Characterization of polyriboadenylate polymerase from Tetrahymena pyriformis.

Poly(A) polymerase [polyadenylate nucleotidyltransferase, EC 2.7.7.19] was extracted from Tetrahymena pyriformis. The enzyme was demonstrated to be present in three forms by column chromatography on DEAE-cellulose, and they were termed poly(A) polymerase Ia, Ib, and II in order of increasing affinity to the column. The properties of enzymes Ia and Ib were similar except that Ia utilizes poly(A) as a primer rather efficiently. Enzyme II differed from enzymes Ia and Ib not only in elution profile on DEAE-cellulose column chromatography but also in pH and temperature preferences, molecular weight, requirement for divalent cations, sensitivity to salts at high ionic strength, optimal primer concentration, and subcellular localization. The molecular weights of enzymes Ia and Ib measured by gel filtration were both 43,000, and that of enzyme II was 95,000. All three enzymes required Mn2+ for maximal activity; Mg2+ could replace Mn2+ in the reaction of enzyme II, but only partially. In the presence of 0.1 M ammonium sulfate the activities of enzymes Ia and Ib were both completely inhibited, whereas enzyme II still showed 42% of its original activity. These findings suggest that there are two distinct types of poly(A) polymerase in Tetrahymena pyriformis.     

Two distinct poly(A) polymerases isolated from the cytoplasm of Ehrlich ascites tumour cells

The poly(A) polymerases from the cytosol and ribosomal fractions of Ehrlich ascites tumour cells are isolated and partially purified by DEAE-cellulose and phosphocellulose column chromatography. Two distinct enzymes are identified: (a) a cytosol Mn2+-dependent poly(A) polymerase (ATP:RNA adenylyltransferase) and (b) a ribosome-associated enzyme defined tentatively as ATP(UTP): RNA nucleotidyltransferase. The cytosol poly(A) polymerase is strictly Mn2+-dependent (optimum at 1 mM Mn2+) and uses only ATP as substrate, poly(A) is a better primer than ribosomal RNA. The purified enzyme is free of poly(A) hydrolase activity, but degradation of [3H]poly(A) takes place in the presence of inorganic pyrophosphate. Most likely this enzyme is of nuclear origin. The ribosomal enzyme is associated with the ribosomes but it is found also in free state in the cytosol. The purified enzyme uses both ATP and UTP as substrates. The substrate specificity varies depending on ionic conditions: the optimal enzyme activity with ATP as substrate is at 1 mM Mn2+, while that with UTP as substrate is at 10--20 mM Mg2+. The enzymes uses both ribosomal RNA and poly(A) [but not poly(U)] as primers. The purified enzyme is free of poly(A) hydrolase activity.     

Characterization of a polyriboadenylate polymerase from vaccinia virions.

A poly(A) polymerase with a molecular weight of approximately 80,000 containing 51,000 and 35,000 molecular weight subunits, was purified by affinity chromatography from vaccinia virus cores. The enzyme had a pH optimum of about 8.6, was dependent on divalent cations, and had considerably more activity with Mn-2+ than Mg-2+. At equimolar concentrations, other ribonucleoside triphosphates inhibited poly(A) polymerase activity by less than 10%; NaCl was extremely inhibitory at concentrations above 0.1 M. Under standard assay conditions, poly(A) polymerase activity was stimulated more than 10-fold by poly(C), but to small extent or not at all by other homopolyribonucleotides or natural RNA species unless they were first subjected to partial hydrolysis and alkaline phosphatase treatment. The ineffectiveness of most long polyribonucleotides was attributed to enzyme binding to internal regions. Short poly- or oligoribonucleotides prepared from natural or synthetic RNAs, except poly(G), exhibited similar priming abilities, and isotope transfer experiments indicated the covalent attachment of poly(A) to cytidylate, uridylate, and inosinate residues. Experiments with a series of uridylate oligomers indicated that the minimum effective primer length was four to six nucleotides. Partially digested DNA and short poly- and oligodeoxyribonucleotides of dT, dC, and dI, but not of dA and dG, also acted as effective primers for the poly(A) polymerase.     

