Parental origin and mechanisms of formation of triploidy: a study of 25 cases

Triploidy is one of the most frequently observed chromosome abnormalities in spontaneous abortions in humans. The parental origin of the additional chromosome set is known to have a major impact on the phenotype of the foetuses and to result in differences in size and structure of the placenta. Early studies based on cytogenetic polymorphisms indicated a preponderant diandric origin of the triploidies; such detection method, however, is known to be prone to error. Other studies revealed a predominant digynic origin in cases with longer intrauterine survival. It is now thought that, to some extent, a detection bias in favour of cases with associated partial hydatidiform moles may account for the high incidences of diandric cases reported in some studies. Furthermore, depending on the gestational age of the cases analysed there may indeed be differences in the proportion of diandric and digynic triploidies. We investigated the parental origin and mechanisms of formation of triploidy in a group of 25 probands with gestational ages ranging from 8 to 37 weeks. DNA samples were extracted from foetal material and from blood samples of the parents, and were analysed using microsatellite markers. The parental origin of the triploidies was found to be maternal in 20 cases and paternal in 5. Regarding the digynic cases, an error at meiosis I was inferred in 10 cases, whereas in the other half an error occurred at meiosis II. All five diandric cases included in this study were found to be due to dispermy. No significant differences in the average maternal ages were found amongst the different subgroups of patients.

Wolf-Hirschhorn syndrome due to a 3:1 segregation of a maternal balanced t(4;15)(p16.3;q11) translocation

The Wolf-Hirschhorn syndrome (WHS) is characterized by severe pre- and postnatal growth retardation, specific pattern of dysmorphisms, and severe developmental delay. These clinical findings are the result of a deletion within the short arm of chromosome 4. Most cases occur de novo and are of paternal origin. Cases due to a balanced translocation are mostly of maternal origin and the deletion of distal 4p, including the WHS critical region, is often combined with a duplication of the other chromosomal segment involved in the rearrangement. Here, we report on a newborn female infant with WHS and pure tertiary monosomy due to a 3:1 segregation of a balanced maternal 4;15 translocation. In this context, importance of fluorescence in situ hybridization (FISH) with specific probes to determine the exact breakpoints in unbalanced chromosomal rearrangements with breakpoints localized around known microdeletion syndromes is emphasized.

Parental origin and mechanisms of formation of cytogenetically recognisable de novo direct and inverted duplications

Cytogenetic, FISH, and molecular results of 20 cases with de novo tandem duplications of 18 different autosomal chromosome segments are reported. There were 12 cases with direct duplications, three cases with inverted duplications, and five in whom determination of direction was not possible. In seven cases a rearrangement between non-sister chromatids (N-SCR) was found, whereas in the remaining 13 cases sister chromatids (SCR) were involved. Paternal and maternal origin (7:7) was found almost equally in cases with SCR (3:4) and N-SCR (4:3). In the cases with proven inversion, there was maternal and paternal origin in one case each. Twenty three out of 43 cytogenetically determined breakpoints correlated with common or rare fragile sites. In five cases, including all those with proven inverse orientation, all breakpoints corresponded to common or rare fragile sites. In at least two cases, one with an interstitial duplication (dup(19)(q11q13)) and one with a terminal duplication (dup(8) (p10p23)), concomitant deletions (del(8) (p23p23.3) and del(19)(q13q13)) were found.

Penoscrotal hypospadias and coarctation of the aorta with mixed gonadal dysgenesis

A 45,X/46,Xidic(Y)(q11.2) mosaicism was found in a 4-year-old boy. The clinical appearance was characterized by bilateral cryptorchidism, penoscrotal hypospadias, short penis, and coarctation of the aorta. The latter is the only abnormality also seen in Turner syndrome. A biopsy of the gonads revealed normal prepubertal testicular tissue. A chromosome analysis in all boys with penoscrotal, scrotal, or perineal hypospadias and a thorough examination of the heart in children with 45,X/46,XY mosaicism are recommended.

Recombinant balanced and unbalanced translocations as a consequence of a balanced complex chromosomal rearrangement involving eight breakpoints in four chromosomes

We report on a family with a balanced complex chromosomal rearrangement (CCR) involving eight breakpoints between chromosomes 6, 7, 18, and 21 in the father. All three sons inherited one derivative chromosome from the father and in addition each inherited a different recombinant chromosome resulting in a partial trisomy 6q in the first, an apparently balanced karyotype in the second, and a partial trisomy 7q in the third son. Fluorescence in situ hybridisation (FISH) and microsatellite analysis were essential for the identification of the breakpoints. In addition, the results were confirmed by a 24-colour FISH experiment using the spectral karyotyping (SKYtrade mark) system. Paternal origin of the de novo CCR in the father was demonstrated for the first time by haplotype analysis. This is the second report of a CCR leading to simpler but unbalanced translocations in offspring as a consequence of recombination during gametogenesis, and the first report of a family case of CCR exhibiting as many as eight breakpoints in the transmitting carrier. The initial prediction that viable offspring would be quite unlikely had to be revised after the birth of three children. Genetic counselling of carriers of balanced complex rearrangements has to consider a higher probability for unbalanced recombinations than has been so far commonly assumed.

