De novo direct duplication of 15q15-->q24 in a newborn boy with mild manifestations

Duplication of distal 15q results in a recognizable clinical phenotype. We report here on a 25-day-old boy with a de novo interstitial duplication of chromosome region 15q15-q24. The manifestations in this patient are milder than those of previously described patients and include minor facial anomalies, velopharyngeal insufficiency, branchial cleft cyst, and hydronephrosis. Fluorescence in situ hybridization (FISH) using a chromosome 15 painting probe confirmed that the extra material is of chromosome 15 origin. Further analysis with the SNRPN probe demonstrated that the duplication is telomeric to the Prader-Willi/Angelman syndrome critical region. This case delineates a broader spectrum for patients with duplication 15q syndrome.

A common breakpoint on 11q23 in carriers of the constitutional t(11;22) translocation

Structural chromosomal rearrangements occur commonly in the general population. Individuals that carry a balanced translocation are at risk of having unbalanced offspring; therefore, the frequency of translocations in couples with recurrent spontaneous abortions is higher than that in the general population. The constitutional t(11;22) translocation is the most common recurrent non-Robertsonian translocation in humans and may serve as a model to determine the mechanism that causes recurrent meiotic translocations. We previously localized the t(11;22) translocation breakpoint to a region on 22q11 within a low-copy repeat, termed "LCR22." To define the breakpoint on 11q23 and to ascertain whether this region shares homology with LCR22 sequences, we performed haplotype analysis on patients with der(22) syndrome. We found that the breakpoint on 11q23 occurred between two genetic markers, D11S1340 and APOC3-tetra, both being present within a single bacterial-artificial-chromosome clone. To determine whether the breakpoint occurred within the same region among a larger set of carriers, we performed FISH mapping studies. The breakpoints were all within the same clone, suggesting that this region may harbor sequences that are prone to breakage. We narrowed the breakpoint interval, in both derivative chromosomes from two unrelated carriers, to a 190-bp, AT-rich repeat, which indicates that this repeat may mediate recombination events on chromosome 11. Interestingly, the LCR22s harbor AT-rich repeats, suggesting that this sequence motif may mediate recombination events in nonhomologous chromosomes during meiosis.

Genomic organization and chromosomal localization of the human Coxsackievirus B-adenovirus receptor gene

Myocarditis and dilated cardiomyopathy (DCM) are common causes of morbidity and mortality in children. Many studies have implicated the enteroviruses and, particularly, the Coxsackievirus-B family as etiologic agents of the acquired forms of these diseases. However, we have shown the group-C adenoviruses to be as commonly detected as enteroviruses in the myocardium of children and adults with these diseases. It has remained something of a conundrum why two such divergent virus families cause these diseases. The recent description of the common human Coxsackievirus B-adenovirus receptor (CAR) offers at least a partial explanation. In order to characterize the CAR gene, we screened a bacterial artificial chromosomal (BAC) library (RPCI11) using a polymerase chain reaction (PCR) product derived from the 3' end of the CAR cDNA sequence. This identified 13 BACs that were further characterized by PCR amplification of seven contiguous regions of the entire cDNA sequence. Eleven of the BACs were determined to encode pseudogenes while the other two BACs (131J5 and 246M1) encoded the presumed functional gene. PCR amplification of a monochromosomal hybrid panel indicated the presence of pseudogenes on chromosomes 15, 18, and 21 while the functional gene is encoded on chromosome 21. Fluorescence in situ hybridization analysis indicated that the gene is located at 21q11.2. DNA sequencing of BACs 131J5 and 246M1 revealed the presence of seven exons. The DNA sequences have been determined for each exon-intron boundary, and putative promoter sequences and transcription initiation sites identified. No consensus polyadenylation signal was identified.

