Poly(A) polymerase in quail oviduct. Changes during estrogen induction.

A nuclear poly(A) polymerase has been isolated from oviducts of immature quails. It could be purified 4300-fold. The enzyme depends specifically on ATP as substrate and requires Mg2+. The most effective primer for the enzyme is a polynucleotide, isolated from oviduct tissue. A poly(A) sequence to a maximum of 60 AMP residues is covalently linked per primer molecule. The poly(A)-rich product of the enzymatic reaction can be annealed to oligo(dT)-cellulose. The purest fraction does not contain any detectable poly(A)-degrading enzyme activity. Only very low activities of RNA polymerase are present. The poly(A polymerase activity in the assay with ATP is reduced by the ATP analogue, beta, lambda-ATP-methylene-diphosphonate. Both K-m and V are lowered. The ATP analogue is incorporated to a smaller extent into the poly(A) sequence, synthesized by the enzyme. Several other analogues of adenine, adenine nucleosides and adenine nucleotides are without effect on the enzymatic reaction. By these properties poly(A) polymerase can be distinguished from RNA polymerases form I and form II, isolated from the same tissue. Actinomycin D and alpha-amanitin failed to inhibit poly(A) polymerase activity. The activity of poly(A) polymerase has been determined during primary stimulation with the estrogen analogue diethylstilbestrol (daily injection for 5 days), after withdrawal of the hormone for 17 days and after secondary stimulation with the hormone analogue. The enzyme activity does not change during primary stimulation, withdrawal of the hormone or secondary stimulation. However the activity of a poly(A) degrading enzyme, localized in the nucleus, is reduced in oviducts from hormone-treated quails.     

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.     

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.     

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 poly(A) polymerase from Saccharomyces cerevisiae

Poly(A) polymerase was purified 22,000-fold to homogeneity from a whole cell extract of Saccharomyces cerevisiae with a yield of 22%. The enzyme is a monomeric polypeptide with a denatured molecular weight of 63,000. Incorporation of labeled ATP into acid-precipitable material by the purified enzyme proceeds faster with manganese than with magnesium ions. Various RNA homopolymers as well as Escherichia coli tRNA or rRNA can serve as primers. An RNA that terminates at the natural poly(A) site of the CYC1 gene is not more efficiently elongated than several nonspecific substrates, indicating the requirement for additional factors to provide specificity. Elongation of the primer is distributive. Covering of a poly(A) primer with poly(A)-binding protein reduces the enzyme's activity more than 10-fold.     

Properties of unprimed poly(A)-poly(U) synthesis by Caulobacter crescentus RNA polymerase.

Some properties of unprimed poly(A)-poly(U) synthesis by DNA-dependent RNA polymerase from Caulobacter crescentus were examined. The reaction required ATP and UTP as substrates and manganese as a divalent cation. Rifampicin completely inhibited the reaction at a concentration of 1 micron/ml, and the enzyme catalyzed the polymer synthesis well regardless of the presence of GTP, CTP or both. The chain length of the poly(A)-poly(U) synthesized was about one hundred base pairs, as estimated from a sedimentation velocity and the molar ratio of [3H]AMP to [gamma-32P]ATP incorporated into the poly(A)-poly(U). The reaction was dependent on the square of the enzyme concentration and the enzyme dimers formed complexes with poly(A)-poly(U) during the reaction.     

Utilization of ribonucleic acid and deoxyoligomer primers for polyadenylic acid synthesis by adenosine triphosphate: polynucleotidylexotransferase from maize.

The ATP:polynucleotidylexotransferase isolated and purified from maize seedlings catalyzes the synthesis of polyadenylic acid by the sequential addition of 80 to 200 AMP moieties from ATP to the 3'-hydroxyl terminus of either ribo- or deoxyoligomers. Copurification of the RNA and DNA-primed activities, identical metal cofactor and reaction requirements for either primer and identical heat inactivation curves with either primer strongly suggest that both primers are utilized by the same enzyme.     

Poly(A) polymerases in normal and virus-transformed cells.

The presence of poly(A) polymerase(s) has been studied in a clone of the established hamster embryo fibroblast line (NIL), and in a subclone of this line transformed by an RNA tumour virus, hamster sarcoma virus, (NIL-HS VIRUS). The results suggest the existence of three distinct poly(A) polymerases, designated I, IIA and IIB, in dense cultures of NIL and NIL-HS virus cells. Forms IIA and IIB have also been found in exponentially growing NIL and NIL-HS virus cells. Poly(A) polymerase I has not been detected in growing NIL cells, while growing and resting NIL-HS virus contain comparable amounts of this enzyme. The poly(A) polymerases differ in chromatographic behaviour and in their requirements for divalent cations. They are highly specific for ATP and require the presence of a primer. Cellular RNA or poly(A), but not the oligoribonucleotide (Ap)4A, can be utilized as primers. The products of the reactions have been identified as poly(A) chains (20-50 nucleotides long) by alkaline degradation and by their resistance to pancreatic RNAase.     

