Paternal nondisjunction in trisomy 21: excess of male patients

Paternal nondisjunction accounts for approximately 5% of casesof trisomy 21. We have studied 36 cases of free trisomy 21,in which the supernumerary chromosome was of paternal origin,with DNA markers in the pericentromeric region and along thelong arm of chromosome 21. Fifteen of the paternal cases wereconsistent with melosis II errors, 8 with mitotic errors andonly 7 with melosis I nondisjunction. This contrasts markedlywith maternally derived trisomy 21, in which meiosis I errorspredominate. An excess of males was observed in the meloticcases (21 maies:6 females), highly significantly different froma 1.06 ratio. A significant difference in mean maternal agewas found between cases of paternal origin (28.1 years) andthose of maternal origin (31.8 years, n=429). This indicatesthat the maternal age effect is confined to maternal nondisjunction.     

BrDU-Giemsa labeling studies of satellite associations in parents of children with trisomy 21 or 13

Studies on satellite association (SA) in parents of trisomy 21 offspring have not provided meaningful comparisons of SA frequencies since the latter was not expressed as a function of cell division number. We have used BrDU-labeling to compare SA frequencies in first and second division metaphases from lymphocytes of parents with either a trisomy 21 or trisomy 13 child and a control group. Parental origin of nondisjunction was determined in three of six families using quinacrine heteromorphisms. In the two cases of trisomy 13 determined, the errors occurred in maternal meiosis. BrDU-labeled metaphases were analyzed for SA frequency in four groups: A) parents contributing the extra chromosome; B) spouses of the parents in A; C) parents (nine) in whom the origin of a trisomy 13 or 21 was unknown; and D) healthy controls (five). The mean numbers of SAs/cell and of chromosomes/SA were not significantly different among the four groups for both first and second division cells. Sex and age showed no effect on SA frequency. There were significant decreases in mean numbers of SA/cell and chromosomes/SA in second-division cells (chromatids differentially stained) compared with first-division cells (chromatids undifferentiated). In second-division cells, two-chromosome SAs of all types showed random concordant and discordant alignment in each subject. The results from this BrDU-labeling approach provide no evidence that either quantitative or qualitative parameters of SA are directly related to a tendency of nondisjunction. They also show that acrocentric nondisjunction occurs in the presence of random chromatid alignment in SAs.     

Parental origin of the extra chromosome in trisomy 21 as indicated by analysis of DNA polymorphisms. Down Syndrome Collaborative Group.

BACKGROUND. Over the past 20 years, the parental origin of the extra chromosome in children with trisomy 21 has been investigated with cytogenetic methods of identifying morphologic variations in chromosome 21. These studies have concluded that the origin of the extra chromosome 21 was maternal in approximately 80 percent of cases and paternal in about 20 percent. METHODS. We studied 200 families, each with a single child with trisomy 21, using DNA polymorphisms as markers to determine the parental origin of the nondisjunction causing the extra chromosome 21. These polymorphisms spanned a region of about 120 centimorgans on the long arm of chromosome 21, from the D21S13 locus (the most centromeric) to the COL6A1 gene (the most telomeric). RESULTS. The parental origin of nondisjunction could be determined for all but 7 of the 200 children. It was maternal in 184 children (proportion [+/- SE], 95.3 +/- 1.5 percent) and paternal in 9 (4.7 +/- 1.5 percent). In a subgroup of 31 families, we compared the results of DNA analysis with those of traditional cytogenetic analysis. According to the cytogenetic analyses, nondisjunction originated in the mother in 26 cases (84 percent) and in the father in 5 (16 percent). DNA analysis demonstrated the origin as maternal in 29 (94 percent) and paternal in 2 (6 percent). With the cytogenetic analyses, there were three false determinations of paternal origin. CONCLUSIONS. In trisomy 21 the extra chromosome 21 is maternal in origin in about 95 percent of the cases, and paternal in only about 5 percent--considerably less than has been reported with cytogenetic methods. DNA polymorphic analysis is now the method of choice for establishing the parental origin of nondisjunction.     

A case of apparent trisomy 21 without the Down''s syndrome phenotype.

