Role of nonhistone chromosomal proteins in determining circular dichroism spectra of chromatin.

Complexing of histone proteins, from WI-38 cells with pure DNA from WI-38 cells, causes a marked decrease in the amplitude of the positive ellipticity band and a red shift in circular dichroism spectra in the 250–300 nm region. Total nonhistone chromosomal proteins from WI-38 cells (without histones) cause an analogous effect, but of significantly reduced magnitude. However, the two effects are not additive, because, when DNA is complexed with both histones and nonhistones, the amplitude of the positive ellipticity band has an intermediate value, between the histone-DNA complex and the nonhistone-DNA complex. Removal of certain nonhistone proteins from chromatin of WI-38 cells, by extraction with 0.25–0.35 m NaCl, causes a decrease in the positive circular dichroism band in the 250–300 nm region. Removal of histones and other nonhistone proteins from chromatin by extraction with 0.75 and 1.5 m NaCl causes a strong increase in positive ellipticity. This suggests the existence of modest but definite effects of nonhistone proteins in determining DNA conformation in native chromatin. Taken as a whole, nonhistone chromosomal proteins have a weaker but analogous effect to that of histones, while the nonhistone proteins extractable with 0.25–0.35 m NaCl have an opposite effect.     

Hepatoma-associated nuclear matrix nonhistone antigens

Polyclonal antibodies generated against a group of high molecular weight nonhistone proteins from Morris hepatoma 7777 were used in immunological studies of hepatoma-associated nonhistone proteins in rat and hamster. We revealed the presence of cross-reactive antigens in rat Morris hepatomas 7777 and 8994, and in hamster Kirkman-Robbins hepatoma, but not in normal rat or hamster livers. These specific nonhistone proteins were found to be preferentially localized in the nuclear matrix of rat Morris hepatoma 7777 as well as hamster Kirkman-Robbins hepatoma.     

Fractionation of rat-liver-chromatin nonhistone proteins into two groups with different metabolic rates.

In the pH interval 10.5-11.8, 70% of the nonhistone proteins normally present in rat liver chromatin were dissociated. The rest remained complexed with DNA even at pH 13. Dodecylsulfate-polyacrylamide gel electrophoresis revealed that the majority of the high-molecular-weight nonhistone proteins together with a few characteristic fractions with molecular weights of 40 000-60 000 remained in the alkali-resistant group. L-[14C]Leucine pulse-labelling experiments showed that the specific radioactivity of the alkali-labile nonhistone proteins was 2-3 times higher than that of the alkali-resistant nonhistone proteins, which, in turn, had the same specific radioactivity as that of the histones. The same held true for chromatin from regenerating rat liver. In the course of a 21-day chase the specific radioactivity of the alkali-labile nonhistone proteins gradually decreased and finally became 3 times lower than that of the alkali-resistant nonhistone proteins. On the contrary, the ratio of the specific radioactivities of the alkali-resistant nonhistone proteins and of the histones to the specific radioactivity of DNA remained constant during the chase. A conclusion can be drawn that a fraction of liver nonhistone proteins exists which is alkali-resistant and is conserved in chromatin like histones.     

O-Phenantroline-CuSO4-induced redistribution of nuclear proteins

Incubation of rat liver nuclei with the o-phenantroline-CuSO₄ (OP-Cu) complex under conditions not causing any DNA cleavage, enhanced the susceptibility of chromatin to the action of micrococcal nuclease. The released nucleosomal fraction had less coextracted nonhistone proteins, while the nuclear matrix was enriched in nonhistone proteins when compared with the controls. These changes were interpreted as the consequence of a displacement of nonhistone proteins from their closer association with the chromatin complex and a concomitant exposure of chromatin regions in a state less protected by nonhistone proteins.     

