ADP-ribosylated histone H1 from HeLa cultures. Fundamental differences to (ADP-ribose)n-histone H1 conjugates formed into vitro

Poly-ADP ribosylation in DNA damage response and cancer therapy

Poly(ADP-ribosyl)ation (aka PARylation) is a unique protein post-translational modification (PTM) first described over 50 years ago. PARylation regulates a number of biological processes including chromatin remodeling, the DNA damage response (DDR), transcription, apoptosis, and mitosis. The subsequent discovery of poly(ADP-ribose) polymerase-1 (PARP-1) catalyzing DNA-dependent PARylation spearheaded the field of DDR. The expanding knowledge about the poly ADP-ribose (PAR) recognition domains prompted the discovery of novel DDR factors and revealed crosstalk with other protein PTMs including phosphorylation, ubiquitination, methylation and acetylation. In this review, we highlight the current knowledge on PAR-regulated DDR, PAR recognition domain, and PARP inhibition in cancer therapy.

Cell fate regulation by chromatin ADP-ribosylation

ADP-ribosylation is an evolutionarily conserved complex posttranslational modification that alters protein function and/or interaction. Intracellularly, it is mainly catalyzed by diphtheria toxin-like ADP-ribosyltransferases (ARTDs), which attach one or several ADP-ribose residues onto target proteins. Several specific mono- and poly-ADP-ribosylation binding modules exist; hydrolases reverse the modification. The best-characterized ARTD family member, ARTD1, regulates various DNA-associated processes. Here, we focus on the role of ARTD1-mediated chromatin ADP-ribosylation in development, differentiation, and pluripotency, and the recent development of new methodologies that will enable more insight into these processes.

Nuclear ADP-Ribosylation and Its Role in Chromatin Plasticity, Cell Differentiation, and Epigenetics

Protein ADP-ribosylation is an ancient posttranslational modification with high biochemical complexity. It alters the function of modified proteins or provides a scaffold for the recruitment of other proteins and thus regulates several cellular processes. ADP-ribosylation is governed by ADP-ribosyltransferases and a subclass of sirtuins (writers), is sensed by proteins that contain binding modules (readers) that recognize specific parts of the ADP-ribosyl posttranslational modification, and is removed by ADP-ribosylhydrolases (erasers). The large amount of experimental data generated and technical progress made in the last decade have significantly advanced our knowledge of the function of ADP-ribosylation at the molecular level. This review summarizes the current knowledge of nuclear ADP-ribosylation reactions and their role in chromatin plasticity, cell differentiation, and epigenetics and discusses current progress and future perspectives.

The role of ADP-ribosylation in regulating DNA double-strand break repair

ADP-ribosylation is the post translational modification of proteins catalysed by ADP-ribosyltransferases (ARTs). ADP-ribosylation has been implicated in a wide variety of cellular processes including cell growth and differentiation, apoptosis and transcriptional regulation. Perhaps the best characterised role, however, is in DNA repair and genome stability where ADP-ribosylation promotes resolution of DNA single strand breaks. Although ADP-ribosylation also occurs at DNA double strand breaks (DSBs), which ARTs catalyse this reaction and the molecular basis of how this modification regulates their repair remains a matter of debate. Here we review recent advances in our understanding of how ADP-ribosylation regulates DSB repair. Specifically, we highlight studies using the genetic model organism Dictyostelium, in addition to vertebrate cells that identify a third ART that accelerates DSB repair by non-homologous end-joining through promoting the interaction of repair factors with DNA lesions. The implications of these data with regards to how ADP-ribosylation regulates DNA repair and genome stability are discussed.

Histone ADP-ribosylation in DNA repair, replication and transcription

Most published work on post-translational histone modifications focuses on small covalent alterations such as acetylation, methylation and phosphorylation. By contrast, fewer data are available on the modification of histones by ADP-ribose. Discussion of the biological significance of histone ADP-ribosylation has often been restricted to functions of the modifying enzymes, rather than to histones as ADP-ribose acceptors. In particular, the identification of specific lysine residues as ADP-ribose acceptor sites in histones and the identification of ADP-ribose binding modules raise this modification to a par with acetylation, methylation or phosphorylation. We discuss here the functional aspects of histone ADP-ribosylation and its influence on DNA repair, replication and transcription.

