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.     

Flow sorting of X and Y chromosome-bearing spermatozoa into two populations

The only established difference on which to base the separation of X and Y chromosome-bearing spermatozoa is chromosomal constitution. This difference is quantifiable both from chromosome morphology (karyotype) and from DNA content. Flow cytometric techniques were used to measure relative DNA content of the X and Y populations and to flow-sort spermatozoa from Chinchilla laniger. Epididymal spermatozoa were recovered in PBS, fixed in 80% ethanol, treated with papain and dithioerythritol, and stained for DNA with Hoechst 33342. Sperm nuclei were analyzed and sorted on an EPICS V flow cytometer/cell sorter, modified specifically for spermatozoa. Two clearly resolved peaks (coefficient of variation < 1.5%) with approximately 7.5% difference in DNA content between X and Y chromosome-bearing spermatozoa were evident. Sperm nuclei were sorted from a portion of the X and Y peaks at a rate of 55 nuclei/sec for each population. Purities of individual X and Y populations averaged 95% as determined by reanalysis of the sorted populations. Successful sorting of Chinchilla X and Y chromosome-bearing spermatozoa into separate populations may aid in the identification of a biochemical marker that could be used to discriminate between the two sperm populations and lead to a practical procedure for sexing spermatozoa.     

哺乳动物精子分离方法的研究进展

分离X、Y精子,用于人工授精或体外受精,是目前实现哺乳动物性别控制的最有效手段。本文对哺乳动物精子分离及分离精子纯度评估方法的研究历史及现状作一回顾和总结。     

Do X and Y spermatozoa differ in proteins?

This article reviews the current knowledge about X- and Y-chromosomal gene expression during spermatogenesis and possible differences between X- and Y-chromosome-bearing spermatozoa (X and Y sperm) in relation to whether an immunological method of separation of X and Y spermatozoa might some day be feasible. Recent studies demonstrated that X- and Y-chromosome-bearing spermatids do express X- and Y-chromosomal genes that might theoretically result in protein differences between X and Y sperm. Most, if not all, of these gene products, however, are expected to be shared among X and Y spermatids via intercellular bridges. Studies on aberrant mouse strains indicate that complete sharing might not occur for all gene products. This keeps open the possibility that X and Y sperm may differ in proteins, but until now, this has not been confirmed by comparative studies between flow-cytometrically sorted X and Y sperm for H-Y antigen or other membrane proteins.     

Preselection of sex of offspring in swine for production: current status of the process and its application

It is estimated that as many as 30,000 offspring, mostly cattle, have been produced in the past 5 years using AI or some other means of transport with spermatozoa sexed by flow cytometric sperm sorting and DNA as the marker of differentiation. It is well documented that the only marker in sperm that can be effectively used for the separation of X- and Y-chromosome bearing spermatozoa is DNA. The method, as it is currently used worldwide, is commonly known as the Beltsville Sperm Sexing Technology. The method is based on the separation of sperm using flow cytometric sorting to sort fluorescently (Hoechst 33342) labeled sperm based on their relative content of DNA within each population of X- and Y-spermatozoa. Currently, sperm can be produced routinely at a rate of 15 million X- and an equal number of Y-sperm per hour. The technology is being applied in livestock, laboratory animals, and zoo animals; and in humans with a success rate of 90-95% in shifting the sex ratio of offspring. Delivery of sexed sperm to the site of fertilization varies with species. Conventional AI, intrauterine insemination, intra-tubal insemination, IVF with embryo transfer and deep intrauterine insemination are effectively used to obtain pregnancies dependent on species. Although sperm of all species can be sorted with high purity, achieving pregnancies with the low numbers of sperm needed for commercial application remains particularly elusive in swine. Deep intrauterine insemination with 50-100 million sexed boar sperm per AI has given encouragement to the view that insemination with one-fiftieth of the standard insemination number will be sufficient to achieve pregnancies with sexed sperm when specialized catheters are used. Catheter design, volume of inseminate, number of sexed sperm are areas where further development is needed before routine inseminations with sexed sperm can be conducted in swine. Cryopreservation of sex-sorted sperm has been routinely applied in cattle. Although piglets have been born from frozen sex-sorted boar sperm, freezing and processing protocols in combination with sex-sorted sperm are not yet optimal for routine use. This review will discuss the most recent results and advances in sex-sorting swine sperm with emphasis on what developments must take place for the sexing technology to be applied in commercial practice.     

