Characterization of ts 16, a temperature-sensitive mutant of vaccinia virus

We have characterized a temperature-sensitive mutant of vaccinia virus, ts16, originally isolated by Condit et al. (Virology 128:429-443, 1983), at the permissive and nonpermissive temperatures. In a previous study by Kane and Shuman (J. Virol 67:2689-2698, 1993), the mutation of ts16 was mapped to the I7 gene, encoding a 47-kDa protein that shows partial homology to the type II topoisomerase of Saccharomyces cerevisiae. The present study extends previous electron microscopy analysis, showing that in BSC40 cells infected with ts16 at the restrictive temperature (40 degrees C), the assembly was arrested at a stage between the spherical immature virus and the intracellular mature virus (IMV). In thawed cryosections, a number of the major proteins normally found in the IMV were subsequently localized to these mutant particles. By using sucrose density gradients, the ts16 particles were purified from cells infected at the permissive and nonpermissive temperatures. These were analyzed by immunogold labelling and negative-staining electron microscopy, and their protein composition was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. While the ts16 virus particles made at the permissive temperature appeared to have a protein pattern identical to that of wild-type IMV, in the mutant particles the three core proteins, p4a, p4b, and 28K, were not proteolytically processed. Consistent with previous data the sucrose-purified particles could be labelled with [3H]thymidine. In addition, anti-DNA labelling on thawed cryosections suggested that most of the mutant particles had taken up DNA. On thawed cryosections of cells infected at the permissive temperature, antibodies to I7 labelled the virus factories, the immature viruses, and the IMVs, while under restrictive conditions these structures were labelled much less, if at all. Surprisingly, however, by Western blotting (immunoblotting) the I7 protein was present in similar amounts in the defective particles and in the IMVs isolated at the permissive temperature. Finally, our data suggest that at the nonpermissive temperature the assembly of ts16 is irreversibly arrested in a stage at which the DNA is in the process of entering but before the particle has completely sealed, as monitored by protease experiments.

Mutational analysis of mRNA capping enzyme identifies amino acids involved in GTP binding, enzyme-guanylate formation, and GMP transfer to RNA

Vaccinia virus mRNA capping enzyme is a multifunctional protein with RNA triphosphatase, RNA guanylyltransferase, RNA (guanine-7) methyltransferase, and transcription termination factor activities. The protein is a heterodimer of 95- and 33-kDa subunits encoded by the vaccinia virus D1 and D12 genes, respectively. The capping reaction entails transfer of GMP from GTP to the 5'-diphosphate end of mRNA via a covalent enzyme-(lysyl-GMP) intermediate. The active site is situated at Lys-260 of the D1 subunit within a sequence element, KxDG (motif I), that is conserved in the capping enzymes from yeasts and other DNA viruses and at the active sites of covalent adenylylation of RNA and DNA ligases. Four additional sequence motifs (II to V) are conserved in the same order and with similar spacing among the capping enzymes and several ATP-dependent ligases. The relevance of these common sequence elements to the RNA capping reaction was addressed by mutational analysis of the vaccinia virus D1 protein. Nine alanine substitution mutations were targeted to motifs II to V. Histidine-tagged versions of the mutated D1 polypeptide were coexpressed in bacteria with the D12 subunit, and the His-tagged heterodimers were purified by Ni affinity and phosphocellulose chromatography steps. Whereas each of the mutated enzymes retained triphosphatase, methyltransferase, and termination factor activities, six of nine mutant enzymes were defective in some aspect of transguanylylation. Individual mutations in motifs III, IV, and V had distinctive effects on the affinity of enzyme for GTP, the rate of covalent catalysis (EpG formation), or the transfer of GMP from enzyme to RNA. These results are concordant with mutational studies of yeast RNA capping enzyme and suggest a conserved structural basis for covalent nucleotidyl transfer.

