The Y chromosome of the mouse is decondensed in Sertoli cells

The condensation of the Y chromosome in mouse cells was studied with two repetitive DNA probes, pY353/B and M34. Both DNA probes are specific to the Y chromosome and hybridize in situ along the whole chromosome. Due to the high resolution of the in situ hybridization technique with non-radioactive labeled DNA probes it was possible to observe the degree of condensation of the Y chromosome in the interphase cell nuclei of various somatic tissues and on testes preparations. The Sertoli cells were the only cell type in which the Y chromosome was always observed to be in a highly decondensed state. The decondensation of the Y chromosome in the Sertoli cells supports the view that the genetic activity of the Y chromosome is cell autonomous and opens the way to its molecular analysis.     

Detection of Y-bearing spermatozoa by DNA-DNA in situ hybridisation

In situ hybridisation of a Y chromosome-specific DNA probe to preparations of decondensed spermatozoa revealed approximately 46.7% labelled spermatozoa among 3,900 scored. This is not significantly different from the 50% expected if only the Y chromosome-bearing spermatozoa are hybridised. Control hybridizations of Escherichia coli DNA and salmon testis DNA to decondensed sperm produced no significant labelling, whereas more than 99% of the spermatozoa were heavily labelled after hybridisation to total human DNA. These controls indicate that the methodology described in this paper renders the chromatin accessible for hybridisation and that the 50% hybridisation observed with the Y chromosome DNA probe was specific. In situ hybridisation with the Y probe therefore identifies the Y-bearing spermatozoa, and the protocol described should prove useful in evaluating methods of separating Y-bearing and X-bearing spermatozoa.     

Amplification of the Y chromosome in three murine tumor cell lines transformed in vivo by different human prostate cancers

Summary Conventional and molecular cytogenetic analyses of three murine cancer cell lines that had been induced in male athymic mice by the injection of three different human prostate cancer cell lines revealed selective amplification of the Y chromosome. In particular, analysis of metaphase and interphase nuclei by fluorescence in situ hybridization (FISH) with the mouse Y chromosome-specific DNA painting probe revealed the presence of various numbers of Y chromosomes, ranging from one to eight, with a large majority of nuclei showing two copies (46.5–60.1%). In Interphase nuclei, the Y chromosomes showed distinct morphology, allowing identification irrespective of whether the preparations were treated for 15 min or for 5 h with Colcemid, a chemical known to cause chromosome condensation. However, FISH performed on human lymphocyte cultures with chromosome-specific DNA painting probes other than the Y chromosome did not reveal condensed chromosome morphology in interphase nuclei even after 12 h of Colcemid treatment. Our FISH results indicate that (1) the Y chromosome is selectively amplified in all three cell lines; (2) the mouse Y chromosome number is comparable in both interphase and metaphase cells; (3) the Y chromosome number varies between one and eight, with a large majority of cells showing two or three copies in most interphase nuclei; (4) the condensation of the Y chromosome is not affected by the duration of Colcemid treatment but by its inherent DNA constitution; and (5) the number of copies of the Y chromosome is increased and retained not only in human prostate tumor cell lines but also in murine tumors induced by these prostate tumor cell lines.     

Size variation and orientation of the human Y chromosome

Summary The material consists of 84 metaphase plates from 17 individuals with clearly distinguishable Y chromosomes. The plates were obtained from leucocyte cultures. In making the preparations, exactly the same procedure was employed in all cases, including among other things, air-drying and light flaming.It was found that the size of the Y chromosome is subject to interindividual variation. The size of the Y chromosome has been expressed in relation to the mean length of the other small acrocentric chromosomes. The chromosomes have been tentatively classified into the following main groups:1. Y/G = 1.8; 2. Y/G =1.5; 3. Y/G is somewhat larger than G or 1.1, and 4. Y/G equals the mean of the small acrocentric chromosomes, or Y/G = 1. In the long Y chromosome two secondary constrictions have been observed.The location of the Y chromosome has been determined as peripheral or non-peripheral. The proband material has been divided into three main groups. The first comprises the individuals with a large Y chromosome (Y/G = 1.8). The second group includes individuals showing Down's syndrome and having 47 chromosomes, and the third comprises individuals with 46 chromosomes and possessing a Y/G sized 1 to 1.5. Preferential peripheral location of the Y chromosome has not been statistically verified in any one of these groups.     

