Expression of baculovirus late and very late genes depends on LEF-4, a component of the viral RNA polymerase whose guanyltransferase function is essential

Baculovirus lef-4 encodes one subunit of the viral RNA polymerase. Here, we demonstrate the essential nature of LEF-4 by RNA interference and bacmid knockout technology. Silencing of LEF-4 in wild-type virus-infected cells suppressed expression of structural genes, while early expression was unaffected, demonstrating its essential role in late gene expression. After transfection of insect cells with lef-4 mutant bacmid, no viral progeny was produced, further defining its central role in infection. Cotransfection with wild-type lef-4 plasmid restored normal replication, but plasmid encoding a guanyltransferase-deficient version failed to rescue. These results emphasize the importance of the mRNA capping function of LEF-4.     

RNA 5′-Triphosphatase, Nucleoside Triphosphatase, and Guanylyltransferase Activities of Baculovirus LEF-4 Protein

Autographa californica nuclear polyhedrosis virus late and very late mRNAs are transcribed by an RNA polymerase consisting of four virus-encoded polypeptides: LEF-8, LEF-9, LEF-4, and p47. The 464-amino-acid LEF-4 subunit contains the signature motifs of GTP:RNA guanylyltransferases (capping enzymes). Here, we show that the purified recombinant LEF-4 protein catalyzes two reactions involved in RNA cap formation. LEF-4 is an RNA 5′-triphosphatase that hydrolyzes the γ phosphate of triphosphate-terminated RNA and a guanylyltransferase that reacts with GTP to form a covalent protein-guanylate adduct. The RNA triphosphatase activity depends absolutely on a divalent cation; the cofactor requirement is satisfied by either magnesium or manganese. LEF-4 also hydrolyzes ATP to ADP and P_i (K_m = 43 μM ATP; V_max = 30 s⁻¹) and GTP to GDP and P_i. The LEF-4 nucleoside triphosphatase (NTPase) is activated by manganese or cobalt but not by magnesium. The RNA triphosphatase and NTPase activities of baculovirus LEF-4 resemble those of the vaccinia virus and Saccharomyces cerevisiae mRNA capping enzymes. We suggest that these proteins comprise a novel family of metal-dependent triphosphatases.     

Characterization of a second vaccinia virus mRNA-decapping enzyme conserved in poxviruses

Vaccinia virus (VACV) encodes enzymes that cap the 5′ end of viral mRNAs, which enhances their stability and translation. Nevertheless, recent studies demonstrated that the VACV D10 protein (VACV-WR_115) decaps mRNA, an enzymatic activity not previously shown to be encoded by a virus. The decapping activity of D10 is dependent on a Nudix hydrolase motif that is also present in the VACV D9 protein (VACV-WR_114), which shares 25% sequence identity with D10. Here, we showed that a purified recombinant VACV D9 fusion protein also decaps mRNA and that this activity was abolished by point mutations in the Nudix hydrolase motif. Decapping was specific for a methylated cap attached to RNA and resulted in the liberation of m⁷GDP. D9 differed from D10 in requiring a longer capped RNA substrate for optimal activity, having greater sensitivity to inhibition by uncapped RNA, and having lower sensitivity to inhibition by nucleotide cap analogs unattached to RNA. Since D9 is expressed early in infection and D10 late, we suggest that the two proteins enhance mRNA turnover and manipulate gene expression in a complementary and overlapping manner.     

Baculovirus lef-12 is not required for viral replication

The baculovirus lef-12 (orf41) gene is required for transient expression of baculovirus late genes. To analyze the role of LEF-12 in the context of infected cells, two mutant viruses were constructed. Both mutants were viable in Trichoplusia ni High 5 and Spodoptera frugiperda Sf9 cells. Single-step growth curves, however, indicated that virus yields were reduced approximately fivefold in the absence of LEF-12. Pulse-labeling of infected cells revealed that LEF-12 mutant viruses entered the late phase and synthesized late proteins at levels equivalent to or only twofold lower than those of wild-type virus-infected cells. Western blot analyses confirmed that LEF-12 was not synthesized in cells infected with mutant virus. In wild-type virus-infected cells, LEF-12 was not detected until 18 h postinfection, and accumulation of LEF-12 peaked at 24 to 36 h postinfection. Primer extension mapping revealed that lef-12 mRNA was synthesized by 12 h postinfection and peaked between 18 and 24 h postinfection. Furthermore, synthesis of lef-12 mRNA and LEF-12 protein were inhibited by the addition of aphidicolin, indicating that lef-12 is expressed after DNA replication.     

