Electron-microscopic localization of baboon acrosomal antigens using antisperm monoclonal antibody.

A sperm antigen corresponding to baboon sperm monoclonal antibody 1A9 was localized in the testis and ejaculated sperm in this animal, using the immunofluorescence technique and immunogold labelling. Immunohistochemical studies of the baboon testis showed that the antigenic determinant was localized in the late spermatid cells and spermatozoa close to the seminiferous tubules. Immunofluorescence studies indicate that the protein was localized on the acrosome region of ejaculated baboon sperm. At the electron-microscopic level, gold particles indicative of the presence of this determinant recognized by 1A9 monoclonal antibody were detected on the inner acrosomal region of ejaculated baboon sperm.     

Evaluation of the human sperm acrosome reaction using a monoclonal antibody, GB24, and fluorescence-activated cell sorter

GB24 is a mouse monoclonal antibody raised against human trophoblast microvilli, which recognizes an antigenic determinant on the acrosomal region of the human sperm head. By indirect immunofluorescence, reactivity of GB24 could not be detected on freshly ejaculated spermatozoa but was strongly positive after sperm permeabilization with acetone. On viable, motile spermatozoa, reactivity appeared after induction of the acrosomal reaction with the calcium ionophore A23187. These results suggest that the antigen recognized by GB24 is present on the inner acrosomal membrane. A quantitative evaluation assay of the acrosome reaction on viable spermatozoa by flow cytometry using GB24 and indirect immunofluorescence is proposed.     

Biochemical and morphological characterization of the intra-acrosomal antigen SP-10 from human sperm

The human sperm protein SP-10 was previously defined as a "primary vaccine candidate" by a World Health Organization Taskforce on Contraceptive Vaccines. By one- and two-dimensional immunoblots, we show that SP-10, extracted from ejaculated human sperm, demonstrated a polymorphism of immunogenic peptides from 18 to 34 kDa, a pattern that was conserved from individual to individual and was not altered by reducing agents. The majority of the antigenic peptides possessed isoelectric points of approximately 4.9. Immunocytochemistry on testis sections indicated that SP-10 was localized to round spermatids and spermatozoa within the adluminal compartment of the seminiferous epithelium. Immunofluorescence showed that SP-10 was not associated with the surface of acrosome-intact, ejaculated sperm. Light and electron microscopic immunocytochemistry localized SP-10 throughout the acrosome, and electron microscopic evidence demonstrated a bilaminar array in association with the inner aspect of the outer acrosomal membrane and the outer aspect of the inner acrosomal membrane. After induction of the acrosome reaction with the ionophore A23187, SP-10 remained displayed on the sperm head in association with the inner acrosomal membrane and equatorial segment. The results indicate that the MHS-10 monoclonal antibody may be used as a marker of acrosome development in the human and as a probe to evaluate acrosome status. The results also support the hypothesis that inhibition of sperm-egg interaction by anti-SP-10 monoclonal antibody may occur as a result of antigen exposure following the acrosome reaction.     

Visualization and characterization of the acrosome reaction of human spermatozoa by immunolocalization with monoclonal antibody

A monoclonal antibody generated against hamster epididymal spermatozoa and recognizing an antigen within the acrosome was used in conjunction with FITC-antimouse immunoglobulin as a marker of the human acrosome during sperm development, capacitation, and the acrosome reaction. The specificity of binding of the monoclonal antibody was assessed using immunolocalization by epi-fluorescence and electron microscopy. Immunofluorescence revealed that antibody bound over the entire anterior acrosome in hamster and human spermatozoa. Ultrastructural localization indicated that antigen was predominantly present on the inner face of the outer acrosomal membrane and within the acrosomal content. Qualitative specificity was studied using a highly purified preparation of hamster acrosomes in an enzyme-linked immunosorbent assay. Since the antibody rapidly visualized human acrosomes, it was used to detect abnormal acrosome morphology of mature spermatozoa and to mark spermatids present in the ejaculate. During incubation in capacitating medium, changes in the immunofluorescence of live or methanol fixed spermatozoa were correlated with incubation interval and the ability of spermatozoa to fuse with zona-free hamster oocytes. Spermatozoa bound to zona-free hamster oocytes displayed no fluorescence, confirming that acrosome loss occurred before spermatozoa attached to the vitellus.     

