Immunological studies of RNA polymerase II using antibodies to subunits of Drosophila and wheat germ enzyme

We induced goat antibodies to Drosophila RNA polymerase II and rabbit antibodies to the isolated 215,000-dalton and 140,000-dalton polymerase II subunits (P215 and P140, respectively). Similarly, we induced rabbit antibodies to wheat germ RNA polymerase II and to the 220,000-dalton subunit and 140,000-dalton subunit (P220 and P140, respectively). Anti-polymerase antibodies precipitated the homologous native enzyme and inhibited its activity in vitro, while several of the anti-subunit sera did neither. The anti-Drosophila P215 serum specifically labeled RNA polymerase II fixed in situ on polytene chromosomes. We reacted the antibodies with polymerase subunits separated by sodium dodecyl sulfate gel electrophoresis and electrophoretically transferred to nitrocellulose ("protein blotting"). Each antibody to whole polymerase reacted with multiple subunits, while the anti-subunit sera each reacted specifically with the subunit employed as immunogen. The anti-subunit sera also cross-reacted with the analogous subunit from several heterologous polymerases II (from yeast, wheat germ, Drosophila, and calf thymus), demonstrating shared subunit-specific determinants in polymerase II from widely divergent organisms. The anti-polymerase sera also showed cross-reactivity with subunits of heterologous enzymes, but only in one case did the cross-reactivity involve subunits other than the two largest ones. Specifically, the goat anti-Drosophila polymerase serum displayed easily detectable cross-reactivity with four low molecular weight subunits of calf thymus polymerase II, providing a unique demonstration of antigenic relatedness of small RNA polymerase II subunits from different higher eukaryotes.     

Comparative study of calf thymus and wheat germ RNA polymerase II: stability of initiation complexes and elongation rates.

Pure wheat germ RNA polymerase II but not calf thymus RNA polymerase II forms relatively stable binary complexes (half life time of 30 minutes at 0°C) with superhelical SV 40 DNA. On the contrary, the addition of a specific dinucleotide and a single ribotriphosphate permits the formation of highly stable complexes between both enzymes and SV 40 DNA. The elongation of RNA chains with preinitiated wheat germ enzyme only is stimulated by sarkosyl. These observations suggest that the wheat germ enzyme, as compared to that isolated from calf thymus, may contain a protein factor, a more native structure or both that permit efficient initiation and elongation of RNA chains on double stranded DNA.     

Purification and subunit structure of RNA polymerase II from the pea.

DNA-dependent RNA polymerase II (EC 2.7.7.6) from pea seedlings (Pisum sativum var. Alaska) has been purified to homogeneity, as judged by native polyacrylamide electrophoresis. The procedure includes polyethyleneimine precipitation and elution, ammonium sulfate precipitation, DEAE-Sephadex chromatography, phosphocellulose chromatography, and heparin-Sepharose chromatography. The enzyme purified almost to homogeneity has a specific activity of 200 nmol/mg per 15 min at 30 degrees C with denatured calf thymus DNA as template. The enzyme activity is 50% inhibited in the presence of 0.05 migrograms/ml of alpha-amanitin. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicates that pea RNA polymerase II is composed of eight subunits with molecular weights and molar ratios (in parentheses) of 170 000 (0.9), 140 000 (1.0), 43 000 (1.5), 26 000 (2.0), 22 500 (1.2), 21 500 (0.6), 18 500 (1.6) and 17 500 (2.3). The structure is closely similar to that of cauliflower RNA polymerase II.     

Isolation of ribonucleic acid polymerases I, II, and III from Saccharomyces cerevisiae.

A procedure for the simultaneous purification of RNA polymerases I, II, and III from Saccharomyces cerevisiae is described. High yields of each enzyme activity are obtained, allowing the preparation of approximately 10 mg of polymerase I, 25 mg of polymerase II, and 12 mg of polymerase III from 1.2 kg of cells (wet weight). Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicates RNA polymerase I contains polypeptides with molecular weights 185 000, 137 000, 41 000, 35 000, 28 000, 24 000, 20 000, 16 000, 14 500, and 12 300; RNA polymerase II contains subunits with molecular weights 170 000, 145 000, 41 000, 33 500, 28 000, 24 000, 18 000, 14 500, and 12 500; and RNA polymerase III contains polypeptides with molecular weights 160 000, 128 000, 82 000, 53 000, 41 000, 37 000, 34 000, 28 000, 24 000, 20 000, 14 500, and 10 700.     