Comparative studies on polyguanylate polymerase and polyadenylate polymerase activities in the DNA-dependent RNA polymerase I fraction from cauliflower.

The properties of poly(G) polymerase and poly(A) polymerase activities in the DNA-dependent RNA polymerase [nucleosidetriphosphate: RNA nucleotidyltransferase EC 2.7.7.6] I fraction from cauliflower (Brassica oleracea var. botrytis) were comparatively investigated. The pH optimum, the effect of ionic strength, the effect of substrate concentration on the rate of synthesis, the effect of divalent metal ion concentration, and the time course of synthesis at different temperatures were all different for the three polymerase activities. The enzyme fraction preferentially utilized denatured DNA. Synthetic poly(C) and poly(U) were more effectively utillized for the synthesis of polyguanylate and polyadenylate, respectively. Further, it was found that poly(G) and poly(A) formed in vitro by the enzyme fraction had chain length of 25-28 and 84-89 nucleotides, respectively, and that poly (adenylate-gluanylate) chain was hardly formed when ATP and GTP were added together as substrates in the same reaction medium.     

Vaccinia virus poly(A) polymerase. Specificity for nucleotides and nucleotide analogs

We have studied the nucleotide specificity of vaccinia virus poly(A) polymerase using a novel primer extension assay. Oligoribonucleotide primers labeled at the 5' end with 32P were elongated by the enzyme in the presence of ATP, leading to the 3' addition of greater than 1000 adenylate residues/primer molecule. In the presence of UTP, the enzyme catalyzed 3' polymerization of long poly(U) tails, albeit at a reduced rate of chain growth. In the presence of both ATP and UTP, 3' addition was selective for ATP. The transient accumulation of RNAs elongated by 10-16 residues suggested that polyadenylation (and polyuridylation) was a biphasic reaction. Quantitative 3' addition of GMP (from GTP) or CMP (from CTP) to the primer was also observed, although the rate of chain growth was so slow as to allow synthesis of only short oligo(G) or oligo(C) tails. The deoxynucleotides 3'-dATP (cordycepin triphosphate) and ddATP were markedly inhibitory to poly(A) polymerase. Primer elongation studies were consistent with inhibition due to 3' incorporation of inhibitor and chain termination. Incubation of enzyme with [alpha-32P] cordycepin triphosphate resulted in labeling of the Mr 57,000 enzyme subunit, apparently via formation of a covalent nucleotidyl-protein complex. These data are discussed in light of their implications for the catalytic mechanism of 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.     

Synthesis of (2'-5')(A)n from ATP. Characteristics of the reaction catalyzed by (2'-5')(A)n synthetase purified from mouse Ehrlich ascites tumor cells treated with interferon

The treatment of Ehrlich ascites tumor cells with mouse interferon increases the level of the latent enzyme (2'-5')(A)n synthetase. If activated by double-stranded RNA, this catalyzes the synthesis from ATP of a series of 2'-5'-oligoadenylates: (2'-5')(A)n where n extends from 2 to about 15. We isolated (2'-5')(A)n synthetase in a homogeneous state. In the presence of double-stranded RNA, the purified enzyme can convert the large majority (about 97%) of the ATP into (2'-5')(A)n and pyrophosphate, although it does not cleave the pyrophosphate. The stoichiometry of the reaction can be formulated as: (n + I) ATP leads to (2'-5') pppA(pA)n + n pyrophosphate. Added pyrophosphate does not inhibit the synthesis of (2'-5')(A)n. The extent of the reverse reaction, i.e. the pyrophosphorolysis of (2'-5')(A)n, was below the level of detection under our conditions. The affinity of the enzyme for ATP is low: the rate of the reaction increases by about 10% when the concentration of ATP is increased from 5 mM to 10 mM. The optimal concentration of double-stranded RNA increases with the concentration of the enzyme. As tested at 0.4, 2, and 10 micrograms/ml of enzyme concentrations, close to maximal (2'-5')(A)n synthesis can be obtained if reovirus double-stranded RNA or poly(I) . poly(C) are used at about half the concentration (in w/v) of the enzyme. The plot of the reaction rate versus enzyme concentration is sigmoidal. It remains to be seen if this reflects on a cooperative behavior of the enzyme.     

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.     

A kinetic and structural characterization of adenosine-5'-triphosphate: ribonucleic acid adenylyltransferase from Pseudomonas putida.

