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     

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 of DNA polymerase II, a distinct DNA polymerase, from Saccharomyces cerevisiae

Yeast DNA polymerases I and III have been well characterized physically, biochemically, genetically and immunologically. DNA polymerase II is present in very small amounts, and only partially purified preparations have been available for characterization, making comparison with DNA polymerases I and III difficult. Recently, we have shown that DNA polymerases II and III are genetically distinct (Sitney et al., 1989). In this work, we show that polymerase II is also genetically distinct from polymerase I, since polymerase II can be purified in equal amounts from wild-type and mutant strains completely lacking DNA polymerase I activity. Thus, yeast contains three major nuclear DNA polymerases. The core catalytic subunit of DNA polymerase II was purified to near homogeneity using a reconstitution assay. Two factors that stimulate the core polymerase were identified and used to monitor activity during purification and analysis. The predominant species of the most highly purified preparation of polymerase II is 132,000 Da. However, polymerase activity gels suggest that the 132,000-Da form of DNA polymerase II is probably an active proteolytic fragment derived from a 170,000-Da protein. The highly purified polymerase fractions contain a 3'----5'-exonuclease activity that purifies at a constant ratio with polymerase during the final two purification steps. However, DNA polymerase II does not copurify with a DNA primase activity.     

Interaction between Auxin–binding Protein–I and RNA Polymerase II

Interactions between auxin–binding protein–I (ABP–I), purified from etiolated mung bean seedlings, and nuclear components from mung bean tissues were investigated. When NaCI–solubilized components of chromatin were put on an affinity column of ABP–I–Iinked Sepharose 4B, a small amount of the material was retained on the affinity column and was eluted with 1 M NaCl. RNA polymerase II activity was detected in the eluted fraction. Partially purified RNA polymerase II from mung bean nuclei and purified RNA polymerase II from wheat germ also bound to ABP–I. Indole–3–acetic acid was not necessary for the binding of RNA polymerase II to ABP–I. Acid–denatured ABP–I did not bind to RNA polymerase II from wheat germ. The addition of ABP–I to the reaction mixture for RNA synthesis in vitro caused a stimulation of the activity of wheat germ RNA polymerase.     

Mouse Brain DNA-Dependent RNA Polymerases After Chronic Morphine Treatment

Abstract: Chronic morphine pellet implantation was found to decrease the specific activity of two forms of mouse brain RNA polymerase I and to alter the requirements of Mg²⁺ and Mn²⁺ for the activities of RNA polymerases II and III. DNA-dependent RNA polymerases were partially purified from small dense nuclei isolated from brains of naive and morphine tolerant-dependent mice, and three RNA polymerases were separated on a DEAE-Sephadex A-25 column. The three fractions, referred to as peak I, peak II, and peak III, were studied, characterized, and identified as being RNA polymerases I, II, and III, respectively. Chronic-morphine pellet implantation resulted in a lower specific activity of RNA polymerase I, but the specific activities of RNA polymerases II and III were not affected. This effect was prevented by preimplantation of a naloxone pellet and thus was narcotic-specific. Chronic morphine treatment lowered the concentration of Mg²⁺ required for optimal activity of RNA polymerase II and elevated the Mn²⁺-Mg²⁺ activity ratios of RNA polymerases II and III. A second DEAE-Sephadex A-25 column chromatography of the peak I RNA polymerase was carried out, revealing five component activity peaks. Two of these contained lower specific activities as a result of chronic morphine pelletimplantation. These specific changes in RNA polymerase function in morphine tolerance-dependence may be associated with the elevated chromatin template activities, altered chromatin phosphorylation, and elevated rates of cell-free translation that have been reported by others.     

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.     

Studies on the molecular species of DNA polymerase extracted from rat ascites hepatoma cells.

DNA polymerase [EC 2.7.7.7] activities present in hypotonic extract from rat ascites hepatoma AH130 cells were eluted in three separable peaks on DEAE-cellulose column chromatography. Peak I activity had an alkaline pH optimum, and was relatively resistant to SH-blocking reagents and salt concentration. These properties of DEAE peak I are typical of low molecular weight DNA polymerase. DEAE peak II and peak III activities possessed properties corresponding to high molecular weight (6-8 S) polymerase; they showed maximal activity at neutral pH, and were sensitive to SH-blocking reagents and salt. No low molecular weight polymerase activity was released from DEAE peak II or peak III by salt treatment, though partial conversion from DEAE peak II to peak III was observed on the same treatment.     