The chemical composition of nuclei and chromosomes isolated by the Langmuir trough technique

The pattern of staining for DNA, histone, and nonhistone protein has been studied in whole cells and in nuclei and chromosomes isolated by surface spreading. In whole interphase cells from bovine kidney tissue culture, nuclear staining for DNA and histones reveals numerous small, intensely stained clumps, surrounded by more diffusely stained material. Nuclei in whole cells stained for nonhistone proteins also contain intensely stained regions surrounded by diffuse stain. These intensely stained regions also stain for RNA, indicating that the regions contain nucleolar material. Electron microscopy of kidney cells confirms that multiple nucleoli are present. Kidney nuclei isolated by surface spreading show an even distribution of stain for DNA, histones, and nonhistone proteins, indicating that the surface forces disperse both condensed chromatin and nucleoli. DNA and protein staining was also studied in metaphase chromosomes from testes of the milkweed bug, Oncopeltus fasciatus. Staining for DNA and histones in metaphase chromosomes is essentially the same in sections of fixed and embedded testes as in preparations isolated by surface spreading. However, striking differences are noted in the distribution of nonhistone proteins. In sections, nonhistone stain is concentrated in extrachromosomal areas; metaphase chromosomes do not stain for nonhistone proteins. Chromosomes isolated by surface spreading, however, stain intensely for nonhistone proteins. This suggests that nonhistone proteins are bound to the chromosomes as a contaminant during the isolation procedure. The relationship of these findings to current work with chromosomes isolated for electron microscopy is discussed.     

A comparative study of the nonhistone proteins of rat liver euchromatin and heterochromatin

Rat liver was fractionated into template-active (euchromatin) and template-inactive (heterochromatin) fractions by controlled shearing and glycerol gradient centrifugation. The histone and nonhistone proteins associated with each fraction were compared. No qualitative differences in histone content were observed, but heterochromatin contained 1.5 times more histone protein than did euchromatin. The nonhistone proteins of each chromatin fraction were fractionated on the basis of salt solubility into loosely bound (those extracted by 0.35 m NaCl), tightly bound (those extracted by 2.0 m NaCl), and residual nonhistone proteins (those not extracted by 2.0 m NaCl). Euchromatin contained 3.7 times more loosely bound nonhistone proteins than did heterochromatin, while the latter contained twice as much residual nonhistone protein. Euchromatin was devoid of tightly bound nonhistone protein, a component of heterochromatin. Electrophoretic analysis of these nonhistone protein fractions revealed marked heterogeneity, with a number of bands unique to either eu- or heterochromatin.     

Chromosomal protein synthesis during erythropoiesis in the mouse spleen

Induced erythropoiesis in the mouse spleen was employed to study chromosomal protein synthesis during erythroid cell development. Splenic erythropoiesis occurring after phenylhydrazine induced hemolysis can be divided into an early phase during which nuclear RNA polymerase activity and RNA production are maximal and a late phase in which hemoglobin synthesis and DNA accumulation are maximal. Chromatin was isolated from splenic tissue during both the early and late phases of erythropoiesis as well as from non-anemic animals. The total protein content of chromatin from the early erythroid phase was greater than that of chromatin from the late erythroid phase or from non-anemic controls. The increase was due to a coordinate increase in the concentration of both histone and nonhistone proteins. During late erythropoiesis, the concentration of each returned to pre-anemic levels. Total histone synthesis increased 2.6-fold during early erythropoiesis as compared with the pre-anemic state and remained elevated in late erythropoiesis. The increase in histone synthesis was due to an increase in the synthesis of all five major histone proteins. Nonhistone protein synthesis was more active than that of histones in the pre-anemic spleen and rose only slightly during early erythropoiesis, returning to preanemic levels during late erythropoiesis. Fractionation of nonhistone proteins on SDS-urea polyacrylamide gels revealed complex patterns with significant differences between the pattern of erythroid spleen non-histone proteins and that of the pre-anemic spleen. Analysis of the incorporation of ³H-valine into the non-histone proteins indicated that during early erythropoiesis there was a generalized increase in nonhistone protein synthesis. During the late erythroid phase, the decline in non-histone protein synthesis was most marked for the higher molecular weight proteins.     

The chemical composition of nuclei and chromosomes isolated by the Langmuir trough technique