A 5-year-old girl with interstitial deletion of 3p14: clinical, psychologic, cytogenetic, and molecular studies

An interstitial deletion of segment 3p14 (breakpoints 3p21.1 and 3p13) was found in a 5-year-old short, microcephalic, and mentally retarded girl with a pattern of anomalies comprising a wide forehead, short up-slanting palpebral fissures, small nose and ears, hypoplasia of larynx, trachea, and bronchi, clino- and camptodactyly of little fingers, and sacral vertebral fusion. Determination of microsatellites mapping to the deleted segment demonstrated that the deletion had occurred in the paternal germ line. This is the seventh patient with a deletion of 3p14, and comparison with the six previously reported cases does not yet allow definition of a specific pattern of minor and major anomalies.

Isochromosomes 12p and 9p: parental origin and possible mechanisms of formation

In a recent study Bugge et al and Kotzot et al reported that isochromosomes 18p originate mainly from maternal meiosis II nondisjunction, followed by misdivision. In order to determine if there is a common mechanism for isochromosome formation, three cases with mosaicism for an additional isochromosome 12p and three cases with tetrasomy 9p were studied. Two probands with isochromosomes 12p and the three cases with isochromosome 9p showed 3 alleles (two different maternal alleles and one paternal allele) at several loci mapping to distal 12p and 9p, respectively. Maternal heterozygosity for distal markers was reduced to homozygosity for markers closer to the centromere in both i(12p) cases and in one i(9p) case. For one patient with isochromosome 12p, the maternal band was clearly stronger than the paternal one at some loci, but two distinct maternal alleles were never seen. For one foetus and the patient with tetrasomy 9p, distal markers showed maternal heterozygosity. All proximal markers were not informative in these two i(9p) cases. Our findings indicate common features in different autosomal isochromosomes: the origin of the isochromosomes analysed in predominantly maternal; and a common mechanism appears to underlie their formation, namely due to meiosis II nondisjunction followed by a rearrangements leading to duplication of the short and loss of the long arm.

Multiple congenital anomalies including the Rieger eye malformation in a boy with interstitial deletion of (4) (q25-->q27) secondary to a balanced insertion in his normal father: evidence for haplotype insufficiency causing the Rieger malformation

A 7 year old boy with minor facial anomalies, the Rieger eye malformation, reduced vision, genital anomalies, and severe mental retardation had deletion of the segment 4q24-->q26. His phenotypically normal father had a balanced insertion of that segment into the distal long arm of chromosome 6: 46,XY,ins(6;4)(q26;q24q26). Microsatellite loci flanking the RIEG gene on 4q25 were deleted giving indirect evidence of deletion of this locus. This finding and the normal ocular findings in the insertion carrier father show that haplotype insufficiency can cause the Rieger eye malformation.

Trisomy first, translocation second, uniparental disomy and partial trisomy third: a new mechanism for complex chromosomal aneuploidy

A 2-year-old, short, microcephalic and developmentally retarded boy revealed a pattern of multiple minor anomalies, hypospadias and a dysplastic right kidney. Maternal age at delivery was 41 years. His karyotype showed two cell lines, one apparently normal, the other with a 1p+ chromosome. FISH examinations showed that the segment attached to 1p was from chromosome 16, and molecular investigations disclosed maternal heterodisomy 16, except for the segment (16)(pter-->p13.1) for which there was mosaicism between trisomy and uniparental disomy (UPD). Most likely, the zygote was trisomic for chromosome 16 due to a maternal meiosis I nondisjunction; a somatic rearrangement would have then occurred at an early postzygotic stage whereby a segment of the paternal chromosome 16 was translocated onto 1p. Subsequently, the paternal chromosomes 16 and 16p- had been lost in the normal and the translocation cell line, respectively. The chromosome aberration was detected secondary to the disclosure of maternal UPD 16 because of the demonstration of a paternal band at several loci on distal 16p. This case shows that chromosome aberrations may be formed in a more complicated manner than primarily assumed. Hence, the phenotype might also be due to underlying factors such as UPD or undetected mosaicism in addition to the more obvious implications of the chromosome rearrangement itself (e.g. partial trisomy).

Interstitial deletion, del(4)(q12q21.1), owing to de novo unbalanced translocation in a 2 year old girl: further evidence that the piebald trait maps to proximal 4q12

A very short, microcephalic, and mentally retarded 2 year old girl showed minor anomalies including prominent occiput, delayed closure of the anterior fontanelle, high frontal hairline, prominent ears, upward slanting palpebral fissures, a small nose with bulbous tip, delayed tooth eruption and bone maturation, and short and tapering fingers and toes. She did not have a white forelock. Cytogenetic investigation disclosed a de novo unbalanced translocation between chromosomes 4 and 18 with deletion of 4q12-->q21.1. Molecular investigation showed lack of a paternal allele for the microsatellite markers D4S392 and D4S398. This case shows indirect evidence that the piebald gene maps to proximal 4q12.

Serum parameters and nuchal translucency in first trimester screening for fetal chromosomal abnormalities

OBJECTIVE

To assess the relation between serum parameters and nuchal translucency in pregnancies affected by fetal aneuploidy in the first trimester.

