Immature Chicken Erythrocytes Research Articles

Dynamically Acetylated Histone Association with Transcriptionally Active and Competent Genes in the Avian Adult β-Globin Gene Domain

In chicken immature erythrocytes, class 1 acetylated histones are rapidly tri- and tetra-acetylated and rapidly deacetylated. Class 2 acetylated H3 and H4 are rapidly acetylated to mono- and di-acetylated isoforms and slowly deacetylated. Our previous studies suggested that class 1 acetylated histones were primarily associated with transcriptionally active DNA (beta(A)-globin) but not competent DNA (epsilon-globin). Chromatin salt solubility (chromatin fiber oligomerization) is directly influenced by hyperacetylation. In this study we investigated the association of class 1 histones with beta(A)- and epsilon-globin DNA by measuring their loss of solubility rates in 150 mm NaCl and 3 mm MgCl(2) as a function of hyperacetylated histone deacetylation. Expressed and competent chromatin was associated with class 1 acetylated histones. As most active chromatin and hyperacetylated histones are associated with the low salt-insoluble residual nuclear material containing the nuclear matrix, we investigated whether hyperacetylated histones are bound to the beta(A)- and epsilon-globin DNA in this fraction. In chromatin immunoprecipitation assays, we found that the beta(A)- and epsilon-globin coding regions are bound to hyperacetylated H3 and H4. Our observations are consistent with a model in which nuclear matrix-associated histone acetyltransferases and deacetylases mediate a dynamic attachment between active and competent chromatin and the nuclear matrix.

A comparative study of histone deacetylases of plant, fungal and vertebrate cells

The enzymatic equilibrium of reversible core histone acetylation is maintained by two enzyme activities, histone acetyltransferase and histone deacetylase (HD). These enzyme activities exist as multiple enzyme forms. The present report describes methods to extract different HD-forms from three: organisms, germinating maize embryos, the myxomycete Physarum polycephalum, and chicken red blood cells; it provides data on the chromatographic separation and partial purification of HD-forms. In germinating maize embryos three HDs (HD1-A, HD1-B, HD2) can be discriminated; HD1-A, HD1-B, and HD2 were characterized in terms of their dependence on pH, temperature and various ions, as well as kinetic parameters ( k M, for core histones) and inhibition by various compounds. The same parameters were investigated for the corresponding enzymes of Physarum polycephalum, and mature and immature chicken erythrocytes. Based on these results, optimum assay conditions were established for the different enzyme forms. The kinetic data revealed that the maize histone deacetylase HD 1-B peak after partial purification by Q-Sepharose chromatography was heterogeneous and consisted of two histone binding sites that differed significantly in their affinity for purified core histones. Optimized affinity chromatography on poly-Lysine Agarose indeed showed that the former defined deacetylase HD 1-B can be separated clearly into two individual HD enzyme forms. The high multiplicity of histone deacetylases underlines the importance of these enzymes for the complex regulation of core histone acetylation.

Properties of chicken erythrocyte histone deacetylase associated with the nuclear matrix

Histone H2B is deacetylated more rapidly than H3 and H4 in chicken immature erythrocytes. Histone deacetylase from chicken immature erythrocytes was partially purified, and the histone specificities of the multiple histone deacetylase forms were determined. Ion-exchange (Q-Sepharose) and gel-exclusion (Superdex 200) chromatography of extracts from erythrocyte nuclei showed two forms (HD1 and HD2) of histone deacetylase. HD1, with a molecular mass of about 55 kDa, preferred free H3-H4 relative to H2A-H2B, while HD2, with a molecular mass of approx. 220 kDa, had a slight preference for H3-H4. HD1 and HD2 differed in pH- and ion-strength-dependence. HD2 dissociated into HD1 when treated with 1.6 M NaCl or when applied to a Q-Sepharose column. The enzymic properties of nuclear-matrix-bound histone deacetylase showed a striking difference from that of HD1 and HD2, particularly in its strong preference for H2A-H2B. Treatment of the nuclear matrix with 1.6 M NaCl and 1% 2-mercaptoethanol solubilized histone deacetylase which chromatographed as 400 and 220 kDa forms on a Superdex 200 column. The solubilized enzyme retained its histone preference for H2A-H2B. Chromatography of the nuclear-matrix-derived enzyme on Q-Sepharose yielded one peak of enzyme activity with chromatographic properties and histone specificities similar to those of HD1. These results provide support for the active form of the enzyme in situ being a high-molecular mass complex associated with proteins that are components of the nuclear matrix. Substrate preference of the enzyme is governed by the proteins associated with the histone deacetylase.