Purification by sucrose density gradient zonal centrifugation and affinity column chromatography of antigenic substances from the livers of mice infected with Tyzzer's disease

Antigenic substances from livers of mice infected with Tyzzer's disease were purified by means of sucrose density gradient zonal centrifugation and affinity column chromatography using antiserum and checking antigenicity with the complement fixation test. Fractions obtained from zonal centrifugation fell into three main groups with different molecular weights, two of which (Fr. I and Fr. II) positively reacted with antiserum in the complement fixation tests. Both fractions were further purified by affinity column chromatography. The molecular weights of the main antigenic substances derived from Fr. I and Fr. II were determined to be about 52 000 and 66 000, respectively, by means of SDS-PAGE.     

绿豆子叶脱分化过程中RNA聚合酶的制备、特性及其活性的研究

绿豆(Phaseolus vadiatus L.)子叶切段在脱分化形成愈伤组织过程中,制备的染色质具有较高的RNA聚合酶活力,3天愈伤组织的酶活力高于5天和7天的;3天、5天和7天加激素脱柱依次分分化形成的愈伤组织,其酶活力均比不脱分化的高一倍以上, 用DEAE —纤维素酶部,依据层析洗脱性质和层析图谱及对d—鹅膏菌素的敏感程度,证明三个峰是RNA聚合I,II和III。     

Deoxyribonucleic acid polymerases of BHK-21/C13 cells. Partial purification and characterization of the enzymes.

DNA polymerase from BHK-21/C13 cells were separated into two species, DNA polymerase I corresponding to the heterogeneous enzyme with sedimentation coefficient of 6-8S, and DNA polymerase II, corresponding to the enzyme with sedimentation coefficient of 3.3S. DNA polymerase I was purified 114-fold and DNA polymerase II 154-fold by a simple extraction procedure followed by column chromatography on phosphocellulose and gel filtration through Sephadex G-100. The purified enzymes differed markedly in respect of pH optimum, stimulation and inhibition by K+, Km for the deoxyribonucleoside 5'-triphosphates, stability to heating at 45 degrees C, and inhibition by N-ethylmaleimide. The preferred primer-template for both enzymes was "activated" DNA (DNA submitted to limited degradation by pancreatic deoxyribonuclease); native or thermally denatured DNA templates were relatively very poorly copied. When certain synthetic templates were tested, substantial differences were revealed between the two enzymes. Poly[d(A-T)] was poorly used by polymerase I but was superior to "activated" DNA for polymerase II. Poly[d(A)]-oligo[d(pT)10] was used efficiently by polymerase I but not by polymerase II. Poly(A)-oligo[d(pT)10] was not an effective primer-template although polymerase I could use it to a limited extent when Mn2+ replaced Mg2+ in the polymerase reaction and when the temperature of incubation was lowered from 37 degrees to 30 degrees C. When only one or two or three triphosphates were supplied in the reaction mixture, the activity of polymerase I was more severly diminished than that of polymerase II.     

Purification using polyethylenimine precipitation and low molecular weight subunit analyses of calf thymus and wheat germ DNA-dependent RNA polymerase II

DNA-dependent RNA polymerase II from calf thymus has been successfully purified using polythylenimine precipitation. Thus, 5-6 mg of nearly homogeneous homogeneous trna polymerase II (greater than 96% pure) can be prepared from 1 kg of calf thymus with three chromatography steps following extraction and precipitation of the enzyme from the polyethylenimine pellet. This procedure eliminates the high salt extraction of chromatin previously used in purification of this enzyme and makes possible the large scale preparation of mammalian RNA polymerase II. Calf thymus polymerase II prepared by this method is greater than 90% form IIb and consists of ten different subunits having the following molecular weights: 180 000; 145 000; 36 000; 25 000; 20 000; 18 500; 16 000; 15 000; 12 000; 11 500. The homologous enzyme isolated from wheat germ is greater than 90% form IIa and contains subunits of the following molecular weights: 206 000; 145 000; 44 000-47 000; 24 500; 21 000; 19 000; 17 000; 14 000; 13 500. The wheat germ and calf thymus enzymes exhibit similar subunits structures, but the molecular weights of individual subunits are clearly different between the enzymes. Wheat germ RNA polymerase II is 50% inhibited by 0.271 microng/mL of alpha-amanitin, a level 30-fold higher than that found for calf thymus RNA polymerase II. These enzymes are further distinguished by the absence of antigenic cross reactivity.     

