Sister chromatid exchange analysis of the 15q11 region in Prader-Willi syndrome patients

Summary Prader-Willi syndrome (PWS) is a sporadic disorder in which about half of cases have a 15q12 deletion. Although a small number of cases have other rearrangements involving 15q12, the rest of the cases appear to have normal chromosomes. Clinical similarities among all these patients regardless of the karyotype strongly suggests a common etiology. To investigate the nature of this common etiology, we analyzed sister chromatid exchange (SCE) at the 15q11-13 region in 10 PWS patients with the chromosome deletion, 12 PWS patients with normal chromosomes, and 11 normal control individuals. While SCE at the q11-13 region was absent on the 15q12 deleted chromosome, the percentage of SCE on chromosome 15 at q11 was statistically higher for PWS with normal chromosomes (10.1%) compared to that for normal controls (1.9%) and the normal homologue (2.2%) in deleted patients (²=7.7982, df=2, P<0.025). The data suggest relative instability of DNA at the 15q11 region in PWS patients.     

Prader-Willi syndrome with an unusually large 15q deletion due to an unbalanced translocation t(4;15)

Prader-Willi syndrome (PWS) is a neurobehavioral disorder caused by deletions in the 15q11-q13 region, by maternal uniparental disomy of chromosome 15 or by imprinting defects. Structural rearrangements of chromosome 15 have been described in about 5% of the patients with typical or atypical PWS phenotype. An 8-year-old boy with a clinical diagnosis of PWS, severe neurodevelopmental delay, absence of speech and mental retardation was studied by cytogenetic and molecular techniques, and an unbalanced de novo karyotype 45,XY,der(4)t(4;15)(q35;q14),-15 was detected after GTG-banding. The patient was diagnosed by SNURF-SNRPN exon 1 methylation assay, and the extent of the deletions on chromosomes 4 and 15 was investigated by microsatellite analysis of markers located in 4qter and 15q13-q14 regions. The deletion of chromosome 4q was distal to D4S1652, and that of chromosome 15 was located between D15S1043 and D15S1010. Our patient's severely affected phenotype could be due to the extent of the deletion, larger than usually seen in PWS patients, although the unbalance of the derivative chromosome 4 cannot be ruled out as another possible cause. The breakpoint was located in the subtelomeric region, very close to the telomere, a region that has been described as having the lowest gene concentrations in the human genome.     

Unbalanced translocation t(15;22) in "severe" Prader-Willi syndrome

A 13-year-old girl with an unbalanced karyotype 45,XX,-15,der(22)t(15;22)(q13;q13.3) de novo had Prader-Willi syndrome (PWS), (score 13.5), but with features of mental and physical retardation more severe than usually seen in PWS. The clinical diagnosis of PWS was confirmed by methylation analysis that showed absence of the paternal band. With GTG banding, the cytogenetic breakpoint on chromosome 15q13, with 15q14 intact, encompassed the PWS region, while the breakpoint on 22q was terminal. Investigations with FISH utilised ten different probes/combinations, namely SNRPN/PML, TUPLE1/22q13.3, TUPLE/ARSA, GABRB3, three YAC clones and one cosmid for specific regions within chromosome 15q, painting probes for the long arm of chromosomes 15 and 22 and a pantelomere probe. Deletion of SNRPN,TYAC 9 (at 15q11-12), TYAC19 (at 15q13) and GABRB3 (within the PWS locus), was evident on the derivative (22) chromosome, while TYAC10 (at 15q22), cos15-5 (at 15q22) and PML (15q22) were not deleted. On the der(22), 22q13.3 and ARSA were not deleted, but the most distal non specific pantelomeric probe was deleted. Thus, the severe phenotype could be attributable to deletion on chromosome 15q extending beyond q13 to q14, (further than the usual chromosome 15q deletion (q11-13) in PWS), or be related to loss of the very terminal 22q region (from ARSA to the pantelomere) or be due to genetic factors elsewhere in the genome.     