ADP-ribosylation of histones by ARTD1: an additional module of the histone code?

ADP-ribosylation is a covalent post-translational protein modification catalyzed by ADP-ribosyltransferases and is involved in important processes such as cell cycle regulation, DNA damage response, replication or transcription. Histones are ADP-ribosylated by ADP-ribosyltransferase diphtheria toxin-like 1 at specific amino acid residues, in particular lysines, of the histones tails. Specific ADP-ribosyl hydrolases and poly-ADP-ribose glucohydrolases degrade the ADP-ribose polymers. The ADP-ribose modification is read by zinc finger motifs or macrodomains, which then regulate chromatin structure and transcription. Thus, histone ADP-ribosylation may be considered an additional component of the histone code.

PARP1 ADP-ribosylates lysine residues of the core histone tails

The chromatin-associated enzyme PARP1 has previously been suggested to ADP-ribosylate histones, but the specific ADP-ribose acceptor sites have remained enigmatic. Here, we show that PARP1 covalently ADP-ribosylates the amino-terminal histone tails of all core histones. Using biochemical tools and novel electron transfer dissociation mass spectrometric protocols, we identify for the first time K13 of H2A, K30 of H2B, K27 and K37 of H3, as well as K16 of H4 as ADP-ribose acceptor sites. Multiple explicit water molecular dynamics simulations of the H4 tail peptide into the catalytic cleft of PARP1 indicate that two stable intermolecular salt bridges hold the peptide in an orientation that allows K16 ADP-ribosylation. Consistent with a functional cross-talk between ADP-ribosylation and other histone tail modifications, acetylation of H4K16 inhibits ADP-ribosylation by PARP1. Taken together, our computational and experimental results provide strong evidence that PARP1 modifies important regulatory lysines of the core histone tails.

APLF (C2orf13) is a novel component of poly(ADP-ribose) signaling in mammalian cells

APLF is a novel protein of unknown function that accumulates at sites of chromosomal DNA strand breakage via forkhead-associated (FHA) domain-mediated interactions with XRCC1 and XRCC4. APLF can also accumulate at sites of chromosomal DNA strand breaks independently of the FHA domain via an unidentified mechanism that requires a highly conserved C-terminal tandem zinc finger domain. Here, we show that the zinc finger domain binds tightly to poly(ADP-ribose), a polymeric posttranslational modification synthesized transiently at sites of chromosomal damage to accelerate DNA strand break repair reactions. Protein poly(ADP-ribosyl)ation is tightly regulated and defects in either its synthesis or degradation slow global rates of chromosomal single-strand break repair. Interestingly, APLF negatively affects poly(ADP-ribosyl)ation in vitro, and this activity is dependent on its capacity to bind the polymer. In addition, transient overexpression in human A549 cells of full-length APLF or a C-terminal fragment encoding the tandem zinc finger domain greatly suppresses the appearance of poly(ADP-ribose), in a zinc finger-dependent manner. We conclude that APLF can accumulate at sites of chromosomal damage via zinc finger-mediated binding to poly(ADP-ribose) and is a novel component of poly(ADP-ribose) signaling in mammalian cells.

A cellular defense pathway regulating transcription through poly(ADP-ribosyl)ation in response to DNA damage

DNA damage is known to trigger key cellular defense pathways such as those involved in DNA repair. Here we provide evidence for a previously unrecognized pathway regulating transcription in response to DNA damage and show that this regulation is mediated by the abundant nuclear enzyme poly(ADP-ribose) polymerase. We found that poly(ADP-ribose) polymerase reduced the rate of transcription elongation by RNA polymerase II, suggesting that poly(ADP-ribose) polymerase negatively regulates transcription, possibly through the formation of poly(ADP-ribose) polymerase-RNA complexes. In damaged cells, poly(ADP-ribose) polymerase binds to DNA breaks and automodifies itself in the presence of NAD(+), resulting in poly(ADP-ribose) polymerase inactivation. We found that automodification of poly(ADP-ribose) polymerase in response to DNA damage resulted in the up-regulation of transcription, presumably because automodified poly(ADP-ribose) polymerase molecules were released from transcripts, thereby relieving the block on transcription. Because agents that damage DNA damage RNA as well, up-regulation of RNA synthesis in response to DNA damage may provide cells with a mechanism to compensate for the loss of damaged transcripts and may be critical for cell survival after exposure to DNA-damaging agents.

