CYTOCHEMICAL AND BIOCHEMICAL DETERMINATIONS OF CHANGES IN NUCLEAR HISTONE CONTENT DURING DIFFERENTIATION OF BARLEY ROOT CELLS

Changes in nuclear histone content in barley root cells have been studied by cytochemical methods for identification of histone subtypes and by conjunction with standard biochemical extraction procedure for various histone fractions and alkaline fast green stainability. The results obtained by the cytochemical methods indicate that the nuclear histones in cell nuclei found in their terminal stages of cellular differentiation or elongation contain histones rich in arginine, whereas the nuclei in meristematic cells contain histones rich in lysine. Cytochemicaly intermediate or transitional types of nuclear histones have been observed in cell nuclei which are undergoing differentiation or elongation and in chromosomes of mitotic nuclei. Information obtained from the conjunction of methods of biochemical extraction procedures for various histone fractions and alkaline fast green stainability indicate that the nuclei in well-differentiated cells contain predominantly histones rich in arginine (f3), whereas the nuclei of meristematic cells contain both very lysine-rich histones (f1) and slightly lysine-rich histones (f2). These results suggest the replacement of lysine-rich histones in the nuclei of meristematic cells by arginine-rich histones during cellular differentiation.     

ANTIGEN-INDUCED CHANGES IN LYMPHOID CELL HISTONES : I. Thymus

An acute effect of antigens on the nuclear histones of mouse thymocytes was investigated by means of cytophotometric measurements of thymocytes stained with ammoniacal-silver (A-S) and with fast green (FG). In addition, the DNA content was measured in terms of Feulgen staining. In terms of such staining it appeared that nuclei of control thymocytes contain a greater amount of nuclear histones and a higher histone/DNA ratio than do renal cell nuclei from the same animal. Within 1 hour after the injection of antigen the thymocyte nuclei appear to lose approximately 32 per cent and 20 per cent, respectively, of A-S and FG stainable nuclear proteins, while the Feulgen staining remains unchanged. Since the renal cell nuclei show no antigen-induced change in histone staining, the histone staining and histone/DNA ratios were found to be similar in the thymocytes and renal cells of the antigen-injected mice. The antigen-induced loss of thymocyte histones was also found to be associated with a change in the color of the A-S staining, from yellowish brown to black. This and other findings suggest that thymocyte nuclei contain an antigen-labile, lysine-rich histone. The implication of these observations in regard to the phenomenon of immunological competence is discussed and the need for continued investigation indicated.     

Immunocytochemical localization of calmodulin in PC12 cells and its possible interaction with histones

The subcellular localization of calmodulin, a multi-functional calcium-binding regulatory protein, was examined immunocytochemically in undifferentiated PC12 rat pheochromocytoma cells and cells differentiated with nerve growth factor (NGF) and dibutyryl cyclic AMP. In undifferentiated PC12 cells, diffuse immunostaining for calmodulin was observed in the cytoplasm, and weak, patch-like staining was found in the nucleus. In differentiated cells, intense immunostaining for calmodulin was observed in the cytoplasm, while nuclear immunostaining was still evident. Immunoreactivity for calmodulin was also observed along newly-formed neuritic processes, with strong staining in varicosity-like structures and growth cones. Using double-label immunochemistry, the relative intensity of immunostaining for calmodulin among the nuclei was found to correlate with the relative intensity of immunostaining for histones in the same nuclei. A comparison of a profile of ¹²⁵I-calmodulin binding in the nuclear fraction from PC12 cells to that of immunoblotting for histones in the same fraction indicated that some of the histones are calmodulin-binding proteins in PC 12 cells. These results show that the level and subcellular distribution of calmodulin are altered during the course of nerve cell differentiation and suggest the possibility that histones may function as major nuclear binding proteins for calmodulin.     

HAMLET interacts with histones and chromatin in tumor cell nuclei

HAMLET is a folding variant of human alpha-lactalbumin in an active complex with oleic acid. HAMLET selectively enters tumor cells, accumulates in their nuclei and induces apoptosis-like cell death. This study examined the interactions of HAMLET with nuclear constituents and identified histones as targets. HAMLET was found to bind histone H3 strongly and to lesser extent histones H4 and H2B. The specificity of these interactions was confirmed using BIAcore technology and chromatin assembly assays. In vivo in tumor cells, HAMLET co-localized with histones and perturbed the chromatin structure; HAMLET was found associated with chromatin in an insoluble nuclear fraction resistant to salt extraction. In vitro, HAMLET bound strongly to histones and impaired their deposition on DNA. We conclude that HAMLET interacts with histones and chromatin in tumor cell nuclei and propose that this interaction locks the cells into the death pathway by irreversibly disrupting chromatin organization.     