Immunolocation of antisperm monoclonal antibody 6B10 and corresponding antigen

An antisperm monoclonal antibody 6B10 was produced by hybridoma technique of the isotype IgG. The monoclonal antibody was purified by means of ammonium sulfate precipitation and protein A-Sepharose Cl-4B affinity chromatography. SDS polyacrylamide gel electrophoresis was used to evaluate the purity of the antibody. Evaluation of the sperm acrosomal status was determined by chlortetracycline (CTC) staining. It was found that monoclonal antibody 6B10 can inhibit the sperm acrosome reaction induced by progesterone. The corresponding antigen recognized by monoclonal antibody 6B10 was located on the plasma membrane of the sperm acrosome by indirect immunofluorescent microscopy and immunoelectronmicroscopy. Sperm protein was extracted by 1% Triton X-100. The molecular weight of the antigen is 50 ku, detected by Western blot. The antigen is a key protein in the sperm acrosome reaction and may be the receptor of progesterone on the sperm acrosome. It may either be developed as a candidate contraceptive vaccine     

Immunolocation of antisperm monoclonal antibody 6B10 and corresponding antigen

An antisperm monoclonal antibody 6B10 was produced by hybridoma technique of the isotype IgG. The monoclonal antibody was purified by means of ammonium sulfate precipitation and protein A-Sepharose C1-4B affinity chromatography. SDS polyacrylamide gel electrophoresis was used to evaluate the purity of the antibody. Evaluation of the sperm acrosomal status was determined by chlortetracycline (CTC) staining. It was found that monoclonal antibody 6B10 can inhibit the sperm acrosome reaction induced by progesterone. The corresponding antigen recognized by monoclonal antibody 6B10 was located on the plasma membrane of the sperm acrosome by indirect immunofluorescent microscopy and immunoelectronmicroscopy. Sperm protein was extracted by 1% Triton X-100. The molecular weight of the antigen is 50 ku, detected by Western blot. The antigen is a key protein in the sperm acrosome reaction and may be the receptor of progesterone on the sperm acrosome. It may either be developed as a candidate contraceptive vaccine or be used as a tool in pest/rodent management.     

Identification of actin in boar spermatids and spermatozoa by immunoelectron microscopy

Actin was localized in testicular spermatids and in ionophore-treated ejaculated sperm of boar by use of a monoclonal anti-actin antibody labeled with colloidal gold. With the on-grid postembedding immunostaining of Lowicryl K4M sections, actin was identified in the subacrosomal region of differentiating spermatids, in the microfilaments of the surrounding Sertoli cells, and in the myoid cells of the tubular wall. Ejaculated sperm, labeled with the preembedding method, showed actin between the plasma membrane and the outer acrosomal membrane of the equatorial segment. Indirect immunofluorescence was positive in the equatorial segment and in the acrosomal cap of intact sperm, whereas reacted sperm at the anterior head region retained fluorescence only in the inner acrosomal membrane. Rhodamine-phalloidin failed to stain intact and reacted sperm. The distribution of actin in sperm head membranes (inner acrosomal membrane, membranes of the equatorial segment), which are retained after the acrosome reaction, is discussed.     

Localized surface antigens of guinea pig sperm migrate to new regions prior to fertilization

We have previously defined distinct localizations of antigens on the surface of the guinea pig sperm using monoclonal antibodies. In the present study we have demonstrated that these antigen localizations are dynamic and can be altered during changes in the functional state of the sperm. Before the sperm is capable of fertilizing the egg, it must undergo capacitation and an exocytic event, the acrosome reaction. Prior to capacitation, the antigen recognized by the monoclonal antibody, PT-1, was restricted to the posterior tail region (principle piece and end piece). After incubation in capacitating media at 37 degrees C for 1 h, 100% of the sperm population showed migration of the PT-1 antigen onto the anterior tail. This redistribution of surface antigen resulted from a migration of the surface molecules originally present on the posterior tail. It did not occur in the presence of metabolic poisons or when tail-beating was prevented. It was temperature-dependent, and did not require exogenous Ca2+. Since the PT-1 antigen is freely diffusing on the posterior tail before migration, the mechanism of redistribution could involve the alteration of a presumptive membrane barrier. In addition, we observed the redistribution of a second surface antigen after the acrosome reaction. The antigen recognized by the monoclonal antibody, PH-20, was localized exclusively in the posterior head region of acrosome-intact sperm. Within 7-10 min of induction of the acrosome reaction with Ca2+ and A23187, 90-100% of the acrosome-reacted sperm population no longer demonstrated binding of the PH-20 antibody on the posterior head, but showed binding instead on the inner acrosomal membrane. This redistribution of the PH-20 antigen also resulted from the migration of pre-existing surface molecules, but did not appear to require energy. The migration of PH-20 antigen was a selective process; other antigens localized to the posterior head region did not leave the posterior head after the acrosome reaction. These rearrangements of cell surface molecules may act to regulate cell surface function during fertilization.     

