Mouse protamine 2 is synthesized as a precursor whereas mouse protamine 1 is not.

The nuclei of mouse spermatozoa contain two protamine variants, mouse protamine 1 (mP1) and mouse protamine 2 (mP2). The amino acid sequence predicted from mP1 cDNAs demonstrates that mP1 is a 50-amino-acid protein with strong homology to other mammalian P1 protamines. Nucleotide sequence analysis of independently isolated, overlapping cDNA clones indicated that mP2 is initially synthesized as a precursor protein which is subsequently processed into the spermatozoan form of mP2. The existence of the mP2 precursor was confirmed by amino acid composition and sequence analysis of the largest of a set of four basic proteins isolated from late-step spermatids whose synthesis is coincident with that of mP1. The sequence of the first 10 amino acids of this protein, mP2 precursor 1, exactly matches that predicted from the nucleotide sequence of cDNA and genomic mP2 clones. The amino acid composition of isolated mP2 precursor 1 very closely matches that predicted from the mP2 cDNA nucleotide sequence. Sequence analysis of the amino terminus of isolated mature mP2 identified the final processing point within the mP2 precursor. These studies demonstrated that mP2 is synthesized as a precursor containing 106 amino acids which is processed into the mature, 63-amino-acid form found in spermatozoa.     

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.     

Intramanchette transport (IMT): managing the making of the spermatid head,centrosome, and tail

Intramanchette transport (IMT) and intraflagellar transport (IFT) share similar molecular components: a raft protein complex transporting cargo proteins mobilized along microtubules by molecular motors. IFT, initially discovered in flagella of Chlamydomonas, has been also observed in cilia of the worm Caenorhabditis elegans and in mouse ciliated and flagellated cells. IFT has been defined as the mechanism by which protein raft components (also called IFT particles) are displaced between the flagellum and the plasma membrane in the anterograde direction by kinesin-II and in the retrograde direction by cytoplasmic dynein 1b. Mutation of the gene Tg737, encoding one of the components of the raft protein complex, designated Polaris in the mouse and IFT88 in both Chlamydomonas and mouse, results in defective ciliogenesis and flagellar development as well as asymmetry in left-right axis determination. Polaris/IFT88 is detected in the manchette of mouse and rat spermatids. Indications of an IMT mechanism originated from the finding that two proteins associated with the manchette (Sak57/K5 and TBP-1, the latter a component of the 26S proteasome) repositioned to the centrosome and sperm tail once the manchette disassembled. IMT has the features of the IFT machinery but, in addition, facilitates nucleocytoplasmic exchange activities during spermiogenesis. An example is Ran, a small GTPase present in the nucleus and cytoplasm of round spermatids and in the manchette of elongating spermatids. Upon disassembly of the manchette, Ran GTPase is found in the centrosome region of elongating spermatids. Because defective molecular motors and raft proteins result in defective flagella, cilia, and cilia-containing photoreceptor cells in the retina, IMT and IFT are emerging as essential mechanisms for managing critical aspects of sperm development. Details of specific role of Ran GTPase in nucleocytoplasmic transport and its relocation from the manchette to the centrosome to the sperm tail await elucidation.     

Nuclear basic protein transition during sperm differentiation. Amino acid sequence of a spermatid-specific protein from the dog-fish Scylliorhinus caniculus

During dog-fish spermatogenesis, chromatin undergoes a continuous processing which involves two basic protein transitions: the first from somatic-type histones to spermatid-specific proteins and the second leading to protamines. Two spermatid-specific proteins S1 and S2 were isolated from nuclei of spermatid-enriched testis zone and the amino acid sequence of S1 has been determined. S1 contains 87 amino acids and has a molecular mass of 11179 Da. It is mainly characterized by a high content of basic residues (45%) and the presence of one residue of cysteine. Its primary structure shows that the N-terminal half is highly basic while the hydrophobic residues are preferentially localized in the C-terminal region. Three forms of S1 are present in testis which correspond to di-, mono- and nonphosphorylated molecules. This spermatid-specific protein shares no common structural feature with either histones and dog-fish protamines or rat spermatid-specific protein which has been previously described.     

