Histones in the first cleavage cycle of fertilised sea urchin eggs

Nuclei were isolated from Echinus eggs through the first cleavage cycle by modification of existing techniques. When these nuclei were extracted with 2 M NaCl and the supernatant diluted to 0.15 M, large amounts of non-histone proteins remained in solution. The precipitated nucleoprotein contained expected amounts of DNA and a protein analogous to mammalian histone H1. Extrachromosomal histone H1 was eliminated by the modified isolation procedure. Amounts of nuclear proteins soluble in 0.15 M NaCl reached a peak in G2. Histones and non-histone proteins were phosphorylated postfertilization, in early prophase and in telophase.     

Non-histone chromosomal proteins easily extractible from chick erythrocytes.

Those non-histone chromosomal proteins which are easily extractible from chick erythrocytes differ substantially from proteins similarly extracted from other tissues of various species. Although a protein P1 was isolated along with histone H1 by extraction of calf thymus chromatin with HC1O4, the same procedure did not extract this protein from chick erythrocyte chromatin of either normal or regenerating blood. Likewise , non-histone proteins extracted with 0.35 M NaCl from calf thymus differed from those of normal chick erythrocytes, which were qualitatively identical but quantitatively inferior to those of regenerating blood. The major protein of about 25 000 molecular weight, totally extracted with 0.35 M NaCl from calf thymus, was not found in chick erythrocyte chromatin, but rather another major protein of about 35 000 molecular weight was partially extracted from erythrocytes.     

Porcine follitropin. The amino-acid sequence of the beta subunit

By treatment with tRNA in the presence of 1 mM MgCl2, a chromatin preparation was obtained containing all five major histone fractions but lacking a considerable portion of non-histone proteins. This chromatin preparation as well as chromatin extracted with 0.6 M NaCl (depleted of H1 histone and some non-histone proteins) were characterized in respect of solubility and chromatin DNA accessibility. Both samples possessed practically the same solubility in the presence of 0.15 M NaCl and 1 mM MgCl2. The solubility of tRNA-treated chromatin in 5 and 10 mM MgCl2 was higher than that of salt-extracted chromation. The accessibility of the DNA of these chromatin preparations was tested with DNA-dependent RNA polymerase of Escherichia coli as a probe, using procedure that permits measurement of binding site frequency. Both tRNA-treated and salt-extracted chromatin contained as many as 33% and untreated chromatin as few as 4% of the number of binding sites found on protein-free DNA. These results demonstrate that at least in part the non-histone proteins are responsible for salt-induced insolubility and low DNA accessibility of chromatin, thus revealing the importance of non-histone proteins in the maintenance of an overall chromatin structure.     

Partial purification of transcriptionally active nucleosomes from trout testis cells.

Mononucleosomes (MN1) enriched in structural non-histone proteins and transcribed DNA sequences were obtained by limited digestion of trout testis nuclei with micrococcal nuclease followed by selective solubilization in 0.1 M NaCl. These monosomes consist of the four inner histones plus stoichiometric amounts of the non-histone protein H6, of the HMG group, complexed with 140 base pairs of DNA. Hybridization experiments indicate that MN1 DNA is enriched in sequences complementary to cytoplasmic polyadenylated RNA.     

Analysis of the effectiveness of sodium chloride in dissociating non-histone chromatin proteins of cultured hepatoma cells

We examined the ability of NaCl (at 0.15 to 3 M) to release non-histone proteins from chromatin of cultured rat hepatoma cells. The percentage of the non-histones released increased with increasing NaCl concentrations up to 0.75 M; 1 and 3 M NaCl were not significantly more effective. A maximum of 50% of the non-histone protein was recovered free of DNA. The release of non-histones from sheared and unsheared chromatin was similar. The electrophoretic patterns of the non-histone proteins released by NaCl resembled that of the non-histones released by sodium dodecyl sulfate, which indicates that many of the detectable components were at least partially released by NaCl. Some non-histones (especially low molecular weight polypeptides) were fully released by NaCl and other proteins were relatively resistant to NaCl release. Higher recoveries of NaCl-dissociated non-histones were obtained with sucrose gradient centrifugation than with centrifugation in the absence of sucrose.     