We describe a case of apparent trisomy 21 that does not fulfill the criteria for the clinical diagnosis of Down's syndrome (DS). Our patient was subjected to karyotype analysis and found to have full, non-mosaic trisomy 21 in both blood lymphocytes and skin fibroblasts, while examination of the term placenta, which was performed earlier in the course of a different study, had shown mosaicism (73%) for trisomy 21. FISH analysis showed no obvious rearrangement of the DS chromosomal region in any of the chromosomes 21. Molecular analysis using polymorphic markers on chromosome 21 verified the existence of trisomy for the entire long arm of the chromosome and showed that the origin of the extra chromosome was maternal and was probably the result of a mitotic error. In contrast with the above, the clinical evaluation using the Jackson checklist of 25 signs failed to establish the diagnosis of DS. We believe that our patient might present mosaicism in other tissues that are not available for analysis and can be regarded as an extreme example in the continuous spectrum of karyotype phenotype associations in mosaic cases.     

Frequency of meiotic trisomy depends on involved chromosome and mode of ascertainment

Although maternal meiotic errors predominate in most studies of nonmosaic trisomy, studies of trisomy ascertained through confined placental mosaicism (CPM) have shown a high rate of somatic errors. However, origin of trisomy of many of the chromosomes involved in CPM has not been evaluated previously in cases ascertained through spontaneous abortions (SAs). Therefore, it was impossible to determine if the relative lack of meiotic errors in trisomy-CPM cases was a characteristic of the specific chromosome involved or due simply to ascertainment through a mosaic state. In the present study, parental and meiotic/somatic stages of origin of trisomy were determined in 89 SAs involving trisomy of chromosomes 2, 4 to 10, 12, 15, 17, and 20. Comparisons were then made to origin of trisomy in cases of confined and generalized trisomy mosaicism. Although somatic errors are generally more common in mosaic cases, this depends on the specific chromosome involved. The results suggest that there are chromosome-specific differences in the relative frequency of somatic chromosome gain or loss and/or the ability of an early somatic loss of one chromosome from a trisomic conceptus to "rescue" the pregnancy. As mean maternal age was less in the somatic than meiotic origin cases (P < 0.01), the age distribution of the study population should also influence the probability of detecting a somatic error. No phenotypic differences were apparent when cases were subdivided based on either parent or stage of origin of the trisomy.     

Two unique patients with trisomy 18 mosaicism and molecular marker studies

We report two unusual patients with trisomy 18 mosaicism presenting with minor anomalies and failure to thrive in the first year of life. Chromosome analysis showed trisomy 18 in 30/30 peripheral blood lymphocytes in both children. Analysis of skin fibroblasts in the first child showed normal female chromosomes in 30/30 cells, and the fibroblast karyotype in the second child showed mosaicism for tetrasomy 18p, trisomy 18, and normal female chromosomes (karyotype 47,XX, +i(18)(p10)[47]/47,XX, +18[9] /46,XX[4]). Trisomy 18 commonly results from nondisjunction at maternal meiosis II (MII). Nondisjunction at maternal MII has also been postulated to be the initial step in the formation of tetrasomy 18p. In our second case, the additional chromosome 18 was the result of maternal nondisjunction at MII, consistent with this hypothesis. In the first case, nondisjunction at maternal meiosis I (MI) was responsible for the extra chromosome 18.     

Monozygotic twins discordant for trisomy 21 and maternal 21q inheritance: a complex series of events

We report on a monochorionic/diamniotic twin pregnancy discordant for trisomy 21. Amniocentesis (at 13(5/7) weeks) was performed following ultrasound signs of hydrops and cystic hygroma in twin 1 (T1). Prenatal karyotype showed non-mosaic trisomy 21 in T1 (47,XX,+21[7]), and low-grade mosaic trisomy 21 in twin 2 (T2) (47,XX,+21[2]/46,XX[19]). Post mortem examination of fetal skin, kidneys and lungs confirmed trisomy 21 in T1 (47,XX,+21[548]) and the placenta (47,XX,+21[200]). T2 had a normal karyotype (46,XX[648]). Analysis of microsatellite polymorphisms in multiple samples from the placenta, hand, lungs, kidneys and the umbilical cords of both twins confirmed monozygosity for all loci tested, and trisomy 21 in T1. Unexpectedly, T1 and T2 inherited different maternal alleles for markers of the most distal 4 Mbp of 21q. At least four successive events are needed to explain the genetic status of both twins and include maternal MI premature chromatids separation or maternal II meiotic nondisjunction and post-zygotic events such as, chromosome rescue, nondisjunction, an/or recombination.     