The pattern of staining for DNA, histone, and nonhistone protein has been studied in whole cells and in nuclei and chromosomes isolated by surface spreading. In whole interphase cells from bovine kidney tissue culture, nuclear staining for DNA and histones reveals numerous small, intensely stained clumps, surrounded by more diffusely stained material. Nuclei in whole cells stained for nonhistone proteins also contain intensely stained regions surrounded by diffuse stain. These intensely stained regions also stain for RNA, indicating that the regions contain nucleolar material. Electron microscopy of kidney cells confirms that multiple nucleoli are present. Kidney nuclei isolated by surface spreading show an even distribution of stain for DNA, histones, and nonhistone proteins, indicating that the surface forces disperse both condensed chromatin and nucleoli. DNA and protein staining was also studied in metaphase chromosomes from testes of the milkweed bug, Oncopeltus fasciatus. Staining for DNA and histones in metaphase chromosomes is essentially the same in sections of fixed and embedded testes as in preparations isolated by surface spreading. However, striking differences are noted in the distribution of nonhistone proteins. In sections, nonhistone stain is concentrated in extrachromosomal areas; metaphase chromosomes do not stain for nonhistone proteins. Chromosomes isolated by surface spreading, however, stain intensely for nonhistone proteins. This suggests that nonhistone proteins are bound to the chromosomes as a contaminant during the isolation procedure. The relationship of these findings to current work with chromosomes isolated for electron microscopy is discussed.     

A contribution of nonhistone proteins to the conformation of chromatin.

1. Changes in circular dichroism (CD) spectra and thermal melting profiles of guinea pigliver DNA reassociated with histones and/or nonhistone proteins from the cerebral of liver chromatin are described. 2. In the DNA-histone complex, positive ellipiticity in the CD spectrum at 260-300 nm is progressively lod by a red-shift of the crossover point at around 260 nm. DNA in this complex is thermally stabilised to a considerable extent, but not to such a full extent as is shown with DNA in native chromatin. 3. DNA-nonhistone complex in 0.14 M NaCl is, in contrast to DNA-histone complex, not precipitable by centrifugation at 20 000 X g. DNA in this complex shows only a slight reduction in ellipticity at 260-300 nm, and a very weak thermal stabilisation. 4. Characteristics in the CD spectrum of the native chromatin are most satisfactorily reproduced in the DNA-histone-nonhistone complex. These include a large decrease in ellipticity at 260-300 nm, a red-shift of the crossover point at around 260 nm, and a slight negative band at around 305 nm. Also, DNA in this complex is thermally stabilised to the extent comparable with DNA in the native chromatin. 5. Addition of nonhistone proteins to the preformed DNA-histone complex in 3 M urea renders a half of the complex, named DNA-histone(-nonhistone), unprecipitable upon centrifugation at 20 000 X g in 0.14 M NaCl. CD spectrum and thermal melting profile of the precipitable DNA-histone(-nonhistone) complex are similar to those of the DNA-histone-nonhistone complex, while in the unprecipitable DNA-histone(-nonhistone) comples, the ellipticity at 260-300 nm is significantly elevated and the highest melting transition (at 80 degrees C) is lacking. 6. The CD spectrum of native cerebral chromatin closely resembles that of unprecipitable DNA-histone(-nonhistone) complex, while in liver chromatin, the spec.trum is an intermediate between those of the unprecipitable and pn of chromatin by nonhistone proteins. Cerebral nonhistone proteins bind to DNA and to the DNA-histone complex more extensively than liver nonhistone proteins. 7. It is concluded that, although the basic conformation of DNA in native chromatin is determined largely by histones, nonhistone proteins also play an individual role. There is also an indication that nonhistone proteins exert an organ-specific modification of chromatin superstructure.     

Properties of the genome in experimental hepatomas: variations in the composition of chromatin

The chromosomal proteins of two rapidly growing and poorly differentiated Morris hepatomas were compared with those of liver from normal and tumor bearing animals. While the total quantity of histone associated with DNA in all tumor and liver chromatin preparations studied were similar, tumor chromatin contained an increased quantity of nonhistone chromosomal proteins. Variations in specific classes of histones and nonhistone chromosomal proteins associated with the genome of the two tumors, host liver and liver of tumor bearing animals were observed.     

Properties of the genome in normal and SV-40 transformed WI-38 human diploid fibroblasts. III. Turnover of nonhisone chromosomal proteins and their phosphate groups.