Ran,a GTP-binding protein involved in nucleocytoplasmic transport and microtubule nucleation,relocates from the manchette to the centrosome region during rat spermiogenesis

Ran, a Ras-related GTPase, is required for transporting proteins in and out of the nucleus during interphase and for regulating the assembly of microtubules. cDNA cloning shows that rat testis, like mouse testis, expresses both somatic and testis-specific forms of Ran-GTPase. The presence of a homologous testis-specific form of Ran-GTPase in rodents implies that the Ran-GTPase pathway plays a significant role during sperm development. This suggestions is supported by distinct Ran-GTPase immunolocalization sites identified in developing spermatids. Confocal microscopy demonstrates that Ran-GTPase localizes in the nucleus of round spermatids and along the microtubules of the manchette in elongating spermatids. When the manchette disassembles, Ran-GTPase immunoreactivity is visualized in the centrosome region of maturing spermatids. The circumstantial observation that fractionated manchettes, containing copurified centrin-immunoreactive centrosomes, can organize a three-dimensional lattice in the presence of taxol and GTP, points to the role of Ran-GTPase and associated factors in microtubule nucleation as well as the potential nucleating function of spermatid centrosomes undergoing a reduction process. Electron microscopy demonstrates the presence in manchette preparations of spermatid centrosomes, recognized as such by their association with remnants of the implantation fossa, a dense plate observed only at the basal surface of developing spermatid and sperm nuclei. In addition, we have found importin beta1 immunoreactivity in the nucleus of elongating spermatids, a finding that, together with the presence of Ran-GTPase in the nucleus of round spermatids and the manchette, suggest a potential role of Ran-GTPase machinery in nucleocytoplasmic transport. Our expression and localization analysis, correlated with functional observations in other cell systems, suggest that Ran-GTPase may be involved in both nucleocytoplasmic transport and microtubules assembly, two critical events during the development of functional sperm. In addition, the manchette-to-centrosome Ran-GTPase relocation, together with the similar redistribution of various proteins associated to the manchette, suggest the existence of an intramanchette molecular transport mechanism, which may share molecular analogies with intraflagellar transport.     

Spnr, a murine RNA-binding protein that is localized to cytoplasmic microtubules

Previous studies in transgenic mice have established the importance of the 3' untranslated region (UTR) of the spermatid-specific protamine-1 (Prm-1) mRNA in its translational control during male germ cell development. To clone genes that mediate the translational repression or activation of the Prm-1 mRNA, we screened cDNA expression libraries made with RNA from pachytene spermatocytes and round spermatids, with an RNA probe corresponding to the 3' UTR of Prm-1. We obtained six independent clones that encode Spnr, a spermatid perinuclear RNA- binding protein. Spnr is a 71-kD protein that contains two previously described RNA binding domains. The Spnr mRNA is expressed at high levels in the testis, ovary, and brain, and is present in multiple forms in those tissues. Immunolocalization of the Spnr protein within the testis shows that it is expressed exclusively in postmeiotic germ cells and that it is localized to the manchette, a spermatid-specific microtubular array. Although the Spnr protein is expressed too late to be directly involved in the translational repression of Prm-1 specifically, we suggest that the Spnr protein may be involved in other aspects of spermatid RNA metabolism, such as RNA transport or translational activation.     

Testis fascin (FSCN3): a novel paralog of the actin-bundling protein fascin expressed specifically in the elongate spermatid head

During spermiogenesis, significant morphological changes occur as round spermatids are remodeled into the fusiform shape of mature spermatozoa. These changes are correlated with a reorganization of microfilaments and microtubules in the head and tail regions of elongating spermatids. There is also altered expression of specialized actin- and tubulin-associated proteins. We report the characterization of a novel, spermatid-specific murine paralog of the actin-bundling protein fascin (FSCN1); this paralog is designated testis fascin or FSCN3. Testis fascin is distantly related to fascins but retains its primary sequence organization. cDNA clones of mouse testis fascin predict a 498 amino acid protein of molecular mass 56 kD that shares 29% identity with mouse fascin. Mapping of murine and human FSCN3 genes shows localization to the 7q31.3 chromosome. Northern analysis indicates that FSCN3 expression is highly specific to testis and that in situ hybridization further restricts expression to elongating spermatids. Antibodies raised against recombinant FSCN3 protein identify a band at 56 kD in testis, epididymis, and epididymal spermatozoa, suggesting that testis fascin persists in mature spermatozoa. In accord with the in situ hybridization results, immunofluorescent microscopy localizes testis fascin protein to areas of the anterior spermatid head that match known distributions of F-actin in the dorsal and ventral subacrosomal spaces. It is possible that testis fascin may function in the terminal elongation of the spermatid head and in microfilament rearrangements that accompany fertilization.     