Adenosine N1-oxide inhibits vaccinia virus replication by blocking translation of viral early mRNAs

Adenosine N1-oxide (ANO) is a potent and highly selective inhibitor of vaccinia virus replication. We examined the impact of ANO on vaccinia virus macromolecular synthesis during synchronous infection of BSC40 cells. Viral DNA replication and viral late protein synthesis were blocked completely by ANO, effects that were attributable to a defect in the expression of viral early genes. Vaccinia virus early proteins were not synthesized in the presence of ANO, even though vaccinia virus early mRNAs were produced. Cellular protein synthesis was unaffected by ANO, and virus infection in the presence of the drug did not elicit the normal shutoff of host protein synthesis. Adenosine N1-oxide triphosphate (ANO-TP), the predominant metabolite of the drug in vivo, could substitute for ATP in RNA synthesis by purified vaccinia virus RNA polymerase. ANO-TP could support early transcription by purified virions if dATP was provided as an energy source. ANO-TP did not inhibit early transcription in the presence of ATP. These findings suggest a novel antiviral mechanism whereby incorporation of a modified nucleotide into viral mRNAs might selectively block viral gene expression at the level of translation. We believe that ANO merits consideration as an antipoxvirus drug for topical treatment of molluscum contagiosum in humans.

Vaccinia virus morphogenesis is blocked by temperature-sensitive mutations in the F10 gene, which encodes protein kinase 2

Four previously isolated temperature-sensitive (ts) mutants of vaccinia virus WR (ts28, ts54, ts61, and ts15) composing a single complementation group have been mapped by marker rescue to the F10 open reading frame located within the genomic HindIII F DNA fragment. Sequencing of the F10 gene from wild-type and mutant viruses revealed single-amino-acid substitutions in the F10 polypeptide responsible for thermolabile growth. Although the ts mutants displayed normal patterns of viral protein synthesis, electron microscopy revealed a profound morphogenetic defect at the nonpermissive temperature (40 degrees C). Virion assembly was arrested at an early stage, with scant formation of membrane crescents and no progression to normal spherical immature particles. The F10 gene encodes a 52-kDa serine/threonine protein kinase (S. Lin and S. S. Broyles, Proc. Natl. Acad. Sci. USA 91:7653-7657, 1994). We expressed a His-tagged version of the wild-type, ts54, and ts61 F10 polypeptides in bacteria and purified these proteins by sequential nickel affinity and phosphocellulose chromatography steps. The wild-type F10 protein kinase activity was characterized in detail by using casein as a phosphate acceptor. Whereas the wild-type and ts61 kinases displayed similar thermal inactivation profiles, the ts54 kinase was thermosensitive in vitro. These findings suggest that protein phosphorylation plays an essential role at an early stage of virion assembly.

Mutational analysis of vaccinia DNA ligase defines residues essential for covalent catalysis

DNA ligation entails AMP transfer from ATP to the 5' end of DNA to form a DNA-adenylate structure, A(5')pp(5')N. A similar reaction involving GMP transfer occurs during 5' capping of eukaryotic mRNA. In both cases, nucleotidyl transfer occurs through a covalent lysyl-NMP intermediate. There is local sequence conservation among ligases and capping enzymes in the vicinity of the active site lysine (KxDG) and at three other collinear motifs. The role of these motifs in DNA ligation was tested by mutating individual conserved residues in the vaccinia virus DNA ligase. Wild-type and mutated versions of vaccinia ligase were expressed in bacteria as His-tagged fusion proteins and purified by Ni-affinity and phosphocellulose chromatography steps. We found that Ala substitution for Lys-231 (the presumptive active site) abrogated enzyme-adenylate formation and DNA ligation activities. Ala mutations at conserved residues Glu-283, Glu-377, and Lys-397 also resulted in loss of ligation activity, which correlated with a defect in ligase-AMP formation. These results are concordant with mutational studies of yeast RNA capping enzyme and suggest a common structural basis for covalent nucleotidyl transfer.