A conserved motif in region v of the large polymerase proteins of nonsegmented negative-sense RNA viruses that is essential for mRNA capping

Nonsegmented negative-sense (NNS) RNA viruses cap their mRNA by an unconventional mechanism. Specifically, 5′ monophosphate mRNA is transferred to GDP derived from GTP through a reaction that involves a covalent intermediate between the large polymerase protein L and mRNA. This polyribonucleotidyltransferase activity contrasts with all other capping reactions, which are catalyzed by an RNA triphosphatase and guanylyltransferase. In these reactions, a 5′ diphosphate mRNA is capped by transfer of GMP via a covalent enzyme-GMP intermediate. RNA guanylyltransferases typically have a KxDG motif in which the lysine forms this covalent intermediate. Consistent with the distinct mechanism of capping employed by NNS RNA viruses, such a motif is absent from L. To determine the residues of L protein required for capping, we reconstituted the capping reaction of the prototype NNS RNA virus, vesicular stomatitis virus, from highly purified components. Using a panel of L proteins with single-amino-acid substitutions to residues universally conserved among NNS RNA virus L proteins, we define a new motif, GxxT[n]HR, present within conserved region V of L protein that is essential for this unconventional mechanism of mRNA cap formation.     

RNA triphosphatase component of the mRNA capping apparatus of Paramecium bursaria Chlorella virus 1

Paramecium bursaria chlorella virus 1 (PBCV-1) elicits a lytic infection of its unicellular green alga host. The 330-kbp viral genome has been sequenced, yet little is known about how viral mRNAs are synthesized and processed. PBCV-1 encodes its own mRNA guanylyltransferase, which catalyzes the addition of GMP to the 5' diphosphate end of RNA to form a GpppN cap structure. Here we report that PBCV-1 encodes a separate RNA triphosphatase (RTP) that catalyzes the initial step in cap synthesis: hydrolysis of the gamma-phosphate of triphosphate-terminated RNA to generate an RNA diphosphate end. We exploit a yeast-based genetic system to show that Chlorella virus RTP can function as a cap-forming enzyme in vivo. The 193-amino-acid Chlorella virus RTP is the smallest member of a family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi and other large eukaryotic DNA viruses (poxviruses, African swine fever virus, and baculoviruses). Chlorella virus RTP is more similar in structure to the yeast RNA triphosphatases than to the enzymes of metazoan DNA viruses. Indeed, PBCV-1 is unique among DNA viruses in that the triphosphatase and guanylyltransferase steps of cap formation are catalyzed by separate viral enzymes instead of a single viral polypeptide with multiple catalytic domains.     

Guanylyltransferase Activity of the LEF-4 Subunit of Baculovirus RNA Polymerase

The baculovirus Autographa californica nuclear polyhedrosis virus encodes a DNA-dependent RNA polymerase that transcribes viral late genes. This polymerase is composed of four equimolar subunits, LEF-4, LEF-8, LEF-9, and p47. Here we present data indicating that the LEF-4 subunit of RNA polymerase is a guanylyltransferase. Incubation of RNA polymerase in the presence of divalent cation and radiolabeled GTP resulted in the formation of a covalent enzyme-guanylate complex that comigrated with the LEF-4 subunit. The label transfer assay showed an absolute requirement for divalent cation which could be satisfied by either manganese or magnesium. The reaction was specific for guanine nucleotides, and GTP was more effective than dGTP in the formation of enzyme-guanylate complex. To demonstrate that LEF-4 was the guanylyltransferase, the single subunit was overexpressed in baculovirus-infected cells. The overexpressed protein was primarily cytosolic, indicating that other proteins in the RNA polymerase complex were responsible for nuclear targeting of LEF-4. LEF-4 alone was able to covalently bind GMP, although less efficiently than viral RNA polymerase.     

Identification of domains in Autographa californica multiple nucleopolyhedrovirus late expression factor 3 required for nuclear transport of P143

Autographa californica multiple nucleopolyhedrovirus (AcMNPV) late expression factor 3 (LEF-3) is an essential protein for DNA replication in transient assays. P143, a large DNA-binding protein with DNA-unwinding activity, is also essential for viral DNA replication in vivo. Both LEF-3 and P143 are found in the nucleus of AcMNPV-infected cells, but only LEF-3 localizes to the nucleus when expressed in transfected cells on its own from a plasmid expression vector. P143 requires LEF-3 as a transporter to enter the nucleus. To investigate the possibility that LEF-3 carries a nuclear localization signal domain, we constructed a series of LEF-3 deletion mutants and examined the intracellular localization of the products in plasmid-transfected cells. We discovered that the N-terminal 56 amino acid residues of LEF-3 were sufficient for nuclear localization and that this domain, when fused with either the green fluorescent protein reporter gene or P143, was able to direct these proteins to the nucleus. Transient DNA replication assays demonstrated that fusing the LEF-3 nuclear localization signal domain to P143 did not alter the function of P143 in supporting DNA replication but was not sufficient to substitute for whole LEF-3. These data show that although one role for LEF-3 during virus infection is to transport P143 to the nucleus, LEF-3 performs other essential replication functions once inside the nucleus.     