Structure of active chromatin: covalent modifications of histones in active and inactive genes of control and hypothyroid rat liver

Covalent modifications of histones in active and bulk chromatin fractions were studied in liver tissue from control and hypothyroid rats. The levels of acetylation and ubiquitination of histones were similar in the active and bulk chromatin fractions, and were not influenced by hypothyroidism. Histone H2A only was phosphorylated in control active and bulk chromatin fractions. The extent of this phosphorylation did not differ between the two fractions, but hypothyroidism greatly suppressed it. Indicating an association with tissue growth. ADP-ribosylation of histones was found to be mainly associated with transcriptional inactivation of the chromatin, while histone methylation was correlated with growth inhibition of the tissue, as observed with hypothyroidism. The validity of these conclusions will, however, depend upon the similarity of the turnover rates of these covalent modifications between active and inactive chromatin and between control and hypothyroid states.

Co-operative interactions of oligonucleosomal DNA with the H1e histone variant and its poly(ADP-ribosyl)ated isoform

H1 histone somatic variants from L929 mouse fibroblasts were purified by reverse-phase HPLC. We analysed the ability of each H1 histone variant to allow the H1-H1 interactions that are essential for the formation of the higher levels of chromatin structure, and we investigated the role played by the poly(ADP-ribosyl)ation process. Cross-linking analysis showed that H1e is the only somatic variant which, when bound to DNA, is able to produce H1-H1 polymers; the size of polymers was decreased when H1e was enriched in its poly(ADP-ribosyl)ated isoform. Measurement of the methyl-accepting ability in native nuclei compared with nuclei in which poly(ADP-ribosyl)ation was induced showed that the poly(ADP-ribosyl)ated H1 histone had not been removed from linker regions, in spite of its different interaction with DNA.

Poly(ADP-ribose) polymerase inhibits DNA synthesis initiation in the absence of NAD

Poly(ADP-ribose) polymerase (ADPRP) is a nuclear enzyme that transfers ADP-ribose from NAD+ to diverse nuclear proteins. Previously, the function of ADPRP was considered to relate exclusively to its catalytic activity. However, recent experiments have shown that ADPRP is actually an abundant DNA-binding protein, and that the potential catalytic activity of the enzyme is more than 100-fold greater than the measured rates of NAD+ turnover in intact cells. To better understand the role of ADPRP, we have used highly purified ADPRP and a monospecific autoantibody to examine the effects of ADPRP on in vitro DNA synthesis in the presence or absence of NAD+ substrate. The data show that DNA synthesis initiation is blocked by ADPRP and that auto-poly (ADP-ribosyl)ation reverses the process by diminishing the DNA binding capacity of the protein. These results suggest that ADPRP actually is a structural DNA binding protein, whose catalytic activity serves to modulate its interaction with DNA.

Factors influencing ADP-ribosylation differences between chromosomal proteins of interphase and metaphase HeLa cells

Fundamental differences were previously discovered in the ADP-ribosylation of proteins from metaphase chromosomes and interphase nuclei of HeLa cells. The number of modified nonhistone species was found to be dramatically reduced for metaphase chromosomes. An investigation has therefore been made of factors which could influence, and therefore be responsible for, this change in ADP-ribosylation during the cell cycle. Modified proteins were detected by autoradiography of sodium dodecyl sulfate-polyacrylamide gels containing mitotic and interphase samples from permeabilized cells that had been incubated with [32P]NAD. Whole cells showed a difference between interphase and metaphase similar to that for isolated nuclei and chromosomes. Chromosome expansion, disruption of chromosomes or nuclei, DNA nicking, and cellular growth activity significantly changed the incorporation of 32P label. Inhibitors of protein, RNA, and DNA synthesis did not, however, greatly affect ADP-ribosylation. The pattern of labeled species was not altered by the presence of nonradioactive NAD, though the extent of labeling declined. The results were not artifactually due to the procedure used to arrest cells in mitosis. Similar results were found with Novikoff rat hepatoma cells, demonstrating that the difference between metaphase and interphase is not confined to HeLa cells.

