Human gene mapping using an X/autosome translocation.

Human fibroblasts containing a translocation between the X chromosome and chromosome 15 were fused with the 6-thioguanine-resistant mouse cell line, IR. Resulting hybrids, selected in HAT medium, retained the X/15 chromosome. Hybrids which were counterselected in 6-thioguanine lost this chromosome. The X-linked markers glucose-6-phosphate dehydrogenase (G6PD), phosphoglycerate kinase (PGK), and hypoxanthine phosphoribosyl transferase (HPRT), and the non-X-linked markers pyruvate kinase (PKM2) mannose phosphate isomerase (MPI), N-acetyl hexosaminidase A (HEXA) and beta2-microglubulin (beta2-m) all segregated in concordance with the X/15 translocation chromosome. The latter markers have been assigned to chromosome 15. Selection against the X/15 chromosome was done using antihuman beta2-m serum. Electrophoretic and immunochemical analyses of the N-acetyl hexosaminidases A and B in these hybrids were performed.     

X/X translocation in a patient with Turner's syndrome

Summary An abnormally large X chromosome was found in a girl with Turner's syndrome, and was identified as a X/X translocation (karyotype 45,X/46,X,-X,+t(XqXp)).Aided by contract No. 20. 122 F.W.G.O., Belgium.     

Two cases of X/autosome translocation in females with incontinentia pigmenti

Summary We report two unrelated girls who present some clinical features of severe incontinentia pigmenti (IP), with characteristic skin pigmentation. Both have balanced de novo X/autosome translocations involving band Xp11. The coincidence of the probable de novo expression of an X-linked disorder in these two girls with translocations involving similar breakpoints on the X chromosome suggests that this band may be the site of the IP gene locus.     

Turner's syndrome and Duchenne muscular dystrophy in a girl with an X; autosome translocation

A balanced de novo (X;9) translocation was observed in a patient with progressive muscular dystrophy of Duchenne's type (DMD), Turner's syndrome, epilepsy and mental retardation. The involvement of the paternal X is suggested. The assignment of the gene locus for DMD is confirmed on Xp21.     

X chromosome inactivation in X autosome translocation carrier cows.

The pattern of X chromosome inactivation in X autosome translocation carries in a herd of Limousin-Jersey crossbred cattle was studied using the reverse banding technique consisting of 5-bromodeoxyuridine incorporation and acridine orange staining and autoradiography on cultures of solid tissues and blood samples exposed to tritiated thymidine. The late-replicating X chromosome was noted to be the normal X in strikingly high proportions of cells in cultures of different tissues from all translocation carriers. It is suggested that the predominance of cells in which the normal X is inactivated may be the result of a post-inactivation selection process. Such a selection process during the prenatal life favouring cells in which the genes of the normal X chromosome remain unexpressed in translocation carrier females may be the mechanism that helps these conceptuses escape the adverse effects of functional aneuploidy. Based on the observation that the translocation carriers of this line of cattle are exclusively females and that there is a higher than expected rate of pregnancy loss, it is also postulated that the altered X chromosome may be lethal to all male conceptuses and to some of their female counterparts.     

Identification of an autosome to X chromosome translocation in the domestic cow.

Chromosomes were harvested from two fibroblast lines derived from a phenotypically normal cow and her albino daughter, both known to be heterozygous for an X/autosome translocation. QFH-banding after early BrdU incorporation identified the translocated autosomal material as chromosome 23 bands 13-25, and revealed that the centromeric portion of the translocated chromosome 23 had been retained. Fluorescent in situ hybridization of a BoLA Class I cDNA probe to the normal chromosome 23 and to the translocated autosomal material confirmed the identity of the translocation, and allowed a more precise sublocalization of the MHC in cattle than that previously reported.     

High-resolution banding study of an X/4 translocation in a female with Duchenne muscular dystrophy

Summary A rare female case of Duchenne muscular dystrophy with an X/4 translocation was found. Detailed cytogenetic analyses by R-banding and high-resolution G-banding techniques revcaled that the exchange point involved in the translcoation was at the p21.1 band on the X chromosome.     

