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.     

Poly(A) polymerase from Vigna unguiculata seedlings. A bifunctional enzyme responsible for both poly(A)-polymerizing and poly(A)-hydrolyzing activities

Poly(A)-specific ribonuclease was co-purified with poly(A) polymerase from Vigna unguiculata seedlings. Both activities were separated into two forms (enzymes I and II) by a final hydrophobic column chromatography. The enzyme I preparation, which was homogeneous as examined by SDS/PAGE, had both poly(A) polymerase and poly(A)-specific ribonuclease activities. The antibody raised to the enzyme I preparation precipitated both enzyme activities. These indicate that a single polypeptide (Mr 63,000) is responsible for both poly(A)-polymerizing and poly(A)-hydrolyzing activities. The poly(A)-specific ribonuclease was a 3'-exonuclease specific to single-stranded poly(A), forming 5'AMP as the sole reaction product. The hydrolytic activity required either Mn2+ or Mg2+ with different optimum concentrations, whereas the polymerizing activity required Mn2+ but not Mg2+. ATP and PPi had little or no effect on the poly(A)-specific ribonuclease activity.     

Characterization of two poly(A) polymerases from cultured hamster fibroblasts.

The enzymatic and physiochemical properties of poly(A) polymerases IIA and IIB from cultured hamster fibroblasts were investigated. The enzymes show an absolute requirement for Mn2+ as the divalent ion. Although Mg2+ alone is inactive, maximum activity is observed in the presence of both Mn2+ and Mg2+. An optimal pH of approx. 8 is found for polymerases IIA and IIB. The enzymes, however, differ somewhat in the pH curves as well as in the Mn2+ and Mg2+ concentration curves. Poly(A) polymerases IIA and IIB have an isoelectric point of about 6 and a sedimentation coefficient of 3.5--4 S. The molecular weights, obtained by gel filtration chromatography, are 145 000 and 155 000 for enzymes IIA and IIB, respectively. Poly(A) polymerases IIA and IIB can utilize a variety of natural and synthetic RNAs as well as DNA as primers. Poly(A) polymerase IIA is saturated at much lower concentrations of primer than enzyme IIB. On the other hand, the chain length of the product synthesized by polymerase IIA is independent of the primer concentration, whereas, with polymerase IIB, the length of the product decreases when the concentration of RNA is increased.     

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.     

Protozoan hemoglobin from Tetrahymena pyriformis. Isolation, characterization, and amino acid sequence

A hemoprotein that can be defined as hemoglobin based on oxygen binding was isolated from Tetrahymena pyriformis. The protein exists in monomeric form and is separated into four fractions (Ia, Ib, IIa, and IIb) on a CM-cellulose column. From examinations of the absorption spectra and the N-terminal sequence, fractions Ia and Ib were assigned to the oxy-form and its met-form, respectively, of the one protein, while IIa and IIb corresponded to those of the other one. The complete amino acid sequence was therefore determined of fractions I and II. The I was composed of 121 amino acid residues, with the N-terminal serine being blocked. The II, on the other hand, consisted of 119 amino acid residues, its sequence being exactly identical to that of the third residue, lysine, to the C-terminal lysine of the fraction I. Although the genomic multiplicity cannot be ruled out completely, we have concluded that fraction II is a degradation product of the fraction I by endogeneous proteases. The amino acid sequence of T. pyriformis hemoglobin is very unique and showed no notable degree of similarity with the other hemoglobins sequenced so far, but it was found to be 33.9% identical with Paramecium caudatum hemoglobin by a maximal alignment.     