Degradation of (ADP-ribose)n in permeabilized HeLa cells

Determination of (ADP-ribose)n degradation rates in permeabilized HeLa cells, measured as loss of acid-insoluble radioactivity from permeabilized cells previously incubated with [3H]NAD+, showed bi-phasic kinetics. The majority of label was lost within 20 min at pH 6.0 and 37 degrees C and has a half-life of about 12-15 min. The minor ADP-ribose component was either removed very slowly, or appeared to be stable over an 80 min incubation. The degradation rate of the labile component was directly proportional to the initial amount of ADP-ribose present, and was independent of the experimental conditions used to create various elevated levels. The degradation rates of monomeric and oligo/polymeric ADP-ribose were the same, surprising since different enzymes catalyse the respective reactions. The more stable ADP-ribose component could be more inaccessible to degrading enzymes and/or might represent a different linkage to protein, the cleavage of which is slow.

Poly(ADP-ribosyl)ation studies in situ

We have studied the poly(ADP-ribosyl)ation of nuclear proteins in situ by examining the incorporation of [3H]NAD-derived ADP-ribose into polymers. We have devised a way to deliver [3H]NAD to cells growing in vitro, and we have determined the kinetics of uptake and incorporation into nuclear proteins using this delivery system. Incorporation into the histone fraction, known acceptors of poly(ADP-ribose), was examined and shown to be sensitive to the poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide. Polyacrylamide gel electrophoresis of 3H-labeled proteins revealed radioactivity associated with known poly(ADP-ribose)-accepting proteins such as poly(ADP-ribose) polymerase and histones. These results were confirmed when we immunoreacted gel-separated proteins with anti-(ADP-ribose) generated in our laboratory.

Amino-acid-transfer reactions in isolated nuclei of Ehrlich ascites tumor cells

Nuclear enzymatic activities incorporating amino acids into acid-insoluble material were investigated with respect to their differentiation from protein biosynthesis, reaction optima, requisites and localization. The product of the reaction was analyzed with respect to its localization and nature. The nuclear activities are not inhibited by a number of inhibitors for protein biosynthesis. The reaction optima found are similar to those of other residual nuclear syntheses including the stringent dependence on ATP. All naturally occurring amino acids are utilized with different efficiencies. Their incorporation is neither cooperative nor competitive which points to individual incorporation mechanisms. Aminoacylation of tRNA may be involved because the incorporation is RNase-sensitive and aminoacylation of tRNA can be shown under the reaction conditions. The enzymatic activities are exclusively nuclear. Significant activity with unchanged characteristics is released by sonication. 70% of the radiolabel incorporated is exported across the nuclear envelope during the incubation. The residual 30% of the radiolabel is distributed without enrichment in any nuclear subfraction. The products are exclusively of polypeptide nature. Since distinct nuclear proteins (e.g. histones) which are definitely preformed in the cytoplasm by protein biosynthesis become radiolabelled by the incorporation of radiolabelled amino acids, it is evident that the incorporation takes place at preformed polypeptides. This is unequivocally proven by the incorporation of radiolabelled amino acids into exogenous proteins by means of the solubilized nuclear activities. The results indicate that the nuclear activity under investigation reflects a nuclear modification system for polypeptides which may be of similar importance as other post-translational modification systems.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Cell cycle variations in ADP-ribosylation of HeLa nuclear proteins

Changes in ADP-ribosylation of nuclear proteins during the HeLa cell cycle were determined. Portions of synchronized cultures were withdrawn at intervals and cells were permeabilized by resuspension in hypotonic buffer containing detergents. Nuclear proteins were radioactively labeled by incubating samples with [32P]NAD. Modified species were resolved using one-dimensional and two-dimensional polyacrylamide gel electrophoresis. Measurements of the incorporation of [32P]NAD by permeabilized cells showed that ADP-ribosylation is a significant modification throughout the cell cycle. A twofold increase was detected during S phase. Autoradiograms of one-dimensional sodium dodecyl sulfate-polyacrylamide gels revealed that many nuclear nonhistones are modified, though the major acceptors of 32P were the histones and a 116,000-Da species (poly(ADP-ribose) polymerase). The same modified proteins were present through the cell cycle, but densitometry of autoradiograms demonstrated a general increase in the level of incorporation in S phase. Autoradiograms of two-dimensional gels of nuclear proteins labeled with [32P]NAD were consistent with these results. Although nonhistones of isolated metaphase chromosomes show a substantial reduction in ADP-ribosylation, histone modification is essentially unchanged in metaphase.