Chromosome 15 anomalies and the Prader-Willi syndrome: Cytogenetic analysis

Summary The behaviour of chromosome 15 is very different from that of the other acrocentric chromosomes. The cytogenetic characteristics of rearrangements associated with Prader-Willi syndrome (PWS) are analyzed as similar rearrangements irrespective of the associated phenotype (reciprocal translocations of chromosome 15, small bisatellited additional chromosomes, Robertsonian translocations, interstitial deletions, pericentric inversions). This study suggests that: (1) The proximal (15q) region and PWS seem to be indissociable; (2) chromosome 15 has an indisputable cytogenetic originality which could be related to its histochemical properties. Chromosome 15 constitutive heterochromatin usually contains much 5-methylcytosine-rich DNA and a large amount of each of the four satellite DNAs. Furthermore the existence in the proximal (15q) region of one or several palindromic sequences could be postulated to explain the great lability of this region of chromosome 15.     

Cytogenetic and molecular characterization of inverted duplicated chromosomes 15 from 11 patients.

We have studied the inverted duplicated chromosomes 15 (inv dup(15)) from 11 individuals--7 with severe mental retardation and seizures, 3 with a normal phenotype, and 1 with Prader-Willi syndrome (PWS). Through a combination of FISH and quantitative DNA analyses, three different molecular sizes of inv dup(15) were identified. The smallest inv dup(15) was positive only for the centromeric locus D15Z1 (type 1); the next size was positive for D15Z1 and D15S18 (type 2); and the largest inv dup(15) was positive for two additional copies of loci extending from D15Z1 and D15S18 through D15S12 (type 3). Type 1 or type 2 was observed in the three normal individuals and the PWS patient. Type 3 was observed in all seven individuals with mental retardation and seizures but without PWS or Angelman Syndrome (AS). The PWS patient, in addition to being mosaic for a small inv dup(15), demonstrated at D15S63 a methylation pattern consistent with maternal uniparental inheritance of the normal chromosomes 15. The results from this study show (a) two additional copies of proximal 15q loci, D15S9 through D15S12, in mentally retarded patients with an inv dup(15) but without AS or PWS and (b) no additional copies of these loci in patients with a normal phenotype or with PWS.     

Trisomy 15 with loss of the paternal 15 as a cause of Prader-Willi syndrome due to maternal disomy.

Uniparental disomy has recently been recognized to cause human disorders, including Prader-Willi syndrome (PWS). We describe a particularly instructive case which raises important issues concerning the mechanisms producing uniparental disomy and whose evaluation provides evidence that trisomy may precede uniparental disomy in a fetus. Chorionic villus sampling performed for advanced maternal age revealed trisomy 15 in all direct and cultured cells, though the fetus appeared normal. Chromosome analysis of amniocytes obtained at 15 wk was normal in over 100 cells studied. The child was hypotonic at birth, and high-resolution banding failed to reveal the deletion of 15q11-13, a deletion which is found in 50%-70% of patients with PWS. Over time, typical features of PWS developed. Molecular genetic analysis using probes for chromosome 15 revealed maternal disomy. Maternal nondisjunction with fertilization of a disomic egg by a normal sperm, followed by loss of the paternal 15, is a likely cause of confined placental mosaicism and uniparental disomy in this case of PWS, and advanced maternal age may be a predisposing factor.     

46,XX, der(15),t(Y;15)(q12;p11) karyotype in an azoospermic male

We report on a Yq/15p translocation in a 23-year-old infertile male referred for Klinefelter Syndrome testing, who had azoospermia and bilateral small testes. Hormonal studies revealed hypergonadotropic hypogonadism. Conventional cytogenetic procedures giemsa trypsin giemsa (GTG) and high resolution banding (HRB) and molecular cytogenetic techniques Fluorescence In Situ Hybridization (FISH) performed on high-resolution lymphocyte chromosomes revealed the karyotype 46,XX, t(Y;15)(q12;p11). SRY-gene was confirmed to be present by classical Polymerase Chain Reaction (PCR) methods. His father carried de novo derivative chromosome 15 [45,X, t(Y;15)(q12;p11)] and was fertile; the karyotype of the father using G-band technique confirmed a reciprocal balanced translocation between chromosome Y and 15. In the proband, the der (15) has been inherited from the father because the mother had a normal karyotype (46,XX). In the proband, the der (15) could have produced genetic imbalance leading to unbalanced robertson translocation between chromosome Y and 15, which might have resulted in azoospermia and infertility in the proband. The paternal translocation might have lead to formation of imbalanced ova, which might be resulted infertility in the proband. Sister''s karyotypes was normal (46,XX) while his brother was not analyzed.     