DESIGN

Retrospective study of different serum parameters collected prior to chorionic villus sampling and measurement of nuchal translucency in relation to fetal aneuploidy.

SETTING

Switzerland (German and Italian sector) and Bregenz, Austria.

POPULATION

One thousand one hundred and fifty-one women aged 25 to 44 years at 10 to 13 weeks of gestation undergoing chorionic villus sampling, mostly for advanced maternal age. Fetal aneuploidy was found in 23 pregnancies including four cases of trisomy 21, five of trisomy 18 and one case of trisomy 13.

MAIN OUTCOME MEASURE

Fetal karyotype, serum levels of free beta-hCG, pregnancy-associated plasma protein A (PAPP-A) and alpha-fetoprotein and the measurement of nuchal translucency.

RESULTS

Serum PAPP-A was decreased in all common chromosomal abnormalities. Free beta-hCG levels were increased in trisomy 21 but decreased in trisomy 18, whereas alpha-fetoprotein was low in trisomy 21, 18 and other chromosomal abnormalities. Nine of twenty-three abnormal embryos had evidence of an increased nuchal translucency. Nuchal translucency, however, did not seem to be associated with any alteration in the levels of the biochemical parameters in either chromosomally normal or abnormal embryos. A low serum PAPP-A or an increased nuchal translucency was seen in two-thirds of all pregnancies with chromosomal abnormalities.

CONCLUSION

A nuchal translucency > or = 3 mm and depressed serum PAPP-A levels have a good predictive value in the detection of fetal aneuploidy at 10 to 13 weeks of pregnancy. Serum free beta-hCG and alpha-fetoprotein levels may give additional information. An increased nuchal translucency was not associated with altered serum parameters. This would allow these different markers to be used in combination.

Molecular studies of translocations and trisomy involving chromosome 13

Twenty-four cases of trisomy 13 and one case with disomy 13, but a de novo dic(13,13) (p12p12) chromosome, were examined with molecular markers to determine the origin of the extra (or rearranged) chromosome. Twenty-one of 23 informative patients were consistent with a maternal origin of the extra chromosome. Lack of a third allele at any locus in both paternal origin cases indicate a somatic duplication of the paternal chromosome occurred. Five cases had translocation trisomy: one de novo rob(13q14q), one paternally derived rob(13q14q), two de novo t(13q13q), and one mosaic de novo t(13q13q)/r(13). The patient with a paternal rob(13q14q) had a maternal meiotic origin of the trisomy; thus, the paternal inheritance of the translocation chromosome was purely coincidental. Since there is not a significantly increased risk for unbalanced offspring of a t(13q14q) carrier and most trisomies are maternal in origin, this result should not be surprising; however, it illustrates that one cannot infer the origin of translocation trisomy based on parental origin of the translocation. Lack of a third allele at any locus in one of the three t(13q13q) cases indicates that it was most likely an isochromosome of postmeiotic origin, whereas the other two cases showed evidence of recombination. One balanced (nontrisomic) case with a nonmosaic 45, -13, -13, +t(13;13) karyotype was also investigated and was determined to be a somatic Robertsonian translocation between the maternal and paternal homologues, as has been found for all balanced homologous Robertsonian translocations so far investigated. Thus, it is also incorrect to assume in de novo translocation cases that the two involved chromosomes are even from the same parent. Despite a maternal origin of the trisomy, we cannot therefore infer anything about the parental origin of the chromosomes 13 and 14 involved in the translocation in the de novo t(13q14q) case nor for the two t(13;13) chromosomes showing a meiotic origin of the trisomy.

Kallmann syndrome in a boy with a t(1;10) translocation detected by reverse chromosome painting

Prometaphase chromosomes from a 16 year old boy with hypogonadotrophic hypogonadism and anosmia (Kallmann syndrome) showed a tiny chromosome fragment attached to the long arm of one chromosome 1 without a visible reciprocal translocation chromosome. Chromosome painting with libraries from chromosomes 1 and X excluded a t(X;1) translocation, but failed to detect a second translocation chromosome. Through reverse chromosome painting, an unbalanced der(1), t(1;10) (q44;q26) translocation could be detected. This is the third case of Kallmann syndrome with a de novo rearrangement between two autosomes. The distal long arm of chromosome 1 may contain a candidate locus for a gene, mutations of which may cause the Kallmann phenotype; a 10q location seems less likely.

[Trisomy-21 screening using AFPplus in the eastern part of Switzerland]

Two years after introduction of maternal serum screening for Down's syndrome in German-speaking Switzerland, based on measurements of alpha-fetoprotein, unconjugated estriol and total beta-HCG, results were analyzed of the two cytogenetic laboratories in Zurich and of a separate collective of the Department of Obstetrics at the University of Zurich. In a total of 489 cases with increased risk for Down's syndrome (> or = 1:380 at term) 19 (1:26; approximately 4%) had an abnormal fetal karyotype from which 16 had a trisomy 21. 13 out of these 16 mothers were aged below 35 years. Thus, after ultrasound, maternal serum screening detects the highest percentage of fetuses with chromosomal abnormalities. At the Department of Obstetrics 2962 serum screening tests were performed during a period of 2 1/2 years. 14.6% of the women were > or = 35 years old, 7.6% showed increased risk and 14 fetuses had an abnormal karyotype including 10 with Down's syndrome. 7 of these 10 were detected by the serum test. Nevertheless, the limited sensitivity of serum screening, its limitation predominantly to detection of fetuses with Down's syndrome and the rather late stage of screening, make effective first trimester screening mandatory.

