Use of atomic force microscopy for morphological and morphometric analyses of acrosome intact and acrosome-reacted human sperm

The objective of this study was to use atomic force microscopy (AFM), with submicron resolution, for morphophologic and morphometric analyses of acrosome intact and acrosome-reacted human sperm heads. A mixed population of acrosome intact and reacted sperm was produced by treating capacitated sperm with A23187, which induced the acrosome reaction in approximately 50% of total sperm population. This A23187-treated sperm suspension was then plated onto a coverslip and acrosome reacted sperm were preidentified by their specific staining with rhodamine-conjugated Concanavalin A. The sperm coverslip was then air-dried and scanned by a Nanoscope IIIa atomic force microscope, using the contact mode. Top and side view images processed through the illuminate mode revealed three dimensional sperm head contour, with the highest point situated in the head posterior in both acrosome intact and acrosome reacted sperm. Maximum height, length, and width measured in 50 acrosome intact and 50 acrosome-reacted sperm were the same in both populations. However, head length at half maximum height was significantly decreased in acrosome reacted sperm (2.99 +/- 0.24 microm vs. 3.56 +/- 0.32 microm of acrosome intact sperm), due to the sudden change of the height contour from the maximum peak to the anterior tip of acrosome-reacted sperm. Our results described here can therefore be used to differentiate acrosome intact and reacted sperm from each other. This would allow future studies on subcellular changes, related to the acrosome reaction, at the submicron resolution level under more physiological conditions, since AFM does not require fixing or staining of the samples.     

Studies on the decondensation of human, mouse, and bull sperm nuclei by heparin and other polyanions

We report heparin-induced decondensation of human, mouse, and bull sperm nuclei. Decondensation did not occur if the spermatozoa were intact but only if the membranes were severely damaged by freezing and thawing or by treatment with a detergent. If a disulphide bond reducing agent (thiol) was absent, decondensation of human sperm nuclei was usually a relatively slow process, with large interindividual variation. Mouse and bull sperm nuclei did not decondense in the absence of a thiol. With a thiol relatively low concentrations of heparin induced a rapid decondensation of the sperm nuclei of all three species. The decondensation activity was not specific for heparin; other polyanions were also active, with heparin being the most effective compound. It is supposed that heparin and other polyanions induce sperm nuclear decondensation because they deplete protamines from the chromatin. Thus the negatively charged phosphate groups of the DNA are no longer opposed by positively charged protamines. Consequently the mutual repulsion of unopposed phosphate groups causes the DNA molecules to stretch, which results in an increase of the sperm nuclear volume. Since heparin and other polyanions induce decondensation under physiological pH and temperature, polyanions might also be active in the oocyte.     

Difference in sperm head volume as a theoretical basis for sorting X- and Y-bearing spermatozoa: potentials and limitations

Volume-based sorting of X- and Y-chromosome-bearing sperm cells could be an interesting alternative to the existing technique based on DNA content. Advantages would be that DNA staining and ultraviolet excitation, used in the existing technique, could be avoided. To assess the possibilities and limitations of sperm-head volume as sorting criterion, achievable purity and yield are determined for bull sperm. Two important parameters in this respect are the magnitude of the volume difference and the biological variation within each (X or Y) population. Earlier, we established a difference in volume matching the difference in DNA content (3.8%) between X- and Y-bearing bull sperm heads by comparing thicknesses and areas of high numbers of pre-sorted X- and Y-bearing bull sperm heads by interference microscopy and subsequent image analysis. Unfortunately, despite the high number of measurements, a direct determination of biological variations was not possible due to an unknown contribution of instrumental variations. In this paper, we determine the contribution of instrumental errors by measuring a single sperm head, varying parameters such as location in the image, orientation angle, focusing etc., simulating the behavior of the measuring system. After correction, both for the instrumental variation, and for the fact that the original samples were not pure, biological variations in volume of 5.9 +/- 0.8% were found. Our results indicate that when 10% of the bull sperm are sorted on basis of their head volume, a theoretical enrichment of 80% could be achieved. Expected purity and yield are lower than what is standard for the existing technique. At the moment, a technique to physically separate X- and Y-bearing sperm cells based on volume is not available. However, for applications for which the potential hazards of DNA staining and UV excitation are problematic, the development of such technique should be considered.     