Microelectrophoretic analysis of basic protein changes during spermiogenesis in the dogfish Scylliorhinus caniculus (L.)

Spermatogenesis in the dogfish is characterized by the synchronous development of germinal cells inside follicles. This particularity has permitted studies on precise stages of cell differentiation, especially on the evolution of chromatin structure. A microelectrophoretic method has been devised for the determination of the basic nuclear protein content of accurately identified homogeneous stages of spermatid differentiation. No significant difference was observed during the first stages of spermiogenesis, i.e., in round spermatids, where a typical histone complement was present. At the beginning of nuclear elongation, two new basic protein fractions appeared and coexisted for some time with typical histones; they replaced somatic histones progressively. Later, during elongation, four proteins of high electrophoretic mobility appeared and gradually replaced the intermediary basic proteins. In elongated spermatids, DNA was found tightly packed by these four proteins: three are arginine- and cysteine-rich (Z1, Z2 and S4), the fourth is arginine-rich (Z3). At first, these fractions are all soluble in 0.25 M HCl but during sperm maturation only one (Z3) remains acid-soluble, the others being extractable only after reducing and alkylating treatments. This modification of solubility of Z1, Z2 and S4 corresponded to the oxidation of cysteine residues to form ---S---S--- crosslinks in chromatin of mature sperm cells. Thus spermiogenesis of the dogfish shows two basic nuclear protein transitions which both occur during nuclear elongation.     

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(adenosine diphosphate ribose) synthetase activity in nuclei of dividing and of non-dividing but differentiating intestinal epithelial cells.

Poly(ADP-ribose) synthetase activity is found in nuclei of regenerating epithelial cells in the lower half of the crypts of guinea-pig small intestine. Nuclei from non-dividing but differentiating and maturing cells in the upper crypts and on the villi contain no more than about 10% of the synthetase activity of lower-crypt cell nuclei. The product in the active nuclei is shown to be 80% poly(ADP-ribosylated) protein and 20% mono(ADP-ribosylated) protein; 60% of thetotal labelled product was attached to acid-soluble proteins (including histones), and 40% to acid-insoluble (non-histone) proteins. The average number of ADP-ribosyl units in the oligomeric chains of the poly(ADP-ribosylated) proteins was 15 but the range of sizes of (ADP-ribose) oligomers attached to nuclear proteins was smaller in villus than in crypt cell nuclei.     

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.     

Transfer of cytoplasmic and nuclear proteins between cells in culture

Evidence is presented for transfer of proteins between cells in culture, using techniques which previously have shown RNA transfer and the lack of DNA transfer between cells in culture. These techniques involved making donor cells heavier than recipient cells by having them ingest tantalum particles. After coculture of donor and recipient cells the two cell types were separated by centri- fugation on Ficoll gradients and the recipient cells analyzed for radioactively labeled proteins that may have passed from the prelabeled donor cells.These techniques also provided evidence for passage of donor cell proteins to recipient cell nuclei. Examination of the nuclear proteins in the recipient cells revealed that histones were transferred intercellularly to a greater extent than other nuclear proteins. The histone subfractions in the recipient cell nuclei were studied by acrylamide gel electrophoresis. No major differences were found in the proportion of each histone subfraction that was transferred to the recipient cell nuclei.     

Differential in vivo binding dynamics of somatic and oocyte-specific linker histones in oocytes and during ES cell nuclear transfer

The embryonic genome is formed by fusion of a maternal and a paternal genome. To accommodate the resulting diploid genome in the fertilized oocyte dramatic global genome reorganizations must occur. The higher order structure of chromatin in vivo is critically dependent on architectural chromatin proteins, with the family of linker histone proteins among the most critical structural determinants. Although somatic cells contain numerous linker histone variants, only one, H1FOO, is present in mouse oocytes. Upon fertilization H1FOO rapidly populates the introduced paternal genome and replaces sperm-specific histone-like proteins. The same dynamic replacement occurs upon introduction of a nucleus during somatic cell nuclear transfer. To understand the molecular basis of this dynamic histone replacement process, we compared the localization and binding dynamics of somatic H1 and oocyte-specific H1FOO and identified the molecular determinants of binding to either oocyte or somatic chromatin in living cells. We find that although both histones associate readily with chromatin in nuclei of somatic cells, only H1FOO is capable of correct chromatin association in the germinal vesicle stage oocyte nuclei. This specificity is generated by the N-terminal and globular domains of H1FOO. Measurement of in vivo binding properties of the H1 variants suggest that H1FOO binds chromatin more tightly than somatic linker histones. We provide evidence that both the binding properties of linker histones as well as additional, active processes contribute to the replacement of somatic histones with H1FOO during nuclear transfer. These results provide the first mechanistic insights into the crucial step of linker histone replacement as it occurs during fertilization and somatic cell nuclear transfer.     