Molecular studies of chromosomal mosaicism: relative frequency of chromosome gain or loss and possible role of cell selection

Studies of uniparental disomy and origin of nonmosaic trisomies indicate that both gain and loss of a chromosome can occur after fertilization. It is therefore of interest to determine both the relative frequency with which gain or loss can contribute to chromosomal mosaicism and whether these frequencies are influenced by selective factors. Thirty-two mosaic cases were examined with molecular markers, to try to determine which was the primary and which was the secondary cell line: 16 cases of disomy/trisomy mosaicism (5 trisomy 8, 2 trisomy 13, 1 trisomy 18, 4 trisomy 21, and 4 involving the X chromosome), 14 cases of 45,X/46,XX, and 2 cases of 45,X/47,XXX. Of the 14 cases of mosaic 45,X/46,XX, chromosome loss from a normal disomic fertilization predominated, supporting the hypothesis that 45,X might be compatible with survival only when the 45,X cell line arises relatively late in development. Most cases of disomy/trisomy mosaicism involving chromosomes 13, 18, 21, and X were also frequently associated with somatic loss of one (or more) chromosome, in these cases from a trisomic fertilization. By contrast, four of the five trisomy 8 cases were consistent with a somatic gain of a chromosome 8 during development from a normal zygote. It is possible that survival of trisomy 8 is also much more likely when the aneuploid cell line arises relatively late in development.

Trisomy 17p11-pter: unbalanced pericentric inversion, inv(17)(p11q25) in two patients, unbalanced translocations t(4;17)(q27;p11) in a newborn and t(4;17) (p16;p11.2) in a fetus

Three patients and one fetus with almost complete trisomy 17p due to familial rearrangements are described. Two patients followed unbalanced transmission of a familial pericentric inversion, and one patient and one fetus were due to unbalanced segregation of familial translocations. In the inversion family, another two patients with multiple malformations had died before chromosome examination could be performed. The pattern of congenital anomalies as revealed from eleven cases of trisomy 17p11-pter include as the most prominent features: prenatal growth retardation, microcephaly, downslanting palpebral fissures, small mouth, small mandible, poorly shaped ears, short and webbed neck, genital hypoplasia, clinodactyly of fingers, crowding of toes, a high incidence of congenital heart defects and hernias. Postnatal survival is short mainly in patients with congenital heart defects. From the age of about 6 years onward, clinical findings become more distinct, with some signs of Charcot-Marie-Tooth neuropathy (pes cavus, adducted thumbs, dorsiflexed hallux, camptodactyly and limitation of movements in different joints), and the nose gets narrow and sharp, with hypoplastic alae.

Intrachromosomal triplication of 15q11-q13

A 7 year old girl with intrachromosomal triplication 46,XX,-15,+der(15)(pter-->q13::q13-->q11::q11-->qter) resulting in tetrasomy of 15q11-q13 is reported. Fluorescence in situ hybridisation confirmed that the tetrasomic region included the entire segment normally deleted in Prader-Willi and Angelman syndrome patients, and breakpoints were similar to those reported in two tandem duplications of 15q11-q13. The middle repeat was inverted, suggesting a possible origin through an inverted duplication intermediate. Microsatellite analysis showed that the rearrangement was of maternal origin and involved both maternal homologues. Clinical findings included multiple minor anomalies (a fistula over the glabella, epicanthic folds, downward slanting palpebral fissures, ptosis of the upper lids, strabismus, a broad and bulbous tip of the nose, and small hands and feet), motor and mental retardation, a seizure disorder, and limited verbal abilities. In addition, immunological examination disclosed a selective immunodeficiency. The overall phenotype did not clearly resemble that of cases with tetrasomy 15pter-q13 associated with an extra inv dup(15)(pter-->q13:q13-->pter) chromosome. The latter aberration causes more severe mental deficit and intractable seizures, but less marked phenotypic alterations, although some overlap in mild facial dysmorphic features is present. A number of features common to Angelman syndrome were also observed in the patient.

Multiple origins of X chromosome tetrasomy

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Biparental inheritance of chromosome 21 polymorphic markers indicates that some Robertsonian translocations t(21;21) occur postzygotically

Robertsonian translocations between acrocentric chromosomes are the most common structural chromosomal rearrangements in humans and many other organisms, and several mechanisms for their formation have been proposed. We have analyzed highly informative DNA polymorphisms in a family with a non-mosaic de novo Robertsonian translocation 21q;21q, to determine the parental origin of the two 21q arms of the rearranged chromosome. The genotypes indicated a biparental origin, i.e. one 21q was paternal and the other maternal. These results imply that in some cases the formation of the rob(21q;21q) occurs in the zygote or in the first few postzygotic mitotic divisions.

