Isolation, structure and protein composition of the perforatorium of rat spermatozoa

Heads of spermatozoa were sonically separated from tails and treated in 1 N NaOH until the perforatoria were partially detached from the nucleus. Their complete detachment was then assured by repeatedly passing the suspension through a 22-gauge needle. The perforatoria were then separated from nuclei on sucrose gradients and the purity of the fraction was verified by electron microscopy. The isolated perforatoria were denatured and used to raise antibodies or run on polycrylamide gels. Such gels revealed many polypeptide bands, six of which were most prominent (Mr approximately 13,000, 13,400, 16,000, 33,000, 35,000, and 43,000). Of these, the 16,000 Mr polypeptide was major. Anti-perforatorium serum reacted with the perforatoria of fixed spermatozoa, with a substance found between the plasmalemma and the outer acrosomal membrane of the acrosomal head cap and with the inner component of the ventral spur, but not with the postacrosomal dense lamina. This observation indicated that the perforatorium and dense lamina, although structurally continuous to form the perinuclear theca, are biochemically distinct. On Western blots, the anti-perforatorium serum reacted with the prominent polypeptides of the perforatorium and cross-reacted with some less prominent polypeptides of the fibrous sheath (FS) and outer dense fibers (ODF), most notably with a 16,000 Mr polypeptide found in both. Likewise anti-FS or anti-ODF serum cross-reacted with some major and minor polypeptides of the perforatorium, again most notably with a major 16,000 Mr polypeptide. The immunocross-reactions observed on Western blots were confirmed by immunocytochemical methods applied to spermatozoa. These results demonstrate that the perforatorium is composed of several polypeptides, is immunologically distinct from the postacrosomal dense lamina, may be immunologically similar to a substance found between the plasmalemma and outer acrosomal membrane and to a substance found on the inner aspect of the ventral spur, has antigenic determinants in common with the FS and ODF, and may share a 16,000 Mr polypeptide with these two cytoskeletal structures of the flagellum.     

Immunocytochemical identification of actin in rabbit spermiogenesis and spermatozoa

Actin was localized in testicular spermatids and in spermatozoa of rabbit by using a monoclonal anti-actin antibody and a specific antiserum against actin, labeled with colloidal gold. The antibody reactivity with sperm homogenates was determined by immunoblotting of one-dimensional gels. With on-grid postembedding immunostaining of Lowicryl K4M sections, actin was identified in the subacrosomal region of differentiating spermatids, and in four bulges situated between the inner acrosomal membrane and the nuclear envelope and in the anterior part of the postacrosomal region of ejaculated spermatozoa. Sperm actin was identified on two-dimensional gels as two spots in the isoelectric point and molecular weight corresponding to gamma and beta-isoforms of actin. Immunoblots stained with specific antibodies demonstrated that rabbit spermatozoa express gamma and beta-actin isoforms.     

Protein composition of the ventral processes on the sperm head of Australian hydromyine rodents

The sperm head of the plains rat, an Australian hydromyine rodent, is highly complex in structure and contains, in addition to an apical hook, two large ventral processes (VPs) that extend from its upper concave surface and that are largely composed of a huge extension of the sperm head cytoskeleton surrounded by postacrosomal dense lamina. In this study we have attempted to determine their protein composition. For this, the VPs were isolated, the proteins within them separated by SDS-PAGE, and the resultant polypeptide bands Western blotted and probed with antibodies against laboratory rat perforatorial and bull perinuclear theca sperm proteins. Antibodies were also used to determine the perforatorial and perinuclear theca proteins by immunogold labeling of transmission electron microscopic sections. The results indicate that the material within the VPs is largely composed of perforatorial cross-reacting proteins together with F-actin with the dominant protein being PERF 15. The perinuclear theca proteins are, by contrast, restricted to a narrow region adjacent to the acrosomal and nuclear membranes. In conclusion, this study has shown that the VPs of the spermatozoa of Australian rodents are perforatorial-like appendages that contain similar proteins to the perforatorium of the apical hook together with F-actin; their functional significance remains unknown.     

Immunoelectron microscopic distribution of actin in hamster spermatids and epididymal, capacitated and acrosome-reacted spermatozoa.