Mapping of the active site of T7 RNA polymerase with 8-azidoATP.

The photoaffinity analog of ATP, 8-azidoATP, labels T7 RNA polymerase. Photoincorporation exhibits saturation behavior and is protected against by the substrate ATP. 8-AzidoATP is a competitive inhibitor of ATP incorporation with Ki approximately 40 microM. The photolabeled T7 RNA polymerase, following cyanogen bromide digestion, was analyzed by phenylboronate agarose column chromatography followed by reverse-phase high pressure liquid chromatography. Sequencing of the peptides labeled with radioactive photoprobe allowed the identification of three peptides, P314-M362 (I), L550-M666 (II), and F751-M861 (III). These peptides are in the proximity of the photoprobe 8-azidoATP and, therefore, expected to contain functionally significant residues and define an active site domain. These peptides (I and II) contain residues previously implicated in T7 RNA polymerase activity or show homology to active site regions of the Klenow fragment of DNA polymerase I (II and III).     

Deoxyribonucleic acid-dependent ribonucleic acid polymerase activity in rat liver after protein restriction.

Rats were fed for 6 days on a diet containing either 3 or 20% high-quality protein. Nuclei were isolated from liver and DNA-dependent RNA polymerases (EC 2.7.7.6) extracted with 1 M-(NH4)2SO4. The proteins were then precipitated with 3.5 M-(NH4)2SO4 and after dialysis applied to a DEAE-Sephadex column. The column was developed with a gradient of (NH4)2SO4. Polymerase I separated well from alpha-amanitin-sensitive polymerase II. The enzyme activities were compared between the two dietary groups. Rats that had received 3% protein showed a lower polymerase I activity per g wet wt. of liver, per mg of DNA and per mg of protein. Polymerase II was lower in activity per g wet wt. of liver and per mg of DNA, but was higher per mg of protein. Polyacrylamide-gel electrophoretograms showed a higher proportion of contaminating proteins in polymerase II fractions isolated from 20%-protein-fed rats. The data explain the lower activity obtained per mg of protein in these rats. It is concluded that a decrease in dietary protein content from 20 to 3% induces a fall in content and specific activity of RNA polymerase I and II in liver.     

Partial purification and characterization of DNA-dependent RNA polymerases I and II from cherry salmon (Oncorhynchus masou)

1. DNA-dependent RNA polymerases I and II were purified approx 3900- and 13,000-fold, respectively, from sonicated nuclear extract of cherry salmon (Oncorhynchus masou) liver by DEAE-Sephadex, heparin-Sepharose and DNA-cellulose column chromatography. 2. The purified RNA polymerases exhibited a requirement for four kinds of ribonucleoside 5'-triphosphates, an exogeneous template and divalent cation. 3. The activities of RNA polymerases I and II were inhibited by Actinomycin D (24 micrograms/ml) but not by Rifampicin (200 micrograms/ml). 4. RNA polymerase I preferred native DNA as template, while polymerase II preferred single-stranded DNA. 5. RNA polymerase II was inhibited by a low concentration of alpha-amanitin (0.02 micrograms/ml). RNA polymerase I was also inhibited by the relatively high concentration of alpha-amanitin (IC50 = 100 micrograms/ml and IC70 = 750 micrograms/ml). 6. RNA polymerases from cherry salmon exhibited a higher activity at low temperature than from rat liver.     

The cellulase of Trichoderma viride. Purification, characterization and comparison of all detectable endoglucanases, exoglucanases and beta-glucosidases