Characterization of baboon testicular antigens using monoclonal anti-sperm antibodies

Sperm antigens that appear during spermatogenesis in the baboon were identified by using three monoclonal antibodies generated in culture from mice immunized with baboon caudal epididymal spermatozoa. Antibodies BSA1 and BSA2 recognize trypsin-sensitive 84,000 and 45,000 dalton determinants that are restricted to the tail and anterior acrosomal regions of the sperm, respectively, as determined by Western blot and immunofluorescence techniques. The tail antigen absent in 2- and 3-yr-old baboon testes first appears in spermatid cells at about 4 yr of age. In contrast, the acrosomal antigen recognized by BSA2 is present in 3-yr-old primitive testicular germ cells. In the mature testis, the 45,000 molecular weight determinant is predominantly localized in the nucleus of late pachytene spermatocytes and round spermatid cells as observed via the avidinbiotin immunoperoxidase method. Antibody BSA3 reacted only with sailidase-treated sections of adult testis. This trypsin-resistant determinant, not expressed on testicular sperm, is recognized by antibody BSA3 only on epididymal sperm, thus indicating a post-testicular sperm modification.     

Acrosomal status in fresh and capacitated human ejaculated sperm

The acrosomal status of human sperm was evaluated by immunofluorescence utilizing a specific monoclonal antibody that recognizes target antigen(s) localized in the acrosomal cap region. Spontaneous acrosomal loss was first examined in sperm preparations used for successful in vitro fertilization of human eggs. In these sperm populations, less than 20% of the sperm underwent degenerative or spontaneous acrosomal loss following 24 h of incubation. The correlation of acrosomal loss with changes in motility and viability suggested that sperm senescence was not necessarily coupled to acrosomal loss. Chemical induction of acrosomal loss by calcium ionophore A23187 and lysophosphatidylcholine (LPC) was characterized. Maximal ionophore induction (10 microM A23187 in media containing calcium) was observed in cells exposed to capacitating conditions in vitro; sperm exposed to noncapacitating conditions did not readily acquire the ability to respond to ionophore. The reaction induced by ionophore was slow (60 min), and at least 30% of the cells were always resistant to induction. In contrast, LPC induced rapid, synchronous acrosomal loss in either freshly ejaculated or capacitated sperm in the presence or absence of extracellular calcium, suggesting that this loss was not a physiologic reaction. These studies may provide a basis for evaluating capacitation and ultimately fertility potential in the human male.     

Localization of wheat germ agglutinin and antibody binding sites on the plasma membranes of sea urchin sperm heads as revealed by label-fracture and fracture-flip

Freeze-fracture electron microscopy reveals that intramembrane particles are concentrated in a band encircling the posterior portion of the acrosome of Strongylocentrotus purpuratus sperm. Two colloidal gold labeling methods, label-fracture and replica-staining fracture-flip, were employed to show that the plant lectin wheat germ agglutinin, which recognizes a 210 kDa sperm surface glycoprotein, binds to this localized band of intramembrane particles. Monoclonal antibody J18/2, which also recognizes the 210 kDa surface glycoprotein, shows this localized binding in approximately 20% of the sperm observed in this study. The majority of sperm displayed a uniform distribution of receptor sites for monoclonal antibody J18/2. Since wheat germ agglutinin and monoclonal antibody J18/2 are known to agglutinate Strongylocentrotus purpuratus sperm but not sperm of another sea urchin, Lytechinus pictus, similar determinations were made for the latter species. Lytechinus pictus sperm are not labeled with wheat germ agglutinin and are only sparsely labeled with monoclonal antibody J18/2. The acrosomal localizations of wheat germ agglutinin and monoclonal antibody J18/2 receptors in Strongylocentrotus purpuratus sperm are consistent with the involvement of the 210 kDa surface glycoprotein in an egg jelly-induced sperm acrosome reaction. Low-temperature post-embed labeling of thin sections with wheat germ agglutinin and monoclonal antibody J18/2 show concentrations of label within the acrosomal vesicle of Strongylocentrotus purpuratus sperm, suggesting the presence of an intracellular storage site for the 210 kDa glycoprotein.     

