Showing papers on "X chromosome published in 1989"

Androgen receptor locus on the human X chromosome: regional localization to Xq11-12 and description of a DNA polymorphism.

Abstract: The gene for the androgen receptor, mutations at which cause the X-linked androgen insensitivity syndrome, has been localized to the q11----q12 region of the human X chromosome by analysis, using a cloned cDNA for the androgen receptor, of somatic cell hybrid panels segregating portions of the X chromosome. A moderate-frequency HindIII RFLP has been found which should be useful in genetic linkage analysis of the various inherited forms of androgen insensitivity.

Contiguous gene syndromes due to deletions in the distal short arm of the human X chromosome.

Abstract: Mendelian inherited disorders due to deletions of adjacent genes on a chromosome have been described as "contiguous gene syndromes." Short stature, chondrodysplasia punctata, mental retardation, steroid sulfatase deficiency, and Kallmann syndrome have been found as isolated entities or associated in various combinations in 27 patients with interstitial and terminal deletions involving the distal short arm of the X chromosome. The use of cDNA and genomic probes from the Xp22-pter region allowed us to identify 12 different deletion intervals and to confirm, and further refine, the chromosomal assignment of X-linked recessive chondrodysplasia punctata and Kallmann syndrome genes. A putative pseudoautosomal gene affecting height and an X-linked non-specific mental retardation gene have been tentatively assigned to specific intervals. The deletion panel described is a useful tool for mapping new sequences and orienting chromosome walks in the region.

elk, tissue-specific ets-related genes on chromosomes X and 14 near translocation breakpoints

Abstract: The myb-ets-containing acute leukemia virus, E26, transforms myeloblasts and erythroblasts in culture and causes a mixed erythroid and myeloid leukemia in chicks. Genes (ets-1, ets-2, and erg) with variable relatedness to the v-ets oncogene of the E26 virus have been identified, cloned, and characterized in several species. Two new members (elk-1 and elk-2) of the ets oncogene superfamily have now been identified. Nucleotide sequence analysis of the elk-1 cDNA clone revealed that this gene encodes a 428-residue protein whose predicted amino acid sequence showed 82% similarity to the 3' region of v-ets. The elk or related sequences appear to be transcriptionally active in testis and lung. The elk cDNA probe detects two loci in the human genome, elk-1 and elk-2, which map to chromosome regions Xp11.2 and 14q32.3, respectively. These loci are near the translocation breakpoint seen in the t(X;18) (p11.2;q11.2), which is characteristic of synovial sarcoma, and the chromosome 14q32 breakpoints seen in ataxia telangiectasia and other T cell malignancies. This suggests the possibility that rearrangements of elk loci may be involved in pathogenesis of certain tumors.

Recovery of induced mutations for X chromosome-linked muscular dystrophy in mice.

Abstract: We have used elevated levels of plasma creatine phosphokinase activity to identify muscular dystrophy phenotypes in mice and to screen the progeny of chemical mutagen-treated male mice for X chromosome-linked muscular dystrophy mutations. We were not successful in identifying heterozygous carriers of these induced muscular dystrophy mutations in greater than 8000 progeny. However, we were highly successful in identifying three additional alleles of the characterized mdx locus. These alleles of mdx were recovered from various mutagen-treated males and they occur on an X chromosome that carries flanking markers that allow us to follow the mutations in genetic crosses and in the development of corresponding mutant stocks. These alleles have been designated as mdx2Cv, mdx3Cv, and mdx4Cv. Preliminary data show that mice with mdx2Cv and mdx3Cv mutations have muscular dystrophic phenotypes that do not grossly differ from the characterized mdx mutation. These additional mdx mutations expand the value of mouse models of X chromosome-linked muscular dystrophy and potentially define additional sites of mutation that impair dystrophin expression.

Zygotic lethals with specific maternal effect phenotypes in Drosophila melanogaster. I. Loci on the X chromosome.

