Narrowing the candidate region of Albright hereditary osteodystrophy-like syndrome by deletion mapping in a patient with an unbalanced cryptic translocation t(2;6)(q37.3;q26)

We here describe a submicroscopic translocation affecting the subtelomeric regions of chromosomes 2q and 6q identified in a patient referred to us because of mental retardation, obesity, brachydactyly, and short stature. FISH analysis using subtelomeric probes showed a 46,XY,der(2)t(2;6)(q37.3;q26) in the propositus, and a balanced t(2;6) in his father and sister. FISH with region-specific genomic clones made it possible to map the 2q37.3 breakpoint precisely to the region covered by BAC 585E12, and the 6q26 breakpoint to between the regions encompassed by 414A5 and 480A20. The 2q subtelomeric deletion has often been found in patients with Albright hereditary osteodystrophy (AHO)-like syndrome but, to the best of our knowledge, the 2q37.3-qter monosomy ascertained in our patient is the smallest so far described within the syndrome's critical interval, and may thus enhance the search for the responsible genes.     

Subtelomeric 6p deletion: clinical, FISH, and array CGH characterization of two cases

Thirty patients have been described with cytogenetically visible deletion of the short arm of chromosome 6. However, subtelomeric 6p deletion detected by subtelomeric specific probes has been reported only twice. We report two new patients with terminal 6p deletion detected by subtelomeric screening using fluorescence in situ hybridization (FISH). The two patients exhibited mental retardation, ocular abnormalities, hearing loss, and a characteristic facial appearance. Detailed FISH analyses with probes covering the distal 6p25 region estimated the size of the terminal deletions to approximately 5.5 Mb and approximately 4.8 Mb. Array-based comparative genomic hybridization (array CGH) was used to confirm the cryptic deletions. Most patients with subtelomeric defects lack a characteristic phenotype. However, some of the subtelomeric deletions result in a specific phenotype, which can direct the clinician towards the diagnosis. Submicroscopic 6p deletion appears to be a recognizable clinical phenotype, and this region should be thoroughly investigated with FISH probes, including at least a subtelomeric 6p probe and a probe covering FOXC1, for patients presenting with a characteristic facial appearance, ocular abnormalities, predominantly anterior-chamber eye defects, hearing loss, and mental retardation.     

Molecular characterization of a cryptic 2q37 deletion in a patient with Albright hereditary osteodystrophy-like phenotype

The Albright hereditary osteodystrophy-like (AHO-like) syndrome was recently defined as a rare dysmorphic syndrome including brachymetaphalangism and mental retardation. This phenotype occurs in Albright hereditary osteodystrophy (AHO) but unlike it, the level of the Gs alpha protein activity is not reduced. To date 59 patients with these clinical and biochemical features have been reported, and for the majority of them (57/59) a cytogenetically visible 2q37 deletion has been observed. We report a new case of typical AHO-like syndrome with normal karyotype. Using the polymorphic marker D2S125 we found a loss of heterozygosity suggestive of a de novo 2q37 deletion of maternal origin. This hypothesis was confirmed by FISH analysis with a subtelomeric 2q probe containing the D2S90 marker. Genotypic analysis allowed us to map the proximal breakpoint of the subtelomeric deletion within an interval delimited by D2S2338 (present) and D2S2253 (deleted). This 2q subtelomeric deletion as small as 4 Mb is to date the smallest one observed in association with a typical AHO-like phenotype, and allows us to move the centromeric boundary of the AHO-like critical region by 750 kb towards the 2q telomere.     

Subtelomeric FISH uncovers trisomy 14q32: Lessons for imprinted regions,cryptic rearrangements and variant acrocentric short arms