An H1-like protein from the macronucleus of Euplotes eurystomus

An H1-like protein has been purified from the macronucleus (MAC) of the hypotrichous ciliated protozoan, Euplotes eurystomus. It is present in amounts comparable to the inner histones and is extracted by treatment with 5% perchloric acid or 0.65 M NaCl, but not by 0.35 M NaCl. Treatment of soluble MAC chromatin with the ionic exchange resin AG 50W-X2 in 80 mM NaCl removes MAC H1 and yields H1-depleted chromatin. Mac H1 is lysine-rich and deficient in acidic amino acids. The stoichiometry of the H1 protein is reduced in mononucleosome preparations, consistent with its postulated interaction with linker DNA regions. Thermal denaturation and circular dichroism studies reveal that H1-depleted chromatin contains a larger portion of destabilized DNA than control chromatin. The molecular weight of Euplotes MAC H1 is significantly smaller than most reported H1 proteins. Comparisons are made with extracts of macronuclei from other hypotrichous ciliated protozoa and published reports of other lower eukaryotes.     

Cytoplasmic and nuclear protein kinases during the cell cycle.

Nuclear and cytoplasmic protein kinases were measured during the traverse of synchronous CHO cultures through G1 into S phase. Cells were synchronized by selective detachment of cells blocked in metaphase using colcemid. Nuclei were isolated and the protein kinases extracted from the nuclear preparation with 0.6 M NaCl. This procedure solubilized greater than 90% of the total protein kinase activity present in the nuclear preparation. DEAE chromatography of this extract showed 5 apparently different ionic forms of nuclear protein kinases. The nuclear protein kinases preferred casein and phosvitin to histone as substrates and were cyclic AMP-independent. Nuclear protein kinase activities increased greater than two-fold, when expressed as units of activity per cell nucleus, during G1 phase traverse, concomitant with a 70% increase in nuclear non-histone proteins (those soluble in 0.6 M NaCl). This resulted in only a 40% increase in the specific activities (units/microgram protein in 0.6 M NaCl extractable nuclear fraction) of these enzymes as cells progressed through G1 into S phase. This was in contrast to cytoplasmic cyclic AMP-dependent protein kinase activities which also increased two-fold during progression through G1 phase while total cellular protein increased less than 20%. Activation of, as well as synthesis of, cyclic AMP-dependent cytoplasmic protein kinases during G1 phase suggests a regulatory mechanism for precise temporal phosphorylation, whereas the constant specific activity in nuclear kinases during cell cycle is more compatible with the maintenance of bulk phosphorylation processes in the nucleus.     

Nuclear protein kinase activities during the cell cycle of HeLa S3 cells

To ascertain the activity and substrate specificity of nuclear protein kinases during various stages of the cell cycle of HeLa S3 cells, a nuclear phospho-protein-enriched sample was extracted from synchronised cells and assayed in vitro in the presence of homologous substrates. The nuclear protein kinases increased in activity during S and G2 phase to a level that was twice that of kinases from early S phase cells. The activity was reduced during mitosis but increased again in G1 phase. When the phosphoproteins were separated into five fractions by cellulose-phosphate chromatography each fraction, though not homogenous, exhibited differences in activity. Variations in the activity of the protein kinase fractions were observed during the cell cycle, similar to those observed for the unfractionated kinases. Sodium dodecyl sulfate polyacrylamide gel electrophoretic analysis of the proteins phosphorylated by each of the five kinase fractions demonstrated a substrate specificity. The fractions also exhibited some cell cycle stage-specific preference for substrates; kinases from G1 cells phosphorylated mainly high molecular weight polypeptides, whereas lower molecular weight species were phosphorylated by kinases from the S, G2 and mitotic stages of the cell cycle. Inhibition of DNA and histone synthesis by cytosine arabinoside had no effect on the activity or substrate specificity of S phase kinases. Some kinase fractions phosphorylated histones as well as non-histone chromosomal proteins and this phosphorylation was also cell cycle stage dependent. The presence of histones in the in vitro assay influenced the ability of some fractions to phosphorylate particular non-histone polypeptides; non-histone proteins also appeared to affect the in vitro phosphorylation of histones.     

