Partial trisomy 13 as a result of de novo (6p;13q) translocation

Summary A newborn infant with the clinical features of the Patau syndrome was found to have excess chromosome 13 material present as a tandem translocation involving the short arm of chromosome 6 and the long arm of an extra chromosome 13: 46,XY,t(6;13)(p24;q12). The major part of the long arm of the extra chromosome 13 was attached linearly (tandem translocation) to the short arm of chromosome 6. Both parents were phenotypically and karyotypically normal.     

X-Y translocation. A case report

Summary A translocation of genetic material involving the long arm of the X chromosome and the heterochromatic portion of the Y chromosome is reported in a young woman. The phenotypic effect of this translocation and loss of almost half of the long arm of the X chromosome is described.     

Une triple translocation chez le Triton Pleurodeles waltlii

A cytogenetic study has lead us to a stock of fertile heterozygotes for a triple translocation. The chromosomal rearrangement has first been detected in a female resulting from a cross between a normal female and a male submitted to X ray-irradiation. The aberration consists of rearrangements between a chromosome 3, a chromosome 6 and a chromosome 7. Abnormal chromosomes have the following constitution: 7q?: the terminal portion of the long arm is lost and replaced by the end of the short arm of the chromosome 3. 6 q+: the terminal portion of the long arm is lost and replaced by the end of the long arm of the chromosome 7. 3p+: the terminal portion of the short arm is lost and replaced by the end of the long arm of the chromosome 6. On the analogy of the human chromosome standardization, the formula of heterozygotes is 24, t (3p+, 6q+, 7q?). The first meiotic division shows both in the female and in the male 9 bivalents and one hexavalent. The formulae of the gametes are the same in both sexes. When a heterozygote is bred with a normal individual the offspring is composed of phenotypically normal or abnormal animals, depending on their karyotypes. The unbalanced karyotypes are lethal or semilethal. The importance of the malformations depends on the temperature of the water where the animals grow. The study of the meiotic slides brings a cytological confirmation of the results obtained from the study of the phenotypes and karyotypes which appear in the offspring.     

Partial monosomy and partial trisomy for different segments of chromosome 13 in several individuals of the same family.

A reciprocal translocation, 46,XX,rcp(13;17)(q13;p13), was found to be segregating in a family. Two children have duplication of the distal portion of the long arm of chromosome 13, 46,XX,der(17),rcp(13;17)(q13;p13)mat. They are mentally retarded, have long philtra and postaxial hexadactyly. A maternal half-uncle has a duplication of the short arm and proximal portion of the long arm of chromosome 13, 47,XY,+der(13),rcp (13;17)(q13;p13)mat. He is mentally retarded, has scalp and skull defects and a very short philtrum. A fetus was found, on analysis of amniotic fluid cells, to have a deletion of the distal portion of the long arm of chromosome 13, 46,XX,der,(13),rcp(13;17)(q13;p13)mat. The fetus had multiple internal abnormalities and only 4 fingers on each hand.     

A neocentromere derived from a supernumerary marker deleted from the long arm of chromosome 6

Parental chromosome studies were referred to us after initial finding of a balanced translocation involving chromosomes 4 and 15 in their phenotypically abnormal male child (cytogenetic analysis was done at another laboratory). In addition to the same 4;15 translocation, the father also had an interstitial deletion of the long arm of one chromosome 6 and a marker chromosome. In this article, we report a neocentromere on this marker, which was determined to be composed of chromosome 6 material by FISH. The child's karyotype was re-interpreted to be unbalanced due to the presence of the abnormal chromosome 6, but without the marker. The clinical phenotype associated with the interstitial deletion of chromosome 6 is also reported.     

Molecular and cytogenetic characterization of a de novo t(5p;21q) in a patient previously diagnosed as monosomy 21.