Purification and characterization of the Tetrahymena pyriformis P-C bond forming enzyme phosphoenolpyruvate phosphomutase

In this paper the purification and characterization of the Tetrahymena pyriformis enzyme phosphoenolpyruvate phosphomutase are described. PEP phosphomutase was first fractionated from T. pyriformis cellular extract by using 70% ammonium sulfate. Chromatography of the crude protein fraction on a DEAE-cellulose column followed by phenyl-Sepharose column chromatography and then Bio-Gel P-200 column chromatography afforded pure PEP phosphomutase in an approximate overall yield of 70 units/150 g of cells. The maximum turnover number observed for PEP phosphomutase catalysis of the phosphonopyruvate----PEP reaction is 38 s-1 (25 degrees C). The enzyme was shown to be a homodimer of 38,000-dalton subunits and to require a divalent metal ion for activity. Mg2+ (relative Vm = 1), Co2+ (rel Vm = 0.5), Zn2+ (rel Vm = 0.4), and Mn2+ (rel Vm = 0.3) each satisfied the cofactor requirement. Binding of the physiological cofactor, Mg2+ (Ki = 0.3 mM at pH 7.5), and phosphonopyruvate (Km = 2 microM at pH 7.5) was found to be ordered, with cofactor binding preceding substrate binding. Within the pH range of 5-9 catalysis (Vm) was found to be pH independent, while phosphonopyruvate binding dropped at acidic and basic pH.     

Nuclear envelope glycoprotein with poly(A) polymerase activity of rat liver: isolation, characterization, and immunohistochemical localization

A protein with poly(A) polymerase activity has been identified and isolated from hepatic nuclear envelopes of rats to near homogeneity. The ability of the enzyme to bind to concanavalin A-agarose and to be eluted from the column with methyl alpha-D-mannopyranoside (0.2 M) as well as the inhibitory effects of alpha-mannosidase suggested that it was a glycoprotein. Poly(A) polymerase has an absolute requirement for a divalent cation, ATP, and an oligonucleotide primer. The enzyme activity with Mn2+ was about 20-fold higher than that with Mg2+. Several known inhibitors adversely affected poly(A) polymerase activity. The enzyme has a molecular weight of 64,000 when analyzed by polyacrylamide gel electrophoresis under denaturing conditions and has a sedimentation coefficient of 4.5 S. Immunohistochemical studies using polyclonal antibodies raised against the purified enzyme revealed that the antigen was localized in the nuclear membranes.     

Making DNA without iron - induction of a manganese-dependent ribonucleotide reductase in response to iron starvation

Ribonucleotide reductases supply cells with their deoxyribonucleotides. Three enzyme types are known, classes I, II and III. Class II enzymes are anaerobic whereas class I enzymes are aerobic, and so class I and II enzymes are often produced by the same organism under opposing oxygen regimes. Escherichia coli contains two types of class I enzyme (Ia and Ib) with the Fe-dependent Ia enzyme (NrdAB) performing the major role aerobically, leaving the purpose of the Ib enzyme (NrdEF) unclear. Several papers have recently focused on the class Ib enzymes showing that they are Mn (rather than Fe) dependent and suggesting that the E. coli NrdEF may function under redox-stress conditions. A paper published in this issue of Molecular Microbiology from James Imlay's group confirms that this unexplained NrdEF Ib enzyme is Mn-dependent, but shows that it does not substitute for NrdAB during redox stress. Instead, a role during iron restriction is demonstrated. Thus, the purpose of NrdEF (and possibly other class Ib enzymes) is to enhance growth under aerobic, low-iron conditions, and to functionally replace the Fe-dependent NrdAB when iron is unavailable. This finding reveals a new mechanism by which bacteria adjust to life under iron deprivation.     

Resolution and some properties of enzymes involved in enantioselective transformation of 1,3-dichloro-2-propanol to (R)-3-chloro-1,2-propanediol by Corynebacterium sp. strain N-1074.

