High resolution DNA content measurements of mammalian sperm

The high condensation and flat shape of the mammalian sperm nucleus present unique difficulties to flow cytometric measurement of DNA content. Chromatin compactness makes quantitative fluorescent staining for DNA difficult and causes a high index of refraction. The refractive index makes optical measurements sensitive to sperm head orientation. We demonstrate that the optical problems can be overcome using the commercial ICP22 epiillumination flow cytometer (Ortho Instruments, Westwood, MA) or a specially built cell orientating flow cytometer (OFCM). The design and operation of the OFCM are described. Measurements of the angular dependence of fluorescence from acriflavine stained rabbit sperm show that it is capable of orienting flat sperm with a tolerance of +/- 7 degrees. Differences in the angular dependence for the similarly shaped bull and rabbit sperm allow discrimination of these cells. We show that DNA staining with 4-6 diamidino-2-phenylindole (DAPI) or an ethidium bromide mithramycin combination allows resolution of the X and Y populations in mouse sperm. They have also been successful with sperm from the bull, ram, rabbit, and boar. Reliable results with human sperm are not obtained. The accuracy of the staining and measurement techniques are verified by the correct determination of the relative DNA content of these two populations in sperm from normal mice and those with the Cattanach [7 to X] translocation. Among the potential uses of these techniques are measurement of DNA content errors induced in sperm due to mutagen exposure, and assessment of the fractions of X and Y sperm in semen that may have one population artifically enriched.     

Flow cytometric sexing of mammalian sperm

This review reexamines parameters needed for optimization of flow cytometric sexing mammalian sperm and updates the current status of sperm sexing for various species where this technology is currently being applied. Differences in DNA content have provided both a method to differentiate between these sex-determining gametes and a method to sort them that can be used for predetermining sex in mammals. Although the DNA content of all cells for each mammalian species is highly conserved, slight but measurable DNA content differences of sperm occur within species even among cattle breeds due to different sizes of Y-chromosomes. Most mammals produce flattened, oval-headed sperm that can be oriented within a sorter using hydrodynamic forces. Multiplying the percentage the difference in DNA content of the X- or Y-chromosome bearing sperm times the area of the flat profile of the sperm head gives a simple sorting index that suggests that bull and boar sperm are well suited for separation in a flow sorter. Successful sperm sexing of various species must take into account the relative susceptibilities of gametes to the stresses that occur during sexing. Sorting conditions must be optimized for each species to achieve acceptable sperm sexing efficiency, usually at 90% accuracy. In the commercial application of sperm sexing to cattle, fertility of sex-sorted bull sperm at 2 x 10(6)/dose remains at 70-80% of unsexed sperm at normal doses of 10 to 20 x 10(6) sperm. DNA content measurements have been used to identify the sex-chromosome bearing sperm populations with good accuracy in semen from at least 23 mammalian species, and normal-appearing offspring have been produced from sexed sperm of at least seven species.     

FLOW CYTOMETRY AND THE SINGLE CELL IN PHYCOLOGY

Flow cytometers measure light scattering and fluorescence characteristics from individual particles in a fluid stream as they cross one or more light beams at rates of up to thousands of events per second. Flow cytometrically detectable optical signals may arise naturally from algae, reflecting cell size, structure, and endogenous pigmentation, or may be generated by fluorescent stains that report the presence of otherwise undetected cellular constituents. Some flow cytometers can physically sort particles with desired optical characteristics out of the flow stream and collect them for subsequent culture or other analyses. The statistically rigorous, cell‐level perspective provided by flow cytometry has been advantageous in experimental investigations of phycological problems, such as the regulation of cell cycle progression. The capacity of flow cytometry to measure large numbers of cells in large numbers of samples rapidly and quantitatively has been used extensively by biological oceanographers to define the distributions and dynamics of marine picophytoplankton. Recent work has shown that flow cytometry can be used to elucidate relationships between the optical properties of individual cells and the bulk optical properties of the water they live in, and thereby may provide an explicit link between algal physiology and global biogeochemistry. Unfortunately, commercially available flow cytometers that are optimized for biomedical applications have a limited capacity to analyze larger phytoplankton. To circumvent these limitations, many investigators are developing flow cytometers specifically designed for analyzing the broad range of sizes, shapes, and pigments found among algae. These new instruments can perform some novel measurements, including simple fluorescence excitation spectra, detailed angular scattering measurements, and in‐flow digital imaging. The growing accessibility and power of flow cytometers may allow the technology to be applied to a wider array of problems in phycology, including investigations of nonplanktonic and multicellular algae, but also presents new challenges for effectively analyzing the large quantity of multiparameter data produced. Ultimately, the detection of molecular probes by flow cytometry may allow single‐cell taxonomic and physiological information to be garnered for a variety of algae, both in culture and in nature.     