The recent development of a set of chromosome‐specific, subtelomeric probes has proved useful in diagnosis and recurrence risk counseling of patients and families with mental retardation and in further characterization of known chromosomal abnormalities. Cases of cryptic, subtelomeric rearrangements may account for up to 7.5% of cases of idiopathic moderate–severe mental retardation. We present the molecular cytogenetic studies of trisomy 14q detected by subtelomeric fluorescence in situ hybridization (FISH). Our patient is a 3‐year‐old girl with growth and developmental delay, myelomeningocele, partial agenesis of the corpus callosum, hypertelorism, tented mouth, simple ears, small mandible, and congenital heart disease (atrial and ventricular septal defects with subaortic conus). G‐banded chromosome analysis was apparently normal. A set of FISH‐based, subtelomeric, region‐specific probes revealed trisomy for 14q in the child. Parental FISH studies established that the mother is a balanced carrier for a half‐cryptic translocation between the distal long arm of chromosome 14 and the short arm of chromosome 22. FISH analysis using two BAC clones that contain the imprinted genes MEG3 and DLK1, which localize to 14q32, established that our patient has two maternal copies of these genes. Because the child does not have features of the maternal UPD 14 syndrome, this case suggests that it is absence of expression of a paternally expressed gene, rather than overexpression of a maternally expressed gene, that is responsible for the maternal UPD 14 phenotype. © 2002 Wiley‐Liss, Inc.     

Clinical and molecular characterization of individuals with 18p deletion: a genotype-phenotype correlation

The deletion 18p syndrome is one of the most common chromosome abnormalities. The medical problems are mental and postnatal growth retardation, and sometimes malformations of the heart and brain. The individuals have some typical features, which might be easy to overlook and which are: ptosis, strabismus, hypertelorism, broad flat nose, micrognathia, big and low set ears. The aims of present study were to clinically and molecularly characterize the syndrome further in seven subjects with de novo 18p deletions and to perform genotype-phenotype correlation. All seven subjects had terminal deletions and no interstitial deletion was observed with subtelomeric FISH analyses. To define the extent of the 18p deletions and the parental origin of the deletion microsatellite- and FISH analyses were performed on genomic DNA and on lymphoblastoid cell lines of the study participants. Totally 19 chromosomes, 18 specific polymorphic microsatellite markers, and 5 BAC clones were used. The results revealed that the deletions were located in the centromeric region at 18p11.1 in four of the seven subjects. In the remaining three the breakpoints were located distal to 18p11.1 (18p11.21-p11.22). Four of the individuals had a paternal and three a maternal origin of the deletion. Genotype-phenotype correlation of the seven subjects suggests a correlation between the extent of the deleted region and the mental development. All the four children with a deletion in the centromeric region at 18p11.1 had a mental retardation (MR). Two of the three children with a more distal breakpoint (distal 18p11.21) had a normal mental development and one had a border-line mental retardation. There might be a critical region for the mental retardation located between 18p11.1 and 18p11.21. The children with a breakpoint at 18p11.1 had all a broad face, which was observed in only one of those with a more distal breakpoint, otherwise no genotype-phenotype correlation of the features was observed.     

Subtelomeric FISH uncovers trisomy 14q32: lessons for imprinted regions,cryptic rearrangements and variant acrocentric short arms

The recent development of a set of chromosome-specific, subtelomeric probes has proved useful in diagnosis and recurrence risk counseling of patients and families with mental retardation and in further characterization of known chromosomal abnormalities. Cases of cryptic, subtelomeric rearrangements may account for up to 7.5% of cases of idiopathic moderate-severe mental retardation. We present the molecular cytogenetic studies of trisomy 14q detected by subtelomeric fluorescence in situ hybridization (FISH). Our patient is a 3-year-old girl with growth and developmental delay, myelomeningocele, partial agenesis of the corpus callosum, hypertelorism, tented mouth, simple ears, small mandible, and congenital heart disease (atrial and ventricular septal defects with subaortic conus). G-banded chromosome analysis was apparently normal. A set of FISH-based, subtelomeric, region-specific probes revealed trisomy for 14q in the child. Parental FISH studies established that the mother is a balanced carrier for a half-cryptic translocation between the distal long arm of chromosome 14 and the short arm of chromosome 22. FISH analysis using two BAC clones that contain the imprinted genes MEG3 and DLK1, which localize to 14q32, established that our patient has two maternal copies of these genes. Because the child does not have features of the maternal UPD 14 syndrome, this case suggests that it is absence of expression of a paternally expressed gene, rather than overexpression of a maternally expressed gene, that is responsible for the maternal UPD 14 phenotype.     