Pseudo dicentric chromosome (5;21): a rare example of maternal germline mosaicism

Karyotyping of a malformed male newborn revealed the unbalanced karyotype of 46,XY, psudic(5;21)(q12;p13), +5 resulting in trisomy for the short arm of chromosome 5 and partial trisomy for 5q. Both parents had normal karyotypes in their peripheral blood lymphocytes. A second pregnancy ended in a miscarriage at 16 weeks gestation, sonographically 12 weeks. Karyotyping of chorionic villi from the abortus revealed the same unbalanced karyotype that had been identified in the first child. Fluorescence in-situ hybridization analysis confirmed a trisomy 5p. Microsatellite marker analysis ruled out illegitimacy and proved the maternal origin of the trisomic section of chromosome 5. Extended chromosome analysis of 60 metaphase cells from maternal skin fibroblasts and 40 metaphase cells from lymphocytes did not reveal mosaicism for psudic(5;21). These findings suggest the presence of a maternal germline mosaicism.     

Variable clinical expression of mosaic trisomy 16 in the newborn infant

Trisomy 16 is common in embryos and fetuses aborted early during development. Mosaicism for trisomy 16 is sometimes encountered during prenatal diagnosis, particularly with chorionic villi biopsy specimens, and, until recently, was thought to be confined to the placenta. However, recently, several liveborn infants with trisomy 16 mosaicism have been described. We report on an additional liveborn infant with trisomy 16 mosaicism and compare the clinical findings with those of the previously reported cases in an attempt to delineate a mosaic trisomy 16 syndrome. Cytogenetic analysis from our patient showed that there was a different proportion of abnormal cells in different tissues and that the anomaly was undetectable in blood lymphocyte cultures. This observation was consistent with some of the previous reports. DNA analysis of parents and child was carried out using a polymorphic dinucleotide marker that maps to the long arm of chromosome 16. This analysis showed that the extra chromosome 16 in the infant was maternal in origin and suggested that the nondisjunction was probably a first meiotic division error. Our results suggest that an investigation of multiple tissues is required before concluding that mosaicism is confined to the placenta. We conclude that a finding of trisomy 16 mosaicism at prenatal diagnosis should be regarded with extreme caution. This diagnosis may be associated with a highly variable phenotype that may occasionally be compatible with extrauterine life. © 1993 Wiley-Liss, Inc.     

Concurrence of ring 21 and trisomy 21 in children of normal parents

We present a case of two siblings with different chromosome 21 abnormalities that are both de novo [r(21)/i(21p13) mosaicism and rob(14;21)]. Molecular studies using polymorphic markers have shown that these two aberrations had a common maternal origin. However, the parents were cytogenetically and phenotypically normal. This unusual association has not been reported and is considered to be a unique case that should be addressed.     

Mosaic trisomy 17 in amniocytes: phenotypic outcome, tissue distribution, and uniparental disomy studies.

Mosaicism for trisomy 17 in amniocyte cultures is a rare finding, whilst postnatal cases are exceptional. In order to gain insight into the possible effects of the distribution of the trisomic line and of uniparental disomy (UPD) on embryofoetal development, we have performed follow-up clinical, cytogenetic and molecular investigations into three newly detected prenatal cases of trisomy 17 mosaicism identified in cultured amniotic fluid. In the first case, the pregnancy ended normally with the birth of a healthy girl, and analysis of newborn lymphocytes and of multiple extra-embryonic tissues was indicative of confined placental mosaicism. The second case was also associated with a normal pregnancy outcome and postnatal development, and only euploid cells were found in peripheral blood after birth. However, maternal isodisomy 17 consequent to a meiosis II error and loss of a chromosome 17 homologue was detected in peripheral lymphocytes postnatally. In the third case, pathological examination after termination of pregnancy showed growth retardation and minor dysmorphisms, and the trisomic line was detected in foetal skin fibroblasts. In addition, biparental derivation of chromosome 17 was demonstrated in the euploid lineage. These results, together with previously reported data, indicate that true amniotic trisomy 17 mosaicism is more commonly of extra-embryonic origin and associated with normal foetal development. Phenotypic consequences may arise when the trisomic line is present in foetal tissues. Case 2 also represents the first observation of maternal UPD involving chromosome 17; the absence of phenotypic anomalies in the child suggests that chromosome 17 is not likely to be subject to imprinting in maternal gametes.     

