Novel aspect of perinuclear theca assembly revealed by immunolocalization of non-nuclear somatic histones during bovine spermiogenesis

The perinuclear theca (PT) is an important accessory structure of the sperm head, yet its biogenesis is not well defined. To understand the developmental origins of PT-derived somatic histones during spermiogenesis, we used affinity-purified antibodies against somatic-type histones H3, H2B, H2A, and H4 to probe bovine testicular tissue using three different immunolocalization techniques. While undetectable in elongating spermatid nuclei, immunoperoxidase light microscopy showed all four somatic histones remained associated to the caudal head region of spermatids from steps 11 to 14 of the 14 steps in bovine spermiogenesis. Immunogold electron microscopy confirmed the localization of somatic histones on two nonnuclear structures, namely transient manchette microtubules of step-9 to step-11 spermatids and the developing postacrosomal sheath of step-13 and -14 spermatids. Immunofluorescence demonstrated somatic histone immunoreactivity in the developing postacrosomal sheath, and on anti-beta-tubulin decorated manchette microtubules of step-12 spermatids. Focal antinuclear pore complex labeling on the base of round spermatid nuclei was detected by electron microscopy and immunofluorescence, occurring before the nucleoprotein transition period during spermatid elongation. This indicated that, if nuclear histone export precedes their degradation, this process could only occur in this region, thereby questioning the proposed role of the manchette in nucleocytoplasmic trafficking. Somatic histone immunodetection on the manchette during postacrosomal sheath formation supports a role for the manchette in PT assembly, signifying that some PT components have origins in the distal spermatid cytoplasm. Furthermore, these findings suggest that somatic histones are de novo synthesized in late spermiogenesis for PT assembly.     

Immunoelectron microscope localization of snRNP,hnRNP, and ribosomal proteins in mouse spermatogenesis

We have studied the ultrastructural distribution of heterogeneous nuclear ribonucleoproteins (hnRNPs), small nuclear ribonucleoproteins (snRNPs), and ribosomal proteins during mouse spermatogenesis and spermiogenesis by means of specific antibodies and immunocytochemistry. All the above components were detectable from primary spermatocytes until the spermatid elongation phase, when the RNA synthetic activity is known to cease. Ribosomal protein (P1/P2 and L7) labeling disappeared as early as during the acrosome phase, and nucleoli were no longer labeled even during the cap phase. The nucleoplasmic structures labeled with the different anti-nucleoplasmic RNP immunoprobes corresponded, until the acrosome phase, to those previously observed as targets of the same antibodies in the nucleoplasm of somatic cell nuclei. Clusters of interchromatin granules of spermatocyte and early spermatid nuclei exhibit some labeling for hnRNP when compared with nuclei of Sertoli cells or previously analyzed liver or tissue culture cells, where these structural constituents usually remain weakly labeled or unlabeled. In spermatids in step 10, another type of nuclear granule, resembling perichromatin granules, but occurring in aggregates, can be observed. These structural constituents were labeled with antibodies recognizing nucleoplasmic snRNP antigens and therefore suggesting a non-nucleolar origin of these granules. Finally, we have observed nucleoplasmic areas of fibrogranular material, occurring only in primary spermatocytes. These components were labeled with anti-ribosomal protein antibodies but did not contain either hnRNPs or snRNPs. © 1993 Wiley-Liss, Inc.     

Partial characterization of a new basic nuclear protein from rat testis elongated spermatids.

A basic protein designated TP2 has been isolated from rat testis elongated spermatids. This new protein contains basic and acidic amino acids in relative amounts similar to those in histone F2al but is unusually rich in serine and proline. Techniques which were developed for preparing relatively homogeneous populations of spermatid nuclei were used to demonstrate that TP2 is most abundant and most actively synthesized in spermatids representing steps 12 through 15 of spermiogenesis.     

