Rapid and simultaneous detection of chromosome Y- and 1-bearing porcine spermatozoa by fluorescence in situ hybridization

This study was carried out to develop a rapid and simultaneous detection system of chromosome Y- and 1-bearing porcine spermatozoa by fluorescence in situ hybridization (FISH). Chromosome Y- and 1-specific DNA probes were produced by polymerase chain reaction with digoxigenin (Dig)- or biotin-dUTP. The hybridization probe mixture of labeled Y-chromosome and chromosome 1-specific DNA was applied to the preparation, immediately denatured at 75°C for 8 min, hybridized for 5 min at 37°C and overall FISH steps were done within a few hours. When double FISH with Dig-labeled chromosome Y-specific and biotin-labeled chromosome 1-specific probes was applied to sperm nuclei pretreated with dithiothreitol, the average of 50.9% of sperm nuclei had the Dig-signal, 99.2% of the sperm nuclei had the biotin-signal and the average of 0.3% of sperm nuclei showed no signal. The putative rate of Y-bearing spermatozoa ranged from 49.8% to 52.8% among 5 boars and the average putative rate of Y-bearing spermatozoa was 51.0%. The results indicated that a rapid and simultaneous FISH with chromosome Y- and 1-specific porcine DNA probes produced by PCR made possible more accurate assessment of Y-bearing porcine spermatozoa. © 1996 Wiley-Liss, Inc.     

Verification of flow cytometorically-sorted X- and Y-bearing porcine spermatozoa and reanalysis of spermatozoa for DNA content using the fluorescence in situ hybridization (FISH) technique

Flow cytometric sperm sorting based on X and Y sperm DNA difference has been established as the only effective method for sexing the spermatozoa of mammals. The standard method for verifying the purity of sorted X and Y spermatozoa has been to reanalyze sorted sperm aliquots. We verified the purity of flow-sorted porcine X and Y spermatozoa and accuracy of DNA reanalysis by fluorescence in situ hybridization (FISH) using chromosome Y and 1 DNA probe. Eight ejaculates from 4 boars were sorted according to the Beltsville Sperm Sexing method. Porcine chromosome Y- and chromosome 1-specific DNA probes were used on sorted sperm populations in combination with FISH. Aliquots of the sorted sperm samples were reanalyzed for DNA content by flow cytometry. The purity of the sorted X-bearing spermatozoa was 87.4% for FISH and 87.0% for flow cytometric reanalysis; purity for the sorted Y-bearing spermatozoa was 85.9% for FISH and 84.8% for flow cytometric reanalysis. A total of 4,424 X sperm cells and 4,256 Y sperm cells was examined by FISH across the 8 ejaculates. For flow cytometry, 5,000 sorted X spermatozoa and 5,000 Y spermatozoa were reanalyzed for DNA content for each ejaculate. These results confirm the high purity of flow sorted porcine X and Y sperm cells and the validity of reanalysis of DNA in determining the proportions of X- and Y-sorted spermatozoa from viewing thousands of individual sperm chromosomes directly using FISH.     

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.     

Sexing of porcine embryo by in situ hybridization using chromosome Y- and 1-specific DNA probes