A 15p+ variant shown to be a t(Y;15) with fluorescence in situ hybridisation.

Prenatal diagnosis in two successive pregnancies revealed the karyotype 46,XX,15p+ (pat). Using the Y heterochromatic probe pHY3.4 and fluorescence in situ hybridisation, the variant 15 was identified as a t(Y;15)(q12;p11). Interphase scanning alone would have given a false result in both prenatal assessments and in the phenotypically normal father.     

Chromosome 15 uniparental disomy is not frequent in Angelman syndrome.

Genetic imprinting has been implicated in the etiology of two clinically distinct but cytogenetically indistinguishable disorders--Angelman syndrome (AS) and Prader-Willi syndrome (PWS). This hypothesis is derived from two lines of evidence. First, while the molecular extents of de novo cytogenetic deletions of chromosome 15q11q13 in AS and PWS patients are the same, the deletions originate from different parental chromosomes. In AS, the deletion occurs in the maternally inherited chromosome 15, while in PWS the deletion is found in the paternally inherited chromosome 15. The second line of evidence comes from the deletion of an abnormal parental contribution of 15q11q13 in PWS patients without a cytogenetic and molecular deletion. These patients have two maternal copies and no paternal copy of 15q11q13 (maternal uniparental disomy) instead of one copy from each parent. By qualitative hybridization with chromosome 15q11q13 specific DNA markers, we have now examined DNA samples from 10 AS patients (at least seven of which are familial cases) with no cytogenetic or molecular deletion of chromosome 15q11q13. Inheritance of one maternal copy and one paternal copy of 15q11q13 was observed in each family, suggesting that paternal uniparental disomy of 15q11q13 is not responsible for expression of the AS phenotype in these patients.     

A combination of five short tandem repeats of chromosome 15 significantly improves the identification of Prader-Willi syndrome etiology in the Argentinean population

Prader-Willi syndrome (PWS) is a multisystemic disorder caused by the loss of expression of paternally transcribed genes in the PWS critical region of chromosome 15. Various molecular mechanisms are known to lead to PWS: deletion 15q11-q13 (75% of cases), maternal uniparental disomy (matUPD15) (23%) and imprinting defects (2%). FISH and microsatellite analysis are required to establish the molecular etiology, which is essential for appropriate genetic counseling and care management. We characterized an Argentinean population, using five microsatellite markers (D15S1035, D15S11, D15S113, GABRB3, D15S211) chosen to develop an appropriate cost-effective method to establish the parental origin of chromosome 15 in nondeleted PWS patients. The range of heterozygosity for these five microsatellites was 0.59 to 0.94. The average heterozygosity obtained for joint loci was 0.81. The parental origin of chromosome 15 was established by microsatellite analysis in 19 of 21 non-deleted PWS children. We also examined the origin of the matUPD15; as expected, most of disomies were due to a maternal meiosis I error. The molecular characterization of this set of five microsatellites with high heterozygosity and polymorphism information content improves the diagnostic algorithm of Argentinean PWS children, contributing significantly to adequate genetic counseling of such families.     

Trisomy 11p15 and Beckwith-Wiedemann syndrome. Report of two new cases

An association between trisomy 11p15 and Beckwith-Wiedemann syndrome is described in two brothers. The first presented at birth with gigantism and macroglossia, umbilical hernia and abdominal distention, hypoglycemia and atresia of the pulmonary artery, leading to the diagnosis of Beckwith-Wiedemann syndrome. Facial dysmorphism also included: a hypoplastic midface, hypertelorism, and a short nose with a flattened bridge. The karyotype showed a trisomy 11p15 with a monosomy 18p11, due to a t(11;18)(p154;p111)pat. His brother, born a year later, showed the same signs. The association between trisomy 11p15 and Beckwith-Wiedemann syndrome is in certain cases well established.     