Prenatal diagnosis of Charcot-Marie-Tooth disease type 1A

Charcot-Marie-Tooth disease (CMT) is the most common cause of peripheral neuropathy, with an incidence of 1: 2500 persons affected. CMT1A is caused by a submicroscopic duplication in 17p12. Several methods exist for determining a diagnosis in an individual. Many of these methods are not suitable for prenatal diagnosis. Previously, we reported the use of fluorescence in situ hybridization (FISH) to detect the common duplication found in more than 98% of individuals with CMT1A. We also have reported the validation of the FISH assay for amniotic fluid specimens and chorionic villus samples. Herein, we report our experience with testing for CMT1A in prenatal specimens.

Monosomy 1p36

We have reviewed published reports on patients with segmental aneusomy for chromosome 1p36 to help geneticists and other health professionals in the recognition of this emerging chromosomal syndrome. Terminal deletions of the short arm of chromosome 1 are associated with hypotonia and developmental delay (usually severe), growth abnormalities (growth retardation, microcephaly, obesity), and craniofacial dysmorphism with a large anterior fontanelle, prominent forehead, deep set eyes, flat nasal bridge and midface hypoplasia, ear asymmetry, a pointed chin, and orofacial clefting. Minor cardiac malformations, cardiomyopathy, seizures, and ventricular dilatation are the more common additional findings. Sensorineural hearing loss and variable ophthalmological anomalies have also been frequently observed. Although the deletions can be detected by high resolution cytogenetic studies, confirmation by fluorescence in situ hybridisation is required in most cases. The majority of deletions are maternally derived. Molecular characterisation of 1p36 deletions has been undertaken in several cases, and it is likely that this condition is a contiguous gene deletion syndrome.

Molecular and clinical characterization of a patient with duplication of 1p36.3 and metopic synostosis

Chromosome 1p duplications are rare. There have been only 11 reported cases of isolated 1p duplication, all of which were proximal, interstitial duplications. We present a patient with a terminal duplication of 1p (1p36.3). To our knowledge, this is the first such reported case. Our patient presented with metopic synostosis, rectal stenosis, atrial septal defect, and mildly delayed gross motor development. Molecular characterization using microsatellite marker analysis and fluorescence in situ hybridization (FISH) revealed an area of duplication between p58 and D1S2893, approximately 13 cM in size. We compare our patient's clinical findings with the clinical phenotype found in patients with the corresponding deletion of 1p36.3 and discuss the role of gene dosage in other deletion/duplication syndromes.

Miller-Dieker syndrome and trisomy 5p in a child carrying a derivative chromosome with a microdeletion in 17p13.3 telomeric to the LIS1 and the D17S379 loci

Trisomy 5p and Miller-Dieker syndromes frequently are the result of unbalanced segregations of reciprocal translocations of chromosomes 5 and 17 with other autosomes. The critical regions for the expression of the mentioned syndromes have been mapped to 5p13-->pter, and 17p13.3-->pter. In this report, we describe an 8-year-old girl with mental retardation, postnatal growth deficiency, generalized muscular hypotonia, seizures, microcephaly, cortical atrophy, partial agenesis of corpus callosum, cerebral ventriculomegaly, facial anomalies, patent ductus arteriosus, pectus excavatum, long fingers, and bilateral talipes equinovarus caused by the presence of a 46,XX,der(17)t(5;17)(p13.1;p13.3)mat chromosome complement. Cytogenetic studies of the family confirmed a balanced reciprocal translocation (5;17)(p13.1;p13.3) in her mother, maternal grandfather, maternal aunt, and a female first cousin. Fluorescence in situ hybridization studies on the mother and the proposita using three probes, which map to distal 17p, confirmed the reciprocal translocation in the mother and a terminal deletion in the patient, which resulted in the retention of LIS1 and D17S379 loci and deletion of the 17p telomere. These findings and the phenotype of the proposita, strongly suggest that genes telomeric to LIS1 and locus D17S379 are involved in many clinical findings, including the minor facial anomalies of the Miller-Dieker syndrome.

