Condensation of DNA by spermatid basic nuclear proteins

Two transition proteins, TP1 and TP2, participate in the repackaging of the spermatid genome early in mammalian spermiogenesis, coincident with the first detectable changes in chromatin condensation. Using an optical trap and a two-channel flow cell to move single DNA molecules into buffer containing protein, we have measured the rates of DNA condensation and decondensation induced by the binding of Syrian hamster transition proteins TP1 and TP2 and protamines P1 and P2. The results show that both transition proteins condense free DNA, with rates similar to those of protamine 1 and 2. DNA molecules condensed with TP1 were significantly less stable than DNA condensed by protamine or by TP2. Experiments conducted with a peptide corresponding to the C-terminal 25 residues of TP2 showed that this domain is responsible for condensing DNA. Experiments conducted with two fragments of TP1 containing arginine and lysine residues demonstrated that DNA binding by TP1 must involve more than these basic sequences. Zinc facilitated the condensation of DNA by P2 but not by TP2. The dissociation rates of TP2 and P2 from DNA were not affected by the addition of zinc.     

Roles of transition nuclear proteins in spermiogenesis

The transition nuclear proteins (TPs) constitute 90% of the chromatin basic proteins during the steps of spermiogenesis between histone removal and the deposition of the protamines. We first summarize the properties of the two major transition nuclear proteins, TP1 and TP2, and present concepts, based on their time of appearance in vivo and in vitro properties, regarding their roles. Distinct roles for the two TPs in histone displacement, sperm nuclear shaping, chromatin condensation, and maintenance of DNA integrity have been proposed. More definitive information on their roles in spermiogenesis has recently been obtained using mice with null mutations in the Tnp1 or Tnp2 genes for TP1 and TP2, respectively. In these mice, histone displacement and sperm nuclear shaping appear to progress quite normally. Spermatid nuclear condensation occurs, albeit in an abnormal fashion, and the mature sperm of the Tnp -null mutants are not as condensed as wild-type sperm. There is also evidence that sperm from these mutant mice contain an elevated level of DNA strand breaks. The mutant sperm showed several unexpected phenotypes, including a high incidence of configurational defects, such as heads bent back on midpieces, midpieces in hairpin configurations, coils, and clumps, other midpiece defects, reduced levels of proteolytic processing of protamine 2 during maturation, and reduced motility. The two TPs appear partly to compensate for each other as both Tnp1 - and Tnp2 -null mice were able to produce offspring, and appear to have largely overlapping functions as the two mutants had similar phenotypes.     

Localization and quantitative expression of mRNAs encoding the testis-specific histone TH2B,the phosphoprotein p19, the transition proteins 1 and 2 during pubertal development and throughout the spermatogenic cycle of the rat

Expression of the testis-specific histone TH2B, the phosphoprotein p19, and the transition proteins TP1 and TP2, was localized in the rat testis and quantified, using in situ hybridization of their mRNAs with radiolabeled probes and image analysis. In a first study, expression was assessed during testicular development between day 2 and day 65 postpartum. TH2B mRNAs appeared first in preleptotene spermatocytes (PL) on day 12 and in pachytene spermatocytes (PS) on day 18; p19 mRNAs were present in PS from day 18 onward, and TP1 and TP2 mRNAs were detected in round spermatids (RS) from day 32 onward. In the second trial, the expression of these four genes was studied throughout the cycle of spermatogenic epithelium in mature animals. TH2B mRNAs were localized in B spermatogonia at stage V, and in PL at stages VII and VIII but no longer in leptotene and zygotene spermatocytes. Thereafter, TH2B mRNAs were observed in PS from stages III–IV to XIII. The steady-state mRNA level per cell was high in PS with a maximum at stages IX–X. p19 mRNAs were present in PS from stages III–IV onward and in RS up to stages 1–2 of spermiogenesis. The maximum mRNA level per cell was observed in PS between stages VII and XIII. The presence of TP1 mRNAs was restricted to spermatids from steps 6 to 15–16 of spermiogenesis while TP2 mRNAs were detected in spermatids only between step 7 and step 13. The highest steady-state amounts of mRNAs were observed between step 7 and step 14 for TP1 and between step 10 and step 12 for TP2. Mol. Reprod. Dev. 51:22–35, 1998. © 1998 Wiley-Liss, Inc.     