Role of non-histone proteins in chromatin solubility

Treatment of chromatin gel with low ionic strength solution of tRNA has produced the dioxyribonucleoprotein (dnptRNA) in which only part of non-histone proteins was removed without loss of any major histone fraction. The solubility of DNP in the presence of 0.15 M NaCl and 1 to 5 mM MgCl2 was considerably higher than that of initial untreated chromatin. It has been assumed that the solubility of chromatin depended primarily on some non-histone proteins and not on H1 histone.     

Acid-soluble, non-histone proteins in rat liver chromatin. Interaction with DNA

Some properties of nonhistone proteins of rat liver chromatin (Mr 40 +/- 1 and 41 +/- 1 KD) are described. These proteins are abundant in monomeric particles formed at the early steps of chromatin fragmentation by Ca2+,Mg2+-DNase. The proteins are not extracted from chromatin by 5% HClO4 and 1 M NaCl, but can be extracted by 0.4 n H2SO4 and 2 M NaCl. Study on proteins binding to DNA demonstrated that in 0.05 M NaCl these proteins are bound both to bovine satellite DNA and to the plasmid pBR 322 DNA.     

DNA binding by cyclic adenosine 3',5'-monophosphate dependent protein kinase from calf thymus nuclei.

Cyclic adenosine 3',5'-monophosphate (cAMP) dependent protein kinase and proteins specifically binding cAMP have been extracted from calf thymus nuclei and analyzed for their abilities to bind to DNA. Approximately 70% of the cAMP-binding activity in the nucleus can be ascribed to a nuclear acidic protein with physical and biochemical characteristics of the regulatory (R) subunit of cAMP-dependent protein kinase. Several peaks of protein kinase activity and of cAMP-binding activity are resolved by affinity chromatography of nuclear acidic proteins on calf thymus DNA covalently linked to aminoethyl Sephrarose 4B. When an extensively purified protein kinase is subjected to chromatography on the DNA column in the presence of 10(-7) M cAMP, the R subunit of the kinase is eluted from the column at 0.05 M NaCl while the catalytic (C) subunit of the enzyme is eluted at 0.1-0.2 M NaCl. When chromatographed in the presence of histones, the R subunit is retained on the column and is eluted at 0.6-0.9 M NaCl. In the presence of cAMP, association of the C subunit with DNA is enhanced, as determined by sucrose density gradient centrifugation of DNA-protein kinase complexes. cAMP increases the capacity of the calf thymus cAMP-dependent protein kinase preparation to bind labeled calf thymus DNA, as determined by a technique employing filter retention of DNA-protein complexes. This protein kinase preparation binds calf thymus DNA in preference to salmon DNA, Escherichia coli DNA, or yeast RNA. Binding of protein kinases to DNA may be part of a mechanism for localizing cyclic nucleotide stimulated protein phosphorylation at specific sites in the chromatin.     

DNA-synthesizing activity of the nucleoid protein core in Escherichia coli

Nucleoids obtained from E. coli cells by extraction with 1 M NaCl and detergents containing solution were further extracted with 2 M NaCl. From these samples, that contain only tightly bound proteins, fractions of protein core and peripheral nucleoprotein were obtained. It is shown that DNA synthesis proceeds mainly in the core structures. We have found that DNA polymerase I, which is bound with DNA nucleoid loops and with the above mentioned core structures, is not dissociating in 2M NaCl solution.     

Biochemical and ultrastructural study of the sperm chromatin from Mytilus galloprovincialis

Protein composition and ultrastructure of the mature spermatozoa of the mussel Mytilus galloprovincialis were studied upon gradual decondensation of the nuclei with increasing NaCl concentration. Three types of protein were found, associated with the sperm DNA: (1) the sperm-specific proteins S1, S2 and S3 (80% of the acid-soluble proteins); (2) the four core histones (20%); (3) three non-histone proteins tightly bound to DNA (about 4 micrograms protein per 100 micrograms DNA). The sperm-specific protein S3 was the first to dissociate at about 0.5 M NaCl and electron micrographs of spread nuclei indicated its participation in the final compaction of the nucleus. Hypotonically treated sperm nuclei revealed the presence of 21-25 nm large granules irregularly scattered along some of the DNA fibers. These granules correspond to the 'superbeads' of histone-containing chromatins. The tightly bound non-histone proteins were represented by a triplet in the range 60-80 kD. They formed 30-60 nm large annular bodies holding DNA fibers and resisting high salt-detergent treatment.     