Unbalanced cryptic 5p deletion/17p duplication identified by subtelomeric FISH in a family with a boy with chimerism and a balanced t(4;5)

The use of subtelomeric FISH probes has greatly supplemented conventional chromosome analysis in detecting cryptic anomalies in patients with mental retardation (MR), dysmorphic features, and congenital malformations. We report a 3-month-old boy who was diagnosed with ambiguous genitalia, dysmorphic features, and developmental delay. Standard chromosome studies on blood revealed a chimeric karyotype of 46,XY,t(4;5)(q31.1;q14)[46]/46,XX[4]. The boy had intra-abdominal gonads that were testicular in origin by biopsy. Multiple dysmorphic features, marked hypotonia, developmental delay, poor growth, and relative macrocephaly were noted on physical exam. His 2.5-year-old sister also presented with hypotonia, developmental delay, relative macrocephaly, and similar dysmorphic stigmata. In addition, she was diagnosed with several internal malformations. Her karyotype was 46,XX. Due to the striking phenotypic similarity, subtelomeric FISH studies were initiated in the siblings. In addition to the known balanced karyotypic abnormalities, the boy was found to have a derivative chromosome 5 with a 5pter deletion and a 17pter duplication. This cryptic abnormality was also detected in his sister. Chromosome analysis of the father revealed a subtle balanced t(5;17)(p15.31;p13.1) which was confirmed by subtelomeric FISH, whereas the mother's chromosome complement was normal. This familial constellation illustrates the usefulness of subtelomeric FISH in the diagnosis of cryptic chromosome abnormalities in patients for whom conventional karyotype does not disclose findings sufficient to explain the observed phenotypic anomalies.     

Possible third case of Lin-Gettig syndrome

We report a patient with craniosynostosis, severe mental retardation, absence of the corpus callosum, camptodactyly, hypogonadism, and ventricular septal defect. We propose that he has Lin-Gettig syndrome and that he is the third reported patient with this entity. Our patient also had additional phenotypic features, including palatal cleft and absent rapid eye movement (REM) sleep that were not present in the two previously described patients with this syndrome. High-resolution karyotype and subtelomeric fluorescence in situ hybridization (FISH) for cryptic telomeric rearrangement were normal. The existence of an unrelated patient with Lin-Gettig syndrome supports that this is a separate and distinct clinical entity.     

A subterminal deletion of the long arm of chromosome 10: a clinical report and review

We report on a girl with mental retardation, dysmorphic features, and behavioral problems. A small terminal deletion of the long arm of chromosome 10 was detected by subtelomeric fluorescence in situ hybridization (FISH) studies in all analyzed metaphases. The deletion was shown to be a de novo terminal deletion of approximately 6.1 Mb, with the deletion breakpoint localized at band 10q26.2, between BAC probes RP11-498K22 and RP11-42K2. A subterminal 10q deletion as found in the present patient has, to our knowledge, only been reported in 15 patients (including 8 familial cases). We review the clinical and behavioral phenotype of these patients with "pure" subterminal 10q deletion.     

Mild phenotype in two unrelated patients with a partial deletion of 21q22.2-q22.3 defined by FISH and molecular studies

We describe two unrelated patients with cytogenetically visible deletions of 21q22.2-q22.3 and mild phenotypes. Both patients presented minor dysmorphic features including thin marfanoid build, facial asymmetry, downward-slanting palpebral fissures, depressed nasal bridge, small nose with bulbous tip, and mild mental retardation (MR). FISH and molecular studies indicated common deleted areas but different breakpoints. In patient 1, the breakpoint was fine mapped to a 5.2 kb interval between exon 5 and exon 8 of the ETS2 gene. The subtelomeric FISH probe was absent on one homologue 21 indicating a terminal deletion spanning approximately 7.9 Mb in size. In patient 2, the proximal breakpoint was determined to be 300-700 kb distal to ETS2, and the distal breakpoint 2.5-0.3 Mb from the 21q telomere, indicating an interstitial deletion sized approximately 4.7-7.3 Mb. The 21q- syndrome is rare and typically associated with a severe phenotype, but different outcomes depending on the size and location of the deleted area have been reported. Our data show that monosomy 21q of the area distal to the ETS2 gene, representing the terminal 7.9 Mb of 21q, may result in mild phenotypes comprising facial anomalies, thin marfanoid build, and mild MR, with or without signs of holoprosencephaly.     