Identification and characterization of cDNAs encoding four novel proteins that interact with translin associated factor-X

Translin-associated factor X (TRAX) is the predominantly cytoplasmic binding partner of TB-RBP/translin in mouse testis. Four mouse testis cDNAs encoding specific TRAX-interacting proteins were isolated from a yeast two-hybrid library screen. One novel cDNA designated Tsnaxip1 (TRAX-interacting protein-1) encodes 709 amino acids. We isolated a cDNA encoding the 427 carboxy-terminal amino acids of MEA-2, a Golgi-associated, maleenhanced autoantigen; a cDNA encoding 429 amino acids with 73% homology to centrosomal Akap9; and a cDNA encoding 346 amino acids with 75% homology to SUN1, a predicted human protein that contains a SUN domain (which is present in some perinuclear proteins). Interactions were verified using in vitro synthesized fusion proteins. All four genes were expressed in the testis and enriched in germ cells. Confocal microscopy studies using green fluorescent protein fusion proteins determined that these TRAX-interacting proteins colocalize with TRAX. The data suggest that TRAX may have a function associated with perinuclear organelles during spermatogenesis.     

Development of the sperm head in the caddis fly Potamophylax rotundipennis (Insecta,Trichoptera)

The restructuring of the sperm head has been examined in a caddis fly, Potamophylax rotundipennis (Limnephilidae), using light and electron microscopy. The roughly spherical nuclei of young spermatids are transformed into needle-shaped elements in advanced spermatids. During this process, the nuclei transiently become sickle-shaped. Prominent structural changes occur within the nucleus during spermiogenesis. The chromatin of spherical and slightly elongated nuclei has an amorphous appearance, then coarse granules become apparent, chromatin threads are visible in fully elongated nuclei and finally lamellar elements appear. During the changes in chromatin texture, a dense layer, the chromatin rim, develops transiently. This feature of the chromatin surface is interpreted as the structural expression of exchanges between nucleus and cytoplasm. A microtubular manchette is formed at the cytoplasmic face of the nuclear envelope. Whereas the manchette covers the full perimeter of the nucleus in early stages of elongation, gaps in the palisade of microtubules appear before the nuclear diameter decreases and needle-shaped nuclei develop. It is possible that the intermittent deployment of manchette microtubules is involved in reducing the nuclear diameter towards the end of nuclear elongation. The delayed detachment of the chromatin from the posterior pole of the nucleus, observed at the onset of nuclear clongation, points to local modifications of the nuclear envelope responsible for the connection of the centriole adjunct and the flagellum with the posterior pole of the nucleus.     

Structural and biochemical features of fractionated spermatid manchettes and sperm axonemes of the azh/azh mutant mouse

The tubulin-containing axoneme and manchette develop consecutively during mammalian spermiogenesis. The nature of their molecular components and developmental sequence are not completely known. The azh/azh (for abnormal sperm headshape) mouse mutant is an ideal model for analyzing tubulin isotypes and microtubule-associated proteins of the manchette and axoneme in light of a potential role of the manchette in the shaping of the sperm head and formation of the tail. We have searched for possible differences in tubulin isotype variants in fractionated manchettes and axonemes of wildtype and azh/azh mutant mice using isotype-specific tubulin antibodies as immunoprobes. Manchettes from wild-type and azh/azh mutant mouse spermatids were fractionated from spermatogenic stage-specific seminiferous tubules and axonemes were isolated from epididymal sperm. We have found that: (1) Fractionated manchettes of azh/azh mutants are longer than in wild-type mice; (2) Manchette and sperm tail axonemes display a remarkable variety of posttranslationally modified tubulins (acetylated, glutamylated, tyrosinated, alpha-3/7 tubulins). Acetylated tubulin was more abundant in manchette than in axonemes; (3) An acidic 62 kDa protein was identified as the main component of the perinuclear ring of the manchette in wild-type and azh/azh mice; (4) Bending and looping of the mid piece of the tail of azh/azh sperm, accompanied by a dislocation of the connecting piece from head attachment sites, were visualized by phase-contrast, immunofluorescence and transmission electron microscopy in about 35% of spermatids/sperm; and (5) A lasso-like tail configuration was predominant in epididymal sperm of azh/azh mutants. We speculate that spermatid and sperm tail abnormalities in the azh/azh mutant could reflect structural and/or assembly deficiencies of peri-axonemal proteins responsible for maintaining a stiffened tail during spermiogenesis and sperm maturation.     

