Origin of the extra chromosome No. 21 in Down's syndrome

Summary A No. 15 chromosome with a short arm longer than usual is observed in two phenotypically normal brothers. This chromosome appears to have no visible satellite, shows no N-band staining, and is never involved in satellite association. These results have led us to the conclusion that this chromosome lacks the nucleolus organizer region.     

Origin of the extra chromosome in trisomy 18

Summary The parental origin of an extra chromosome in five patients with trisomy 18 was traced using a restriction fragment length polymorphism (RFLP) of the human prealbumin (PA) gene, localized to 18p11.1–q12.1, as a genetic marker. MspI digests of the genomic DNAs of the five patients, their parents and normal controls were hybridized with the PAcDNA. Densitometric analysis on the gene dose of the polymorphic fragments of these patients revealed that three had originated from a maternal meiotic error. The other two patients were uninformative for the parental origin of trisomy 18. Our results indicate that nondisjunctional errors leading to trisomy 18 may occur predominantly at the maternal meiosis, consistent with the results of previous studies on the parental origin of trisomies 21 and 13.     

Origin of the extra chromosome in trisomy 21

Summary Of 61 families of children with trisomy 21, polymorphism of chromosome 21 elucidating the origin of the extra chromosome was found in 42. Nondisjunction was of paternal origin in 8 cases (19.04%) and the anomaly occurred with equal frequency during the first and second meiotic divisions. Maternal nondisjunction was demonstrated in 34 cases (80.95%), in which nondisjunction occurred by far the most often during the first meiotic division (29 cases).These results are in agreement with data from the literature, and suggest the existence of at least two different causes for chromosomal nondisjunction, the first being the same in both sexes and occurring in both meiotic divisions and the second specifically limited to the first meiotic division in the mother.Attachée de Recherche au CNRSAttachée de Recherche à l'INSERM     

Parental origin of the extra chromosome in Down's syndrome

Summary Chromosome 21 fluorescent heteromorphisms were studied in 42 patients with Down's syndrome, their parents and their siblings. Included in this number are two instances of an aunt and niece affected with trisomy 21, and one of affected siblings. One case has a de novo 21/21 translocation. Blood group, red cell and serum protein markers were also studied for linkage, gene exclusions, associations, and paternity testing. Thirty-one of the trisomy 21 cases were informative for parental origin of the extra chromosome and for stage of meiosis. The non-disjunctional event was of maternal origin in 24; 23 occurred in meiosis I, 1 in meiosis II. Seven were of paternal origin; 5 in meiosis I, and 2 in meiosis II. The translocation case was of paternal origin. A literature search revealed a total of 98 cases informative for the parent of origin of the extra chromosome, of >347 families tested. In addition, 3 de novo translocation cases, of 7 tested, were informative. The data suggest that most cases result from an error in the first meiotic division in the mother, but that a significant proportion are paternal in origin.     

Pure trisomy 19p syndrome in an infant with an extra ring chromosome

We report a 12-month-old infant evaluated for severe hypotonia, psychomotor retardation, and facial dysmorphisms, including round face, high prominent forehead, downward slanted palpebral fissures, hypertelorism, short nose, chubby cheeks, long philtrum, anteverted lower lip, low-set asymmetric and dysmorphic ears. Karyotype analysis disclosed an extra mosaic ring chromosome, which included the whole 19p arm. Four additional patients with supernumerary ring 19 chromosomes have been reported, but none of them had pure trisomy 19p.     

The origin of an extra chromosome 21 in families of children with Down syndrome

These are the first studies on the origin of nondisjunction of trisomy 21 in the USSR. Parental contribution was established in 84 of 140 families observed. In 66% cases the nondisjunction took place in oogenesis and in 34% cases - in spermatogenesis. Among the children, who inherited the additional chromosome from father, boys predominate. Compilative work on all the data available concerning the origin of the 21 nondisjunction has been performed; the factors favouring nondisjunction in I and II mitotic divisions in female meiosis, both genetical and age-dependent, have been considered. The great importance of the disturbances taking place in spermatogenesis for etiology is emphasized. It is proved that somatic hyperploidy does not serve as an indicator of predisposition for chromosome nondisjunction in meiosis.     