Isolation of a foot-and-mouth disease polyuridylic acid polymerase and its inhibition by antibody

A template-dependent polyuridylic acid [poly(U)] polymerase has been isolated from BHK cells infected with foot-and-mouth disease virus (FMDV). Enzyme activity in a 20,000 x g supernatant of a cytoplasmic extract was concentrated by precipitation with 30 to 50% saturated ammonium sulfate. The poly(U) polymerase was freed of membranes by sodium dodecyl sulfate and 1,1,2-trichlorotrifluoroethane extraction, and RNA was removed by precipitation with 2 M LiCl. The solubilized poly(U) polymerase required polyadenylic acid as template complexed to an oligouridylic acid primer and Mg2+ for activity, but was inhibited by Mn2+. Antisera from animals infected with FMDV had previously been shown to inhibit the activity of FMDV RNA replicase complexed to the endogenous RNA template. The same antisera also inhibited the activity of poly(U) polymerase. Antisera depleted of antibody by absorption with the virus infection-associated antigen of FMDV no longer inhibited replicase and polymerase activities. The evidence suggests that FMDV RNA replicase, poly(U) polymerase, and the virus infection-associated antigen share a common protein.     

Mitochondrial poly(A) polymerase from a poorly differentiated hepatoma: purification and characteristics.

Poly(A) polymerase (EC 2.7.7.19) solubilized from mitochondria of a poorly differentiated rat tumor, Morris hepatoma 3924A, was purified more than 1000-fold by successive column chromatography on phosphocellulose, DEAE-Sephadex, and hydroxylapatite. Purified enzyme catalyzed the incorporation of ATP into poly(A) only upon addition of an exogenous primer. Of several primers tested, synthetic poly(A) was the most effective. The enzyme utilized mitochondrial RNA as a primer at least five times as efficiently as nuclear RNA. The enzyme required Mn2+, and had a pH optimum of 7.8-8.2. The enzyme utilized ATP exclusively as a substrate; the calculated K-m for ATP was 28 muM. The polymerization reaction was not inhibited by RNase, ethidium bromide, distamycin, or alpha-amanitin. The reaction was sensitive to O-n-octyloxime of 3-formylrifamycin SV (AF/013). As estimated from glycerol gradient centrifugation and acrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, the molecular weight of the enzyme was 60,000. The product was covalently linked to the polynucleotide primer and the average length of the poly(A) formed was 600 nucleotides.     

Primer specificity of ribosome-associated poly(A) polymerase from Ehrlich ascites tumour cells

The reaction product of the ribosomal poly(A) polymerase [ATP(UTP):RNA nucleotidyltransferase] is analyzed. Two systems are used in vitro: (a) isolated polyribosomes with endogenous enzyme and RNA primer and (b) purified enzyme with total polyribosomal RNA as primer. In the polyribosome system about 50% of the [3H]AMP label is in poly(A)-containing mRNA. This RNA displays a heterogeneous size ditribution in the range of 8--30 S with a maximum at about 14 S. Upon denaturation the maximum is shifted towards the 10-S zone. The poly(A) polymerase catalyzes the addition of 12--18 adenylate residues to pre-existing mRNA poly(A) sequences of 40--160 residues. The [3H]AMP incorporated into poly(A)-lacking RNA is mainly in a fraction with an electrophoretic mobility corresponding to 4-S RNA. In the purified enzyme system, specificity towards poly(A)-containing mRNA is lost to a considerable extent. Only 10% of the [3H]AMP label is retained by oligo(dT)-cellulose. The bulk of the product is in 18-S rRNA and heterogeneous small molecular weight RNA. We conclude that the ribosome-associated poly(A) polymerase is most likely the enzyme responsible for the cytoplasmic polyadenylation of poly(A)-containing mRNA in vivo.     

