Partial trisomy 21 (21q21 - 21q22.2)]

An abnormal chromosome 21 is reported in a child with a phenotype strongly reminiscent of trisomy 21 syndrome. It is shown to result from duplication of the segment 21q21 leads to 21q22.2. Comparison of the phenotype with that of other partial and total trisomics shows that the characteristic features of the trisomy 21 syndrome (mongolism), the mental retardation in particular - is due to trisomy 21q22.2 and perhaps 21q22.2.     

Isochromosome not translocation in trisomy 21q21q

Summary After primary trisomy, de novo 21q21q trisomy is the most frequent chromosomal aberration responsible for Down syndrome. This rearrangement is more commonly referred to as a Robertsonian translocation or centric fusion product than as an isochromosome, e.g., t(21q;21q) instead of i(21q); however, in practice, it has not so far proved possible to distinguish between these alternatives. The aim of this work was to establish which of the two alternatives is acceptable.     

t(21q21q)/r[t(21q21q)] mosaic in two unrelated patients with mild stigmata of Down's syndrome

Two cases of t(21q21q)/r[t(21q21q)] mosaic in unrelated infants, 17 and 14 months old respectively are reported. The proportion of cells with the ring chromosome was 45% in the former, 80% in the latter. Both cases had mild manifestations of the Down's syndrome. The origin of this unusual mosaicism as well as the significance of the difference in the proportions of the ring chromosome in the two have been discussed.     

A novel translocation,t(9;21)(q13;q22) rearranging the RUNX1 gene in acute myelomonocytic leukemia

A novel translocation t(9;21)(q13;q22) associated with trisomy 4 has been detected in a patient with acute myelomonocytic leukemia (AML,M4) in relapse. The chromosomal translocation results in rearrangement of the RUNX1 gene at 21q22. The DNA sequence rearranged on chromosome 9 remains unidentified. The diversity of the partners involved in translocations implicating RUNX1 suggests that the functional consequences of the abnormality are more due to the truncation of RUNX1 than to the identity of its partner in the rearrangement.     

A new unbalanced chromosomal abnormality in 1q31.1 to 1q32 without phenotypic consequences

A familial duplication in the long arm of one chromosome 1 was detected due to recurrent abortions in a couple. The duplication was present in the male partner of the couple and in his mother, both clinically healthy. By reverse FISH, the duplication was determined to be located in 1q31. Multicolor banding (MCB) and application of locus-specific probes narrowed down the breakpoints to 1q31.1 and 1q32. The duplication spans a region of 13.9 Mb. None of the two breakpoints was colocalized with a known fragile site in 1q31.2, which, however, was duplicated. To the best of our knowledge, this is the first report of an unbalanced chromosome abnormality in this region that is not correlated with any clinical consequences.     

Translocation (13q21q)

Summary A (13q21q) translocation was found in an infant with Down's syndrome. The 17-year-old mother and the grandmother carried the translocation 45,XX,t(13;21)(p12;q11). The great grandparents had normal karyotypes. Fluorescence marker studies suggested that the translocation originated in the great grandmother. The hypothesis was supported by satellite association studies which showed a significant excess of 13–21 and 13–15 associations in the great grandmother.     

Unstable telocentric chromosome produced after centric misdivision of a 21q/21q translocated element

Summary An unstable telocentric chromosome was found in an individual with Down's syndrome and an unusual chromosomal mosaic, 46,XX, t(21q21q)+,21-/46,XX,21p-/45,XX,21-. As the 21q/21q chromosome was of paternal origin, based on the characteristics of its centromeric heterochromatin and on the characteristics of both 21 chromosomes of the father, it was concluded that its formation involved centric breakage and loss of centromeric material. The cell line with the 21p- chromosome may have originated from the translocation by an asymmetric misdivision of the reduced centromeric material. Of the two telocentrics produced by this fracture, one, possessing the smaller amount of centromeric apparatus, would be immediately lost; the other would be retained, but complete activity of its centromere would not be restored. It would therefore be unstable and might be lost.     