Zinc is sufficiently abundant within mammalian sperm nuclei to bind stoichiometrically with protamine 2

Although studies have demonstrated that zinc can bind to sperm nuclear proteins, specifically protamine 2, it has not been shown that the metal is sufficiently abundant inside the sperm nucleus to interact stoichiometrically with these proteins. In this study proton-induced X-ray emission (PIXE) has been used to measure the amount of sulfur and zinc within the nuclei of individual sperm cells to infer the stoichiometry of zinc binding to protamine 2 in six species of mammal: bull, chinchilla, stallion, hamster, human, and mouse (protamine 2 comprises from 0% (bull) to 67% (mouse) of the protamine present in the sperm of these animals). Using the sulfur mass and electrophoretic data on the relative proportion of protamine 1 and protamine 2 in the sperm chromatin of these species, the protamine 1, protamine 2, and total protamine contents within each species sperm nuclei have been determined. The PIXE measurements reveal that the zinc content of the sperm nucleus varies proportionately with the protamine 2 content of sperm chromatin. PIXE analyses of hamster protamines extracted under conditions that appear to at least partially preserve zinc binding also confirm that the majority of the metal is bound to protamine. In five of the species examined, sufficient zinc is present for each protamine 2 molecule to bind one zinc. The results obtained for chinchilla sperm, conversely, indicate the chinchilla protamine 2 molecule may interact differently with zinc. Chinchilla sperm only contain enough zinc for one atom to be bound to two protamine 2 molecules.     

Atomic force microscopy of mammalian sperm chromatin

We have used the atomic force microscope (AFM) to image the surfaces of intact bull, mouse and rat sperm chromatin and partially decondensed mouse sperm chromatin attached to coverglass. High resolution AFM imaging was performed in air and saline using uncoated, unfixed and unstained chromatin. Images of the surfaces of intact chromatin from all three species and of an AFM-dissected bull sperm nucleus have revealed that the DNA is organized into large nodular subunits, which vary in diameter between 50 and 100 nm. Other images of partially decondensed mouse sperm chromatin show that the nodules are arranged along thick fibers that loop out away from the nucleus upon decondensation. These fibers appear to stretch or unravel, generating narrow smooth fibers with thicknesses equivalent to a single DNA-protamine complex. High resolution AFM images of the nodular subunits suggest that they are discrete, clipsoid-shaped DNA packaging units possibly only one level of packaging above the protamine-DNA complex.     

Quantitative changes in histones during the formation of structures characteristic of the male pronucleus in mammalian spermatozoa in vitro

Treatment of bull spermatozoa with DDC--Na/dithiothreitol results in the swelling and decondensation of nuclear chromatin. The structures formed at the final stages of decondensation are morphologically similar to the male pronucleus. Cytophotometric analysis has shown that decondensation of chromatin in the gametes in followed by quantitative changes of basic nuclear proteins. In partly--decondensed sperm nuclei the intensity of histone staining increases as a result of the appearance of extra reactive groups. In fully decondensed nuclei there remain only 54% of histones of the original haploid level. Nucleoproteins revealed in the sperm with fully dispersed chromatin must be histones of the somatic type.     

Interspecies differences in the stability of mammalian sperm nuclei assessed in vivo by sperm microinjection and in vitro by flow cytometry