Improved flow cytometric sorting of X‐ and Y‐chromosome bearing sperm: Substantial increase in yield of sexed semen

The yield of flow cytometric sorted X‐ and Y‐chromosome‐bearing sperm in a given time period is an important factor in the strategies used for fertilization and the production of sex‐preselected offspring. This yield is dependent on the efficiency with which the modified flow cytometer/cell sorter analyzes the DNA of spermatozoa. The efficiency is directly related to the number of sperm with the correct orientation during DNA analysis. Currently, the efficiency of flow cytometric sperm sorting is low since orientation of the sperm head to laser excitation is rate limiting. To overcome this problem, a new nozzle was designed to enhance sperm orientation and tested under flow cytometric sorting conditions. The degree of orientation improvement was determined with different sample rates using viable sperm and dead sperm of several different species. There was at minimum, a two‐fold increase in the proportion of oriented sperm when comparing the new nozzle with the currently used modified flow cytometer/cell sorter employing a beveled needle. More than 60% of intact bull sperm and boar sperm were correctly oriented compared with 25% to 30% using the beveled needle system. A unique characteristic of the novel nozzle was that the proportion of oriented sperm was independent of sample rate and of sperm motility. The accuracy of DNA measurement together with high purity sorting was tested using the novel nozzle. The novel nozzle was unique in that accuracy of measurement and sorting performance were not diminished. Using the new nozzle, samples of 88% purity of sorted X‐sperm and Y‐sperm were obtained for viable bull and boar sperm. The yield of flow cytometric sorted X‐ and Y‐chromosome‐bearing sperm using the novel nozzle was, on average, twice that obtained by using the beveled needle system in conjunction with a standard equipment nozzle for orientation. Mol. Reprod. Dev. 52:50–56, 1999. Published 1999 Wiley‐Liss, Inc.     

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.     

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.     

Identification of X- and Y-chromosome bearing buffalo (Bubalus bubalis) sperm

The aim of this study was to identify the difference in DNA content characterizing the X- and Y-chromosome bearing sperm of buffalo. Sperm from six Murrah buffaloes and six Nili-Ravi buffaloes were collected and stained with Hoechst 33342 followed by flow cytometry analysis of the DNA content. Two symmetrical, separate but overlapping peaks presumed to be X- and Y-chromosome bearing sperm were detected. The difference in fluorescence intensity, which related to the DNA content, between the X- and Y-sperm was 3.59+/-0.11% for Murrah buffalo and 3.55+/-0.14% for Nili-Ravi buffalo, respectively. Significant differences were observed among males within each breed, but there were no differences between the averages of the two breeds. The results indicate that flow cytometric sorting of X- and Y-sperm of buffalo is feasible.     

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.     

Sex ratio determination in bovine semen: a new approach by quantitative real time PCR

Sex preselection of livestock offspring in cattle represents, nowadays, a big potential for genetic improvement and market demand satisfaction. Sperm sorting by flow cytometer provides a powerful tool for artificial insemination and production of predefined sexed embryos but, an accurate verification of the yield of sperm separation remains essential for a field application of this technique or for improvement and validation of other related semen sexing technologies. In this work a new method for the determination of the proportion of X- and Y-bearing spermatozoa in bovine semen sample was developed by real time PCR. Two sets of primers and internal TaqMan probes were designed on specific X- and Y-chromosome genes. To allow a direct quantification, a standard reference was established using two plasmid cDNA clones (ratio 1:1) for the specific gene targets. The method was validated by a series of accuracy, repeatability and reproducibility assays and by testing two sets of sorted and unsorted semen samples. A high degree of accuracy (98.9%), repeatability (CV=2.58%) and reproducibility (CV=2.57%) was shown. The results of X- and Y-sorted semen samples analysed by real time PCR and by flow cytometric reanalysis showed no significant difference (P>0.05). The evaluation of X-chromosome bearing sperms content in unsorted samples showed an average of 51.11+/-0.56% for ejaculates and 50.17+/-0.58% for the commercial semen. This new method for quantification of the sexual chromosome content in spermatozoa demonstrated to be rapid and reliable, providing a valid support to the sperm sexing technologies.     

Flow cytometry of X and Y chromosome-bearing sperm for DNA using an improved preparation method and staining with Hoechst 33342

A new and improved method of preparing mammalian spermatozoa for high resolution flow cytometric DNA analysis and flow sorting is described. Ejaculated or cryopreserved sperm were briefly sonicated to remove tails and then stained with Hoechst 33342. This simple procedure was found superior to more severe treatments of dimethylsulfoxide washes, fixation in 80% ethanol, and protease digestion of the sperm membranes and tails by papain. Flow cytometric DNA analyses of sperm samples subjected to varying sonication times indicated that X and Y chromosome-bearing sperm populations could be well resolved with as little as 15-sec sonication. In addition, a comparison of sonicated samples stained with four concentrations of bisbenzimide (Hoechst 33342) or 4′,6-diamidino-2-phenylindole (DAPI) indicated that 2.5 or 5.0 μg/ml of Hoechst was sufficient to resolve the X and Y sperm populations. In order to quantitatively describe the flow cytometric data, several indices (sample quality, orientation and splitting) were developed.     