The turnover of nonhistone chromosomal proteins and their phosphate groups was compared in normal and in SV-40 virus transformed WI-38 human diploid fibroblasts. Cells were pulse labelled with tryptophan-³H and ³²P for 30 minutes and the specific activities of tryptophan-³H and ³²P in the various molecular weight classes of nonhistone chromosomal proteins were determined during the first four hours following termination of labelling. While a rapid turnover of high molecular weight nonhistone polypeptides (142, 000 to 200, 000 Daltons) is evident after one hour in SV_40 transformed cells, the specific activities of these nonhistone chromosomal polypeptides are not significantly decreased in normal cells. In contrast, a rapid turnover of low molecular weight (30, 000 to 51, 000 Daltons) nonhistone chromosomal proteins occurs during the first hour in normal WI-38 cells with no corresponding decrease in the specific activities of these proteins in SV-40 transformed cells. There is no apparent net turnover of phosphate groups on nonhistone chromosomal proteins in either normal or SV-40 transformed cells four hours following pulse labelling. Rather, during the first four hours significant fluctuations are observed in the ³²P specific activities of defined molecular weight fractions. Taken together with previous reports of differences in the composition, synthesis and phosphorylation of nonhistone chromosomal proteins in normal and SV-40 transformed human diploid cells the present results further indicate the complex nature of the alterations in these proteins which accompany viral transformation.     

Role of nonhistone proteins in metaphase chromosome structure

In this paper, we show that HeLa metaphase chromosomes still possess a highly organized structure retaining the familiar metaphase morphology following removal of virtually all the histones and most of the nonhistone proteins. The structure is stabilized by a relatively small number of nonhistones, which we call scaffolding proteins.These results are based on a method which allows the removal of the histones, and most of the nonhistone proteins, by competition with polyanions such as dextran sulfate and heparin.The histone-depleted chromosomes sediment in sucrose gradients as a broad peak between 4000 to 7000S. These structures are dissociated by mild trypsin or chymotrypsin treatment, or by 4 M urea, but are stable in 2 M NaCl and insensitive to treatment with RNAase A. The histone-depleted chromosomes have a DNA to protein ratio of about 6:1; gel electrophoresis reveals the presence of about 30 nonhistone proteins and the virtual absence of histones. These experiments suggest that nonhistone proteins exist in metaphase chromosomes which maintain the DNA chain in a highly folded conformation.Structural studies support this conclusion. Analysis by fluorescence microscopy of histone-depleted chromosomes stained with ethidium bromide shows that each chromatid is still paired with its sister chromatid, and consists of a central structure surrounded by a halo of DNA. The length of the central structure in each chromatid is about 2–3 times longer than the chromatid length in the original chromosome.     

The occurrence of extended acidic sequences in nonhistone chromosomal proteins

Nonhistone chromosomal proteins and soluble cytoplasmic proteins from rat liver were treated with a combination of proteases and chemical reagents which split a variety of peptide bonds but do not attack sequences consisting predominantly or exclusively of acidic amino acid residues. Analysis of the resulting digests by gel filtration chromatography and column electrophoresis demonstrated that, relative to cytoplasmic proteins, nonhistone chromosomal proteins are rich in highly charged, acidic peptides up to 12 residues in length, but rarely contain very long peptides consisting exclusively of acidic residues such as are found in the nonhistone chromosomal proteins HMG1 and HMG2.     

Partial purification and properties of a chromatin-associated phosphoprotein kinase from rat liver nuclei.

A phosphoprotein kinase (EC 2.7.1.37) KIVb, from rat liver nuclei, was purified 75-fold by phosphocellulose chromatography and gel filtration on Sephadex G-200. The enzyme, which has an apparent molecular weight of 55 000, phosphorylates casein and chromatin-bound nonhistone proteins more readily than histones or ribosomal proteins. It exhibits an absolute requirement for divalent cation with optimum activity at 15--20 mM Mg2+. Maximal kinase activity is achieved at 100 mM NaCl. The pH vs. activity curve is biphasic with optima at pH 6.5 and pH 8.0. The Km value for casein is 280 mug/ml and the Km for ATP is 6-10(-6) M. Kinase KIVb phosphorylates numerous nonhistone nuclear proteins as shown by electrophoretic analysis. The addition of kinase KIVb to reaction mixtures containing nonhistone proteins results in the phosphorylation of a spectrum of polypeptides similar to those that are phosphorylated by endogenous nuclear kinases. Nonhistone proteins bound to chromatin appear to be better substrates for KIVb than nonhistones dissociated from chromatin. A comparison of nuclear phosphoproteins phosphorylated either in the intact animal or in vitro (by the addition of kinase KIVb) indicates some differences and some similarities in the patterns of phosphorylation.