Fine structure of scorpion spermatozoa (Buthus occitanus; buthidae,scorpiones)

The mature spermatozoa of Buthus occitanus are threadlike in shape and divided into sperm head, middle piece, and end piece. The sperm head is corkscrew shaped anteriorly and in this region bears an unusual acrosomal complex consisting of a ring-shaped acrosomal vacuole associated with a subacrosomal filament and a perinuclear amorphous component. The subacrosomal filament extends posteriorly into a tube-like invagination of the elongated nucleus. The middle piece is characterized by elongated mitochondria which spiral around the anterior part of the flagellum in an extended collar separated from the flagellum by an extracellular cleft, termed the central flagellar tunnel. In addition to the usual 9 × 2 + 2 axonemal pattern in flagella, 9 × 2 + 1 and 9 × 2 + 3 patterns also were observed. The end piece is represented by the free flagellum. Similarities and diversities of scorpionid spermatozoa are discussed with respect to systematic relationships.     

Discrete regional distributions suggest diverse functional roles of calcium channel alpha1 subunits in sperm

The Ca channels of male germ-line cells are partially characterized, but the molecular properties and subcellular localization of the Ca channels of mature sperm are unknown. Here, we probe rodent sperm with anti-peptide antibodies directed to cytosolic domains of cloned rat brain alpha1A, alpha1C, and alpha1E Ca channel subunits. Each recognizes a 200- to 245-kDa band on immunoblots of whole rat sperm extracts. A smaller ( approximately 110-kDa) alpha1C band also is detected. Confocal fluorescence images of mouse sperm show characteristic patterns of punctate alpha1A-, alpha1C-, and alpha1E-immunoreactivity. For alpha1A, the puncta are larger, less numerous, and more variable in distribution than for alpha1C and alpha1E. They are absent from the acrosomal crescent, but are present elsewhere over the sperm head, often at the apical tip and equatorial segment. They also are found at irregular intervals along both the midpiece and the principal piece of the flagellum. For alpha1C and alpha1E, puncta are dense along dorsal and ventral aspects of the acrosomal cap. For alpha1E but not alpha1C, the remainder of the acrosomal region also is labeled. Neither is found in the postacrosomal region or on the midpiece. Puncta of alpha1C and alpha1E occur at regular intervals each in two parallel rows, at the dorsal and ventral aspects of the proximal segment of the flagellar principal piece. The puncta in these arrays become less abundant and intense in the distal flagellum. These results demonstrate that multiple Ca channel proteins are present in mature sperm and are regionally localized in ways that may give them different regulatory roles.     

Spermiogenesis and ultrastructure of spermatozoa in Saxipendium coronatum (Hemichordata,Enteropneusta), with consideration of their relation to reproduction and dispersal

Summary Sperm ultrastructure and spermiogenesis of the enteropneust hemichordate Saxipendium coronatum conforms to the general pattern of the prototype spermatozoon found in many phyla. The sperm is about 29 m long, including head, middle piece, and tail. The Saxipendium spermatozoon has some unique features. The head is pyramidal in shape and the nucleus has four frontal ridges radiating from the base of the acrosomal region. The acrosome is composed of a large acrosomal vesicle surrounded by periacrosomal material. The acrosomal region projects about 1 m in front of the nucleus and has a width at the base of 1.5 m. The middle piece is dish-shaped and contains a large mitochondrial mass surrounding the centriolar region. The centriolar region is partially located in a centriolar fossa at the basal part of the nucleus. In spermatids, an anchoring fiber apparatus is observed surrounding the centriolar region. The distal ends of the fibers are attached to the plasmalemma by electron-dense thickenings. The tail is a simple flagellum. The sperm of Saxipendium and the small eggs found in the female suggest non-specialized external fertilization and embryogeny leading to a planktotrophic larva. The main results of the fine structure of the spermatozoon in Saxipendium are summarized in Fig. 12.Abbreviations used in the figures an antrum - av acrosomal vesicle - ax axoneme - d distal centriole - ep epidermis - f flagellum - gp gonopore - m mitochondrion - mp middle piece - n nucleus - p proximal centriole - per periacrosomal material - sp sperm - te testis - vac vacuolated cells     

Rabbit epididymal secretory proteins. II. Immunolocalization and sperm association of REP38

