Hepatitis A virus capsid protein VP1 has a heterogeneous C terminus

Hepatitis A virus (HAV) encodes a single polyprotein which is posttranslationally processed into the functional structural and nonstructural proteins. Only one protease, viral protease 3C, has been implicated in the nine protein scissions. Processing of the capsid protein precursor region generates a unique intermediate, PX (VP1-2A), which accumulates in infected cells and is assumed to serve as precursor to VP1 found in virions, although the details of this reaction have not been determined. Coexpression in transfected cells of a variety of P1 precursor proteins with viral protease 3C demonstrated efficient production of PX, as well as VP0 and VP3; however, no mature VP1 protein was detected. To identify the C-terminal amino acid residue of HAV VP1, we performed peptide sequence analysis by protease-catalyzed [18O]H2O incorporation followed by liquid chromatography ion-trap microspray tandem mass spectrometry of HAV VP1 isolated from purified virions. Two different cell culture-adapted isolates of HAV, strains HM175pE and HM175p35, were used for these analyses. VP1 preparations from both virus isolates contained heterogeneous C termini. The predominant C-terminal amino acid in both virus preparations was VP1-Ser274, which is located N terminal to a methionine residue in VP1-2A. In addition, the analysis of HM175pE recovered smaller amounts of amino acids VP1-Glu273 and VP1-Thr272. In the case of HM175p35, which contains valine at amino acid position VP1-273, VP1-Thr272 was found in addition to VP1-Ser274. The data suggest that HAV 3C is not the protease responsible for generation of the VP1 C terminus. We propose the involvement of host cell protease(s) in the production of HAV VP1.

Effects of poliovirus 3AB protein on 3D polymerase-catalyzed reaction

Poliovirus RNA replication requires the activities of a viral RNA-dependent RNA polymerase, 3Dpol, in conjunction with several additional viral and likely cellular proteins. The importance of both the 3A and 3B coding regions has been documented previously by genetic tests, and their biochemical activities have been the subject of several recent investigations. In this study, we examined the previously reported stimulation of 3D-catalyzed RNA synthesis by 3AB. We show that 3AB does not stimulate RNA synthesis on templates that are stably base paired to a primer, indicating that 3AB does not stabilize or otherwise activate 3Dpol for chain elongation. Similarly, it does not alter the kinetic parameters or binding affinities of 3D for substrates. In the absence of a primer, or in the presence of a primer that does not form a stable hybrid with the template, 3AB increases the utilization of 3'-hydroxyl termini as sites for chain elongation by 3D, and thereby stimulates RNA synthesis. 3AB may interact with and stabilize these sites and/or may recruit 3Dpol to the site, resulting in stimulation of the initiation of elongation events. We propose that this activity is required for stabilizing weak interactions that occur during nucleotidyl-protein-primed initiation events in the viral RNA replication complex.

One of two NTP binding sites in poliovirus RNA polymerase required for RNA replication

The poliovirus RNA-dependent RNA polymerase (3Dpol) has been shown to contain two NTP binding sites by chemical cross-linking of oxidized nucleotide to the intact protein. Only one site (Lys-61) was shown to be essential for RNA chain elongation activity by purified enzyme; however, a full-length viral RNA, coding for an altered lysine residue (K276L) in the second site, generated virus with a minute plaque phenotype that rapidly reverted to a wild-type phenotype with Arg-276 replacing Leu-276 in 3D. Viruses with lysine to leucine substitutions in other positions of the second binding site of their polymerase proteins grew with wild-type phenotype. To test the significance of the second binding site, poliovirus 3Dpol was generated with lysine (wild-type), leucine, or arginine at residue 276 and tested for NTP cross-linking using 32P-oxidized GTP. Analysis of cyanogen bromide peptides of each 3D preparation showed that the second NTP binding site had severely reduced NTP binding in mu276(Leu) but not in the revertant mu276(Arg), despite the reported requirement for lysine in the cross-linking reaction. To eliminate the possibility that 32P-oxidized GTP cross-linked to Arg at residue 276, a model system was designed with unmodified amino acid or acetylated (alpha-amino) amino acid and 32P-oxidized GTP. Cross-linking to lysine, but not leucine or arginine, was observed thus eliminating the possibility that NTP could be cross-linked to residue 276 in 3D. We conclude that NTP binding at the second site in poliovirus 3D is at lysine residues at positions other than 276 (278 or 283), and nucleotide binding at these sites has no bearing on elongation activity or replication of the virus. Nucleotide binding only at the site including Lys-61 is essential for RNA replication.

