rearrangement of 1p36 to understand the mechanism of formation. Analysis of the breakpoint junctions revealed that three of the four breakpoints each interrupted a gene. Alignments of the junctions showed the lack of any sequence similarity between the breakpoints, suggesting the involvement of non-homologous end joining (NHEJ) in the ligation of broken ends following deletion. The identification of translin recognition sites in the breakpoints suggests translin involvement in the repair of broken chromosomes. This report is one of the first to examine constitutional chromosomal rearrangements at the DNA sequence level. The discovery of cryptic events in seemingly simple chromosome rearrangements may provide the basis for proposing mechanisms of formation.

Detecting sex chromosome anomalies and common triploidies in products of conception by array-based comparative genomic hybridization

OBJECTIVES

In recent years, array-based comparative genomic hybridization (array CGH) has moved to the forefront of molecular cytogenetics with its ability to rapidly characterize chromosome abnormalities at resolutions much higher than routine chromosome banding. However, array CGH, like all CGH procedures, has heretofore been deemed unable to detect ploidy, a major cause of fetal demise and spontaneous miscarriage.

METHOD

We recently developed a CGH microarray that is designed for detecting aneuploidy and unbalanced chromosome rearrangements. Here, we introduce the use of a Klinefelter male cell line (47,XXY) as a control for array CGH analyses on products of conception (POCs).

RESULTS

This approach facilitates the detection of common trisomies and monosomies of the sex chromosomes by reducing the analysis to the identification of single copy gains or losses. Furthermore, in a blinded study, careful interpretation of the microarray results with particular attention to the sex chromosome ratios between the patient sample and the control allowed for the detection of some common triploidies.

CONCLUSION

These results suggest that using a chromosomally abnormal cell line in array CGH analysis can be applied to other CGH platforms and that array CGH, when properly performed and analyzed, is a powerful tool that can detect most chromosomal abnormalities observed in a clinical setting including some polyploidies.

Comparative Genomic Hybridization by Microarray for the Detection of Cytogenetic Imbalance

Chromosomal abnormalities often result in the improper dosage of genes in a particular chromosome or chromosome segment, which may cause specific and complex clinical phenotypes. Comparative genomic hybridization by microarray (array CGH) is a high-throughput and high-resolution method for the detection of microscopic and submicroscopic chromosome abnormalities, some of which may not be detectable by conventional cytogenetic techniques. In addition, with the human genome sequenced and publicly available, array CGH allows for the direct correlation between chromosomal anomalies and genomic sequence. Properly constructed, microarrays have the potential to be a valuable tool for the detection of chromosomal abnormalities in cancer and genetic disease.

Risk estimates for uniparental disomy following prenatal detection of a nonhomologous Robertsonian translocation

Carriers of nonhomologous Robertsonian translocations (ROB) are at risk for having offspring with uniparental disomy (UPD). Although risk estimates have been calculated in several independent studies, the estimates have not been optimal because most studies are not of sufficient size and UPD events are rare. However, these collective data have provided the opportunity to derive an overall risk estimate for UPD in the fetus after the prenatal identification of a ROB.

Allele-specific methylation of a functional CTCF binding site upstream of MEG3 in the human imprinted domain of 14q32

The gene MEG3 is located in the imprinted human chromosomal region on 14q32. Imprinting of a structurally homologous region IGF2/H19 on 11p15 is mediated through cytosine methylation-controlled binding of the protein CTCF to target sites upstream of H19. We identified five new CTCF binding sites around the promoter of MEG3. Using an electrophoretic mobility shift assay, we showed that these sites bind CTCF in vitro. Using one of these sites, chromatin immunoprecipitation (ChIP) analysis confirmed CTCF binding in-vivo, and differential allele-specific methylation was demonstrated in seven individuals with either maternal or paternal uniparental disomy 14 (UPD14). The site was unmethylated on the maternally inherited chromosomes 14 and methylated on the paternally inherited chromosomes 14, suggesting parent-specific methylation of sequences upstream of MEG3. We speculate that this CTCF-binding region may provide a mechanism for the transcriptional regulation of MEG3 and DLK1.