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.     

Coupling sperm mediated gene transfer and sperm sorting techniques: a new perspective for swine transgenesis

Flow cytometric separation of X and Y chromosome-bearing spermatozoa has been demonstrated to be effective in pigs, allowing the use of boar sexed semen in in vitro trials. Sperm Mediated Gene Transfer (SMGT) is a widely used and efficient technique for the creation of transgenic animals. The present research intended to prove that it is possible to associate sperm sexing with the SMGT technique in order to speed up the assessment of homozygous lines of transgenic pigs. In the first experiment, the sorting protocol was modified in order to obtain the highest DNA uptake by sorted spermatozoa. In the second experiment, spermatozoa that had undergone only sperm sorting, only SMGT, or both procedures (Sorted-SMGT) were used for in in vitro fertilization of in vitro matured oocytes. In the third experiment, transformed blastocysts of the desired gender (male) were obtained with Sorted-SMGT in an in vitro fertilization trial. The method we developed here allowed us to produce transgenic swine blastocysts of pre-determined gender, giving a positive answer at the aim to couple SMGT and sperm sorting in swine, obtaining fertile spermatozoa able to produce transgenic embryos of pre-determined gender.     

牛精子蛋白质组学技术平台的建立及冻融前后精子差异蛋白初步分析

本研究通过探索不同的精子蛋白制备方法、水化液成分和优化2D电泳程序以建立牛精子蛋白质组学研究技术平台,同时以牛鲜冻精为实验材料通过差异凝胶电泳寻找冻融前后精子蛋白的改变。结果表明：使用改进的热TRIzol法裂解精子细胞制备蛋白,结合优化的2D电泳技术可建立稳定的牛精子蛋白质组学研究技术平台。差异凝胶电泳揭示牛精子在冻融后有质和量的改变：冻融后缺失的蛋白点有20个,表达下调的有2个,表达上调的有10个。作为一项阶段性的实验成果,本研究建立的2D平台和所发现的冻融引起的差异表达蛋白质点为揭示冷冻损伤机理和性控精液的差异蛋白质组学研究奠定了较好的基础。     

Production of piglets preselected for sex following in vitro fertilization with X and Y chromosome-bearing spermatozoa sorted by flow cytometry

In vivo-matured porcine oocytes were fertilized in vitro with X and Y chromosome-bearing spermatozoa, and sorted for sex on the basis of DNA content by flow cytometry. Developmental competence of the sexed embryos was determined through established pregnancies after embryo transfer. Spermatozoa were stained with Hoechst 33342 and sorted using a flow cytometry cell sorter. Purity of sorting was 83% for Y spermatozoa and 92% for X spermatozoa. A total of 387 mature cumulus-oocyte-complexes (COC) was collected from 18 superovulated prepuberal gilts shortly before ovulation. In vitro fertilization with sorted spermatozoa was performed in 4 replicates. After 18 h of sperm- oocyte co-culture at 39 degrees C, the zygotes were placed into culture medium (NCSU-23) for another 24 h. The average cleavage rate was 56.2%. Ninety-two embryos produced from X-sorted sperm cells were transferred surgically into the uterus of 2 recipients. Two gilts farrowed and delivered 6 and 4 healthy female piglets, respectively. Additionally, 2 gilts were inseminated intratubally via surgical laparotomy with either X or Y sorted spermatozoa (2 x 10(5)) per oviduct. The 2 sows farrowed producing 15 piglets. Thirteen of the 15 piglets were of the predicted gender (85%).     

In vitro production of cat blastocysts of predetermined sex using flow cytometrically sorted semen

Sex preselection in cats can have applications for both breeding purposes and as an experimental model for endangered felids. The present study examined the ability to produce cat embryos from in vitro fertilization (IVF) of in vitro matured (IVM) cat oocytes with flow cytometrically sorted spermatozoa and to verify the sex of the embryos obtained from sexed spermatozoa by PCR. In the first experiment, a total of 224 oocytes were fertilized with spermatozoa from six ejaculates sorted without sex separation. The sorting process did not influence the cleavage rate (sorted 44.0% versus unsorted 46.1%), day 6 morula-blastocyst rate (sorted 26.6% versus unsorted 29.6%) and day 7 blastocyst rate (sorted 16.5% versus unsorted 16.5%). In the second experiment, a total of 84 IVM oocytes were fertilized with sorted X- and Y-chromosome bearing spermatozoa from four ejaculates in order to obtain embryos of preselected sex. Embryonic sex determination by PCR revealed that 21 out of 24 embryos reaching morula/blastocyst stage (87.5%) were of the desired sex. In particular 12 out of 14 embryos (85.7%) derived from X-bearing spermatozoa were female and 9 embryos out of 10 (90%) derived from Y-bearing spermatozoa were male. Our results show, for the first time, that X- and Y-chromosome bearing spermatozoa sorted by high-speed flow cytometry can be successfully used in an IVM-IVF system to obtain cat embryos of a predetermined sex.     