Genomic single-copy DNA fragments were used to characterize an undetected chromosome translocation in an individual whose metaphase chromosome analysis revealed apparent monosomy 21. Eight RFLPs detected by six probes were used to identify homologous sequences from chromosome 21 in DNA digests from the proband and her parents. These family studies showed that the proband was disomic for the distal region of 21q. Reverse banding and in situ hybridization of chromosome 21-specific probes to metaphase chromosomes from the proband revealed a de novo translocation with breakpoints at 5p13 or 14 and 21q11 or 21. In situ hybridization permitted orientation of the translocated portion of chromosome 21 on the derivative chromosome 5 and, in conjunction with molecular analysis and previous mapping studies, refined the physical map for the long arm of chromosome 21.     

Y;autosome translocations and mosaicism in the aetiology of 45,X maleness: assignment of fertility factor to distal Yq11

Summary Three 45,X males have been studied with Y-DNA probes by Southern blotting and in situ hybridization. Southern blotting studies with a panel of mapped Y-DNA probes showed that in all three individuals contiguous portions of the Y chromosome including all of the short arm, the centromere, and part of the euchromatic portion of the long arm were present. The breakpoint was different in each case. The individual with the largest portion (intervals 1–6) is a fertile male belonging to a family in which the translocation is inherited in four generations. The second adult patient, who has intervals 1–5, is an azoospermic, sterile male. These phenotypic findings suggest the existence of a gene involved in spermatogenesis in interval 6 in distal Yq11. The third case, a boy with penoscrotal hypospadias, has intervals 1–4B. In situ hybridization with the pseudoautosomal probe pDP230 and the Y chromosome specific probe pDP105 showed that Y-derived DNA was translocated onto the short arm of a chromosome 15, 14, and 14, respectively. One of the patients was a mosaic for the 14p+ translocation chromosome. Our data and those reported by others suggest the following conclusions based on molecular studies in eight 45,X males: The predominant aetiological factor is Y;autosome translocation observed in seven of the eight cases. As the remaining case was a low-grade mosaic involving a normal Y chromosome, the maleness in all cases was due to the effect of the testis determing factor, TDF. There is preferential involvement of the short arm of an acrocentric chromosome (five out of seven translocations) but other autosomal regions can also be involved. The reason why one of the derivative translocation chromosomes becomes lost may be that it has no centromere.     

Partial trisomy of chromosome no. 1 in two adult brothers due to maternal translocation (1q-;6p+)

Summary Extra chromosome material on the short arm of chromosome no. 6 (46,XY,6p+) was found in two mentally retarded adult half-brothers with mildly dysmorphic features. The phenotypically normal mother had a balanced translocation between the long arm of chromosome no. 1 and the short arm of chromosome no. 6: 46,XX,t(1;6)(q32;p25). Thus the two affected brothers were trisomic for the long arm segment of chromosome no. 1, distal to q32. These patients, with mildly dysmorphic features and mental retardation, represent the first cases of partial trisomy 1q surviving to adulthood.The clinical and cytogenetic data obtained from eight individuals with partial trisomies for different long arm segments of chromosome no. 1 suggest that partial trisomy of the distal two-thirds of the long arm is characterized by severe malformations, growth retardation, and early death. Conversely, partial trisomy for the distal one-third of the long arm is associated with milder malformations and longer survival time as well as growth and mental retardation.     

Molecular cytogenetic analysis of radiation-induced wheat-rye terminal and intercalary chromosomal translocations and the detection of rye chromatin specifying resistance to Hessian fly

Radiation-induced wheat-rye chromosome translocation lines resistant to Hessian fly, Mayetiola destructor (say), were analyzed by in situ hybridization using total genomic and highly repetitive rye DNA probes pSc119 and pSc74. In situ hybridization analysis revealed the exact locations of the translocation breakpoints and allowed the estimation of the sizes of the transferred rye segments. T6BS·6BL-6RL and T4BS· 4BL-6RL are terminal translocations with either most of the complete long arm of rye chromosome 6R or only the distal 57% of the 6RL arm attached to the long arms of wheat chromosomes 6B and 4B, respectively. The breakpoint in T6BS·6BL-6RL is located at a fraction length (FL) of 0.11 in the long arm of T6BS 6BL-6RL and at FL 0.46 in the long arm of T4BS·4BL-6RL. Ti4AS·4AL-6RL-4AL is an intercalary translocation with the breakpoint located at FL 0.06 in the long arm of wheat chromosome 4A. The inserted 6RL segment, with the Hessian fly resistance gene, has a size of 0.7 m, and is the smallest and, so far, the first radiation-induced intercalary translocation identified in wheat.by R. Apples     