Construction of a natural panel of 11p11.2 deletions and further delineation of the critical region involved in Potocki-Shaffer syndrome

Potocki-Shaffer syndrome (PSS) is a contiguous gene deletion syndrome that results from haploinsufficiency of at least two genes within the short arm of chromosome 11[del(11)(p11.2p12)]. The clinical features of PSS can include developmental delay, mental retardation, multiple exostoses, parietal foramina, enlarged anterior fontanel, minor craniofacial anomalies, ophthalmologic anomalies, and genital abnormalities in males. We constructed a natural panel of 11p11.2-p13 deletions using cell lines from 10 affected individuals, fluorescence in situ hybridization (FISH), microsatellite analyses, and array-based comparative genomic hybridization (array CGH). We then compared the deletion sizes and clinical features between affected individuals. The full spectrum of PSS manifests when deletions are at least 2.1 Mb in size, spanning from D11S1393 to D11S1385/D11S1319 (44.6-46.7 Mb from the 11p terminus) and encompassing EXT2, responsible for multiple exostoses, and ALX4, causing parietal foramina. Yet one subject with parietal foramina whose deletion does not include ALX4 indicates that ALX4 in this subject may be rendered functionally haploinsufficient by a position effect. Based on comparative deletion mapping of eight individuals with the full PSS syndrome including mental retardation and two PSS families with no mental retardation, at least one gene related to mental retardation is likely located between D11S554 and D11S1385/D11S1319, 45.6-46.7 Mb from the 11p terminus.

Interstitial deletion 11(p11.12p11.2) and analphoid marker formation results in inherited Potocki-Shaffer syndrome

We report a family with inherited Potocki-Shaffer syndrome. The phenotypically normal mother has an interstitial deletion of 11(p11.12p11.2) with neocentric marker chromosome formation. The marker chromosome contains the deleted material on 11p11.2 and is likely a ring. The patient inherited a maternal deleted chromosome 11 but not the marker chromosome, thus resulting in an unbalanced karyotype along with the phenotype of Potocki-Shaffer syndrome. The deleted region in our case-11p11.12p11.2-is a newly reported site of constitutional neocentromere formation. This is also the first report describing deletion of 11p11.12-p11.2 and neocentromere formation resulting in inherited Potocki-Shaffer syndrome.

Use of targeted array-based CGH for the clinical diagnosis of chromosomal imbalance: is less more?

Chromosome analysis is an important component to the diagnosis of congenital anomalies, developmental delay, and mental retardation. Routine chromosome analysis identifies aneuploidy and structural rearrangements greater than 5 Mb but cannot identify abnormalities of the telomeric regions or microdeletions reliably. Molecular cytogenetic techniques were developed to overcome these limitations. High-resolution comparative genomic hybridization (CGH)-based microarrays (array CGH) were developed to increase the resolution of chromosomal studies and to provide a comprehensive assay by using large-insert clones as the target for analysis. We constructed a microarray for the clinical diagnosis of medically significant and relatively common chromosomal alterations. Nine hundred six bacterial artificial chromosome (BAC) clones were chosen, the chromosomal locations of which were confirmed by fluorescence in situ hybridization (FISH). FISH-testing showed that 7% of the clones were mismapped based on map locations obtained from two publicly available databases (58 mapped to the wrong chromosome and three mapped to a different locus on the same chromosome), 16% cross-hybridized to other chromosomes, and 12% did not hybridize or showed poor hybridization signals under uniform FISH conditions. Thus, from a total of 906 BAC clones that were evaluated, only 589 (65%) were deemed adequate for arraying on this clinical device. The performance of this array was tested in a set of blinded experiments on a cohort of phenotypically normal individuals and on individuals with known chromosome abnormalities. The array identified deletion/duplication polymorphisms not seen by FISH in the phenotypically normal individuals and detected single copy dosage differences in all of the cases with known chromosomal abnormalities. All abnormalities detected by the array were confirmed by FISH with BACs from the appropriate loci. Our data demonstrate that the rigorous assessment of BACs and their use in array CGH is especially important when the microarray is used for clinical diagnosis. In addition, this study illustrates that when constructed carefully with proper attention to the quality of the BACs that are arrayed, array CGH is an effective and efficient tool for delineating chromosomal aberrations and an important adjunct to FISH and conventional cytogenetics.

Partial trisomy of chromosome 10(q22-q24) due to maternal insertional translocation (15;10)

Interchromosomal insertional translocations are rare chromosome rearrangements with an incidence of about 1:80,000 live births. We report on the clinical and cytogenetic findings of a newborn baby with partial trisomy 10q22-10q24 due to a maternal insertional translocation 15;10. Partial trisomy of the long arm of chromosome 10 is a distinctive chromosome aberration characterized by prenatal-onset growth retardation and craniofacial, skeletal, and other somatic anomalies. Most cases are unbalanced products from reciprocal chromosome translocations, and insertional translocations are rarely involved. The proband was initially referred because of severe intrauterine growth retardation, and fluorescence in situ hybridization (FISH) using painting probes confirmed the maternal balanced (15;10) insertion.