Chromatin decondensation and nuclear reprogramming by nucleoplasmin

Somatic cell nuclear cloning has repeatedly demonstrated striking reversibility of epigenetic regulation of cell differentiation. Upon injection into eggs, the donor nuclei exhibit global chromatin decondensation, which might contribute to reprogramming the nuclei by derepressing dormant genes. Decondensation of sperm chromatin in eggs is explained by the replacement of sperm-specific histone variants with egg-type histones by the egg protein nucleoplasmin (Npm). However, little is known about the mechanisms of chromatin decondensation in somatic nuclei that do not contain condensation-specific histone variants. Here we found that Npm could widely decondense chromatin in undifferentiated mouse cells without overt histone exchanges but with specific epigenetic modifications that are relevant to open chromatin structure. These modifications included nucleus-wide multiple histone H3 phosphorylation, acetylation of Lys 14 in histone H3, and release of heterochromatin proteins HP1beta and TIF1beta from the nuclei. The protein kinase inhibitor staurosporine inhibited chromatin decondensation and these epigenetic modifications with the exception of H3 acetylation, potentially linking these chromatin events. At the functional level, Npm pretreatment of mouse nuclei facilitated activation of four oocyte-specific genes from the nuclei injected into Xenopus laevis oocytes. Future molecular elucidation of chromatin decondensation by Npm will significantly contribute to our understanding of the plasticity of cell differentiation.     

Methylation of Chromosomal Proteins in Neuronal and Glial Nuclei Purified from Cerebral Hemispheres of Rat During Postnatal Development

The process of methylation of chromosomal proteins [histones and nonhistone proteins (NHP)] in neuronal and glial cell nuclei obtained from cerebral hemispheres of rats at 1, 10, and 30 days of age was investigated. Purified neuronal and glial nuclei were incubated in the presence of S-adenosyl[methyl-3H]methionine. Histone and NHPs were extracted and fractionated by polyacrylamide gel electrophoresis. The results obtained indicate remarkable differences in the process of methylation of histones and NHPs between neuronal and glial nuclei, especially during the first period of postnatal development. In both nuclear populations the histone fraction H3 was labeled to a greater degree than the other fractions and showed the major changes during postnatal development. The densitometric and radioactive patterns of NHPs show considerable changes in the two nuclear populations at the various ages examined. The main difference between neuronal and glial nuclei consists in the intense methylation of proteins with a molecular weight of approximately 100,000, which are present in neuronal nuclei and virtually absent in glial ones. The results obtained may be correlated with the different chromatin structures of neuronal and glial nuclei and with the patterns of maturation and differentiation of neuronal and glial cells during postnatal development.     

EVIDENCE For THE CYTOPLASMIC SYNTHESIS OF NUCLEAR HISTONE DURING SPERMIOGENESIS IN THE GRASSHOPPER CHORTOPHAGA VIRIDIFASCIATA (DE GEER)

Histone synthesis during spermiogenesis in the grasshopper Chortophaga viridifasciata was studied using autoradiographic and cytochemical methods. It was found that meiosis is followed by a cessation of RNA synthesis, an elimination of RNA from the nucleus, and, during the cytoplasmic sloughing accompanying the initial cytoplasmic elongation, a loss of most of the RNA from the cell. The initial phase of cell elongation results in a long spermatid headed by a spherical RNA-less nucleus bounded by a thin RNA-containing layer of cytoplasm. Subsequent nuclear elongation is accompanied by a replacement of the typical histones by others rich in arginine. This replacement is the result of synthesis of new protein. Incorporation of arginine is first seen to occur in the thin cytoplasmic layer surrounding the nucleus. This layer was shown by staining and electron microscopy to contain aggregations of ribosome-like particles. These observations support the conclusion that the histone is synthesized in association with the RNA granules in the cytoplasm, then migrates into the nucleus where it combines with the DNA.     