Different patterns of X chromosome inactivity in lymphocytes and fibroblasts of a human balanced X; autosome translocation

Summary In lymphocytes of a human female carrier of a balanced X;3 translocation, 46,X,t(X;3)(q28;q21), late replication of the structurally normal X chromosome only was previously described (de la Chapelle and Schröder 1973). We have now confirmed this finding using a fresh blood sample. Examining the chromosomes of this individual in fibroblasts we observed that either the normal X or the Xq+ chromosome could replicate late and show inactivity after fusion with heteroploid mouse cells. The replication patterns of chromosomes in human X;autosome translocations have so far almost exclusively been analyzed in lymphocytes. Our findings stress that results based on these cells are not representative for all cell types.     

Common sequence motifs at the rearrangement sites of a constitutional X/autosome translocation and associated deletion.

Reciprocal chromosome translocations are common de novo rearrangements that occur randomly throughout the human genome. To learn about causative mechanisms, we have cloned and sequenced the breakpoints of a cytologically balanced constitutional reciprocal translocation, t(X;4)(p21.2;q31.22), present in a girl with Duchenne muscular dystrophy (DMD). Physical mapping of the derivative chromosomes, after their separation in somatic cell hybrids, reveals that the translocation disrupts the DMD gene in Xp21 within the 18-kb intron 16. Restriction mapping and sequencing of clones that span both translocation breakpoints as well as the corresponding normal regions indicate the loss of approximately 5 kb in the formation of the derivative X chromosome, with 4-6 bp deleted from chromosome 4. RFLP and Southern analyses indicate that the de novo translocation is a paternal origin and that the father's X chromosome contains the DNA that is deleted in the derivative X. Most likely, deletion and translation arose simultaneously from a complex rearrangement event that involves three chromosomal breakpoints. Short regions of sequence homology were present at the three sites. A 5-bp sequence, GGAAT, found exactly at the translocation breakpoints on both normal chromosomes X and 4, has been preserved only on the der(4) chromosome. It is likely that the X-derived sequence GGAATCA has been lost in the formation of the der(X) chromosome, as it matches an inverted GAATCA sequence present on the opposite strand exactly at the other end of the deleted 5-kb fragment. These findings suggest a possible mechanism which may have juxtaposed the three sites and mediated sequence-specific breakage and recombination between nonhomologous chromosomes in male meiosis.     

Trisomy of an autosome in mice heterozygous by a Robertson translocation]

From 866 embryos of mice heterozygous by Roberstsonian translocations 54 ones (6,2%) had trisomy of one of translocated chromosomes. The frequency of trisomy is unique for each translocation, dependent on other chromosomal redistributions in the karyotype and on sex of heterozygous individuals. Trisomy of all the autosomes studied (N 1, 5, 8, 9, 14, 15, 17, 19) results in a characteristic complex of non-specific malformations which includes general delay in development, reduction of the cephalic portion of the nervous tube, cranio-fascial malformations, hypertrophy of the heart cavities. In a number of cases autosomal trisomy (N 15,8) is responsible for certain specific disturbances of morphogenesis. The excess of majority of autosomes (N 5, 8, 9, 15, 16 and 17) causes death of embryos in the period of active organogenesis. Embryos with trisomy of the 1st, 14th and 19th pairs of autosomes in certain cases reach the fetal period but have severe malformations and are non-survival. In mice karyotype there seems to be no autosomes whose trisomy is compatible with postnatal development. Signs of similarity and difference in manifestation of numericle chromosomal aberrations were noted in embryogenesis of mice and man. Principle possibility of modelling chromosomal embryopathy of man in mice with Robertsonian translocations is supposed.     

X/Y translocation in a family with Leri-Weill dyschondrosteosis

An X/Y translocation associated with Leri-Weill dyschondrosteosis (LWD) was detected in a boy and in his mother. FISH analysis with specific probes for SHOX and SRY displayed no signal on the der(X), while one signal for SHOX was detected on the normal X chromosome in the mother, and one signal each for SHOX and SRY was detected on the normal Y chromosome in the proband.     

A new case of Y to X translocation in a female

Summary Cytogenetic investigation of married couples with the history of two or more recurrent abortions or unsuccessful pregnancies was carried out. The study concerns the occurrence of reciprocal translocations in regard to spontaneous miscarriages. In 115 examined couples 9 reciprocal translocations were observed, i.e., in 7.8%.     