Acetylation and methylation of histones H3 and H4 in chicken immature erythrocytes are not directly coupled

The relationship between histone methylation and dynamic histone acetylation was investigated. Previously, we demonstrated in chicken erythrocytes that dynamically acetylated histones H3 and H4 of transcriptionally active gene chromatin were selectively methylated. However, methylation of these histones was not dependent upon their acetylated states. Here, we tested the hypothesis that methylation tags these histones for participation in dynamic acetylation. Using an inhibitor of protein methylation, adenosine dialdehyde, we show that the processes of histone methylation and dynamic acetylation are not directly coupled. Our results suggest that the selective methylation of dynamically acetylated chromatin reflects features of the organization of transcriptionally active gene chromatin.

Multisubunit erythroid complexes binding to the enhancer element of the chicken histone H5 gene.

We identified the factor(s) that bind to the chicken erythroid-cell-specific histone H5 enhancer region which is located on the 3' end of the gene. In DNAase I footprinting and u.v. cross-linking experiments with nuclear extracts from adult chicken immature erythrocytes, we determined that the trans-acting factor GATA-1 was the predominating protein interacting with the histone H5 enhancer. GATA-2 and GATA-3 were not detected. In contrast, gel-mobility-shift assays and competition experiments demonstrated that several specific complexes formed with the histone H5 enhancer region. Gel-mobility-shift assays with 23 bp oligonucleotides containing the GATA-binding site (AGATAA) of the histone H5 enhancer or of the beta-globin enhancer showed that the GATA sequence was sufficient for the formation of at least five complexes. Diagonal mobility-shift assays demonstrated that multisubunit complexes were forming with the GATA-1 protein. Our interpretation of the results is that GATA-1 interacts with a protein of approx. 105 kDa which, in turn, can associate with protein or protein complexes of approx. 26 kDa, 146 kDa and a protein(s) of molecular mass greater than 450 kDa. The different multisubunit complexes formed via the trans-acting factor GATA-1 may impart different transcriptional responses to the promoter and enhancer elements of the histone H5 and globin genes.

Histone deacetylase is a component of the internal nuclear matrix.

In chicken immature erythrocytes, approximately 4% of the modifiable histone lysine sites participate in active acetylation. There are two categories of actively acetylated histone H4. Although both are acetylated at the same rate (t1/2 = 12 min), one is acetylated to the tetraacetylated form and is rapidly deacetylated (class 1), and the other is acetylated to mono- and diacetylated forms and is slowly deacetylated (class 2). We show that the chromatin distribution of the class 1 labeled tetraacetylated H4 species paralleled that of the transcriptionally active DNA sequences. For example, the chromatin fragments of the insoluble nuclear material contained 76% of the active DNA and 74% of the labeled tetraacetylated H4. Class 2 labeled acetylated H4 species were found in repressed chromatin and were enriched in active/competent gene-enriched chromatin fragments. The majority of the histone deacetylase activity (75-80%) was located with the insoluble residual nuclear material. Further, approximately 40-50% of the enzyme activity was associated with nuclear matrices prepared by two methods using high salt and intermediate/high salt extraction. Histone deacetylase was solubilized by extracting the nuclear matrices with high salt and 2-mercaptoethanol, a procedure that generates nuclear pore-lamina complexes. These results demonstrate that histone deacetylase is a component of the internal nuclear matrix.