Formation of highly stable complexes between 5-azacytosine-substituted DNA and specific non-histone nuclear proteins. Implications for 5-azacytidine-mediated effects on DNA methylation and gene expression

Incubation of 5-azacytosine-substituted DNA ([5-aza-C]DNA) with nuclear proteins leads to the formation of highly stable DNA . protein complexes which remain intact in the presence of 1 M NaCl and/or 0.6% Sarkosyl. The proteins involved in binding double-stranded [5-aza-C]DNA in these stable complexes comprise a specific subset of non-histone nuclear proteins that includes DNA methyltransferase. Complex formation does not require S-adenosylmethionine and does not involve covalent linkage of protein to DNA or modification of 5-azacytosine residues. Non-histone nuclear proteins do not form complexes with double-stranded unsubstituted DNA that are resistant to dissociation with NaCl and Sarkosyl but are capable of forming such complexes with single-stranded DNA regardless of whether it contains 5-azacytosine residues or not. However, it can be demonstrated 1) that single-stranded regions do not account for stable binding of proteins to native [5-aza-C]DNA and 2) that many nuclear proteins which form stable complexes with single-stranded DNA are incapable of forming such complexes with double-stranded [5-aza-C]DNA. Synthesis of [5-aza-C]DNA by cells growing in the presence of either 5-azacytidine or 5-aza-2'-deoxycytidine leads to rapid loss of extractable DNA methyltransferase (Creusot, F., Acs, G., and Christman, J.K. (1982) J. Biol. Chem. 257, 2041-2048). Analogous depletion of non-histone nuclear proteins capable of forming stable complexes with [5-aza-C]DNA in vitro is observed, suggesting that the same proteins can form highly stable complexes with [5-aza-C]DNA in vitro and in vivo. Formation of stable complexes between non-histone nuclear proteins and [5-aza-C]DNA could potentially affect not only the activity of DNA methyltransferase but the action of other regulatory proteins or enzymes that interact with DNA. Such interactions could explain effects of 5-azacytidine on gene expression that cannot be directly linked to loss of methyl groups from DNA.     

Complexes of nuclear matrix DNA with proteins tightly bound to DNA contain a specific small-size RNA of a novel type

Analysis of DNA-protein structures composed of nuclear matrix attached DNA and the most tightly bound proteins was performed. Although the previously described non-histone proteins (1) were present the buoyant density of the complex was the same as that of pure DNA. RNA inaccessible to RNase in 0.4 M NaCl but digestible in low ionic strength buffer was detected. This RNA is not a nascent one. It turned out to be homogeneous and represent a novel type of small nuclear RNA. Partial sequence of this RNA is presented.     

Isolation and characterization of protein A24, a "histone-like" non-histone chromosomal protein.

In earlier studies, the nucleolar levels of protein A24 were found to be markedly decreased in the nucleolar hypertrophy induced by thioacetamide or during liver regeneration (Ballal, N.R., Goldknopf, I.L., Goldberg, D.A., and Busch, H. (1974) Life Sci. 14, 1835-1845; Ballal, N.R., Kang, Y.-J., Olson, M.O.-J., and Busch, H.J. Biol. Chem. 250, 5921-5925). To determine the role of protein A24, methods were developed for its isolation in highly purified form. Milligram quantities of highly purified protein A24 were isolated from the 0.4 N H2SO4-soluble proteins of calf thymus chromatin by exclusion chromatography on Sephadex G-100, followed by preparative polyacrylamide gel electrophoresis. Protein A24 was highly purified as shown by its migration as a single spot on two-dimensional polyacrylamide gel electrophoresis, its single NH2-terminal amino acid, methionine, and the production of approximately 50 peptides by tryptic digestion. Like histones 2A, 2B, 3, and 4. A24 was extractable from chromatin with 0.4 N H2SO4 or 3 M NaCl/7 M urea, but unlike most non-histone proteins or histone 1, protein A24 was not extracted with 0.35 M NaCl, 0.5 M HClO4, or 0.6 M NaCl. Protein A24 was present in only 1.9% of the total amount of histones 2A, 2B, 3 and 4; its molecular weight is 27,000.     