Acrosome reaction of stallion spermatozoa evaluated with monoclonal antibody and zona-free hamster eggs

The acrosome of the stallion spermatozoon was visualized by indirect immunofluorescence with monoclonal antibody (18.6) which recognized an integral acrosomal membrane component. Localization was confirmed by electron microscopy using peroxidase labelled antibody. In fresh semen samples (n = 19), 73.9 +/- 9.1% of the spermatozoa from five fertile stallions displayed a uniform bright fluorescence over their acrosome region. In two semen samples from an infertile stallion only 28% and 35% of spermatozoa showed the same pattern of fluorescence. Spermatozoa from fertile stallions incubated for up to 12 hours in TALP medium maintained motility and exhibited a significant progressive loss of acrosomes as detected by immunofluorescence. Alternatively, a similar loss of acrosomes could be induced with calcium ionophore A23187 over a 90 minute incubation. Ultrastructural observations and incubation with zona-free hamster eggs indicated that only with ionophore treatment was immunofluorescent acrosome loss correlated with a physiological acrosome reaction, while prolonged sperm incubation led to degenerative membrane changes. It was concluded that, if carefully validated, immunofluorescent localization of the acrosome of stallion sperm with monoclonal antibody could be used to monitor the acrosome reaction. Furthermore, definitive acrosome visualization would be valuable in assessing semen quality.     

Flow cytometric analysis of mouse sperm using monoclonal anti-sperm antibody A-1

We have previously prepared an anti-mouse sperm monoclonal antibody (A-1) which inhibited sperm penetration into the egg zona pellucida. By indirect immunofluorescence (IIF), the A-1 antibody was shown to recognize an antigen localized in the acrosomal area of sperm. This antibody bound negligibly to fresh sperm, while binding to methanol-fixed sperm was almost complete. After methanol fixation, no sperm that penetrated into the zona were immunoreactive for this antibody. In the present study we examined the localization and fate of A-1 antigen during the acrosome reaction by IIF and flow cytometry (FCM). Cauda epididymal sperm were treated with either calcium ionophore A23187 or zona solution, immunostained indirectly, and subjected to FCM. Treatment with A23187 reduced the percentage of immunoreactive sperm to 59% from the 80% obtained in the untreated sperm. The treatment also reduced the average fluorescence intensity per fluorescence-positive spermatocyte to 65 channels, while this intensity was 89 channels in the untreated sperm. A similar result was obtained from treatment with zona solution. The proportion of sperm that was immunoreactive with A-1 antibody was reduced to 55% by incubation in zona-containing media from the 80% obtained in zona-free media. On the other hand, neither A23187 nor the zona solution affected the immunoreactivity or the fluorescence intensity of caput epididymal sperm, while the A-1 antigen was present in both the immature sperm from the caput epididymis of adult mice and in the mature sperm from the cauda epididymis of the same mice. These findings suggest that the intramembrane antigen recognized by the A-1 monoclonal antibody is released from sperm as a result of the acrosome reaction. © 1994 Wiley-Liss, Inc.     