Familial MCA/MR syndrome due to inherited submicroscopic translocation t(18;21)(q22.1q21.3) with breakpoint at the Down syndrome critical region

We report three generation family that includes two patients with severe mental retardation and additional anomalies who have been studied, clinically, cytogenetically, and molecular cytogenetically. A clinical diagnosis could not be made in the propositus, but facial anomalies of Down syndrome (DS) were recognized in the maternal uncle of the propositus. In view of a strong family history of recurrent miscarriage, a familial translocation was highly suggestive. Standard cytogenetic analysis did not reveal any abnormalities. Fluorescence in situ hybridization (FISH) using subtelomeric DNA probes identified a familial cryptic translocation of chromosomes 18 and 21, resulting in partial trisomy 21 and partial monosomy 18q in both patients. FISH analysis of obligate carriers demonstrated a balanced translocation between the terminal parts of 18q and 21q. Including this family, a total of six different familial cases with cryptic or subtle subtelomeric translocations of chromosome 21q has been reported, of which three involved terminal parts of chromosome 18q. The remarkable similarity of the chromosomal breakpoints of our patients and the described families prompted us to refine the breakpoints and to discuss phenotypic differences between these patients. Our results reinforce the role of cryptic subtelomeric rearrangements in patients with mental retardation associated with physical anomalies and stress the importance of FISH technology to supplement routine cytogenetics.     

Familial complex 3q;10q rearrangement unraveled by subtelomeric FISH analysis

In recent years, subtelomeric rearrangements have been identified as a major cause of multiple congenital anomalies/mental retardation syndromes. Currently, more than 2,500 individuals with mental retardation have been tested and reported in whom subtelomeric rearrangements were detected ranging from 2% to 29%. Therefore, subtelomeric FISH analysis is indicated as a second tier test after high-resolution G-banding analysis in patients with otherwise unexplained developmental delay/mental retardation and/or multiple congenital anomalies. We describe a patient and her three maternal female cousins, all showing an undiagnosed MCA/MR syndrome, associated with the same complex subtelomeric rearrangement. Subtelomeric FISH testing performed between 3(1/2) and 18 years after the initial karyotype showed, in all four patients, distal trisomy 3q and distal monosomy 10q as follows: 46,XX,ish der(10)t(3;10)(q29;q26.3)mat(D10S2488+,D10S2490-, D3S1272+,D10Z1+). Parental subtelomeric FISH analysis showed that the proposita's mother and three of four brothers and one of two sisters had a cryptic balanced 3:10 telomere translocation. The three brothers with the balanced translocation were father to one each of the three proband's cousins. All four affected girls showed a similar phenotype with pre/postnatal growth retardation, microcephaly, severe developmental delay/mental retardation, poor/absent speech, and a distinct pattern of malformation. On examination there were coarsening of facial features with low fronto-temporal hairline; thick eyebrows; bilateral epicanthal folds; hypertelorism; prominent nose with squared nasal root and narrow alar base; low-set posteriorly rotated large ears with a prominent anthelix; high arched palate; prominent chin; hands/feet brachydactyly; bilateral squint; hypotonia; and muscle hypotrophy. A slow overall improvement was seen in all patients over time. To our knowledge, this complex subtelomeric rearrangement in our patients has never been reported so far. Monosomy 10q has recently been described either isolated or as part of a complex rearrangement involving telomeres other than the 3q. Trisomy 3q29 has not yet been reported, but our patients resembled cases with 3q26 trisomy suggesting that the critical region of duplication for this phenotype is in 3q29.     

Screening of subtelomeric rearrangements in 100 Korean Pediatric patients with unexplained mental retardation and anomalies using subtelomeric FISH (fluorescence in situ hybridization)

