Moderately repeated DNA sequences specific for the short arm of the human Y chromosome are present in XX males and reduced in copy number in an XY female

The role of SRY in mammalian sex determination

The gene SRY (sex determining region of the Y), located at the distal region of the short arm of the Y chromosome, is necessary for male sex determination in mammals. SRY initiates the cascade of steps necessary to form a testis from an undifferentiated gonad. The SRY gene encodes an HMG (High Mobility Group) protein which may act as a transcription factor by binding to double stranded DNA and then bending the DNA. Mutations in SRY have been identified in some subjects with 46,XY pure gonadal dysgenesis. However the role for other autosomal and X-linked genes in testis determination is evident by the presence of a normal SRY gene in the majority of females with 46,XY pure gonadal dysgenesis and the lack of SRY in a minority of males with 46,XY maleness.

Primary infertility in a phenotypic male with 46XX chromosomal constitution

The case of a 32 year old male with normal male adrenarchal hair pattern, bilateral gynaecomastia, a small phallus, hypospadias and bilateral poorly developed testes presenting with primary infertility secondary to azoospermia and a pelvic cyst is described. Repeated chromosomal analysis showed 46XX chromosomal constitution. Laparotomy revealed a simple cyst between the urinary bladder and the rectum. XX male syndrome is a rare cause of male infertility. The majority of cases is due to interchange of a fragment of the short arm of the Y chromosome containing the region that encodes the testes determining factor with the X chromosome. The presence of a simple cyst in the anatomical location of the uterus to our knowledge has not been reported in the literature.

Chromatid contamination can impair the purity of flow-sorted metaphase chromosomes

We describe a phenomenon where a second flow karyotype is superimposed on the normal metaphase flow karyotype of human lymphoblastoid chromosomes. The events of this second flow karyotype contain half the DNA content of corresponding events in the normal flow karyotype and, when sorted, show the morphology of single chromatids. DNA amplified by degenerate oligonucleotide-primed PCR of 300 chromatids sorted from a single peak and hybridized onto normal metaphase spreads painted the entire length of the corresponding chromosome type. In retrospect, we could observe this phenomenon at a low level in 37% of randomly selected, previously analyzed flow karyotypes and in several published flow karyotypes from other laboratories. Experimentally, chromatid frequency was shown to vary with the colcemid blocking conditions as well as with the cell line used. At the extreme, we obtained a 4:10 ratio of chromatids to metaphase chromosomes, whereas this could be reduced tenfold by altering the colcemid blocking conditions in the same cell line. The presence of chromatids in chromosome preparations has important implications for the purity of isolated fractions used for generating libraries and in PCR analysis.

Absence of Turner stigmata in a 46,XYp-female

A 46,XY female patient with streak gonads and a large deletion of Yp is described. The deletion included the Y chromosomal genes SRY, ZFY, and RPS4Y. The patient did not display any Turner stigmata, such as webbing of the neck, cardiac or other abnormalities. The findings argue against an important role of RPS4Y in the prevention of Turner stigmata in males and are consistent with a role of SRY in testis differentiation in humans.

Microdeletions in interval 6 of the Y chromosome of males with idiopathic sterility point to disruption of AZF, a human spermatogenesis gene

For males with idiopathic sterility, a molecular screen specific for small lesions (microdeletions) in interval 6 of the Y chromosome was set up using 29 Y-DNA probes. A "de novo" microdeletion in Y interval 6 was detected in 2 out of 19 "chromosomally normal" sterile males. The first microdeletion includes the Y-DNA probes pY6HP35 and 12f3; the second microdeletion includes the Y-DNA probes pY6HP52, 49f, FR15-II and the subinterval "C" of probe 50f2. A probe of the pY6H sequence family is present in both deletions. Sequences of this family cross-hybridize to dhMiF1, a DNA sequence of a fertility gene structure on the Y chromosome of Drosophila hydei. It was possible to map the position of the Y-deletion of one patient to the distal part of Yq11.22 or the proximal part of Yq11.23, and the deletion of the second patient to the distal part of Yq11.23. These microdeletions probably do not overlap. Since AZF, a human spermatogenesis gene, has been mapped to Y interval 6, we postulate that the microdeletions detected in this chromosome region affect the functional DNA structure of the AZF gene. If this holds true, it is possible that the AZF locus, cytogenetically mapped to distal Yq11, contains two spermatogenesis genes (AZFa and AZFb) or a large gene structure comparable to the Y fertility genes of Drosophila.

Simple repeat sequences on the human Y chromosome are equally polymorphic as their autosomal counterparts

The human genome contains a large number of interspersed simple repeat sequences that are variable in length and can therefore serve as highly informative, polymorphic markers. Typing procedures include conventional multilocus and single locus probing, and polymerase chain reaction aided analysis. We have identified simple sequences in a cosmid clone stemming from the human Y chromosome and consisting of (gata)n repeats. We have compared these with two equivalent simple repeat loci from chromosome 12. After amplifying the tandemly repeated motifs, we detected between four and eight different alleles at each of the three loci. Codominant inheritance of the alleles was established in family studies and the informativity of the simple repeat loci was determined by typing unrelated individuals. The polymorphisms are suitable for application in linkage studies, practical forensic case work, deficiency cases in paternity determination, and for studying ethnological questions. The mutational mechanisms that bring about changes in simple repeats located both on the autosomes and on the sex chromosomes, are discussed.