During the course of the transformation of 1,3-dichloro-2-propanol (DCP) into (R)-3-chloro-1,2-propanediol [(R)-MCP] with the cell extract of Corynebacterium sp. strain N-1074, epichlorohydrin (ECH) was transiently formed. The cell extract was fractionated into two DCP-dechlorinating activities (fractions Ia and Ib) and two ECH-hydrolyzing activities (fractions IIa and IIb) by TSKgel DEAE-5PW column chromatography. Fractions Ia and Ib catalyzed the interconversion of DCP to ECH, and fractions IIa and IIb catalyzed the transformation of ECH into MCP. Fractions Ia and IIa showed only low enantioselectivity for each reaction, whereas fractions Ib and IIb exhibited considerable enantioselectivity, yielding R-rich ECH and MCP, respectively. Enzymes Ia and Ib were isolated from fractions Ia and Ib, respectively. Enzyme Ia had a molecular mass of about 108 kDa and consisted of four subunits identical in molecular mass (about 28 kDa). Enzyme Ib was a protein of 115 kDa, composed of two different polypeptides (about 35 and 32 kDa). The specific activity of enzyme Ib for DCP was about 30-fold higher than that of enzyme Ia. Both enzymes catalyzed the transformation of several halohydrins into the corresponding epoxides with liberation of halides and its reverse reaction. Their substrate specificities and immunological properties differed from each other. Enzyme Ia seemed to be halohydrin hydrogen-halide-lyase which was already purified from Escherichia coli carrying a gene from Corynebacterium sp. strain N-1074.     

Phosphoglucomutase from potato tubers. Chemical and catalytic properties.

The chemical and catalytic properties of potato phosphoglucomutase [EC 2.7.5.1] were studied using various enzyme species (Peaks Ia, Ib, Ic, and II; Takamiya, S. & Fukui, T. (1978) Plant Cell Physiol. 19, 319--328). The molecular weights of the species are all approximately 60,000. No indication of the presence of subunit structure was obtained under various conditions. The amino acid composition of Peak Ia is generally similar to those of the enzymes from other sources, though it has some peculiarities. The Peak Ia and Peak II enzymes both absolutely require alpha-D-glucose 1,6-bisphosphate and Mg2+ for activity, and appear to have a "ping-pong" mechanism. A low concentration of Be2+ inhibits their action, the inhibition being retarded either by Mg2 or EDTA. Although the inhibition patterns by various metabolites, are similar for Peaks Ia and II, they differ in their kinetic parameters and optimal pH values.     

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.     

Purification and characterization of a poly(A) polymerase from beef liver nuclei

Poly(A) polymerase [EC 2.7.7.19] was highly purified from beef liver nuclei by the use of column chromatographies on heparin-Sepharose 4B and Blue Dextran-Sepharose 4B. The purified enzyme showed one major protein band of the molecular weight of 57,000 in SDS polyacrylamide gel electrophoresis, which agreed with the molecular weight estimated from glycerol gradient centrifugation. The enzyme required the presence of Mn2+ for its activity but was almost completely inactive with Mg2+. It incorporated specifically ATP into polynucleotide as a sole substrate. The enzyme activity dependend entirely on the addition of exogenous polynucleotide primer. It showed certain selectivity for the primers. The most effective among the tested polynucleotides was a short poly(A), for which the Km of the enzyme was shown to be 7 microM. Poly(G, U) and short poly(U) also primed the reaction, but tRNA, phage RNA, poly(G), and poly(C) were inactive. Based on observed specificity for the primer, the role of this enzyme in the cell nuclei was discussed. Digestion of the reaction product of this enzyme by two specific exonucleases, snake venom and spleen phosphodiesterases, suggested that this enzyme catalyzed the covalent bonding of the substrate to the 3' terminus of the primer as in the manner expected for in vivo polyadenylation.     

Purification and characterization of a mammalian polyadenylate polymerase involved in the 3' end processing of messenger RNA precursors

A polyadenylate polymerase involved in the polyadenylation of pre-mRNA has been purified 6,000-fold to apparent homogeneity from extracts of calf thymus. In the last purification step, anion exchange chromatography separates the enzyme into three major peaks that are indistinguishable by other physical or functional criteria. On denaturing polyacrylamide gels, the two predominant forms of poly(A) polymerase have molecular weights of 57,000 and 60,000. In solution, the enzyme is a monomer. It polymerizes exclusively ATP. The reaction is distributive and proceeds linearly without any lag phase. The requirement for a primer can be satisfied by any of a number of polyribonucleotides. A significantly higher activity in the presence of Mn2+ as opposed to Mg2+ is due to a hundredfold higher affinity for the primer terminus. In the presence of mg2+ and of a specificity factor partially purified from HeLa cells, the enzyme specifically polyadenylates an RNA that ends at the natural adenovirus L3 polyadenylation site. This reaction depends on the AAUAAA polyadenylation signal.     