Abstract: In order to identify all X-linked zygotic lethal loci that exhibit a specific maternal effect on embryonic development, germline clonal analyses of X-linked zygotic lethal mutations have been performed. Two strategies were employed. In Screen A germline clonal analysis of 441 mutations at 211 previously mapped X-linked loci within defined regions was performed. In Screen B germline clonal analysis of 581 larval and pupal mutations distributed throughout the entire length of the X chromosome was performed. These approaches provide an 86% level of saturation for X-linked late zygotic lethals (larval and pupal) with specific maternal effect embryonic lethal phenotypes. The maternal effect phenotypes of these mutations are described.

Chromosome maps of man and mouse. IV.

Abstract: SUMMARY Current knowledge of man-mouse genetic homology is presented in the form of chromosomal displays, tables and a grid, which show locations of the 322 loci now assigned to chromosomes in both species, as well as 12 DNA segments not yet associated with gene loci. At least 50 conserved autosomal segments with two or more loci have been identified, twelve of which are over 20 cM long in the mouse, as well as five conserved segments on the X chromosome. All human and mouse chromosomes now have conserved regions; human 17 still shows the least evidence of rearrangement, with a single long conserved segment which apparently spans the centromere. The loci include 102 which are known to be associated with human hereditary disease; these are listed separately. Human parental effects which may well be the result of genomic imprinting are reviewed and the location of the factors concerned displayed in relation to mouse chromosomal regions which have been implicated in imprinting phenomena.

Germinal mosaicism increases the recurrence risk for 'new' Duchenne muscular dystrophy mutations.

Abstract: In 288 Dutch and Belgian Duchenne and Becker muscular dystrophy families, the parental origin of 41 new deletion or duplication mutations was determined. Twenty seven of the new mutations occurred in the maternal X chromosome and nine in the grandmaternal and five in the grandpaternal X chromosome. The grandparental data are compatible with equal mutation rates for DMD in male and female X chromosomes. New mutations were defined by their presence in one or more progeny and absence in the lymphocytes of the mother or the grandparents. In one family a fraction of the maternal lymphocytes was found to carry the mutation, suggesting somatic mosaicism. In six cases out of 41, the mutation was transmitted more than once by a parent in whom the mutation was absent in lymphocytes, suggesting gonadal mosaicism as the explanation for the multiple transmission. Using our data for the recurrence of the mutations among the total of at risk haplotypes transmitted, we arrive at a recurrence risk of 14% for the at risk haplotype. The observation of this high risk of germinal mosaicism is crucially important for all physicians counselling females in DMD families. Recently, germinal mosaicism has been observed also in a number of other X linked and autosomal disorders. The implications and appropriate diagnostic precautions are discussed.

Trisomy 7 and sex chromosome loss in human brain tissue.

Abstract: Short-term cultures of nonneoplastic brain tissue from 11 patients, seven of whom had a malignant brain tumor, were cytogenetically examined. In only a single case was a wholly normal chromosome compl

Chromosome mapping and expression of a putative testis-determining gene in mouse.

Abstract: Isolation and mapping of a mouse complementary DNA sequence (mouse Y-finger) encoding a multiple, potential zinc-binding, finger protein homologous to the candidate human testis-determining factor gene is reported. Four similar sequences were identified in Hind III-digested mouse genomic DNA. Two (7.2 and 2.0 kb) were mapped to the Y chromosome. Only the 2.0-kb fragment, however, was correlated with testis determination. Polymerase chain reaction analysis suggests both Y loci are transcribed in adult testes. A 3.6-kb fragment was mapped to the X chromosome between the T16H and T6R1 translocation breakpoints, and a fourth (6.0 kb) was mapped to chromosome 10. Hence, mYfin sequences have been duplicated several times in the mouse, although they are not duplicated in humans.

The genetics of postzygotic isolation in the Drosophila virilis group.

Abstract: In a genetic study of postzygotic reproductive isolation among species of the Drosophila virilis group, we find that the X chromosome has the largest effect on male and female hybrid sterility and inviability. The X alone has a discernible effect on postzygotic isolation between closely related species. Hybridizations involving more distantly related species also show large X-effects, although the autosomes may also play a role. In the only hybridization yet subjected to such analysis, we show that hybrid male and female sterility result from the action of different X-linked loci. Our results accord with genetic studies of other taxa, and support the view that both Haldane's rule (heterogametic F1 sterility or inviability) and the large effect of the X chromosome on reproductive isolation result from the accumulation by natural selection of partially recessive or underdominant mutations. We also describe a method that allows genetic analysis of reproductive isolation between species that produce completely sterile or inviable hybrids. Such species pairs, which represent the final stage of speciation, cannot be analyzed by traditional methods. The X chromosome also plays an important role in postzygotic isolation between these species.