Prenatal diagnosis of Charcot-Marie-Tooth disease type 1A by interphase fluorescence in situ hybridization

Charcot-Marie-Tooth Disease (CMT) is the most common cause of peripheral neuropathy, with an incidence of 1:2500 persons affected. Previously, we reported the use of fluorescence in situ hybridization (FISH) to detect the common submicroscopic duplication of 17p12 found in more than 98 per cent of individuals with CMT1A. We found that FISH is a reliable means for the diagnosis of the duplication of 17p12 in peripheral blood and reported the validation of the FISH assay for amniotic fluid specimens. Herein, we report the validation of the FISH assay for use on chorionic villus samples (CVS) to prenatally diagnose CMT1A duplications and the testing of 17 prenatal specimens. Seven fetuses were found to carry the duplication and are predicted to be affected. FISH is a rapid assay in prenatal specimens, with a 9.3 day average turn-around time. Limited follow-up on pregnancies indicates that the duplication found in CMT1A is reliably diagnosed in the fetus, using FISH on either amniotic fluid specimens or CVS.

Pure trisomy 10p involving an isochromosome 10p

We report a child with trisomy 10p due to a translocation of the long arm of chromosome 10 to the short arm of chromosome 14 and isochromosome formation of 10p [46,XX,i(10)(p10),der(14)t(10;14)(q10;p10)]. Most reported cases of trisomy 10p involve double segmental imbalance. In contrast, the clinical features described in the current case represent pure trisomy 10p and, thus, delineate the 10p trisomy syndrome phenotype. Mechanisms of the chromosomal rearrangements in this case are suggested.

Proteolipid protein gene duplications causing Pelizaeus-Merzbacher disease: molecular mechanism and phenotypic manifestations

Pelizaeus-Merzbacher disease (PMD) is an X-linked disorder characterized by dysmyelination of the central nervous system (CNS) caused by mutations involving the proteolipid protein gene (PLP). In addition to point and frameshift mutations in the coding region, duplications involving the entire PLP have been recognized recently as a major genetic abnormality causing PMD. We devised an interphase fluorescence in situ hybridization (FISH) assay to establish an efficient screening test for PLP duplication. Thirteen patients from 11 Japanese PMD families were determined to have PLP duplications. This molecular diagnostic FISH test also readily detected female carriers. Molecular analysis revealed that the size of the duplication and location of the breakpoints showed striking variation. Fiber FISH demonstrated that the duplication is tandem in nature. Haplotype analysis indicated an intrachromosomal origin for the duplication. These results suggest that an unequal sister chromatid exchange in male meiosis is likely to be the major mechanism leading to the formation of the duplication. Patients with the duplication commonly present with a mild PMD phenotype. Two patients with an exceptionally severe clinical phenotype carried large duplications, suggesting that either the larger duplicated segment incorporates additional dosage-sensitive genes or that the location of the duplication junction may affect the phenotype.

DNA rearrangements on both homologues of chromosome 17 in a mildly delayed individual with a family history of autosomal dominant carpal tunnel syndrome

Disorders known to be caused by molecular and cytogenetic abnormalities of the proximal short arm of chromosome 17 include Charcot-Marie-Tooth disease type 1A (CMT1A), hereditary neuropathy with liability to pressure palsies (HNPP), Smith-Magenis syndrome (SMS), and mental retardation and congenital anomalies associated with partial duplication of 17p. We identified a patient with multifocal mononeuropathies and mild distal neuropathy, growth hormone deficiency, and mild mental retardation who was found to have a duplication of the SMS region of 17p11.2 and a deletion of the peripheral myelin protein 22 (PMP22) gene within 17p12 on the homologous chromosome. Further molecular analyses reveal that the dup(17)(p11.2p11.2) is a de novo event but that the PMP22 deletion is familial. The family members with deletions of PMP22 have abnormalities indicative of carpal tunnel syndrome, documented by electrophysiological studies prior to molecular analysis. The chromosomal duplication was shown by interphase FISH analysis to be a tandem duplication. These data indicate that familial entrapment neuropathies, such as carpal tunnel syndrome and focal ulnar neuropathy syndrome, can occur because of deletions of the PMP22 gene. The co-occurrence of the 17p11.2 duplication and the PMP22 deletion in this patient likely reflects the relatively high frequency at which these abnormalities arise and the underlying molecular characteristics of the genome in this region.