Microduplication and triplication of 22q11.2: a highly variable syndrome

22q11.2 microduplications of a 3-Mb region surrounded by low-copy repeats should be, theoretically, as frequent as the deletions of this region; however, few microduplications have been reported. We show that the phenotype of these patients with microduplications is extremely diverse, ranging from normal to behavioral abnormalities to multiple defects, only some of which are reminiscent of the 22q11.2 deletion syndrome. This diversity will make ascertainment difficult and will necessitate a rapid-screening method. We demonstrate the utility of four different screening methods. Although all the screening techniques give unique information, the efficiency of real-time polymerase chain reaction allowed the discovery of two 22q11.2 microduplications in a series of 275 females who tested negative for fragile X syndrome, thus widening the phenotypic diversity. Ascertainment of the fragile X-negative cohort was twice that of the cohort screened for the 22q11.2 deletion. We also report the first patient with a 22q11.2 triplication and show that this patient's mother carries a 22q11.2 microduplication. We strongly recommend that other family members of patients with 22q11.2 microduplications also be tested, since we found several phenotypically normal parents who were carriers of the chromosomal abnormality.

Acute lymphoblastic leukemia in a patient with Greig cephalopolysyndactyly and interstitial deletion of chromosome 7 del(7)(p11.2 p14) involving the GLI3 and ZNFN1A1 genes

Greig cephalopolysyndactyly (GCPS; OMIM 175700) is an autosomal dominant condition caused by mutations of the gene GLI3, located on 7p13. To date, several cases of deletions and/or translocations involving this locus have been reported in patients with GCPS. GLI3 is a transcription factor from the GLI-Kruppel gene family that has been implicated in three distinct entities: GCPS, Pallister-Hall syndrome, and postaxial polydactyly type A. The zinc finger protein, subfamily 1, member 1 gene (ZNFN1A1; OMIM 603023), on 7p12, codes for a lymphoid-restricted zinc finger transcription factor, ZNFN1A1, also called IKAROS, that regulates lymphocyte differentiation and has been associated with the development of childhood leukemia. We present the case of a 9-year-old Latin-American boy who was referred for stem cell transplantation because of recurrent acute lymphoblastic leukemia (ALL). On evaluation, he was found to have dysmorphic features consistent with GCPS, including a prominent forehead, down-slanting palpebral fissures, 1-2-3 toe syndactyly, broad thumbs and first toes, and mild developmental delay. He had developed ALL at 5 years of age. Chromosome analysis of bone marrow and fibroblastic cells showed an interstitial deletion of chromosome arm 7p, del(7)(p11.2p14), in 74% and 44% of the cells, respectively. We performed FISH analysis with a BAC clone containing the ZNFN1A1 gene and demonstrated that it is contained in the deleted segment. To our knowledge, this is the first report of a patient with GCPS and leukemia. We hypothesize that constitutional deletion of the ZNFN1A1 gene in this patient may have resulted in an increased risk of lymphoid malignancy.

A mixed epigenetic/genetic model for oligogenic inheritance of autism with a limited role for UBE3A

The genetic contribution to autism is often attributed to the combined effects of many loci (ten or more). This conclusion is based in part on the much lower concordance for dizygotic (DZ) than for monozygotic (MZ) twins, and is consistent with the failure to find strong evidence for linkage in genome-wide studies. We propose that the twin data are compatible with oligogenic inheritance combined with a major, genetic or epigenetic, de novo component to the etiology. Based on evidence that maternal but not paternal duplications of chromosome 15q cause autism, we attempted to test the hypothesis that autism involves oligogenic inheritance (two or more loci) and that the Angelman gene (UBE3A), which encodes the E6-AP ubiquitin ligase, is one of the contributing genes. A search for epigenetic abnormalities led to the discovery of a tissue-specific differentially methylated region (DMR) downstream of the UBE3A coding exons, but the region was not abnormal in autism lymphoblasts or brain samples. Based on evidence for allele sharing in 15q among sib-pairs, abnormal DNA methylation at the 5'-CpG island of UBE3A in one of 17 autism brains, and decreased E6-AP protein in some autism brains, we propose a mixed epigenetic and genetic model for autism with both de novo and inherited contributions. The role of UBE3A may be quantitatively modest, but interacting proteins such as those ubiquitinated by UBE3A may be candidates for a larger role in an oligogenic model. A mixed epigenetic and genetic and mixed de novo and inherited (MEGDI) model could be relevant to other "complex disease traits".