Protein Synthetic Activities during Spermiogenesis in the Sea Urchin: An high Resolution Autoradiographic Study of 3H-Leucine Incorporation

Protein synthetic activity has been studied during spermiogenesis of Paracentrotus lividus by high-resolution autoradiography using ³H-leucine as a labeled precursor. Under the adopted experimental conditions ³H-leucine is incorporated during the whole spermiogenesis period. The early spermatid is the most active stage and it shows labeling over the nucleus, the cytosol and the mitochondria. Nuclear ³H-leucine incorporation progressively decreases as spermiogenesis proceeds. Cytosol labeling shows similar values at early and intermediate spermatid and it undergoes a considerable decreases at late spermatid. Mitochondrial grain density increases from early to intermediate spermatid and it remains almost constant at late spermatid.
Our results are compared with the data reported for other animal groups and possible functions of the observed protein synthesis are discussed.     

Incorporation of (3H)uridine by the chromatoid body during rat spermatogenesis

The in vitro incorporation of tritiated uridine into RNA by the spermatogenic cells of the rat has been analyzed by high-resolution autoradiography. Special attention has been focused on the unique cytoplasmic organelle, the chromatoid body. After a short labeling time (2 h), this organelle remains unlabeled in the vast majority of the early spermatids although the nuclei are labeled. When the 2-h incubation with (3H)uridine is followed by a 14-h chase, the chromatoid body is seen distinctly labeled in all spermatids during early spermiogenesis from step 1 to step 8. Very few grains are seen elsewhere in the cytoplasm of these cells. When RNA synthesis in the spermatid ceases, the chromatoid body also remains unlabeled. It is likely that the chromatoid body contains RNA which is synthesized in the nuclei of the spermatids. The function of this RNA as a stable messenger RNA needed for the regulation of late spermiogenesis is discussed.     

Transformation of ram spermatid chromatin

In order to investigate the sequence of changes in nuclear basic proteins throughout ram spermiogenesis, we have used different techniques to obtain populations of spermatid nuclei in specific stages of maturation. Sedimentation of testis cells at 1 gravity followed by treatment with Triton X-100 resulted in one population of round spermatid nuclei (steps 1–a), one of non-round spermatid nuclei (steps 8b-15), and one of elongated spermatid nuclei (steps 12–15). Populations of non-round spermatid nuclei were obtained by treatment with EDTA (steps 9–15), by sonication (steps 12–15) and digestion by DNase (steps 13–15). Nuclear proteins, extracted either directly with dilute acid or following a reducing treatment with 2-mercaptoethanol were characterized by polyacrylamide gel electrophoresis.The most striking alterations in protein composition occur during the elongation phase (steps 8–12). The five histones are displaced from chromatin at the same rate. When they are freed of histones (step 12), the nuclei start to accumulate the sperm-specific protein (BNSP) which is then partly extractable by dilute acid without a thiol that is required for its extraction from more mature nuclei. This stepwise replacement process is accompanied by a reduction of the basic protein amount bound to DNA. As soon as histones begin to disappear, eight spermatidal protein fractions are present in the nuclei until the BNSP synthesis reaches its maximum rate. Except for one, they all contain cysteine and are partially intermolecularly cross-linked in the chromatin. After in vivo and in vitro labelling experiments, they are synthesized in elongating spermatids (steps 8–11). None are degradation products of histones.Correlations of the times of onset of EDTA, sonication and DNase resistances with changes in the basic nuclear proteins point out that stabilization and condensation of spermatid chromatin is promoted through a progressive increase in disulfide bridges.     

Spermiogenesis in the bullfrog (Rana catesbeiana): a study of cytoplasmic events including cell volume changes and cytoplasmic elimination