The distribution of actin in hamster sperm cells was studied during spermiogenesis, epididymal transit, in vitro capacitation and acrosome reaction by immunogold procedures using a polyclonal and two monoclonal antiactin antibodies. A predominant actin labeling (F-actin) was detected in the subacrosomal space of spermatids. Actin labeling was also observed under the plasma membrane of intercellular bridges and along the outer acrosomal membrane. In late spermatids there was both F-actin depolymerization and a loss of actin immunolabeling, thus suggesting a dispersion of G-actin monomers. No obvious labeling was evidenced in residual bodies. This pattern was observed with the three antiactin probes. In contrast, an actin labeling reappeared over the fibrous sheath of the flagellum in epididymal spermatozoa but only when the polyclonal antibody was used. Only one single actin reactive band was detected by immunoblotting of sperm extracts. Since the sperm tails were NBD phallacidin negative they were considered to contain either G-actin or actin oligomers rather than bundles of actin filaments. It is suggested that G-actin originating in the head of late spermatids was redistributed to the flagellum of epidymal spermatozoa. No further changes were noted after capacitation and acrosome reaction thus indicating no apparent effect on actin polymerization and distribution.     

Actin-binding properties and colocalization with actin during spermiogenesis of mammalian sperm calicin

The nucleus of mammalian spermatozoa is surrounded by a rigid layer, the perinuclear theca, which is divided into a subacrosomal layer and a postacrosomal calyx. Among the proteins characterized in the perinuclear theca, calicin is one of the main components of the calyx. Its sequence contains three kelch repeats and a BTB/POZ domain. We have studied the association of boar calicin with F-actin and the distribution of boar and human calicin during spermiogenesis compared with the distribution of actin. Calicin was purified from boar sperm heads under nondenaturating conditions. The molecule bound actin with high affinity (K(d) = approximately 5 nM), and a stoichiometry of approximately one calicin per 12 actin monomers was observed. Gel filtration studies showed that calicin forms homomultimers (tetramers and higher polymers). According to immunocytochemical results, calicin is present (together with actin) in the acrosomal region of round spermatids and is mainly localized in the postacrosomal region of late spermatids and spermatozoa. Taken together, the results suggest that the affinity of calicin to F-actin allows targeting of calicin at the subacrosomal space of round spermatids, and that its ability to form homomultimers contributes to the formation of a rigid calyx.     

Distribution of filamentous actin in and around spermatids and in spermatozoa of Australian conilurine rodents.

The distribution of filamentous actin around the maturing sperm head and in spermatozoa of four species of Australian conilurine rodents was investigated at the light and electron microscopic levels. Similar results were obtained for all the species studied. Mechanically isolated spermatids had NBD-phallacidin-positive longitudinal bands of fluorescence over the dorsolateral surface and, in late spermatids, bands of bright fluorescence passed perpendicularly from the dorsal convex to ventral concave surface. TEM observations indicated that these regions corresponded to filaments of ectoplasmic specializations and granular filamentous material around the tubulobulbar complexes, respectively. In testicular and cauda spermatozoa NBD-phallacidin fluorescent material was present in the two ventral processes that extended from the upper concave surface of the sperm head; also fainter material occurred along the concave border and as a dorsocaudal spur. Its distribution was identical for testicular and cauda spermatozoa. TEM of late spermatids showed that in the ventral process closest to the apical hook there were between 170 and 245 filaments, which attached to the inner surface of the postacrosomal dense lamina; in the more caudal ventral process about 70 filaments occurred. No filaments were, however, visible in the mature spermatozoon but, after immunocytochemical labelling for actin, deposition of gold particles was evident over ventral processes of both late spermatids and cauda spermatozoa. Within the female tract these ventral processes made contact with the zona matrix and were taken into the egg cytoplasm unchanged in morphology. The possible functional significance of the filamentous actin in these structures is discussed.     

Structural changes in sperm from the fiddler crab, Uca tangeri (Crustacea, Brachyura), during the acrosome reaction.