Cerebellar hypoplasia, zonular cataract, and peripheral neuropathy in trisomy 17 mosaicism

Trisomy 17 mosaicism in liveborns is an extremely rare chromosomal abnormality, with only three cases reported in the literature. Here we describe a 7-year-old boy with trisomy 17 mosaicism. The chromosome abnormality was detected by amniocentesis and was confirmed postnatally in cultured skin fibroblasts. The main clinical features were mental retardation and growth reduction, peripheral motor and sensory neuropathy, hypoplastic cerebellar vermis, zonular cataract, and body asymmetry. In our patient, and in the three earlier described cases, the additional chromosome 17 was detected in skin fibroblasts, not in peripheral lymphocytes. Molecular investigations excluded uniparental disomy of chromosome 17 in our patient. The extra chromosome 17 probably originated from a postzygotic mitotic nondisjunction of the maternal chromosome 17. In most cases of trisomy 17 mosaicism detected in amniocytes the chromosome abnormality seems to be confined to extra-embryonic tissues and clinically normal children are born. If, however, there are also ultrasound abnormalities, the possibility of fetal trisomy 17 mosaicism should certainly be considered. If postnatal karyotyping is limited to blood the diagnosis of trisomy 17 mosaicism could easily be missed. Therefore, we recommend chromosome analysis to be based on cultured skin fibroblasts in all cases where mental retardation is accompanied by postnatal growth retardation, body asymmetry, peripheral neuropathy, and cerebellar hypoplasia or zonular cataract.     

Copper/zinc superoxide dismutase (SOD-1) activity in regular trisomy 21, trisomy 21 by translocation and mosaic trisomy 21

Cu/Zn superoxide dismutase (SOD-1) (E.C.1.15.1.1.) activity was estimated in children with regular trisomy 21-Down syndrome as well as in cases of translocation and mosaic trisomy 21, as identified by the GTG, CBG and RHG banding techniques. SOD-1 activity was found to be increased in all examined cases except trisomy 21 mosaicism. These findings provide further proof of the gene dosage theory and additional biochemical evidence for the triplicate existence of the SOD-1 gene localized on chromosome 21     

Down综合征与正常核型的孪生姐妹细胞遗传学及DNA多态性分析

目的报告1对异卵孪生姊妹,分别为21三体综合症患者和表型核型正常的个体,并讨论患者额外21号染色体的来源.方法对孪生姊妹进行外周血淋巴细胞染色体核型分析和15个DNA微卫星位点多态性分析.结果孪生姐姐核型为47,XX, 21,孪生妹妹核型为46,XX.孪生姊妹15个STR位点与其父母比较,5个位点上显示有来自母亲的不同标志物,6个位点上显示有来自父亲的不同标志物.21三体综合征患者在D21S11位点上显示有3个不同的标志物,其中2个源自母亲.结论孪生姐妹为异卵孪生,孪生姐姐额外的21号染色体来自于母亲第1次减数分裂不分离.     

Mosaic trisomy 16 in a thriving infant; maternal heterodisomy for chromosome 16

Lindor NM, Jalal SM, Thibodeau SN, Bonde D, Sauser KL, Karnes PS. Mosaic trisomy 16 in a thriving infant; maternal heterodisomy for chromosome 16
Clin Genet 1993: 44: 185–189. © Munksgaard, 1993
Trisomy 16 is the most common trisomy in spontaneous abortions and is usually, if not always, lethal in the nonmosaic state. We report a liveborn infant with trisomy 16 mosaicism first diagnosed by amniocentesis at 20 weeks gestation. At birth, the infant was growth retarded and mildly dysmorphic. At age 14 months she was developmentally normal and had facial asymmetry. Her length, weight and head circumference were normal. Pure trisomy 16 was found in cells from the placenta. A normal female karyotype was found in lymphocytes from the infant. Skin fibroblasts revealed a trisomy 16 karyotype in 6 of 30 cells. Molecular analysis showed maternal uniparental heterodisomy, indicating that the trisomic conceptus arose from a nondisjunction of maternal meiosis. Fibroblasts may be the tissue of choice for detection of low-level trisomy 16 mosaicism.     

Parental origin of the supernumerary chromosome in trisomy 18

Ya-gang X, Robinson WP, Spiegel R, Binkert F, Ruefenacht U, Schinzel AA. Parental origin of the supernumerary chromosome in trisomy 18. Clin Genet 1993: 44: 57–61. Munksgaard, 1993
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.     

The origin of trisomy 13

Trisomy 13 is one of the most common trisomies in clinically recognized pregnancies and one of the few trisomies identified in liveborns, yet relatively little is known about the errors that lead to trisomy 13. Accordingly, we initiated studies to investigate the origin of the extra chromosome in 78 cases of trisomy 13. Our results indicate that the majority of cases (>91%) are maternal in origin and, similar to other autosomal trisomies, the extra chromosome is typically due to errors in meiosis I. Surprisingly, however, a large number of errors also occur during maternal meiosis II ( approximately 37%), distinguishing trisomy 13 from other acrocentric and most nonacrocentric chromosomes. As with other trisomies, failure to recombine is an important contributor to nondisjunction of chromosome 13.     