Poly(A) Polymerase from Vaccinia Virus-Infected Cells I. Partial Purification and Characterization

Poly(A) polymerase activity is induced during vaccinia virus infection of HeLa cells. The enzyme is maximally induced at 3.5 h postinfection. Partial purification frees the preparation of RNase activity and RNA polymerase activity. ATP is the substrate for poly(A) synthesis. A small amount of poly(A) is produced from added adenosine diphosphate due to the production of ATP by an adenylate kinase present in the preparation. The incorporation of ATP into poly(A) is dependent on divalent cations (Mg²⁺ or Mn²⁺) and is not inhibited by UTP, CTP, or GTP. Poly(U) stimulates ATP incorporation; poly(A) and poly(C) have little effect on ATP incorporation, and poly(dT) is extremely inhibitory. RNA prepared from HeLa cells and from the partially purified poly(A) polymerase (the enzyme preparation contains endogenous RNA [Brakel and Kates]) stimulates ATP incorporation by poly(A) polymerase which was subjected to DEAE-cellulose chromatography. RNase's, pancreatic and T₁, inhibit the production of poly(A). DNase has little effect. Poly(U) is able to stimulate poly(A) production in the presence of T₁ RNase.     

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).     

Polyadenylate polymerase from cytoplasm and nuclei of N.I.H.-Swiss mouse embryos.

Poly (A) polymerase activity from cytoplasm and nuclei of 12-16-day-old mouse embryos has been partially purified by (NH4)2SO4 fractionation, DEAE-cellulose, phosphocellulose and tRNA-Sepharose affinity chromatography, and their properties have been compared. The nuclear and cytoplasmic enzymes exhibit similar chromatographic elution profiles, and similar biochemical and physical properties. Poly(A) polymerase has an absolute requirement for a divalent cation, ATP and an oligo- or polyribonucleotide primer. With tRNA, the divalent salt concentrations for optimum enzyme activity are 1 mM MnCl2 or 10 mM MgCl2. The enzyme activity with MnCl2 is 10-15-fold higher than that with MgCl2. The molecular weight of the native enzyme is about 65 000 and its sedimentation coefficient is around 4.5 S. The average chain length synthesized by the enzyme is between 10 and 13 nucleotides. The inhibitors of RNA polymerase do not affect poly (A) polymerase activity; however, some synthetic rifamycin SV derivatives are potent inhibitors of this enzyme.     

DNA polymerases from bakers' yeast.

Two DNA polymerases are present in extracts of commercial bakers' yeast and wild type Saccharomyces cerevisiae grown aerobically to late log phase. Yeast DNA polymerase I and yeast DNA polymerase II can be separated by DEAE-cellulose, hydroxylapatite, and denatured DNA-cellulose chromatography from the postmitochondrial supernatants of yeast lysates. The yeast polymerases are both of high molecular weight (greater than 100,000) but are clearly separate species by the lack of immunological cross-reactivity. Analysis of associated enzyme activities and other reaction properties of yeast DNA polymerases provides additional evidence for distinguishing the two species. Enzyme I has no associated nuclease activity but does carry out pyrophosphate exchange and pyrophosphorolysis reactions, and has an associated 3'-exonuclease activity. Enzyme I does not degrade deoxynucleoside triphosphates and cannot utilize a mismatched template. Enzyme II does carry out a template-dependent deoxynucleoside triphosphate degradation reaction and can excise mismatched 3'-nucleotides from suitable template systems. Earlier studies have shown that both Enzyme I and Enzyme II are inhibited by N-ethylmaleimide. The yeast enzymes are not identical to any known eukaryotic or prokaryotic DNA polymerases. In general, Enzyme I appears to be most similar to eukaryotic DNA polymerase alpha and Ezyme II exhibits properties of prokaryotic DNA polymerases II and III.     

The primer specificity of cytoplasmic poly(A) polymerase from cryptobiotic gastrulae of Artemia salina

Poly(A) polymerase has been purified to near homogeneity from the cytoplasm of Artemia salina as described previously (Roggen, E and Slegers, H. (1985) Eur. J. Biochem. 147, 225–232). Affinity chromatography on poly(A)-Sepharose 4B separates the enzyme preparation into two fractions. In standard assay conditions poly(A) polymerase fraction I (poly(A)-Sepharose 4B unbound) and fraction II (poly(A)-Sepharose 4B bound) have specific activities of 2.4 and 8.0 μmol AMP/h per mg enzyme, respectively. Poly(A) polymerase fraction II shows a high primer specificity towards the 17 S poly(A)-containing mRNP. Depending on the reaction conditions used, poly(A) sequences of 140 ± 15 AMP residues/μg enzyme are synthesized on the latter primer. In contrast, poly(A) polymerase fraction I only elongates oligo(A) primers efficiently. An endogenous RNA is detected in poly(A) polymerase II preparations. This RNA has a length of 83 ± 2 nucleotides and is a component of a 60 kDa particle. After removal of the latter the specificity of poly(A) polymerase fraction II for the 17 S poly(A)-containing mRNP is abolished and the characteristics of the enzyme resemble those of poly(A) polymerase I.     