Organization of the Y chromosome in testis cells of fetal,subadult and adult mice as determined by in situ hybridization

In order to reveal the time-course of decondensation of the Y chromosome in Sertoli cells, testes preparations of fetal, subadult and adult laboratory mice in different developmental stages were hybridized in situ with biotinylated probe pY353/B, which binds along the entire long arm of the mouse Y chromosome. All fetal and subadult testicular cells exhibited tightly compacted hybridization signals, indicating highly condensed Y chromosomes. Diffuse signals, indicating decondensation of the Y chromosome were found for the first time in the structurally differentiated Sertoli cells of 35 to 40 day old animals. Since this coincides with the appearance of mature sperm nuclei, a correlation between decondensation of the Y chromosome and its activity in sperm maturation and/or sperm motility can be presumed.     

The chromosomal localisation of human satellite DNA I

The major concentrations of human satellite DNA I (1.688 g/ml) have been localised on human chromosome preparations by the technique of in situ hybridisation using radioactive complementary RNA synthesised in vitro. Chromosomes were identified by prior study using quinacrine fluorescence microscopy. The satellite DNA is concentrated, mainly in centromeric constitutive heterochromatin, on many chromosomes but is especially obvious in the fluorescent distal segment of the Y chromosome.     

一例t（Y;15）并t（14;21）复合易位的细胞与分子遗传学研究

本文对一便生育过先天愚型儿的个体刊进行了细胞与分子遗传学研究。发现先证者拥有ｔ（１４;２１）用一个短臂增大变异为１５号标记染色体。通过Ｇ－显带、Ｃ－显带、Ｑ－显带、硝酸银染色及Ｙ染色体长臂异染色质区特异控针ｐＹ３．４对先证者基因组ＤＮＡ的斑点杂交和中期染色体的原位杂交,证实变异部分由Ｙ染色体长臂异染色质区易位所形成,从而排除了巨大随体的存在或其他染色体参与重排形成变的可能性,结果表明,常规显带与染     

The minimal mammalian Y chromosome - the marsupial Y as a model system

The mammalian X and Y chromosomes are very different in size and gene content. The Y chromosome is much smaller than the X and consists largely of highly repeated non-coding DNA, containing few active genes. The 65-Mb human Y is homologous to the X over two small pseudoautosomal regions which together contain 13 active genes. The heterochromatic distal half of the human Yq is entirely composed of highly repeated non-coding DNA, and even the euchromatic portion of the differential region is largely composed of non-coding repeated sequences, amongst which about 30 active genes are located. The basic marsupial Y chromosome (about 10 Mb) is much smaller than that of humans or other eutherian mammals. It appears to include no PAR, since it does not undergo homologous pairing, synaptonemal complex formation or recombination with the X. We show here that the tiny dunnart Y chromosome does not share cytogenetically detectable sequences with any other chromosome, suggesting that it contains many fewer repetitive DNA sequences than the human or mouse Y chromosomes. However, it shares several genes with the human and/or mouse Y chromosome, including the sex determining gene SRY and the candidate spermatogenesis gene RBMY, implying that the marsupial and eutherian Y are monophyletic. This minimal mammalian Y chromosome might provide a good model Y in which to hunt for new mammalian Y specific genes.     

Isolation and characterization of Y chromosome DNA probes.

A sorted, cloned Y chromosome phage library was screened for unique Y chromosome sequences. Of the thousands of plaques screened, 13 did not hybridize to radiolabeled 46,XX total chromosomal DNA. Three plaques were characterized further. Clone Y1 hybridized to multiple restriction enzyme fragments in both male and female DNA with more intense bands in male DNA. Clone Y2, also found in female and male DNA, is probably located in the pseudosutosomal region because extra copies of either the X or Y chromosomes increased Y2 restriction enzyme fragment intensity in total cellular DNA. Clone Y5 was male specific in three of four restriction enzyme digests although in the fourth a light hybridizing band was observed in both male and female DNA. Clone Y5 was sublocalized to band Yq 11.22 by hybridization to a panel of cellular DNA from patients with Y chromosome rearrangements. Clone Y5 can be used to test for retention of the proximally long arm Y suggested to cause gonadal cancer in carrier females. The long series of GA repeats in Y5, anticipated to be polymorphic, may provide a sensitive means to follow Y chromosome variation in human populations.     