RNA capping enzyme and DNA ligase: a superfamily of covalent nucleotidyl transferases

mRNA capping entails GMP transfer from GTP to a 5' diphosphate RNA end to form the structure G(5')ppp(5')N. A similar reaction involving AMP transfer to the 5' monophosphate end of DNA or RNA occurs during strand joining by polynucleotide ligases. In both cases, nucleotidyl transfer occurs through a covalent lysyl-NMP intermediate. Sequence conservation among capping enzymes and ATP-dependent ligases in the vicinity of the active site lysine (KxDG) and at five other co-linear motifs suggests a common structural basis for covalent catalysis. Mutational studies support this view. We propose that the cellular and DNA virus capping enzymes and ATP-dependent ligases constitute a protein superfamily evolved from a common ancestral enzyme. Within this superfamily, the cellular capping enzymes display more extensive similarity to the ligases than they do to the poxvirus capping enzymes. Recent studies suggest that eukaryotic RNA viruses have evolved alternative pathways of cap metabolism catalysed by structurally unrelated enzymes that nonetheless employ a phosphoramidate intermediate. Comparative analysis of these enzymes, particularly at the structural level, should illuminate the shared reaction mechanism while clarifying the basis for nucleotide specificity and end recognition. The capping enzymes merit close attention as potential targets for antiviral therapy.

Yeast mRNA cap methyltransferase is a 50-kilodalton protein encoded by an essential gene

RNA (guanine-7-)methyltransferase, the enzyme responsible for methylating the 5' cap structure of eukaryotic mRNA, was isolated from extracts of Saccharomyces cerevisiae. The yeast enzyme catalyzed methyl group transfer from S-adenosyl-L-methionine to the guanosine base of capped, unmethylated poly(A). Cap methylation was stimulated by low concentrations of salt and was inhibited by S-adenosyl-L-homocysteine, a presumptive product of the reaction, but not by S-adenosyl-D-homocysteine. The methyltransferase sedimented in a glycerol gradient as a single discrete component of 3.2S. A likely candidate for the gene encoding yeast cap methyltransferase was singled out on phylogenetic grounds. The ABD1 gene, located on yeast chromosome II, encodes a 436-amino-acid (50-kDa) polypeptide that displays regional similarity to the catalytic domain of the vaccinia virus cap methyltransferase. That the ABD1 gene product is indeed RNA (guanine-7-)methyltransferase was established by expressing the ABD1 protein in bacteria, purifying the protein to homogeneity, and characterizing the cap methyltransferase activity intrinsic to recombinant ABD1. The physical and biochemical properties of recombinant ABD1 methyltransferase were indistinguishable from those of the cap methyltransferase isolated and partially purified from whole-cell yeast extracts. Our finding that the ABD1 gene is required for yeast growth provides the first genetic evidence that a cap methyltransferase (and, by inference, the cap methyl group) plays an essential role in cellular function in vivo.

Mutational analysis of vaccinia virus nucleoside triphosphate phosphohydrolase II, a DExH box RNA helicase

Vaccinia virus nucleoside triphosphate phosphohydrolase II (NPH-II), a 3'-to-5' RNA helicase, displays sequence similarity to members of the DExH family of nucleic acid-dependent nucleoside triphosphatases (NTPases). The contributions of the conserved GxGKT and DExH motifs to enzyme activity were assessed by alanine scanning mutagenesis. Histidine-tagged versions of NPH-II were expressed in vaccinia virus-infected BSC40 cells and purified by nickel affinity and conventional fractionation steps. Wild-type His-NPH-II was indistinguishable from native NPH-II with respect to RNA helicase, RNA binding, and nucleic acid-stimulated NTPase activities. The K-191-->A (K191A), D296A, and E297A mutant proteins bound RNA as well as wild-type His-NPH-II did, but they were severely defective in NTPase and helicase functions. The H299A mutant was active in RNA binding and NTP hydrolysis but was defective in duplex unwinding. Whereas the NTPase of wild-type NPH-II was stimulated > 10-fold by polynucleotide cofactors, the NTPase of the H299A mutant was nucleic acid independent. Because the specific NTPase activity of the H299A mutant in the absence of nucleic acid was near that of wild-type enzyme in the presence of DNA or RNA and because the Km for ATP was unaltered by the H299A substitution, we regard this mutation as a "gain-of-function" mutation and suggest that the histidine residue in the DExH box is required to couple the NTPase and helicase activities.