The process by which spermatid cytoplasmic volume is reduced and cytoplasm eliminated during spermiogenesis was investigated in the bullfrog Rana catesbeiana. At early phases of spermiogenesis, newly formed, rounded spermatids were found within spermatocysts. As acrosomal development, nuclear elongation, and chromatin condensation occurred, spermatid nuclei became eccentric within the cell. A cytoplasmic lobe formed from the caudal spermatid head and flagellum and extended toward the seminiferous tubule lumen. The cytoplasmic lobe underwent progressive condensation whereby most of its cytoplasm became extremely electron dense and contrasted sharply with numerous electron-translucent vesicles contained therein. At the completion of spermiogenesis, many spermatids with their highly condensed cytoplasm still attached were released from their Sertoli cell into the lumen of the seminiferous tubule. There was no evidence of the phagocytosis of residual bodies by Sertoli cells. Because spermatozoa are normally retained in the testis in winter and are not released until the following breeding season, sperm were induced to traverse the duct system with a single injection of hCG. Some spermatids remained attached to their cytoplasm during the sojourn through the testicular and kidney ducts; however, by the time the sperm reached the Wolffian duct, separation had occurred. The discarded cytoplasmic lobe (residual body) appeared to be degraded with the epithelium of the Wolffian duct. It was determined that the volume of the spermatid was reduced by 87% during spermiogenesis through a nuclear volume decrease of 76% and cytoplasmic volume decrease of 95.3%.     

Hormonal control of meiosis reinitation in starfish oocytes. New evidence for the absence of efficient intracellular receptors for l-methyladenine recognition.

Nuclei isolated from testes of the house cricket were centrifuged in a gradient of colloidal silica with a density range of about 1.12 to 1.18 g/ml. Fractions were collected from the bottom to the top of the gradient, and the types of nuclei in them were classified by phase microscopy. The distribution of nuclear types in the gradient indicated relatively large increases in nuclear density during spermatogenesis, and that silica-gradient centrifugation can readily yield fractions enriched for nuclei of specific developmental stages needed to study basic protein changes during sperm development. Basic proteins could be extracted from nuclei spun through silica if they were washed with polyvinylpyrrolidone. The histones in different fractions of nuclei were analysed electrophoretically. Fractions of spermatocyte and early spermatid nuclei contained histones of the somatic types as their only basic proteins. Fractions with mixtures of mid-spermatid and earlier nuclei also yielded somatic histones primarily. Essentially pure samples of late spermatid nuclei were obtained. They lacked somatic histones. In one fraction of late nuclei, the spermatid-specific histones TH1 and TH2 were the major proteins present. In another, two additional histone-like components, not detected in previous studies, were also prominent.     

Sequential Expression of Nucleoproteins during Rat Spermiogenesis

Transition proteins and protamines are highly basic sperm-specific nuclear proteins that serve to compact the DNA during late spermiogenesis. To understand their sequential role in this function, transition protein 1 (TP1), transition protein 2 (TP2), and protamine 1 (P1) were assayed by polyacrylamide gel electrophoresis in pools of microdissected, staged seminiferous tubule segments in the rat. The results were compared with immunocytochemical analyses of squash preparations from accurately identified stages of the epithelial cycle. TP2 was the first to appear as a faint band at stages IX–XI, followed by high levels at stages XII–XIV of the cycle. TP1 showed a low expression at stage XII of the cycle and peaked at stages XIII–I, whereas protamine 1 first appeared at stage I of the cycle and remained high throughout the rest of spermiogenesis. Immunocytochemical analyses and Western blots largely confirmed these results: TP2 in steps 9–14, TP1 in steps 12–15, and P1 from late step 11 to step 19 of spermiogenesis. We propose that TP2 is the first nucleoprotein that replaces histones from the spermatid nucleus, and its appearance is associated with the onset of nuclear elongation. TP1 shows up along with the compaction of the chromatin. The two transition proteins seem to have distinct roles during transformation of the nuclei and compaction of spermatid DNA.     

Histone synthesis and replacement during spermatogenesis in the mouse.