Maternal Cell Contamination of Cultures of Spontaneous Abortion Fibroblasts: Importance for Cytogenetic Analysis of Embryonic Lethality

The results of standard cytogenetic analysis of the long-term cultures of embryonic fibroblasts of 478 first-trimester spontaneous abortions were retrospectively reviewed. In 16% of embryos with cytogenetically confirmed karyotype 46,XX, the Y chromosome was found by molecular genetic methods. Prior to obtaining the chromosome preparations, the cell cultures of Y chromosome-carrying embryos were maintained for a longer period than the cultures of embryos without the Y chromosome. Thus, a late entry of a culture into the log-growth phase serves as marker of maternal cell contamination. We developed a mathematical model for assessment of karyotype incidence and the sex ratio of spontaneous abortions, taking into account risk of maternal cell contamination in extraembryonic tissue cultures. Thus estimated, the incidence of chromosomal abnormalities in the studied sample increased from 54.6 to 60.3% and the expected sex ratio increased from 0.66 to 1.02 in abortions with normal karyotype. Using molecular analysis of inheritance of polymorphic DNA markers of six autosomes (2, 11, 16, 19, 20, and 21), the proposed model was tested on 60 embryos with karyotype 46,XX and their parents. Numerical chromosome abnormalities were revealed in uncultured tissues of seven abortions (11.7%), including four without the Y chromosome, which is in a good agreement with the expected incidence of karyotype abnormalities (8.3%) predicted by our model. In view of this, estimating risk of maternal cell contamination in embryonic cell cultures seems necessary for correctly assessing the effect of natural selection in humans, for understanding the mechanisms that determine the sex ratio, and for evaluating the accuracy of prenatal cytogenetic diagnosis of chromosomal abnormalities.     

Binding of anti-H-Y monoclonal antibodies to separated X and Y chromosome bearing porcine and bovine sperm

Studies designed to answer the question whether or not H-Y antigen is preferentially expressed on Y chromosome bearing sperm have resulted in conflicting results. This is probably due to the absence of reliable methods for estimating the percentage of X and Y chromosome bearing sperm in fractions, enriched or depleted for H-Y antigen positive sperm. In recent years a reliable method for separating X and Y chromosome bearing sperm has been published. With this method, separation is achieved by using a flow cytometer/cell sorter, which detects differences in DNA content. This technique provided the first opportunity for testing anti-H-Y antibody binding to fractions enriched for X and Y chromosme bearing sperm, directly. A total of 7 anti-H-Y monoclonal antibodies were tested using sorted porcine sperm and in one experiment also sorted bovine sperm. All monoclonal antibodies bound only a fraction of the sperm (20 to 50%). However, no difference in binding to the X and Y sperm enriched fractions was found. Therefore, the present experiments do not yield evidence that H-Y antigen is preferentially expressed in Y chromosome bearing sperm. © 1993 Wiley-Liss, Inc.     

Use of repetitive DNA for diagnosis of chromosomal rearrangements

Summary We have used two repeated DNA fragments (3.4 and 2.1 kb) released from Y chromosome DNA by digestion with the restriction endonuclease Hae III to analyze potential Y chromosome/autosome translocations. Two female patients were studied who each had an abnormal chromosome 22 with extra quinacrine fluorescent material on the short arm. The origin of the 22p+ chromosomes was uncertain after standard cytologic examinations. Analysis of one patient's DNA with the Y-specific repeated DNA probes revealed the presence of both the 3.4 and 2.1 kb Y-specific fragments. Thus, in this patient, the additional material was from the Y chromosome. Analysis of the second patient's DNA for Y-specific repeated DNA was negative, indicating that the extra chromosomal segment was not from the long arm of the Y chromosome. These two cases demonstrate that repeated DNA can distinguish between similar appearing aberrant chromosomes and may be useful in karyotypic and prenatal diagnosis.     

