Acetylation of rat testis histones H2B and TH2B

The in vivo acetylation of rat testis histones H3 and H4 has been demonstrated in previous studies. In this study, analysis of purified histone fractions revealed the in vivo acetylation of histone H2B, the testis histone variant designated TH2B, and two or more of the histone H2A variants. These findings are quite significant, because it is possible that all of the core histones are acetylated in elongating spermatids at the time of removal of the entire histone complement for replacement by basic spermatidal transition proteins (S.R. Grimes and N. Henderson, 1983, Arch. Biochem. Biophys. 221, 108-116).     

The role of histones in chromatin remodelling during mammalian spermiogenesis.

One of the most dramatic chromatin remodelling processes takes place during mammalian spermatogenesis. Indeed, during the postmeiotic maturation of male haploid germ cells, or spermiogenesis, histones are replaced by small basic proteins, which in mammals are transition proteins and protamines. However, nothing is known of the mechanisms controlling the process of histone replacement. Two hints from the literature could help to shed light on the underlying molecular events: one is the massive synthesis of histone variants, including testis-specific members, and the second is a stage specific post-translational modification of histones. A new testis-specific 'histone code' can therefore be generated combining both histone variants and histone post-translational modifications. This review will detail these two phenomena and discuss possible functional significance of the global chromatin alterations occurring prior to histone replacement during spermiogenesis.     

Changes in nuclear proteins of rat testis cells separated by velocity sedimentation.

The technique of velocity sedimentation at unit gravity has been used to separate rat testis cell suspensions into fractions enriched in particular cell types. Changes in the nuclear proteins from the various fractions have been characterized by polyacrylamide gel electrophoresis, and correlated with the changing morphology of the nucleus during spermatogenesis. The most striking alterations in both protein composition and nuclear morphology occur during spermatid maturation as both histone and non-histone proteins are replaced by highly basic, low molecular weight, spermatidal proteins. This replacement process is accompanied by a quantitative reduction in both histone and non-histone proteins. The synthesis of at least three basic proteins has been identified with late stage spermatids. One of these proteins is a highly basic sperm-specific protein containing high levels of cyst(e)ine and arginine. A second protein synthesized in late stage spermatids is lysine rich, while the third protein contains cyst(e)ine and co-migrates with histone F2a1 on acid-urea polyacrylamide gels. The changes in protein composition of rat testis nuclei after irradiation or hypophysectomy reflect the resulting changes in the cellular composition of the testis. After selective elimination of the germinal cells by irradiation, the electrophoretic pattern of acid-soluble proteins from the testis is very similar to that of somatic tissue. Thus, the cellular specificity of nuclear proteins demonstrated here using cell separation techniques is also apparent following treatments which selectively alter the cellular composition of the testis.     

Changes in the structural organization of chromatin during spermatogenesis in the rat

In this study, histone H4 was shown to be extensively hyperacetylated in mid-spermatids of the rat during the time period when the entire complement of histones is replaced by basic spermatidal transition proteins. The degree of hyperacetylation of histone H4 was minimal in pachytene spermatocytes. Therefore, the hyperacetylation appears to be directly involved in the histone replacement process late in spermatogenesis in mid-spermatids. In order to investigate further the possible effects of histone H4 hyperacetylation and the other dramatic changes in the nuclear proteins on the structure of chromatin in germinal cells, we examined the thermal denaturation profiles of chromatin from various purified germinal cell types. Our analyses revealed that chromatins from pachytene spermatocytes and early spermatids have similar thermal denaturation profiles, with their major thermal transitions slightly lower than those for rat liver. However, the major thermal transitions for chromatin from mid-spermatids are much lower than those from pachytene spermatocytes and early-spermatids. We propose that the greatly lowered thermal stability of mid-spermatid chromatin represents a dramatic relaxation or decondensation of the chromatin in this cell type in preparation for the replacement of histone by the basic spermatidal transition proteins and that the decondensation is due in large part to the extensive histones hyperacetylation which occurs in these cells.     

The sea urchin histone gene complement

The only eukaryotic mRNAs that are not polyadenylated are the replication-dependent histone mRNAs in metazoans. The sea urchin genome contains two sets of histone genes that encode non-polyadenylated mRNAs. One of these sets is a tandemly repeated gene cluster with a 5.6-kb repeat unit containing one copy of each of the five alpha-histone genes and is present as a single large cluster which spans over 1 Mb. There is a second set of genes, consisting of 39 genes, containing two histone H1 genes, 34 genes encoding core histone proteins (H2a, H2b, H3 and H4) and three genes expressed only in the testis. Unlike vertebrates where these genes are clustered, the sea urchin late histone genes, expressed in embryos, larvae and adults, are dispersed throughout the genome. There are also genes encoding polyadenylated histone mRNAs, which encode histone variants, including all variants found in other metazoans, as well as a unique set of five cleavage stage histone proteins expressed in oocytes. The cleavage stage histone H1 is the orthologue of an oocyte-specific histone H1 protein found in vertebrates.     

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.     

Transformation of sperm histone during formation and maturation of rat spermatozoa.