Six endoglucanases (Endo I; II; III; IV; V; VI), three exoglucanases (Exo I; II; III) and a beta-glucosidase (beta-gluc I) were isolated from a commercial cellulase preparation derived from Trichoderma viride, using gel filtration on Bio-Gel, anion exchange on DEAE-Bio-Gel A, cation exchange on SE-Sephadex and affinity chromatography on crystalline cellulose. Molecular masses were determined by polyacrylamide gel electrophoresis. One group of endoglucanases (Endo I, Endo II and Endo IV) with Mr of 50 000, 45 000 and 23 500 were more random in their attack on carboxymethylcellulose than another group (Endo III, Endo V and Endo VI) showing Mr of 58 000, 57 000 and 53 000 respectively. Endo III was identified as a new type of endoglucanase with relatively high activity on crystalline cellulose and moderate activity on carboxymethylcellulose. Exo II and Exo III with Mr of 60 500 and 62 000 respectively showed distinct adsorption affinities on a column of crystalline cellulose and could be eluted by a pH gradient to alkaline regions. These enzymes were cellobiohydrolases as judged by high-pressure liquid chromatography of the products obtained from incubation with H3PO4-swollen cellulose. It was concluded that these exoglucanases are primarily active on newly generated chain ends. Exo I was essentially another type of exoglucanase which in the first instance was able to split off a cellobiose molecule from a chain end and then hydrolyse this molecule in a second step to two glucose units beta-Gluc I was a new type of aryl-beta-D-glucosidase which had no activity on cellobiose. The enzyme had a Mr of 76 000 and was moderately active on CM-cellulose, crystalline cellulose and xylan and highly active on p-nitrophenyl-beta-D-glucose and p-nitrophenyl-beta-D-xylose.     

The polyadenylate polymerases from yeast.

Poly(A) polymerase activity was first detected in yeast extracts, primarily in association with the ribosomal fraction, by Twu and Bretthauer in 1971 (Twu, J. S., and Bretthauer, RK. (1971) Biochemistry 10, 1576-1582). This activity has now been separated into three distinct enzymes by chromatography on DEAE-cellulose. Each of the three enzymes can catalyze the incorporation of adenylate residues from ATP into a polyadenylate (poly(A)) tract at the 3' terminus of a primer RNA. Enzyme I elutes at 0.07 M ammonium sulfate from the DEAE-cellulose column, utilizes the mixed polynucleotide poly(A,G,C,U) or ribosomal RNA most efficiently in vitro, and may be responsible in vivo for the initiation of the poly(A) tracts found on yeast messenger RNA. Enzyme II elutes from the column at 0.20 M ammonium sulfate, requires poly(A) itself or an RNA primer containing a 3'-oligo(A) tract, and may be responsible in the nucleus for the elongation of tracts initiated by enzyme I. Enzyme III elutes from the column at 0.56 M ammonium sulfate and is present in low amounts in nuclear extracts. It may be involved in adding poly(A) tracts to messenger RNA in mitochondria. These enzymes also have the intrinsic capacity for the incorporation of cytidylate residues from CTP, which correlates with the finding of cytidylate residues in the poly(A) tracts present in the yeast RNA which is rapidly labeled in vivo. About 75% of the total poly(A) polymerase activity of yeast is enzyme I, most of which is present in the soluble protein fraction of the whole yeast extract. About 20% of the total poly(A) polymerase is enzyme II, and 1 to 5% is enzyme III. All three of the yeast poly(A) polymerases require an RNA primer with a free 3'-hydroxyl group, show no requirement for a DNA template, require Mn-2+ for optimal activity, have pH optima of 8.5, and are inhibited by GTP, CTP, UTP, and native yeast DNA. Polymerases I and II have similar molecular weights by gel filtration.     

Purification and characterization of two distinct Ca2+-activated proteinases from hearts of hypertensive rats

Two distinct Ca2+-activated proteinases were purified and characterized from hearts of hypertensive rats. Ca2+-activated proteinases I and II, having low and high Ca2+ requirements, respectively, were first separated by DEAE-cellulose chromatography. The enzymes were then purified individually by different column procedures: chromatography on phenyl-Sepharose, then Sephadex G-200 for proteinase I and reactive-red agarose for proteinase II. The apparent molecular weight of purified proteinase I was 125 000 and that for purified proteinase II was 110 000. Both enzymes are heterodimers made up of a larger catalytic subunit and a smaller subunit devoid of proteinase activity. Ca2+ concentrations for half-maximal activation were 5 microM for proteinase I and 200 microM for proteinase II. Both enzymes were inhibited by sulfhydryl-modifying agents, but exhibited different characteristics in the auto-digestion reaction in the presence of Ca2+. Proteinases I and II were also purified from hearts of normotensive rats and shown to be identical to their respective counterparts from hearts of hypertensive rats. However, proteinase II activity in hypertensive rat hearts was significantly elevated as compared to controls.