Changes in distribution of basic nuclear proteins and chromatin organization during spermiogenesis in the greater bandicoot rat, <Emphasis Type="Italic">Bandicota indica</Emphasis>

Male germ cells of the greater bandicoot rat, Bandicota indica, have recently been categorized into 12 spermiogenic steps based upon the morphological appearance of the acrosome and nucleus and the cell shape. In the present study, we have found that, in the Golgi and cap phases, round spermatid nuclei contain 10-nm to 30-nm chromatin fibers, and that the acrosomal granule forms a huge cap over the anterior pole of nucleus. In the acrosomal phase, many chromatin fibers are approximately 50 nm thick; these then thickened to 70-nm fibers and eventually became 90-nm chromatin cords that are tightly packed together into highly condensed chromatin, except where nuclear vacuoles occur. Immunocytochemistry and immunogold localization with anti-histones, anti-transition protein2, and anti-protamine antibodies suggest that histones remain throughout spermiogenesis, that transition proteins are present from step 7 spermatids and remain until the end of spermiogenesis, and that protamines appear at step 8. Spermatozoa from the cauda epididymidis have been analyzed by acid urea Triton X-100 polyacrylamide gel electrophoresis for basic nuclear proteins. The histones, H2A, H3, H2B, and H4, transitional protein2, and protamine are all present in sperm extracts. These findings suggest that, in these sperm of unusual morphology, both transition proteins and some histones are retained, a finding possibly related to the unusual nuclear form of sperm in this species.     

Stimulation of DNA repair by the spermatidal TP1 protein

The chromatin remodeling process that takes place during spermiogenesis in mammals is characterized by a transient increase in DNA single-strand breaks (SSB). The mammalian transition proteins (TPs) are expressed at a high level at mid-spermiogenesis steps coincident with chromatin remodeling and could be involved in the repair of these lesions since SSB are no longer detected in terminally differentiated spermatids. We report that TP1 can stimulate the repair of SSB in vitro and demonstrate that in vivo repair of UV-induced DNA lesions is enhanced in mammalian cells stably expressing TP1. These results suggest that, aside from its role in DNA compaction, this major transition protein may contribute to the yet unidentified enzymatic activity responsible for the repair of SSB at mid-spermiogenesis steps. These results also suggest that the TP1 proteins have the potential to participate in the repair process following genotoxic insults and therefore may play an active role in the maintenance of the integrity of the male haploid genome during spermiogenesis.     

Spatiotemporal Organization of AT- and GC-rich DNA and Their Association With Transition Proteins TP1 and TP2 in Rat Condensing Spermatids

Transition protein 1 (TP1) and TP2 replace histones during midspermiogenesis (stages 12–15) and are finally replaced by protamines. TPs play a predominant role in DNA condensation and chromatin remodeling during mammalian spermiogenesis. TP2 is a zinc metalloprotein with two novel zinc finger modules that condenses DNA in vitro in a GC-preference manner. TP2 also localizes to the nucleolus in transfected HeLa and Cos-7 cells, suggesting a GC-rich preference, even in vivo. We have now studied the localization pattern of TP2 in the rat spermatid nucleus. Colocalization studies using GC-selective DNA-binding dyes chromomycin A3 and 7-amino actinomycin D and an AT-selective dye, 4′,6-diamidino-2-phenylindole, indicate that TP2 is preferentially localized to GC-rich sequences. Interestingly, as spermatids mature, TP2 and GC-rich DNA moves toward the nuclear periphery, and in the late stages of spermatid maturation, TP2 is predominantly localized at the nuclear periphery. Another interesting observation is the mutually exclusive localization of GC- and AT-rich DNA in the elongating and elongated spermatids. A combined immunofluorescence experiment with anti-TP2 and anti-TP1 antibodies revealed several foci of overlapping localization, indicating that TP1 and TP2 may have concerted functional roles during chromatin remodeling in mammalian spermiogenesis. (J Histochem Cytochem 57:951–962, 2009)     

Transition nuclear proteins during spermiogenesis: unrepaired DNA breaks not allowed

The completion of spermiogenesis requires condensation of the haploid spermatid genome. This task is accomplished in a gradual and relentless manner by first erasing the nucleosomal organization of chromatin while the DNA is protected by transient nuclear proteins TP1 and TP2. Then, the more permanent protamines come into play to stabilize the spermatid genome until fertilization occurs. Mice lacking TPI manage to produce relatively structurally normal sperm, although fertility is reduced and chromatin condensation is abnormal despite the compensatory expression of TP2. TP1 and TP2 appear to have the house-keeping function of reestablishing continuity when chromatin breaks take place during the remodeling process. DNA single-strand breaks are frequently observed when spermiogenesis is half completed. There is a temporal relationship between TP1 and DNA breaks: TP1 nuclear levels increase and the frequency of DNA breaks become less prominent as spermiogenesis is reaching completion. TP1 seems to hold the broken ends together until an as-yet-unidentified ligase bridges the gap.     