Comparison of ADP-ribosylation of chromosomal proteins between intact and broken cells

ADP-ribosylation of nonhistone high mobility group (HMG) proteins and histone H1 in intact cells was markedly different from that in the broken cell systems using isolated nuclei and chromatin. (i) The amounts of (ADP-ribose)n on these proteins in intact cells were less 10(-2) - 10(-3) of those in the broken cell systems. (ii) The modified protein molecules in intact cells were about 2 orders of magnitude less extent than those in the broken cells. (iii) The (ADP-ribose)n chains synthesized in intact cells, nuclei and chromatin were mainly mono, oligo and poly, respectively. (iv) The principal acceptor molecules in intact cells were concentrated in HMG 1, 2, 14 and 17, and histone H1, whereas the four HMG proteins were minor acceptors in nuclei, and HMG 1 and 2 and histone H1 were major acceptors in chromatin.

ADP-ribosylation of metaphase and interphase nonhistones using [3H]adenosine as a radioactive label

ADP-ribosylation of HeLa nonhistone proteins was investigated by using [3H]adenosine as an in vivo radioactive label. The aim was to determine basic differences in the patterns of modification of interphase and metaphase nonhistones. Fluorography revealed a relatively small number of modified proteins for isolated metaphase chromosomes. In addition to the core histones, a protein of 116 kDa, which is identified as poly-(ADP-ribose) polymerase, was a primary acceptor of [3H]adenosine. Two-dimensional gels revealed a profound difference in the modification of metaphase and interphase nonhistones. For interphase nuclei, 3H label was distributed among a large number of nonhistone acceptors.

Decrease in ADP-ribosylation of HeLa non-histone proteins from interphase to metaphase

Variations for non-histones in the ADP-ribosylating activities of interphase and metaphase cells were investigated. 32P-Labeled nicotinamide adenine dinucleotide ([32P]NAD), the specific precursor for the modification, was used to radioactively label proteins. Permeabilized interphase and mitotic cells, as well as isolated nuclei and chromosomes, were incubated with the label. One-dimensional and two-dimensional gels of the proteins of total nuclei and chromatin labeled with [32P]NAD showed more than 100 modified species. Changing the labeling conditions resulted in generally similar patterns of modified proteins, though the overall levels of incorporation and the distributions of label among species were significantly affected. A less complex pattern was found for nuclear scaffolds. The major ADP-ribosylated proteins included the lamins and poly(ADP-ribose) polymerase. Inhibitors of ADP-ribosylation were effective in preventing the incorporation of label by most non-histones. Snake venom phosphodiesterase readily removed protein-bound 32P radioactivity. A fundamentally different distribution of label from that of interphase nuclei and chromatin was found for metaphase chromosome non-histones. Instead of 100 or more species, the only major acceptor of label was poly(ADP-ribose) polymerase. This profound change during mitosis may indicate a structural role for ADP-ribosylation of non-histone proteins.

Presence of poly (ADP-ribose) polymerase and poly (ADP-ribose) glycohydrolase in the dinoflagellate Crypthecodinium cohnii

Poly(ADP-ribose) polymerase and poly(ADP-ribose) glycohydrolase have been detected in chromatin extracts from the dinoflagellate Crypthecodinium cohnii. Poly(ADP-ribose) glycohydrolase was detected by the liberation of ADP-ribose from poly(ADP-ribose). Poly(ADP-ribose) polymerase was proved by (a) demonstration of phosphoribosyl-AMP in the phosphodiesterase digest of the reaction product, (b) demonstration of ADP-ribose oligomers by fractionation of the reaction product on DEAE-Sephadex. The (ADP-ribose)-protein transfer is dependent on DNA; it is inhibited by nicotinamide, thymidine, theophylline and benzamide. The protein-(ADP-ribose bond is susceptible to 0.1 M NaOH (70%) and 0.4 M NH2OH (33%). Dinoflagellates, nucleated protists, are unique in that their chromatin lacks histones and shows a conformation like bacterial chromatin [Loeblich, A. R., III (1976) J. Protozool. 23, 13--28]; poly(ADP-ribose) polymerase, however, has been found only in eucaryotes. Thus our results suggest that histones were not relevant to the establishment of poly(ADP-ribose) during evolution.