Malaria-infected erythrocytes serve as biological standards to ensure reliable and consistent scoring of micronucleated erythrocytes by flow cytometry

A procedure for optimizing the configuration of flow cytometers for enumerating micronucleated erythrocytes is described. The method is based on the use of a biological model for micronucleated erythrocytes, the malaria parasite Plasmodium berghei. P. berghei endows target cells of interest (erythrocytes) with a micronucleus-like DNA content. Unlike micronuclei, parasitized red blood cells have a homogenous DNA content, and can be very prevalent in circulation. These characteristics make malaria-infected erythrocytes extremely well suited for optimizing instrument setup on a daily basis. The experiment described herein was designed to test the hypothesis that malaria-infected erythrocytes can greatly enhance the consistency with which flow cytometers are configured for micronucleus analyses, and thereby minimize intra- and interexperimental variation. Data collected over the course of several months, on two different flow cytometers, supports the premise that malaria-infected blood represents a useful biological standard which helps ensure reliable and consistent flow cytometric enumeration of rare micronucleated erythrocytes.     

Implementation of flow cytometry for quality control in four Danish bull studs

A flow cytometric method for simultaneous determination of sperm concentration and viability has recently been developed. In 2001, four Danish bull studs purchased flow cytometers and eight technicians were trained for routine analysis of raw and frozen-thawed semen. After initial training of the technicians, an experiment was carried out to document the precision of the system. The aim was also to assess if flow cytometric determination of sperm concentration could result in a more uniform production of semen doses. Results of this experiment showed high precision in the determination of sperm concentration and coefficients of variation were 3.5 and 2.4% for raw and frozen-thawed semen, respectively. Sperm viability was also assessed with high precision and coefficients of variation were 0.9% for raw semen and 1.7% for frozen-thawed semen. Furthermore, the experiment showed that package of semen doses after flow cytometric determination of sperm concentration in the raw semen results in a significantly smaller variation in the number of sperm per dose. In the second experiment, frozen semen was exchanged between the participating studs and were analysed by flow cytometry as well as by microscopic assessments by the eight technicians. Results show that the average correlation between technicians were 0.38 for motility assessments while flow cytometric agreement between technicians was significantly higher (average correlation was 0.86 for sperm viability and 0.92 for sperm concentration). The experiment also showed very high agreements between assessments within lab technician (correlations r=0.98 (sperm concentration) and r=0.99 (sperm viability)). Experiment 3 revealed that straws from the same batch varies in both concentration and viability. It is concluded that flow cytometric determination of sperm concentration and viability can be used to improve semen assessment by AI studs and result in a better quality control.     

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.     

History of commercializing sexed semen for cattle

Although the basic principles controlling the sex of mammalian offspring have been known for a relatively long time, recent application of certain modern cellular methodologies has led to development of a flow cytometric system capable of differentiating and separating living X- and Y-chromosome-bearing sperm in amounts suitable for AI and therefore, commercialization of this sexing technology. After a very long history of unsuccessful attempts to differentiate between mammalian sperm that produce males from those that produce females, a breakthrough came in 1981 when it was demonstrated that precise DNA content could be measured. Although these initial measurements of DNA content killed the sperm in the process, they led to the ultimate development of a sperm sorting system that was capable, not only of differentiating between live X- and Y-sperm, but of sorting them into relatively pure X- and Y-sperm populations without obvious cellular damage. Initial efforts to predetermine the sex of mammalian offspring in 1989 required surgical insemination, but later enhancements provided sex-sorted sperm in quantities suitable for use with IVF. Subsequent advances in flow sorting provided minimal numbers of sperm sufficient for use in AI. It was not until the flow cytometric sorting system was improved greatly and successful cryopreservation of sex-sorted bull sperm was developed that efficacious approaches to commercialization of sexed semen could be implemented worldwide in cattle. A number of companies now offer sex-sorted bovine sperm. Innovative approaches by a diverse group of scientists along with advances in computer science, biophysics, cell biology, instrumentation, and applied reproductive physiology provided the basis for commercializing sexed semen in cattle.     