Polyclonal antibody was used to partially characterize REP38, a major rabbit epididymal secretory protein. Western blot analyses and immunohistochemistry indicated that REP38 is only expressed in regions 5 and 6 of the epididymis (corpus epididy-midis) and is localized in the supranuclear region and microvilli of the principal cells in these regions. It was not expressed in other tissues of the body. In region 8 (cauda epididymidis), REP38 was detected in the luminal border and cytoplasm of scattered principal cells, indicating that it may be reabsorbed in this region. This protein accumulated on the sperm plasma membrane downstream of region 5 and was localized predominantly over the acrosomal and postacrosomal regions of the head and the middle piece. Although tightly bound to epididymal sperm, REP38 migrated to the equatorial segment under conditions in vivo that would promote capacitation. When tested in vitro, anti-REP38 IgG reduced the percentage of ova fertilized in a concentration-dependent manner, apparently by blocking sperm-egg fusion.     

Identification of 36-kDa flagellar phosphoproteins associated with hamster sperm motility

In our previous paper [M. Fujinoki et al. (2001) BIOMED: Res. 22, 45-58], we reported that two types of 36-kDa protein, which were designated as 36K-A protein and 36K-B protein, obtained from hamster sperm flagella were phosphorylated at serine residues associated with the regulation of motility activation. In the present experiments, it was suggested that these two types of 36-kDa protein were phosphorylated in a cAMP-dependent manner associated with motility activation of hamster spermatozoa. Because the 36K-B protein was the most intensely phosphorylated in a cAMP-dependent manner, attempts were made to further characterize it. The 36K-B protein was assumed to be localized in the middle piece. The localization of the 36K-B protein was the same as that of the 36-kDa protein reported in our previous paper [Y. Si et al. (1999) Mol. Reprod. Dev. 52, 328-334]. In order to identify the 36K-B protein, it was analyzed by peptide mass finger printing and amino acid sequencing. The results suggested that the 36K-B protein was a pyruvate dehydrogenase E1 component beta subunit and a component of the mitochondrial sheath of the middle piece.     

Comparative distribution of short dystrophin superfamily products in various guinea pig spermatozoa domains

In this study, the presence and cellular distribution of dystrophin family products (i.e. Dp71d, Dp71f-like protein and dystrobrevin) was examined by indirect immunofluorescence and Western blotting in guinea pig spermatozoa. Two dystrophin-associated proteins, beta-dystroglycan and alpha-syntrophin, and nNOS a protein frequently associated with alpha-syntrophin, were determined. In spermatozoa lacking plasma membrane and acrosome, Dp71f-like protein was found in the postacrosomal perinuclear theca and also in the middle piece of the flagellum. In the flagellum, Dp71f-like protein is localized together with alpha-syntrophin and nNOS. Dp71d was present in the plasma membrane of the middle piece with beta-dystroglycan, alpha-syntrophin and nNOS. Dp71d was also present in plasma membrane of the post acrosomal region, but only with nNOS. Finally, dystrobrevin was located all along skeletal flagellum structures and in the subacrosomal hemisphere of the perinuclear theca. This distinct and complementary distribution in various domains of spermatozoa may reveal a specific function for each short dystrophin family product, in the stabilization of the domains where they are located.     

Identification of a heat-shock protein Hsp40, DjB1, as an acrosome- and a tail-associated component in rodent spermatozoa

Iba1 is a 17-kDa EF-hand protein highly expressed in the cytoplasm of elongating spermatids in testis. Using Iba1 as a bait, we performed yeast Two-hybrid screening and isolated a heat-shock protein Hsp40, DjB1, from cDNA library of mouse testis. To characterize DjB1 that is encoded by Dnajb1 gene, we carried out immunoblot analyses, in situ hybridization, and immunohistochemistry. Immunoblot analyses showed that DjB1was constitutively expressed in mouse testis and that its expression level was not changed by heat shock. Dnajb1 mRNA was exclusively expressed in spermatocytes and round spermatids in mouse testis, and Dnajb1 protein DjB1 was predominantly expressed in the cytoplasm of spermatocytes, round spermatids, and elongating spermatids. In mature mouse spermatozoa, DjB1 was localized in the middle and the end pieces of flagella as well as in association with the head (acrosomal region). Association of DjB1 with the acrosomal region in sperm head was also observed in rat spermatozoa. These data suggested that DjB1, which was constitutively expressed in postmeiotic spermatogenic cells in testis, was integrated into spermatozoa as at least two components, that is, sperm head and tail of rodent spermatozoa.     