ADP-ribosylation of nonhistone proteins during the HeLa cell cycle

ADP-ribosylation of nonhistone proteins during the HeLa cell cycle was investigated. Proteins were radiolabeled by incubating interphase nuclei and mitotic cells with the specific precursor, [32P]NAD. Autoradiograms of two-dimensional gels of total nuclear nonhistone proteins showed a large number of modified species (more than 140). A complex pattern was also found for interphase chromatin. Nuclear scaffolds showed a simpler pattern of four major groups of modified species, which appeared to be the lamins and poly(ADP-ribose) polymerase. The labeling pattern for nonhistones of metaphase chromosomes was fundamentally different than with interphase nuclei. Autoradiograms were dominated by the incorporation of label into poly(ADP-ribose) polymerase.

Nicotinamide and its derivatives increase growth hormone and prolactin synthesis in cultured GH3 cells: role for ADP-ribosylation in modulating specific gene expression

To determine if changes in ADP-ribosylation of the chromosomal proteins can influence the expression of specific genes, the effects of compounds that influence this modification were investigated on the expression of the growth hormone (GH) and prolactin (Prl) genes in cultured rat pituitary (GH3) cells. The drugs tested, nicotinamide, N'-methylnicotinamide, 5-methylnicotinamide, 3-acetylpyridine, and 3-aminobenzamide, decrease ADP-ribosylation either by inhibiting (ADP-ribose)n synthetase and/or by decreaseing cellular levels of NAD+, the substrate for the enzyme. These drugs increased the synthesis of both GH and Prl and were synergistic in stimulating an increase in GH synthesis in response to triiodothyronine, a physiological regulator of GH synthesis. N'-methylnicotinamide, the most effective agent, was analyzed in detail; it increased the synthesis of both GH and Prl (maximally after 2 days) and increased their mRNAs in parallel; furthermore, this effect was reversible after drug removal. The effects of N'-methylnicotinamide were relatively specific for GH and Prl, since the synthesis of only a few other proteins was affected. These data suggest that changes in ADP-ribosylation can modulate the expression of specific genes.

A note on the ADP-ribose-protein linkages in rat-liver nuclei: a possible approach to assessing megavitamin therapy with niacin

Nuclei isolated from rat liver were incubated with NAD whose two ribose moieties were respectively labeled with 3H or 14C. By enzymatic (phosphodiesterase) and/or chemical (hydroxylamine) attack on doubly labeled ADP-ribosylated nuclear residues, AMP was found after hydroxylaminolysis as well as iso-ADP-ribose after phosphodiesterase plus hydroxylamine, in the absence of detectable amounts of ribose-5-phosphate. This is taken to indicate the existence of additional ribose-protein binding sites in in vitro ADP-ribosylated nuclear proteins: Besides C-1" (Hayaishi et al., Stocken et al.) C-2' and/or C-3' (purine-near) as well as C-2" and/or C-3" (pyrimidine-near), not only at the end but also within the chain of oligo-ADPR.

Immunological evidence for the in vivo occurrence of a crosslinked complex of poly(ADP-ribosylated) histone H1

The poly(ADP-ribosylation) of histones, which occurs within a limited and functionally specific domain of chromatin, is a novel post-translational modification. However, in the past it has been difficult to study this process in living cells because the substrate of the reaction (NAD) does not permeate the plasma membrane. In the current study, antibodies specific for histone H1 and poly(ADP-ribose) were used to study the occurrence of poly(ADP-ribose)+ species of H1 in vivo. Perchloric acid-extracted proteins from synchronously growing HeLa cells were fractionated by electrophoresis and transferred to nitrocellulose, and the transferred moieties were allowed to react with the specific antibodies and then with 125I-labeled protein A. The results conclusively demonstrate the natural occurrence of poly(ADP-ribose)-crosslinked complexes of histone H1 (i.e., H1 dimer), at the S/G2 phase transition of the cell cycle.