This study was carried out to determine if a rapid, simultaneous detection system using chromosome Y- and 1-bearing boar spermatozoa was applicable for sexing embryos. Porcine embryos were recovered from gilts and sows 4 to 6 d after mating, and whole embryos or biopsy cells were mounted on a glass slide with a small amount of fixative (methanol: acetic acid: distilled water = 9:1:4). The samples were then stained by means of a fluorescence in situ hybridization (FISH) procedure developed specifically for the detection of Y-bearing spermatozoa. Hybridization was performed using digoxigenin (dig)-labeled chromosome Y- specific DNA, and biotin-labeled chromosome 1-specific DNA sequences were detected as a signal of FITC and Texas Red on nucleus visualized DAPI-stain. Proportions of whole embryos labeled with chromosome 1-probe were 17 and 97% at the 3 to 16 and > or = 32 cell stage, respectively. Of the 93 biopsied embryos analyzed by FISH, 85 embryos (91%) could be accurately classified as male or female. Of the 65 biopsied embryos, 60 embryos (92%) had a clear blastocoele and a inner cell mass after 48 h of culture in vitro, and these embryos were evaluated as available embryos. One out of 4 recipient gilts which received sexed embryos at transfer farrowed 12 piglets of the expected sex. The results of this study demonstrated that porcine embryos at the > or = 32 cell stage can be sexed within 2 h using the FISH method. Moreover further development of the FISH technique could make it an effective tool for the study of early porcine embryos and for the control of porcine sex.     

Determination of Y chromosome aneuploidy in human sperm nuclei by nonradioactive in situ hybridization.

Sperm nuclei from eight normal, healthy donors were hybridized in situ with the biotin-labeled Y-specific pHY2.1 DNA probe to evaluate the X:Y ratio, the location of the Y chromosome, and the frequency of Y aneuploidy in human sperm. The streptavidine-horseradish-peroxidase and DAB detection system used permitted the unequivocal identification of sperm heads with zero, one, or two hybridization signals and proved superior to either quinacrine staining or radioactive in situ hybridization. The low incidence of 0.27% of sperm nuclei with two Y chromosomes that was found is similar to the frequency of XYY males among newborns. The average proportions of X- and Y-bearing sperm nuclei were 50.3% and 49.4%, respectively, corresponding to the expected 1:1 ratio. The Y heterochromatin was located in the central part of the nucleus in 58% of the Y-carrying sperm cells.     

Fluorescence in situ hybridization with Y chromosome-specific probe in decondensed bovine spermatozoa

This study was carried out to demonstrate bovine Y chromosome-bearing spermatozoa by rapid fluorescence in situ hybridization (FISH), using a digoxigenin (Dig)-labeled DNA probe specific to bovine Y chromosome. Before the FISH procedure, sperm heads were treated for decondensation with dithiothreitol (DTT) and glutathione (GSH) with or without heparin supplementation. Concentrations of either above 2 mM DTT or above 100 mM GSH induced swelling of the sperm head, which resulted in sufficient detection of the Y chromosome signal in sperm nuclei by rapid FISH (49.8 to 53.4%). When FISH was used with 2 mM DTT or 100 mM GSH on specimens from 7 sires, the rate of detection of the Y chromosome signal varied among sires (5.4 to 49.6%), especially that of the GSH treatment. Supplementation of GSH with heparin (100 U/mL), however, could induce reliable, repeatable detection of the Y chromosome signal in sperm nuclei of all the 7 sires (48.4 to 50.3%). These results show that in bovine spermatozoa decondensed with GSH and heparin, rapid FISH can detect Y chromosome-bearing spermatozoa.     

Specific cytogenetic labeling of bovine spermatozoa bearing X or Y chromosomes using fluorescent in situ hybridization (FISH)

X and Y specific probes were identified in order to apply the fluorescent in situ hybridization (FISH) technique to bovine spermatozoa. For Y chromosome detection, the BRY4a repetitive probe, covering three quarters of the chromosome, was used. For X chromosome detection, a goat Bacterial Artificial Chromosome (BAC) specific to the X chromosome of bovine and goats and giving a strong FISH signal was used. Each probe labeled roughly 45% of sperm cells. The hybridization method will be useful for evaluating the ratio of X- and Y- bearing spermatozoa in a sperm sample and consequently can be used to evaluate the efficiency of sperm sorting by different techniques such as flow cytometry.     