Changes of chromosomal basic proteins of rats have been followed during transformation of spermatids into spermatozoa in the testis and during maturation of spermatozoa in the epididymis. Rat testis chromatin has been fractionated on the basis of differing sensitivity to shearing, yielding a soluble fraction and a condensed fraction. The sperm histone is found in the condense fraction. Somatic-type histones are found in both fractions. The somatic-type histones in the condensed fraction contains much more lysine-rich histone I, than does the somatic-type histones in the soluble fraction. This may suggest that the lysine-rich histone I is the last histone to be displaced during the replacement of somatic-type histones by sperm histone. After extensive shearing followed by sucrose centrifugation, the condensed portion of testis chromatin can be further fractionated into two morphologically distinctive fractions. One is a heavy fraction possessing an elongated shape typical of the head of late spermatids. The other is a light fraction which is presumably derived from spermatids at earlier stages of chromatin condensation and which is seen as a beaded structure in the light microscope. Sperm histone of testis chromatin can be extractable completely by guanidinium chloride without a thiol, wheras 2-mercaptoethanol is required for extraction of sperm histone from caput and cauda epididymal spermatozoa. The light fraction of the condensed testis chromatin contains unmodified and monophospho-sperm histone. The sperm histones of the heavy fraction is mainly of monophospho and diphospho species, whereas unmodified and monophosphosperm histones are found in caput and cauda epididymal spermatozoa. Labeling of cysteine sulfhydryl groups of sperm histone releases by 2-mercaptoethanol treatment shows that essentially all of the cysteine residues of sperm histone in testis chromatin are present as sulfhydryl groups, while those of sperm histone isolated from mature (cauda epididymal) spermatozoa are present as disulfide forms and approximately 50% of the cysteine residues of sperm histone obtained from caput epididymal spermatozoa are in disulfide forms. These results suggest that phosphorylation of sperm histone is involved in the process of chromatin condensation during transformation of spermatozoa in the epididymis.     

H3.5 is a novel hominid-specific histone H3 variant that is specifically expressed in the seminiferous tubules of human testes

The incorporation of histone variants into chromatin plays an important role for the establishment of particular chromatin states. Six human histone H3 variants are known to date, not counting CenH3 variants: H3.1, H3.2, H3.3 and the testis-specific H3.1t as well as the recently described variants H3.X and H3.Y. We report the discovery of H3.5, a novel non-CenH3 histone H3 variant. H3.5 is encoded on human chromosome 12p11.21 and probably evolved in a common ancestor of all recent great apes (Hominidae) as a consequence of H3F3B gene duplication by retrotransposition. H3.5 mRNA is specifically expressed in seminiferous tubules of human testis. Interestingly, H3.5 has two exact copies of ARKST motifs adjacent to lysine-9 or lysine-27, and lysine-79 is replaced by asparagine. In the Hek293 cell line, ectopically expressed H3.5 is assembled into chromatin and targeted by PTM. H3.5 preferentially colocalizes with euchromatin, and it is associated with actively transcribed genes and can replace an essential function of RNAi-depleted H3.3 in cell growth.     

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.     

Anomalous nuclease digestion of Holothuria sperm chromatin containing histone H1 variants

We have investigated the micrococcal nuclease digestion of chromatin from the spermatozoa of the sea cucumber Holothuria tubulosa. This chromatin contains minor protein variants related to histone H1 with a high proportion of basic amino acids. One of these variants, protein phi 0, represents about 4% of the total histones. It is 78 amino acids long and its amino acid composition and sequence are related to the very basic C-terminal region of histone H1. The presence of these proteins induces an unusual digestion pattern. Oligonucleosomal particles which are soluble at 150 mM NaCl are depleted of protein phi 0 and they are also defective in histone H1. A low percentage of the insoluble material can be solubilized at lower NaCl concentrations (50 mM). These oligonucleosomal particles show a very peculiar protein content, since at early digestion times, they contain histone H1 and protein phi 0 exclusively. We conclude that these particles arise from a cooperative displacement of core histones by protein phi 0 and histone H1. These results show that minor changes in histone H1 complement can result in the formation of artifactual particles upon microccocal nuclease digestion. These observations may be of interest in other systems which contain H1 variants.     

Diisopropylfluorophosphate-interacting proteinases of nuclei of rat testis cells

Nuclei and chromatin of seminiferous epithelial cells of rat testis contain acid-extractable and non-extractable proteins which interact readily with [³H]DFP (diisopropylfluorophosphate). Proteinase activity is closely associated with these DFP-interacting proteins, and the proteinase activities are inhibited by DFP and PMSF. DFP-interacting proteins of testis chromatin increase greatly in amount at 26–32 days after birth when spermatids are appearing in increasing numbers. In nuclei separated by zonal centrifugation on sucrose gradients, the DFP-labeled proteins are highest in activity in the elongated spermatids at the stage in spermiogenesis at which histones are being replaced by testis-specific proteins and protamines. Electrophoresis in SDS-polyacrylamide gels reveals the presence of three species of DFP-interacting proteins in nuclei of seminiferous epithelial cells of the testis. The chromatin of epididymal spermatozoa of the rat contains three or four species of DFP-interacting proteins by SDS-polyacrylamide electrophoresis and some of these labeled proteins co-migrate with two of the three basic proteins which are observed during electrophoresis on polyacrylamide gels in Triton-urea.     

