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.     

Nuclear transition protein 2 (TP2) of mammalian spermatids has a very basic carboxyl terminal domain

Nuclear transition protein 2 (TP2) along with TP1 are major basic chromosomal proteins of rat spermatids during the period of transition from histone-associated to protamine-associated DNA. TP2 isolated by reversed phase high pressure liquid chromatography was cleaved with S. aureus V8 protease to yield two fragments. The complete amino acid sequence of the 27 residue peptide assigned to the carboxyl terminus was established. It contains most of the basic residues of the protein and is likely to be a major site of DNA binding. Thus, TP2 is differentiated from core histones in having its basic domain at the carboxyl rather than amino terminal end.     

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.     

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.     

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.     

Role of follitropin receptor signaling in nuclear protein transitions and chromatin condensation during spermatogenesis

Follitropin receptor (FSHR) in testicular Sertoli cells mediates signaling by pituitary follitropin (FSH) promoting intercellular communication with germ cells for normal spermatogenesis. Using receptor knockout mice we examined changes in sperm nucleoproteins and chromatin architecture. The expressions of transition proteins 1/2 (TP1/2) and protamine-2 (PRM-2) were greatly diminished at 21 days, but returned to normal at 35 days and 3 months after birth. However, protein components in chromatin were quite different. Western blots detected a reduction in PRM1/2 and prolonged retention of mono-ubiquitinated histone 2A (uH2A) in the epididymal sperm from adult mutants. Two forms of mono- and poly-uH2A were present in sonication-resistant testicular spermatids in normal mice, whereas only an elevated mono-uH2A was detectable in mutants. Decrease in PRM1/2 and retention of mono-uH2A was coincident with reduction in TP1/2 in premature spermatids. Thus lack of FSHR signaling impairs expression of TP1/2 and PRM-2 at an early stage of post-natal development causing delayed spermatogenesis. In the adult, absence of FSHR signaling prolongs retention of mono-uH2A, leading to impair transition of basic nucleoproteins and chromatin remodeling during mouse spermatogenesis.     

Involvement of protein kinase A in the phosphorylation of spermatidal protein TP2 and its effect on DNA condensation.

Rat spermatidal protein TP2 is rich in serine residues and has several potential sites for phosphorylation by different protein kinases. Recombinant TP2 is phosphorylated upon incubation in vitro with salt extract of testicular sonication resistant nuclei (SRN) (representing elongating and elongated spermatids). The major phosphorylation sites were localized to the C-terminal, V8 protease-derived, fragment (residues 87-114). Phosphorylation experiments with the wild type and different site-specific mutants of TP2 revealed that serine 109 and threonine 101 are the phosphorylation sites. Phosphorylation of the C-terminal fragment of TP2 was also demonstrated in vivo. Phosphorylation was not stimulated by either protein kinase C activators or cGMP but was inhibited by protein kinase A inhibitor (PKI) peptide, showing the involvement of protein kinase A in the phosphorylation of TP2. Phosphorylation of TP2 greatly reduced its DNA condensation property. TP2 when complexed with DNA was not a good substrate for phosphorylation by PKA. Dephosphorylation of the DNA-TP2 complex by calf intestinal alkaline phosphatase restored the DNA condensation property to a level equivalent to that observed with TP2. The physiological significance of the phosphorylation-dephosphorylation cycle is discussed with reference to the two-domain model of TP2.     

Nucleotide sequences and expression of cDNA clones for boar and bull transition protein 1 and its evolutionary conservation in mammals

During spermatogenesis, the nucleoproteins undergo several dramatic changes as the germinal cells differentiate to produce the mature sperm. With nuclear elongation and condensation, the histones are replaced by basic spermatidal transition proteins, which are themselves subsequently replaced by protamines. We have isolated cDNA clones for one of the transition proteins, namely for TP1, of bull and boar. It turned out that TP1 is a small, but very basic protein with 54 amino acids (21% arginine, 19% lysine) and is highly conserved during mammalian evolution at the nucleotide as well as at the amino-acid level. Gene expression is restricted to the mammalian testis, and the message first appears in round spermatids. Thus production of TP1 is an example of haploid gene expression in mammals. The size of the mRNA for TP1 was found to be identical in 11 different mammalian species at around 600 bp. Hybridization experiments were done with cDNAs from boar and bull, respectively. The positive results in all mammalian species give further evidence for the conservation of the TP1 gene during mammalian evolution and its functional importance in spermatid differentiation.     