Strategy for constructing somatic hybrids isolating the two derivative chromosomes in X;autosome translocations. Application to a female patient t(X;5) with Hunter syndrome

X; autosomal translocations are excellent tools for genetic analysis because of the easy selection of clones isolating the derivative bearing the HPRT gene in somatic cell hybrids. We have developed a strategy to select clones isolating the other derivative avoiding fastidious and time consuming technics, mainly based on immunofluorescent screening using MIC 2 and MIC 5 antigenic markers and we have succeeded in isolating in a rodent context the two X;5 translocated derivative chromosomes of a female patient with Hunter syndrome. The location of MIC 5 gene was specified between the IDS and G6PD DXS369 (RN1), DXS296 (VK21c), and DXS304 (U62), DXS52 and F8c (F814) are proximal and distal from the breakpoint disrupting the IDS gene respectively.     

Expression of an X-linked muscular dystrophy in a female due to translocation involving Xp21 and non-random inactivation of the normal X chromosome

Summary A young female was diagnosed as having X-linked muscular dystrophy of the Duchenne type. Chromosome studies, including trypsin-Giemsa banding, Quinacrine fluorescence, and nucleolus organizer region (NOR) silver staining revealed an X-autosome reciprocal translocation t(X;21) (p21;p12). Utilizing both [³H] thymidine autoradiography and the BrdU-Hoechst 33258-Giemsa technique, lymphocytes and fibroblasts were found to show a preferential inactivation of the normal X suggesting the presence of a single mutant gene on the translocated X. This patient is one of seven reported cases of an X-linked muscular dystrophy associated with an X-autosome translocation. In all seven cases the exchange point in the X chromosome is in band p21 at or near the site of the Duchenne gene.     

Sequence analysis of the breakpoint regions of an X;5 translocation in a female with Duchenne muscular dystrophy.

X;autosome translocations in females with Duchenne muscular dystrophy (DMD) provide an opportunity to study the mechanisms responsible for chromosomal rearrangements that occur in the germ line. We describe here a detailed molecular analysis of the translocation breakpoints of an X;autosome reciprocal translocation, t(X;5)(p21;q31.1), in a female with DMD. Cosmid clones that contained the X-chromosome breakpoint region were identified, and subclones that hybridized to the translocation junction fragment in restriction digests of the patient's DNA were isolated and sequenced. Primers designed from the X-chromosomal sequence were used to obtain the junction fragments on the der(X) and the der(5) by inverse PCR. The resultant clones were also cloned and sequenced, and this information used to isolate the chromosome 5 breakpoint region. Comparison of the DNA sequences of the junction fragments with those of the breakpoint regions on chromosomes X and 5 revealed that the translocation arose by nonhomologous recombination with an imprecise reciprocal exchange. Four and six base pairs of unknown origin are inserted at the exchange points of the der(X) and der(5), respectively, and three nucleotides are deleted from the X-chromosome sequence. Two features were found that may have played a role in the generation of the translocation. These were (1) a repeat motif with an internal homopyrimidine stretch 10 bp upstream from the X-chromosome breakpoint and (2) a 9-bp sequence of 78% homology located near the breakpoints on chromosomes 5 and X.     

Lowe oculocerebrorenal syndrome in a female with a balanced X;20 translocation: mapping of the X chromosome breakpoint.

A Hispanic girl with Lowe oculocerebrorenal syndrome (OCRL), an X-linked recessive condition characterized by cataracts, glaucoma, mental retardation, and proteinuria, is reported. A balanced X;20 chromosomal translocation with the X chromosome breakpoint at q26.1 was found with high-resolution trypsin-Giemsa banding. Somatic cell hybridization was used to separate the X chromosome derivative and the chromosome 20 derivative in order to position, with respect to the translocation breakpoint, several DNA loci that are linked to the Lowe syndrome locus (Xq24-q26). DXS10 and DXS53 were found to be distal to the breakpoint, whereas DXS37 and DXS42 were located proximal to it. These studies suggest that the OCRL locus lies in the region between these probes. The translocation chromosome originated from an unaffected male without a visible translocation, indicating that the most likely cause of OCRL in this patient is the de novo translocation that disrupted the OCRL locus.