A single amino acid mutation in the mouse MEIG1 protein disrupts a cargo transport system necessary for sperm formation

Mammalian spermatogenesis is a highly coordinated process that requires cooperation between specific proteins to coordinate diverse biological functions. For example, mouse Parkin coregulated gene (PACRG) recruits meiosis-expressed gene 1 (MEIG1) to the manchette during normal spermiogenesis. Here we mutated Y68 of MEIG1 using the CRISPR/cas9 system and examined the biological and physiological consequences in mice. All homozygous mutant males examined were completely infertile, and sperm count was dramatically reduced. The few developed sperm were immotile and displayed multiple abnormalities. Histological staining showed impaired spermiogenesis in these mutant mice. Immunofluorescent staining further revealed that this mutant MEIG1 was still present in the cell body of spermatocytes, but also that more MEIG1 accumulated in the acrosome region of round spermatids. The mutant MEIG1 and a cargo protein of the MEIG1/PACRG complex, sperm-associated antigen 16L (SPAG16L), were no longer found to be present in the manchette; however, localization of the PACRG component was not changed in the mutants. These findings demonstrate that Y68 of MEIG1 is a key amino acid required for PACRG to recruit MEIG1 to the manchette to transport cargo proteins during sperm flagella formation. Given that MEIG1 and PACRG are conserved in humans, small molecules that block MEIG1/PACRG interaction are likely ideal targets for the development of male contraconception drugs.     

Transcriptional and translational control of the message for transition protein 1, a major chromosomal protein of mammalian spermatids

The spermatid transition proteins comprise a set of basic chromosomal proteins that appear during the period when spermatids are undergoing nuclear elongation and condensation, about midway between the end of meiosis and the release of spermatozoa from the seminiferous tubule. The transition proteins replace the histones but are themselves subsequently replaced by protamines, and they are not found in sperm nuclei. We have used a cDNA clone for the smallest transition protein (TP1, 54 amino acids) to show that its message first appears postmeiotically in late round spermatids. Thus production of TP1 is an example of haploid gene expression. The message remains translationally inactive for some 3-4 days before translation occurs in early elongating spermatids. While translationally repressed, TP1 message is nonpolysomal and has a discrete size of about 590 bases, including a 140 residue poly(A) tail. In contrast, polysome-associated message is of heterogeneous size due to variability of poly(A) lengths.     

A membrane protein,TMCO5A,has a close relationship with manchette microtubules in rat spermatids during spermiogenesis

We isolated the transmembrane and coiled‐coil domains 5A (Tmco5A) gene using polymerase chain reaction‐based subtraction technique and showed that Tmco5A was predominantly expressed in rat testes starting at 4 weeks of postnatal development. When expressed in COS7 cells, TMCO5A was found to be distributed in the endoplasmic reticulum‐nuclear membrane (ER‐NM) of cells as a membrane‐associated protein, while TMCO5AΔC lacking the transmembrane region (TM) mislocalized and diffused throughout the cytoplasm. The result suggested that TM is responsible for the retention of TMCO5A at the ER‐NM. Immunocytochemical and immunoblotting analyses indicated that TMCO5A was localized along the posterior part of the nuclei in both round and elongated rat spermatids but disappeared from epididymal spermatozoa. Double immunolabeling of isolated spermatids with the anti‐TMCO5A and the anti‐β tubulin antibodies showed that TMCO5A was always found to be closely associated with developing manchette microtubules but did not completely colocalize with them. On the other hand, we found that almost all TMCO5A colocalized with SUN4, a linker of nucleoskeleton and cytoskeleton complex protein present at the posterior part of spermatid nuclei. These data suggested that TMCO5A is located closer to the nuclei than the manchette microtubules. It is likely that TMCO5A, in association with manchette microtubules, is involved in the process of spermiogenesis.