Senescence and human chromosome changes

Summary A girl with slight psychomotor retardation, microphthalmia, and colobomata of the left eye, a hypotrophy of the right arm and a surnumerary digit on the right hand is described. The routine chromsome analysis and a G-banding analysis revealed an elongated long arm of chromosome 10. An extra light and dark band was present proximally. Both parents had normal chromosomes. While the visual comparison of the abnormal with the normal chromosome 10, did not enable the extra bands of the normal bands q21 and q22 to be distinguished. However, measurements of length, surface area, and relative reflection of the different light and dark bands of the long arm on tracings or directly on the normal and abnormal chromosomes, enabled us to precisely locate the extra bands and to determine that the abnormal chromosome was a result of an insertional translocation. The value of such measurements is discussed.     

A, 1;6, translocation associated with congenital glaucoma and cleft lip and palate.

A translocation of a part of the long arm of a chromosome No. 1 onto the long arm of a chromosome No. 6 was observed in a 2 1/2-year-old boy with mental retardation, harelip, cleft palate and congenital glaucoma. Different banding methods revealed that the translocation t(1;6)(q23;q27) apparently was balanced. The conncection between the patients' symptoms and the chromosomal rearrangement might be fortuitous or produced by the chromosome aberration.     

Molecular analysis of aberrations of Xp and Yq

Summary Three cases of Y chromosomal aberrations were studied using a panel of Y-specific DNA sequences from both Yp and euchromatic Yq. One case was a phenotypic male fetus with a Y-derived marker chromosome. The short arm of this chromosome was intact, but most of its long arm was missing. The second case had a 46,Xyq- karyotype with portions of euchromatic Yq, including the spermatogenesis region, missing. The third case was a phenotypic female with a 46,XXp+ karyotype. The extra material on the Xp+ chromosome was derived from the heterochromatic, and part of the euchromatic, portion of Yq. Application of X-specific DNA sequences demonstrated that the distal portion of the short arm of the translocation X chromosome was deleted (Xpter—p22.3). The three examples demonstrate the importance of diagnostic DNA analysis in cases of marker chromosomes, and X and Y chromosomal aberrations. In addition, the findings in the patients facilitate further deletion mapping of euchromatic Yq.     

Fusion of 9 beta-satellite and telomere (TTAGGG)n sequences results in a jumping translocation

A newborn was found to have an isochromosome for the short arm of chromosome 9, i(9p) and a jumping translocation of the whole long arm. In 94.4% metaphases, 9q was fused to the telomere of chromosome 19p and, in 5.6% of metaphases, 9q was fused to the telomere of chromosome 8p. The net result was trisomy for the short arm of chromosome 9. With the pan telomere probe, fluorescent in situ hybridization (FISH) investigations found an interstitial telomere on the der(19) and der(8). The 9 beta and classical satellite probes gave a signal only on the long arm of chromosome 9 involved in the jumping translocation. The 9 alpha satellite probe hybridized to i(9p) and not to the other derivative chromosomes. A combination of chromosome 9 (red) and chromosome 19 (green) paint probes used to rapidly screen metaphases for the jumping translocation found 88 metaphases had a der(19)t(9;19) and 4metaphases had a der(8)t(8;9). For the first time, the junction of a jumping translocation has been shown to involve the telomere sequence (TTAGGG)n and beta-satellite sequences by FISH. In this paper, we also review the simultaneous occurrence of an isochromosome for the short arm and translocation of the whole long arm and constitutional jumping translocations.     