A catalytic and structural study of ATP:RNA adenylyltransferase (EC 2.7.7.19) from the particulate fraction of Pseudomonas putida was made. During the large-scale purification of this enzyme, designated adenylyltransferase B, a previously undetected ATP-incorporating activity, designated adenylyltransferase A, was observed. Adenylyltransferases A and B were indistinguishable catalytically; however, they differed in their chromatographic and sedimentation properties. Adenylyltransferases A and B were resolved by phosphocellulose, by poly (U)-Sepharose and by Bio-Gel P-100 chromatographies. Adenylytransferase A was determined to have a sedimentation coefficient (S020,w) of 9.3 S and B of 4.3 S. The molecular weight of adenylyltransferase A was estimated to be 185000 and that of adenylyltransferase B to be 50000-60000. Apparently, adenylyltransferase A was generated from adenylyltransferase B during the purification. The AMP incorporation catalyzed by adenylyltransferases A and B was inhibited by two derivatives of the antibiotic rifamycin, AF/013 (50% at 5 mug/ml) and AF/DNFI (50% at 10 mug/ml). The 5'-triphosphate derivative (3'-dATP) of the drug cordycepin (3'-deoxyadenosine/ was a competitive inhibitor with ATP for both adenylyltransferases. The Ki for 3'-deoxyadenosine 5'-triphosphate was 6 - 10(-4)--10 - 10(-4) M, while the Km for ATP was 1 - 10(-4)--2 - 10(-4) M. Several other anaolgs of ATP, 2'-deoxyadenosine 5' triphosphate, 2'-O-methyl ATP, or the fluorescent 3-beta-D-ribofuranosylimidazo [2,1-i] purien 5'-triphosphate did not affect the activity of adenylyltransferase A or B. Poly(U) and poly(dT) were competitive inhibitors of the ribosomal RNA-primed polymerization reaction. The Ki for poly(U) or poly(dT), in terms of nucleotide phosphate, was 4 - 10-6)--10 - 10(-6) M for adenylyltransferases A and B, compared to 2 - 10(-4)--4 - 10(-4) M for the Km of ribosomal RNA. The inhibition was a result of the competition between the non-priming poly(U), or poly(dT), and ribosomal RNA for the primer binding site on the enzyme.     

Modulation of poly(A)+ RNA levels in fungal-infected wheat embryos through the selective inactivation of RNA polymerase II and poly(A) polymerase

Infection of germinating wheat embryos by a fungal pathogen (Drechslera sorokiana) drastically lowered (70–73%) the relative abundance of poly(A)⁺ RNA. This was paralleled by a significant loss in the activities of RNA polymerase II (60–70%) and poly(A) polymerase (80–85%) enzymes. The inhibition of RNA polymerase II (60–65%) and poly(A) polymerase (70–85%) activities was also witnessed by the in vitro addition of the fungal extract to the enzyme preparations isolated from healthy embryos. The fungal extract showed negligible phosphatase and nuclease activities. This ruled out the possibility of rapid degradation of the labelled substrate [³H]ATP, primer RNA, or even the labelled reaction products under our assay conditions. The inhibitory effect of the fungal extract could be alleviated by fractionating the treated enzyme preparation by phosphocellulose chromatography. This indicated that the fungal extract was directly responsible for the inactivation of the polymerases in a reversible manner. The inhibitory function of the fungal extract was destroyed by treatment with pronase, but not with RNAase A and RNAase Ti. Poly(A) ‘tails’ were enzymatically excised from ³²P-labelled poly(A)⁺ RNA and fractionated on acrylamide gels for autoradiographic analysis. The lengths of the ³²P-labelled poly(A) ‘tails’ in control and infected embryos turned out to be identical (64 nucleotides). Our results suggest that the relative abundance of poly(A)⁺ RNA is diminished in fungal-infected wheat embryos through the selective inactivation of RNA polymerase II and poly(A) polymerase enzymes.     

Inhibition of a novel subspecies of DNA polymerase α by 2′-deoxy-2′-azidoadenosine 5′-triphosphate

DNA polymerase α₁, a subspecies of DNA polymerase α of Ehrlich ascites tumor cells, was associated with a novel RNA polymerase activity and utilized poly(dT) and single-stranded circular fd DNA as a template without added primer in the presence of ribonucleoside triphosphates and a specific stimulating factor. DNA synthesis in the above system was inhibited by the ATP analogue, 2′-deoxy-2′-azidoadenosine 5′-triphosphate more than the DNA synthesis with poly(dT)·oligo(rA) by DNA polymerase α₁ and RNA synthesis by mouse RNA polymerases I and II. Kinetic analysis showed that the analogue inhibited DNA polymerase α₁ activity on poly(dT) competitively with respect to ATP, suggesting that the analogue inhibited RNA synthesis by the associated RNA polymerase activity.     