Partial gonadal dysgenesis in a patient with a marker Y chromosome

We evaluated a patient with partial gonadal dysgenesis including a right dysgenetic testis and a left streak gonad with rudimentary fallopian tube and uterus. She had ambiguous external genitalia and was raised female. Although her height is normal (25th centile at age 12 years), she has some findings of Ullrich-Turner syndrome. Her karyotype was reported to be 46,X,+marker; subsequent molecular investigations showed the marker to be the short arm of the Y chromosome. Genomic DNA, isolated from leukocytes of the patient and her father, was digested with a variety of restriction endonucleases and subjected to Southern blot analysis. A positive hybridization signal was obtained with probes for the short arm of the Y chromosome (pRsY0.55, SRY, ZFY, 47Z, pY-190, and YC-2) in DNA from the patient, indicating the presence of most if not all of the short arm, while long arm probes (HinfA and pY3.4) indicated that at least 75% of the long arm of the Y chromosome was missing. The gene responsible for testicular determination (TDF) is on the distal portion of the short arm of the Y chromosome; Yq has no known influence on sex determination. Hence, the deletion of the long arm of the Y chromosome cannot explain the gonadal dysgenesis in this patient. One explanation for the gonadal dysgenesis and Ullrich-Turner phenotype in the patient could be undetected 45,X/46,X,+marY mosaicism but no such mosaicism was observed in peripheral lymphocytes. Several investigators have suggested the presence of an "anti-Turner" gene near TDF. Hence it is possible that the clinical phenotype in our patient results from a Y chromosomal defect in sequences flanking TDF, which reduces the function of both TDF and the "anti-Turner" genes.

Molecular cytogenetic analysis of XX males using Y-specific DNA sequences, including SRY

XX maleness is the most common condition in which testes develop in the absence of a cytogenetically detectable Y chromosome. Using molecular techniques, it is possible to detect Yp sequences in the majority of XX males. In this study, we could detect Y-specific sequences, including the sex-determining region of the Y chromosome (SRY), using fluorescence in situ hybridization. In 5 out of 6 previously unpublished XX males, SRY was translocated onto the terminal part of an X chromosome. This is the first report in which translocation of an SRY-bearing fragment to an X chromosome in XX males could be directly demonstrated.

Dystonia-parkinsonism syndrome (XDP) locus: flanking markers in Xq12-q21.1

The study of rare genetic forms of dystonia and parkinsonism permits positional cloning of genes potentially involved in more common, multifactorial forms of these diseases. One movement disorder amenable to molecular genetic analysis is the X-linked dystonia-parkinsonism syndrome (XDP). This disease is endemic to the Philippines where it originated by a genetic founder effect. Linkage analysis was performed with DNA from 14 XDP kindreds by using 12 polymorphic DNA sequences in Xp11-Xq22. Two-point analysis demonstrated maximum lod scores of 5.45, 4.95, 4.28, and 5.99 for DXS106, DXS159, PGK1, and DXS72, respectively, at recombination fractions of zero (DXS106 and DXS159), .01 (PGK1), and .04 (DXS72). Multipoint analysis resulted in a maximum-likelihood score (Zmax) of 8.41 with a (Zmax - 1) support interval of 9 cM between DXS159 and DXS72 (Xq12-q21.1). In 19 XDP kindreds significant linkage disequilibrium was found for loci DXS72 (delta = .47), PGK1 (delta = .36), DXS95 (delta = .30), DXS106 (delta = .28), and DXS159 (delta = .26). These data indicate that the gene mutated in XDP (locus DYT3) is located in Xq12-q21.1.

Molecular analysis of aberrations of Xp and Yq

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.

True hermaphroditism in a wild sheep: A clinical report

Intersexuality in sheep is rare, with the freemartin anomaly being the most common. We describe here a true hermaphrodite in a wild sheep. An F(1) wild sheep ewe of Argali-mouflon X Mexican desert bighorn breeding was bred to an F(1) ram of the same breeding. A single lamb was born with the external appearance of a normal female. The lamb grew faster than its female cohorts, and by 6 months of age exhibited the aggressive behavior, size, coloration and horn development associated with males. Phenotypically, the intersex had female external genitalia with an enlarged clitoris. A human chorionic gonadotrophin (hCG) response test was performed when the intersex was 1-year-old and serum testosterone, progesterone and estradiol levels were compared to the response of a normal female and male of similar age and breeding. An exploratory celiotomy revealed two gonadal-like structures associated with a female reproductive tract. Histopathology of the structures revealed spermatogenically inactive testicular vessels and ovarian tissue with primary follicles. The reproductive tract was complete with two uterine horns and a cervix. The intersexuality is attributed to an XX/XXY mosaic.

Deletion mapping of DNA segments from the Y chromosome long arm and their analysis in an XX male

Twelve DNA segments have been localized to the long arm of the Y chromosome and were assigned to three intervals by deletion mapping. Of these segments, six were from distal Yq11.23, which is supposed to contain a spermatogenesis locus. The physical mapping information was used to analyze an XX male who is positive for DNA sequences both from distal Yp and from Yq. Two of the twelve sequences from Yq (Y-198 and Y-253) were detected in this patient along with two of six short-arm segments tested. Long-range physical mapping placed Y-198 and Y-253 on a common 1100-kb BssHII fragment. In this patient, the long-arm sequences were assigned to distal Xp by in situ hybridization. The data suggest that this XX male derived from an unequal interchange between an X and an inverted Y chromosome presumed to have been present in the patient's father.