Rearrangements of the subtelomeric regions of chromosomes account for a significant proportion of the underlying genetic defects in both idiopathic mental retardation (MR) and multiple congenital anomalies. To detect the rearrangements, a set of subtelomeric fluorescence in situ hybridization (FISH) probes has been developed. The aim of this study was to reveal the frequency of subtelomeric rearrangements in Korean patients with MR or multiple anomalies. We performed a FISH study using a commercially available subtelomeric FISH probes on a series of unrelated Korean pediatric patients with MR or multiple anomalies without identifiable causes. We used a checklist to evaluate the developmental delay and/or MR. Patients who were shown to have chromosome abnormalities, metabolic disorders, or recognizable dysmorphic syndromes by clinical and laboratory findings were excluded. As a result, 100 patients were eligible for the Subtelomeric FISH study, and a total of 29 patients (29%) were suspected to have subtelomeric rearrangements on initial screening by the multiprobe FISH kit. Among theses, confirmatory FISH studies by using single locus-specific FISH probes were performed in 24 patients. One patient (a 10- yr-old girl) was confirmed to have rearrangement, deletion of the telomeric portion of the short arm of chromosome 4 (4p). Her clinical manifestation was compatible with Wolf-Hirschhorn syndrome, which is known to be caused by 4p deletion. The frequency of subtelomeric rearrangements in this study was 1.1% (1/95), lower than those previously reported (0.5-16.3%). We suggest that subtelomeric FISH test is a useful screening tool for patients with idiopathic MR and/or dysmorphism regardless of its false positive value.     

Distinct phenotype associated with a cryptic subtelomeric deletion of 19p13.3-pter

Telomeres are gene rich regions with a high recombination rate. Cryptic subtelomeric rearrangements are estimated to account for 5% of mental retardation/malformation syndromes. Here we present the first patient with a deletion of 19p13.3, identified by subtelomeric FISH analysis. His features included a distinctive facial appearance, cleft palate, hearing impairment, congenital heart malformation, keloid scarring, immune dysregulation, and mild learning difficulties. Subtelomeric FISH analysis identified a deletion of 19p13.3-pter. The deletion size was determined to be 1.2 Mb by FISH analysis. It extended from within the chromosomal region covered by BAC RP11-50C6 to 19pter. The deleted area encompassed approximately 60 genes. Fifteen possible candidate genes were considered with respect to the phenotype, including follistatin-related precursor 3 (FSTL3) and serine-threonine kinase 11 (STK-11).     

Screening for submicroscopic chromosome rearrangements in children with idiopathic mental retardation using microsatellite markers for the chromosome telomeres

Recently much attention has been given to the detection of submicroscopic chromosome rearrangements in patients with idiopathic mental retardation. We have screened 27 subjects with mental retardation and dysmorphic features for such rearrangements using a genetic marker panel screening. The screening was a pilot project using markers from the subtelomeric regions of all 41 chromosome arms. The markers were informative for monosomy in both parents at 3661902 loci (40.6%, 95% confidence interval 37.0-44.2%) in the 22 families where DNA was available from both parents. In two of the 27 subjects, submicroscopic chromosomal aberrations were detected. The first patient had a 5-6 Mb deletion of chromosome 18q and the second patient had a 4 Mb deletion of chromosome 1p. The identification of two deletions in 27 cases gave an aberration frequency of 7.5% without adjustment for marker informativeness (95% confidence interval 1-24%) and an estimated frequency of 18% if marker informativeness for monosomy was taken into account. This frequency is higher than previous estimates of the number of subtelomeric chromosome abnormalities in children with idiopathic mental retardation (5-10%) although the confidence interval is overlapping. Our study suggests that in spite of the low informativeness of this pilot screening, submicroscopic chromosome aberrations may be a common cause of dysmorphic features and mental retardation.     

Genotype-phenotype correlations to aid in the prognosis of individuals with uncommon 20q13.33 subtelomere deletions: a collaborative study on behalf of the 'association des Cytogénéticiens de langue Française'

The identification of subtelomeric rearrangements as a cause of mental retardation has made a considerable contribution to diagnosing patients with mental retardation. It is remarkable that for certain subtelomeric regions, deletions have hardly ever been reported so far. All the laboratories from the 'Association des Cytogénéticiens de Langue Fran?aise' were surveyed for cases where an abnormality of the subtelomere FISH analysis had been ascertained. Among 1511 cases referred owing to unexplained mental retardation, 115 (7.6%) patients showed a clinically significant subtelomeric abnormality. We report the clinical features and the molecular cytogenetic delineation of isolated de novo deletions on 20q13.33 in two cases. Detailed mapping was performed by micro-array CGH in one patient and confirmed by FISH in the two patients. We compare our data with the only three patients reported in the literature. Both patients shared a deleted region of approximately 1.33 Mb including 40 genes, with a 324 kb difference between the two patients. Haploinsufficiency for CHRNA4 and ARFGAP1 may have contributed towards a severe phenotype. In addition, the data in all patients suggest that haploinsufficiency for SOX18 may not cause the hypotrichosis-lymphedema-telangiectasia syndrome, or causes milder disease. Our study gives important information by defining the size of imbalance and better predicting the phenotype. Two clinically distinct phenotypes may be drawn, a mild mental retardation or a more complex and severe phenotype, according to the presence or absence of the CHRNA4 and ARFGAP1 genes respectively.     