The D1 and D12 subunits are both essential for the transcription termination factor activity of vaccinia virus capping enzyme

Transcription termination by vaccinia virus RNA polymerase during synthesis of early mRNAs requires a virus-encoded termination factor (VTF). VTF is but one of many activities associated with the vaccinia virus mRNA capping enzyme, a heterodimer of 95- and 33-kDa subunits encoded by the D1 and D12 genes, respectively. Although the three catalytic domains involved in cap formation have been assigned to individual subunits or portions thereof, the structural requirements for VTF activity are unknown. We now report that both full-length subunits are required for transcription termination. The 844-amino acid D1 subunit by itself, which is fully active in triphosphatase and guanylyltransferase functions, has no demonstrable VTF activity in vitro. Neither does the D12 subunit by itself. The heterodimeric methyltransferase domain of D1 (residues 498 to 844) and D12 subunits also has no VTF activity. VTF is not affected by a K-to-M mutation of the guanylyltransferase active site at position 260 (K260M) that abolishes enzyme-GMP complex formation or by a H682A/Y683A double mutation of the D1 subunit, which abrogates methyltransferase activity. Thus, the structural requirements for termination are distinct from those for nucleotidyl transfer and methyl transfer.

Proteolytic footprinting of vaccinia topoisomerase bound to DNA

Vaccinia DNA topoisomerase, a member of the eukaryotic type I enzyme family, binds duplex DNA and forms a covalent protein.DNA complex at sites containing a conserved sequence element 5'-CCCTT decreases. The structure of the enzyme in the free and DNA-bound states was probed by limited proteolysis. The free topoisomerase (a 314-amino acid polypeptide) consists of protease-resistant amino- and carboxyl-terminal structural domains flanking a protease-sensitive "hinge." The hinge region, located between residues 135 and 142, is defined by accessibility to three different proteases. The amino-terminal region is punctuated by a trypsin-sensitive "bridge" at Arg-80, suggesting at least a tripartite domain structure overall. A specific subset of residues accessible to proteases in the free enzyme becomes resistant to proteolysis in the DNA-bound state. The trypsin-sensitive site at Arg-80 is protected almost completely in the covalent complex. Within the hinge region, Lys-135, Tyr-136, and Glu-139 are protected from trypsin, chymotrypsin, and V8, respectively. Acquisition of altered protease sensitivity upon DNA binding occurs prior to covalent adduct formation. The 20-kDa carboxyl domain by itself binds noncovalently to duplex DNA, albeit without the sequence specificity characteristic of the full-sized topoisomerase.

Vaccinia DNA topoisomerase I: kinetic evidence for general acid-base catalysis and a conformational step

The pH dependences of the internal equilibrium (Kcl) and rate constants for site-specific DNA strand cleavage (kcl) and resealing (kr) catalyzed by Vaccinia DNA topoisomerase I have been investigated using single-turnover conditions in the pH range 4.6-9.8 at 20 degrees C. The pH dependence of the rate constant for strand cleavage (kcl) shows a bell-shaped profile with apparent pKa values of 6.3 +/- 0.2 and 8.4 +/- 0.2, suggesting base catalysis of the attack of the active site Tyr-274 on the phosphodiester phosphorus, and acid catalysis of the expulsion of the 5'-deoxyribose oxygen. A low pKa (i.e., 6.3) for Tyr-274 in the free enzyme is ruled out by NMR titration from pH 5.1 to 8.8 monitoring the C-zeta chemical shift of [zeta-13C]-tyrosine-enriched topoisomerase. The dependence of the internal equilibrium constant (Kcl) on pH reveals very similar pKa values as kcl (5.8 +/- 0.2 and 8.6 +/- 0.2). However, kr is found to be independent of pH. The differing response of kcl and kr to pH rules out a simple two-state internal cleavage equilibrium and suggests that a conformational change occurs following formation of the covalent complex which retains the correct protonation state for strand religation. A conformation step is further indicated by a 4.6-fold "thio effect" on kcl upon substitution of the nonbridging oxygen atom of the attacked phosphoryl group by sulfur [Stivers, J. T., Shuman, S., & Mildvan, A. S. (1994) Biochemistry 33, 327], and the absence of such an effect on kr, (krphos/krthio = 0.9 +/- 0.2), indicating the rates of cleavage and religation to be limited by covalent chemistry and a conformational step, respectively. The rate constant of this conformational change in the direction of religation agrees with the average rate constant for supercoil release from plasmid substrates, suggesting this conformational change to be a part of the topoisomerization step. Although the general acid and general base catalysts have not yet been identified, the quantitative roles of these and other residues in catalysis are discussed.