Flow sorting of X and Y chromosome-bearing mammalian sperm: Activation and pronuclear development of sorted bull,boar, and ram sperm microinjected into hamster oocytes

Flow cytometric techniques were used to measure relative DNA content of X and Y chromosome-bearing bull, boar, and ram sperm populations and to separate the two sex-determining populations. Neat semen was prepared for flow cytometric analysis by washing, light sonication, and staining with 9 μM Hoechst 33342. Computer analysis of the bimodal histograms showed mean X-Y DNA differences of 3.9, 3.7, and 4.2% for bull, boar, and ram, respectively. Flow cytometric reanalysis of sorted bull, boar, and ram sperm showed purities greater than 90%. Bull, boar, and ram sperm nuclei were microinjected into hamster oocytes. Microinjected sperm were either unsorted, sorted, unsorted plus dithio-threitol (DTT) exposure, or sorted plus DTT exposure. Following microinjection, eggs were incubated 3 hr, fixed, and stained. A total of 579 eggs was observed for sperm activation (decondensation or formation of a male pronucleus). A lower percentage of sorted than unsorted (3 vs. 23%) boar sperm was activated (P <.05). However, sorted and unsorted DTT-exposed boar sperm or sorted and unsorted bull or ram sperm, regardless of DTT treatment, did not differ significantly. Sorted sperm nuclei of both rams and bulls exhibited higher activation rates than sorted boar sperm (P <.05). Treatment of sperm with DTT increased the activation rate (P < .05) for sorted boar sperm but not for bull or ram sperm. These data represent the first separation of bull, boar, and ram X and Y chromosome-bearing sperm populations and the first evidence that sperm of domestic animals sorted on the basis of DNA by flow cytometric procedures have the ability to decondense and to form pronuclei upon injection into a hamster egg.     

Sex selection in mammals: a review

New methods for sperm separation and embryo sexing provide the opportunity to select the gender of the offspring of domestic mammals. We review here procedures currently available for pre- and post-fertilization sex determination, including flow cytometric selection of X- and Y-chromosome bearing spermatozoa and the application of the polymerase chain reaction to biopsied embryos. Modern techniques are considered in the context of the development of the field and parallel innovations in human medicine are briefly considered.     

Sex preselection: laboratory validation of the sperm sex ratio of flow sorted X- and Y-sperm by sort reanalysis for DNA

Laboratory validation is essential in developing an effective method for separating X and Y sperm to preselect sex. Utilizing sexed sperm from a particular experiment to test fertility and achieve the subsequent phenotypic sex without knowing the likely outcome at conception is too costly for most applications. Further, research advances need to be built on an ongoing assessment with respect to the collection of data to continue progress towards achieving a successful outcome. The Beltsville Sperm Sexing Technology, which is based on the sorting of X- and Y-bearing sperm through the process of flow-cytometric sperm sorting, is also well suited for validation in the laboratory by "sort reanalysis" of the sperm X- and Y-bearing fractions for DNA content. Since the sexing technology is based on the use of Hoechst 33342, a permeant nuclear DNA stain for sorting X- and Y-bearing sperm, it also can be the marker for determining the proportions of X and Y populations by sort reanalysis. The process consists of using an aliquot of the sorted sperm and sonicating to obtain sperm nuclei. The uniformity of the nuclear staining is re-established through the addition of more Hoechst 33342. Separate analysis of each aliquot produces a histogram that is fitted to a double gaussian curve to determine proportions of X and Y populations. The relative breadths of the distributions of DNA of X- and Y-bearing sperm within a species affects interpretations of the histogram. Sort reanalysis is consistently repeatable with differences in X/Y DNA equal to or greater than 3.0%. This information on sex ratio of the sperm then provides the precise tool by which one can predict the outcome in terms of sex, from a particular sample of semen. Simple analysis of unsorted sperm to determine the proportions of X- and Y-bearing sperm based on DNA content is also an effective tool for validating sperm-sex ratio, whether it is in a sample assumed to be 50:50 or predicted to be something other than 50:50. This simple analysis provides for a check on the potential sex ratio of any sample of semen.