Dynamically acetylated histones of chicken erythrocytes are selectively methylated

The relationship between histone acetylation and methylation in chicken immature erythrocytes was investigated. Previous studies have shown that transcriptionally active/competent gene-enriched chromatin fragments are enriched in newly methylated histones H3 and H4. Moreover, newly methylated histone H4 is hyperacetylated. Here, we show that dynamically acetylated histone H4 is selectively engaged in ongoing methylation. While sodium butyrate (an inhibitor of histone deacetylase) does not inhibit ongoing histone methylation, it does affect the acetylation state of newly methylated histone H4 when chicken immature erythrocytes are incubated in its presence or absence. Only one rate of acetylation of labelled newly methylated unacetylated histone H4 with a t1/2 of 8 min is observed. Previous studies have shown that the solubility of transcriptionally active/competent gene chromatin fragments in 0.15 M-NaCl is dependent upon the level of acetylated histone species, with induction of hyperacetylation increasing the solubility of this gene chromatin. Here, we show that the low salt solubility of chromatin fragments associated with newly methylated histones H3 and H4 is also dependent upon the level of acetylated histones. These results provide further support for the hypothesis that histones participating in ongoing methylation are associated with transcriptionally active/competent chromatin and suggest that the processes of histone H4 methylation and dynamic acetylation are partially coupled in terminally differentiated erythrocytes.

Nucleosomal histones of transcriptionally active/competent chromatin preferentially exchange with newly synthesized histones in quiescent chicken erythrocytes

The incorporation of newly synthesized histones among various chromatin fraction isolated from non-replicating cell-cycle-phase-Go chicken immature erythrocytes was investigated. We find that newly synthesized erythroid-specific histone Hl variant H5, is incorporated randomly into chromatin. In contrast, newly synthesized nucleosomal histones H2A, H2A.Z, H2B, H3.3, and H4 are preferentially found in a fraction that is highly enriched in active/competent gene chromatin fragments and depleted in repressed gene chromatin. Moreover, ubiquitinated species of histones H2A and H2B and hyperacetylated species of H4 and H2B, which are complexed to active DNA, are labelled. These observations provide evidence that newly synthesized histones preferentially exchange with the nucleosomal histones of transcriptionally active/component chromatin domains. The results of this study suggest that nucleosomes of active chromatin may be inherently less stable than bulk nucleosomes in vivo and have implications for chromatin remodelling.

Distribution of methylated histones and histone methyltransferases in chicken erythrocyte chromatin

The relationship between histone methylation and the transcriptionally active chromatin state was investigated. Immature chicken erythrocytes, which were obtained from the peripheral blood of anemic birds, were incubated with L-[methyl-3H]methionine and cycloheximide. Under these conditions histones H3 and H4 are methylated. The erythrocyte nuclei were incubated with micrococcal nuclease, and the chromatin fragments were fractionated according to their solubility in EDTA and 0.15 M NaCl. Chromatin fractions, which were enriched in transcriptionally active genes, were enriched in methylated histones. Moreover, the acetylated species of histones H3 and H4, which are complexed with active genes (Hebbes, T. R., Thorne, A. W., and Crane-Robinson, C. (1988) EMBO J. 7, 1395-1402), were preferentially methylated. The methylation of these histones was not dependent on ongoing transcription. The distribution of histone H3 methyltransferase activity among the various chromatin regions was also studied. This enzyme activity was greatest for the chromatin fragments that were enriched in active/competent genes. However, our results suggest that histone H3 methyltransferase is bound to the nucleosome. The enzyme, which may be localized in the active gene chromatin domains, may ensure that the histones associated with active genes are methylated. Histone methylation, which has a slow turnover rate, may contribute to the maintenance of the transcriptionally active chromatin state.

Chromatin structure of erythroid-specific genes of immature and mature chicken erythrocytes.