To assess the structural stability of mammalian sperm nuclei and make interspecies comparisons, we microinjected sperm nuclei from six different species into hamster oocytes and monitored the occurrence of sperm nuclear decondensation and male pronucleus formation. The time course of sperm decondensation varied considerably by species: human and mouse sperm nuclei decondensed within 15 to 30 min of injection, and chinchilla and hamster sperm nuclei did so within 45 to 60 min, but bull and rat sperm nuclei remained intact over this same period of time. Male pronuclei formed in oocytes injected with human, mouse, chinchilla, and hamster sperm nuclei, but rarely in oocytes injected with bull or rat sperm nuclei. However, when bull sperm nuclei were pretreated with dithiothreitol (DTT) in vitro to reduce protamine disulfide bonds prior to microinjection, they subsequently decondensed and formed pronuclei in the hamster ooplasm. Condensed rat spermatid nuclei, which lack disulfide bonds, behaved similarly. The same six species of sperm nuclei were induced to undergo decondensation in vitro by treatment with DTT and detergent, and the resulting changes in nuclear size were monitored by phase-contrast microscopy and flow cytometry. As occurred in the oocyte, human sperm nuclei decondensed the fastest in vitro, followed shortly by chinchilla, mouse, and hamster and, after a lag, by rat and bull sperm nuclei. Thus species differences in sperm nuclear stability exist and appear to be related to the extent and/or efficiency of disulfide bonding in the sperm nuclei, a feature that may, in turn, be determined by the type(s) of sperm nuclear protamine(s) present.     

Cholesteric organization of DNA in the stallion sperm head

The fine structure of chromatin in sperm heads was investigated by different microscopic techniques: in vivo examinations in the polarizing microscope, thin sections and freeze-fracture replicas observed by transmission electron microscopy. The freeze-fractured chromatin appears to be formed of superimposed lamellae, each one 330 A thick. These lamellae are parallel to the flattening plane of the sperm head. This situation was already described in other mammal spermatozoa and in particular in the bull and the rabbit. This work presents a new interpretation of this lamellated aspect. The chromatin structure of these spermatozoa is that of a cholesteric liquid crystal. This structure resembles that of a plywood, made of superimposed layers of parallel filaments, but instead of having a right angle between two successive layers, there is a progressive rotation and similar orientation occurs at each 180 degrees rotation. The apparent lamellae result from cleavages due to freeze-fracture between levels of parallel filament orientation. The thickness of lamellae corresponds therefore to the half helicoidal pitch of the cholesteric liquid crystal. This model is consistent with our observations by polarizing microscopy. The lamellation is not visible in thin sections of stallion spermatozoa. There are however biochemical methods to decondense chromatin and we are able to observe this lamellation in sections normal to the flattening plane of sperm heads. The methods used classically to decondense the sperm chromatin lead to extremely varied aspects which are discussed, some of them being closely related to the structure of cholesteric liquid crystals.     

Morphological differences in nuclear materials released from hamster sperm heads at an early stage of incorporation into immature oocytes,mature oocytes,or fertilized eggs

To elucidate the effects of ooplasmic factors on the early morphological changes in hamster sperm heads within the ooplasm, immature ovarian oocytes at the germinal vesicle stage (GV oocytes), ovulated fully mature oocytes, and fertilized eggs at anaphase II or the pronuclear stage (PN eggs) were examined in detail 15–30 min after insemination or reinsemination. Thin-sectioning studies demonstrated distinct materials released from the sperm nucleus over the entire postacrosomal nuclear surface immediately after disappearance of the sperm nuclear envelope. The release occurred in all of the oocytes and eggs prior to or even in the absence of subsequent chromatin decondensation. Depending upon the stage of the penetrated oocyte or egg, however, the materials varied in morphology: several hemispherical projections of amorphous material within mature oocytes; a number of electron-dense globules within GV oocytes and PN eggs; and both forms within eggs at anaphase II-telophase II. These observations and the fact that only the release of the amorphous material was accompanied by sperm chromatin decondensation indicate that this release was the initial process of chromatin decondensation, whereas the release of the globules resulted from a deficiency or lack of ooplasmic factors affecting the sperm nucleus. Restriction of the release in both forms of material to the late meiotic phase suggests changes in the factors associated with progression of meiosis. To approach an understanding of the mechanism of successful decondensation of sperm chromatin, the ooplasmic factors considered responsible for the stage-dependent release of nuclear materials are discussed. © 1996 Wiley-Liss, Inc.     

Difference in volume of X- and Y-chromosome-bearing bovine sperm heads matches difference in DNA content.