Novel genes influencing the expression of the yellow locus and mdg4 (gypsy) in Drosophila melanogaster

Abstract: We used a system with a mobilized Stalker transposable element, sometimes in combination with P-M hybrid dysgenesis, in the search for new mutations interfering with the y 2 mutation induced by mdg4 (gypsy) insertion into the yellow locus. A novel gene, modifier of mdg4, was detected in chromosome 3. The mutation mod(mdg4) either enhanced or suppressed phenotypic changes in different mutations induced by mdg4 insertions. Thus, mod(mdg4) seems to be involved in the control of mdg4 expression. Six other loci designated as enhancers of yellow were also detected. The e(y) n (with n from 1–6) mutations enhanced the expression of several y mutations induced by different insertions into the yellow locus. The major change is a damage of bristle and hair pigmentation which is not suppressed by su(Hw) mutations. On the other hand, e(y) n alleles do not interact with mdg4 induced mutations in other loci. All e(y) n genes are located in different regions of the X chromosome. One may speculate that e(y) n genes are involved in trans-regulation of the yellow locus and possibly of some other loci.

Molecular studies of deletions at the human steroid sulfatase locus.

Abstract: The human steroid sulfatase gene (STS) is located on the distal X chromosome short arm close to the pseudoautosomal region but in a segment of DNA that is unique to the X chromosome. In contrast to most X chromosome-encoded genes, STS expression is not extinguished during the process of X chromosome inactivation. Deficiency of STS (steryl-sulfatase; steryl-sulfate sulfohydrolase, EC 3.1.6.2) activity produces the syndrome of X chromosome-linked ichthyosis, which is one of the most common inborn errors of metabolism in man. Approximately 90% of STS- individuals have large deletions at the STS locus. We and others have found that the end points of such deletions are heterogeneous in their location. One recently ascertained subject was observed to have a 40-kilobase deletion that is entirely intragenic, permitting the cloning and sequencing of the deletion junction. Studies of this patient and of other X chromosome sequences in other subjects permit some insight into the mechanism(s) responsible for generating frequent deletions on the short arm of the X chromosome.

Genetics of sterility in hybrids between two subspecies of drosophila.

Abstract: Hybrids between D. pseudoobscura bogotana and D. pseudoobscura pseudoobscura are fertile except for males produced in one of the two reciprocal crosses. As there is no premating isolation between these subspecies, nonreciprocal male sterility represents the first step in speciation. Genetic analysis reveals two causes of hybrid F, sterility: a maternal effect and incompatibilities between chromosomes within males. The maternal effect appears to play the greatest role in hybrid sterility. The X chromosome has the largest effect on fertility of any chromosome, a ubiquitous result in analyses of hybrid sterility and inviability in Drosophila. This effect is entirely attributable to a region comprising less than 30% of the X chromosome. These results are compared to those from a similar study of D. pseudoobscura-D. persimilis hybrids, an older and more reproductively isolated species pair in the same lineage. Such com- parisons may allow one to identify the genetic changes characterizing the early versus late stages of speciation.

Duplication of an Xp segment that includes the ZFX locus causes sex inversion in man.

Abstract: Two 46,XY females with tandem duplications of an X short arm segment were studied by cytogenetic and Southern blot analysis. The results show that the duplicated segment in each case included the Xp21.2–Xp22.2 interval, resulting in a double dose of ZFX on the single active X chromosome. The results from our two cases, in conjunction with those reported by other workers, lead us to conclude that the duplication is the reason for the sex inversion. If ZFY and ZFX are indeed sex-determining gene loci, these findings favour a model of sex determination characterized by antagonistic interaction between these genes.

Exchange of terminal portions of X- and Y-chromosomal short arms in human XY females.