Assays of testis development in the mouse distinguish three classes of domesticus-type Y chromosome

The Y chromosome of Mus musculus poschiavinus interacts with the autosomal recessive gene tda-1b of the C57BL/6J laboratory strain of the house mouse to cause complete or partial sex reversal. Ovaries or ovotestes develop in a substantial proportion of the XY fetuses. Several different Y-specific DNA probes distinguish two major types of Y chromosome in the house mouse and they are represented by M. m. domesticus and M. m. musculus. The poschiavinus Y chromosome appears identical to the domesticus Y. The developmental distribution of the gonad types was examined in the first backcross or N2 generation of fetuses in C57BL/6J with six different domesticus-type Y chromosomes and, as controls, three different musculus-type Y chromosomes. Gonadal hermaphrodites were found with three of the six domesticus-type Y chromosomes. Both overall frequency and phenotypic distribution of types of gonadal hermaphrodites identify three classes of domesticus-type Y chromosome by their differential interaction with the C57BL/6J genetic background.     

Electron microscopic band-interband pattern of polytene chromosomes in Drosophila nasuta albomicans. 1. Salivary gland chromosome 2R

The band-interband pattern of salivary gland chromosome 2R in Drosophila nasuta albomicans (division 53-83) was studied by light (LM) and electron microscopy (EM) using squash preparations and surface-spread polytene (SSP) chromosome preparations, respectively. LM and EM maps were compiled. Based on the digitized EM patterns of five homologous SSP chromosomes a computerized chromosome map was plotted. The EM pattern analysis showed a total number of 662 chromosome bands with an almost 98% increase compared with the LM analysis of squash preparations. The majority (about 92%) of interband lengths in SSP chromosome 2R ranged between 0.25 and 0.64 microns, which equal about 0.8-2.1 kb of totally extended DNA or 2.5-6.4 kb of DNA, if a DNA packing ratio of 0.1 microns/kb is assumed for the interbands of SSP chromosomes.     

Replication banding and FISH analysis reveal the origin of the Hyla femoralis karyotype and XY/XX sex chromosomes

The pine woods treefrog, Hyla femoralis, is unique among North American hylid frogs in having a metacentric chromosome 6 and heteromorphic sex chromosomes of the XY/XX type. The X chromosome is distinguished by having a nucleolar organizing region (NOR) in the short arm. The Y chromosome does not possess an NOR. Until the present study, it was not known if the NOR was not present on the Y chromosome or inactive and therefore not detectable by conventional cytogenetic methods like silver staining. Exclusive of its unique features the karyotype of H. femoralis closely resembles those of North American frogs with karyotypes like H. chrysoscelis. We used replication banding and fluorescence in situ hybridization (FISH) with a DNA probe to the 18S + 28S ribosomal genes, which are located at the NOR, to characterize the H. femoralis karyotype. Our analysis revealed that the 18S + 28S ribosomal genes are not present on the Y chromosome, and that the karyotype of H. femoralis was derived from an H. chrysoscelis-like karyotype by relocation of the NOR to the X chromosome from chromosome 6 and either a concurrent or subsequent pericentric inversion of chromosome 6.     

Maternal cell contamination of cultures of spontaneous abortion fibroblasts: importance for cytogenetic analysis of embryonic lethality