Origin of the supernumerary X chromosome in a patient with fragile X and Klinefelter syndrome

We report on a 10-year-old patient with the fragile X [fra(X)] syndrome and a 47,XXY karyotype. He had Martin-Bell syndrome, including typical craniofacial findings and mental retardation. The fra(X) was detected on both X chromosomes of the patient in 8% of the metaphases examined. DNA analysis using X-chromosome sequences from the pericentromeric region and from distal Xq suggests that the patient is homozygous at the fra(X) locus due to maternal nondisjunction during meiosis II.

Clinical management issues in males with sex chromosomal mosaicism and discordant phenotype/sex chromosomal patterns

The recent availability of Y DNA probes has made it possible to identify two forms of 46,XX male syndrome: Y DNA positive and Y DNA negative. The Y DNA positive male results from a X;Y translocation with a low recurrence risk; the Y DNA negative males are due to a mutation with a high recurrence risk. 46,XX males and mosaic forms are phenotypically indistinguishable. A review of the case histories for 11 individuals indicates that affected males have highly variable genital and nongenital phenotypes. Physical findings may be clearly apparent or nonexistent. With the exception of external genitalia, the basis for this variability is unknown. It may be related to differences in Y chromatin expression as the result of variable inactivation of the X chromosomes, or to the existence of minor deletions or point mutations secondary to an exchange of genetic material. Common and uncommon clinical problems in these individuals require evaluation and follow-up care that is provided through a cooperative, interdisciplinary approach.

Cytogenetic and molecular analysis of a Yq isochromosome

The dicentric Yq isochromosome of a male with azoospermia and some features of Klinefelter's syndrome was examined using cytogenetic and molecular methods. C- and R-banding of chromosomes of peripheral blood lymphocytes revealed a complex mosaic consisting of 46,X,i(Yq)/45,XO/46,XY/47,XYY/47,XY, i(Yq)/47,X,i(Yq),i(Yq) cells. EBV-transformed lymphocytes either had a 46,X,i(Yq) (90%) or a 46,X, + mar (10%) karyotype. The marker chromosome was shown to be Y-derived by in situ hybridization. C-banding, quinacrine- and DA/DAPI-staining indicated inactivation of one of the centromeres in almost all Yq isochromosomes. The use of Y chromosomal DNA sequences demonstrated that most of the Y chromosome, including its short arm, was duplicated.

A human XY female with a frame shift mutation in the candidate testis-determining gene SRY

The primary decision about male or female sexual development of the human embryo depends on the presence of the Y chromosome, more specifically on a gene on the Y chromosome encoding a testis-determining factor, TDF. The human sex-determining region has been delimited to a 35-kilobase interval near the Y pseudoautosomal boundary. In this region there is a candidate gene for TDF, termed SRY, which is conserved and specific to the Y chromosome in all mammals tested. The corresponding gene from the mouse Y chromosome is deleted in a line of XY female mutant mice, and is expressed at the expected stage during male gonadal development. We have now identified a mutation in SRY in one out of 12 sex-inversed XY females with gonadal dysgenesis who do not lack large segments of the short arm of the Y chromosome. The four-nucleotide deletion occurs in a sequence of SRY encoding a conserved DNA-binding motif and results in a frame shift presumably leading to a non-functional protein. The mutation occurred de novo, because the father of the sporadic XY female that bears it has the normal sequence at the corresponding position. These results provide strong evidence for SRY being TDF.

Determining the origins and the structural aberrations of small marker chromosomes in two cases of 45,X/46,X, + mar by use of chromosome-specific DNA probes

A 17-year-old girl (S.M.) and a 13-year-old girl (C.L.) both with Ullrich-Turner syndrome (UTS) were found to have 45,X/46,X, + mar mosaicism. The marker chromosomes in both patients were very small in size. In S.M. the marker chromosome was present in 80% of phytohemagglutinin-stimulated lymphocytes, 28% of skin fibroblasts, and 11-20% of gonadal fibroblasts. In C.L., the small marker chromosome was found in 50% of stimulated lymphocytes. S.M. is of normal height, but C.L. is short. Molecular hybridization with a number of Y-specific DNA probes demonstrated their presence in S.M. but absence in C.L. In situ hybridization with Y-specific and X-centromere-specific DNA probes confirmed the Y origin of the marker chromosome in S.M. and the X origin of the minute chromosome in C.L. Biotinylated centromere and telomere probes were also used for in situ hybridization to show the presence of centromeric and telomeric sequences in the Y-marker chromosome, suggesting that the deletion of this marker chromosome is interstitial.

A physical map of the human Y-chromosome short arm

A physical map of the Y-chromosome short arm was constructed using DNA probes p19B, Y-286/la5, pZFY, Y-280, and Y-227. These probes hybridize with four NotI fragments of 400 kb (p19B and Y-286/la5), 350 kb, 1.9 Mb, and 3.0 Mb, respectively. The restriction fragments were shown to be adjacent to each other by analysis of NotI partial digests, overlapping restriction fragments, and/or the detection of rearranged restriction fragments in a 46,XX male. The present map covers approximately 5.6 Mb of contiguous DNA of Yp. Previously, the size of the pseudoautosomal region was estimated to be 2.3 Mb, and a 5.3-Mb NotI fragment containing Y-specific repeated DNA was assigned to proximal Yp. These and the present data account for approximately 13 Mb and thus for most of the DNA content of the Y short arm.