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)     

Mouse transition protein 1 is translationally regulated during the postmeiotic stages of spermatogenesis

Transition protein 1 (TP1) is a small basic nuclear protein that functions in chromatin condensation during spermatogenesis in mammals. Here, recently identified cDNA clones encoding mouse transition protein 1(mTP1) were used to characterize the expression of the mTP1 mRNA during spermatogenesis. Southern blot analysis demonstrates that there is a single copy of the gene for transition protein 1 in the mouse genome. Northern blot analysis demonstrates that mTP1 mRNA is a polyadenylated mRNA approximately 600 bases long, which is first detected at the round spermatid stage of spermatogenesis. mTP1 mRNA is not detectable in poly(A)+ RNAs isolated from mouse brain, kidney, liver, or thigh muscle. mTP1 mRNA is translationally regulated in that it is first detected in round spermatids, but no protein product is detectable until approximately 3 days later in elongating spermatids. In total cellular RNA isolated from stages in which mTP1 is synthesized, the mTP1 mRNA is present as a heterogeneous class of mRNAs that vary in size from about 480 to 600 bases. The shortened, heterogeneous mTP1 mRNAs are found in the polysome region of sucrose gradients, while the longer, more homogeneous mTP1 mRNAs are present in the postmonosomal fractions.     

Partial characterization of ram spermatidal basic nuclear proteins

Several techniques were used to demonstrate that eight spermatidal proteins are present in the nucleus of ram non-round spermatids. Excepting one, they all contain cysteine and are partially intermolecularly cross-linked in the chromatin of non-round spermatids. Ion-exchange chromatography on carboxymethylcellulose shows that most of them have over-all basic charges similar to those of histones. The molecular weights determined by gel filtration in 6M guanidine hydrochloride, range between that of the smallest histone and that of the basic nuclear sperm protein.     

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.     

Isolation of a cDNA clone for transition protein 1 (TP1), a major chromosomal protein of mammalian spermatids

We have isolated a cDNA clone for rat transition protein 1 (TP1), a major chromosomal protein of mammalian spermatids. The clone was identified initially by hybrid selection of TP1 mRNA. The sequence of the 251-nucleotide cDNA includes the entire coding region for the protein, thereby confirming the identity of the clone as well as predicting two changes in the published amino acid sequence.     

Acetylation of histones during spermatogenesis in the rat

Acetate was actively incorporated into rat testis histones when testis cells were prepared by the trypsinization technique in the presence of [³H]acetate. The acetylation was enhanced by 10 mm sodium butyrate. Although histones H3 and H4 were the only histones which incorporated high levels of acetate, the testis-specific histones TH2B and TH3 also appeared to incorporate acetate. This was shown by electrophoresis of the histones on polyacrylamide gels containing Triton X-100. Results, obtained from analysis of histones by two-dimensional gel electrophoresis, confirmed a recent report (P. K. Trostle-Weige, M. L. Meistrich, W. A. Brock, K. Nishioka, and J. W. Bremer, (1982) J. Biol. Chem.257, 5560–5567) that TH2A was a testis-specific histone. The results also confirmed the H2A nature of a testis-enriched histone band, previously designated X2. When histones from populations of cells enriched in specific testis cell types, representing various stages of spermatogenesis, were examined, the patterns of acetylation varied dramatically. Very high levels of acetate were incorporated into multiacetylated species of histone H4 from a population of cells enriched in transition stage spermatids (steps 9–12) compared to the levels of acetate incorporated into H4 from round spermatids (steps 1–8) and earlier stages of spermatogenesis, where acetate was incorporated primarily into the monoacetylated species of H4. Thus, a striking correlation exists between the time of hyperacetylation of histone H4 and the time of removal of histones for their replacement by the basic spermatidal transition proteins designated TP, TP2, and TP4. Hyperacetylation of histone H4 may facilitate the removal of the entire histone complement during the protein transition. In any case, it must be an obligatory step in the dramatic process.