Novel approach to molecular cloning and polynucleotide synthesis using vaccinia DNA topoisomerase

Construction of chimaeric DNA molecules in vitro relies traditionally on two enzymatic steps catalyzed by separate protein components. Site-specific restriction endonucleases are used to generate linear DNAs with defined termini that can then be joined covalently at their ends via the action of DNA ligase. A novel approach to the synthesis of recombinant DNAs exploits the ability of a single enzyme, vaccinia DNA topoisomerase, to both cleave and rejoin DNA strands with extreme specificity at each step. Placement of the CCCTT cleavage motif for vaccinia topoisomerase near the end of a duplex DNA permits efficient generation of a stable, highly recombinogenic protein-DNA adduct that can religate only to acceptor DNAs that contain complementary single-strand extensions. Linear DNAs containing CCCTT cleavage sites at both ends (bivalent substrates) can be activated by topoisomerase and inserted into a plasmid vector in a simple and rapid in vitro procedure that is especially well suited to the molecular cloning of polymerase chain reaction-amplified DNAs. Activation of polyvalent (e.g. branched) DNA substrates by topoisomerase offers a potentially powerful method for the synthesis of two- and three-dimensional polynucleotide networks.

Vaccinia topoisomerase binds circumferentially to DNA

Vaccinia DNA topoisomerase, a member of the eukaryotic type I enzyme family, binds duplex DNA and forms a covalent adduct at sites containing a conserved sequence element 5'-CCCTT decreases in the scissile strand. The protein-DNA interface entails essential contacts with four phosphate moieties within the CCCTT motif, including the scissile phosphate, and three phosphates within the GGGAA sequence on the noncleaved strand. Critical protein-phosphate contacts are arrayed across the minor groove of the DNA helix. Base-specific contacts with the pentamer element are within the major groove and are situated on the opposite face of the helix. Thus, vaccinia topoisomerase binds circumferentially to its target site in duplex DNA. This binding mode suggests that the eukaryotic enzyme adopts a toroidal shape in the DNA-bound state. Conformational isomerization of the bound protein provides a plausible mechanism for DNA relaxation.

Requirements for noncovalent binding of vaccinia topoisomerase I to duplex DNA

Vaccinia DNA topoisomerase binds duplex DNA and forms a covalent adduct at sites containing a conserved sequence element 5'(C/T)CCTT decreases in the scissile strand. Distinctive aspects of noncovalent versus covalent interaction emerge from analysis of the binding properties of Topo(Phe-274), a mutated protein which is unable to cleave DNA, but which binds DNA noncovalently. Whereas DNA cleavage by wild type enzyme is most efficient with 'suicide' substrates containing fewer than 10 base pairs distal to the scissile bond, optimal noncovalent binding by Topo(Phe-274) requires at least 10-bp of DNA 3' of the cleavage site. Thus, the region of DNA flanking the pentamer motif serves to stabilize the noncovalent topoisomerase-DNA complex. This result is consistent with the downstream dimensions of the DNA binding site deduced from nuclease footprinting. Topo(Phe-274) binds to duplex DNA lacking the consensus pentamer with 7-10-fold lower affinity than to CCCTT-containing DNA.