Small metacentric nonsatellited extra chromosome

Summary Five mentally retarded male patients with a supernumerary small metacentric nonsatellited chromosome were found to have many clinical features in common. The face showed characteristic small crowded features, the bodily habitus was asthenic, and the hands and feet had minor abnormalities. Renal anomalies were present in two patients. One patient had a myelomeningocele.Cytogenetic studies employing Q, R, and C banding in four patients showed the small extra chromosome to have staining properties compatible with an isochromosome of the short arm of chromosome 18.A comparison with previous case reports suggests a new syndrome. However, the identity of the extra chromosome has not yet been determined.     

An extra idic(15p)(q11) chromosome in Prader-Willi syndrome

Using a nonfluorescent AT-specific oligopeptide antibiotic, Distamycin A, on DAPI fluorescent banding of human chromosome (DA-DAPI) as described by Schweizer et al. (1978), we have detected an additional idic(15p) chromosome in a patient with typical Prader-Willi syndrome. On the basis of the evidence available in previous studies and of our own present results, we suspect that the fundamental genetic error in the syndrome is not caused by a chromosome aberration but by a gene aberration on chromosome 15.     

Maternally transmitted extra ring(21) chromosome in a boy with Down's syndrome

Summary An 11-month-old boy with typical Down's syndrome is presented. His karyotype was 47,XY,+r(21); the erythrocyte superoxide dismutase-1 (SOD-1) activity was elevated. His phenotypically normal mother showed 46,XX,r(21) karyotype and normal SOD-1 activity. Analysis of chromosomal heteromorphism revealed that in addition to the ring, a normal chromosome 21 was transmitted from the mother.     

Patau syndrome with a long survival. A case report

Trisomy 13 is a clinically severe entity; 85% of the patients do not survive beyond one year, and most children die before completing six months of age. We report a female child, 28 months old, white, the fourth child of a non-consanguineous couple, who presented trisomy 13. The child was born at term, from a vaginal delivery, weighing 2600 g. At birth, she was cyanotic, icteric, spastic, and cried weakly. The initial clinical examination detected polydactyly in the left hand, congenital clubfoot and convex soles, ocular hypertelorism, a low nasal bridge, numerous hemangiomas distributed throughout the body, cardiomegaly, and perimembranous inter-ventricular communication. There was no cleft lip or palate. On physical examination at 18 months old, the child weighed 6,900 g, had a cephalic perimeter of 41 cm, a thoracic perimeter of 43 cm and was 76 cm tall. At 28 months, she weighed 10,760 g and was 88.5 cm tall. Neuropsychomotor development retardation was evident from birth and, according to the psychologist and the social assistant of APAE (Handicapped Parents and Friends Association) in Cangu?u, Rio Grande do Sul, there was a noticeable improvement after physiotherapy and recreational sessions.     

Patau综合征患者额外13号染色体父亲起源

报告1例孕38周经剖腹产出生的畸形男儿。患儿双侧唇裂,严重腭裂,胸骨畸形,骶部脊柱裂,双侧睾丸未降,足内翻。出生后10分钟由于呼吸衰竭而夭折。患儿经外周血淋巴细胞染色体核型分析为47,XY,+13,后经荧光原位杂交技术加以证实。对患儿及其父母进行短重复序列D13S317位点检测,证实患儿额外的13号染色体源自父亲第一次减数分裂不分离。     

An extra human chromosome 21 reduces mlc-2a expression in chimeric mice and Down syndrome

An extra copy of human chromosome 21 (Chr 21) causes Down syndrome (DS), which is characterized by mental retardation and congenital heart disease (CHD). Chimeric mice containing Chr 21 also exhibit phenotypic traits of DS including CHD. In this study, to identify genes contributing to DS phenotypes, we compared the overall protein expression patterns in hearts of Chr 21 chimeras and wild type mice by two-dimensional electrophoresis. The endogenous mouse atrial specific isoform of myosin light chain-2 (mlc-2a) protein was remarkably downregulated in the hearts of chimeric mice. We also confirmed that the human MLC-2A protein level was significantly lower in a human DS neonate heart, as compared to that of a normal control. Since mouse mlc-2a is involved in heart morphogenesis, our data suggest that the downregulation of this gene plays a crucial role in the CHD observed in DS. The dosage imbalance of Chr 21 has a trans-acting effect which lowers the expression of other genes encoded elsewhere in the genome.     