Separation of labelled nuclei by sedimentation velocity at unit gravity (Staput method) was used to study the timing of histone synthesis and replacement by testis-specific basic nuclear protein (TSP) during spermatogenesis in the mouse. Animals were injected (intratesticularly) with 1.25 micronCi per testis 3H-arginine or 2.5 micronCi per testis 3H-lysine, testis nuclei were separated, and the acid extract of each nuclear fraction was analyzed by acrylamide gel electrophoresis. The distribution of labelled histones and TSP in separated nuclei was assessed 2 h after incorporation. Changes in the labelled histone and TSP content of nuclei during subsequent differentiation (1--34 days post-label) was followed in fractions of separated testis cell nuclei and in nuclei of cauda epididymal spermatozoa. Analysis of total histone and (TSP) content indicated quantitative changes during development. Nuclei from primary spermatocytes had relatively larger amounts of histones H1 and H4. Spermatid nuclei showed a relative reduction in histones H1 and H4, coincident with the appearance of TSP in these nuclei. These results suggested that synthesis and/or removal of certain histones must occur in late primary spermatocyte and early spermatid stages of spermatogenesis. Results of labelling experiments indicated several periods of histone synthesis during spermatogenesis: (1) closely associated with the last DNA synthesis(i.e., in early primary spermatocytes), (2) late in meiotic prophase (i.e., in pachytene primary spermatocytes) and (3) simultaneous with TSP synthesis (i.e., in late spermatids). Histone H1 was more heavily labelled toward the end of the primary spermatocyte period. Histone H4 was more heavily labelled in the early primary spermatocyte period, and again at the time of TSP synthesis in spermatids. Histones synthesized before the pachytene primary spermatocyte stage appeared to be replace, but histones synthesized later in spermatogenesis appeared to be at least partially retained in epididymal spermatozoa. These results suggested that repeated specific alterations in the protein complement of the nucleus are an integral part of spermatogenic differentiation in the mouse.     

Fractionation of cricket testis nuclei on gradients of colloidal silica for study of basic protein changes during spermiogenesis

Nuclei isolated from testes of the house cricket were centrifuged in a gradient of colloidal silica with a density range of about 1.12 to 1.18 g/ml. Fractions were collected from the bottom to the top of the gradient, and the types of nuclei in them were classified by phase microscopy. The distribution of nuclear types in the gradient indicated relatively large increases in nuclear density during spermatogenesis, and that silica-gradient centrifugation can readily yield fractions enriched for nuclei of specific developmental stages needed to study basic protein changes during sperm development. Basic proteins could be extracted from nuclei spun through silica if they were washed with polyvinylpyrrolidone. The histones in different fractions of nuclei were analysed electrophoretically. Fractions of spermatocyte and early spermatid nuclei contained histones of the somatic types as their only basic proteins. Fractions with mixtures of mid-spermatid and earlier nuclei also yielded somatic histones primarily. Essentially pure samples of late spermatid nuclei were obtained. They lacked somatic histones. In one fraction of late nuclei, the spermatid-specific histones TH1 and TH2 were the major proteins present. In another, two additional histone-like components, not detected in previous studies, were also prominent.     

Testicular degeneration during spermatogenesis in the blue shark,Prionace glauca: Nonconformity with expression as seen in the diametric testes of other carcharhinids

The elasmobranch testis consists of spherical spermatocysts, each housing a single germ cell stage and its own clone of Sertoli cells. Because of the simple diametrical arrangement of cysts in maturational order, the testes of Squalus acanthias, Scyliorhinus canicula, and Prionace glauca are classified as the diametric shark testis type. The aim of this study was to document histologically the spermatocyst composition in the blue shark stage‐by‐stage and to establish whether the diametric testis type confers any uniformity regarding the expression of spermatogenesis in all sharks with this testis type. Analysis of the testes of blue sharks breeding in summer revealed extensive cyst degeneration of various forms and degrees, cyst shrinkage, and cyst disorganization with or without evidence of cell death, initially at the spermatogonia—spermatocyte transition but predominantly in spermatocyte and spermatid cysts. Animals could be grouped into two categories based on the major degenerative phenomena observed, namely those with extensive multinucleate cell (MNC) formation, and those with pronounced vacuolation in cysts. A major finding was the significant (P < 0.001) predominance of MNC formation and vacuolation in late‐stage spermatogonial cysts in the respective categories of sharks. Spermatocyte cysts showed varying degrees of germ cell depletion, with or without evidence of degeneration. Normal‐looking, but clearly subnormal‐sized primary and secondary spermatocyte cysts with no evidence of degeneration were significantly the dominant spermatocyte cyst types in both categories. It is proposed that these subnormal‐sized spermatocyte cysts could proceed into spermiogenesis. Because neighboring spermatid cysts lacked ordered bundling of spermatid heads (disorganized), a morphology significantly correlated with the vacuolation category of sharks, these results suggest that further progression into spermiogenesis was halted in such cysts. Thus, testicular degeneration in the diametric testis type is species specific in quantity and quality. J. Morphol., 2011. © 2011 Wiley‐Liss, Inc.     