ATR-16 due to a de novo complex rearrangement of chromosome 16

We describe a child with ATR-16 [alpha-thalassemia (thal)/mental retardation], who was referred for genetic evaluation because of minor anomalies and developmental delay. Cytogenetic analysis demonstrated a de novo complex rearrangement of chromosome 16. Fluorescence in situ hybridization (FISH) analysis, using chromosome 16 subtelomeric probes, showed that this patient had a deletion of the distal short arm of chromosome 16 that contains the alpha-globin genes and a duplication of 16q. Analysis of the alpha-globin locus by Southern blot showed a half normal dose of the alpha-globin gene. Microsatellite marker studies revealed that the duplicated 16q region was maternal in origin. Hematological studies revealed anemia, hypochromia and occasional cells with Hb H inclusion bodies. A hematological screening for alpha-thal should be considered in patients with mild developmental delay and a suggestive phenotype of ATR-16 with microcytic hypochromic anemia and normal iron status. The stellate pattern of the iris, a new finding in our patient, may contribute to a better clinical delineation of both syndromes, ATR-16 and/or duplication of 16qter.

Delineation of mechanisms and regions of dosage imbalance in complex rearrangements of 1p36 leads to a putative gene for regulation of cranial suture closure

Structural chromosome abnormalities have aided in gene identification for over three decades. Delineation of the deletion sizes and rearrangements allows for phenotype/genotype correlations and ultimately assists in gene identification. In this report, we have delineated the precise rearrangements in four subjects with deletions, duplications, and/or triplications of 1p36 and compared the regions of imbalance to two cases recently published. Fluorescence in situ hybridization (FISH) analysis revealed the size, order, and orientation of the duplicated/triplicated segments in each subject. We propose a premeiotic model for the formation of these complex rearrangements in the four newly ascertained subjects, whereby a deleted chromosome 1 undergoes a combination of multiple breakage-fusion-bridge (BFB) cycles and inversions to produce a chromosome arm with a complex rearrangement of deleted, duplicated and triplicated segments. In addition, comparing the six subjects' rearrangements revealed a region of overlap that when triplicated is associated with craniosynostosis and when deleted is associated with large, late-closing anterior fontanels. Within this region are the MMP23A and -B genes. We show MMP23 gene expression at the cranial sutures and we propose that haploinsufficiency results in large, late-closing anterior fontanels and overexpression results in craniosynostosis. These data emphasize the important role of cytogenetics in investigating and uncovering the etiologies of human genetic disease, particularly cytogenetic imbalances that reveal potentially dosage-sensitive genes.

A cytogeneticist's perspective on genomic microarrays

The identification of cytogenetic imbalance is an important component of clinical genetics. About 1 in 154 newborns has a chromosome abnormality. Conventional cytogenetic analysis has enabled the identification of microscopic alterations of the chromosomes. The development of fluorescence in situ hybridization (FISH) and other molecular methodologies has made possible the identification of submicroscopic aberrations. An additional development was comparative genomic hybridization (CGH), a method that directly compares two genomes for DNA copy differences. As first developed, the substrate for CGH analysis is normal metaphase chromosomes. Recently, CGH has been applied to microarrays (array CGH) constructed from large insert clones to identify chromosome imbalance. Array CGH has many advantages over conventional cytogenetic and molecular cytogenetic techniques. Array CGH can be comprehensive (genome-wide), high resolution, amenable to automation, rapid, and sensitive. We anticipate that array CGH will be employed in the clinical cytogenetics laboratory in the near future and will lead to the identification of the chromosomal basis of new syndromes and existing genetic conditions.

Trisomy 14 mosaicism: a case report and review of the literature

Trisomy 14 mosaicism is a rare chromosomal abnormality with distinct and recognizable clinical features. We describe two previously unreported abnormalities in this condition and delineate physical and psychomotor features and concerns for medical management. Trisomy 14 mosaicism should be suspected in individuals who have the features described herein, thus prompting cytogenetic evaluation of blood, and possibly other tissues for diagnosis.