BACKGROUND: To investigate the possibilities of sperm head volume as a sorting criterion for gender preselection, we determined the magnitude of the difference in volume of X- and Y-chromosome-bearing bull sperm heads. MATERIALS AND METHODS: Bovine sperm heads were sorted on the basis of their DNA content in X- and Y-chromosome-bearing fractions, using an existing flow-cytometric technique. Images of sperm heads of both populations were recorded using Differential Interference Contrast (DIC) microscopy. After reconstructing the DIC images, the area and the optical thickness of sperm heads of both populations were determined. RESULTS: We found a difference in volume of X- and Y-bearing bovine sperm heads matching the difference in DNA content (3.5-4%). CONCLUSIONS: Our findings indicate that volume can be used as a criterion to distinguish X- and Y-chromosome-bearing sperm, making development of a technique to sort X- and Y-chromosome-bearing sperm based on head volume theoretically possible. A strong advantage of such a technique over the existing technique based on DNA content would be that X- and Y-chromosome-bearing sperm cells could thus be sorted without subjecting them to any staining.     

Transformation of sperm nuclei into male pronuclei in nucleate and anucleate fragments of parthenogenetic mouse eggs

Our objective was to examine the ability of nucleate and anucleate fragments of artificially activated mouse eggs to transform sperm nucleus into male pronucleus. To this end, zona-free oocytes in metaphase II were activated by ethanol and bisected into halves (one with the spindle, the other anucleate) either within 10 to 20 min (series A) or 3 or 5 hr later (series B). In series A, the fragments were inseminated 3,5, and 8 h after activation, and in series B. 3 and 5 h after activation. Both nucleate and anucleate fragments lose the capability of transforming sperm nucleus into fully formed pronucleus sometime between 3 and 5 h after activation. In 8 h old parthenogenetic fragments, the majority of sperm nuclei remain unchanged or begin decondensation but never reach the stage of an early pronucleus. In over 1/3 of anucleate fragments of this age group, sperm nuclei develop defectively: chromatin decondenses inside the persisting nuclear envelope. In other experimental groups, the incidence of these abnormal sperm nuclei varies between 0 and 10%. In general, the anuclcate fragments retain the capability to transform sperm nuclei (fully or partially) longer than their nuclear counterparts. This difference may be accounted for by a different level of substances required for pronuclcar growth (extrachromosomal constituents of the germinal vesicle and nuclear lamins): high and constant in the cytoplasm of anucleate egg halves and low and progressively decreasing in the nucleate halves because of their putative uptake by the female pronucleus. However, the cytoplasmic factors responsible for the initial stages of transformation (nuclear envelope breakdown, chromatin decondensation) become eventually inactivated both in the presence and in the absence of a female pronucleus.     

Sperm penetration into immature mouse oocytes and nuclear changes during maturation: an EM study

The ultrastructure of oocyte and sperm nuclei was studied in mouse ovarian oocytes inseminated in vitro and cultured for 1 1/2 and 3 h in a medium containing dbcAMP or lacking the maturation inhibitor. In oocytes blocked at the germinal vesicle (GV) stage, certain maturation-linked changes were noted. Sperm apposition and sperm-oocyte fusion were similar to that during fertilization of ovulated oocytes. The sperm nucleus and its nuclear envelope remained intact after penetrating into the ovarian oocyte. One and a half h after removal of the drug (time 0 of maturation) the germinal vesicle (GV) and sperm nucleus remained intact. In oocytes maturing for 3 h, the nuclear envelopes of the GV and sperm nucleus had fragmented. The NE of the oocyte formed quadruple membranes while the NE of the sperm remained as flat vesicles. Oocyte chromatin condensed to form chromosomes, whereas at the same time the sperm chromatin was in the process of decondensation and was surrounded by fragments of the sperm NE. The sperm chromatin, composed of DNA complexed with protamines, consisted of thin fibrils; the individual fibrils measured 3.8 nm in diameter. Near the penetrated spermatozoa only occasional Mts were detected which were not related to the proximal centriole which was recognizable in the neck-piece of the flagellum. Thus in mouse oocytes the introduced sperm centriole is not capable of behaving as a centrosome and organizing microtubules in the form of an aster.     