Birth of piglets preselected for gender following in vitro fertilization of in vitro matured pig oocytes by X and Y chromosome bearing spermatozoa sorted by high speed flow cytometry

The present study examined the ability to establish pregnancies after transfer of pig embryos derived from in vitro fertilization (IVF) of in vitro matured (IVM) oocytes by X and Y chromosome-bearing spermatozoa sorted by flow cytometry. Cumulus-oocyte complexes (COC) were cultured in BSA-free NCSU-23 medium containing porcine follicular fluid (10%), cysteine (0.1 mg/mL), epidermal growth factor (10 ng/mL), LH (0.5 microgram/mL) and FSH (0.5 microgram/mL) for 22 h, then the oocytes were cultured without hormonal supplements for an additional 22 h. Boar semen was collected and prepared by flow cytometry sorting of X and Y chromosome bearing spermatozoa. After IVM, cumulus-free oocytes were co-incubated with sorted X or Y spermatozoa (2 x 10(4)/mL) for 6 to 7 h in modified Tris-buffered medium containing 2.5 mM caffeine and 0.4% BSA. After IVF, putative embryos were transferred to NCSU-23 medium containing 0.4% BSA for culture. A portion of the oocytes was fixed 12 h after IVF, the remainder were cultured up to 96 h. At 96 h after IVF, 8-cell to morula stage embryos (n = 30 to 35) from each gender were surgically transferred to the uterus of recipient gilts. Insemination of IVM pig oocytes with X- or Y-bearing sperm cells did not influence the rate of penetration (67 vs 80%), polyspermy (40 vs 53%), male pronuclear formation (95 vs 96%), or mean number of spermatozoa per oocyte (1.6 vs 1.6), respectively. Furthermore, no difference was observed between cleavage rates at 48 h after IVF (X, 49 vs Y, 45%). Transfer of embryos derived from X-bearing spermatozoa to 18 recipients resulted in 5 pregnancies and delivery of 23 females and 1 male piglet. Similarly, transfer of embryos derived from Y-bearing sperm cells to 10 recipients resulted in 3 pregnancies, with 9 male piglets delivered. The results show that X- and Y-bearing spermatozoa sorted using USDA sperm sexing technology can be successfully used in an IVM-IVF system to obtain piglets of a predetermined sex.     

Meiotic behaviour of sex chromosomes investigated by three-colour FISH on 35 142 sperm nuclei from two 47,XYY males

Meiotic segregation of sex chromosomes from two fertile 47,XYY men was analysed by a three-colour fluorescence in situ hybridisation procedure. This method allows the identification of hyperhaploidies (spermatozoa with 24 chromosomes) and diploidies (spermatozoa with 46 chromosomes), and their meiotic origin (meiosis I or II). Alpha-satellite probes specific for chromosomes X, Y and 1 were observed simultaneously in 35 142 sperm nuclei. For both 47,XYY men (24 315 sperm nuclei analysed from one male and 10 827 from the other one) the sex ratio differs from the expected 1:1 ratio (P < 0.001). The rates of disomic Y, diploid YY and diploid XY spermatozoa were increased for both 47,XYY men compared with control sperm (142 050 sperm nuclei analysed from five control men), whereas the rates of hyperhaploidy XY, disomy X and disomy 1 were not significantly different from those of control sperm. These results support the hypothesis that the extra Y chromosome is lost before meiosis with a proliferative advantage of the resulting 46,XY germ cells. Our observations also suggest that a few primary spermatocytes with two Y chromosomes are able to progress through meiosis and to produce Y-bearing sperm cells. A theoretical pairing of the three gonosomes in primary spermatocytes with an extra sex chromosome, compatible with active spermatogenesis, is proposed. Received: 12 April 1996 / Revised: 26 August 1996     

Human gametes and zygotes studied by nonradioactive in situ hybridization

A nonradioactive in situ hybridization technique was applied to human gametes and abnormally fertilized or developed zygotes. Using haptenized chromosome-specific probes, visualization was obtained using immunocytochemistry to achieve a fluorescent stain on specific hybrids. Using a chromosome 1-specific DNA probe, almost all spermatozoa gave a positive result, i.e., one hybridization signal per cell could be observed. Furthermore, it was possible to identify sperm cells with two spots, suggesting nondisjunction. Two cleavage arrested embryos from different patients showed both: two brightly fluorescent spots and two weaker spots with the same DNA probe. Using a Y-specific DNA probe the percentages of positive spermatozoa from the normal males ranged between 48.1% and 49.1%. In an embryo with four grossly haploid chromosome sets, three fluorescent spots were obtained with the Y-specific DNA probe, indicating the penetration of three spermatozoa.     