Deletion mapping of 39 random isolated Y-chromosome DNA fragments

Thirty-nine recombinants isolated from a Y chromosome-specific library were deletion mapped. Seven deletion intervals were defined by hybridization of probes to DNA of eight individuals with aberrant Y chromosomes. Extreme cytogenetic limits of the deletion intervals were determined by in situ hybridization of one probe per deletion interval. Five intervals, with a total of twenty-five probes, were allocated to the long-arm euchromatic region. The probes described will be useful for characterization of aberrant Y chromosomes, in searching for expressed sequences on the Y chromosome, and for further study of the evolutionary relationship between the Y chromosome and other chromosomes.

Isolation of fetal DNA from nucleated erythrocytes in maternal blood

Fetal nucleated cells within maternal blood represent a potential source of fetal genes obtainable by venipuncture. We used monoclonal antibody against the transferrin receptor (TfR) to identify nucleated erythrocytes in the peripheral blood of pregnant women. Candidate fetal cells from 19 pregnancies were isolated by flow sorting at 12 1/2-17 weeks gestation. The DNA in these cells was amplified for a 222-base-pair (bp) sequence present on the short arm of the Y chromosome as proof that the cells were derived from the fetus. The amplified DNA was compared with standardized DNA concentrations; 0.1-1 ng of fetal DNA was obtained in the 20-ml maternal samples. In 7/19 cases, a 222-bp band of amplified DNA was detected, consistent with the presence of male DNA in the isolated cells; 6/7 of these were confirmed as male pregnancies by karyotyping amniocytes. In the case of the female fetus, DNA prepared from samples at 32 weeks of gestation and cord blood at delivery also showed the presence of the Y chromosomal sequence, suggesting Y sequence mosaicism or translocation. In 10/12 cases where the 222-bp band was absent, the fetuses were female. Thus, we were successful in detecting the Y chromosomal sequence in 75% of the male-bearing pregnancies, demonstrating that it is possible to isolate fetal gene sequences from cells in maternal blood. Further refinement in methodology should increase sensitivity and facilitate noninvasive screening for fetal gene mutations.

Potential genetic functions of tandem repeated DNA sequence blocks in the human genome are based on a highly conserved "chromatin folding code"

This review is based on a thorough description of the structure and sequence organization of tandemly organized repetitive DNA sequence families in the human genome; it is aimed at revealing the locus-specific sequence organization of tandemly repetitive sequence structures as a highly conserved DNA sequence code. These repetitive so-called "super-structures" or "higher-order" structures are able to attract specific nuclear proteins. I shall define this code therefore as a "chromatin folding code". Since locus-specific superstructures of tandemly repetitive sequence units are present not only in the chromosome centromere or telomere region but also on the arms of the chromosomes, I assume that their chromatin folding code may contribute to, or even organize, the folding pathway of the chromatin chain in the nucleus. The "chromatin folding code" is based on its specific "chromatin code", which describes the sequence dependence of the helical pathway of the DNA primary sequence (i.e., secondary structure) entrapping the histone octamers in preferential positions. There is no periodicity in the distribution of the nucleosomes along the DNA chain. The folding pathway of the nucleosomal chromatin chain is however still flexible and determined by e.g., the length of the DNA chain between the nucleosomes. The fixation and stabilization of the chromatin chain in the space of the nucleus (i.e., its "functional state") may be mediated by additionally unique DNA protein interactions that are dictated by the "chromatin folding code". The unique DNA-protein interactions around the centromeres of human chromosomes are revealed for example by their "C-banding". I wish to stress that it is not my aim to relate each block of repetitive DNA sequences to a specific "chromatin folding code", but I shall demonstrate that there is an inherent potential for tandem repeated sequence units to develop a locus-specific repetitive higher order structure; this potential may create a specific chromatin folding code whenever a selection force exists at the position of this repetitive DNA structure in the genome.

Maternal meiosis II nondisjunction in a case of 47,XXY testicular feminization

An 11-year-old patient with incomplete testicular feminization and a 47,XXY karyotype is described. The patient had female external genitalia, clitoromegaly, and some features of Klinefelter's syndrome, including speech delay and delayed intellectual development. DNA analysis using X chromosomal DNA sequences suggest that the supernumerary X chromosome in the patient resulted from maternal nondisjunction during meiosis II. The M II error thereby provides the basis for homozygosity of a mutation in the androgen receptor locus.

Steroid sulfatase gene in XX males

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)

Study of X chromosome abnormality in XX males using bivariate flow karyotype analysis and flow sorted dot blots

We have used bivariate flow karyotype analysis to quantify aberrant X chromosome size in 11 XX males. With one exception, the patients could be grouped into those with an X homologue difference greater than normal (Group A, n = 3) and into those whose X homologue difference could not be distinguished from female controls (Group B, n = 7). The range of sizes of the aberrant X chromosome in Y-sequence positive patients agrees with the variable nature of the X-Y interchange in these individuals as determined by the use of Y-specific DNA probes and Southern blotting analysis. In one patient it was possible to sort separately the normal and the X-Y interchanged homologues for dot blot analysis. The presence of Y sequences and an increased dose of the zinc finger gene, ZFY, were detected in the X-Y interchanged homologue. In preliminary studies of 5 male and 6 female controls, it was noted that a consistent difference between the two X homologues in females was found which could not be totally explained by errors of the fitting procedure. We suggest that this difference could be due to X inactivation and that the two X homologues in females might be distinguishable.