Molecular refinement of the 1p36 deletion syndrome reveals size diversity and a preponderance of maternally derived deletions

The deletion of chromosome 1p36 is a newly recognized, relatively common contiguous gene deletion syndrome with a variable phenotype. The clinical features have recently been delineated and molecular analysis indicates that the prevalence of certain phenotypic features appears to correlate with deletion size. Phenotype/genotype comparisons have allowed the assignment of certain clinical features to specific deletion intervals, significantly narrowing the regions within which to search for candidate genes. We have extensively characterized the deletion regions in 30 cases using microsatellite markers and fluorescence in situ hybridization analyses. The map order of 28 microsatellite markers spanning the deletion region was obtained by a combination of genotypic analysis and physical mapping. The deletion region was divided into six intervals and breakpoints were found to cluster in mainly two regions. Molecular analysis of the deletions showed that two patients had complex re-arrangements; these cases shared their distal and proximal breakpoints in the two common breakpoint regions. Of the de novo deletions ( n = 28) in whichparental samples were available and the analysis was informative ( n = 27), there were significantly morematernally derived deletions ( n = 21) than paternally derived deletions ( n = 6) (chi1(2) = 8.35, P < 0.0001). Phenotype/genotype correlations and refinements of critical regions in our naturally occurring deletion panel have delineated specific areas in which to focus the search for the causative genes for the features of this syndrome.

Investigation of two cases of paternal disomy 13 suggests timing of isochromosome formation and mechanisms leading to uniparental disomy

Uniparental disomy (UPD) is the abnormal inheritance of two copies of a chromosome from the same parent. Possible mechanisms for UPD include trisomy rescue, monosomy rescue, gametic complementation, and somatic recombination. Most of these mechanisms can involve rearranged chromosomes, particularly isochromosomes and Robertsonian translocations. Both maternal and paternal UPD have been reported for most of the acrocentric chromosomes. However, only UPD for chromosomes 14 and 15 show an apparent imprinting effect. Herein, we present two cases of paternal UPD 13 involving isochromosomes. Both cases were referred for UPD studies due to the formation of a de novo rea(13q13q). Case 2 was complicated by the segregation of a familial rob(13q14q) of maternal origin. Both propositi were phenotypically normal at the time of examination. Polymorphic marker analysis in Case 1 showed the distribution of alleles of markers along chromosome 13 to be complete isodisomy, consistent with an isochromosome. This rearrangement could have occurred either meiotically, without recombination, or mitotically. A likely mechanism for UPD in this case is monosomy rescue, through postzygotic formation of the isochromosome. In Case 2 the distribution of proximal alleles indicated an isochromosome, but recombination was evident. Thus, this isochromosome must have formed prior to or during meiosis I. A likely mechanism for UPD in this case is gametic complementation, since the mother carries a rob(13q14q) and is at risk of producing aneuploid gametes. However, trisomy rescue of a trisomy 13 conceptus cannot be completely excluded. Given that both cases were phenotypically normal, these data further support that paternal UPD 13 does not have an adverse phenotypic outcome and, thus, does not show an apparent imprinting effect.

Trisomy 16q in a female newborn with a de novo X;16 translocation and hypoplastic left heart

We report a case of a newborn female with minor dysmorphic features and hypoplastic left heart. Chromosome studies showed that she was the carrier of an unbalanced translocation between the X-chromosome and chromosome 16, resulting in monosomy for Xp and trisomy for 16q. Only a handful of partial trisomy 16q cases have been reported in the literature among liveborns. The great majority of these cases have had significant anomalies in contrast to what has been seen in our patient. The absence of dysmorphic features and other significant abnormalities in this case (with the exception to the hypoplastic left heart), suggested that the inactivation of the derivative X chromosome might have played a role in the mild phenotype of this patient. Conventional cytogenetic studies were conducted in this patient in conjunction with fluorescent in situ hybridization studies, which were used to characterize the X inactivation pattern. The studies revealed that the X chromosome material in the derivative chromosome was inactive while the chromosome 16 derived material in the derivative chromosome was early replicating and active in all cells studied.