Spermatogenesis inPlatynereis massiliensis (Polychaeta: Nereidae)

Stage 1 of spermatogenesis in the protandrous polychaetePlatynereis massiliensis is represented by clusters of about 60 spermatogonia which appear in the coelomic cavity. There are no testes inP. massiliensis. The origin of the spermatogonial clusters is not known. Subclusters of approximately 20 primary spermatocytes each represent stage 2. The appearance of synaptonemal figures in the spermatocyte nuclei marks the beginning of stage 3. Cells tend to lose their tight packing during stage 3 but interdigitate with cellular processes. Then very small subclusters of 4 to 8 spermatocytes appear. Meiosis is completed during stage 4, giving rise to secondary spermatocytes and then to spermatid tetrads. Spermatogonia and primary spermatocytes are interconnected by structurally specialized fusomes while secondary spermatocytes and spermatids, which are also in cytoplasmic continuity, show rather simple cell bridges. Synthesis of acrosomal material starts during stage 2. During spermiogenesis the proacrosomal vesicles of Golgi origin travel from the posterior part of the cell to its anterior part to form the acrosome proper. Acrosome formation, nuclear condensation, shaping of the long and slender sperm nucleus, and development of the sperm tail are the main events during spermiogenesis. Sperm morphology is briefly discussed wity respect to its phylogenetic bearings.     

Nuclear protein transitions in cuttle-fish spermiogenesis: Immunocytochemical localization of a protein specific for the spermatid stage

The changes in basic nuclear proteins throughout cuttle-fish spermiogenesis were investigated both by immunocytochemical procedures and by isolation of late spermatid nuclei (by virtue of their resistance to sonication). Antibodies were raised in rabbits to a protein, named protein T, isolated from testis chromatin. The anti-protein T immune serum was found to recognize protein T and not histones from the testis. Immunoperoxidase staining of sections or of smears of testis with anti-protein T antibodies showed that protein T appears in the nuclei of round spermatids, is abundant in elongating spermatid nuclei, but cannot be detected in elongated spermatids. Nuclei from these elongated spermatids were isolated by sonication treatment of testis cells. A protein, named protein Sp, with the characteristic mobility of a protamine, was isolated from elongated spermatid nuclei. This protein has the same mobility as the protamine present in mature spermatozoa. Taken together, the results indicate that in cuttle-fish, nuclear protein transitions involve the replacement of histones by a spermatid-specific protein (protein T), which is replaced at the end of elongation of the nucleus by a protamine (protein Sp). Thus, spermiogenesis of the cuttle-fish (and perhaps of other cephalopods), shows two basic nuclear protein transitions, which are similar to the transitions observed in higher vertebrates such as mammals.     

Sak57, an acidic keratin initially present in the spermatid manchette before becoming a component of paraaxonemal structures of the developing tail