Covalent catalysis in nucleotidyl transfer reactions: essential motifs in Saccharomyces cerevisiae RNA capping enzyme are conserved in Schizosaccharomyces pombe and viral capping enzymes and among polynucleotide ligases

Formation of the 5' cap structure of eukaryotic mRNAs occurs via transfer of GMP from GTP to the 5' terminus of the primary transcript. RNA guanylyltransferase, the enzyme that catalyzes this reaction, has been isolated from many viral and cellular sources. Though differing in molecular weight and subunit structure, the various guanylyltransferases employ a common catalytic mechanism involving a covalent enzyme-(Lys-GMP) intermediate. Saccharomyces cerevisiae CEG1 is the sole example of a cellular capping enzyme gene. In this report, we describe the identification and characterization of the PCE1 gene encoding the capping enzyme from Schizosaccharomyces pombe. PCE1 was isolated from a cDNA library by functional complementation in Sa. cerevisiae. Induced expression of PCE1 in bacteria and in yeast confirmed that the 47-kDa Sc. pombe protein was enzymatically active. The amino acid sequence of PCE1 is 38% identical (152 of 402 residues) to the 52-kDa capping enzyme from Sa. cerevisiae. Comparison of the two cellular capping enzymes with guanylyltransferases encoded by DNA viruses revealed local sequence similarity at the enzyme's active site and at four additional collinear motifs. Mutational analysis of yeast CEG1 demonstrated that four of the five conserved motifs are essential for capping enzyme function in vivo. Remarkably, the same motifs are conserved in the polynucleotide ligase family of enzymes that employ an enzyme-(Lys-AMP) intermediate. These findings illuminate a shared structural basis for covalent catalysis in nucleotidyl transfer and suggest a common evolutionary origin for capping enzymes and ligases.

Mutational analysis of vaccinia DNA topoisomerase defines amino acid residues essential for covalent catalysis

The eukaryotic family of type I DNA topoisomerases includes the nuclear type I enzymes and the enzymes encoded by vaccinia and other poxviruses. The small size of the vaccinia topoisomerase (314 amino acids as compared to 765-972 amino acids for the cellular enzymes) makes it likely that this protein constitutes the minimal functional unit of a eukaryotic type I enzyme and provides an opportunity for a comprehensive structure-function analysis through mutagenesis. Two protein subregions were targeted for mutagenesis in the present study. The role of the Ser-Lys-X-X-Tyr sequence present at the active site of all family members was examined by replacing each conserved residue with alanine. Alanine substitution at the active site Tyr abrogated topoisomerase activity. In contrast, mutations at Ser-270 and Lys-271 had no effect on enzyme activity. The region of the vaccinia topoisomerase from amino acids 126-142 (MFFIRFGKMKYLKENET) is highly conserved and contains a residue, Gly-132, shown previously to be essential. Twenty-nine different mutations were generated in this region, with at least one substitution at each position. Point mutations were identified at three positions, Arg-130, Tyr-136, and Leu-137, which either abrogated or severely reduced DNA relaxation. The effects on activity could be attributed to a defect in formation of the covalent intermediate. Alterations of 13 other amino acids, including conserved residues, had little or no effect on topoisomerase activity.

Stimulation of vaccinia topoisomerase I by nucleoside triphosphates

The rate of relaxation of supercoiled DNA by purified vaccinia topoisomerase I is stimulated 20-fold by 5 mM ATP. A similar effect is elicited by GTP, CTP, UTP, dATP, and adenosine 5'-(beta, gamma-imido)triphosphate. ATP-mediated rate enhancement requires salt as a coactivator. ADP and inorganic pyrophosphate also stimulate relaxation 10-20-fold, whereas AMP and inorganic phosphate have little effect. A model for allosteric activation of topoisomerase by nucleotides is suggested.