Molecular evidence for true isochromosome 21q

Summary In one family a duplicated 21q was shown to be a true isochromosome, which segregates from mosaic mother to non-mosaic child with full Down syndrome phenotype. Densitometric analysis of Southern blots, using probe pPW228C for the distal long arm of chromosome 21, indicated that the 21q duplication contains two copies of the allele detected by the probe. Maternal mosaic karyotype of 45,XX,-21/46,XX/46, XX,-21,+21i(21q) also suggested transverse mitotic centromere division as the origin of the 21q isochromosomes. Morphologic analysis of chromosome heteromorphisms strengthened this interpretation because the free 21 missing in the cell line with 45 chromosomes was also missing in cells with the isochromosome. In a second family the cytogenetic data also suggested transmission of an i(21q) from mosaic mother to nonmosaic Down syndrome child but molecular evidence did not prove identity of alleles in the duplicated chromosome 21.     

Partial trisomy of chromosome 21 by maternal translocation t(15;21) (q26.2; q21)]

A balanced reciprocal translocation, t(15;21) (q262;q21) was observed in the mother and maternal grandfather of two patients. The propositus, who received the abnormal chromosome 15 from his mother, is trisomic for the distal part of chromosome 21, and his phenotype is that of classical trisomy 21. His sister, who is trisomic for the proximal part of 21q, is slightly retarded but developmentally normal otherwise.     

Partial trisomy 21 with 45 chromosomes due to translocation of two chromosomes 21 onto a chromosome 14 : 45,XX-14,-21,+t(14q21q21q) (author's transl)

A patient with the phenotype of trisomy 21 and increased activity of superoxide dismutase A is reported with partial trisomy for the distal portion of 21q. The exceptional feature in this case is a 45-chromosome karyotype due to the translocation of two chromosomes 21 onto the distal end of 14q.     

Maternal origin of a de novo balanced t(21q21q) identified by ets-2 polymorphism

Summary Molecular investigations were done in a woman with a de novo balanced t(21q21q) discovered because of the birth of a trisomic 21 baby. Polymorphisms detected with probe ets-2 after MspI digestion showed that both chromosomes 21 involved in the rearrangement were of maternal origin. The most likely hypothesis is that of a disomic 21 oocyte fertilized by a nullisomic 21 sperm.     

Trisomy 21 by mirror duplication 46,XX,psu dic(21)ter rea (21q21q) (author's transl)

"Mirror image" duplication of chromosome 21 -- 46,XX,pter dic(21)ter rea(21q21q) -- was observed in a patient with the complete phenotype of trisomy 21 and a ses-sesquialtère de la SOD1.     

Patau's syndrome and 13q21q translocation

Summary This paper reports the case of a one-day-old male child presenting the typical features of Patau's syndrome. The cytogenetic study by means of conventional techniques and GTG and QFQ banding techniques showed that the chromosomal pattern of the propositus was 46,XYq+,-21,+t(13q21q) 15ps+,22ps+, and that the nondisjunction that originated the translocation and trisomy had occurred in the mother.     

Replication timing of extremely large genes on human chromosomes 11q and 21q

Many human genes have been mapped precisely in the genome. These genes vary from a few kb to more than 1 Mb in length. Previously, we measured replication timing along the entire lengths of human chromosomes 11q and 21q at the sequence level. In the present study, we used the newest information for human chromosomes 11q and 21q to analyze the replication timing of 30 extremely large genes (>250 kb) in two human cell lines (THP-1 and Jurkat). The timing of replication differed between the 5'- and 3'-ends of each of extremely large genes on 11q and 21q, and the time interval between their replication varied among genes of different lengths. The large genes analyzed here included several tissue-specific genes associated with neural diseases and genes encoding cell adhesion molecules: some of these genes had different patterns of replication timing between the two cell lines. The amyloid precursor protein gene (APP), which is associated with familial Alzheimer's disease (AD1), showed the largest difference in timing of replication between its 5'- and 3'-ends in relation to gene length of all the large genes studied on 11q and 21q. These extremely large genes were concentrated in and around genomic regions in which replication timing switches from early to late on both 11q and 21q. The differences of replication timing between the 5'- and 3'-terminal regions of large genes may be related to the molecular mechanisms that underlie tissue-specific expression.     