Deoxyribonucleic acid polymerases of Euglena gracilis. Primer-template utilization of and enzyme activities associated with the two deoxyribonucleic acid polymerases of high molecular weight.

The two high-molecular-weight DNA polymerases from Euglena gracilis, pol A (mol. wt. 190 000) and pol B (mol. wt. 240 000), were differentiated on the basis of associated enzymic activities and primer-template utilization. Neither enzyme had endodeoxyribonuclease activity, but pol B, like pol B of yeast and the corresponding enzyme from Tetrahymena pyriformis, exhibited at least one other nuclease activity directed against denatured DNA and the RNA of an RNA-DNA hybrid. These nuclease functions preferred an alkaline pH and Mg2+. Pol B also exhibited nucleoside diphosphokinase activity. Both enzymes were active with 'activated' DNA and poly[d(A-T)] as primer-templates and were sensitive, especially pol B, to inhibition by excess of native or heat-denatured DNA. Pol B also utilized oligo[d(T)] and poly(A) templates under certain conditions, whereas pol A exhibited only slight activity with poly[d(A)]. (U)6 was not used as a primer by either enzyme.     

Three forms of DNA polymerase from Drosophila melanogaster embryos. Purification and properties.

DNA polymerase was purified from Drosophila melanogaster embryos by a combination of phosphocellulose adsorption, Sepharose 6B gel filtration, and DEAE-cellulose chromatography. Three enzyme forms, designated enzymes I, II, and III, were separated by differential elution from DEAE-cellulose and were further purified by glycerol gradient centrifugation. Purification was monitored with two synthetic primer-templates, poly(dA) . (dT)-16 and poly(rA) . (dT)-16. At the final step of purification, enzymes I, II, and III were purified approximately 1700-fold, 2000-fold and 1000-fold, respectively, on the basis of their activities with poly(dA) . (dT)-16. The DNA polymerase eluted heterogeneously as anomalously high-molecular-weight molecules from Sepharose 6B gel filtration columns. On DEAE-cellulose chromatography enzymes I and II eluted as distinct peaks and enzyme III eluted heterogeneously. On glycerol velocity gradients enzyme I sedimented at 5.5-7.3 S, enzyme II sedimented at 7.3-8.3 S, and enzyme III sedimented at 7.3-9.0 S. All enzymes were active with both synthetic primer-templates, except the 9.0 S component of enzyme III, which was inactive with poly(rA) . (dT)-16. Non-denaturing polyacrylamide gel electrophoresis did not separate poly(dA) . (dT)-16 activity from poly(rA) . (dT)-16 activity. The DNA polymerase preferred poly(dA) . (dT)-16 (with Mg2+) as a primer-template, although it was also active with poly(rA) . (dT)-16 (with Mn2+), and it preferred activated calf thymus DNA to native or heat-denatured calf thymus DNA. All three primer-template activities were inhibited by N-ethylmaleimide. Enzyme activity with activated DNA and poly(dA) . (dT)-16 was inhibited by K+ and activity with poly(rA) . (dT)-16 was stimulated by K+ and by spermidine. The optimum pH for enzyme activity with the synthetic primer-templates was 8.5. The DNA polymerases did not exhibit deoxyribonuclease or ATPase activities. The results of this study suggest that the forms of DNA polymerase from Drosophila embryos have physical properties similar to those of DNA polymerase-alpha and enzymatic properties similar to those of all three vertebrate DNA polymerases.     

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.     