Assignment of a porcine male-specific DNA repeat to Y-chromosomal heterochromatin.

Primers were designed to amplify by PCR a 509-bp genomic fragment from male pig DNA, using the porcine male-specific repeat sequence described by McGraw et al. (1988). This PCR product showed male-specific hybridization in Southern blots. Nonradioactive in situ hybridization localized it to the entire length of the heterochromatic portion of Yq. The assignment was confirmed using the PCR primer pDYZ1-S for primed in situ labeling.     

Simultaneous detection of X- and Y-bearing human sperm by double fluorescence in situ hybridization

Double fluorescence in situ hybridization (FISH) was used to detect sex chromosomes in decondensed human sperm nuclei. Biotinylated X chromosome specific (TRX) and digoxigenin-labeled Y chromosome specific (HRY) probes were simultaneously hybridized to sperm preparations from 12 normal healthy donors. After the hybridization, the probes were detected immuno-cytochemically, using two different and independent affinity systems. Ninety-six percent of the 12,636 sperm showed fluorescent labeling, of which 47.4% were haploid X and 46.8% were haploid Y. A frequency of 0.46% of XX-bearing sperm (0.28% disomic, 0.18% diploid) and 0.38% YY-bearing sperm (0.21% disomic, 0.17% diploid) was found. The overall proportions of X- and Y-bearing sperm in the ejaculates were 47.9% and 47.2%, respectively, which was not significantly different from the expected 50:50 ratio. In addition 0.21% of cells appeared to be haploid XY-bearing sperm, 0.62% were diploid XY-bearing cells, and 0.05% of cells were considered to be tetraploid cells. The application of double FISH to human sperm using X-chro-mosome and Y-chromosome probes has allowed a more accurate assessment of the sex chromosal complements in sperm than single FISH method and quinacrine staining for Y-bodies. © 1993 Wiley-Liss, Inc.     

Swine in Biomedical Research: Creating the Building Blocks of Animal Models

Abstract

Sex of preimplantation porcine embryos was determined by DNA amplification using porcine male(Y chromosome)‐specific DNA primers in the polymerase chain reaction (PCR). In order to determine the sensitivity of this sexing method, single porcine embryos ranging from unfertilized ova to the blastocyst stage were amplified in the PCR using the Y‐specific primers, and analyzed by ethidium bromide‐staining of polyacrylamide gels. The 192 bp product which denotes the presence of the Y chromosome was seen in the embryos. The unfertilized ova which is of female origin gave no product. These results are representative of PCR analysis of a total of 34 swine embryos.

Results obtained using the PCR for sexing were validated by karyotyping and confirmed by in situ hybridization with the porcine Y‐chromosome‐specific probe. In order to confirm the sex of the embryos determined by PCR, 10 day‐old porcine preimplantation embryos were biopsied to produce a small number of cells for sex determination via PCR, while the remainder of the embryo was prepared for in situ hybridization using the biotinylated probe. In situ hybridization performed on embryos shown to be male by PCR, showed pinpoint fluorescence within the nuclei, similar to that obtained when male porcine lymphocytes were hybridized. No evidence of fluorescence was seen when in situ hybridization was performed in parallel on embryos determined to be female by the PCR.

The PCR was found to be a relatively fast, accurate and reproducible means of sex determination of swine preimplantation embryos. This capability could have significant impact on animal breeding and production programs by using PCR as a screening tool for traits of economic importance.     