Genotype-phenotype correlations in XX males and their bearing on current theories of sex determination

Clinical, chromosomal and molecular studies of a group of 15 XX males confirm the presence of two main groups. A Y + ve group of ten patients exhibit sex reversal as the result of transfer of the distal end of the short arm of the Y chromosome, including testis determining factors, to the short arm of one X-chromosome, presumably by accidental crossing-over in paternal meiosis. The ten patients have Klinefelter's syndrome but differ from XXY cases in that they are short and shown no impairment of intelligence. The four Y-ve XX males have no demonstrable Y sequences and differ from Y + ve cases in abnormality of the external genitalia and invariable gynaecomastia; in this, they more closely resemble XX true hermaphrodites than XY males. These observations on Y - ve XX males and an additional exceptional Y + patients suggest that the ZFY locus is not essential for male differentiation and is not the primary testis determining factor. Male sex determination in sporadic, and familial Y-ve XX males and true hermaphrodites is likely to be the result of mutation in an X-linked TDF gene and its consequent escape from the constraints of X-inactivation. It seems premature to abandon the dosage model of sex determination on the recent evidence that ZFX does not show dosage compensation.

Parental origin of the extra chromosome in trisomy 18

The parental origin of the supernumerary chromosome 18 was investigated by RFLP analysis in 23 individuals with Edwards syndrome. All families were studied with the DNA probe pERT-25, which recognizes a locus of highly polymorphic tandemly repeated DNA sequences on chromosome 18. The extra chromosome was found to be of maternal origin in 19 patients (95%), of paternal origin in one patient (5%), and indeterminate in three patients. In one of the three indeterminate cases, a mosaic, an apparent recombination event had taken place within the pERT-25 locus. The overall high degree of informativeness of pERT-25 illustrates the power of a chromosome-specific variable-number tandem repeat probe (VNTR) in parental origin studies of aneuploidy.

Livestock embryo sexing: A review of current methods, with emphasis on Y-specific DNA probes

Control of the sex ratio of domestic species is potentially of great commercial importance to agriculture. While sexing of spermatozoa would be the most advantageous approach, studies to date suggest that this technology is unlikely to be available in the near future. As an alternative, four methods of sexing embryos have been developed. The use of X-linked enzymes and a serological assay involving H-Y antigen are noninvasive methods which have the advantage of allowing all embryos to be sexed, but these methods are not always accurate. Cytogenetic analysis and the use of Y-specific DNA probes are invasive methods which are limited by the accessibility of embryonic material for biopsy, but they are highly accurate. Each method is reviewed, with an emphasis on the use of Y-linked probes, and each is seen to have both advantages and limitations; the difficulty is in achieving a method that provides both an accurate sexing procedure and an acceptable pregnancy rate after embryo transfer. While no single method currently available fulfills all the criteria for a commercial method of embryo sexing, the potential for the development of an ideal method does exist.

Breakage of the human Y-chromosome short arm between two blocks of tandemly repeated DNA sequences

Y-chromosomal rearrangements, a common cause of sex reversal in man, frequently occur between two blocks of repeated DNA. Both blocks are composed of 20-kb tandemly repeated Y-chromosome-specific DNA sequences. They are located in the proximal portion of the Y short arm on a NotI restriction fragment of approximately 5.3 Mb and on an MluI fragment of approximately 5.5 Mb. Chromosome breaks positioned between the two blocks were detected in two of three 46,XY females with deletions of Yp and in five of six 46,XX males positive for the repeat sequences. The rearranged NotI fragments in the 46,XX males were 4.4 Mb and the MluI fragments were 2.0 Mb in length. This indicates that breaks occur within a small region of Yp defined by the two blocks of specific repeated DNA sequences. The region between the two blocks thus appears to be a focus of structural lability in the human Y chromosome.

Evidence for distinguishable transcripts of the putative testis determining gene (ZFY) and mapping of homologous cDNA sequences to chromosomes X,Y and 9

Oligonucleotide sequences based on the amino acid sequence of the putative testis determining gene ZFY have been used to isolate a 1.3 Kb Hind III Y genomic DNA fragment CMPXY1 and three human testis cDNA sequences (CMPXY2, CMPXY3 and CMPXY4). These sequences detect at least four potential exons on the Y (Y1, Y3, Y4 and Y5), three on the X (X1, X2 and X3) and three of autosomal origin (A1, A2 and A3) as determined by comparing the fragments detected by different clones. Analysis with subfragments of CMPXY4 shows that Y3 is unique to the Y and that Y4 and X1 are homologous. Y5 and X3 are detected by the same subfragment of CMPXY4. This is also the case for Y1, X2, A1, A2 and A3. Thus these exons may contain further regions of homology between the X, Y and an autosomal locus. The X-linked sequences all lie in Xp21.2-Xp22.1 and studies with XX males have placed the Y-linked sequences in distal Yp adjacent to the Y-autosomal homologous sequence GMGY3. We have confirmed these localizations by in situ hybridization with CMPXY4 and have shown additionally that the autosomal sequences of both the CMPXY4 sequence and GMGY3 map to 9p22-9pter. Restriction analysis demonstrates that CMPXY1/XY2/XY3 differ in sequence from CMPXY4 at three restriction enzyme sites, thus suggesting that they are transcribed from different but closely related genes and that CMPXY4 must be either X-linked or autosomal in origin. This indicates that more than one of the loci containing ZFY-related sequences are transcribed and potentially fulfil functionally distinct roles in the human sex determining pathway. Northern blot analysis of human foetal testis RNA has shown that three low abundance transcripts of 5, 6 and 8 Kb can be detected by ZFY-related DNA sequences.