An interstitial deletion of proximal 8q (q11-q13) in a girl with Silver-Russell syndrome-like features

Silver-Russell syndrome (SRS) is characterized by pre- and postnatal growth retardation, a fine, triangular face, a high frontal hairline and prominent forehead, clinodactyly of the fifth fingers, and sometimes asymmetry of face, trunk and extremities. In a 10-year-old girl referred for SRS, cytogenetic examination disclosed a microdeletion of band 8q12. Dosage analysis of Southern blots hybridized to 8q markers revealed a deletion of three loci: MOS, D8S96 and D8S108, all mapping to 8q11-q12, however the deletion did not include PLAT (8q12-q11). PCR analysis of the D8S166 microsatellite (8q11-q12) showed the lack of paternal inheritance, indicating that the deletion occurred in the paternal chromosome. The patient showed prenatal and postnatal growth retardation, mild developmental delay, microcephaly, a triangular face with high frontal hairline, shallow supraorbital ridges, hypoplastic alae nasi, small and prominent ears, prominent lateral palatine ridges, clinodactyly and brachymesophalangy of the fifth fingers. There were normal female genitalia and no asymmetry or detectable malformations. Screening of 19 other patients with the SRS for a similar cytogenetic and/or molecular deletion at 8q12 and for uniparental disomy 8 was negative. However, 8q12 still remains as one potential locus for a gene whose mutations may cause the clinical findings of SRS and which could be included in a larger deletion in a proband who has additional mild mental retardation.

Exclusively paternal X chromosomes in a girl with short stature

A 13 1/2 year-old girl with short stature and very few Turner stigmata revealed 45,X/46,XX mosaicism with 90%-100% 46,XX cells in three sequential blood lymphocyte cultures. Molecular investigation of the parental origin of her X chromosomes revealed homozygosity for paternal X markers and an absence of maternal markers. Luteinizing hormone response to growth hormone releasing hormone was increased. Impaired gonadal function and shortness of stature in this case could be a result of the mild mosaicism with a 45,X cell line and/or is a consequence of the paternal-only origin of her X chromosomes.

Parental origin of the supernumerary chromosome in trisomy 18

The parental origin of an extra chromosome in Edwards syndrome has been investigated in 23 families by the combination of the VNTR probe pERT25, two microsatellite polymorphisms for D18S34 and D18S40, and several two-allele polymorphisms. Of the 23 cases, 22 were informative, with 17 (77%) being maternal and 5 (23%) paternal in origin. These results support the previous investigations, suggesting that trisomy 18 is predominantly of maternal origin, although a higher rate of paternally derived cases was observed than previously reported. A significant increase in maternal age was found to be associated with meiotic nondisjunction. Parental age was increased in both the maternally and paternally derived cases, but the size of the latter class was small and did not reach statistical significance.

Unbalanced translocation, t(18;21), detected by fluorescence in situ hybridization (FISH) in a child with 18q- syndrome and a ring chromosome 21

We report on an 8-year-old girl with minor anomalies consistent with 18q- syndrome and mild developmental delay. Initially cytogenetics showed a terminal deletion of chromosome 21 with mosaicism for a small ring chromosome 21 as the only apparent karyotypic abnormality: mos 45,XX,-21/46,XX,+r(21) (48%/52%). Further studies including FISH and DNA analysis demonstrated a de novo unbalanced translocation of chromosomes 18 and 21 with the likely breakpoints in 18q23 and 21q21.1. Most of 21q was translocated to the distal long arm of one chromosome 18, and this derivative 18 appeared to lack 18q23-qter. The small ring chromosome 21 [r(21)], present in only 52% of the patient's blood lymphocytes, did not appear to be associated with the abnormal phenotype since all 13 chromosome 21 markers that were examined in genomic DNA were present in 2 copies, and the phenotype of the patient was consistent with the 18q- syndrome. The karyotype was reinterpreted as mos 45,XX,-18,-21,+der(18) t(18;21) (q23;q21.1)/46,XX,-18,-21,+der(18) t(18;21) (q23;q21.1), +r(21) (p13q21.1) (48%/52%). These results demonstrate the power of FISH in conjunction with DNA analysis for examination of chromosome rearrangements that may be misclassified by traditional cytogenetic studies alone.

Ultrasound screening for chromosomal anomalies in the first trimester of pregnancy

For the last 6 years, sonographic signs for excessive fluid accumulation in the backs of 10- to 12-week-old fetuses have been looked for prior to transabdominal chorionic biopsy. In 1400 pregnancies, subsequent karyotype analyses revealed 28 cases of Down syndrome. In 15 (= 54 per cent), a large fluid cushion over most of the back had been documented at the time of biopsy. Only a few chromosomally normal fetuses with the same peculiarity were observed. The cushion was also present in fetuses with trisomies 18 and 13, and in Turner syndrome. Systematic first-trimester screening for nuchal fluid accumulation seems to be a recommended method for the detection of Down syndrome and other chromosome anomalies in young pregnant women at low risk. It compares favourably with current methods of maternal serum screening performed at 16-18 weeks which require a higher number of invasive procedures.