Microisolation and microcloning of bovine X-chromosomes for identification of sorted buffalo (Bubalus bubalis) spermatozoa

Flow-cytometry sorting technology has been successfully used to separate the X- and Y-chromosome bearing spermatozoa for production of sex-preselected buffalo. However, an independent technique should be employed to validate the sorting accuracy. In the present study, X-chromosomes of bovine were micro-dissected from the metaphase spreads by using glass needles. Then X-chromosomes were then amplified by PCR and labelled with Cy3-dUTP for use as a probe in hybridization of the unsorted and sorted buffalo spermatozoa -chromosome. The results revealed that 47.7% (594/1246) of the unsorted buffalo spermatozoa were positive for X- chromosome probe, which was conformed to the sex ratio in buffalo (X:Y spermatozoa=1:1); 9.6% (275/2869) of the Y-sorted buffalo spermatozoa and 86.1% (1529/1776) of the X-sorted buffalo spermatozoa showed strong X-chromosome FISH signals. Flow cytometer re-analysis revealed that the proportions of X- and Y-bearing spermatozoa in the sorted X and Y semen was 89.6% and 86.7%, respectively. There were no significant differences between results assayed by flow-cytometry re-analysis and by FISH in this study. In conclusion, FISH probe derived from bovine X- chromosomes could be used to verify the purity of X and Y sorted spermatozoa in buffalo.     

Segregation of sex chromosomes into sperm nuclei in a man with 47,XXY Klinefelter’s karyotype: a FISH analysis

Meiotic segregation of the sex chromosomes was analysed in sperm nuclei from a man with Klinefelter’s karyotype by three-colour FISH. The X- and Y-specific DNA probes were co-hybridized with a probe specific for chromosome 1, thus allowing diploid and hyperhaploid spermatozoa to be distinguished. A total of 2206 sperm nuclei was examined; 958 cells contained an X chromosome, 1077 a Y chromosome. The ratio of X : Y bearing sperm differed significantly from the expected 1 : 1 ratio (χ² = 6.96; 0.001 < P < 0.01). Sex-chromosomal hyperhaploidy was detected in 2.67% of the cells (1.22% XX, 1.36% XY, 0.09% YY) and a diploid constitution in 0.23%. Although the frequency of 24,YY sperm was similar to that detected in fertile males, the frequencies of 24,XX, 24,XY and diploid cells were significantly increased. A sex-chromosomal signal was missing in 4.26% of the spermatozoa. This percentage appeared to be too high to be attributed merely to nullisomy for the sex chromosomes and was considered, at least partially, to be the result of superposition of sex-chromosomal hybridization signals by autosomal signals in a number of sperm nuclei. The results contribute additional evidence that 47,XXY cells are able to complete meiosis and produce mature sperm nuclei. Received: 6 November 1996     

Flow cytometric sorting of non-human primate sperm nuclei

Pre-determination of the sex of offspring has implications for management and conservation of captive wildlife species, particularly those with single sex-dominated social structures. Our goal is to adapt flow cytometry technology to sort spermatozoa of non-human primate species for use with assisted reproductive technologies. The objectives of this study were to: (i) determine the difference in DNA content between X- and Y-bearing spermatozoa (ii) sort sperm nuclei into X- and Y-enriched samples; and (iii) assess the accuracy of sorting. Spermatozoa were collected from two common marmosets (Callithrix jacchus), seven hamadryas baboons (Papio hamadryas) and two common chimpanzees (Pan troglodytes). Human spermatozoa from one male were used as a control. Sperm nuclei were stained (Hoechst 33342), incubated and analyzed using a high-speed cell sorter. Flow cytometric reanalysis of sorted samples (sort reanalysis, 10,000 events/sample) and fluorescence in situ hybridization (FISH; 500 sperm nuclei/sample) were used to evaluate accuracy of sorting. Based on fluorescence intensity of X- and Y-bearing sperm nuclei, the difference in DNA content between X and Y populations was 4.09 +/- 0.03, 4.20 +/- 0.03, 3.30 +/- 0.01, and 2.97 +/- 0.05%, for marmoset, baboon, chimpanzee and human, respectively. Sort reanalysis and FISH results were similar; combined data revealed high levels of purity for X- and Y-enriched samples (94 +/- 0.9 and 93 +/- 0.8%, 94 +/- 0.7 and 94 +/- 0.5%, 91 +/- 0.9 and 97 +/- 0.6%, 94 +/- 0.6 and 94 +/- 0.9%, for marmoset, baboon, chimpanzee and human, respectively). These data indicate the potential for high-purity sorting of spermatozoa from non-human primates.     