Reciprocal translocation between Y chromosome long arm euchromatin and the short arm of chromosome 1

A case with an apparently balanced reciprocal translocation between the long arm of the Y chromosome and the short arm of chromosome 1 t(Y;1)(q11.2;p34.3) is described. The translocation was found in a phenotypically normal male ascertained by infertility and presenting for intra-cytoplasmatic sperm injection treatment. Histological examination of testicular biopsies revealed spermatogenic failure. Chromosome painting with probes for chromosome 1 and for the euchromatic part of the Y chromsome confirmed the translocation of euchromatic Y chromosomal material onto the short arm of chromosome 1 and of a substantial part of the short arm of chromosome 1 onto the Y chromosome. Among the Y/autosome translocations, the rearrangements involving long arm euchromatin of the Y chromosome are relatively rare and mostly associated with infertility. Microdeletion screening at the azoospermia locus revealed no deletions, suggesting another mechanism causing infertility in this translocation carrier.     

Frequency of chromosome variants in human populations]

Chromosome variants were analyzed in the course of the population chromosome investigation of 6000 newborns and clinical cytogenetic studies of 403 married couples with recurrent spontaneous abortions, stillbirths or offsprings having congenital malformations or Down's syndrome. The following variants were determined: 1) Igh+, 9gh+, 16gh+ - the enlargement of the secondary constrictions of the size, more than 1/4 of the long arm of the chromosome; 2) Dp+ or Gp+ - the enlargement of the short arms of acrocentrics, their size being more than the short arm of the chromosome 18; 3) Ds+ or Gs - large satellites of the acrocentrics which are equal or more than the thickness of the chromatids of the long arms; 4) Es+ - satellites on the short arms of the chromosomes 17 or 18; 5) Dss of Gss - double satellites; 6) Yq+ - the enlargement of the long arm of Y chromosome, the size of which being more than G chromosome; 7) Yq- - deletion of the long arm of Y chromosome, the size of the long arm being less than chromosomes 21--22. The total frequency of variants in newborns was 12.8/1000 births. The incidence of different types of variants per 1000 births was as follows: Igh+ - 0.33; 9gh+ - 0.17; 16gh+ - 0.50; Ds+ - 2.33; Dp+ - 1.50; Dp- - 0.17; Gs+ - 0.83; Gp+ - 2.17; Yq+ - 6.91/1000 males; Yg- - 0.99/1000 males; double variants - 0.33; other variants - 0.33. 4.0% of married couples with recurrent spontaneous abortions had major chromosome aberrations, 14.6% - extreme variants of chromosomes. Among 113 couples with the history of congenital malformations in their offsprings major chromosome abnormalities were found in 4.4%, chromosome variants - 13.3%. The frequency of chromosome variants among 139 patients with Down's syndrome was 7.2%. In one case Robertsonian translocation t(DqGa) was determined. The most frequent types of variant chromosomes were Ds+, Dp+, Es+, Yq+.     

Clinical and molecular evaluation of four patients with partial duplications of the long arm of chromosome 18.

Four individuals with partial duplications of the long arm of chromosome 18 were analyzed at the clinical, cytogenetic, and molecular levels. Two of the individuals had duplications of the long arm from 18q21.1-qter because of inheritance of an unbalanced translocation. Both of these individuals displayed the clinical phenotype characteristic of Edwards syndrome. Two other patients had de novo interstitial duplications of 18q but did not have a clinical diagnosis of Edwards syndrome. The extent of the duplicated material in each patient was determined initially by using cytogenetic analysis and subsequently with more detailed comparisons of the duplicated regions by using molecular probes derived from a chromosome 18-specific lambda phage library. The results demonstrated that one of the de novo interstitial duplications that did not result in the Edwards syndrome phenotype had a more proximal breakpoint than that of the partial duplications of the two patients with features of Edwards syndrome. These results suggest that a single critical region for Edwards syndrome in the proximal portion of 18q is unlikely.     