Adenylate kinases 1 and 2 are part of the accessory structures in the mouse sperm flagellum

Proper sperm function depends on adequate ATP levels. In the mammalian flagellum, ATP is generated in the midpiece by oxidative respiration and in the principal piece by glycolysis. In locations where ATP is rapidly utilized or produced, adenylate kinases (AKs) maintain a constant adenylate energy charge by interconverting stoichiometric amounts of ATP and AMP with two ADP molecules. We previously identified adenylate kinase 1 and 2 (AK1 and AK2) by mass spectrometry as part of a mouse SDS-insoluble flagellar preparation containing the accessory structures (fibrous sheath, outer dense fibers, and mitochondrial sheath). A germ cell-specific cDNA encoding AK1 was characterized and found to contain a truncated 3' UTR and a different 5' UTR compared to the somatic Ak1 mRNA; however, it encoded an identical protein. Ak1 mRNA was upregulated during late spermiogenesis, a time when the flagellum is being assembled. AK1 was first seen in condensing spermatids and was associated with the outer microtubular doublets and outer dense fibers of sperm. This localization would allow the interconversion of ATP and ADP between the fibrous sheath where ATP is produced by glycolysis and the axonemal dynein ATPases where ATP is consumed. Ak2 mRNA was expressed at relatively low levels throughout spermatogenesis, and the protein was localized to the mitochondrial sheath in the sperm midpiece. AK1 and AK2 in the flagellar accessory structures provide a mechanism to buffer the adenylate energy charge for sperm motility.     

Changes in distribution and molecular weight of the acrosomal protein acrin2 (MC41) during guinea pig spermiogenesis and epididymal maturation

In this study, we examined the localization and characteristics of an intra-acrosomal protein, acrin2 (MC41), during guinea pig spermiogenesis and post-testicular sperm maturation in the epididymis, using the monoclonal antibody MC41. Immunoelectron microscopy demonstrated not only a specific domain localization of acrin2 in the apical segment of the guinea pig sperm acrosome, but also its dynamic behavior according to the spermatid differentiation and passage through the epididymis, as follows: acrin2 was exclusively localized in the membrane of the endoplasmic reticulum of early-stage spermatids but was not detectable in the developing acrosome until spermatids reached the maturation phase. In the final stage of spermiogenesis, acrin2 became localized in the outer acrosomal membrane (OAM)/matrix-associated materials both in the small region posterior to the dorsal matrix and along the ventral margin of the acrosomal apical segment. The acrosomal location of acrin2 in caput epididymidal sperm was almost identical to that observed in the final step spermatids, but during maturation it became progressively more restricted in area until on distal cauda epididymidal sperm it remained only in the dorsal region. In Western blot analysis, the MC41 antibody recognized a 165-kDa protein in the mature sperm extract. Furthermore, it was demonstrated that molecular weight reduction of the protein occurred during sperm passage through the epididymis. These findings indicate that acrin2 changes progressively in both distribution and size during development and maturation of the acrosome.     

Phagocytosis of sperm heads lacking the acrosomal process by unfertilized starfish oocytes

In sperm of the starfish Asterina pectinifera, the acrosomal process and the flagellum were mechanically separated from the sperm head with a disperser. The sperm head fraction was then used to examine the direct interaction between the sperm head and the egg surface. Sperm heads lacking the acrosomal process and the flagellum did not fertilize oocytes, even after removal of the vitelline coat. Transmission electron microscopy showed that each denuded oocyte engulfed the sperm head without gamete membrane fusion. The sperm-engulfing response, similar to phagocytosis, was induced without the mediation of the acrosomal process. The present results suggest that the process of sperm incorporation consists of two independent events, acrosomal process-egg surface fusion and the phagocytotic movement of the egg surface.     

Fine structure of the spermatozoa of Crassostrea gigas (Mollusca,Bivalvia)

We describe sperm ultrastructure and acrosome differentiation during spermiogenesis in Crassostrea gigas (Mollusca Bivalvia). The sperm cell is a uniflagellated cell of the primitive type. The head region contains a rounded or conical nucleus surmounted by small acrosome. This organelle consists of a membrane-bound acrosomal granule, the contents of which have a homogeneous density, except in the anterior region, which is positive for PTA. The acrosome also surrounds the perforatorium, which includes oriented fibrillar elements: this is the axial body. The middle piece contains four mitochondria encircling two perpendicular centrioles. The distal centriole is provided with a system of mechanical fixation to the plasma membrane, consisting of nine fibers in radial arrangement. The tail flagellum, about 50 m?m long, contains the usual microtubular axoneme. © 1993 Wiley-Liss, Inc.     

