Purification and properties of poly(adenosine diphosphate ribose) synthetase.

Poly(ADP-ribose) synthetase has been purified approximately 5000-fold from rat liver nuclei. The activity of the purified enzyme is absolutely dependent upon the presence of native or synthetic DNA, and the further addition of histone(s) stimulates the activity 3- to 5-fold. When the ADP-ribosylated material synthesized in the absence or presence of various histones is analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the major product in all cases migrates between histones H1 and H3-H2B with the same RF value of 0.58 relative to the marker dye. No ADP-ribose was found to co-electrophorese with any of thehistones. The addition of histones does not affect the chain number of the poly(ADP-ribose) synthesized but does result in an increase in the average chain length of the polymer. In the presence of histones, the Km for NAD+ decreases from 80 micron to 25 micron and the Vmax doubles. These results indicate that, in the purified poly(ADP-ribose) synthetase system, histones are not ADP-robosylated but act as allosteric activators.     

Nonenzymic adenosine 5'-diphosphate ribosylation of poly(adenosine diphosphate ribose)

Poly(adenosine 5'-diphosphate ribose) [poly(ADP-ribose]) is spontaneously ADP-ribosylated when it is incubated with nicotinamide adenine dinucleotide, especially in 0.5 M NaCl and at an alkaline pH. The ADP-ribose residues are monomeric and are attached to the middle of polymer chains. The linkage is similar to, and may be identical with, that of the branch points that are created in cells. RNA is also spontaneously ADP-ribosylated, but not DNA.     

Bovine thymus poly(adenosine diphosphate ribose) polymerase.

About 1,300-fold purification of poly(adenosine diphosphate ribose) polymerase has been achieved from the extract of bovine thymus with a recovery of 10 to 20%. The final preparation has a purity of 99%, and the enzyme is composed of a single peptide with a molecular weight of 130,000. The purified enzyme required NAD+, Mg2+, a thiol compound, DNA, and histones for full activity. Whereas DNA is essential for activation of the enzyme, histones are not. The observed stimulation of the reaction by histones is shown to be due to masking of the inhibitory effect of contaminating denartured DNA in native DNA preparation. The concentration of DNA required for half-maximal enzyme activity (apparent Km for DNA) is proportional to the concentration of enzyme in the reaction mixture. The minimum estimation of the number of nucleotide pairs of DNA required for half-maximal activation of one enzyme molecule is 220 to 240 for bulk of calf thymus DNA, while the value is 10 for a calf thymus DNA fraction, "active DNA," which was separated from the enzyme fraction in a stage of the purification. These results suggest that the enzyme is activated by binding to a specific site on calf thymus DNA. The apparent Km for NAD+ and the maximum velocity of the enzyme are estimated to be 60 micrometer and 0.91 mumolper min per mg, respectively.     

A peplomycin-supersensitive cell line lacking activation of poly(adenosine diphosphate ribose) synthetase by peplomycin

In peplomycin-supersensitive Chinese hamster lung cells, the increase in poly(ADP-ribose) synthesizing activity following peplomycin treatment was significantly reduced as compared with the parental lung cells, suggesting that peplomycin-supersensitive lung cells may have some deficiency in DNA repair. On the contrary, peplomycin-supersensitive ovary cells, which undergo increased DNA damage induced by peplomycin, showed normally increased poly(ADP-ribose) polymerizing activity compared with the parental ovary cells. Relationship between poly(ADP-ribose) polymerase and peplomycin sensitivity was discussed.     

A new method for the assay of poly(adenosine diphosphate ribose) glycohydrolase activity.

Poly(adenosine diphosphate ribulose) [poly(ADP-Rib)] glycohydrolase activity was determined by measuring the amount of ADP-Rib hydrolyzed from polymers of ADP-Rib as substrate. In principle, the method consists of incubating oligomers or polymers of [¹⁴C]ADP-Rib with testis glycohydrolase. The reaction was stopped by the addition of a suspension of Dowex 1X-2 formate in H₂O (1:3, $\text{v}\text{v}$) which adsorbed monomers and oligomers of ADP-Rib. The adsorbed [¹⁴C]ADP-Rib was selectively extracted from the resin with 6 m formic acid. The amount of [¹⁴C]ADP-Rib was estimated by measuring the radioactivity in aliquots of formic acid extract. Oligomers or polymers of ADP-Rib can be utilized as substrates since the reaction rates were the same with either compound.A method to determine phosphodiesterase and glycohydrolase activities was established. These two enzymic activities were distinguished by treating the products of the reactions with alkaline phosphatase and by differential extraction of the adsorbed reaction products on Dowex with 0.5 m and 6 m formic acid.     

Noncovalent interactions of poly(adenosine diphosphate ribose) with histones.