Polyadenylic acid synthesis activity of purified DNA-dependent RNA polymerase from Caulobacter

Characterization of purified DNA-dependent RNA polymerase (EC 2.7.7.6) of Caulobacter crescentus, strain CB15 has led to the conclusion that this enzyme catalyzes poly(A) synthesis in the absence of template. Poly(A) synthetase activity co-purifies with both holoenzyme and core polymerase on DNA-cellulose columns, and core polymerase purified to 98% homogeneity by glycerol gradient centrifugation is still capable of catalyzing poly(A) polymerization. Both RNA synthesis and poly(A) polymerization activities are sensitive to rifampicin. In addition, RNA polymerase purified from partially rifampicin-sensitive mutants exhibits the same partial sensitivity in vitro to the drug in the synthesis of RNA and poly(A). The enzyme used in these studies was prepared by a simple method which allows a high yield of pure RNA polymerase from large batches of exponential cells. The procedure includes high speed centrifugation of cell extracts, DEAE-cellulose column, DNA-affinity chromatography, and low salt glycerol gradient centrifugation. Holoenzyme can be resolved into core and sigma subunit by either DNA-cellulose chromatography or glycerol gradient centrifugation, and the latter step allows recovery of pure sigma factor.     

Isolation and characterization of polyadenylate-containing RNA from Bacillus brevis.

A substantial fraction (30--40%) of pulse-labeled RNA from exponentially growing cells of Bacillus brevis contains polyadenylate sequences, as measured by adsorption to oligo(dT)-cellulose. The weight-average length of poly(A) tracts obtained after digestion with pancreatic and T1 ribonucleases is 60 nucleotide residues. Susceptibility to degradation by snake venom phosphodiesterase after ribonuclease degradation indicates that the poly(A) sequences are located near the 3' ends of the RNA chains, but that in 40% of the material at least one internal pyrimidine nucleotide residue intervenes between the poly(A) tract and the 3'-hydroxyl terminus. These pyrimidine nucleotides consist of 65% cytidylate and 35% uridylate residues. In the remaining RNA chains, the poly(A) sequence is directly at the 3'-terminus, but the possibility cannot be excluded that a small fraction of this material may contain a 3'-hydroxyl terminal guanylate residue. The weight-average sedimentation coefficient of poly(A)-containing RNA is 12.5 S, corresponding to a polynucleotide chain length of 800--900 residues. This is in a size range expected for messenger RNA, a possibility which is also supported by the observation that pulse-labeled RNA has a considerably higher poly(A) content than long-term labeled RNA.     

Purification and properties of a low molecular weight DNA polymerase from Neurospora crassa

A third DNA polymerase 'C' with low molecular weight was isolated and purified 3700-fold from ground hyphae of Neurospora crassa WT 74 A, which shows similarities to beta- and gamma-polymerases from higher eukaryotes: preference for poly(rA)(dT) as a template/primer, inhibition by p-chloromercuribenzoate, resistance against N-ethylmaleimide up to 10 mmol/l, and molecular weight of about 40000. This polymerase elutes as a distinct peak from DEAE-cellulose at 0.60 mol/l KCl and has an optimum for K+ at 2-20 mmol/l, for Mn2+ at 0.8 mmol/l, for Mg2+ at 4.0 mmol/l, the pH optimum is 8.0. Its Km is 1.5 mumol/l using dTTP as substrate. The enzyme activity described here is free of endonuclease but contains detectable amounts of exonuclease.     