Molecular characterization of a novel, de novo, cryptic interstitial deletion on 19p13.3 in a child with a cutis aplasia and multiple congenital anomalies

We report on a de novo constitutional deletion within G-band region 19p13.3 in a girl with cutis aplasia of the scalp, facial anomalies, structural heart abnormalities, hypotonia, mild mental retardation and conductive hearing loss which we characterized with chromosomal microarray, fluorescence in situ hybridization (FISH), and SNP analyses. Initial microarray analysis revealed a 6-BAC-clone deletion covering an approximately 1.612?Mb region within 19p13.3. Subsequent BAC FISH studies delineated the proximal deletion breakpoint to within BAC clone RP11-125C3 and the distal deletion breakpoint to within BAC clone RP11-648B14. SNP analysis showed the deletion to be of paternal origin and further refined its distal breakpoint to within a 20?kb region between rs11666694 and novel SNP2 that we identified at g.2,924,845, and its proximal deletion breakpoint to within a 22?kb region between rs35280644 and rs262562. Accordingly, the size of the deletion was revised to 1.89-1.932?Mb in length. We identified many Alu, L1, and L2 repeats, as well as SINE and LINE sequences at both deletion breakpoints. We found the deletion to encompass 71 genes, two of which appear to be good candidates for the patient's observed craniofacial and cardiac anomalies: guanine nucleotide binding protein (G protein), alpha 11 (Gq class)(GNA11), and Transducin-like Enhancer of Split 2 (E(sp1) homolog, Drosophila)(TLE2).     

Prospective study comparing HR-CGH and subtelomeric FISH for investigation of individuals with mental retardation and dysmorphic features and an update of a study using only HR-CGH

In a prospective study 94 individuals with mental retardation (MR) and dysmorphic features with normal conventional karyotypes were investigated by both subtelomeric FISH and high resolution CGH (HR-CGH) in order to compare the potential of the two techniques in this application. A total of 9.6% abnormalities were found with HR-CGH and subtelomeric FISH, with HR-CGH detecting 8.5% (95% CI: 4.4-15.9) and FISH 3.2% (95% CI: 1.2-9.0). Thus, the techniques complemented each other, however, the diagnostic yield appeared higher of HR-CGH than of subtelomeric FISH, as most aberrations were interstitial. Another 330 individuals with MR and dysmorphic features with normal conventional karyotypes were investigated by HR-CGH on a routine basis. When added to the analyses of the prospective study a total of 51/424 (12%; 95% CI: 9.3-15.5) abnormalities were found, of which the majority were interstitial. We conclude that HR-CGH is well suited for routine screening for cryptic chromosomal imbalances in patients with MR and dysmorphic features. It is likely that the use of the technique in this application will reinforce the effort of defining new syndromes.     

Screening of subtelomeric rearrangements in autistic disorder: identification of a partial trisomy of 13q34 in a patient bearing a 13q;21p translocation.

Within the framework of a FISH screening protocol to detect cryptic subtelomeric rearrangements in autistic disorder (AD), a patient bearing three copies of the subtelomeric portion of the q arm of chromosome 13 has been identified. Beside AD, the patient also has severe mental retardation and displays several dysmorphic features. Further FISH analyses revealed that the trisomy was caused by the translocation of a 13q subtelomeric fragment to the acrocentric tip of one chromosome 21 [46,XY.ish der(21) t(13;21) (q34;p13)(D13S1825+)]. Gene dosage experiments carried out with three multiallelic polymorphisms of the subtelomeric region of chromosome 13q showed that the putative length of the triplicate region does not exceed 300 kb about, that is, the distance from telomere to the first normally inherited marker. In addition, gene dosage analysis performed on the derivative chromosome 21, did not reveal loss of the most telomeric protein-encoding genes on 21p. The potential relationship between a postulated increased expression of genes on 13q34 and the complex phenotype in this trisomic patient is discussed.