Clinical and molecular analysis of five inv dup(15) patients

Five patients with inv dup(15) chromosomes were investigated with molecular probes on proximal 15q to determine the parental origin and extent of the duplicated segment. Cytogenetic investigation showed that four patients carried one and a fifth patient had two extra chromosomes derived from number 15 in all cells. In situ hybridization with a chromosome 15 library and a centromere 15 probe confirmed that the entire inv dup chromosomes were derived from chromosome 15. Molecular analysis using probes mapping in the region deleted in Prader-Willi syndrome (PWS) and Angelman syndrome (AS) patients implied that in at least two patients the extra chromosomes were asymmetric with one copy of the PWS region on the extra marker chromosome but two copies of the region centromeric to the PWS region. Three other cases had an inv dup(15) with two extra copies of the PWS region, but in one of these, heteromorphisms clearly demonstrated that the two centromeres derived from two different chromosomes. The inv dup(15) presumably resulted from an illegitimate recombination event between two different chromosomes 15 in most or all of these cases. All patients showed a maternal origin of the duplicated chromosome. The clinical severity appears to be associated with dosage of the PWS/AS region rather than with differences in the extent of the duplicated segment.

Reduced recombination and paternal age effect in Klinefelter syndrome

The parental origin of the additional sex chromosome was studied in 47 cases with an XXY sex chromosome constitution. In 23 cases (49%), the error occurred during the first paternal meiotic division. Maternal origin of the additional chromosome was found in the remaining 24 cases (51%). Centromeric homo- versus heterozygosity could be determined in 18 out of the 24 maternally derived cases. According to the centromeric status and recombination rate, the nondisjunction was attributable in 9 cases (50%) to an error at the first maternal meiotic division, in 7 cases (39%) to an error at the second maternal meiotic division and in 2 cases (11%) to a nullo-chiasmata nondisjunction at meiosis II or to postzygotic mitotic error. No recombination, and in particular none in the pericentromeric region, was found in any of the 9 cases due to nondisjunction at the first maternal meiotic division. Significantly increased paternal age was found in the paternally derived cases. Maternal age was significantly higher in the maternally derived cases due to a meiotic I error compared with those due to a meiotic II error. There were no significant clinical differences between patients with respect to the origin of the additional X chromosome.

Molecular study of 45,X conceptuses: correlation with clinical findings

The parental origin of the single X in 45 cases (40 liveborns and 5 fetuses) with a 45,X karyotype was studied using polymorphic DNA probes. The single X was paternal in origin (Xp) in 10 cases (22.2%) and maternal (Xm) in 35 cases (77.8%). Y chromosome material was detected in 1 out of the 35 cases with a 45,Xm constitution. Analysis of parental ages and clinical data of the patients with respect to the origin of the single X revealed no significant differences between the origins.

The meiotic stage of nondisjunction in trisomy 21: determination by using DNA polymorphisms

We have studied DNA polymorphisms at loci in the pericentromeric region on the long arm of chromosome 21 in 200 families with trisomy 21, in order to determine the meiotic origin of nondisjunction. Maintenance of heterozygosity for parental markers in the individual with trisomy 21 was interpreted as resulting from a meiosis I error, while reduction to homozygosity was attributed to a meiosis II error. Nondisjunction was paternal in 9 cases and was maternal in 188 cases, as reported earlier. Among the 188 maternal cases, nondisjunction occurred in meiosis I in 128 cases and in meiosis II in 38 cases; in 22 cases the DNA markers used were uninformative. Therefore meiosis I was responsible for 77.1% and meiosis II for 22.9% of maternal nondisjunction. Among the 9 paternal nondisjunction cases the error occurred in meiosis I in 2 cases (22.2%) and in meiosis II in 7 (77.8%) cases. Since there was no significant difference in the distribution of maternal ages between maternal I error versus maternal II error, it is unlikely that an error at a particular of maternal ages between maternal I error versus maternal II error, it is unlikely that an error at a particular meiotic stage contributes significantly to the increasing incidence of Down syndrome with advancing maternal age. Although the DNA polymorphisms used were at loci which map close to the centromere, it is likely that rare errors in meiotic-origin assignments may have occurred because of a small number of crossovers between the markers and the centromere.(ABSTRACT TRUNCATED AT 250 WORDS)

No evidence for a paternal interchromosomal effect from analysis of the origin of nondisjunction in Down syndrome patients with concomitant familial chromosome rearrangements

The parental origin of the extra chromosome 21 was determined with DNA polymorphisms in seven families in whom the proband and one of the parents carried an additional chromosome rearrangement (balanced translocation or pericentric inversion) not involving chromosome 21. The balanced rearrangement was inherited from the mother in two families and from the father in five families, whereas the additional chromosome 21 was derived from the mother in all seven families. These findings are not in agreement with the hypothesis of a paternal interchromosomal effect. The latter would imply that a balanced rearrangement in the father would favor nondisjunction during meiosis in the germ cells.

Uniparental origin of sex chromosome polysomies

The parental origin of the additional sex chromosomes in 8 cases with high-order sex chromosome polysomies was determined using DNA polymorphisms. The additional sex chromosomes were paternally derived in 3 48,XXYY cases, and maternal in origin in 1 48,XXXY case and 4 49,XXXXY cases. Thus, all extra chromosomes, within a particular patient, were always derived from only one parent. Their most likely origin was successive nondisjunction at the first and second meiotic division in one germ cell. The mechanism involved remains unclear, but appears to be independent of parental ages.

