Showing papers by "David C. Page published in 1990"

Additional deletion in sex-determining region of human Y chromosome resolves paradox of X,t(Y;22) female.

Abstract: WHETHER a human embryo develops as a male or a female is determined by the presence of the Y chromosome1,2. The sex-determining function lies entirely in interval 1A, inasmuch as most XX individuals with descended testes and normal male external genitalia carry this small region of the Y chromosome3. We have localized an essential part of the sex-determining function to a portion of interval 1A, on the basis of the discovery of a female with a reciprocal Y;22 translocation and part of 1A deleted at the translocation breakpoint3. Recently, a paradox has arisen with the report4 of four partially masculinized XX individuals who carry only a portion of interval 1A—a portion that does not overlap the deletion in the X,t(Y;22) female. These recent findings imply that the sex-determining function lies in the portion of 1A present in the four XX intersexes and not in the portion deleted in the X,t(Y;22) female. To explain the X,t(Y;22) individual, it was proposed that she was female because of a chromosomal position effect4 or delayed development of the gonadal soma5. Here we report that the X,t(Y;22) female has a deletion of a second portion of interval 1A—a portion corresponding closely to that present4 in the XX intersexes. This resolves the apparent contradiction. Nonetheless, phenotype-genotype correlations suggest that two or more genetic elements in interval 1A may contribute to the sex-determining function of the Y chromosome. The X,t(Y;22) female lacks the ZFY gene but does not exhibit the complex phenotype known as Turner's syndrome, arguing against the hypothesis5 that ZFY is the Turner's syndrome gene on the Y chromosome.

Mouse Zfx protein is similar to Zfy-2: each contains an acidic activating domain and 13 zinc fingers.

Abstract: The Zfy gene is located on the Y chromosome of placental mammals and encodes a zinc finger protein which may serve as the primary sex-determining signal. A related gene, Zfx, is similarly conserved on the X chromosome. Unlike that in most mammals, the mouse genome contains four homologous zinc finger loci: Zfy-1, Zfy-2, Zfx, and Zfa (on an autosome). We report that, in contrast to the mouse Zfy genes, Zfx is widely transcribed in embryos, newborns, and adults, both male and female. Moreover, Zfx transcripts contain long 3' untranslated sequences which are phylogenetically conserved. Zfa is a processed gene derived from Zfx. An analysis of cDNA clones demonstrated that Zfx encodes a 799-amino-acid protein that is 70% identical to the mouse Zfy-1 and Zfy-2 proteins. Zfx, Zfy-1, and Zfy-2 contain highly acidic amino-terminal domains and carboxy-terminal regions containing 13 zinc fingers. When fused to the DNA-binding domain of GAL4, the acidic domains of Zfx and Zfy-2 activated transcription in yeast cells.

Steroid sulfatase gene in XX males.

Abstract: The human X and Y chromosomes pair and recombine at their distal short arms during male meiosis. Recent studies indicate that the majority of XX males arise as a result of an aberrant exchange between X and Y chromosomes such that the testis-determining factor gene (TDF) is transferred from a Y chromatid to an X chromatid. It has been shown that X-specific loci such as that coding for the red cell surface antigen, Xg, are sometimes lost from the X chromosome in this aberrant exchange. The steroid sulfatase functional gene (STS) maps to the distal short arm of the X chromosome proximal to XG. We have asked whether STS is affected in the aberrant X-Y interchange leading to XX males. DNA extracted from fibroblasts of seven XX males known to contain Y-specific sequences in their genomic DNA was tested for dosage of the STS gene by using a specific genomic probe. Densitometry of the autoradiograms showed that these XX males have two copies of the STS gene, suggesting that the breakpoint on the X chromosome in the aberrant X-Y interchange is distal to STS. To obtain more definitive evidence, cell hybrids were derived from the fusion of mouse cells, deficient in hypoxanthine phosphoribosyltransferase, and fibroblasts of the seven XX males. The X chromosomes in these patients could be distinguished from each other when one of three X-linked restriction-fragment-length polymorphisms was used. Hybrid clones retaining a human X chromosome containing Y-specific sequences in the absence of the normal X chromosome could be identified in six of the seven cases of XX males.(ABSTRACT TRUNCATED AT 250 WORDS)

A bird zinc-finger protein closely related to ZFY.

Abstract: The ZFY gene is thought to reside in the "sex-determining" region of the mammalian Y chromosome and encodes a zinc-finger protein that may function in determining the sex of embryos. Although birds have a ZZ(male)/ZW(female) sex-determination system, they possess a gene, Zfb, that is highly homologous to ZFY. We used ZFY as a hybridization probe to clone the zinc-finger domain of the chicken Zfb gene. Chicken Zfb is widely transcribed in male and female tissues and encodes a protein with a zinc-finger domain that is 93% identical in amino acid sequence to the zinc-finger domain of ZFY. Thus, the putative DNA-binding domains of the Zfb and ZFY proteins diverged little from a common ancestral protein that existed prior to birds and mammals, suggesting that the DNA binding site has been similarly conserved. The absence of sex differences in the hybridization patterns of Zfb raises the question of whether this gene is present on the Z/W sex chromosomes in birds.