Expression of cathepsin H in differentiating rat spermatids: immunoelectron microscopic study

The expression of cathepsin H (CH) in differentiating rat spermatids was studied by an immunoelectron microscopic technique. Cathepsin H was detected in the acrosome throughout differentiation steps but cathepsins B, D, and L and lysosomal membrane protein (LGP107) were not. Early in the formation of the acrosome, CH signals were observed in Golgi vesicles but not in acrosomal vesicles. At steps 3–4, CH signals were associated with a fibrous material attached to the inner surface of the vesicle membrane on the Golgi side. At steps 5–6, this fibrous material accumulated to form an electron-dense sheet to which CH signals were confined. The rest of the acrosome was negative for the enzyme. At steps 11–12, the CH-positive fibrous sheet expanded from the apical to the ventral side of the sperm head. After step 16, the surface of outer dense fibers in the flagellar axoneme and reticulated bodies were stained for CH. In epididymal sperm, CH signals were detected in the acrosome as well as on the surface of the outer dense fibers running from the middle to the principal piece. By immunofluorescence staining, CH was found to be localized to the acrosome, middle piece, and principal piece.     

Immunolocalization of multiple Galpha subunits in mammalian spermatozoa and additional evidence for Galphas

Like somatic cells, mammalian spermatozoa appear to contain several different heterotrimeric G protein alpha-subunits that could mediate specialized cell responses. However, the precise Galpha subunits present, their subcellular location and their possible roles are still incompletely defined. In this study, using commercially available specific antibodies, we have shown by immunoblotting that Galpha(s) is present in human and mouse sperm lysates. Immunolocalization using intact spermatozoa from both species revealed this protein to be in the acrosomal cap region and the flagellum, particularly the principal piece. Treatment of permeabilized mouse spermatozoa with cholera toxin led to enhanced ADP-ribosylation of a protein the same size as Galpha(s), as well as an increase in cAMP, providing further proof for Galpha(s). Evidence for the presence and distinct localizations of Galpha(i2), Galpha(i3), Galpha(o), Galpha(q/11), and Galpha(olf) was also obtained. Of particular interest was Galpha(i2) which, like Galpha(s), was present in the acrosomal cap region and flagellum, the same regions where stimulatory and inhibitory adenosine receptors are localized. These observations are consistent with our hypothesis that G proteins mediate adenosine receptor modulation of adenylyl cyclase, with consequent alterations in cAMP production, apparently crucial for the spermatozoon's acquisition and maintenance of fertilizing ability.     

The ultrastructural organization of the mature spermatozoon of Luidia clathrata (Say) (Echinodermata: Asteroidea)

The sperm of Luidia clathrata are morphologically typical of asteroid sperm. The head is spherical and contains the nucleus and acrosomal complex. The nucleus has an anterior indentation in which rests the acrosomal complex. There is no evidence of a centriolar fossa along the posterior border of the nucleus. The acrosome is a cup-shaped structure containing a less electron dense central region. The periacrosomal material is homogeneous in nature, and the subacrosomal specialization of the periacrosomal materials appear as bands of varying electron density. The middle piece is an annular band of mitochondria which surrounds the proximal and distal centrioles. The centrioles exhibit the typical nine triplet arrangement. Both the centrioles and the axoneme project to one side of the middle piece region. Associated with the distal centriole is an elaborate pericentriolar process.     

Germinal angiotensin I-converting enzyme is totally shed from the rodent sperm membrane during epididymal maturation

Acquisition of sperm fertilizing ability is due, in part, to the reorganization of plasma membrane proteins that occurs during epididymal sperm transit. Using polyclonal antibodies against angiotensin I-converting enzyme (ACE), we showed that this enzyme is immunolocalized mainly on the middle piece of rat and mouse testicular sperm and with less intensity along the initial part of the principal piece of the flagellum. In both species, only some sperm from the caput epididymis were still reactive, whereas no labeling was observed on cauda epididymal sperm. The 105- to 110-kDa germinal ACE was absent from the rat testicular fluid but appeared in the fluid of the anterior epididymis. Thereafter, its molecular weight shifted to 94 kDa in the corpus epididymal fluid and remained at this weight in the caudal region. The 105- to 110-kDa immunoreactive protein was present in testicular rat sperm extract but was completely absent from epididymal sperm extracts. Western blot analysis of testicular and epididymal tissue extracts from the rat and mouse also confirmed that the germinal enzyme was absent from the epididymal sperm cell. Our results demonstrated that the rodent germinal ACE is released from the testicular sperm membrane when sperm enter the epididymis, a process similar to that observed in domestic mammals. This result is discussed in view of the suggested role for this enzyme in sperm fertility.     