The acrosome reaction (AR) was induced in sperm from the brachyuran crustacean Uca tangeri either by mixing male and female gametes in filtered seawater or by treating the spermatozoa with the divalent cation ionophore A23187. This latter method provided a sufficient number of reacted spermatozoa to allow a detailed ultrastructural study of the AR. The process consists of two separate phases: a) initial release of the acrosomal vesicle contents, and b) further elongation of the acrosomal filament, which causes reversal of the rigid capsule limiting the acrosomal vesicle contents. The elongate acrosomal filament consists of an apical perforatorium and a basal columnar structure called here the proximal piece. The former derives from the perforatorium of the uninduced sperm stage with only small ultrastructural changes. The proximal piece forms from myelin-like membrane layers which are initially distributed all around the subacrosomal region and then accumulate in a column at the perforatorial base, thus promoting a sudden forward projection of the perforatorium. The AR in brachyurans is thought to be a passive mechanism that utilizes the negative pressure exerted on the nucleus--caused by emptying of the acrosomal vesicle--for an organized accumulation of membrane-rich material immediately behind the perforatorium, with the final result of the raising of a 3 microns long acrosomal filament.     

Formation of the ventral hooks on the sperm head of the plains mouse,Pseudomys australis

The sperm head of the plains mouse, Pseudomys australis, has three curved hooks projecting from its anterior margin. The two ventral hooks have previously been shown to consist largely of an extension of the subacrosomal material. To characterize further the structure and composition of the ventral hooks, we have examined their formation during spermiogenesis using transmission electron microscopy, silver staining, and actin localization with NBD-phallacidin. The ventral hooks develop as an extension of the perinuclear space and postacrosomal dense lamina on the anteroventral margin of the sperm head. Bundles of 6-nm-thick filaments appear in the core of each hook; these are probably actin filaments based on staining of the hooks with NBD-phallacidin. Just prior to spermiation, electron-dense material condenses in the core of the ventral hooks and concurrently in the perinuclear space in the remainder of the sperm head. The two ventral hooks thus appear to consist of a core of perinuclear material and actin filaments, which is enclosed by a continuation of the postacrosomal dense lamina.     

Basic proteins of the perinuclear theca of mammalian spermatozoa and spermatids: a novel class of cytoskeletal elements

The nuclei of bovine spermatids and spermatozoa are surrounded by dense cytoplasmic webs sandwiched between the nuclear envelope and the acrosome and plasma membrane, respectively, filling most of the cytoplasmic space of the sperm head. This web contains a complex structure, the perinuclear theca, which is characterized by resistance to extractions in nondenaturing detergents and high salt buffers, and can be divided into two major subcomponents, the subacrosomal layer and the postacrosomal calyx. Using calyces isolated from bull and rat spermatozoa we have identified two kinds of basic proteins as major constituents of the thecal structure and have localized them by specific antibodies at the light and electron microscopic level. These are an Mr 60,000 protein, termed calicin, localized almost exclusively to the calyx, and a group of multiple-band polypeptides (MBP; Mr 56,000-74,000), which occur in both the calyx and the subacrosomal layer. The polypeptides of the MBP group are immunologically related to each other, but unrelated, by antibody reactions and peptide maps, to calicin. We show that these basic cytoskeletal proteins are first detectable in the round spermatid stage. As we have not detected any intermediate filament proteins and proteins related to nuclear lamins of somatic cells in sperm heads, we conclude that the perinuclear theca and its constituents, calicin and MBP proteins, are the predominant cytoskeletal elements of the sperm head. Immunologically cross-reacting polypeptides with similar properties have been identified in the heads of rat and human spermatozoa. We speculate that these insoluble basic proteins contribute, during spermiogenesis, to the formation of the perinuclear theca as an architectural element involved in the shape changes and the intimate association of the nucleus with the acrosome and the plasma membrane.     