Molecular diagnosis of the Prader-Willi and Angelman syndromes by detection of parent-of-origin specific DNA methylation in 15q11-13

The Prader-Willi syndrome (PWS) and the Angelman syndrome (AS) are distinct genetic disorders that are caused by a deletion of chromosome region 15q11-13 or by uniparental disomy for chromosome 15. Whereas PWS results from the absence of a paternal copy of 15q11-13, the absence of a maternal copy of 15q11-13 leads to AS. We have found that an MspI/HpaII restriction site at the D15S63 locus in 15q11-13 is methylated on the maternally derived chromosome, but unmethylated on the paternally derived chromosome. Based on this difference, we have devised a rapid diagnostic test for patients suspected of having PWS and AS.     

Subfertile couple with inv(2),inv(9) and 16qh+

This case report presents two chromosomal inversions in one of partners from a subfertile couple. The woman was referred due to a spontaneous abortion in the 5th week of pregnancy. Cytogenetic examination showed that the proband's karyotype was normal: 46,XX,16qh+, as centromeric heterochromatin is thought to be clinically insignificant. However, the proband's partner occurred to be a carrier of two pericentric inversions. His karyotype was 46,XY,inv(2)(p11q13),inv(9)(p11q13). The abnormal karyotype is recognised as a possible reason of fertility problems in the investigated couple. The risk of further miscarriages is considered high, but the risk of progeny with abnormal karyotypes is rather low, as small inversions may lead to lethal recombinants.     

A de novo unbalanced reciprocal translocation identified as paternal in origin in the Prader-Willi syndrome

Summary Interstitial cytogenetic deletions involving the paternally derived chromosome 15q11–13 have been described in patients with the Prader-Willi syndrome (PWS). We report a child with PWS and a de novo unbalanced karyotype –45,XY,–9,–15,+der(9)t(9;15)(q34;q13). Molecular studies with the DNA probe pML34 confirmed that only a single Prader Willi critical region (PWCR: 15q11.2-q12) copy was present. Hybridisation of patient and parental DNA with the multi-allelic probe CMW1, which maps to pter-15q13, showed that the chromosome involved in the translocation was paternal in origin. This is the first example of a paternally-derived PWCR allele loss caused by an unbalanced translocation that has arisen de novo.     

Methylation-specific multiplex ligation-dependent probe amplification analysis of subjects with chromosome 15 abnormalities

Prader-Willi syndrome (PWS) and Angelman syndrome (AS) are neurodevelopmental disorders caused by loss of expression of imprinted genes from the 15q11-q13 region. They arise from similar defects in the region but differ in parent of origin. There are two recognized typical 15q11-q13 deletions depending on size and several diagnostic assays are available but each has limitations. We evaluated the usefulness of a methylation-specific multiplex ligation-dependent probe amplification (MLPA) kit consisting of 43 probes to detect copy number changes and methylation status in the region. We used the MLPA kit to genotype 82 subjects with chromosome 15 abnormalities (62 PWS, 10 AS and 10 individuals with other chromosome 15 abnormalities) and 13 with normal cytogenetic findings. We developed an algorithm for MLPA probe analysis which correctly identified methylation abnormalities associated with PWS and AS and accurately determined copy number in previously assigned genetic subtypes including microdeletions of the imprinting center. Furthermore, MLPA analysis identified copy number changes in those with distal 15q deletions and ring 15s. MLPA is a relatively simple, cost-effective technique found to be useful and accurate for methylation status, copy number and analysis of genetic subtype in PWS and AS, as well as other chromosome 15 abnormalities.     

Chromosome 15 abnormalities and the Prader-Willi syndrome: a follow-up report of 40 cases.