Genetic, Physical, and Functional Interactions between the Triphosphatase and Guanylyltransferase Components of the Yeast mRNA Capping Apparatus

We have characterized an essential Saccharomyces cerevisiae gene, CES5, that when present in high copy, suppresses the temperature-sensitive growth defect caused by the ceg1-25 mutation of the yeast mRNA guanylyltransferase (capping enzyme). CES5 is identical to CET1, which encodes the RNA triphosphatase component of the yeast capping apparatus. Purified recombinant Cet1 catalyzes hydrolysis of the γ phosphate of triphosphate-terminated RNA at a rate of 1 s⁻¹. Cet1 is a monomer in solution; it binds with recombinant Ceg1 in vitro to form a Cet1-Ceg1 heterodimer. The interaction of Cet1 with Ceg1 elicits >10-fold stimulation of the guanylyltransferase activity of Ceg1. This stimulation is the result of increased affinity for the GTP substrate. A truncated protein, Cet1(201-549), has RNA triphosphatase activity, heterodimerizes with and stimulates Ceg1 in vitro, and suffices when expressed in single copy for cell growth in vivo. The more extensively truncated derivative Cet1(246-549) also has RNA triphosphatase activity but fails to stimulate Ceg1 in vitro and is lethal when expressed in single copy in vivo. These data suggest that the Cet1-Ceg1 interaction is essential but do not resolve whether the triphosphatase activity is also necessary. The mammalian capping enzyme Mce1 (a bifunctional triphosphatase-guanylyltransferase) substitutes for Cet1 in vivo. A mutation of the triphosphatase active-site cysteine of Mce1 is lethal. Hence, an RNA triphosphatase activity is essential for eukaryotic cell growth. This work highlights the potential for regulating mRNA cap formation through protein-protein interactions.     

Identification of a novel function of the alphavirus capping apparatus. RNA 5'-triphosphatase activity of Nsp2

Both genomic and subgenomic RNAs of the Alphavirus have m(7)G(5')ppp(5')N (cap0 structure) at their 5' end. Previously it has been shown that Alphavirus-specific nonstructural protein Nsp1 has guanine-7N-methyltransferase and guanylyltransferase activities needed in the synthesis of the cap structure. During normal cap synthesis the 5' gamma-phosphate of the nascent viral RNA chain is removed by a specific RNA 5'-triphosphatase before condensation with GMP, delivered by the guanylyltransferase. Using a novel RNA triphosphatase assay, we show here that nonstructural protein Nsp2 (799 amino acids) of Semliki Forest virus specifically cleaves the gamma,beta-triphosphate bond at the 5' end of RNA. The same activity was demonstrated for Nsp2 of Sindbis virus, as well as for the amino-terminal fragment of Semliki Forest virus Nsp2-N (residues 1-470). The carboxyl-terminal part of Semliki Forest virus Nsp2-C (residues 471-799) had no RNA triphosphatase activity. Replacement of Lys-192 by Asn in the nucleotide-binding site completely abolished RNA triphosphatase and nucleoside triphosphatase activities of Semliki Forest virus Nsp2 and Nsp2-N. Here we provide biochemical characterization of the newly found function of Nsp2 and discuss the unique properties of the entire Alphavirus-capping apparatus.     

A baculovirus gene involved in late gene expression predicts a large polypeptide with a conserved motif of RNA polymerases.

We have identified and sequenced a novel baculovirus gene, late expression factor eight gene (lef-8), of Autographa californica nuclear polyhedrosis virus that is necessary for efficient expression from late and very late virus gene promoters in a transient expression assay. The predicted gene product, LEF-8, has a molecular mass of 102 kDa and contains a conserved sequence motif, GXKX4HGQ/NKG, found in DNA-directed RNA polymerases throughout the animal, plant, and microbial kingdoms.     

Heterogeneity of the 5'' terminus of late mRNA induced by a viable simian virus 40 deletion mutant.

d1-1811 is a viable simian virus 40 deletion mutant which lacks the DNA region corresponding to the major capping site of the late viral RNA. The exact size of the deletion (40 base pairs) was determined by comparison of the mutant DNA sequence with the wild-type simian virus 40 (strain 776) DNA sequence. Although d1-1811 forms somewhat smaller plaques, the amount of viral RNA late after infection was not significantly reduced compared with that of the wild type. Virus-specific, polyadenylate-containing, 32P-labeled late RNA was purified from the cytoplasm and enzymatically degraded to characterize the 5' terminus. The cap-containing oligonucleotides were isolated, and their structures were analyzed by further digestion. Instead of a single cap structure, we found a variety of capped 5' termini, with adenosine caps occurring much more frequently than guanosine caps. Nevertheless, there was a remarkable homology between both types of terminal sequences. Conceivably, the minor cap population present in wild-type simian virus 40 late mRNA may correspond to the collection of capped termini identified in the d1-1811 late mRNA . Cellular cytoplasmic RNA shows a similar pattern of cap structures, but the relative abundance is quite different.     