Formation of the perinuclear theca in spermatozoa of diverse mammalian species: relationship of the manchette and multiple band polypeptides

The perinuclear theca is a novel cytoskeletal consisting of a densely layered lamina that surrounds the nucleus of mammalian sperm. Using antibodies specific for the multiple band polypeptides present in the perinuclear theca of bull sperm, we show that a heterogeneous group of immunological related proteins are present in the sperm heads of other mammals with greatly different morphologies, including guinea pig, hamster, rat, and mouse. In none of the species were identical groups of immunoreactive polypeptides found, although immunoreactive proteins of molecular weights 65,000 to 80,000 were present in the sperm heads of all species examined. Immunoreactive proteins less than Mr 55,000 were prominent in rat sperm heads and mouse sperm: guinea pig, hamster, and rat sperm heads and mouse sperm had one band in common at approximately Mr 50,000. Different immunoreactive proteins were present in isolated sperm tails. The perinuclear theca first appeared in the subacrosomal space of round to elongating spermatids. Later, with the caudal movement of the manchette, the postacrosomal segment of the perinuclear theca was deposited in a cephalad to caudal direction along the sperm nucleus. Concomitantly, the cytoplasmic space between the nuclear envelope and the plasma membrane narrowed such that only the theca occupied this portion of the sperm head. Immunoreactivity accompanied the ultrastructural appearance of the subacrosomal layer and the postacrosomal segment. The periods of spermiogenesis, in which sub- and post-acrosomal components of the perinuclear theca are formed and the morphogenesis of sperm organelles with which these elements are associated, suggest that components of this cytoskeletal structure function to join the acrosome and the postacrosomal plasma membrane to the nucleus.     

Immunocytochemical localization of actin in the sperm head of Talpa europaea (Insectivora)

Actin in the sperm head of Talpa europaea was observed by immunofluorescence and immunoelectron microscopy. The indirect immunofluorescence technique, using both anti-actin and DNase anti-DNase methods, showed a shining fluorescent band around the sperm head in some spermatozoa, whereas in others the fluorescence was found in the postacrosomal region. Since no labeling was detected in sperms treated with NBD-phallacidin, it is likely that mature mole sperms contain G-actin but not F-actin. The results of electron microscopy indicated the deposition of the anti-actin antibodies in two places in mole spermatozoa: the postacrosomal region and the nuclear segment of the acrosome. In the first case, the actin was localized in the space between the outer surface of the postacrosomal sheath and the plasma membrane; in the second one, the actin was localized in the space between the outer acrosomal membrane and the plasma membrane. The significance of the presence of actin and its role(s) during fertilization are discussed.     

F-actin in acrosome-reacted boar spermatozoa.

Biochemical and immunoelectron microscopic methods have been used to analyze the distribution of actin in boar spermatozoa and its state of aggregation before and after acrosome reaction. F-actin was detected on sperm head and tail by electron microscopy using an improved phalloidin probe: incubation with a fluorescein-phalloidin complex and an anti-fluorescein antibody, followed by labeling with protein A-gold complex. Gold particles, indicating the presence of F-actin, were localized on the sperm surface of the acrosome-reacted spermatozoa. Specific labeling was localized (1) between the outer acrosomal membrane and the plasma membrane in the equatorial region, (2) between the outer surface of the fibrous sheath and the plasma membrane in the postacrosomal region, (3) around the connecting piece and the neck region, and (4) on the external surface of the fibrous sheath in the principal piece of the tail. Furthermore, after NP-40 extraction, the SDS-PAGE revealed a difference in solubility between reacted and unreacted boar spermatozoa, reflecting actin polymerization. We conclude that most actin in the acrosome reacted boar spermatozoa is polymeric.     

Ultrastructural and cytochemical changes of the head components of human spermatids and spermatozoa