Immunogold localization of the regulatory subunit of a type II cAMP- dependent protein kinase tightly associated with mammalian sperm flagella

We have shown previously that the regulatory subunit (RII) of a type II cAMP-dependent protein kinase is an integral component of the mammalian sperm flagellum (Horowitz, J.A., H. Toeg, and G.A. Orr. 1984. J. Biol. Chem. 259:832-838; Horowitz, J.A., W. Wasco, M. Leiser, and G.A. Orr. 1988. J. Biol. Chem. 263:2098-2104). The subcellular localization of this flagellum-associated RII in bovine caudal epididymal sperm was analyzed at electron microscope resolution with gold-conjugated secondary antibody labeling techniques using anti-RII monoclonal antibodies. By immunoblot analysis, the flagellum-associated RII was shown to interact with mAb 622 which cross reacts with both neural and nonneural isoforms of RII. In contrast, a neural specific monoclonal antibody (mAb 526) failed to interact with flagellar RII. In the midpiece of the demembranated sperm tail, gold label after mAb 622 incubation was primarily associated with the outer mitochondrial membrane. Although almost all specific labeling in the midpiece can be assigned to the mitochondria, in the principal piece, there is some labeling of the fibrous sheath. Labeling of the outer dense fibers and the axoneme was sparse. Specific labeling was virtually absent in the sperm head. Sections of sperm tails incubated in the absence of primary antisera or with mAb 526 showed little labeling. A beta-tubulin monoclonal antibody localized only to the 9 + 2 axoneme. These results raise the possibility that a type II cAMP-dependent protein kinase located at the outer mitochondrial membrane plays a role in the direct cAMP stimulation of mitochondrial respiration during sperm activation.     

Localization of prostaglandin on the plasmalemma of rabbit sperm.

Prostaglandin and prostaglandin receptors were localized on unwashed ejaculate rabbit sperm utilizing ferritin conjugated antibody to prostaglandin. Reaction was obtained over the acrosomal portion of the plasma membrane, with a greater aggregation over the apex of the head. The remainder of the head plasmalemma and flagellum showed no deposits of of reaction product. The reaction did not occur if the sperm were washed prior to incubation with the labelled antisera. However enhanced binding of ferritin was demonstrated if washed sperm were pre-incubated in PGE1. No reaction was seen in similar studies with human sperm.     

On the fine structure of spermatozoa of Tachypleus gigas (Xiphosura,Merostomata)

Summary

Among the Arthropoda the Xiphosura are the only group whose spermatozoa resemble the so-called ‘primitive type’, although even here there are some differences. The spermatozoa of Tachypleus consist of a sperm head, a middle piece, and a long flagellum. Though principally quite similar to the spermatozoa of Limulus polyphemus some characteristics are noticeably different: the axonemal pattern (9 × 2 + 0), the shape of the acrosomal vacuole, the different position of the acrosomal filament, and the distribution of mitochondria throughout the cytoplasm. In contrast to what is known from Limulus the nuclear envelope is apparently dissolved over wide areas. Consequences for the interpretation of the acrosomal reaction are discussed. Structural conditions are compared with those in other Chelicerata.     

Identification and expression of boar sperm proteins in the reproductive tract that interact with antibodies in serum from an infertile woman

Serum designated as IS obtained from a young healthy infertile woman induced a head-to-head agglutination of ejaculated boar sperm. The immunoglobulin G (IgG) prepared from IS localized to the acrosomal region of the sperm head obtained from the corpus and cauda epididymis as determined by an indirect immunofluorescent method. The IgG interacted with a boar sperm protein with an estimated molecular weight of 45-kDa, determined by sodium dodecyl sulfate-polyacrylamide gel electrophoretic (SDS-PAGE) immunoblotting technique. However, the IgG did not interact with proteins extracted from sperm obtained from the testis and caput epididymis or from non-gonadal tissues including liver, kidney, spleen, muscle and serum. The IgG interacted with additional proteins of about 75- and 38-kDa present in the corpus and cauda epididymal fluids but not those in the caput epididymal fluid. The staining intensity of the 75-kDa band was reduced and that of the 38-kDa was nullified with ejaculated seminal plasma proteins. The interacting proteins were adsorbed when chromatographed on Concanavalin A Sepharose column, suggesting that they are glycoproteins.