Inherited duplication Xq27-qter at Xp22.3 in severely affected males: molecular cytogenetic evaluation and clinical description in three unrelated families

We describe the clinical phenotype in four males from three families with duplication (X)(qter-->q27::p22.3-->qter). This is an unusual duplication of the distal long arm segment, Xq27-qter, onto the distal short arm of the X chromosome at Xp22.3, as shown by fluorescent in situ hybridization analysis with multiple X-specific probes. The patients are young male offspring of three unrelated, phenotypically normal carrier women. The affected males have similar clinical manifestations including severe growth retardation and developmental delay, severe axial hypotonia, and minor anomalies. Such clinical similarity in three unrelated families demonstrates that this chromosome abnormality results in a new and distinct clinical phenotype. Replication studies, performed on two of the mothers, provided evidence that inactivation of the abnormal X chromosome permitted the structural abnormality to persist in these families for a generation or more in females without phenotypic expression.

Combined trisomy 9 and Ullrich-Turner syndrome in a girl with a 46,X,der(9)t(X;9)(q12;q32) karyotype

Total trisomy 9 is a rare disorder with most patients dying before age 4 months. Herein, we report a 9-year-old girl with mental retardation, short stature, a peculiar face and other minor defects, who was diagnosed as having an unbalanced de novo X-autosome translocation with a 46,X,der(9)t(X;9)(q12;q32) karyotype resulting in almost a full trisomy 9(pter-->q32) and a partial monosomy X(q12-->pter). The clinical findings of our patient, almost exclusively resemble those of trisomy 9p and the Ullrich-Turner syndromes and has few manifestations of 9q trisomy. BrdU replication studies by Giemsa staining showed an earlier replication of 9p in the translocated chromosome, but a marked late-replication pattern for almost the complete 9q arm involved in the translocation. FISH studies confirmed the presence of three 9 centromeres, excluded the presence of the X centromere signal in the rearranged chromosome, and showed that both Xq telomeric sequences were present. BrdU replication studies by FISH showed an usual pattern of striking late-replication around the XIC of the derivative chromosome, but early replication of the chromosome 9p segment and distal Xq.

Molecular analysis of mosaicism for two different de novo acrocentric rearrangements demonstrates diversity in Robertsonian translocation formation

Robertsonian translocations (ROBs) involving chromosome 21 occur in about 5% of individuals with Down syndrome. ROBs are the most common chromosomal rearrangements in humans and are formed through whole arm exchanges of any two acrocentric chromosomes. The de novo formation of ROBs occurs at exceptionally high rates. The present case concerns a child with mosaic Down syndrome who has two cell lines that contain two different de novo ROBs: 45,XX,rob(14;21)(q10;q10) and 46,XX,rea(21;21)(q10;q10),+21. To elucidate the mechanisms by which the rearrangements formed, somatic cell hybrids were constructed to allow the parental origins of the chromosomes involved in the ROBs to be distinguished. The analysis of the hybrids showed that the rob(14q21q) must have formed postzygotically because it contained a maternal chromosome 14 and a paternal chromosome 21. Furthermore, hybrid analysis of the rea(21q21q) demonstrated two copies of the same chromosome from the mother and thus, by definition, was an isochromosome [i(21q)]. All free-lying chromosomes 21 isolated in hybrids were of maternal origin. These chromosomes may have originated from either of the patient's cell lines. We present four hypotheses for the formation of the two cell lines of this child. This case is part of an ongoing project to determine the mechanism(s) of de novo ROB formation and the results differ from the other de novo rob(14q21q) studied in our laboratory (n = 7) in that all previously studied translocations were maternally derived, leading to the conclusion that most de novo rob(14q21q) occur in oogenesis. The current case illustrates that other mechanisms may contribute to ROB formation.