The beta-globin and histone H5 genes are transcriptionally active in immature chicken erythrocytes and potentially active in mature erythrocytes. In both immature and mature erythrocytes, the majority of these erythroid-specific gene sequences are located in two chromatin fractions: the low-salt-insoluble residual nuclear material and the 0.15 M-NaCl-soluble oligo- and poly-nucleosomes. These salt-soluble chromatin fragments are enriched in hyperacetylated species of H4 and H2B, ubiquitinated and polyubiquitinated species of H2A and H2B and are depleted of linker histones H1 and H5. The competent, transcriptionally inactive embryonic epsilon-globin gene, which is part of the DNAase I-sensitive beta-globin domain, is highly enriched in the 0.15 M-NaCl-soluble polynucleosome fraction but not in the insoluble nuclear material. The repressed vitellogenin gene shows no enrichment in either of these fractions. These results suggest that only those genes that are expressed or have the potential for expression are enriched in the low-salt-insoluble nuclear material of immature or mature erythrocytes. The enrichment of active genes in the low-salt-insoluble residual nuclear material of immature erythrocytes is not dependent on on-going transcription, the presence of RNA or changes in the amount of acetylated histone species. Our results are consistent with the hypothesis that active and potentially active genes are insoluble because of the presence of preinitiation transcription complexes.

Mismatch and blunt to protruding-end joining by DNA ligases.

A nuclear DNA ligase activity from immature chicken erythrocytes, and to a lesser extent T4-induced DNA ligase, can join cohesive-ends (3 and 5-nucleotides long) having one of the mismatches, A/A, T/T, C/C, G/G, at the middle position. The rate of ligation depends on the length and stability of the mispaired intermediate (G/G, T/T greater than A/A, C/C). When the non-complementary overhanging-ends are short (i.e. 1-nucleotide) both ligases catalyze the joining of the single-stranded protruding-end with a blunt-end. This reaction occurs at low but significant rates compared to blunt-end ligation. The chicken ligase has lower flush-end joining activity than T4 DNA ligase, but it is more permissive since it joins C/C or A/A mismatched-ends, whereas the prokaryotic ligase does not. Possible biological implications of the reactions are discussed. We have also found that BstEII easily cleaves at sites harboring a C/C or a G/G mismatch at the center of its recognition sequence, whereas AvaII (T/T or A/A), HinfI (G/G) and DdeI (G/G) do not.

The beta-globin domain in immature chicken erythrocytes: enhanced solubility is coincident with histone hyperacetylation.

A 60 minute exposure of chicken immature erythrocytes to n-butyrate shifts actively acetylated and deacetylated histones to hypermodified forms. Micrococcal nuclease digestion of nuclei from n-butyrate treated cells and subsequent fractionation of the chromatin releases 40-45% of the adult beta-globin (beta A) nucleohistone into a soluble fraction. This is an eleven fold enrichment over the soluble chromatin from untreated cells (Ferenz and Nelson (1985) Nucleic Acids Res. 13, 1977-1995). The enhanced beta A chromatin solubility and induced histone hyperacetylation are coincident. Removal of n-butyrate from the cell incubation medium allows rapid histone deacetylation and a striking reduction in beta A chromatin solubility. Chromatin from cells incubated in the absence of n-butyrate, or in medium containing 10 mM NaCl or 2% dimethylsulfoxide, does not exhibit histone hyperacetylation, or the acquired solubility of beta A chromatin. We show that the H4 histone co-isolated with the beta A DNA is in a hyperacetylated state and present evidence that the n-butyrate incubation increases the solubility of both coding and noncoding chromatin regions in the beta-globin domain.

N-Butyrate incubation of immature chicken erythrocytes preferentially enhances the solubility of beta A chromatin.