The nature of the 1;29 translocation in cattle as revealed by synaptonemal complex analysis using electron microscopy

Synaptonemal complex analyses were carried out by electron microscopy on surface-spread spermatocytes of one normal bull and two bulls that were heterozygous for the so-called 1;29 translocation. The autosomal bivalents of the normal karyotype, which could be arranged by size in a series, demonstrated kinetochores at the terminally located attachment plaques. One autosomal bivalent was clearly larger than the rest and apparently consisted of the long arm of the 1;29 translocation. The 1;29 translocation was the longest autosome in the set and had a kinetochore in a subtelocentric position. Some of the autosome pairs had nucleolus organizer regions in telomeric regions. The X and Y chromosomes, which were not paired at zygotene, demonstrated association in a very short segment at early pachytene; in no cells could a synaptonemal complex be seen between the X and Y. Very often the sex chromosomes were dissociated. At zygotene, a few, usually large, bivalents were unpaired proximally. This always also involved the proximal parts of the arms of the 1;29 translocation and their normal homologs. At early pachytene, the 1;29 trivalent, although to a less extensive degree, was also unpaired in the pericentric region. Configurations in which one chromosome, either 1 or 29, was completely paired with its corresponding arm in the 1;29 translocation chromosome also occurred. When unpaired proximally, the size of chromosome 1 agreed fairly well with the size of its corresponding arm, but the size of chromosome 29 was considerably larger than the corresponding arm of the 1;29 translocation chromosome. During late zygotene and early pachytene, the percent difference between chromosome 29 and its corresponding arm decreased, and at mid and late pachytene there had been a complete synaptic adjustment. The size difference and pairing behavior indicated that a deletion of the kinetochore and the most proximal segment of chromosome 29 had preceded the fusion with chromosome 1 into the 1;29 translocation. The unique structural appearance of the 1;29 translocation chromosome compared to that of other centric fusion translocations in cattle lends support to the theory of a monophyletic origin of the 1;29 translocation. The importance of the pairing behavior observed in governing recombination and chromosome disjunction is briefly discussed.     

Concordant congenital malformations in twins with inherited translocation: t(9p-;13q+)

Summary Several members of a family with a translocation between the short arm of chromosome 9 and the long arm of chromosome 13 (9p-;13q+) are presented. Although the translocation found in various members of the family looked alike and appeared to be balanced, the clinical features were different. The like-sex twins displayed some features of 9p monosomy syndrome, whereas their mother and maternal grandmother, who apparently had the same translocation, showed only a few features of 9p- syndrome in addition to mild mental retardation. We suggest that a minute deletion of the short arm of chromosome 9 may cause features of 9p- syndrome and that the clinical features of this syndrome in older individuals may be too mild for the clinical diagnosis to be possible.     

Regional control of nondisjunction of the B chromosome in maize

Control of nondisjunction in the maize B chromosome was studied using a set of B-10 translocations. The study focused on the possible effect of the proximal region of the B long arm. The experimental procedure utilized a combination of a 10^B chromosome from one translocation with a B¹⁰ from another translocation. The breakpoints of the two translocations were so located that combination of the two elements created a deletion in the proximal region of the B chromosome, but no deletion in chromosome 10. Two different types of deletions were established; one involved a portion of the euchromatic region and the other the entire heterochromatic portion comprising the distal half of the B long arm, except for the small euchromatic tip. Deletion of the heterochromatic portion did not exert any effect on nondisjunction. Deletions of different portions of the euchromatic region produce different responses. Some deletions resulted in typical B nondisjunctional activity; others resulted in the disappearance of this activity. It is concluded that a region within the euchromatic portion of the chromosome is critical for the nondisjunction of B chromosomes. Among 22 translocations with breakpoints in the euchromatic regions, three were proximal to the critical region, 16 were distal and the position of three others was not determined.     

Trisomy 9q-. a variant of the 9p trisomy syndrome.

A low-birth-weight near-term male infant was found to have a non-familial 47,XY chromosome complement with an extra medium-sized metacentric chromosome slightly larger than a number 16. By Giemsa-trypsin (G-banding) this extra chromosome was determined to be a number 9 with deletion of approximately half of the long arm at region q 22. Chromosome studies on the clinically normal 38-year-old mother showed a balanced translocation with the deleted portion attached onto the distal end of a number 8 short arm, i.e. 46,XX,t(8;9)(p23;q22). Nondisjunction during meiosis of this woman's normal and deleted number 9 chromosomes is the basis of the child's abnormalities. One half-sibling of the child has a balanced translocation similar to that in the mother. Chromosome analyses on 4 others of the child's maternal half-siblings and on the maternal grandmother all showed normal patterns.