Purification and Subunit Structure of DNA-dependent RNA Polymerase III from Wheat Germ

A rapid and simple, large-scale method for the purification of DNA-dependent RNA polymerase III (EC 2.7.7.6) from wheat germ is presented. The method involves enzyme extraction at low ionic strength, polyethyleneimine fractionation, (NH₄)₂SO₄ precipitation, and chromatography on DEAE-Sepharose CL-6B, DEAE-cellulose, and heparin agarose. Milligram quantities of highly purified enzyme can be obtained from kilogram quantities of starting material in 2 to 3 days. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that RNA polymerase III contains 14 subunits with molecular weights of: 150,000; 130,000; 94,000; 55,000; 38,000; 30,000; 28,000; 25,000; 24,500; 20,500; 20,000; 19,500; 17,800; and 17,000. Subunit structure comparison of wheat germ RNA polymerases I, II, and III indicates that all three enzymes may contain common subunits with molecular weights 20,000, 17,800, and 17,000. In addition, RNA polymerases II and III may contain a common subunit with a molecular weight of 25,000, and RNA polymerases I and III may contain a common subunit with a molecular weight of 38,000.     

Probing eukaryotic RNA polymerases B with monoclonal antibodies

Monoclonal antibodies directed against RNA polymerase B of the fungus Podospora comata were selected on the basis of different subunits recognition and inhibitory effect on enzyme activity. A library of 10 antibodies biased toward B180, B145, B39, B23,5 and B11 subunits was constructed. Most of these antibodies also recognize yeast, wheat germ and calf thymus RNA polymerase B. Subunits bearing antigenic determinants are not always homologous in Podospora and yeast enzyme. As some of these antibodies strongly inhibit enzyme activity they constitute potent probes for functional studies of corresponding subunits.     

Purification and characterization of RNA polymerase I from a higher plant.

RNA polymerase I was purified from chromatin isolated from auxin-treated soybean hypocotyl. Purification was achieved by using Agarose A-1.5m gel filtration, DEAE-cellulose, CM-sephadex, and phosphocellulose chromatography, and sucrose density gradient centrifugation. With denatured calf thymus DNA as template, the enzyme has a high specific activity (200-300 nmol/mg/30 min at 28 degrees C) which is comparable to other RNA polymerase I enzymes purified from animals and yeast. While the gel profiles indicate that purification to homogeneity (greater than 90%) may not have been achieved, the enzyme appears to be composed of possibly 7 subunits, several of which are similar to the subunits of yeast RNA polymerase I. The putative subunits and molar ratios are 183 000 (1), 136 000 (1), 50 000 (0.5), 46 000 (0.5), 40 000 (0.5), 33 000 (0.2), and 28 000 (2). The purified enzyme strongly prefers a completely denatured template such as poly(dC).     

A DNA-binding protein specific for the early replicated region of the chromosome obtained from Escherichia coli membrane fractions

The binding sites of calf thymus RNA polymerase (B) II, wheat germ RNA polymerase B and of the Escherichia coli RNA polymerase were mapped on the simian virus 40 genome by observation of enzyme-linear DNA complexes by electron microscopy. Three to four major sites and several minor sites are observed for each enzyme; common binding sites for the three enzymes are found in positions 0.17, 0.53 and 0.90 of the viral physical map. Initiation complexes with these enzymes can be stabilized with specific ribodinucleotides and a single ribonucleoside triphosphate. Whereas ApA and ATP greatly enhances the binding of the E. coli enzyme at position 0.17, they stabilize the binding of the eukaryotic enzyme at many sites, some of them located in close proximity of the origin of replication.     

Purification and subunit structure of RNA polymerases I and II from Dictyostelium discoideum vegetative cells

Summary A purification procedure to obtain RNA polymerases I (or A) and II (or B) from Dictyostelium discoideum amoeba has been developed. The enzymes were solubilized from purified nuclei and separated by DEAF-Sephadex chromatography. RNA polymerases I and II were further purified by a second chromatography on DEAE-Sephadex followed by chromatographies on phosphocellulose and heparin-sepharose. The specific activities of purified RNA polymerases I and II are 92 units/ mg protein and 70 units/ mg protein, respectively. The subunit structure of both RNA polymerases were analyzed by polyacrylamide gel electrophoresis under denaturing conditions after glycerol gradient centrifugation of the enzymes. The putative subunits of RNA polymerase I have molecular weights of 180 000,125 000,43 000,40 000,34 000, 31 000, 25 000,19 000, 17 000 and 14 000. The putative subunits of RNA polymerase II have molecular weights of 200 000 (170 000), 130 000, 33 000, 25 000, 19 000, 17 000, 15 000, 13 000. There are three polypeptides with common molecular weight in Dictyostelium RNA polymerases I and 11. The subunit of 25 000 daltons of both enzymes has common immunological determinants with RNA polymerase II from crustacean Artemia.Abbreviations TLCK tosyl-lysine-chloromethyl-ketone - DPT diazophenylthioether     