Poly(A) polymerase activity in ethionine-intoxicated rats: the relative effectiveness of disaggregated and intact polyribosomes as primers for poly(A) polymerase

Ethionine intoxication causes a change in the metabolism of poly(A) sequences on the 3' OH terminus of mRNA in rat liver in vivo. In an attempt to determine the factors responsible for these changes, nuclear and cytoplasmic poly(A) polymerase activities and the state of the primer were examined in vitro. Requirements for optimal enzyme activities were determined. The nuclear and cytoplasmic enzymes had different K+, Mn2+, and poly(A) primer optima. The levels of nuclear and cytoplasmic poly(A) polymerase activity were shown to decrease following ethionine intoxication. Poly(A)+ RNA isolated from the livers of saline- and ethionine-treated rats served equally well as primers for the cytoplasmic poly(A) polymerase.Disaggregated polysomes were seven times more effective as primers than were intact polysomes. The results suggest that the mRNP particle which is released from polysomes as a result of ethionine intoxication functions better as a poly(A) polymerase primer than does the intact polysome.     

Ca(2+)-calmodulin-dependent protein kinases Ia and Ib from rat brain I. Identification, purification, and structural comparisons.

Two Ca(2+)-calmodulin (CaM)-dependent protein kinases were purified from rat brain using as substrate a synthetic peptide based on site 1 (site 1 peptide) of the synaptic vesicle-associated protein, synapsin I. One of the purified enzymes was an approximately 89% pure protein of M(r) = 43,000 which bound CaM in a Ca(2+)-dependent fashion. The other purified enzyme was an apparently homogenous protein of M(r) = 39,000 accompanied by a small amount of a M(r) = 37,000 form which may represent a proteolytic product of the 39-kDa enzyme. The 39-kDa protein bound CaM in a Ca(2+)-dependent fashion. Gel filtration analysis indicated that both enzymes are monomers. The 43- and 39-kDa enzymes are named Ca(2+)-CaM-dependent protein kinases Ia and Ib (CaM kinases Ia, Ib), respectively. The specific activities of CaM kinases Ia and Ib were similar (5-8 mumol/min/mg protein). CaM kinase Ia (but not CaM kinase Ib) activity was enhanced by addition of a CaM-Sepharose column wash (non-binding) fraction suggesting the existence of an "activator" of CaM kinase Ia. Both kinases phosphorylated exogenous substrates (site 1 peptide and synapsin I) in a Ca(2+)-CaM-dependent fashion and both kinases underwent autophosphorylation. CaM kinase Ia autophosphorylation was Ca(2+)-CaM-dependent and occurred exclusively on threonine while CaM kinase Ib autophosphorylation showed Ca(2+)-CaM independence and occurred on both serine and threonine. Proteolytic digestion of autophosphorylated CaM kinases Ia and Ib yielded phosphopeptides of differing M(r). These characteristics, as well as enzymatic and regulatory properties (DeRemer, M. F., Saeli, R. J. Brautigen, D. L., and Edelman, A. M. (1992) J. Biol. Chem. 267, 13466-13471), indicate that CaM kinases Ia and Ib are distinct and possibly previously unrecognized enzymes.     

Nuclear poly(A) polymerase from rat liver and a hepatoma. Comparison of properties, molecular weights and amino acid compositions.

Poly(A) polymerase was extracted from isolated nuclei of rat liver and a rapidly growing solid tumor (Morris hepatoma 3924A). The enzyme from each tissue was purified by successive chromatography on DEAE-Sephadex, phosphoecllulose, hydroxyapatite and QAE-Sephadex. Purified enzyme from both liver and tumor was essentially homogeneous as judged by polyacrylamide gel electrophoresis. Under nondenaturing conditions, enzyme activity corresponded to visible protein and, upon denaturation, a single polypeptide was detected. The enzymes had absolute requirements for Mn2+ as the divalent ion, ATP as the substrate and an oligonucleotide or polynucleotide as the primer. Both enzymes were inhibited by sodium pyrophosphate, N-ethylmaleimide, Rose Bengal, cordycepin 5'-triphosphate and several rifamycin derivatives. The reactions were unaffected by potassium phosphate, alpha-amanitin and pancreatic ribonuclease. However, the liver and hepatoma enzymes differed from each other with respect to apparent Km, primer saturation levels and sensitivity to pH changes. The most striking differences between the enzymes were in their calculated molecular weights (liver, 48000; hepatoma, 60000) and amino acid compositions. Finally, the level of the hepatoma enzyme relative to that of the liver enzyme was at least 1.5-fold higher when expressed per mg DNA.     

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.