The ultrastructural study of chromatin condensation simultaneously with the evolution of the perinuclear organelles was conducted in the spermatids and epididymal and ejaculated spermatozoa of man with the aid of the “en bloc” alcoholic PTA staining and the EDTA regressive method. The round nuclei of young spermatids (steps 1, 2) were characterized by the persistence of nucleoli that were PTA positive, and the presence of a subacrosomal layer of well-stained peripheral chromatin. In the beginning of the phase of nuclear elongation (step 3), the central chromatin also became dense, like the peripheral chromatin, while the nuclear ring and the associated manchette and the two anlages of the postacrosomal dense lamina and the posterior ring appeared. During steps 4 and 5, the sliding of the nuclear ring and the manchette, the growth of the postacrosomal dense lamina, and the progression of the posterior ring towards the base of the nucleus were seen along with structural and cytochemical modifications of the chromatin. In the flattened nuclei of step 4 spermatids, coinciding with the loss of the nucleolar components, the chromatin achieved maximum compactness in the entire nucleus and was PTA positive. In the spermatids of step 5, the disappearance of peripheral dense chromatin and the specific staining of the chromatin granules marked the beginning of the second stage of transformation of the basic nucleo-proteins. The condensed nuclei of the mature spermatids were partially stained by PTA in step 6 and totally unstained in step 7. The PTA staining revealed the persistence of PTA-positive chromatin areas in the nuclei of certain spermatids otherwise mature. The morphological aspect of the chromatin then remained the same in the nuclei of epididymal and ejaculated spermatozoa. These observations suggest that in man, as in other mammals studied, new proteins accumulate in the elongating nuclei of spermatids and are replaced at the phase of maturation by sperm-specific nucleoproteins. The defects in condensation of the chromatin that occur during spermiogenesis could be related to the modalities of accumulation of intermediate nucleoproteins.     

Silver-staining patterns of mammalian epididymal spermatozoa

Epididymal spermatozoa from 12 species of mammals were stained using silver nitrate and examined with the light microscope. Silver nitrate differentiates many of the gross morphological features of spermatozoa, including the acrosome, subacrosomal region, perforatorium, postacrosomal sheath, neck, dense outer fibers of the core of the midpiece, annulus, principal piece, and end piece. Silver-staining patterns of spermatozoa reveal both species-specific and strain-specific differences, particularly of the sperm head. The biochemical basis of silver staining may be due in part to the presence of sulfhydryl- and disulfide-rich proteins; however, it cannot be explained entirely by the presence of these moieties. The detail obtained using silver nitrate staining, coupled with the ease and rapidity of the procedure, should be useful to workers in many areas of biological and medical research.     

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.     

Perinuclear cytoskeleton of acrosome-less spermatids in the blind sterile mutant mouse.

The perinuclear cytoskeleton of mammalian spermatids is thought to play a major role in nucleus-acrosome association and in shape changes of the head during spermiogenesis. To test these hypotheses acrosome-less spermatids in blind-sterile mutant mice were investigated for the development of the subacrosomal layer. Immunogold procedures were used for the detection of actin and calmodulin. In addition to various other abnormalities many acrosome-less round and elongating spermatids developed a subacrosomal layer with an actin and calmodulin distribution similar to that observed in normal spermatids. However, in mutant elongating spermatids the apical part of the nucleus was truncated and/or folded. The expected elongation and shaping of the nucleus only occurred in its caudal part associated with an hypertrophied and somewhat ectopic manchette. These abnormalities and those previously observed in mutant and experimental models indicated that the subacrosomal layer may form independently of the acrosome. It is suggested that the subacrosomal filamentous actin is a transitory scaffolding which might be involved in the assemblage of other proteins of the perinuclear cytoskeleton. However, by itself, this layer is not sufficient to ensure a normal shaping of the nucleus. Acrosome-nucleus interactions mediated by the subacrosomal layer seem necessary to shape the cranial spermatid head. The manchette appears to be involved only in the caudal nuclear shaping.     

Immunogold distribution of actin during sperimiogenesis in the normal rabbit and after experimental cryptorchidism

Immunogold procedures for actin detection were used in combination with experimental cryptorchidism in the rabbit as a modei to shed more light on the function of subacrosomal actin during spermiogenesis. In the normal testis, actin was localized in the perinuclcar substance (PNS) from round spermatid onward but it was not detected in late spermatids. Actin labeling in each type of spermatid was essentially unmodified after 24 hr of cryptorchidism. However, among relevant immediate and delayed effects, discontinuous acrosomes overlying a continuous PNS with normal actin labeling were noted. Nuclear invaginations were seen in combination with subacrosomal dilatations: at this site actin labeling was found only in the PNS closely apposed to the nuclear envelope. In subacrosomal areas lacking PNS, actin labeling also was lacking. These results suggest that the subacrosomal actin (F-actin) is a component of the PNS that is tightly bound to the nuclear envelope rather than the overlying inner acrosomal membrane. Therefore, a function for the subacrosomal actin either in anchoring the acrosome to the nucleus or in capping the inner acrosomal membrane appears unlikely. The data rather suggest a capping function for the nuclear membrane during spermiogenesis.     

Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa

Using commercial monoclonal antibodies against actin and tubulin (alpha and beta), the respective antigens were localized on semithin and ultrathin sections of the rat testis. Tubulin immunofluorescence was found in the socalled manchette surrounding the heads of the maturating spermatids as well as the sperm tail. The distribution pattern varied with sperm development. Modified Sertoli cells found at the transition between the seminiferous tubules and the rete testis displayed much filamentous tubulin-reactive material. The immunofluorescence findings could be confirmed at the ultrastructural level using the indirect immunogold method. Actin immunofluorescence was demonstrated in vascular smooth muscle cells, interstitial macrophages and - most intensely - in peritubular cells. Inside the seminiferous tubules the Sertoli cell junctions and the ectoplasmic specializations of the Sertoli cells that follow the outer contour of spermatid heads displayed distinct actin immunofluorescence. In addition to the locations mentioned, actin-like immunoreactivity was visualized at the ultrastructural level in the chromatoid body and the subacrosomal space of spermatids as well as on the outer dense fibers of the sperm tail. Immunoblotting experiments with actin antibodies showed that in extracts from testicular spermatozoa, intact or fragmented into heads and tails, from isolated Sertoli cells grown in vitro, and from testis tissue in addition to authentic actin a protein was present in sperm tail extracts that strongly bound the actin antibody. This protein may be an actin-related protein and may be responsible for the actin-like immunoreactivity of the outer dense fibers of the sperm tail.     

Differentiation of the acrosomal complex in ostrich (Struthio camelus) spermatids

The acrosomal complex of ostrich sperm consists of a small, cone-shaped acrosome and a slender, cylindrical perforatorium housed within a deep endonuclear canal. The perforatorium is almost exclusively endonuclear in location and is only covered by the acrosome at its point of origin in the apical subacrosomal space. The development of the acrosome is generally similar to that described in other non-passerine birds. Small proacrosomal granules (vesicles) emanating from the Golgi apparatus coalesce to form a large, membrane-bound acrosomal vesicle filled with homogeneous, electron-dense material. The acrosomal vesicle attaches to the nucleus via a shallow depression and subsequently collapses to form the typical cap-like acrosome of non-passerine birds. In ostrich spermatids the endonuclear canal becomes obvious when the collapsed acrosomal vesicle has assumed a dumbbell-shaped appearance. The perforatorium, which originates from moderately electron-dense material contained within the apical subacrosomal space, expands within the deepening endonuclear canal. The material of the perforatorium does not originate in the form of an obvious granule as in chicken and budgerigar spermatids. Indications are that in ostrich spermatids the developing acrosome plays a role in the shaping of the tip of the nucleus. The perforatorium, however, appears to represent a residual structure that has no specifically identified function. © 1996 Wiley-Liss, Inc.     

Localization of a single sperm membrane autoantigen (RSA-1) on spermatogenic cells and spermatozoa

The rabbit sperm membrane autoantigen RSA-1 is a sialoglycoprotein of 13,000 daltons which first appears on the surface of pachytene spermatocytes. Using specific antiserum to RSA-1 the antigen has been localized by immunofluorescence and immunoperoxidase staining. On testicular cells labeled at 37°C, RSA-1 is seen in patches on the surfaces of pachytene spermatocytes, round spermatids, and over the acrosomal area of later spermatids and spermatozoa. Over the postacrosomal and middle-piece regions of late spermatids and spermatozoa the labeling appears uniform. The uniformity can be seen to stop abruptly at the equatorial segment-postacrosomal border. Labeling cells after fixation gives a uniform distribution of label over the surface where patches were seen at 37°C. The polypeptides recognized by the antiserum used for labeling were identified by immunoadsorbent chromatography and subsequent SDS-PAGE. In testicular cells anti-RSA-1 recognizes the 13,000-dalton form and another component which migrates with the dye front. In ejaculated spermatozoa anti-RSA-1 recognizes a distinct ejaculate complex of higher-molecular-weight proteins containing an 84,000-dalton major band and five minor components.