The results of standard cytogenetic analysis of the long-term cultures of embryonic fibroblasts of 478 first-trimester spontaneous abortions were retrospectively reviewed. In 16% of embryos with cytogenetically confirmed karyotype 46,XX, the Y chromosome was found by molecular genetic methods. Prior to obtaining the chromosome preparations, the cell cultures of Y chromosome-carrying embryos were maintained for a longer period than the cultures of embryos without the Y chromosome. Thus, a late entry of a culture into the logarithmic growth phase serves as marker of maternal cell contamination. We developed a mathematic model for assessment of karyotype incidence and the "sex ratio" of spontaneous abortions, taking into account risk of maternal cell contamination in extraembryonic tissue cultures. Thus estimated, the incidence of chromosomal abnormalities in the studied sample increased from 54.6 to 60.3% and the expected sex ratio increased from 0.66 to 1.02 in abortions with normal karyotype. Using molecular analysis of inheritance of polymorphic DNA markers of six autosomes (2, 11, 16, 19, 20, and 21), the proposed model was tested on 60 embryos with karyotype 46,XX and their parents. Numerical chromosome abnormalities were revealed in uncultured tissues of seven abortions (11.7%), including four without the Y chromosome, which is in a good agreement with the expected incidence of karyotype abnormalities (8.3%) predicted by our model. In view of this, estimating risk of maternal cell contamination in embryonic cell cultures seems necessary for correctly assessing the effect of natural selection in humans, for understanding the mechanisms that determine the sex ratio, and for evaluating the precision of prenatal cytogenetic diagnosis of chromosomal abnormalities.     

The majority of the marker chromosomes in Japanese patients with stigmata of turner syndrome are derived from Y chromosomes

Summary DNA analyses of 41 individuals with stigmata of Turner syndrome and a 45,X/46,X+mar or 46,X+mar karyotype were carried out. Southern-blot analysis employing 17 Y-specific probes was used to determine whether the marker chromosome was Y-chromosomal in origin. Of the 41 DNA samples from these patients, 23 contained detectable Y-chromosomal DNA. Points of chromosome breakage were distributed over the entire length of the Y long arm. Three individuals, who carry different portions of the Y chromosome, had developed gonadoblastoma. GBY (the gonadoblastoma locus on the Y chromosome) is mapped proximal to DYS132, midway between the 13 Yq loci that we have studied. We also used a polymerase chain reaction technique that could detect 7 loci over the length of the Y chromosome. This technique may be useful for the rapid assessment of marker chromosomes, especially for evaluating the risk of gonadoblastoma.     

Identification of a case of Y:18 translocation using a Y-specific repetitive DNA probe

Summary We have used a recombinant DNA clone derived from the Y-specific 3,4-kb repeats for in situ chromosome hybridization and Southern blotting analysis to identify a case of de novo Y;18 translocation. The proband has a chromosome complement of 46,XY and a variant chromosome 18 with a Q-bright and C-positive short arm. The father has a normal male karyotype of 46,XY. The mother has a female karyotype of 46,XX and an unusually large Q-bright satellite on one chromosome 22. In situ hybridization with the 3,4-kb probe to the metaphase preparations of family members indicated that the additional Q-bright material in the proband's variant chromosome 18 derived from the Y chromosome of his father, and not from the variant chromosome 22 of his mother. On Southern hybridization, the proband had approximately twice the amount of 3,4-kb repeats per cell as his father. These observations suggest a de novo genetic rearrangement in the proband which probably occurred during the father's spermatogenesis.     

Interstitial deletions of repetitive DNA blocks in dicentric human Y chromosomes

Cytogenetic analysis of aberrant human Y chromosomes was done by fluorescence in situ hydbridization (FISH) with Y specific repetitive DNA probes. It revealed an interstitial deletion of different DNA blocks in two dicentric chromosome structures. One deletion includes the total alphoid DNA structure of one centromeric region. The second deletion includes the total repetitive DYZ5 DNA structure in the pericentromeric region of one short Y arm. Both dicentric Y chromosomes were iso(Yp) chromosomes with break and fusion point located in Yq11, the euchromatic part of the long Y arm. Their phenotypic appearance was abnormal, resembling small monocentric Yq-chromosomes in metaphase plates. Mosaic cell lines, usually included in karyotypes with dicentric Y chromosomes, were not observed. It is assumed that both deletion events suppress the kinetochore activity in one Y centromeric region and thus stabilize its dicentric structure. Local interstitial deletion events had not been described in dicentric human Y chromosomes, but are common in dicentric yeast chromosomes. This raises the question of whether deletion events in dicentric human chromosomes are rare or restricted to the Y chromosome or also represent a general possibility for stabilization of a dicentric chromosome structure in human.