Four-color flow cytometric detection of retrovirally expressed red, yellow, green, and cyan fluorescent proteins

Flow cytometric procedures are described to detect a "humanized" version of a new red fluorescent protein (DsRed) from the coral Discosoma sp. in conjunction with various combinations of three Aequorea victoria green fluorescent protein (GFP) variants--EYFP, EGFP, and ECFP. In spite of overlapping emission spectra, the combination of DsRed with EYFP, EGFP, and ECFP generated fluorescence signals that could be electronically compensated in real time using dual-laser excitation at 458 and 568 nm. Resolution of fluorescence signals from DsRed, EYFP, and EGFP was also readily achieved by single-laser excitation at 488 nm. Since many flow cytometers are equipped with an argon-ion laser that can be tuned to 488 nm, the DsRed/EYFP/EGFP combination is expected to have broad utility for facile monitoring of gene transfer and expression in mammalian cells. The dual-laser technique is applicable for use on flow cytometers equipped with tunable multiline argon-ion and krypton-ion lasers, providing the framework for studies requiring simultaneous analysis of four fluorescent gene products within living cells.     

A new multiparameter flow cytometer: optical and electrical cell analysis in combination with video microscopy in flow

BACKGROUND: Flow cytometers, which are commercially available, do not necessarily meet all demands of actual biomedical research. This is the case for the investigation of mechanisms involved in cell volume regulation, which requires electrical volume measurement and ratiometric multichannel fluorescence analysis for the simultaneous assessment of different physiologic parameters (intracellular pH and the intracellular concentration of calcium ions, etc). METHODS AND RESULTS: We describe the construction of a new nonsorting flow cytometer designed for the simultaneous acquisition of seven parameters including fluorescence signals, forward and perpendicular light scatter, cell volume according to the electrical Coulter principle, and flow cytometric imaging. The instrument is equipped with three different light sources. A tunable argon-ion laser generates efficient excitation of the most standard fluorescent probes in the visible spectral range, and an arc lamp provides the means for ultraviolet excitation at low cost. Because of the spatial filtering by the excitation and detection optics, two independent sets of dual fluorescence measurements can be performed, a prerequisite for flexible ratiometric fluorescence analysis. A flow video microscope integrated into the optical system optionally generates either brightfield or phase images of selected flowing particles. Only particles whose individual datasets meet predefined gating conditions are imaged in real time. To avoid smear effects, the motion of the object to be imaged (speed approximately 8 m/s) is frozen on the target of a CCD camera by flash illumination. For this purpose, a high radiance gas discharge lamp with 25-mJ electric pulse energy provides an illumination time of 18 ns (full width half maximum). Test results obtained from latex spheres and cells are shown. CONCLUSIONS: Test results indicate that our instrument can perform Coulter measurements in combination with flexible optical analysis. Moreover, integration of an adapted video microscope into a flow cytometer is an approach to overcome the gap between flow and image cytometry.     

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.     

"Cellular astronomy"--a foreseeable future in cytometry.

Advances in electro-optic technology within the past 2 years, notably the development of high-intensity light-emitting diodes and highly efficient charge-coupled device cameras, have made it feasible to produce small, simple, rugged, automated fluorescence image cytometers, with selling prices well below 10,000 US dollars, that can make measurements previously the exclusive domain of flow and scanning cytometers costing many times more. It should be feasible to apply the new cytometric technology in scientific and geographic areas for which a previous generation of instruments was too complex and too expensive, e.g., to problems of diagnosis and management of infectious diseases prevalent at critical levels in resource-poor areas, such as the human immunodeficiency virus, malaria, and tuberculosis.     