The solubility of adult beta-globin chromatin (beta A chromatin) from immature chicken red blood cells can be controlled by the presence or absence of n-butyrate in a cell incubation medium. In the absence of n-butyrate, only a small percentage (approximately 4%) of the total beta A chromatin is in a soluble chromatin fraction following micrococcal nuclease digestion and centrifugation. This percentage increases to approximately 40-45% of the beta A chromatin if cells are incubated 1 hour in the presence of 10 mM sodium n-butyrate. The highest yield and enrichment of solubilized beta A chromatin is attained when 1-4% of the DNA is rendered acid soluble, and in buffers containing 1.5 - 5 mM MgCl2. The soluble beta A nucleohistone is nucleosome oligomer size (contains DNA 250-600 bases in length) and can be separated from soluble, transcriptionally inert mononucleosomes by agarose A-5m exclusion chromatography. The enhanced solubility appears to be specific for transcriptionally active chromatin. Whereas 40-45% of the beta A chromatin is recovered in the supernatant fraction from n-butyrate incubated immature erythrocytes, nucleohistone containing ovalbumin DNA sequences remains insoluble.

An improved method for the preparation of undegraded polysomes and active messenger RNA from immature chicken erythrocytes

A simple method for the large-scale isolation of undegraded polysomes and active mRNA from immature hen erythrocytes is described. The method is based on the removal of white cells from heparinized blood by adsorption on sulfoethyl- or sulfopropyl-Sephadex. Red cells thus purified can be stored frozen and lysed in the presence of nonionic detergents. The yield of polysomes is about twice that obtained by the usual mild lysis procedures designed to prevent lysis of lysosomes from contaminating white cells.

The product of ribosome-associated RNA-dependent RNA polymerase in immature chicken erythrocytes

The radioactively labelled product obtained after incubation of chicken erythrocyte ribosomes with [ 3H]-UTP was shown by sucrose density gradient centrifugation to have a sedimentation coefficient of 4–5S; the ratio of UMP to uridine incorporated was 6.09. The product synthesized and isolated after incubation of intact cells in the presence of [ 3H]-uridine and actinomycin D was shown to be very similar with respect to sedimentation coefficient and the ratio of UMP/uridine incorporated, providing for the first time evidence of a ribosome-associated terminal ribonucleotidyl-transferase activity in intact cells.

Direct evidence that ribosome bound RNA-dependent RNA polymerase does not play a role in globin messenger RNA replication.

The radioactively labelled product of RNA-dependent RNA polymerase+ from ribosomes of immature chicken erythrocytes was tested for the presence of newly replicated globin mRNA using unlabelled globin complementary DNA. No radioactively labelled globin mRNA sequences were found in the product, providing direct confirmation that this RNA-dependent RNA polymerase is not involved in globin mRNA amplification.

Ribosome bound RNA-dependent RNA polymerase: Changes in total and specific activity during maturation of avian erythrocytes

Ribosome bound RNA-dependent RNA polymerase activity from immature chicken erythrocytes was shown to be predominantly primer-dependent, in contrast to the template-dependent synthesis demonstrated by previous workers (4). During the maturation of the immature avian erythrocyte, the total and specific activities of this ribosome bound enzyme preparation increase 40 and 9.4 times respectively.

The role of newly synthesized RNA on nuclear histone synthesis by chicken immature erythrocytes

Chicken reticulocytes in vitro synthesize hemoglobin, nuclear ribonucleic acid, and nuclear proteins including histones. Inhibition of nuclear ribonucleic acid synthesis occurred promptly after administration of actinomycin D or 5,6-dichloro-l-β- d-ribofuranosylbenzimidazole and was followed by a rapid decrease in the rate of synthesis of certain nuclear proteins, particularly histones. The rate of synthesis of the hemoglobin fraction, which comprised the major bulk of cellular protein, was not affected by the inhibitors. The histone fractions demonstrating the greatest degree of biosynthetic suppression after inhibition of RNA synthesis were fractions f 1 (the “lysinerich” histone) and f 2b. These fractions were synthesized at less than 50 per cent of the rate of controls within 20 min after inhibition of RNA synthesis. These results suggest that the synthesis of specific histones may be under precise control in the reticulocyte nucleus through the mediation of newlyformed nuclear ribonucleic acid.