Abstract: Human Y(+) XX maleness has been shown to result from an abnormal terminal Xp-Yp interchange that can occur during paternal meiosis. To test whether human XY females are produced by the same mechanism, we followed the inheritance of paternal pseudoautosomal loci and Xp22.3-specific loci in two XY female patients. Y-specific sequences and the whole pseudoautosomal region of the Y chromosome of their fathers were absent in these patients. However, the entire pseudoautosomal region and the X-specific part of Xp22.3 distal to the STS locus had been inherited from the X chromosome of the respective father. This Xp transfer to Yp was established by in situ hybridization experiments showing an Xp22.3-specific locus on Yp in both cases. Such results demonstrate that an abnormal and terminal X-Y interchange generated the rearranged Y chromosome of these two XY females; they appear to be the true countertype of Y(+) XX males. In these patients, who also display some Turner stigmata, the Y gene(s) involved in this phenotype is (are) localized to interval 1 or 2. If the loss of such gene(s) affects fetal viability, their proximity to TDF would account for the underrepresentation of interchange 46,XY females compared with Y(+) XX males.

Recombination between small X chromosome duplications and the X chromosome in Caenorhabditis elegans.

Abstract: Twelve new X chromosome duplications were identified and characterized. Eight are translocated to autosomal sites near four different telomeres, and four are free. Ten include unc-1(+), which in wild type is near the left end of the X chromosome, and two of these, mnDp72(X;IV) and mnDp73(X;f), extend rightward past dpy-3. Both mnDp72 and mnDp73 recombined with the one X chromosome in males in the unc-1-dpy-3 interval at a frequency 15- to 30-fold higher than was observed for X-X recombination in hermaphrodites in the same interval. Recombinant duplications and recombinant X chromosomes were both recovered. Recombination with the X chromosome in the unc-1-dpy-3 interval was also detected for five other unc-1(+) duplications, even though their right breakpoints lie within the interval. In hermaphrodites, mnDp72 and mnDp73 promoted meiotic X nondisjunction and recombined with an X chromosome in the unc-1-dpy-3 interval at frequencies comparable to that found for X-X recombination; mnDp72(X;IV) also promoted trisomy for chromosome IV. A mutation in him-8 IV was identified that severely reduced recombination between the two X chromosomes in hermaphrodites and between mnDp73 and the X chromosome in males. Recombination between the X chromosome and duplications of either the right end of the X or a region near but not including the left end was rare. We suggest that the X chromosome has one or more elements near its left end that promote meiotic chromosome pairing.

Choroideremia and deafness with stapes fixation: a contiguous gene deletion syndrome in Xq21.

Abstract: The study of contiguous gene deletion syndromes by using reverse genetic techniques provides a powerful tool for precisely defining the map location of the genes involved We have made use of individuals with overlapping deletions producing choroideremia as part of a complex phenotype, to define the boundaries on the X chromosome for this gene, as well as for X-linked mixed deafness with perilymphatic gusher (DFN3) Two patients with deletions and choroideremia are affected by an X-linked mixed conductive/sensorineural deafness; one patient, XL-62, was confirmed at surgery to have DFN3, while the other patient, XL-45, is suspected clinically to have the same disorder A third choroideremia deletion patient, MBU, has normal hearing Patient XL-62 has a cytogenetically detectable deletion that was measured to be 77% of the X chromosome by dual laser flow cytometry; the other patient, XL-45, has a cytogenetically undetectable deletion that measures only 33% of the X chromosome We have produced a physical map of the X-chromosome region containing choroideremia and DFN3 by using routine Southern blotting, chromosome walking and jumping techniques, and long-range restriction mapping to generate and link anonymous DNA sequences in this region DXS232 and DXS233 are located within 450 kb of each other on the same SfiI and MluI fragments and share partial SalI fragments of 750 and greater than 1,000 kb but are separated by at least one SalI site In addition, DXS232, which lies outside the MBU deletion, detects the proximal breakpoint of this deletion We have isolated two new anonymous DNA sequences by chromosome jumping from DXS233; one of these detects a new SfiI fragment distal to DXS233 in the direction of the choroideremia gene, while the other jump clone is proximal to DXS233 and detects a new polymorphism These data refine the map around the loci for choroideremia and for mixed deafness with stapes fixation and will provide points from which to isolate candidate gene sequences for these disorders

Genetic analysis of X-linked sterility in hybrids between three sibling species of Drosophila.