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

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.

Chromosome instability associated with human alphoid DNA transfected into the Chinese hamster genome

Repetitive DNA sequences have been implicated in the mediation of DNA rearrangement in mammalian cells. We have tested this hypothesis by using a dihydrofolate reductase (DHFR) expression vector into which candidate sequences were inserted. DHFR- Chinese hamster ovary (CHO) cells were transfected with this vector, the amplification of which was then selected for by methotrexate (MTX) exposure. Cells transfected with the vector alone (and resistant to 0.02 or 1.0 microM MTX) or with a poly(dG-dT) insert (and resistant to 0.05 or 1.0 microM MTX) showed little change in chromosome aberrations or sister chromatid exchange frequencies. In contrast, transfection of DHFR- CHO cells with a vector containing either of two distinct 0.34-kilobase human alphoid DNA segments (and selection to 0.05 to 10.0 microM MTX) showed an approximately 50% increase in chromosome number and marked changes in chromosome structure, including one or two dicentric or ring forms per cell. The sister chromatid exchange frequency also increased, to more than double the frequency of that in cells transfected without insert or those containing poly(dG-dT). In situ hybridization of one 0.34-kilobase insert in some cells suggested clustering of homologous sequences in structurally abnormal recipient CHO cell chromosomes. The approach described provides an introduction to a unique means for a coordinate molecular and cytological study of dynamic changes in chromosome structure.

Amplified inverted duplications within and adjacent to heterologous selectable DNA

Plasmids containing a dihydrofolate reductase (DHFR) expression unit were transfected into DHFR-deficient Chinese hamster ovary (CHO) cells. Methotrexate exposure was used to select cells with amplified DHFR sequences. Three cell lines were isolated containing amplified copies of transfected DNA that had integrated into the Chinese hamster genome. Plasmid DNA was found to co-amplify with flanking hamster sequences that were repetitive (2 cell lines) and unique (1 cell line). Fragments comprising the junctions of amplified plasmid and CHO DNA were found to exist as inverted duplications in all three cell lines. These observations provide evidence that inverted duplication occurred prior to DNA amplification, thus underscoring the importance of inverted duplication in the DNA amplification process.

Analysis of two 47,XXX males reveals X-Y interchange and maternal or paternal nondisjunction

Two cases of 47,XXX males were studied, one of which has been published previously (Bigozzi et al. 1980). Analysis of X-linked restriction fragment length polymorphisms revealed that in this case, one X chromosome was of paternal and two were of maternal origin, whereas in the other case, two X chromosomes were of paternal and one of maternal origin. Southern blot analysis with Y-specific DNA probes demonstrated the presence of Y short arm sequences in both XXX males. In one case, the results obtained pointed to a paracentric inversion on Yp of the patient's father. In situ hybridization indicated that the Y-specific DNA sequences were localized on Xp22.3 in one of the three X chromosomes in both cases. The presence of Y DNA had no effect on random X inactivation. It is concluded that both XXX males originate from aberrant X-Y interchange during paternal meiosis, with coincident nondisjunction of the X chromosome during maternal meiosis in case 1, and during paternal meiosis II in case 2.

Localization of Y chromosome sequences and X chromosomal replication studies in XX males

By in situ hybridization, Y-specific DNA sequences were localized on Xp22.3-Xpter of one of the two X chromosomes in all of eleven XX males studied. In nine of the cases the presence of the Y-specific DNA did not affect random X inactivation in fibroblasts. Fibroblasts of the other two cases showed a preferential inactivation of the Y DNA-carrying X chromosome. In only one of these two exceptions blood lymphocytes could also be studied, and here, random inactivation of the Y DNA-carrying X chromosome occurred. Furthermore, the gene dosage of steroid sulfatase (STS) was examined by Southern blot analysis. In ten of the cases including the one showing random X-inactivation in lymphocytes but not in fibroblasts, a double dosage of the STS gene is present. The remaining case with non-random inactivation shows a single STS gene dosage. This case was reported previously to have STS enzyme activity in the male range. It is assumed that, as a consequence DNA sequences may result in the preferential inactivation of the Y DNA-carrying X chromosome.

Accidental X-Y recombination and the aetiology of XX males and true hermaphrodites

Accidental recombination between the differential segments of the X and Y chromosomes in man occasionally allows transfer of Y-linked sequences to the X chromosome leading to testis differentiation in so-called XX males. Loss of the same sequences by X-Y interchange allows female differentiation in a small proportion of individuals with XY gonadal dysgenesis. A candidate gene responsible for primary sex determination has recently been cloned from within this part of the Y chromosome by Page and his colleagues. The observation that a homologue of this gene is present on the short arm of the X chromosome and is subject to X-inactivation, raises the intriguing possibility that sex determination in man is a quantitative trait. Males have two active doses of the gonad determining gene, and females have one dose. This hypothesis has been tested in a series of XX males, XY females and XX true hermaphrodites by using a genomic probe, CMPXY1, obtained by probing a Y-specific DNA library with synthetic oligonucleotides based on the predicted amino-acid sequence of the sex-determining protein. The findings in most cases are consistent with the hypothesis of homologous gonad-determining genes, GDX and GDY, carried by the X and Y chromosomes respectively. It is postulated that in sporadic or familial XX true hermaphrodites one of the GDX loci escapes X-inactivation because of mutation or chromosomal rearrangement, resulting in mosaicism for testis and ovary-determining cell lines in somatic cells. Y-negative XX males belong to the same clinical spectrum as XX true hermaphrodites, and gonadal dysgenesis in some XY females may be due to sporadic or familial mutations of GDX.