Occurrence of Mitochondria in the Nuclei of Tobacco Sperm Cells

Tobacco sperm cells contain intact mitochondria within their nuclei with a frequency of 0.35 [plusmn] 0.13 per cell. These inclusions appear to originate from mitochondria found among chromatids in the highly elongated metaphase plate of the dividing generative cell. These organelles are apparently captured during the reconstitution of the nuclear envelope. Only sperm cells were observed to contain these nuclear mitochondria; generative cells, vegetative pollen cells, transmitting tissue cells, unfertilized egg cells, and central cells lacked them. Nuclear mitochondria were also seen in the nuclei of the egg and central cell after fusion with sperm nuclei, suggesting that nuclear mitochondria are transmitted into the zygote and primary endosperm cells during double fertilization. Organellar inclusions in the sperm nucleus provide a potential mechanism for transmitting organellar DNA into the next generation and could potentially facilitate the transfer of genetic material between the nucleus and other organelles.     

Nuclear proteins and DNA in the myocardial myocytes in compensatory cardiac hypertrophy]

Using cytophotometry, the amount of DNA, total nuclear proteins and of histones were studied in the myocardial cells during days 21--36 of experimental compensatory hypertrophy of the heart (in rats). The enlargement of myocardial nuclei during the cardial hyperfunction was accompanied by accumulation of total nuclear protein, in particular, the histone fraction, without distinct changes in DNA. Analysis of correlations between nuclear proteins and DNA in the myocardial cells allows to reveal a delayed accumulation of histones in the big and gigantic nuclei, with a superfluous increase in non-histone nuclear proteins. In middle-sized nuclei, non-histone proteins have little changes against intensive accumulation of histones.     

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.     

Spermine-induced phosphorylation of myotube histones by endogenous nuclear protein kinases

The effects of spermine on phosphorylation of nuclear proteins in isolated nuclei from proliferation and myotube stage cells during differentiation of cultured chicken myoblasts have been investigated. Incorporation of phosphate from 32P-gamma-ATP was assessed by incubating nuclei with and without 2 mM spermine, which caused an approx. 1.5-fold increase in phosphorylation of total nuclear proteins in both cell types. Modification of individual proteins was assessed by extracting basic proteins in dilute acid, followed by SDS-electrophoresis on 18% acrylamide gels and radioautography. Results indicated that whereas most phosphoproteins in both cell types were increased 1.5-2.0-fold, phosphorylation of a 31 000 D band increased several-fold. Most strikingly, myotube nuclei displayed selective 3.5- and 9-fold increases in specific radioactivity of histones Hla and H3, respectively, which normally exhibit little, if any, phosphorylation.     

Isolation and characterization of the nuclear matrix in Friend erythroleukemia cells: chromatin and hnRNA interactions with the nuclear matrix.

Nuclear matrices from undifferentiated and differentiated Friend erythroleukemia cells have been obtained by a method which removes DNA in a physiological buffer. These matrices preserved the characteristic topographical distribution of condensed and diffuse "chromatin" regions, as do nuclei in situ or isolated nuclei. Histone H1 was released from the nuclear matrix of undifferentiated cells by 0.3 M KCl; inner core histones were released by 1 M KCl. Nuclear matrix from differentiated cells did not maintain H1, and histone cores were fully released in 0.7 M KCl. KCl removed the core histones as an octameric structure with no evidence of preferential release of any single histone. Electron microscopy of KCl-treated matrix revealed no condensed regions but rather a network of fibrils in the whole DNA-depleted nuclei. When nuclear matrices from both types of cell were exposed to conditions of very low ionic strength, inner core histones and condensed regions remained. These observations support the contention that inner core histones are bound to matrix through natural ionic bonds or saline-labile elements, and that these interactions are implicated in chromatin condensation. hnRNA remained undegraded and tenaciously associated to the matrix fibrils, and was released only by chemical means which, by breaking hydrophobic and hydrogen bonds, produced matrix lysis. Very few nonhistone proteins were released upon complete digestion of DNA from either type of nuclei. The remaining nonhistone proteins represent a large number of species of which the majority may be matrix components. The molecular architecture in both condensed and diffuse regions of interphase nuclei appears to be constructed of two distinct kinds of fibers; the thicker chromatin fibers are interwoven with the thinner matrix fibers. The latter are formed by a heteropolymer of many different proteins.