Changes in the stainability and sulfhydryl level in the sperm nucleus during sperm-oocyte interaction in mice

During maturation in the epididymis, mouse sperm nuclei become difficult to stain with Giemsa and its component basic dyes. Mature sperm from the cauda epididymis can be stained only after DTT treatment. Stainable sperm such as those from the testis accumulate ³H NEM when examined by autoradiography, while unstainable sperm do not, indicating a close correlation between the basic dye binding capacity and SH levels in the sperm nuclei. During insemination of zonafree ovarian oocytes with a germinal vesicle (GV), mature sperm nuclei become stainable and capable of binding with ³H NEM. At the same time, sperm have established pronase-resistant contact with the oocyte. Similarly, sperm nuclei become stainable during fertilization when the sperm attachment to the egg becomes pronase resistant. However, these changes occur before sperm chromatin decondensation begins. Therefore, it is suggested that S-S bonds in sperm nucleoproteins are reduced when the sperm establish a stable contact with the egg plasma membrane, thus reversing sperm maturational changes. The reduction of S-S bonds may be a prerequisite for sperm chromatin decondensation.     

Biochemical and ultrastructural characterizations of nucleoprotamine in human sperm heads treated with micrococcal nuclease and salt

Preparation of human sperm heads containing mainly nucleoprotamines as their chromatin constituent was described. Acrosome-depleted human sperm heads were treated with micrococcal nuclease followed with 2 M NaCl. The treatment specifically removed nucleohistone as small chromatin fragments from the human sperm heads. The nuclease-NaCl-treated sperm head pellets primarily contained nuclease-resistant nucleoprotamine as their chromatin. Transmission electron microscopic study showed that there were two populations of the nuclease-NaCl-treated human sperm head pellets. One population had thick nucleoprotamine cords of ?650–1,200 Å in diameter, and the other had thin nucleoprotamine cords of ?330–420 Å.     

Analysis of anisotropic diamagnetic susceptibility of a bull sperm

Bull sperm and paramecium cilium were exposed to uniform static magnetic fields to observe their magnetic orientations and measure their anisotropic diamagnetic susceptibility (deltachi) for each. The prepared samples were whole bull sperm, bull sperm flat heads, and paramecium cilia, because bull sperm tails in a perfect condition could not be prepared. The whole bull sperm and the bull sperm heads became oriented perpendicular to the magnetic fields (1.7 Tesla maximum), while the paramecium cilia became parallel to the magnetic fields (8 Tesla maximum). A whole bull sperm, a bull sperm head, and a paramecium cilium were photometrically studied to obtain deltachi for each, which were estimated to be 1 x 10(-19), 3 x 10(-19), and 2 x 10(-20) J/T(2), respectively. deltachi of a sperm flagellum was estimated from the measured value of deltachi of the paramecium cilium, which agrees well with the difference between deltachi of the whole sperm and the sperm head. Additionally, this difference of deltachi almost coincides with the deltachi values calculated from deltachi of tubulin, as well. If the magnetic effect on biological systems is solved and the magnetic orientation correlates with it, deltachi will become the quantitative index of the effect.     

Formation of native-like mammalian sperm cell chromatin with folded bull protamine

The DNA of most vertebrate sperm cells is packaged by protamines. The primary structure of mammalian protamine I can be divided into three domains, a central DNA binding domain that is arginine-rich and amino- and carboxyl-terminal domains that are rich in cysteine residues. In native bull sperm chromatin, intramolecular disulfide bonds hold the terminal domains of bull protamine folded back onto the central DNA binding domain, whereas intermolecular disulfide bonds between DNA-bound protamines help stabilize the chromatin of mature mammalian sperm cells. Folded bull protamine was used to condense DNA in vitro under various solution conditions. Using transmission electron microscopy and light scattering, we show that bull protamine forms particles with DNA that are morphologically similar to the subunits of native bull sperm chromatin. In addition, the stability provided by intermolecular disulfide bonds formed between bull protamine molecules within in vitro DNA condensates is comparable with that observed for native bull sperm chromatin. The importance of the bull protamine terminal domains in controlling the bull sperm chromatin morphology is indicated by our observation that DNA condensates formed under identical conditions with a fish protamine, which lacks cysteine-rich terminal domains, do not produce as uniform structures as bull protamine. A model is also presented for the bull protamine.DNA complex in native sperm cell chromatin that provides an explanation for the positions of the cysteine residues in bull protamine that form intermolecular disulfide bonds.     