Adenosine diphosphate ribosylation of chicken-erythrocyte histones H1, H5 and high-mobility-group proteins by purified calf-thymus poly(adenosinediphosphate-ribose) polymerase

Poly(ADP-ribosylation) of histones H1, H5 and non-histone chromosomal high-mobility-group proteins HMG 1, 2, 14 and 17 from chicken erythrocytes by purified calf thymus poly(ADP-ribose) polymerase was studied using acid/urea/Triton gel electrophoresis and autoradiography. With histone H1, besides ADP-ribosylated H1 supporting short chains of polymer, the appearance of H1 'dimer' was observed and this reaction was dependent on NAD concentration and incubation time. In addition, highly modified and/or aggregated species of histone H1 were observed. Histone H5 was slightly ADP-ribosylated at low NAD concentrations. At higher NAD concentrations or after longer incubations the formation of H5 'dimer' and of more modified forms of H5 could be observed. HMG 1 and HMG 2 were found to be ADP-ribosylated, the reaction being dependent on NAD concentration and time. Here again some discrete intermediates appeared. HMG 14 and HMG 17 were only slightly ADP-ribosylated under our experimental conditions. These results indicate that the purified DNA-independent poly(ADP-ribose) polymerase can catalyse the formation of H1 'dimer' as in nuclei and nucleosomes and that H5 and HMG proteins can also be ADP-ribosylated and produce well-defined higher complexes. These modifications of nuclear proteins may provide a means of localized conformational changes of the chromatin structure in vivo.

Mono ADP-ribosylation and poly ADP-ribosylation of proteins in normal and malignant tissues

Three subclasses of (ADPR)n protein conjugates were quantified from intact tissue; proteins carrying poly(ADPR) and two types of mono(ADPR) protein conjugates, one susceptible, the other resistant to neutral hydroxylamine. Mono(ADPR) conjugates were found in all major compartments of the liver cell although the two subfractions were unevenly distributed. Poly(ADPR) protein conjugates appear to be restricted to the nucleus. Independent changes of the subclasses in normal and malignant tissues associated with cell growth and differentiation also point to independent functions. Hydroxylamine-resistant mono(ADPR) protein conjugates of various tissues changed with the degree of terminal differentiation. Formation of poly(ADPR) proteins, on the other hand, was stimulated by treatment of cells with alkylating agents which lead to DNA-fragmentation. This points to an involvement of polyADP-ribosylation in DNA excision repair.

Characterization of poly(ADP-ribose)--histone H1 complex formation in purified polynucleosomes and chromatin

Poly(ADP-ribose) [poly(ADP-Rib)] polymerase of HeLa nucleosomes has been shown in vitro, to catalyze the synthesis of a complex of histone H1 containing 2 H1 histones and 15-16 units of oligo(ADP-Rib). The synthesis of the H1 complex in vitro was compared in polynucleosome populations of various sizes (3--16 and greater than 30) released from HeLa nuclei following micrococcal nuclease digestion. Poly(ADP-Rib) was synthesized from [32P]NAD and the poly(ADP-ribosyl)ation of H1 was studied by selective H1 extraction, gel electrophoresis and autoradiography. Quantitative differences in H1 complex formation occurred when either chromatin concentration or polynucleosome length was varied. The data indicated that H1 complex formation in vitro was favored in polynucleosomes 16 nucleosomes long as compared to 8 nucleosomes. A series of partially ADP-ribosylated H1 species was also detected. Partially modified H1 species migrate more slowly than pure H1 in dodecylsulfate gels. The reduced mobility is a function of the number of attached ADP-Rib moieties. Thus, molecules containing one molecule of H1 and various numbers of ADP-Rib residues can be separated. When the partially modified H1 species were incubated in alkali to cleave the linkage of ADP-Rib to protein, (ADP-Rib1-15) were detected by chain length analysis on 15% polyacrylamide gels. The intermediate H1 species could be chased, in vitro, into as H1 complex with NAD and thus were determined to be successive precursors in the formation of the H1 complex. Evidence is presented that the H1 complex is synthesized in intact cells permeabilized with lysolecithin.