Shuffling of genes within low-copy repeats on 22q11 (LCR22) by Alu-mediated recombination events during evolution

Low-copy repeats, or segmental duplications, are highly dynamic regions in the genome. The low-copy repeats on chromosome 22q11.2 (LCR22) are a complex mosaic of genes and pseudogenes formed by duplication processes; they mediate chromosome rearrangements associated with velo-cardio-facial syndrome/DiGeorge syndrome, der(22) syndrome, and cat-eye syndrome. The ability to trace the substrates and products of recombination events provides a unique opportunity to identify the mechanisms responsible for shaping LCR22s. We examined the genomic sequence of known LCR22 genes and their duplicated derivatives. We found Alu (SINE) elements at the breakpoints in the substrates and at the junctions in the truncated products of recombination for USP18, GGT, and GGTLA, consistent with Alu-mediated unequal crossing-over events. In addition, we were able to trace a likely interchromosomal Alu-mediated fusion between IGSF3 on 1p13.1 and GGT on 22q11.2. Breakpoints occurred inside Alu elements as well as in the 5' or 3' ends of them. A possible stimulus for the 5' or 3' terminal rearrangements may be the high sequence similarities between different Alu elements, combined with a potential recombinogenic role of retrotransposon target-site duplications flanking the Alu element, containing potentially kinkable DNA sites. Such sites may represent focal points for recombination. Thus, genome shuffling by Alu-mediated rearrangements has contributed to genome architecture during primate evolution.

Translocation breakpoint mapping and sequence analysis in three monosomy 1p36 subjects with der(1)t(1;1)(p36;q44) suggest mechanisms for telomere capture in stabilizing de novo terminal rearrangements

Monosomy 1p36 results from a variety of chromosome rearrangements, including terminal deletions, interstitial deletions, derivative chromosomes, and complex rearrangements. Our previous molecular studies on a large cohort of monosomy 1p36 subjects suggest that a significant percentage of terminal deletions of 1p36 are stabilized by the acquisition of telomeric sequences from other chromosome ends, forming derivative chromosomes (i.e., "telomere capture"). However, the molecular mechanism(s) that results in and/or stabilizes terminal deletions of 1p36 by telomere capture is poorly understood. In this report, we have mapped the translocation breakpoints in three subjects with der(1)t(1;1)(p36;q44) chromosomes by fluorescence in situ hybridization (FISH). These results indicate that the breakpoint locations are variable in all three subjects, with no common 1p deletion or 1q translocation breakpoints. In addition, sequence analysis of the 1p and 1q breakpoint-containing clones did not identify homologous sequences or low-copy repeats in the breakpoint regions, suggesting that nonallelic homologous recombination did not play a role in mediating these rearrangements. Microsatellite marker analysis indicates that two of the three derivative chromosomes were formed by intra-chromosomal rearrangements. These data are consistent with a number of recent reports in other model organisms that suggest break-induced replication at the site of a double-strand break may act as a mechanism of telomere capture by generating nonreciprocal translocations from terminally deleted chromosomes. Alternative models are also discussed.

Monosomy 1p36 breakpoints indicate repetitive DNA sequence elements may be involved in generating and/or stabilizing some terminal deletions

Monosomy 1p36 is the most commonly observed terminal deletion syndrome in humans. Our previous molecular studies on a large cohort of subjects suggest that monosomy 1p36 can result from a variety of chromosomal rearrangements including terminal truncations, interstitial deletions, derivative chromosomes, inverted duplications, and complex rearrangements. However, the mechanism(s) by which rearrangements of 1p36 are generated and/or stabilized is not understood. Sequence analysis of breakpoint junctions may provide valuable clues to the underlying mechanisms of many chromosomal aberrations. In this report, we analyze the breakpoints at the DNA-sequence level in four subjects with variable-sized deletions of 1p36. All four breakpoints fall within repetitive DNA-sequence elements (LINEs, SINEs, etc). This suggests that repetitive DNA-sequence elements may play an important role in generating and/or stabilizing terminal deletions of 1p36. Mechanisms by which repetitive elements may be involved in the process of terminal deletion formation and stabilization are discussed.

Omphalocele in trisomy 3q: further delineation of phenotype

We report a case of a patient with omphalocele, dysmorphic features, and mild developmental delay associated with a chromosomal aberration. Chromosome studies showed that the propositus carries a maternally derived unbalanced translocation der(4)t(3;4)(q27.3;q32.3), resulting in trisomy for region 3q27.3-->qter and monosomy for 4q32.3-->qter. Because the association between dup3q and omphalocele has been reported in several cases, we analyzed the data on 93 previously reported patients with partial trisomy of the long arm of chromosome 3 and compared the clinical features between the cases. The imbalance of chromosome 3 in the patient was further defined by fluorescence in situ hybridization (FISH) studies using bacterial artificial chromosome (BAC) clones. BAC clone RP11-171N2 was identified as a breakpoint-spanning clone in the patient and his mother. Based on our comparative analysis, we have delineated that the smallest region of overlap (SRO) associated with omphalocele is from BAC 171N2 to 3qter. We hypothesize that the SRO contains a gene(s) important in normal abdominal wall development and is of potential interest for further investigation.