Basic nuclear proteins in testicular cells and ejaculated spermatozoa in man

Human testis was shown to contain a specific histone, TH2B, having the same electrophoretic mobility as rat TH2B. Testicular and ejaculated human sperm still possessed histones at 50% and 15% of the total basic nuclear proteins, respectively. Comparison of the electrophoretic patterns of histones from human testis, testicular sperm and ejaculated sperm implied that the histones may be removed in the order H2A and H1 before H3, H4 and H2B before TH2B. TH2B which is the major histone fraction in ejaculated sperm has no longer a strong affinity to DNA. TH2B in sperm nuclei could be separated from other basic nuclear proteins by Bio-Gel P-10 column chromatography and its amino acid composition is similar to that of rat TH2B, although no cysteine residue was found.     

Chromatin condensation during spermiogenesis in the golden hamster (Mesocricetus aureus): a flow cytometric study

DNA-staining of hamster testis cell suspensions followed by flow cytometry demonstrated appearance of the first haploid cells at 23 days post partum (dpp) and of condensed chromatin (in elongated spermatids and spermatozoa) at 33-34 dpp. Mature spermatozoa were first observed in the caput epididymis at 36-37 dpp, thus completing the first spermatogenic wave. Testicular cell suspensions from animals from 23 to 38 dpp were stained with acridine orange, and flow cytometer gating was adjusted to include only the haploid cells. Acridine orange intercalated into double-stranded DNA to produce green fluorescence. The decrease in green fluorescence intensity from 23 until 37 dpp was caused by changes in the binding of DNA to basic proteins in such a fashion as to impede the access of the dye to the DNA double helix. When the green fluorescence values (of the most advanced spermatids) were plotted against the age of the hamsters (in dpp) or the corresponding steps of spermiogenesis, the decrease in fluorescence could be seen to occur in three phases. The inflection point between the first and second phases was observed at about spermiogenesis step 7, consistent with the hypothesis that this represents removal of histone from the chromatin. The second phase presumably represents the period in which transition proteins are bound to the DNA. At approximately steps 15 or 16 a further inflection point was seen where protamines replaced the transition proteins. The red fluorescence produced when acridine orange bound to RNA in spermatids, increased early in spermiogenesis and decreased dramatically at 34 dpp, consistent with the fact that elongating spermatids discard the bulk of their cytoplasm during the maturation process.     

Changes in the histone H2A variant H2A.Z and polyubiquitinated histone species in developing trout testis

The trout histone H2A variant H2A.Z has been identified by its electrophoretic mobility on two-dimensional polyacrylamide gels and its N-terminal amino acid sequence. Similar to bovine H2A.Z and chicken H2A.F (also called H2A.Z and M1), the trout H2A.Z had a two-residue extension when aligned with trout H2A and a 67% sequence homology with the N-terminal portion of trout H2A. The first 29 amino acids of trout H2A.Z were identical with those of chicken H2A.F and differed from those of bovine H2A.Z at only one position. Thus, the N-terminal part of histone H2A.Z appears to be highly conserved. The levels of histone H2A.Z and ubiquitinated species of the histones H2A, H2A.Z, and H2B, which were detected with an anti-ubiquitin antibody, were studied at various stages of trout testis development. At the final stages of spermatogenesis in trout, histones are replaced by protamines. Ubiquitinated and diubiquitinated histone H2A remained at similar levels in early and late stage testis nucleohistone. In the late stage testis chromatin (nucleohistone), ubiquitinated histone H2A.Z was not detected, the level of ubiquitinated histone H2B was reduced, and the amount of diubiquitinated histone H2B increased. There was also a marked reduction in the level of histone H2A.Z. This observation suggests nucleosomes with this histone variant were selectively disassembled during the transition from nucleohistone to nucleoprotamine, indicating that protamine deposition is not a random process in rainbow trout.     

Metabolic behaviors of the core histones in proliferating Friend cells

This study examines the turnover of the core histones in proliferating Friend cells. It was calculated that these proteins turn over with half-lives of 21.6 days for H2A, 13.8 days for H2B, 43.3 days for H3, and 138.6 days for H4. The significant differences in the half-lives of the four core histones indicate that the protein moiety of the nucleosome is not replaced as one entire unit but as a "mosaic" in which each component follows its own rate of replacement. In some experiments the turnover rates of the variants of H2A, H2B, and H3 were compared. The results did not indicate any differences among these histone variants, suggesting that they are not excluded from the mechanisms controlling histone turnover. Metabolic heterogeneity was discovered, however, when the turnover rates of the acetylated and nonacetylated molecules of histone H4 were followed: it appeared that the acetylated molecules are replaced 2.5 times faster. The comparison of the rate of replacement of the histones in proliferating and differentiated cells from one site and their level of acetylation from another suggests that this postsynthetic modification might be involved in the control of histone metabolism. Such a conclusion is supported also by a number of model experiments.