Purification and characterization of two new high molecular weight forms of DNA polymerase delta

Two high molecular weight DNA polymerases, which we have designated delta I and delta II, have been purified from calf thymus tissue. Using Bio Rex-70, DEAE-Sephadex A-25, and DNA affinity resin chromatography followed by sucrose gradient sedimentation, we purified DNA polymerase delta I 1400-fold to a specific activity of 10 000 nmol of nucleotide incorporated h-1 mg-1, and DNA polymerase delta II was purified 4100-fold to a final specific activity of 30 000 nmol of nucleotide incorporated h-1 mg-1. The native molecular weights of DNA polymerase delta I and DNA polymerase delta II are 240 000 and 290 000, respectively. Both enzymes have similarities to other purified delta-polymerases previously reported in their ability to degrade single-stranded DNA in a 3' to 5' direction, affinity for an AMP-hexane-agarose matrix, high activity on poly(dA) X oligo(dT) template, and relative resistance to the polymerase alpha inhibitors N2-(p-n-butylphenyl)dATP and N2-(p-n-butylphenyl)dGTP. These two forms of DNA polymerase delta also share several common features with alpha-type DNA polymerases. Both calf DNA polymerase delta I and DNA polymerase delta II are similar to calf DNA polymerase alpha in molecular weight, are inhibited by the alpha-polymerase inhibitors N-ethylmaleimide and aphidicolin, contain an active DNA-dependent RNA polymerase or primase activity, display a similar extent of processive DNA synthesis, and are stimulated by millimolar concentrations of ATP. We propose that calf DNA polymerase delta I, which also has a template specificity essentially identical with that of calf DNA polymerase alpha, could be an exonuclease-containing form of a DNA replicative enzyme.     

Plant DNA-dependent RNA polymerases: subunit structures and enzymatic properties of the class II enzymes from quiescent and proliferating tissues

Class II DNA-dependent RNA polymerases were purified from soybean tissues of different physiological states: (1) from seed embryo tissue, representative of a quiescent, low metabolic state and (2) from auxin-treated hypocotyl tissue, representative of a highly proliferative and metabolically active state. Dodecyl sulfate, polyacrylamide gel electrophoresis indicates that RNA polymerase II from embryonic tissue consists largely (90-95%) of the form IIA enzyme, the largest subunit having a molecular weight of 215 000. RNA polymerase II from hypocotyl tissue is exclusively a form IIB enzyme, the largest subunit having a molecular weight of 180 000. Polypeptides common to RNA polymerases IIA and IIB have the following molecular weights: 138 000; 42 000; 27 000; 22 000; 19 000; 17 600; 17 000; 16 200; 16 100; and 14 000. Peptide mapping in the presence of dodecyl sulfate suggests that the 215 000 and 180 000 subunits possess similar peptide fragments. Plant embryo tissues do not contain protease activity capable of cleaving the 215 000 subunit to the 180 000 subunit, but proliferating plant tissues do contain such an activity. Mixing experiments indicate that appreciable amounts of RNA polymerase IIB are not being artifactually produced during protein purification.     

Conservation of a DNA-binding site in the largest subunit of eukaryotic RNA polymerase II

Using a monoclonal antibody to a DNA-binding site of calf RNA polymerase II, we found that this site occurs on the largest subunit and is structurally similar in RNA polymerase II of widely divergent eukaryotes. In immuno-blotting of electrophoretically separated subunits, the monoclonal antibody recognized a determinant on the largest polypeptide of all RNA eukaryotic polymerase II forms tested, with a preference for the IIA enzyme subunit of 215 X 10(3) Mr over the partially proteolyzed 180 X 10(3) Mr form. This site is conserved on human, chicken, Drosophila, wheat germ and yeast RNA polymerase II, all of which reacted strongly with the monoclonal antibody. These results contrasted with those obtained with polyclonal antibodies to non-functional determinants of the calf enzyme. The reactivity of the polyclonal antibody with eukaryotic RNA polymerase II steadily decreased with increasing evolutionary distance from the original antigen; the yeast enzyme showed no cross-reactivity. These results suggest that a basic functional feature of eukaryotic RNA polymerase II has been strongly conserved and support the view that divergence of RNA polymerase II has taken place mainly in other, perhaps regulatory, sites of the enzyme.     