Structure of a hypervariable tandemly repeated DNA sequence on the short arm of the human Y chromosome

The structure of a repeated DNA sequence located on the short arm of the human Y chromosome is described. Genomic mapping and cloning in lambda or cosmid vectors show that the repeated sequence consists of units 20.3 x 10(3) base-pairs long that contain the three previously described DNA sequences: Y-156, Y-190 and Y-223a. Analysis of male genomic DNA by pulsed-field gel electrophoresis shows that the units are tandemly arranged and are organized into two blocks. The major block is hypervariable in size and alleles in the range approximately 540 x 10(3) to 800 x 10(3) base-pairs were detected. The minor block is not variable in size and is approximately 60 x 10(3) base-pairs long. Analysis of rearranged Y chromosomes shows that both blocks are located on the short arm of the chromosome. Most commonly, the major block is distal to the minor block, but the opposite arrangement is also found.

Analysis of peripheral maternal blood samples for the presence of placenta-derived cells using Y-specific probes and McAb H315

Using flow cytometry, a small number of cellular elements expressing on their surface an antigen (H315) produced by placental trophoblast have been observed in the peripheral blood of pregnant women. This is in agreement with previous observations (Covone et al., 1984a,b) and recent results documenting the presence of a small number of H315-positive cells in the peripheral circulation of pregnant women (Pool et al., 1987; Caligaris-Cappio and Camaschella, personal communication). When DNA extracts, prepared from H315-positive cells sorted from maternal samples were tested by Southern transfer using Y-specific probes (Y190 or Y411), a Y-specific band could not be detected in any sample analysed, irrespective of the sex of the fetus. In control samples from healthy male donors, a Y-specific band could be detected with as few as 800 46,XY cells without interference from contaminating 46,XX cells. H315-positive cellular elements, sorted by flow cytometry from the maternal peripheral blood, were also examined in interphase using Y-specific probes (Y190 and Y431) and an in situ biotin-avidin fluorescent hybridization technique. The great majority of the sorted H315-positive cellular elements did not show a fluorescent Y body, even in samples from mothers who later delivered a male infant. While previous investigations had failed to demonstrate the in vitro uptake of H315 antigen onto the surface of leucocytes from healthy males incubated in maternal sera, the present studies demonstrate that cells from male donors could adsorb this antigen following incubation in extracts prepared from retroplacental blood. These findings thus suggest that the majority of H315-positive nucleated cells previously detected by flow cytometry in the peripheral circulation of pregnant women are maternal cells which have adsorbed H315 antigen in vivo, either in soluble form or as small cell membrane fragments.

Chromosome instability associated with human alphoid DNA transfected into the Chinese hamster genome

Repetitive DNA sequences have been implicated in the mediation of DNA rearrangement in mammalian cells. We have tested this hypothesis by using a dihydrofolate reductase (DHFR) expression vector into which candidate sequences were inserted. DHFR- Chinese hamster ovary (CHO) cells were transfected with this vector, the amplification of which was then selected for by methotrexate (MTX) exposure. Cells transfected with the vector alone (and resistant to 0.02 or 1.0 microM MTX) or with a poly(dG-dT) insert (and resistant to 0.05 or 1.0 microM MTX) showed little change in chromosome aberrations or sister chromatid exchange frequencies. In contrast, transfection of DHFR- CHO cells with a vector containing either of two distinct 0.34-kilobase human alphoid DNA segments (and selection to 0.05 to 10.0 microM MTX) showed an approximately 50% increase in chromosome number and marked changes in chromosome structure, including one or two dicentric or ring forms per cell. The sister chromatid exchange frequency also increased, to more than double the frequency of that in cells transfected without insert or those containing poly(dG-dT). In situ hybridization of one 0.34-kilobase insert in some cells suggested clustering of homologous sequences in structurally abnormal recipient CHO cell chromosomes. The approach described provides an introduction to a unique means for a coordinate molecular and cytological study of dynamic changes in chromosome structure.

Fluorescence in situ hybridization and Y ring chromosome

Investigations by fluorescence in situ hybridization and a Y-specific probe (Y190) of a male patient with a Y ring chromosome, 46,X,r(Y) showed four bright fluorescent spots within the ring. Thus, using this technique, it is possible to suggest that the ring originates from the duplication of the short arms of the Y chromosome.

Isolation of DNA sequences on human chromosome 21 by application of a recombination-based assay to DNA from flow-sorted chromosomes

By merging two efficient technologies, bivariate flow sorting of human metaphase chromosomes and a recombination-based assay for sequence complexity, we isolated 28 cloned DNA segments homologous to loci on human chromosome 21. Subregional mapping of these DNA segments with a somatic cell hybrid panel showed that 26 of the 28 cloned DNA sequences are distributed along the long arm of chromosome 21, while the other 2 hybridize with sequences on the short arm of both chromosome 21 and other chromosomes. This new collection of probes homologous to chromosome 21 should facilitate molecular analyses of trisomy 21 by providing DNA probes for the linkage map of chromosome 21, for studies of nondisjunction, for chromosome walking in clinically relevant subregions of chromosome 21, and for the isolation of genes on chromosome 21 following the screening of cDNA libraries.