Application of an optical immersion-gel in a flow cytometer with horizontally oriented objective

In certain flow cytometry systems, it is desirable to use immersion optics to obtain optimum fluorescence yield. This is important when propidium iodide and other DNA fluorochromes are used that have weaker fluorescence emission compared to DAPI, when a lamp is used instead of a laser and when the DNA concentrations are low. Our Partec PA II with a horizontally oriented objective and a vertically oriented flow chamber precludes using a liquid immersion medium. The problem was solved using an optical gel with appropriate characteristics. This gel is commercially available and commonly used for connecting glass fiber cables, but has never been used for microscopy before. Compared to the manufacturer's objective (40 ×, aperture 0.8), the fluorescence yield was improved approximately four-fold using the optical gel and a 40 × glycerol objective (aperture 1.25). This innovation widens the applicability of flow cytometers with horizontally oriented objectives and vertical flow chambers. We expect it to facilitate the use of propidium iodide as a DNA stain, especially when interspecific genome size comparisons are to be done and base ratio dependent bias must be avoided.     

The binding kinetics and interaction of DNA fluorochromes used in the analysis of nuclei and chromosomes by flow cytometry

Summary The interactions and binding characteristics of DNA dyes used in the flow cytometric analysis of chromatin were studied using human chromosomes and mouse thymocyte nuclei. The kinetics of dye binding and the relationship between fluorescence intensity and dye concentration are presented. Under the conditions used, Hoechst 33258, propidium iodide and chromomycin A3 reach an equilibrium with thymocyte nuclei after approximately 5 min, 20 min and more than 1 h, respectively. The same binding kinetics are observed with Hoechst 33258 and chromomycin when nuclei are stained with a mixture of the two dyes. Sodium citrate, which improves the resolution of flow karyotypes, causes a rapid increase in Hoechst and propidium iodide fluorescence, but a decrease in the fluorescence of chromomycin. The relative peak positions of chromosomes in a flow karyotype are unaffected by sodium citrate addition. The spectral interaction between Hoechst and chromomycin is quantified. There is variation among the human chromosome types in the amount of energy transferred from Hoechst to chromomycin. By measuring the Hoechst and chromomycin fluorescence of each chromosome after Hoechst excitation, it is shown that the amount of energy transferred is correlated to the ratio of the amount of Hoechst to chromomycin bound. Although the energy transfer between the two dyes is considerable, this has little effect on the reproducibility of flow karyotype measurements. The relative peak positions of all human chromosomes in a 64×64 channel flow karyotype, except for the 13 and Y chromosomes, vary in the order of 0.5 channel over a 16-fold change in either Hoechst or chromomycin concentration. This implies that, with the present flow cytometers, variation in staining conditions will have minimal effects on the reproducibility of the relative peak positions in flow karyotypes.In honour of Prof. P. van Duijn     

Adaptation of ubiquitin-PNA based sperm quality assay for semen evaluation by a conventional flow cytometer and a dedicated platform for flow cytometric semen analysis

The purpose of semen quality evaluation is to predict the fertility potential of the sample in an objective, rapid and inexpensive manner. However, utilization of sperm quality biomarkers such as ubiquitin and lectin Arachis hypogaea agglutinin (PNA) for flow cytometric semen evaluation might eliminate the need for visual assessment by microscopy. Herein, we demonstrate a robust ubiquitin and PNA-based semen evaluation conducted on a simple, easy to operate, dedicated sperm flow cytometer, EasyCyte Plus (IMV Technologies, L'Aigle, France). Semen samples were collected periodically from two dairy bulls, which were subjected to temporary scrotal insults to induce variable semen quality. Samples were labeled with fluorescently-conjugated anti-ubiquitin antibodies (bind exclusively to the surface of defective sperm) and lectin PNA (binds to acrosomal surface in prematurely capacitated and acrosome-damaged sperm). Fluorescent properties of the samples were measured with a conventional flow cytometer (Becton Dickinson FACScan; Becton Dickinson Corp., Franklin Lakes, NJ, USA) and by the EasyCyte (IMV Technologies) instrument. Data from the two flow cytometers were positively correlated for the percentage of PNA-positive sperm with a damaged acrosome (r = 0.47; P < 0.001) and the percentage of ubiquitin-positive, defective sperm (r = 0.68; P < 0.001). Relative intensities of ubiquitin-induced fluorescence in cells with high ubiquitin levels were also positively correlated (r = 0.90). The proportion of sperm with abnormal morphology was positively correlated with ubiquitin-induced fluorescence measured by EasyCyte (IMV Technologies) (r = 0.63; P < 0.001). These observations provided a rationale for the adaptation of a dual ubiquitin-PNA sperm quality assay for flow cytometric semen evaluation.     