Charcot-Marie-Tooth phenotype produced by a duplicated PMP22 gene as part of a 17p trisomy-translocation to the X chromosome

The Charcot-Marie-Tooth disease type 1A (CMT1A) phenotype is most often associated with a 1.5 megabase (mb), tandem duplication of chromosome 17 band p12 (17p12). The prevailing hypothesis is that the demyelinating neuropathy results from a dosage effect of the peripheral myelin protein gene PMP22 which is included within this duplication. We present a patient with clinical and electrophysiological features of CMT1A in whom an extra PMP22 gene resulted from a rare unbalanced translocation of 17p to the X chromosome. This finding further supports the hypothesis of gene dosage as the basis for CMT1A. Moreover, this case highlights the importance of fluorescence in situ hybridization (FISH) as an alternative molecular technique in the diagnosis of CMT1A.

Systematic search for uniparental disomy in early fetal losses: the results and a review of the literature

About 20% of all human conceptuses are estimated to be trisomic and trisomy of all chromosomes remains a common cause of early fetal loss. Uniparental disomy (UPD) has been reported for most human chromosomes and may be an underrecognized contributor to embryonic lethality. To investigate the contribution of UPD to spontaneous abortions, we devised a genome-based screening strategy to identify holochromosomic UPD in 18 fetal losses. No cases of UPD were identified using this approach. Based on our data, UPD does not appear to be a significant contributor to early embryonic lethality. The results of the study are presented along with a review of the cases of UPD reported in the literature by chromosome, parental origin, mode of ascertainment, and phenotypic consequences due to imprinting.

Cytogenetics and the biological basis of sarcomas

Recently, much research has been directed toward gaining a better understanding of sarcoma biology. To accomplish this goal, researchers have focused on characterizing the cytogenetic abnormalities that are detectable by routine karyotyping. With the use of widely-available molecular biologic tools, new information on the genetic abnormalities of sarcomas is rapidly emerging. In addition, physicians are beginning to successfully apply cytogenetic and molecular biologic findings to clinical settings in the form of molecular diagnostic and prognostic tests. Moreover, detailed study of these genetic abnormalities is leading to a better understanding of the molecular pathology of sarcomas, which may eventually lead to better therapy. In this paper, we will review the important new findings on genetic abnormalities in sarcomas, clinical applications of cytogenetic studies, and insight into the biology of sarcomas.

Delineation of the common critical region in Williams syndrome and clinical correlation of growth, heart defects, ethnicity, and parental origin

Williams syndrome (WS) is a neurodevelopmental disorder with a variable phenotype. Molecular genetic studies have indicated that hemizygosity at the elastin locus (ELN) may account for the cardiac abnormalities seen in WS, but that mental retardation and hypercalcemia are likely caused by other genes flanking ELN. In this study, we defined the minimal critical deletion region in 63 patients using 10 microsatellite markers and 5 fluorescence in situ hybridization (FISH) probes on chromosome 7q, flanking ELN. The haplotype analyses showed the deleted cases to have deletions of consistent size, as did the FISH analyses using genomic probes for the known ends of the commonly deleted region defined by the satellite markers. In all informative cases deleted at ELN, the deletion extends from D7S489U to D7S1870. The genetic distance between these two markers is about 2 cM. Of the 51 informative patients with deletions, 29 were maternal and 22 were paternal in origin. There was no evidence for effects on stature by examining gender, ethnicity, cardiac status, or parental origin of the deletion. Heteroduplex analysis for LIMK1, a candidate gene previously implicated in the WS phenotype, did not show any mutations in our WS patients not deleted for ELN. LIMK1 deletions were found in all elastin-deletion cases who had WS. One case, who has isolated, supravalvular aortic stenosis and an elastin deletion, was not deleted for LIMK1. It remains to be determined if haploinsufficiency of LIMK1 is responsible in part for the WS phenotype or is simply deleted due to its close proximity to the elastin locus.