Interaction of subunits of cAMP-dependent protein kinase with structural elements of the cell nucleus

Using the method of protein transfer from polyacrylamide gel to nitrocellulose filters with subsequent incubation of filter-adsorbed protein with [32P]DNA, it was found that the catalytic subunit of cAMP-dependent protein kinase from porcine brain is capable of interacting with DNA to form a stable complex. This complex is resistant even to 2 M NaCl. The ability of the catalytic subunit to interact with DNA depends on the degree of enzyme nativity. The regulatory subunit of cAMP-dependent protein kinase does not bind to DNA both in the presence and absence of cAMP. The 125I-labeled regulatory subunit can interact with some chromatin proteins, in particular, with histone H1 and core histones. An essential role in this binding belongs to electrostatic and hydrophobic interactions.     

Rous sarcoma virus-induced changes in the pattern of phosphorylation of non-histone nuclear proteins

We here studied the protein kinase activity and in vitro phosphorylable sites of non-histone nuclear proteins, 0.4 M NaCl extracts (mostly chromosomal proteins) from chick embryo fibroblasts (CEF), infected or not with a Schmidt Ruppin strain subgroup A of Rous sarcoma virus (RSV).The infection and transformation of chick fibroblasts by RSV induced an increase in kinase activity and endogenous phosphorylation of non-histone chromosomal (NHC) proteins. The stimulation, by a change of medium, of the proliferation of dense cultures of normal chick fibroblasts also induced an increase in the kinase activity and endogenous phosphorylation of NHC proteins.However, two-dimensional gel electrophoresis of the ³²P-phosphorylated proteins showed that stimulation due to a change of medium and that due to the expression of transformation were very different. The stimulation by a change of medium increased to a greater or lesser extent the phosphorylation of the different NHC proteins, with no fundamental variations in the pattern of protein phosphorylation. In contrast, RSV infection induced significant changes in the pattern of protein phosphorylation. One of the most striking feature was the large increase of amount and phosphorylation of high molecular weight (HMW) proteins in particular of phosphoproteins having an evaluated molecular weight (MW) of 78 K and 82 K and pI>8.2.The percent of phosphotyrosine residues in NHC proteins was clearly increased when the proteins were extracted from transformed cells instead of normal cells. But the alkaline treatment of two-dimensional gel electrophoresis indicated that the 80 K phosphoproteins did not contain phosphotyrosine residues, and thus cannot be considered as substrates for pp60^src kinase.     

Partial displacement of histone H1 from chromatin is required before it can be phosphorylated by mitotic H1 kinase in vitro.

The massive nonselective and reversible phosphorylation of histone H1 during mitosis is a universal phenomenon among eukaryotes. The growth-associated kinase responsible for this phosphorylation is identical to the maturation promoting factor, a key regulator of the cell cycle. Here we showed that growth-associated kinase, isolated from mitotic HeLa cells which were capable of phosphorylating HeLa H1 in vitro with high activity and mostly at the same sites phosphorylated during mitosis in vivo (assayed by two-dimensional analysis of tryptic phosphopeptides), did not significantly phosphorylate chromatin-bound or nuclear H1 in vitro. Its inability to phosphorylate chromatin-bound H1 did not change when the amount of kinase was increased or the incubation was prolonged. The resistance of chromatin-bound H1 to phosphorylation did not result from chromatin aggregation. Rapid phosphorylation of H1 in vitro, as well as in a nuclear system, was restored when NaCl concentrations were raised above 200 mM where H1:DNA interactions are weakened. At 300 mM NaCl, chromatin-bound H1 was phosphorylated in a subset of the sites observed for free H1 phosphorylated in vitro. These results suggest that active displacement of H1 from chromatin DNA may take place before H1 can be fully phosphorylated during mitosis.