High-resolution chromosome analysis and multiple banding techniques were performed on blood samples from 40 patients with Prader-Willi syndrome (PWS) as a follow-up to our recent report in which we found interstitial deletions of 15q in four of five patients with this syndrome. Of the 40 new patients, 19 had interstitial del(15q), one had an apparently balanced 15;15 translocation, and one was mos46,XX/47,XX+idic(15) (pter leads to q11::q11 leads to pter). These data confirm our previous report and demonstrate that half of all patients with the clinical diagnosis of PWS have chromosome abnormalities involving chromosome 15 detectable by high-resolution methods. Although the majority of these involve a specific deletion of bands 15q11-q12, other alterations of chromosome 15 may be present.     

Localization of the gene encoding the GABAA receptor β3 subunit to the Angelman/Prader-Willi region of human chromosome 15

Deletions of the proximal long arm of chromosome 15 (bands 15q11q13) are found in the majority of patients with two distinct genetic disorders, Angelman syndrome (AS) and Prader-Willi syndrome (PWS). The deleted regions in the two syndromes, defined cytogenetically and by using cloned DNA probes, are similar. However, deletions in AS occur on the maternally inherited chromosome 15, and deletions in PWS occur on the paternally derived chromosome 15. This observation has led to the suggestion that one or more genes in this region show differential expression dependent on parental origin (genetic imprinting). No genes of known function have previously been mapped to this region. We show here that the gene encoding the GABAA (gamma-aminobutyric acid) receptor beta 3 subunit maps to the AS/PWS region. Deletion of this gene (GABRB3) was found in AS and PWS patients with interstitial cytogenetic deletions. Evidence of beta 3 gene deletion was also found in an AS patient with an unbalanced 13;15 translocation but not in a PWS patient with an unbalanced 9;15 translocation. The localization of this receptor gene to the AS/PWS region suggests a possible role of the inhibitory neurotransmitter GABA in the pathogenesis of one or both of these syndromes.     

Unbalanced reciprocal translocations in cases of Prader-Willi syndrome

Summary A case of Prader-Willi syndrome (PWS) associated with a de novo unbalanced 15q;17q reciprocal translocation presumptively resulting from the tertiary monosomic form of 3:1 meiotic disjunction is described. Twenty-three similar unbalanced translocations have been identified from the literature. The 24 karyotypes are characterised by having 45 chromosomes, monosomy for the pericentromeric region of chromosome 15 (range pter»q11 to q21), and little monosomy of the recipient (non-15) chromosome. Two-thirds of the cases with these karyotypes have phenotypic features of PWS. It seems probable that (i) where unbalanced reciprocal translocations are associated with PWS, they will almost invariably be presumptive segregants of the tertiary monosomic form of 3:1 disjunction and (ii) the majority of cases found with this type of karyotype, particularly it appears when de novo in origin, will be associated with phenotypic features of PWS.     

DNA diagnosis of Prader-Willi and Angelman syndromes with the probe PW71 (D15S63)

Previously, 158 nuclear families with probands suspected of having either Prader Willi (PWS) or Angelman syndrome (AS) were analyzed with polymorphic DNA markers from the 15q11–13 region. These cases have been re-evaluated with the probe PW71 (D15S63), which detects parent-of-origin-specific alleles after digestion with a methylation-sensitive restriction enzyme (HpaII). Application of PW71 to DNA samples isolated from leucocytes, confirmed the deletions and uniparental disomies detected earlier by marker analysis, and resolved 50% of the previously uninformative (n=18) cases. PW71 and restriction fragment length polymorphism analysis indicated that, in all resolved cases, disomies of the 15q11–13 region were present. The use of PW71 increased the percentage of disomies detected in our PWS and AS patient groups. Almost 50% of our PWS patients and 17% of the AS patients showed a disomy of maternal or paternal origin, respectively. DNA of first trimester chorionic villi and of fibroblast cultures was not suitable for analysis with PW71 because of different methylation patterns. The application of PW71 is recommended for the diagnosis of the PWS and AS, with respect to DNA samples from blood.