Pre- and postnatal findings in trisomy 17 mosaicism

Trisomy 17 mosaicism is one of the rarest autosomal trisomies in humans. Thus far, only 23 cases have been described, most of them detected prenatally. In only five instances has mosaicism been demonstrated in lymphocytes and/or fibroblasts postnatally, and only in these have multiple congenital anomalies (MCA), facial dysmorphisms, and mental retardation been reported. Patients with trisomy 17 mosaicism at amniocentesis and a normal karyotype in blood and fibroblasts (n = 17) were always healthy. Here, we report on pre- and postnatal clinical, cytogenetic, molecular-cytogenetic, and molecular findings in four patients with trisomy 17 mosaicism. The first case was detected in cultured but not in short-term chorionic villi and amniocytes. Due to MCA on prenatal ultrasound examination the pregnancy was terminated. The second patient is a 13-month-old healthy boy, in whom low level trisomy 17 mosaicism was detected in cultured chorionic villi only. The third patient is a 2-year-old girl with growth retardation, developmental delay, MCA, and trisomy 17 mosaicism in amniocytes, fibroblasts, and placenta, but not in blood and buccal smear. The fourth patient is a 9-year-old boy with growth and mental retardation, sensoneurinal hearing loss, and MCA. Cytogenetic analyses showed trisomy 17 mosaicism in amniocytes, skin fibroblasts, and urinary sediment cells, whereas in blood and buccal smear a 46,XY karyotype was found. Molecular investigations in all four cases indicated biparental inheritance of chromosome 17. Formation of trisomy was most likely due to a maternal meiosis I error in Patient 1 and a postzygotic non-disjunction of the paternal chromosome 17 in Patient 4. Cerebellar malformations, reported in two cases from the literature and in two reported here may be a specific feature of trisomy 17 mosaicism. Since the aberration has rarely been reported in lymphocytes, chordocentesis is not indicated in prenatal diagnosis. Prenatal genetic counseling for trisomy 17 mosaicism in chorionic villi or amniocytes should consider that the clinical significance remains uncertain.     

Recurrent trisomy 21: four cases in three generations

Recurrent trisomy 21: four cases in three generations.While gonadal mosaicism can lead to recurrence of trisomy 21 (T21) for a single couple, the recurrence of free T21 in multiple members of a single pedigree has rarely been reported. We present an unusual pedigree with four cases of Down syndrome (DS) with free T21 were born to four separate women related through three generations of one family. The mothers were aged 18, 21, 29, and approximately 30 years at the time of the births. Using microsatellite markers, we excluded most of chromosome 21, excepting two small regions within 21q11.1 and 21q22.3, as being shared among the mothers of the DS children. However, two members of the pedigree, including one DS mother with a normal G-banded karyotype, carried supernumerary alleles at markers 2503J9TG, D21S369, and D21S215, which span the region from 21pter to 21q11.1. Fluorescence in situ hybridization using a centromeric probe hybridizing to chromosomes 13 and 21 did not reveal a novel location, ruling out a cryptic centromeric translocation between chromosome 21 and any chromosome other than chromosome 13. The level of meiotic recombination on chromosome 21 was unusually high in this family as well. We hypothesize that a cryptic rearrangement within the highly repetitive region of 21q11.1 is present in this family, disrupting pairing and leading to an increased risk of non-disjunction of chromosome 21 in this family.     

Characterization and molecular analysis of nondisjunction in 18 cases of trisomy 21 and leukemia.

We recently began a cytogenetic and molecular study of nondisjunction in leukemic Down syndrome individuals to determine whether the mechanism by which the extra chromosome 21 originates predisposes the individual to leukemia. In the present report, we summarize our observations on 18 patients with trisomy 21 and acute or transient leukemia, including 11 patients with acute lymphocytic leukemia, three with acute myeloid leukemia, one with B-cell lymphoma, one with acute megakaryoblastic leukemia, and two with transient leukemia. Results of DNA marker studies of the parental origin of the extra chromosome 21 indicated that 16 of the 18 cases (89%) were maternally derived, a percentage similar to that seen among nonleukemic Down syndrome patients. We noted that most leukemic Down syndrome patients had one locus or more in which parental heterozygosity was maintained in the trisomic individual, indicating a meiotic rather than a mitotic origin for the trisomy.