Flow cytometry and cell sorting of heterogeneous microbial populations: the importance of single-cell analyses.

The most fundamental questions such as whether a cell is alive, in the sense of being able to divide or to form a colony, may sometimes be very hard to answer, since even axenic microbial cultures are extremely heterogeneous. Analyses that seek to correlate such things as viability, which is a property of an individual cell, with macroscopic measurements of culture variables such as ATP content, respiratory activity, and so on, must inevitably fail. It is therefore necessary to make physiological measurements on individual cells. Flow cytometry is such a technique, which allows one to analyze cells rapidly and individually and permits the quantitative analysis of microbial heterogeneity. It therefore offers many advantages over conventional measurements for both routine and more exploratory analyses of microbial properties. While the technique has been widely applied to the study of mammalian cells, is use in microbiology has until recently been much more limited, largely because of the smaller size of microbes and the consequently smaller optical signals obtainable from them. Since these technical barriers no longer hold, flow cytometry with appropriate stains has been used for the rapid discrimination and identification of microbial cells, for the rapid assessment of viability and of the heterogeneous distributions of a wealth of other more detailed physiological properties, for the analysis of antimicrobial drug-cell interactions, and for the isolation of high-yielding strains of biotechnological interest. Flow cytometric analyses provide an abundance of multivariate data, and special methods have been devised to exploit these. Ongoing advances mean that modern flow cytometers may now be used by nonspecialists to effect a renaissance in our understanding of microbial heterogeneity.     

Modification of a laser-based flow cytometer for high-resolution DNA analysis of mammalian spermatozoa

Modification of a Coulter EPICS V orthogonal laser-based flow cytometer/cell sorter allows resolution of X and Y mammalian sperm populations based on DNA content. The modification consists of beveling the sample injection tube situated in the flow chamber, adding a second fluorescence detector directly forward along the laser beam axis, and routing the collected fluorescence through an optical fiber bundle to one of the existing photomultiplier tubes. The X and Y chromosome-bearing spermatozoa from the bull, boar, and ram can be resolved using this system.     

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.     

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。     

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.     

Radiation-induced DNA content variability in mouse sperm

Mouse sperm collected from the cauda epididymidis 35 days after acute testicular X-ray exposure and fluorescently stained for DNA show dose-dependent increases in the coefficient of variation (CV) of flow cytometrically obtained fluorescence distributions. By comparing dose-response curves obtained with three protocols which overcome the optical and cytochemical difficulties of sperm measurement in different ways we conclude the response is due to X-ray-induced DNA content variability. In the range between 0 and 600 rad the dose dependence of the square of CV of the DNA content variability, delta CV2D, is described by delta CV2D = Bx + Cx2, with 0 less than or equal to B less than or equal to 0.23 X 10(-2) and C = (0.44 +/- 0.06) X 10(-4). The dose x is measured in rad and delta CVD is expressed in percent. Computer modeling of the shapes of the fluorescence distributions show that at 600 rad 30 to 40% of the sperm have abnormal DNA content. Some have errors as large as two whole chromosomes, but it is not clear whether they are due to whole chromosome nondisjunction or a finer fragmentation of the genome. Exposures to benzo(a)pyrene and mitomycin C cause no detectable DNA content variability. We conclude mouse sperm DNA content measurements are not sensitive to small amounts of aneuploidy and as such will only be useful in detecting agents that produce substantial DNA content variability. Another animal with a smaller number of chromosomes might be more favorable. These sperm measurement techniques may find additional application in other areas of reproductive biology, such as the determination of the relative numbers of X and Y chromosome-bearing sperm in semen that may be artificially enriched in one population.