Abstract: Three morphological markers (yellow, miniature, and forked) are used to map the location of X-chromosome segments causing male sterility in Drosophila simulans/D. mauritiana and D. simulans/D. sechellia hybrids. In both hybridizations at least three sections of the chromosome contain genes with substantial effects on sterility. This represents the maximum genetic divergence detectable with the three markers, suggesting that the X chromosome contains many loci affecting postzygotic reproductive isolation. The tight linkage between some markers and "sterility loci" may be useful in localizing and later cloning genes important in speciation.

The Chromosomal Basis of Sex Differentiation in Marsupials

Abstract: Data on ten intersexual marsupials, eight of which were of known karyotype, are presented and reviewed. Three of the intersexes were known or suspected XO/XX or XO/XX/XXX, two were XXY, one was XXY/XY/XX and two were XY in sex chromosome constitution. In all three intersexes which had an XO cell line, but in which no Y chromosome was found in any cell, a small empty scrotum was found to one side of the midline or in the midline. Those which had a non-midline scrotum had mammary tissue on the opposite side and a partial or complete pouch. The intersex with the midline scrotum had no pouch or mammary glands. Unilateral or bilateral putative spermatic cords, not containing a ductus deferens, descended to the scrotum, but in all other respects the internal reproductive systems were like those of normal XX female marsupials. Intersexes with no Y chromosome were of female body size when adult. The XXY and XXY/XY/XX intersexes all had complete pouches and mammary glands and none had a scrotum. All had well developed male internal reproductive systems and undescended testis-like gonads, and were of intermediate body size. Both XY intersexes also had complete pouches and mammary glands, no scrotum, and male-type internal reproductive systems with undescended testes which were normal except for absence of post- primary spermatocyte stages of spermatogenesis. One XY intersex was fully adult and it did not differ from normal XY males of the same species in body measurements, body weight and secondary sex coloration. One of the intersexes of unknown karyotype, but of suspected XX chromosome constitution, was morphologically like the XO/XX/XXX mosaic with a centrally placed scrotum. The other, of suspected XY chromosome constitution, was essentially comparable to the XY intersexes. The data are interpreted, at the whole chromosome level, as follows. In the presence of a single active X chromosome scrotal and spermatic cord development were initiated, whereas they were inhibited in the presence of two X chromosomes. Complete scrotal development completely inhibited, and unilateral scrotal development partly inhibited, pouch and mammary gland development. The Y chromosome was responsible for primary gonadal sex and, apparently through production of MIS, eliminated the Miillerian (i.e. female) sex ducts. Development of a male type of reproductive system was dependent on presence of a Y chromosome and, apparently, androgen production from testes or testis-like gonads. At the gene level the data may be interpreted in terms of a hypothetical S or 'switch' locus, carried on the X chromosome, which induced scrotal development in single dose and a pouch and mammary glands in double dose. If this hypothesis is correct, it would explain the occurrence of incomplete X-chromosome inactivation in marsupials; complete X-inactivation is impossible in marsupials because it would leave each female with a scrotum, not a pouch.

A study of ten families of transposable elements on X chromosomes from a population of Drosophila melanogaster.

Abstract: Data were collected on the distribution of ten families of transposable elements among fourteen X chromosomes isolated from a natural population of Drosophila melanogaster, by means of in situ hybridization to polytene chromosomes. It was found that, with the exception of roo, the copy number per chromosome followed a Poisson distribution. There was no evidence for linkage disequilibrium, either within or between families. Some pairs of families of elements were correlated with respect to the identity of the sites that were occupied in the sample, although there was no evidence for a correlation with respect to the sites at which elements attained relatively high frequencies. Elements appeared to be distributed randomly along the distal part of the X chromosome. There was, however, a strong tendency for elements to accumulate at the base of the chromosome. Element frequencies per chromosome band were generally low, except at the base of the chromosome where bands in subdivisions 19E and 20A sometimes had high frequencies of occupation. These results are discussed in the light of models of the population dynamics of transposable elements. It is concluded that they provide strong evidence for the operation of a force or forces opposing transpositional increase in copy number. The accumulation of elements at the base of the chromosome is consistent with the idea that unequal exchange between elements at non-homologous sites is such a force, although other possibilities cannot be excluded at present. The data suggest that the rate of transposition per element per generation is of the order of 10(-4), for the elements included in this study.