The role of subunits in yeast DNA-dependent ribonucleic acid polymerase A.

The properties of RNA polymerase A, which lacked the subunits of 48 000, 37 000 and 16 000 mol. wt., were compared with those of RNA polymerase A by using native calf thymus DNA as the template. The results showed that: (1) the specific activity of RNA polymerase A was about one-third that of RNA polymerase A; (2) more than 80% of RNA polymerase A, but only about 25% of RNA polymerase A, made RNA; (3) initiation by RNA polymerase A, but not by RNA polymerase A, began after a lag of 2 min; (4) the temperature-dependence for productive binding to DNA was greater for RNA polymerase A; (5) the apparent Km for UTP was greater for RNA polymerase A. These results support the supposition that the subunits missing from RNA polymerase A are involved in DNA binding [Huet, Dezélée, Iborra, Buhler, Sentenac & Fromageot (1976) Biochimie 58, 71-80] and show also that the loss of these subunits affects the elongation reaction.     

Affinity isolation of RNA polymerase II on amanitin-Sepharose

We report here the first case of an affinity isolation of eukaryotic RNA polymerase II. The procedure employs an affinity matrix composed of α-amanitin coupled to Sepharose 4B via a ten atom spacer. RNA polymerase II from either calf thymus or wheat germ binds to the amanitin-Sepharose, as indicated by subsequent elution with sodium dodecylsulfate-containing buffer and analysis by polyacrylamide gel electrophoresis. The specificity of binding is demonstrated by the fact that when the enzyme is preincubated with 1 μg/ml of free α-amanitin, subsequent binding to the amanitin-Sepharose is abolished. Elution methods that should permit the recovery of active enzyme from the column are discussed.     

Antigenic homology of eukaryotic RNA polymerases

Facilitated by an improved enzyme purification procedure, antisera to calf thymus DNA-dependent RNA polymerase II was prepared in hens. Using immunoprecipitation and inhibition of enzymatic activity the immunological properties of several eukaryotic RNA polymerases were examined. Purified calf thymus and rat liver polymerase II exhibited antigenic homology. The partially purified amphibian ($\text{Xenopus laevis}$) and protozoan ($\text{Tetrahymena pyriformis}$) polymerase II had reduced crossreactivities. Calf thymus polymerase I also shared antigenic homology with the form II enzymes.     

Comparison of Large Subunits of Type II DNA-dependent RNA Polymerases from Higher Plants

Two-dimensional tryptic mapping of ¹²⁵I-labeled polypeptides has been employed to compare the large subunits of type II DNA-dependent RNA polymerases from maize, parsley (Petroselinum sativum), and wheat. Maps of the 220 kilodalton (kd) and 140 kd subunits from wheat RNA polymerase II differ from those of the corresponding subunits from parsley enzyme II. The 180 kd subunits from maize and parsley type II enzymes also yield dissimilar tryptic maps. Thus, despite similarities in molecular mass, the large subunits of wheat, parsley, and maize type II RNA polymerases are unique to each individual plant species.     

High molecular weight deoxyribonucleic acid polymerase from crown gall tumor cells of periwinkle (Vinca rosea).

A high molecular weight (6 S) plant DNA polymerase from axenic Vinca rosea tissue culture cells has been purified 2200-fold and characterized. The enzyme has a molecular weight of 105 000 (+/-5000). Sodium dodecyl sulfate-acrylamide gel electrophoresis of the purified enzyme yields polypeptide subunits having molecular weights of 70 000 and 34 000. The purified enzyme has a pH optimum of 7.5; a cation requirement optimum of 6 mM Mg2+ or 0.5 mM Mn2+; an apparent requirement for Zn2+; a Km of 1 muM for dTTP; and a 3.5-fold stimulation by 50 mM KCl. The enzyme is sensitive to N-ethylmaleimide (1 mM), heparin (0.1 muM), ethanol (5%), pyrophosphate (0.05 muM), and o-phenanthroline (0.1 mM) but is insensitive to rifamycin. Denatured DNA is found to be the best natural template, and only negligible activity can be demonstrated with the ribopolymer templates poly(dT)n-poly(rA)n and p(dT)10-poly(rA)n. In addition to the polymerization reaction, the enzyme catalyzes a pyrophosphate exchange reaction. Antibody to calf thymus 6-8S DNA polymerase does not inhibit DNA polymerase from Vinca rosea, suggesting no antigenic relationships between the mammalian and plant enzymes.