Retrospective study of the parental origin of the extra chromosome in trisomy 18 (Edwards syndrome)

The parental origin of the extra chromosome in trisomy 18 was traced in 30 informative families using highly polymorphic (CA) repeats mapped on the long arm of chromosome 18. Proband DNA was recovered from slides of chromosome preparations in 28 cases and from paraffin-embedded tissues in two cases. The extra chromosome was found to be of maternal origin in 26 cases (86.7%), and paternal origin in 4 cases (13.3%).     

Maternal and paternal origin of extra chromosome in trisomy 21

Summary Fluorescence markers were studied in 40 patients with Down's syndrome and their parents. In 11 cases maternal and in 5 cases paternal non-disjunction could be shown. The disjunctional event occurred in the first meiotic division in 5 maternal and in 2 paternal cases. A second division failure was found in 4 maternal and 2 paternal cases. In 3 cases the failure could either be of first or second meiotic division origin.     

Parental origin of the extra chromosome in trisomy 18.

The parental origin of the supernumerary chromosome 18 was investigated by RFLP analysis in 23 individuals with Edwards syndrome. All families were studied with the DNA probe pERT-25, which recognizes a locus of highly polymorphic tandemly repeated DNA sequences on chromosome 18. The extra chromosome was found to be of maternal origin in 19 patients (95%), of paternal origin in one patient (5%), and indeterminate in three patients. In one of the three indeterminate cases, a mosaic, an apparent recombination event had taken place within the pERT-25 locus. The overall high degree of informativeness of pERT-25 illustrates the power of a chromosome-specific variable-number tandem repeat probe (VNTR) in parental origin studies of aneuploidy.     

Two extra euchromatic bands in the qh region of chromosome 9

Chromosome analysis in a fetus revealed an abnormal appearance of chromosome 9. The secondary constriction region of chromosome 9 was very large and two separate G+ bands were observed within this region with GTG banding. Parents' karyotypes showed maternal inheritance of this variant chromosome 9. Two G+ bands were stained negative with C banding both in the fetus and in the mother. The mother was phenotypically normal. Regarding phenotypically normal mother, normal fetal ultrasonographic findings and the similar cases described before in the literature it was considered that the fetus would be normal. Physical examination of the baby was normal after birth as expected. The existence of two G+ bands in 9qh was considered to be a normal variant in humans.     

The role of the X chromosome in mammalian extra embryonic development

Accumulating evidence points to the importance of the X chromosome for trophoblast development. In rodents, the extraembryonic cell lineage differs from somatic tissues in that X chromosome inactivation is imprinted, preferentially silencing the paternal X chromosome. As a consequence, trophoblast development is extremely susceptible to deviations from normal X inactivation and is impaired in situations of increased and reduced X-linked gene dosage. Mouse mutants have also shown that maintenance of X chromosome silencing in extraembryonic tissues requires a special set of heterochromatin proteins. Moreover, the X chromosome has been implicated in causing several malformations of the placenta. The observed importance of the X chromosome for placental development can be explained by the presence of many trophoblast-expressed genes, especially in the proximal and central regions. Given that the placenta represents a postzygotic barrier to reproduction, evolutionary constraints may be responsible for the presence of placental genes on the X chromosome that are often co-expressed in brain and testis.     

Origin of human chromosome 2 revisited

Similarities in chromosome banding patterns and hornologies in DNA sequence between chromosomes of the great apes and humans have suggested that human chromosome 2 originated through the fusion of two ancestral ape chromosomes. A lot of work has been directed at understanding the nature and mechanism of this fusion. The recent availability of the human chrornosome-2-specific alpha satellite DNA probe D2Z and the human chromosome-2p-specific subtelomeric DNA probe D2S445 prompted us to attempt cross-hybridization with chromosomes of the chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orangutan (Pongo pygmaeus) to search for equivalent locations in the great apes and to comment on the origin of human chromosome 2. The probes gave different results. No hybridization to the chromosome-2-specific alpha satellite DNA probe was observed on the presumed homologous great ape chromosomes using both high-stringency and low-stringency post-hybridization washes, whereas the subtelomeric-DNA probe specific for chromosome 2p hybridized to telomeric sites of the short arm of chromosome 12 of all three great apes. These observations suggest an evolutionary difference in the number of alpha satellite DNA repeat units in the equivalent ape chromosomes presumably involved in the chromosome fusion. Nevertheless, complete conservation of DNA sequence of the subtelomeric repeat sequence D2S445 in the ape chromosomes is demonstrated.