Male infant with ichthyosis, Kallmann syndrome, chondrodysplasia punctata, and an Xp chromosome deletion

Abstract: We report on a male infant with X-linked ichthyosis, X-linked Kallmann syndrome, and X-linked recessive chondrodysplasia punctata (CPXR). Chromosome analysis showed a terminal deletion with a breakpoint at Xp22.31, inherited maternally. This patient confirms the localization of XLI, XLK, and CPXR to this region of the X chromosome and represents an example of a "contiguous gene syndrome." A comparison of the manifestations of patients with CPXR, warfarin embryopathy, and vitamin K epoxide reductase deficiency shows a remarkable similarity. However, vitamin K epoxide reductase deficiency does not appear to be the cause of CPXR. We propose that CPXR may be due to a defect in a vitamin K-dependent bone protein such as vitamin K-dependent bone carboxylase, osteocalcin, or matrix Gla protein.

Molecular cytological differentiation of active from inactive X domains in interphase: implications for X chromosome inactivation.

Abstract: A fluorescence in situ hybridization method using a biotinylated DNA probe specific for the centromeric region of the human X chromosome was used to differentiate the genetically active from the inactive X in interphase cells. With this technique, we were able to interpret both the relative position and the degree of condensation of the X chromosomes within the nucleus. We first established the specificity of fluorescence labelling of the hybridized probe by comparing its location and appearance (either dense or diffuse) when associated with a sex chromatin body (SCB) in early passage normal human female fibroblasts. In these cells, where the presence of inactive X chromatin was verified by identification of a 4',6-diamidino-2-phenyl indole (DAPI)-positive SCB in 85% of the cells examined, the X chromatin fluorescence was always associated with the SCB. The signal was dense in structure in 98% and peripheral in location in 80% of the nuclei. A second type of signal, diffuse in form, was observed in 85% of the nuclei and presumably represents the location of the active X chromosome. It was located peripherally or centrally with equal frequency and was not associated with any identifiable nuclear component. This diffuse signal was the major type associated with human male fibroblasts. In rodent x human hybrid cells containing a human inactive X, the fluorescent signal was associated with an SCB-like structure in only 13% of the nuclei; it was dense in 66% of the nuclei and equally peripheral or central in location. This indicates an alteration in the interphase structure of the human inactive X chromosome in hybrid cells which may explain its known instability with respect to genetic activity in such systems.

Assignment of human genes for phosphorylase kinase subunits alpha (PHKA) to Xq12-q13 and beta (PHKB) to 16q12-q13.

Abstract: Phosphorylase kinase (PHK), the enzyme that activates glycogen phosphorylases in muscle, liver, and other tissues, is composed of four different subunits. Recently isolated rabbit muscle cDNAs for the larger two subunits, alpha and beta, have been used to map the location of their cognate sequences on human chromosomes. Southern blot analysis of rodent x human somatic cell hybrid panels, as well as in situ chromosomal hybridization, have provided evidence of single sites for both genes. The alpha subunit gene (PHKA) is located on the proximal long arm of the X chromosome in region Xq12-q13 near the locus for phosphoglycerate kinase (PGK1). X-linked mutations leading to PHK deficiency, known to exist in humans and mice, are likely to involve this locus. This hypothesis is consistent with the proximity of the Phk and Pgk-1 loci on the mouse X chromosome. In contrast, the beta subunit gene (PHKB) was found to be autosomal and was mapped to chromosome 16, region q12-q13 on the proximal long arm. Several different autosomally inherited forms of PHK deficiency for which the PHKB could be a candidate gene have been described in humans and rats.