A cytochemical study of the transcriptional and translational regulation of nuclear transition protein 1 (TP1), a major chromosomal protein of mammalian spermatids

Immunocytochemical localization and in situ hybridization techniques were used to investigate the presence of spermatid nuclear transition protein 1 (TP1) and its mRNA during the various stages of spermatogenesis in the rat. A specific antiserum to TP1 was raised in a rabbit and used to show that TP1 is immunologically crossreactive among many mammals including humans. During spermatogenesis the protein appears in spermatids as they progress from step 12 to step 13, a period in which nuclear condensation is underway. The protein is lost during step 15. An asymmetric RNA probe generated from a TP1 cDNA clone identified TP1 mRNA in late round spermatids beginning in step 7. The message could no longer be detected in spermatids of step 15 or beyond. Thus, TP1 mRNA first appears well after meiosis in haploid cells but is not translated effectively for the several days required for these cells to progress to the stage of chromatin condensation. Message and then protein disappear as the spermatids enter step 15. In agreement with a companion biochemical study (Heidaran, M.A., and W.S. Kistler. J. Biol. Chem. 1987. 262:13309-13315), these results establish that translational control is involved in synthesis of this major spermatid nuclear protein. In addition, they suggest that TP1 plays a role in the completion but not the initiation of chromatin condensation in elongated spermatids.     

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.     

Persistence of protamine precursors in mature sperm nuclei of the mouse

During mouse spermiogenesis, two protamines, mP1 and mP2, are synthesized in replacement of histones. One of them (protamine mP2, 63 residues) appears at first in elongating spermatid nuclei as a pro-protamine of 106 residues (pmP2) with an amino-terminal extension that is progressively excised. The two protamines were previously described as the only proteins associated with DNA in sperm chromatin. This paper shows that the nuclear proteins of mouse spermatozoa are indeed heterogeneous: at least six minor polypeptides in addition to protamines can be identified. The primary structure of four of them has been established. They are intermediate in the maturation of the precursor of protamine mP2 and correspond to polypeptides pmP2/11, pmP2/16, pmP2/20, and pmP2/32, characterized previously in mouse testis. Therefore, these intermediates of proteolysis generated from pmP2 inside spermatid nuclei persist in mature sperm, whereas the largest precursors, pmP2 and pmP2/5, disappear. These findings clearly indicate that limited proteolysis events still occur outside of the testis. © 1995 Wiley-Liss, Inc.     

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.     

Poly(ADP-ribosyl)ation during chromatin remodeling steps in rat spermiogenesis

In spermiogenesis, spermatid differentiation is marked by dramatic changes in chromatin density and composition. The extreme condensation of the spermatid nucleus is characterized by an exchange of histones to transition proteins and then to protamines as the major nuclear proteins. Alterations in DNA topology that occur in this process have been shown to require the controlled formation of DNA strand breaks. Poly(ADP-ribosyl)ation is a posttranslational modification of proteins mediated by a family of poly(ADP-ribose) polymerase (PARP) proteins, and two family members, PARP-1 and PARP-2, are activated by DNA strand breaks that are directly detected by the DNA-binding domains of these enzymes. Here, we show for the first time that poly(ADP-ribose) formation, mediated by poly(ADP-ribose) polymerases (PARP-1 and presumably PARP-2), occurs in spermatids of steps 11–14, steps that immediately precede the most pronounced phase of chromatin condensation in spermiogenesis. High levels of ADP-ribose polymer were observed in spermatid steps 12–13 in which the highest rates of chromatin nucleoprotein exchanges take place. We also detected -H2AX, indicating the presence of DNA double-strand breaks during the same steps. Thus, we hypothesize that transient ADP-ribose polymer formation may facilitate DNA strand break management during the chromatin remodeling steps of sperm cell maturation.M.L. Meyer-Ficca and H. Scherthan contributed equally to this work     

Abnormalities and reduced reproductive potential of sperm from Tnp1- and Tnp2-null double mutant mice

Previous studies have demonstrated the importance of transition nuclear proteins, TP1 and TP2, in spermatogenesis and male fertility. However, importance of the overall level of transition proteins and their level of redundancy in the production of normal sperm is not clear. Epididymal sperm from the nine possible Tnp1 and Tnp2 null genotypes demonstrated a general decrease in normal morphology, motility, chromatin condensation, and degree of protamine 2 processing with decreasing levels of transition proteins in mutant sperm. Nuclei of some mutant epididymal sperm stained poorly with hematoxylin and DNA fluorochromes, suggesting that the DNA of these sperm underwent degradation during epididymal transport. When epididymal sperm were injected directly into oocytes, fertilization and embryonic development were reduced only in the two most severely affected genotypes. These phenotypes indicated some functional redundancy of transition proteins; however, redundancy of transition protein function was not complete, as, for example, sperm from double heterozygous males had fewer abnormalities than sperm from males homozygous for a single Tnp null mutation. Our study suggests that each TP fulfills some unique function during spermiogenesis even though sperm phenotypes strongly indicate defects are largely attributable to an overall gene dosage effect. Similarities between sperm defects found in Tnp mutants and infertile patients make the Tnp mutants a valuable tool with which to study outcomes following fertilization using sperm with compromised DNA integrity.     