Synthesis and degradation of poly(A) in permeable cells of Escherichia coli.

Poly(A) synthesis and degradation have been examined in Escherichia coli cells made permeable to nucleotides by treatment with toluene. Although newly synthesized poly(A) is normally rapidly degraded in this system, extraction of the soluble portion of the cell effectively eliminates this process without affecting poly(A) synthesis. Poly(A) synthesis in this system displays many properties associated with poly(A) synthesis by purified poly(A) polymerase in vitro including a lag in polymerization, stimulation by increased ionic strength, and a low Mg2+ optimum. As with the purified enzyme, this system uses both ADP and ATP as substrates, requires conversion of ATP to ADP, and is strongly inhibited by dADP, orthophosphate, and pyrophosphate. In contrast to the purified poly(A) polymerase, the permeable cell system displays some properties suggestive of in vivo poly(A) metabolism. Thus, the permeable cells require an endogenous RNA primer for activity, the poly(A) product remains with the cells, and the reaction is greatly stimulated by polyamines. This system should prove extremely useful for studies of poly(A) metabolism in E. coli. A surprising feature of these studies was the finding that mutant strains deficient in polynucleotide phosphorylase were unable to synthesize poly(A). The possible roles of polynucleotide phosphorylase and poly(A) in E. coli are discussed.     

Regulation of poly(A) polymerase activity and poly(A)+ RNA in germinated wheat embryos under conditions of pathogenesis

The induction of poly(A) polymerase was accompanied by a rise in the level of poly(A)⁺ RNA during early germination of excised wheat embryos (48 h). Fractionation of this RNA-processing enzyme by acrylamide gel electrophoresis and also by molecular sieving on Sephadex G-200 revealed a single molecular form of poly(A) polymerase with a molecular weight of 125 000. Wheat poly(A) polymerase specifically catalyzed the incorporation of [³H]AMP from [³H]ATP into the polyadenylate product only in the presence of primer RNA. Substitution of [³H]ATP by other labelled nucleoside triphosphates, such as [³H]GTP, [³H]UTP or [α-³²P]CTP in the assay mixture did not yield any labelled polynucleotide reaction product. The ³H-labelled reaction product was retained on poly(U)-cellulose affinity column and was not degraded by RNAase A and RNAase T₁ treatment. In addition, the nearest-neighbour frequency analysis of the ³²P-labelled reaction product predominantly yielded [³²P]AMP. Thus, characterization of the reaction product clearly indicated its polyadenylate nature. The average chain length of the [³H]poly(A) product was 26 nucleotides. Infection of germinating wheat embryos by a fungal pathogen (Drechslera sorokiana) brought about a severe inhibition (62–79%) of poly(A) polymerase activity. Concurrently, there was a parallel decrease (73%) in the level of poly(A)⁺ RNA. Inhibition of poly(A) polymerase activity in infected embryos could be due to enzyme inactivation, which in turn brought about a downward shift in the level of poly(A)⁺ RNA. The crude extract of the cultured pathogen contains a non-dialysable, heat-labile factor, which, along with a ligand, inactivates (65–74%) poly(A) polymerase in vitro. The fungal extracts also contained a dialysable, heat-stable stimulatory effector which activated wheat poly(A) polymerase (3.6–4.0-fold stimulation) in vitro. However, the stimulatory fungal effector was not expressed in vivo, but was detectable after the inhibitory fungal factor had been destroyed by heat-treatment in our in vitro experiments.     

Inhibition of the polyadenylation reaction in vitro by polyamines

The effect of polyamines on the polyadenylation reaction in vitro was investigated. Varying concentrations of spermine were added to the reaction catalyzed by purified poly(A) polymerase using rat liver nuclear RNA, poly(A), Escherichia coli tRNA or (Ap)₃A as exogenous primers. The enzyme activity decreased progressively with increasing concentrations of polyamines; complete inhibition was obtained at 0.4 and 1.2 mm spermine for the nuclear RNA- and poly(A)-primed reactions, respectively. No inhibition was observed for the (Ap)₃A-primed reaction. Spermidine and putrescine also inhibited polyadenylation but to a lesser extent than spermine. The degree of inhibition by spermine was related to the polynucleotide primer concentrations. Spermine prevented polyadenylation by binding to the primer but not to the poly(A) polymerase molecule as shown by the migration of [¹⁴C]spermine through glycerol gradients after preincubation with enzyme or tRNA. At concentrations inhibitory to polyadenylation in vitro, spermine could stimulate the DNA-dependent RNA synthesis catalyzed by RNA polymerase II. The present study suggests that low levels of polyamines could be used as specific inhibitors of the poly(A) synthesis in vitro.