Molecular, cytogenetic, and clinical investigations of Prader-Willi syndrome patients

Thirty-seven patients presenting features of the Prader-Willi syndrome (PWS) have been examined using cytogenetic and molecular techniques. Clinical evaluation showed that 29 of these patients fulfilled diagnostic criteria for PWS. A deletion of the 15q11.2-q12 region could be identified molecularly in 21 of these cases, including several cases where the cytogenetics results were inconclusive. One clinically typical patient is deleted at only two of five loci normally included in a PWS deletion. A patient carrying a de novo 13;X translocation was not deleted for the molecular markers tested but was clinically considered to be "atypical" PWS. In addition, five cases of maternal heterodisomy and two of isodisomy for 15q11-q13 were observed. All of the eight patients who did not fulfill clinical diagnosis of PWS showed normal maternal and paternal inheritance of chromosome 15 markers; however, one of these carried a ring-15 chromosome. A comparison of clinical features between deletion patients and disomy patients shows no significant differences between the two groups. The parental ages at birth of disomic patients were significantly higher than those for deletion patients. As all typical PWS cases showed either a deletion or disomy of 15q11.2-q12, molecular examination should provide a reliable diagnostic tool. As the disomy patients do not show either any additional or more severe features than typical deletion patients do, it is likely that there is only one imprinted region on chromosome 15 (within 15q11.2-q12).

A molecular study of X isochromosomes: parental origin, centromeric structure, and mechanisms of formation

Fourteen individuals with an i(Xq) or idic(Xq) were studied using RFLP analysis in order to determine both parental origin and extent of heterozygosity of the isochromosome and to search for the presence of short-arm material. In five cases the isochromosome was paternally derived, while nine patients had a maternal i(Xq). The analysis of heterozygosity of the nine maternally derived isochromosomes by using Xq markers showed heterozygosity in two cases, suggesting an origin from two homologous X chromosomes. Homozygosity was found at all informative loci in seven cases, which therefore are probably the product of either centromere misdivision or sister-chromatid exchange. Presence of Xp markers was seen both in the three i(Xq) chromosomes which appeared dicentric by cytogenetic analysis and in three additional cytogenetically monocentric cases. Mean parental ages were greater for the maternally derived cases as compared with the paternally derived cases.

A case of Hirschsprung disease with a chromosome 13 microdeletion, del(13)(q32.3q33.2): potential mapping of one disease locus

A mentally retarded boy with discrete physical findings, Hirschsprung disease (HD) and a microdeletion of 13q,del(13)(q32.3q33.2) is described. Band 13q33.1 was consistently missing in all cells. There have been, to date, 4 published cases of deletions involving the long arm of chromosome 13 associated with HD: the interstitial deletion reported here is much smaller than, and it partially overlaps with, the previously reported deletions; it could be helpful for mapping one of the genes involved in this disease.

Down syndrome due to de novo Robertsonian translocation t(14q;21q): DNA polymorphism analysis suggests that the origin of the extra 21q is maternal

Down syndrome is rarely due to a de novo Robertsonian translocation t(14q;21q). DNA polymorphisms in eight families with Down syndrome due to de novo t(14q;21q) demonstrated maternal origin of the extra chromosome 21q in all cases. In seven nonmosaic cases the DNA markers showed crossing-over between two maternal chromosomes 21, and in one mosaic case no crossing-over was observed (this case was probably due to an early postzygotic nondisjunction). In the majority of cases (five of six informative families) the proximal marker D21S120 was reduced to homozygosity in the offspring with trisomy 21. The data can be best explained by chromatid translocation in meiosis I and by normal crossover and segregation in meiosis I and meiosis II.

A 48,XXY,+21 Down syndrome patient with additional paternal X and maternal 21

The origin of meiotic nondisjunction of the extra chromosomes X and 21 was studied in a patient with the karyotype 48,XXY,+21 using DNA polymorphisms. The extra chromosome X was the result of paternal first meiotic nondisjunction of X and Y. The extra chromosome 21 was derived from the mother. The meiotic error in the mother most probably occurred in meiosis II. Thus, this is a combination caused by the chance occurrence of two independent events.

Interstitial deletion of the long arm of chromosome 18, del(18)(q12.2q21.1): a report of three cases of an autosomal deletion with a mild phenotype

We describe three unrelated patients with apparently identical interstitial deletions of the segment (18) (q12.2q21.1). They were a short and markedly mentally retarded 5 year old girl, a macrocephalic and obese 2 1/2 year old boy with moderate mental retardation, and a macrocephalic, severely mentally retarded 5 year old boy. Findings common to all five liveborn patients so far identified as carrying this deletion include a pattern of minor dysmorphic features (prominent forehead, ptosis of the upper eyelids, full periorbital tissue, epicanthic folds, strabismus), muscular hypotonia, seizures, behavioural disorders, and lack of major malformations.