We have previously reported that Sak57 (for Spermatogenic cell/Sperm-associated keratin of molecular mass 57 kDa) is an acidic keratin found in rat spermatocytes, spermatids, and sperm. Sak57 displays conserved amino acid sequences found in the 1A and 2A regions of the α-helical rod domain of keratins in human, rat, and mouse. We now report indirect immunofluorescence, confocal laser scanning microscopy and immunogold electron microscopy data showing that Sak57 is associated with the microtubular mantle of the manchette, a transient microtubular structure largely regarded as formed by tubulin and microtubule-associated proteins. The immunocytochemical localization of Sak57 was detected with a polyclonal antiserum to a multiple antigenic peptide (MAP) containing an amino acid sequence known to be present in the 2A region of the α-helical rod domain. During spermiogenic steps 8–12, Sak57 immunoreactive sites were restricted to microtubular mantle of the manchette which encircles the spermatid nucleus during shaping and chromatin condensation. At later stages (spermiogenic steps 12–14), Sak57 immunoreactive sites in the spermatid head region disappeared gradually as specific immunoreactivity appeared along the already assembled axoneme of the developing spermatid tail. Immunogold electron microscopy confirmed the presence of Sak57 immunoreactivity among microtubules of the manchette and on outer dense fibers and the longitudinal columns linking the ribs of the fibrous sheath. Mature spermatids (spermiogenic step 19) displayed tails with an immunofluorescent banding pattern contrasting with the lack of Sak57 immunoreactivity in the head region. Results from this study suggest that, during early spermiogenesis, a microtubular-Sak57 scaffolding is associated with the spermatid nucleus during shaping and chromatin condensation. During late spermiogenesis, the dispersion of the manchette coincides with the progressive visualization of Sak57 in the paraaxonemal outer dense fibers and longitudinal columns of the fibrous sheath in the developing spermatid tail. © 1996 Wiley-Liss, Inc.     

The fine structure of spermatogenesis in Hymenolepis diminuta (Cestoda) with a description of the mature spermatozoon

The processes of spermatogenesis and spermiogenesis in Hymenolepis diminuta were studied by electron microscopy using improved preparative techniques. Spermatogonia (Type A) are characterized by nuclei 3.79 (+/- 0.17) micrometer in diameter, dense cytoplasm packed with free ribosomes and aggregates of mitochondria. After mitoses, certain spermatogonia (Type B) assume syncytial rosettes containing eight nuclei. Primary spermatocytes maintain the rosette syncytium and have large nuclei (4.28 +/- 0.24 micrometer in diameter), smooth endoplasmic reticulum, and polysomes. The secondary spermatocyte is short-lived and is characterized by nuclei (2.0 +/- 0.11 micrometer in diai (2.0 +/- 0.11 micrometer in diameter) and perinuclear membranous lamellae. The syncytial spermatid cluster contains avoid nuclei which condense and elongate to a final diameter of 0.22 +/- 0.04 micrometer. Once elongated, these nuclei become delimited from the syncytium by invaginations of the plasma membrane. During delimitation, cortical peripheral microtubules arise beneath the spermatozoon plasmalemma and a 9 + 1 axoneme extends the length of the mature lance-shaped spermatozoon.     

Nuclear morphogenesis during spermiogenesis in the nudibranch molluscHypselodoris tricolor (Gastropoda,opisthobranchia)

An electron microscope study was carried out on Hypselodoris tricolor spermatids to describe the development of the nuclear morphogenesis and investigate the possible cause(s) of the change in the shape of the spermatid nucleus during spermiogenesis. Three different stages may be distinguished in the course of the nuclear morphogenesis on the basis of the morphology and inner organization of the nucleus. Stage 1 spermatid nuclei are spherical or ovoid in shape and the nucleoplasm finely granular in appearance. Stage 2 nuclei exhibit a disc- or cup-shaped morphology, and the chromatin forms short, thin filaments. During stage 3, a progressive nuclear elongation takes place, accompanied by chromatin rearrangement, first into fibers and then into lamellae, both formations helically oriented. A row of microtubules attached to the nuclear envelope completely surrounds the nucleus. Interestingly, the microtubules always lie parallel to the chromatin fibers adjacent to them. Late stage 3 spermatids show the highest degree of chromatin condensation and lack the manchette at the end of spermiogenesis. Our findings indicate the existence of a clear influence exerted on the chromatin by the manchette microtubules, which appear to be involved in determining the specific pattern of chromatin condensation in Hypselodoris tricolor.