Inhibitory effects of various 3'-deoxyribonucleotides on DNA polymerase alpha 2-primase from developing cherry salmon (Oncorhynchus masou) testes

DNA polymerase alpha 2-primase has been purified 2750 fold from developing cherry salmon (Oncorhynchus masou) testes by the following purification steps: fractional extraction, phosphocellulose (1st), ammonium sulfate fractionation, DEAE-cellulose, phosphocellulose (2nd), hydroxylapatite and single-stranded DNA-cellulose column chromatographies. Final preparation of this enzyme has a specific activity of 107,000 units/mg protein (activated salmon sperm DNA as template-primer). DNA primase activity (rGTP dependent incorporation of labelled dGMP into poly (dC) or rNTP dependent incorporation of dNMP into M13 single-stranded DNA) was tightly associated with DNA polymerase alpha activity during all stage of this purification process. Inhibition of DNA primase activity by six kinds of 3'-deoxyribonucleotides was studied by using rNTP dependent DNA synthesis on M13 DNA as template. The inhibition constants (Ki) were larger than those of DNA-dependent RNA polymerases I and II. However, Ki/Km values were very close.     

DNA polymerase I and DNA primase complex in yeast

Chromatographic analysis of poly(dT) replication activity in fresh yeast extracts showed that the activities required co-fractionate with the yeast DNA polymerase I. Since poly(dT) replication requires both a primase and a DNA polymerase, the results of the fractionation studies suggest that these two enzymes might exist as a complex in the yeast extract. Sucrose gradient analysis of concentrated purified yeast DNA polymerase I preparations demonstrates that the yeast DNA polymerase I does sediment as a complex with DNA primase activity. Two DNA polymerase I peptides estimated at 78,000 and 140,000 Da were found in the complex that were absent from the primase-free DNA polymerase fraction. Rabbit anti-yeast DNA polymerase I antibody inhibits DNA polymerase I but not DNA primase although rabbit antibodies are shown to remove DNA primase activity from solution by binding to the complex. Mouse monoclonal antibody to yeast DNA polymerase I binds to free yeast DNA polymerase I as well as the complex, but not to the free DNA primase activity. These results suggest that these two activities exist as a complex and reside on the different polypeptides. Replication of poly(dT) and single-stranded circular phage DNA by yeast DNA polymerase I and primase requires ATP and dNTPs. The size of the primer produced is 8 to 9 nucleotides in the presence of dNTPs and somewhat larger in the absence of dNTPs. Aphidicolin, an inhibitor of yeast DNA polymerase I, is not inhibitory to the yeast DNA primase activity. The primase activity is inhibited by adenosine 5'-(3-thio)tri-phosphate but not by alpha-amanitin. The association of yeast DNA polymerase I and yeast DNA primase can be demonstrated directly by isolation of the complex on a column containing yeast DNA polymerase I mouse monoclonal antibody covalently linked to Protein A-Sepharose. Both DNA polymerase I and DNA primase activities are retained by the column and can be eluted with 3.5 M MgCl2. Part of the primase activity can be dissociated from DNA polymerase on the column with 1 M MgCl2 and this free primase activity can be detected as poly(dT) replication activity in the presence of Escherichia coli polymerase I.     

Nuclear and chloroplast poly(A) polymerases from plants share a novel biochemical property

Poly(A) polymerases are centrally involved in the process of mRNA 3' end formation in eukaryotes. In animals and yeast, this enzyme works as part of a large multimeric complex to add polyadenylate tracts to the 3' ends of precursor RNAs in the nucleus. Plant nuclear enzymes remain largely uncharacterized. In this report, we describe an initial analysis of plant nuclear poly(A) polymerases (nPAPs). An enzyme purified from pea nuclear extracts possesses many features that are seen with the enzymes from yeast and mammals. However, the pea enzyme possesses the ability to polyadenylate RNAs that are associated with polynucleotide phosphorylase (PNP), a chloroplast-localized enzyme involved in RNA turnover. Similar behavior is not seen with the yeast poly(A) polymerase (PAP). A fusion protein consisting of glutathione-S-transferase and the active domain of an Arabidopsis-encoded nuclear poly(A) polymerase was also able to utilize PNP, indicating that the activity of the pea enzyme was due to an interaction between the pea nPAP and PNP, and not to other factors that might copurify with the pea enzyme. These results suggest the existence, in plant nuclei, of factors related to PNP, and an interaction between such factors and poly(A) polymerases.