Use of short sequence repeat DNA polymorphisms after PCR amplification to detect the parental origin of the additional chromosome 21 in Down syndrome

The origin of nondisjunction in trisomy 21 has so far been studied using cytogenetic heteromorphisms and DNA polymorphisms using Southern blot analysis. Short sequence repeats have recently been described as an abundant class of DNA polymorphisms in the human genome, which can be typed using the polymerase chain reaction (PCR) amplification. We describe the usage of such markers on chromosome 21 in the study of parental origin of the additional chromosome 21 in 87 cases of Down syndrome. The polymorphisms studied were (a) two (GT)n repeats and a poly(A) tract of an Alu sequence within the HMG14 gene and (b) a (GT)n repeat of locus D21S156. The parental origin was determined in 68 cases by studying the segregation of polymorphic alleles in the nuclear families (either by scoring three different alleles in the proband or by dosage comparison of two different alleles in the proband). Our results demonstrate the usefulness of highly informative PCR markers for the study of nondisjunction in Down syndrome.

Analysis of DNA polymorphisms suggests that most de novo dup(21q) chromosomes in patients with Down syndrome are isochromosomes and not translocations

Down syndrome is rarely due to a de novo duplication of chromosome 21 [dup(21q)]. To investigate the origin of the dup(21q) and the nature of this chromosome, we used DNA polymorphisms in 10 families with Down syndrome due to de novo dup(21q). The origin of the extra chromosome 21q was maternal in six cases and paternal in four cases. Furthermore, the majority (eight of 10) of dup(21q) chromosomes were isochromosomes i(21q) (four were paternal in origin, and four were maternal in origin); however, in two of 10 families the dup(21q) chromosome appeared to be the result of a Robertsonian translocation t(21q;21q) (maternal in origin in both cases).

Partial trisomy of chromosome 18 (pter----q12) following a familial 18;21 translocation rcp(18;21)(q12;q11)

A 1-year-old boy with trisomy 18 (pter----q12) following a paternal balanced translocation revealed microcephaly, a pattern of minor dysmorphic features including upslanting narrow palpebral fissures, receding forehead, large nose and receding mandible, cryptorchidism, flexion contractures of fingers, a cardiac malformation and moderate mental retardation. While pure trisomy 18p generally goes along with a near-normal phenotype, additional trisomy of only a short segment of the proximal long arm 18 has a distinct negative influence on the phenotype, as seen in our proband.

[Chorionic villi (placental) biopsy in the 2d and 3d trimester: new perspectives in prenatal diagnosis]

A report of our first experience in second and third trimester chorionic villus (placental) biopsy is given. In all 16 cases a cytogenetic result could be received within 2 to 5 days. There were 6 normal female and 9 normal male karyotypes. A third trimester CVS showed a mosaicism of a structural aberration of chromosome 9 (46, XX/46, XX, 9p+). Blood cultures of the fetus revealed a normal female karyotype. The following indications of a second and third trimester CVS are discussed: direct or indirect signs of fetal malformations in ultrasound scanning (Oligo- or Anhydramnios with severe intrauterine growth retardation), placental anomalies (exclusion of triploidies), non immunologic hydrops fetalis, low serum alpha FP and failed amniotic fluid culture. We believe that transabdominal CVS in the second and third trimester is a simple and rapid tool to exclude distinctively any chromosomal anomaly and therefore influences further management of pregnancy and parturition.

Pre-implantation embryos of Chinese hamster. II incidence and type of karyotype anomalies after treatment of the paternal post-meiotic germ cells with an alkylating mutagen

Ninety-two male Chinese hamsters were treated with a single, sub-lethal dose of the alkylating cytostatic drug Trenimon. After 3--23 days they were mated with untreated females. The great majority of the male germ cells had been exposed to the mutagen while they were in the highly sensitive post-meiotic spermatid stage. The karyotypes of the resulting embryos were studied in the 4--8-cell stage. Out of 221 analysable embryos, 24.4% had aberrant karyotypes. Ploidy and genome mutations were, at 0.9% each, within control limits. Structural aberrations, involving one or several chromosomes, were present in 23.6% of the embryos (control 1.8%). 51% had a single aberrant centric element. The most frequent aberration types were deletions (54%), dicentrics (16%), translocations inversions and complex rearrangements with 22% and rings with 7%. About one-third of the cells, in addition, contained acentric fragments.

Pre-implantation embryos of Chinese hamster. I. Incidence of karyotype anomalies in 226 control embryos

Karyotyes were determined in 226 pre-implantation embryos (4--8-cell stages) of Chinese hamster. The study was carried out under controlled natural breeding conditions, without superovulation and with the embryos developing in their mothers. A total of 5.3% karyotypically abnormal embryos were found. Over half, 3.1%, were due to ploidy mutations, 5 cases of triploidy and 2 cases of haploidy. Only 0.9% genome mutations were present, consisting of one autosomal trisomy and one autosomal monosomy. Structural aberrations were found in 1.8%, half of these probably due to a balanced maternal aberration and the rest appearing the mosaic condition only. These results are compared with the scarce body of mammalian data from the literature. Compared with the situation in man, the spontaneous aberration rates in the Chinese hamster and other experimental mammals are extremely low. This may be due, in part, to optimal timing of copulation in respect to estrus and ovulation prevailing in these animals but not in man. The low spontaneous aberration rate in the reported system is a valuable asset for purposes of mutagen testing.