Nonisotopic in situ hybridization as a method for nondisjunction studies in human spermatozoa

Human spermatozoa were studied with a nonradioactive in situ hybridization method. Using a chemically modified DNA probe and immunocytochemical reactions for visualization, it was possible to obtain hybridization signals in 31 of 32 semen samples. Positive hybridization reactions, depending on cell accessibility, varied from 40% to over 90% for the different samples. Using a chromosome 1-specific DNA probe, disomy for this chromosome was found in 0.67% of all accessible sperm cells.     

Flow cytometric quantification of human chromosome specific repetitive DNA sequences by single and bicolor fluorescent in situ hybridization to lymphocyte interphase nuclei

Fluorescent in situ hybridization allows for rapid and precise detection of specific nucleic acid sequences in interphase and metaphase cells. We applied fluorescent in situ hybridization to human lymphocyte interphase nuclei in suspension to determine differences in amounts of chromosome specific target sequences amongst individuals by dual beam flow cytometry. Biotinylated chromosome 1 and Y specific repetitive satellite DNA probes were used to measure chromosome 1 and Y polymorphism amongst eight healthy volunteers. The Y probe fluorescence was found to vary considerably in male volunteers (mean fluorescence 169, S.D. 35.6). It was also detectable in female volunteers (mean fluorescence 81, S.D. 10.7), because 5-10% of this repetitive sequence is located on autosomes. The Y probe fluorescence in males was correlated with the position of the Y chromosome cluster in bivariate flow karyotypes. When chromosome 1 polymorphism was studied, one person out of the group of eight appeared to be highly polymorphic, with a probe fluorescence 26% below the average. By means of fluorescent in situ hybridization on a glass slide and bivariate flow karyotyping, this 26% difference was found to be caused by a reduction of the centromere associated satellite DNA on one of the homologues of chromosome 1. The simultaneous hybridization to human lymphocyte interphase nuclei of biotinylated chromosome 1 specific repetitive DNA plus AAF-modified chromosome Y specific DNA was detected by triple beam flow cytometry. The bicolor double hybridized nuclei could be easily distinguished from the controls. When the sensitivity of this bicolor hybridization is improved, this approach could be useful for automatic detection of numerical chromosome aberrations, using one of the two probes as an internal control.     

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.     

Detection of chromosome 17- and X-bearing human spermatozoa using fluorescence in situ hybridization.

Fluorescence in situ hybridization (FISH) with DNA probes specific to chromosomes 17 and the X has been applied to human ejaculated sperm. After sperm nuclei were decondensed with EDTA and DTT, biotinylated alpha satellite DNA probes TR17 and TRX were separately used on preparations from thirteen healthy donors. After hybridization 96% of sperm were labelled with the TR17 probe and 48% of sperm were labelled with the TRX probe. Frequencies of 0.33% disomic 17 and 0.29% disomic X sperm were found. The frequencies of diploid sperm were assessed as 0.37% using the TR17 probe and 0.20% using the TRX probe which labelled only one half of the sperm; after correcting the result from the X-probe to 0.40% the two frequencies are very similar.