Acrosomal status evaluation in human ejaculated sperm with monoclonal antibodies

An important question in mammalian gamete physiology concerns how capacitation and the occurrence of acrosome reactions in motile sperm relate to fertility. Evaluation of these relationships has been restricted by practical limitations because rapid, quantitative assays are unavailable. We have developed a rapid, reproducible assay for the evaluation of acrosomal status utilizing monoclonal antibodies specific to antigens localized in the acrosomal cap region of the sperm head. Mice were immunized with human ejaculated sperm preparations and the resultant hybridomas producing antisperm antibody were selected by solid-phase radioimmunoassay and indirect immunofluorescence (IIF). Two monoclonal antibodies (HS-19, HS-21) recognized target antigens restricted to the acrosomal cap by IIF, and 87 +/- 8.5% of the sperm in fresh ejaculates from 10 different sperm donors showed positive cap fluorescence with these reagents. Loss of HS-21 binding as measured by IIF was correlated with disappearance of the acrosomal cap as observed directly by transmission electron microscopy. Acrosomal disappearance, artificially induced in vitro using the calcium ionophore A23187, also resulted in a loss of HS-21 binding. The induction of acrosomal loss by ionophore was dependent upon extracellular calcium. The data presented suggest that specific monoclonal antibodies can be used for the rapid evaluation of acrosomal status in mammalian sperm.     

Alkalinization of acrosome measured by GFP as a pH indicator and its relation to sperm capacitation

We previously targeted EGFP (a mutant of green fluorescent protein) to the lumen of the mouse sperm acrosome and reported the time course of EGFP release during the acrosome reaction. In the study reported here, we estimated the pH within the mouse sperm acrosome utilizing the pH-dependent nature of EGFP fluorescence. The average intra-acrosomal pH was estimated to be 5.3 +/- 0.1 immediately after sperm preparation, gradually increasing to 6.2 +/- 0.3 during 120 min of incubation in TYH media suitable for capacitation. Spontaneous acrosome reactions were noted to increase concomitantly with acrosomal alkalinization during incubation. We also demonstrated that acrosomal antigens detected by monoclonal antibodies MN7 and MC41 did not dissolve following the acrosome reaction in pH 5.3 media, but dissolved at pH 6.2. These data suggest that acrosomal alkalinization during incubation conducive for sperm capacitation may function to alter acrosomal contents and prepare them for release during the acrosome reaction.     

SOB3, a human sperm protein involved in zona pellucida binding: Physiological and biochemical analysis,purification

LB5 antibody was selected from a monoclonal antibody (mAb) library directed against human sperm proteins. LB5 mAb detected the corresponding protein SOB3 in the neck region and the flagellum of most live ejaculated sperm while it labelled, in addition, the acrosome of about 10–20% of spermatozoa. The percentage of LB5 acrosome-stained sperm was significantly correlated with the percentages of either spontaneous or A23187-induced acrosome-reacted sperm. While SOB3 could not be detected in the testis, it appeared in spermatozoa from the corpus epididymis segment. LB5 mAb impaired neither sperm motion parameters, acrosomal reaction triggering, nor sperm binding to zona-free hamster oocytes. By contrast, LB5 Fab fragments (200 μg/ml) inhibited sperm binding to human zonae pellicidae by 35.7%. If sperm were induced to acrosome react with A23187 prior to LB5 treatment, the inhibitory effect shifted to 59.9%, while no significant effect was observed following A23187 incubation alone. Western blotting of human sperm and cauda epididymis extracts revealed two bands of 18 and 19 kDa. While no cross-reaction was observed with other tested organs, a similar 18-kDa band was revealed in erythocytes and one of 19 kDa in B-lymphocytes. No cross-reactivity could be evidenced in any animal sperm analyzed. SOB3 was first separated in a 17- to 20-kDa preparative electrophoresis fraction and finally purified by isoelectrofocusing according to its pI of 9.8. These results suggest that SOB3 is localized under the outer acrosomal membrane, that it participates in secondary sperm binding to the zona pellucida, and that it shares homologies with the immune system. Mol. Reprod. Dev. 49:286–297, 1998. © 1998 Wiley-Liss, Inc.     

Haprin,a novel haploid germ cell-specific RING finger protein involved in the acrosome reaction

The acrosome reaction (i.e. the exocytosis of the sperm vesicle) is a prerequisite for fertilization, but its molecular mechanism is largely unknown. We have identified a cDNA clone for a gene named haprin, which encodes a haploid germ cell-specific RING finger protein. This protein is a novel member of the RBCC (RING finger, B-box type zinc finger, and coiled-coil domain) motif family that has roles in several cellular processes, such as exocytosis. It is transcribed exclusively in testicular germ cells after meiotic division. Western blot and immunohistochemical analyses showed the molecular weight of Haprin protein to be Mr approximately 82,000. It was localized in the acrosomal region of elongated spermatids and mature sperm and was not present in acrosome-reacted sperm. The specific antibody against the RING finger domain of Haprin inhibited the acrosome reaction in permeabilized sperm. These results indicated that the novel RBCC protein Haprin plays a key role in the acrosome reaction and fertilization.     