Prenatal diagnosis of de novo unbalanced translocation 8p;21q using subtelomeric probes

We report an unbalanced translocation involving chromosomes 8 and 21 in a fetus showing ultrasonographic abnormalities in the second trimester of pregnancy. A 41-year-old pregnant woman, gravida 1 para 0, was referred to the Genetics Clinic at the 16th week of gestation because of advanced maternal age and fetal pelvicaliectasis on ultrasonographic examination. Pregnancy had occurred following ICSI treatment. After genetic counseling amniocentesis was performed. Fetal karyotype analysis revealed a 46,XY,8p+ karyotype. Ultrasonographic examination was repeated at the 20th week of gestation and showed intrauterine growth retardation, ventriculomegaly, cerebellar structural abnormality and pelvicaliectasis. Chromosomes of both parents were normal. Molecular cytogenetic studies (FISH) using chromosome-specific subtelomere probes showed a terminal deletion of 8p and trisomy of the 21q subtelomeric region. Further analysis with Down Syndrome specific region probes revealed two signals. The couple decided to terminate the pregnancy. This is the first prenatally diagnosed case of unbalanced t(8p;21q) of de novo origin.     

Normal superoxide dismutase-1 (SOD-1) activity with deletion of chromosome band 21q21 supports localization of SOD-1 locus to 21q22

Summary The gene for superoxide dismutase-1 (SOD-1) is clearly on chromosome 21, although there is disagreement on the precise band location of SOD-1 on the long (q) arm of number 21. We report a patient with normal superoxide dismutase-1 (SOD-1) activity and an interstitial deletion of chromosome 21 resulting in monosomy for band q21. His phenotype is characterized by moderate mental retardation, a long narrow face, high and arched palate, cardiac murmur, undescended testes, and long hyperflexible extremities. The normal SOD-1 activity supports localization of this enzyme to 21q22.1.     

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.     

Maternal balanced translocation (4;21) leading to an offspring with partial duplication of 4q and 21q without phenotypic manifestations of Down syndrome

We describe an 8-years old female with supernumerary chromosome der(21)t(4;21)(q25;q22) resulting in partial trisomy 4q25-qter and partial trisomy 21(pter-q22). The extra material was originated from a reciprocal balanced translocation carrier mother (4q;21q). Karyotyping was confirmed by FISH using whole chromosome painting probes for 4 and 21q and using 21q22.13-q22.2 specific probe to rule out trisomy of Down syndrome critical region. Phenotypic and cytogenetic findings were compared with previously published cases of partial trisomy 4q and 21q. Our patient had the major criteria of distal trisomy 4q namely severe psychomotor retardation, growth retardation, microcephaly, hearing impairment, specific facies (broad nasal root, hypertelorism, ptosis, narrow palpebral fissures, long eye lashes, long philtrum, carp like mouth and malformed ears) and thumbs and minor feet anomalies. In spite of detection of most of the 3 copies of chromosome 21, specific features of Down syndrome (DS) were lacked in this patient, except for notable bilateral symmetrical calcification of basal ganglia. This report represents further delineation of the phenotype-genotype correlation of trisomy 4q syndrome. It also supports that DS phenotype is closely linked to 21q22. Nevertheless, presence of basal ganglia calcification in this patient may point out to a more proximal region contributing in its development in DS, or that genes outside the critical region may influence or control manifestations of DS features.     

Down syndrome in two siblings with 47,XY,+21 and 46,XY/46,XY,-21,+t(21q;21q)

Summary This is the first report in the literature of siblings affected with Down syndrome; one sibling had a nondisjunction of chromosome 21 and the other a (21q;21q) translocation.     

Unbalanced 13q/21q translocation: A revised study of the case previously reported as 21-monosomy

Summary Reexamination was made on a male infant previously reported as 21-monosomy. Extensive chromosome banding analyses in the patient and parents disclosed an unbalanced de novo translocation between chromosomes 13 and 21. The patient's karyotype was interpreted as 45,XY,-13,-21,+der(13),t(13;21) (q2 or 3;q1 or 2)pat. The patient showed many clinical features characteristic of 13q- syndrome.