Temporal association of protamine 1 with the inner nuclear membrane protein lamin B receptor during spermiogenesis

During mammalian spermiogenesis, histones are replaced by transition proteins, which are in turn replaced by protamines P1 and P2. P1 protamine contains a short arginine/serine-rich (RS) domain that is highly phosphorylated before being deposited into sperm chromatin and almost completely dephosphorylated during sperm maturation. We now demonstrate that, in elongating spermatids, this phosphorylation is required for the temporal association of P1 protamine with lamin B receptor (LBR), an inner nuclear membrane protein that also possesses a stretch of RS dipeptides at its nucleoplasmic NH(2)-terminal domain. Previous studies have shown that the cellular protein p32 also binds tightly to the unmodified RS domain of LBR. Extending those findings, we now present evidence that p32 prevents phosphorylation of LBR and furthermore that dissociation of this protein precedes P1 protamine association. Our data suggest that docking of protamine 1 to the nuclear envelope is an important intermediate step in spermiogenesis and reveal a novel role for SR protein kinases and p32.     

Purification and characterization of the rat spermatid basic nuclear protein TP4.

Following elongation of spermatids in mammals, the histones are replaced by a set of basic nuclear transition proteins; in the rat there are four, named TP1-TP4. Of these, TP1 and TP2 are well characterized. Here we report the purification to homogeneity of TP4 from rat spermatids. It is a low molecular mass (about 13-20 kDa) basic protein with arginine and lysine constituting 24 mol % and histidine 2.2 mol %. Its 25 N-terminal amino acids were sequenced, and no sequence homologies with any known protein were found. Polyclonal antibodies raised against it in rabbit did not cross-react with other transition proteins, protamines, or histones. The presence of TP4 during sperm development was monitored by cell separation studies. No TP4 was detected in round spermatids, and along with TP1 and TP2, it is present in step 13-15 spermatids and its amount decreased in steps 16-19. Trace amounts of TP4 were also detected in epididymal sperm. A possible role for TP4 in spermatid and sperm chromatin structure is discussed.     

Stage-specific expression of rat transition protein 2 mRNA and possible localization to the chromatoid body of step 7 spermatids by in situ hybridization using a nonradioactive riboprobe.

The present study has used methoxyacetic acid (MAA)-induced depletion of specific germ cell types in the rat and in situ hybridization with nonradioactive riboprobes to determine the stages of the spermatogenic cycle at which there is expression of the mRNA for the basic chromosomal protein transition protein 2 (TP2). On Northern blots, an abundant mRNA was detectable in samples from control adult rats, but the amount of message was markedly reduced when RNA was extracted from the testes of rats treated 14 and 21 days previously with methoxyacetic acid. These testes were depleted specifically of step 7-12 spermatids, suggesting that these cells contain TP2 mRNA. When tissue sections were subjected to in situ hybridization, the TP2 mRNA was localized at the cellular and subcellular levels. Messenger RNA for TP2 was first detectable in spermatids at step 7. In these spermatids, at high magnification, in addition to some positive reaction in the cytoplasm, intense staining was located to a perinuclear structure consistent with localization of mRNA within the chromatoid body. The amount of TP2 mRNA in the cytoplasm increased as remodelling of the early spermatid nucleus progressed and was highest in step 10 and 11 spermatids at stages X and XI. Thereafter, the mRNA decreased until it was undetectable in step 14 spermatids at stage XIV. The localization of TP2 mRNA to the chromatoid body of step 7 spermatids would be consistent with this organelle being a storage site for long-lived mRNAs utilized later in spermiogenesis.     

DNA packaging in mouse spermatids : Synthesis of protamine variants and four transition proteins

A comparison of the protein compositions of mouse late-step spermatids and cauda epididymal sperm has revealed that the relative distribution of the two amino acid sequence variants of mouse protamine differ markedly in spermatids and sperm. Sonication-resistant spermatids contain the two variants in a ratio of 1:1, while the ratio of these two proteins in cauda epididymal sperm is approx. 2:1. Labeling studies in vivo have shown that this difference is due, in part, to an asynchrony in the time of synthesis of the two protamine variants. Both proteins are synthesized in late-step spermatids, but synthesis of the tyrosine variant in sperm chromatin begins approximately one day before synthesis of the more predominant histidine variant. Analyses of the time of synthesis of protamine and the four transition proteins in late-step spermatids allowed us to estimate the spermatid stage in which these proteins are deposited on DNA and relate these events to the onset of sonication resistance in maturing spermatids. These results indicate that: (1) synthesis and deposition of protamine begins coincident with the onset of sonication resistance in early step 12 spermatids; (2) protamine deposition is complete by mid-step 15; and (3) synthesis of the transition proteins occurs coincident with protamine synthesis.