Assessment of acrosome-reacted boar spermatozoa using monoclonal antibody GB 24 and propidium iodide

Fluorescein-labeled GB 24, a mouse monoclonal antibody, was evaluated as an acrosomal dye for boar spermatozoa that had previously been stained with propidium iodide (PI) to assess sperm viability. A specific sperm-staining pattern with fluorescein-labeled GB 24 was shown to be associated with acrosome reaction on freshly ejaculated sperm when fixed with acetone or induced with ionophore A 23187, whereas the presence of PI staining was typical of dying spermatozoa. The GB 24-PI procedure was as accurate as the glutaraldehyde method in assessing acrosomal presence or absence on freshly ejaculated spermatozoa when spontaneous or A 23187-induced acrosomal reactions were considered. Approximately half of A 23187-induced spermatozoa with acrosomal loss did not exhibit a PI fluorescence; these were potentially viable acrosome-reacted spermatozoa. On semen diluted in a boar sperm-specific diluent (BTS-A) and stored, percentages of spermatozoa with nonintact acrosome from glutaraldehyde and GB 24-PI were not significantly different. Conversely, data from GB 24-PI was significantly lower than those from glutaraldehyde when semen were undiluted. This suggested that spermatozoa with reacted acrosome gradually lost their ability to bind with GB 24. Providing unequivocal and rapid scoring of acrosome-reacted spermatozoa, the GB 24-PI procedure may be a valuable tool in the evaluation of the acrosomal status of porcine fresh spermatozoa.     

Identification and distribution of actin in spermatogenic cells and spermatozoa of the rabbit

Using a monoclonal antibody as a highly specific probe and a seminal particle-free fraction of rabbit ejaculated spermatozoa, actin has been localized in the postacrosomal region of mature rabbit spermatozoa. The sperm actin has been extracted and identified on two-dimensional PAGE immunoblots as a single spot of pI = 5.45 and Mr = 43,000. Rabbit sperm actin is present in a nonfilamentous form and is not removed by removing the plasma membrane. Unlike mature spermatozoa, however, filamentous actin is present in spermatogenic cells, as determined by rhodamine phalloidin staining. Starting as diffusely distributed in spermatocytes, actin accumulates in the subacrosomal space and appears as a band in conjunction with the developing acrosome. This band lengthens throughout the spermatid stage and becomes continuous with the postacrosomal region staining in testicular spermatozoa. Actin may therefore function during spermatogenesis to both shape the acrosome to the nucleus and to anchor inner acrosomal membrane proteins.     

Induction of the acrosome reaction in human spermatozoa by a fraction of human follicular fluid

Human ejaculated spermatozoa were washed through a Percoll gradient, preincubated for 10 hr in a defined medium containing serum albumin, and then induced to undergo rapid acrosome reactions by addition of human follicular fluid or a Sephadex G-75 column fraction of the fluid. Induction by follicular fluid did not occur when the spermatozoa were preincubated for only 0 or 5 hr. The reactions were detected by indirect immunofluorescence using a monoclonal antibody directed against the human sperm acrosomal region. The percentage of acrosomal loss counted by transmission electron microscopy agreed with that counted by immunofluorescence. The apparent molecular weight of the Sephadex G-75 fraction containing the peak of acrosome reaction-inducing activity was 45,000 ± 4,200 (SD). The occurrence of physiological acrosome reactions was supported by: assessing motility (no significant loss of motility occurred during the treatment period when sperm were preincubated with bovine serum albumin), transmission electron microscopy (the ultrastructural criteria for the acrosome reaction were met), and zona-free hamster oocyte binding and penetration (spermatozoa pretreated with the active fraction of follicular fluid, then washed and incubated with oocytes, showed significantly greater binding to and penetration of oocytes). The stimulation of the acrosome reaction by follicular fluid is apparently not due to blood serum contamination; treatment of preincubated spermatozoa with sera from the follicular fluid donors had no effect on the spermatozoa. The nature of the active component(s) in that fraction is currently being investigated.