The structural organization of sperm chromatin

The structure of rabbit, fowl, and Xenopus laevis sperm chromatin was explored by study of the reaction of their decondensed nuclei with DNase 1 and micrococcal nuclease. Those of rabbit and fowl were readily digested by DNase 1, and the polyacrylamide gel electrophoresis profiles of DNAs extracted from the digests were similar, each being polydisperse with a single discrete band of DNA smaller than 72 base pairs. There were differences, however, between the sperm chromatins in the course of their digestion by micrococcal nuclease. A limit digest at about 45% acid solubility was obtained with Xenopus sperm chromatin, while 90% of fowl sperm DNA was rendered acidsoluble by the enzyme. The gel profiles of the limit digests were polydisperse, but only those of rabbit and fowl sperm chromatins possessed a discrete band of DNA smaller than 72 base pairs. Bleomycin did not react with DNA of rabbit, fowl, or Xenopus spermatozoa. Since bleomycin reacts with somatic cell chromatin, and the course of DNase 1 or micrococcal nuclease digestion of sperm chromatin was different from that found for somatic cell chromatin, it would appear that sperm chromatin does not have the repeating nucleosometype structure of somatic cell chromatin. The nuclease digestion studies further suggest that the organization of rabbit and fowl sperm chromatins is similar, and is different from that of Xenopus sperm chromatin. The dependence of the structure of sperm chromatin on the composition of its basic proteins, and a possible structure for a protamine-type sperm chromatin, are discussed.     

Flow cytometry of mammalian sperm: progress in DNA and morphology measurement.

Variability in DNA content and head shape of mammalian sperm are potentially useful markers for flow cytometric monitoring of genetic damage in spermatogenic cells. The high refractive index and extreme flatness of the sperm heads produce an optical effect which interferes with DNA measurements in flow cytometers which have dye excitation and fluorescence light collection normal to the axis of flow. Orientation of sperm in flow controls this effect and results in coefficients of variation of 2.5% and 4.2%, respectively, for DNA measurements of mouse and human sperm. Alternatively, the optical effect can be used to generate shape-related information. Measurements on randomly oriented sperm from three mammalian species using a pair of fluorescence detectors indicate that large shape differences are detectable. Acriflavine-Feulgen stained sperm nuclei are significantly bleached during flow cytometric measurements at power levels routinely used in many flow cytometers. Dual beam studies of this phenomenon indicate it may be useful in detecting abnormally shaped sperm.     

Short communication: Extraction of sp18 family membrane proteins on posterior head of bull sperm and the effect of anti‐sp18 IgG on sperm motility and murine in vitro fertilization

Abstract

Bovine sperm heads were separated via ultrasonic treatment and centrifugation. Anti‐bull sperm IgG was produced by immunizing rabbits with acrosome‐reacted bull sperm heads. SDS PAGE patterns revealed that the main membrane proteins on acrosome‐reacted bull sperm head were sp18 family, including 18, 16, and 14 kD, which represented about 64% of the total membrane proteins in bull sperm. Indirect immunofluorescence shown sp18 antigens primarily distributed in postacrosomal and proximal tail regions. Western blot analysis revealed that the anti‐bull sperm IgG reacted with sp18 antigens in acrosome‐reacted bull sperm head and bull seminal plasma. Anti‐bull sperm IgG also reacted with 14, 16, 18, 42, 57 and 60 kD proteins in fresh bull, mouse and rabbit sperm. Anti‐sp18 IgG caused agglutination of bull and rabbit sperm, but had no effect on murine sperm. In murine in vitro fertilization trials, preincubating capacitated sperm with 0.364 mg/ml of anti‐sp18 IgG resulted in a decrease in the fertilization rate from 75.6% in the controls to 50.8% in the experimental groups (p<0.001).