Intrinsic RNA (guanine-7) methyltransferase activity of the vaccinia virus capping enzyme D1 subunit is stimulated by the D12 subunit. Identification of amino acid residues in the D1 protein required for subunit association and methyl group transfer

Vaccinia virus mRNA capping enzyme, a heterodimer of virus-encoded D1 and D12 subunits, catalyzes three steps in the synthesis of the m7GpppN cap. By expressing portions of the subunits in bacteria, singly and together, we have localized the RNA (guanine-7) methyltransferase domain to a 305-amino acid carboxyl-terminal segment of the D1 polypeptide (residues 540-844) complexed with the D12 protein. We find that the purified carboxyl D1 protein has a weak intrinsic methyltransferase activity, indicating that the catalytic center resides within this subunit. The basal level of activity can be stimulated 100-fold by addition of purified D12 protein, which is itself catalytically inert. The carboxyl region of D1 forms a heterodimer with the D12 subunit in vivo and in vitro. Analysis of alanine substitution mutants of the D1 protein identifies amino acid residues important for subunit interaction. Our results suggest that subunit heterodimerization is necessary, but not sufficient, for full methyltransferase activity. A mutation of vicinal positions His-682-Tyr-683 that specifically affects catalytic activity but not subunit interaction implicates these residues as constituents of the active site.

A role for the H4 subunit of vaccinia RNA polymerase in transcription initiation at a viral early promoter

The vaccinia virus H4 gene encodes an essential subunit of the DNA-dependent RNA polymerase holoenzyme encapsidated within virus particles (Ahn, B., and Moss, B. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 3536-3540; Kane, E. M., and Shuman, S. (1992) J. Virol. 66, 5752-5762). The role of this protein in transcription of viral early genes was revealed by the effects of affinity-purified anti-H4 antibody on discrete phases of the early transcription reaction in vitro. Anti-H4 specifically prevented the synthesis of a 21-nucleotide nascent RNA chain but had no impact on elongation of the 21-mer RNA by preassembled ternary complexes. Inhibition of initiation but not elongation was also observed with affinity-purified anti-D6 antibody directed against the 70-kDa subunit of the vaccinia early transcription initiation factor (ETF). Native gel mobility-shift assays showed that anti-H4 prevented the NTP-dependent recruitment of RNA polymerase to the preinitiation complex of ETF bound at the early promoter. Two species of ternary complexes could be resolved by native gel electrophoresis. Addition of anti-H4 to preformed complexes elicited a supershift of both ternary species but not of the preinitiation complex. Supeshift by anti-D6 revealed that the more rapidly migrating species of ternary complex did not contain immunoreactive ETF. Loss of ETF from the ternary complex was time-dependent. Thus, whereas the H4 protein was a stable constituent of the elongation complex, ETF was dissociable. We suggest that H4 functions as a molecular bridge to ETF and thereby allows specific recognition of early promoters by the core RNA polymerase. H4 is unlike bacterial sigma factor in that it remains bound to polymerase after the elongation complex is established.

Mutational analysis of yeast mRNA capping enzyme

RNA guanylyltransferase (capping enzyme) catalyzes the transfer of GMP from GTP to the 5'-diphosphate end of mRNA. The capping reaction proceeds via an enzyme-guanylate intermediate in which GMP is linked covalently to a lysine residue of the enzyme. In the capping enzyme of Saccharomyces cerevisiae, GMP is attached to a 52-kDa polypeptide, identified as the product of the essential CEG1 gene. The amino acid sequence of the CEG1 protein includes a motif, Lys70-Thr-Asp-Gly, that is conserved at the active site of vaccinia virus RNA guanylyltransferase and which is similar to the KXDG sequence found at the active sites of RNA and DNA ligases. To evaluate the role of this motif in the function of the yeast enzyme, we have expressed the CEG1 protein in active form in Escherichia coli. Replacement of Lys70 or Gly73 with alanine abrogated enzyme-guanylate formation in vitro; in contrast, alanine substitutions at Thr71 or Asp72 merely reduced activity relative to wild-type enzyme. The K70A and G73A mutations were lethal to yeast, whereas yeast carrying the T71A and D72A alleles of CEG1 were viable. These results implicate Lys70 as the active site of yeast guanylyltransferase and provide evidence that cap formation per se is an essential function in eukaryotic cells.