Covalent linkage of ADP-ribose polymers to proteins is generally considered essential for the posttranslational modification of protein function by poly(ADP-ribosyl)ation. Here we demonstrate an alternative way by which ADP-ribose polymers may modify protein function. Using a highly stringent binding assay in combination with DNA sequencing gels, we found that ADP-ribose polymers bind noncovalently to a specific group of chromatin proteins, i.e., histones H1, H2A, H2B, H3, and H4 and protamine. This binding resisted strong acids, chaotropes, detergents, and high salt concentrations but was readily reversible by DNA. When the interactions of variously sized linear and branched polymer molecules with individual histone species were tested, the hierarchies of binding were branched polymers greater than long, linear polymers greater than short, linear polymers and H1 greater than H2A greater than H2B = H3 greater than H4. For histone H1, the target of polymer binding was the carboxy-terminal domain, which is also the domain most effective in inducing higher order structure of chromatin. Thus, noncovalent interactions may be involved in the modification of histone functions in chromatin.     

Monoclonal antibodies to poly(adenosine diphosphate ribose) recognize different structures

Two hybridomas producing monoclonal antibodies to poly(adenosine diphosphate ribose) [poly(ADP-Rib)] were established. One antibody, 10H (IgG3, kappa), bound to most of the poly(ADP-Rib) preparation, which consisted of molecules of various sizes of more than 20 ADP-Rib residues. The binding of this antibody was inhibited by not only poly-(ADP-Rib) but also a monomer unit of poly(ADP-Rib), Ado(P)-Rib-P. The sites protected by antibody 10H were isolated and analyzed by hydrolysis with alkaline phosphomonoesterase and then snake venom phosphodiesterase. The sites contained the same amounts of monomer units and branched portions [Ado(P)-Rib(P)-Rib-P] as the original poly(ADP-Rib) molecules but a lower average number of branched portions per molecule than in the original molecules. The other antibody, 16B (IgM, lambda), reacted with only 50% of the radioactive poly(ADP-Rib), and its binding was not inhibited by a monomer unit. This antibody protected 25% of all the poly(ADP-Rib) molecules from hydrolysis by snake venom phosphodiesterase. The protected sites contained twice as many branched portions per molecule as the original poly(ADP-Rib) molecules. These results show that the two monoclonal antibodies recognize different structures of poly-(ADP-Rib); 10H antibody recognizes the linear structure with ribose-ribose linkages, and 16B antibody may recognize specific structures, including the branched portions of poly-(ADP-Rib).     

Synthesis of poly(adenosine diphosphate ribose) in synchronized Chinese hamster cells.

Chinese hamster ovary cells were synchronized by mitotic selection and used to study the relation of poly(adenosine diphosphate ribose) synthesis to DNA synthesis and the different phases of the cell cycle. DNA synthesis was measured in cells rendered permeable to exogenously supplied nucleotides. Poly(ADPR) synthesis was also measured in permeable cells in the presence of both minimum and maximum DNA damage. The maximum DNA damage was produced by treating the cells with saturating concentrations of DNase. As anticipated, the DNA synthesis complex showed its maximum activity during S phase and showed 4–5-fold less activity during the other phases of the cell cycle. The basal level of poly(ADPR) synthesis was elevated during G1, fell to its lowest level during S phase, then increased during G2 and rose to its highest level during G1. The DNase responsive activity of poly(ADPR) synthesis was relatively constant thru the cell cycle but showed a peak at the end of S phase; then the activity decreased during the subsequent G2-M period.     

Demonstration of high molecular weight poly (adenosine diphosphate ribose).

An electrophoretic system was established that resolves poly(adenosine diphosphate ribose), enzymatically synthesized polymer from NAD+, by size difference of one residue on polyacrylamide gel. The existence of a polymer of at least 65 residues was demonstrated by band counting in this system. The polymer showed a heterogeneous size distribution on the electrophoregram, and the molecular weight of the largest polymer was deduced to be more than 4.5 X 10(5) daltons. The discrepancy between the size, estimated by electrophoresis, and the chain length, determined by the ratio of total radioactivity to that derived from the terminus, suggests that the polymer has a branched structure.     

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

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

Natural occurence of a biopolymer, poly (adenosine diphosphate ribose).

Evidence for the natural occurrence of poly(adenosine diphosphate ribose) in vivo was obtained using a sensitive radioimmunoassay and poly(adenosine diphosphate ribose) glycohydrolase, which specifically hydrolyzes poly(adenosine diphosphate ribose). Calf thymus, liver, kidney, brain, pancreas and spleen contained poly(adenosine diphosphate ribose). Naturally occurring poly(adenosine diphosphate ribose) in calf thymus is composed of molecules of various chain lengths, like that synthesized by an in vitro system. Calf thymus was estimated to contain about 0.02 microgram/mg DNA of poly(adenosine diphosphate ribose).     

Use of two-dimensional thin-layer chromatography for the components study of poly(adenosine diphosphate ribose)

Two-dimensional thin-layer chromatography on cellulose plates has been used for separating and quantifying the three adenosine derivatives: AMP, phosphoribosyl AMP (PRAMP), and (PR)2AMP obtained by venom phosphodiesterase digestion of poly(ADP-ribose). In vitro synthesized polymer, up to 300 derivatives in length were studied. Some parameters of the complexity of poly(ADP-ribose) could be deduced from our results: (i) The first branching point appears in fragments of approximately 21 derivatives in length. (ii) The branching points are located at regular distances of approximately 41 derivatives from each other.