Inhibition of a metal-dependent viral RNA triphosphatase by decavanadate

Paramecium bursaria chlorella virus, a large DNA virus that replicates in unicellular Chlorella-like algae, encodes an RNA triphosphatase which is involved in the synthesis of the RNA cap structure found at the 5' end of the viral mRNAs. The Chlorella virus RNA triphosphatase is the smallest member of the metal-dependent RNA triphosphatases that include enzymes from fungi, DNA viruses, protozoans and microsporidian parasites. In the present study, we investigated the ability of various vanadate oxoanions to inhibit the phosphohydrolase activity of the enzyme. Fluorescence spectroscopy and CD studies were used to directly monitor the binding of decavanadate to the enzyme. Moreover, competition assays show that decavanadate is a potent non-competitive inhibitor of the phosphohydrolase activity, and mutagenesis studies indicate that the binding of decavanadate does not involve amino acids located in the active site of the enzyme. In order to provide additional insight into the relationship between the enzyme structure and decavanadate binding, we correlated the effect of decavanadate binding on protein structure using both CD and guanidinium chloride-induced denaturation as structural indicators. Our data indicated that no significant modification of the overall protein architecture was occurring upon decavanadate binding. However, both fluorescence spectroscopy and CD experiments clearly revealed that the binding of decavanadate to the enzyme significantly decreased the structural stability of the enzyme. Taken together, these studies provide crucial insights into the inhibition of metal-dependent RNA triphosphatases by decavanadate.     

ATPase, GTPase, and RNA binding activities associated with the 206-kilodalton protein of turnip yellow mosaic virus.

The 206-kDa protein of turnip yellow mosaic virus belongs to an expanding group of proteins containing a domain which includes the consensus nucleotide binding site GxxxxGKS/T. A portion of this protein (amino acids [aa] 916 to 1259) was expressed in Escherichia coli and purified by affinity chromatography to near homogeneity. In the absence of any other viral factors, it exhibited ATPase and GTPase activities in vitro. A mutant protein with a single amino acid substitution in the consensus nucleotide binding site (Lys-982 to Ser) exhibited only low levels of both activities, implying that Lys-982 is important for nucleoside triphosphatase activity. The protein also possessed nonspecific RNA binding capacity. Deletion mutants revealed that an N-terminal domain (aa 916 to 1061) and a C-terminal domain (aa 1182 to 1259) participate in RNA binding. The results presented here provide the first experimental evidence that turnip yellow mosaic virus encodes nucleoside triphosphatase and RNA binding activities.     

Amino acid residues within conserved domain VI of the vesicular stomatitis virus large polymerase protein essential for mRNA cap methyltransferase activity

During mRNA synthesis, the polymerase of vesicular stomatitis virus (VSV) copies the genomic RNA to produce five capped and polyadenylated mRNAs with the 5'-terminal structure 7mGpppA(m)pApCpApGpNpNpApUpCp. The 5' mRNA processing events are poorly understood but presumably require triphosphatase, guanylyltransferase, [guanine-N-7]- and [ribose-2'-O]-methyltransferase (MTase) activities. Consistent with a role in mRNA methylation, conserved domain VI of the 241-kDa large (L) polymerase protein shares sequence homology with a bacterial [ribose-2'-O]-MTase, FtsJ/RrmJ. In this report, we generated six L gene mutations to test this homology. Individual substitutions to the predicted MTase active-site residues K1651, D1762, K1795, and E1833 yielded viruses with pinpoint plaque morphologies and 10- to 1,000-fold replication defects in single-step growth assays. Consistent with these defects, viral RNA and protein synthesis was diminished. In contrast, alteration of residue G1674 predicted to bind the methyl donor S-adenosylmethionine did not significantly perturb viral growth and gene expression. Analysis of the mRNA cap structure revealed that alterations to the predicted active site residues decreased [guanine-N-7]- and [ribose-2'-O]-MTase activity below the limit of detection of our assay. In contrast, the alanine substitution at G1674 had no apparent consequence. These data show that the predicted MTase active-site residues K1651, D1762, K1795, and E1833 within domain VI of the VSV L protein are essential for mRNA cap methylation. A model of mRNA processing consistent with these data is presented.