Adenosine diphosphate ribosylation of histone H1 by purified calf thymus polyadenosine diphosphate ribose polymerase

The mechanism of poly ADPR synthesis and the transfer of poly ADPR to histone H1 molecule by electrophoretically homogenous calf thymus poly ADPR polymerase containing DNA was examined. 1) An acid insoluble radioactive complex (I) was obtained after incubation of purified enzyme with [3H] NAD. The stability of (I) was examined by SDS-polyacrylamide gel electrophoresis. The complex (I) was stable against acid, SDS, urea, DNase and RNase, but labile against pronase, trypsin, alkali and snake venom phosphodiesterase treatment. The molecular weight of (I) was about 130 000 daltons estimated by SDS-gel electrophoresis. The radioactive products of successive alkali, venom phosphodiesterase and Pronase hydrolysis of (I) were PR-AMP and AMP. The mean chain length of poly ADPR of (I) was 20--30. These results suggest that the complex (I) is poly ADP-ribosylated poly ADPR polymerase. 2) Besides (I), a second radioactive peak (II) was observed when acid insoluble products obtained from an incubation mixture containing purified poly ADPR polymerase, [3H] NAD and purified histone H1 were analyzed on SDS-polyacrylamide gel electrophoresis. The molecular weight of (II) was estimated to be about 23 000 daltons. The complex (II) is eluted like histone H1 on CM-cellulose columns and hydrolyzed by alkali, trypsin and snake venom phosphodiesterase but not by DNase, or RNase. The comples (II) was extracted selectively by 5 per cent perchloric acid or 5 per cent trichloroacetic acid from mixture of (I) and (II). The mean chain length of poly ADPR of complex (II) and 5--20; these results suggest that the complex (II) is poly ADP-ribosylated histone H1. 3) Results 1) and 2) indicate that purified DNA containing, thus DNA independent, poly ADPR polymerase catalyzes two different reactions, the ADPR transfer onto the enzyme itself and onto histone H1 and the elongation of ADPR chains. Dimeric forms of ADP-ribosylated histone H1 was not observed. Free poly ADPR was observed only when very small quantities of enzyme were used for incubation.

Adenosine diphosphate ribose transferase from baby-hamster kidney cells (BHK-21/C13). Characterization of the reaction and product

Some properties of ADP-ribose transferase, and its reaction product, from BHK-21/C13 cells are described. Enzyme activity was found almost exclusively in nuclei (90%), with the remaining 10% located in the cytosolic fraction. The nuclear enzyme is chromatin-bound and requires bivalent cations, preferably Mg2+, a pH of 8.0 and a temperature of 25 degrees C for optimal activity. Chromatin preparations incorporated radioactivity from [14C]NAD+ into acid-insoluble material for about 60 min. Kinetics for substrate NAD+ utilization were not of Michaelis--Menten type; biphasic kinetics were shown from a double-reciprocal plot (1/reaction velocity against 1/[NAD+]) and from a 'Hofstee' plot (reaction velocity/[NAD+] against reaction velocity). The transferase is unstable in the absence of Mg2+ ions. It is inhibited by thymidine, nicotinamide and nicotinamide analogues, but not by ATP, which stimulates it at concentrations of 5 mM and above. The enzyme requires thiol groups for activity; it is readily inhibited by N-ethylmaleimide at 0.5 mM. The product of the reaction is stable under acid conditions at temperatures up to 25 degrees C, but it is hydrolysed by HClO4 at 70 degrees C. It is resistant to NaOH, but is cleaved from its attachment to protein with alkali into trichloroacetic acid-insoluble and -soluble components. On the basis of Cs2SO4- density-gradient analysis under denaturing conditions (gradients included urea and guanidinium hydrochloride), and analysis of the reaction product directly on hydroxyapatite, we conclude that most of the radioactive ADP-ribose residues are firmly bound to protein, presumably in covalent linkage. Hydroxyapatite-chromatographic analysis of ADP-ribose residues released from protein by alkaline digestion showed a spectrum of molecular sizes including mono-, oligo- and poly-(ADP-ribose), when chromatin was incubated initially with [14C]NAD+ for 10 min and then for a further 30 min after addition of excess non-radioactive NAD+, only about 10% of the radioactive mono-(ADP-ribose) could be 'chased' into longer-chain molecules. Hydroxyapatite analysis was also used to show that, whereas all ADP-ribose residues were released from protein with NaOH, only 50% of them were susceptible to hydroxylamine. These hydroxylamine-sensitive residues included all size classes, although mono-(ADP-ribose) predominated. Finally, there was an approximately equal distribution of ADP-ribose incorporated into HCl-soluble proteins (including the histones) and HCl-insoluble proteins (including the non-histone proteins) when chromatin was incubated with NAD+ up to 0.5 mM, but at higher NAD+ concentrations more ADP-ribose was incorporated into the HCl-soluble fraction (82% at 4.0 mM-NAD+).