Selection and separation of X- and Y- chromosome-bearing mammalian sperm

Preselection of the gender of offspring is a subject that has held man's attention since the beginning of recorded history. Most scientific hypotheses for producing the desired sex of offspring address separation of X- and Y-bearing sperm, and most have had limited, if any success. Eight of these hypotheses and their experimental verifications are discussed here. Three hypotheses are based on physical characteristics of sperm, one on supposed differences in size and shape, another on differences in density, and a third on differences in surface charge. There has been no experimental verification of differences based on size and shape, and the results from attempts to verify separation of X- and Y-bearing sperm based on density have been mixed. Electrophoresis may provide a method for separating X- and Y-bearing sperm, but it is currently unproven and would be of little practical utility, since sperm motility is lost. A fourth hypothesis employs H-Y antigen to select preimplantation embryos. This method reliably produces female offspring, but does not permit the selection of male offspring and does not work on sperm. There are two applications of the theory that X- and Y-bearing sperm should be separable by flow fractionation. Flow fractionation using thermal convection, counter-streaming sedimentation, and galvanization is highly promoted by its originator but has not gained wide acceptance due to lack of independent confirmation. Flow fractionation by laminar flow is said to provide up to 80% enrichment of both X- and Y-bearing sperm; however, this method also has not been confirmed by other workers or tested in breeding trials. The sixth theory discussed is that of separation through Sephadex gel filtration. This method may provide enrichment of X-bearing sperm, but, again, other experimenters have not been able to adequately confirm the enrichment. The best-known approach to sperm separation is that employing albumin centrifugation, yet even with this method, not all researchers have been able to confirm a final fraction rich in Y sperm, and trials in animals have given contradictory results. The most reliable method for separating X- and Y-bearing sperm is use of flow cytometric and flow sorting techniques. These techniques routinely separate fractions with a purity greater than 80% and can be above 90%. Unfortunately, these methods do not always work for human samples. Furthermore, as with electrophoretic approaches, the methods identify and separate only chemically fixed sperm and provide limited biological applications.(ABSTRACT TRUNCATED AT 400 WORDS)

Progress in the molecular cytogenetics of man

Recombinant DNA technology has contributed greatly to the precision of chromosome analysis in man. Breakpoints of chromosome deletions and rearrangements may be defined on a chromosome map whose landmarks are the loci of DNA sequences rather than Giemsa bands. Flow cytogenetics allows the extent of chromosome duplications and deletions to be measured more precisely than has hitherto been possible. DNA probes can reveal hidden translocations through the application of in situ hybridization, and may be used as markers to determine the parental origin of non-disjunction. It is evident that a study of the pathology of human chromosomes now requires the combined skills of recombinant DNA and cytology.

In situ fluorescence hybridization of Y translocations: cytogenetic analysis using probes Y190 and Y431

Two moderately repetitive DNA probes (Y190 and Y431) and a fluorescent in situ hybridization technique, using a biotin, avidin, anti-avidin system, were employed to investigate a group of patients with Y chromosome abnormalities. In normal male subjects, a bright fluorescent spot could be detected in cells in interphase and on the short arm of the Y chromosome in metaphase spreads. Translocations of DNA fragments of the short arm of the Y chromosome to autosomes 10, 13 and 15 were observed in five patients. In a 45,XX male subject the translocation involved one of the X chromosomes. With this in situ hybridization procedure, bright fluorescent spots were also noticed in uncultured amniotic cells and chorionic cellular elements from male fetuses, thus allowing a rapid and reproducible approach to prenatal fetal sexing.

Y-specific DNA sequences in male patients with 46,XX and 47,XXX karyotypes

Y chromosomal DNA sequences were detected in three of four 46,XX males and in one 47,XXX male. One reiterated Y chromosomal sequence, Y-190, was localized by in situ hybridization to the distal short arm of an X chromosome of the 47,XXX male. This result is compatible with the hypothesis that an aberrant X/Y interchange has occurred, most likely during paternal meiosis, and that this interchange accounts for Y chromosomal material and sex reversal in this 47,XXX individual.

An XXX male resulting from paternal X-Y interchange and maternal X-X nondisjunction

A 2-year-old boy was found to have a 47,XXX karyotype. Restriction-fragment-length-polymorphism analysis showed that, of his three X chromosomes, one is of paternal and two are of maternal origin. The results of Y-DNA hybridization were reminiscent of those in XX males in two respects. First, hybridization to Southern transfers revealed the presence in this XXX male of sequences derived from the Y-chromosomal short arm. Second, in situ hybridization showed that this Y DNA was located on the tip of the X-chromosomal short arm. We conclude that this XXX male resulted from the coincidence of X-X nondisjunction during maternal meiosis and aberrant X-Y interchange either during or prior to paternal meiosis.

Mapping the testis determinants by an analysis of Y-specific sequences in males with apparent XX and XO karyotypes and females with XY karyotypes

A number of patients with paradoxical sex chromosome complements (so-called XY females, XX and XO males) have been investigated with a series of 19 Yp and 4 Yq DNA probes to establish which region of the Y is essential for male sexual differentiation. Of the 23 XX males, 18 possessed one or more Yp probe sequences with only 5 lacking such sequences. Of 9 XY females examined, only one showed evidence of a deletion in Yp occurring either as a result of X-Y interchange or interstitial deletion. This suggests that the majority of XY females are not commonly deleted for those Y sequences which are found to be transferred to the X in XX males. The DNA of two XO males both contained different portions of the Y. From a comparison of the patterns of Yp sequences in these patients, it has been possible to elaborate a model of Yp in terms of the order of probe sequences and to suggest a location for the testis determining region in distal Yp.