Mutation of lysine residues in the nucleotide binding segments of the poliovirus RNA-dependent RNA polymerase

The poliovirus 3D RNA-dependent RNA polymerase contains two peptide segments previously shown to cross-link to nucleotide substrates via lysine residues. To determine which lysine residue(s) might be implicated in catalytic function, we engineered mutations to generate proteins with leucine residues substituted individually for each of the lysine residues in the NTP binding regions. These proteins were expressed in Escherichia coli and were examined for their abilities to bind nucleotides and to catalyze RNA chain elongation in vitro. Replacement of each lysine residue in the NTP binding segment located in the central portion of the 3D molecule (Lys-276, -278, or -283) with leucine produced no impairment of GTP binding or polymerase activity. Substitution of leucine for Lys-61 in the N-terminal portion of the protein, however, abolished the binding of protein to GTP-agarose and all detectable polymerase activity. A nearby lysine replacement with leucine at position 66 had no effect on enzyme activity. The three mutations in the central region of 3D were introduced into full-length viral cDNAs, and the infectivities of RNA transcripts were examined in transfected HeLa cells. Growth of virus containing 3D with a mutation at residue 278 (3Dmu278) or 3Dmu283 was indistinguishable from that of the wild type; however, 3Dmu276 generated extremely slow-growing, small-plaque virus. Polyprotein processing by 3CDmu276 was unaffected. Large-plaque variants, in which the Leu-276 codon had mutated again to an arginine codon, emerged at high frequency. The results suggest that a lysine residue at position 61 of 3Dpol is essential for polymerase catalytic function and that a basic (lysine or arginine) residue at position 276 is required for some other function of 3D important for virus growth but not for RNA chain elongation or polyprotein processing.

Elongation activity of poliovirus RNA polymerase derived from Sabin type 1 sequence is not temperature sensitive

Determinants of attenuation in the Sabin type 1 strain of poliovirus are located in the 5' noncoding region, the capsid coding region and the viral RNA-dependent RNA polymerase (3Dpol) coding region. These mutations also contribute to a temperature sensitive pheno-type of virus replication. We have cloned and expressed the Sabin 1 virus 3Dpol) protein which contains three amino acid differences from the wild-type (Mahoney) sequence, as well as a wild- type polymerase containing only a single Sabin amino acid substitution at nt 6203. These enzymes have been examined and compared for temperature sensitive polymerase activity. Wild-type and mutated polymerases demonstrated identical specific activities at 30, 35 and 39 degrees C. All three showed the same kinetics of heat inactivation after pre-incubation at elevated temperatures. Thus the contribution of Sabin 3Dpol sequences to the inability of the virus to grow at elevated temperatures must lie in a function or activity of the enzyme other than RNA polymerization. A likely reaction is the initiation step of RNA chain synthesis.

Identification of nucleotide binding sites in the poliovirus RNA polymerase

Poliovirus RNA polymerase (3Dpol) was cross-linked to [32P]ribonucleoside triphosphates (NTPs) by reduction of oxidized NTP-protein complexes. Cross-linked complexes were digested with cyanogen bromide, and resulting peptides were fractionated by reverse-phase HPLC. 32P-Labeled peptides were purified by secondary HPLC fractionation and/or additional digestion with endoproteinases Glu-C, TPCK-trypsin, or Asp-N followed by another HPLC fractionation. N-Terminal sequences of the major [32P]-peptides were determined, and approximate sizes of these peptides were obtained by SDS-polyacrylamide gel electrophoresis. Two major NTP binding sites in 3Dpol were found. One site was between Asp-266 and Met-286; possible binding residues in this fragment were Lys-276, Lys-278, or Lys-283. A second binding site was between Ala-57 and Met-74 with Lys-61 or Lys-66 as possible binding residues. Alignment of these regions on the known structure of HIV-1 reverse transcriptase allowed us to predict the position of the downstream nucleotide binding site in the conserved "fingers" subdomain present near the active site cleft of both RNA and DNA polymerases. The N-terminal nucleotide binding site is not contained within a region that is conserved among other polymerases.

Identification of terminal adenylyl transferase activity of the poliovirus polymerase 3Dpol

A terminal adenylyl transferase (TATase) activity has been identified in preparations of purified poliovirus RNA-dependent RNA polymerase (3Dpol). Highly purified 3Dpol is capable of adding [32P]AMP to the 3' ends of chemically synthesized 12-nucleotide (nt)-long RNAs. The purified 52-kDa polypeptide, isolated after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and renatured, retained the TATase activity. Two 3Dpol mutants, purified from Escherichia coli expression systems, displayed no detectable polymerase activity and were unable to catalyze TATase activity. Likewise, extracts from the parental E. coli strain that harbored no expression plasmid were unable to catalyze formation of the TATase products. With the RNA oligonucleotide 5'-CCUGCUUUUGCA-3' used as an acceptor, the products formed by wild-type 3Dpol were 9 and 18 nt longer than the 12-nt oligomer. GTP, CTP, and UTP did not serve as substrates for transfer to this RNA, either by themselves or when all deoxynucleoside triphosphates were present in the reaction. Results from kinetic and stoichiometric analyses suggest that the reaction is catalytic and shows substrate and enzyme dependence. The 3'-terminal 13 nt of poliovirus minus-strand RNA also served as an acceptor for TATase activity, raising the possibility that this activity functions in poliovirus RNA replication. The efficiency of utilization and the nature of the products formed during the reaction were dependent on the acceptor RNA.

Expression of hepatitis A virus precursor protein P3 in vivo and in vitro: polyprotein processing of the 3CD cleavage site

Hepatitis A virus (HAV) cDNAs encoding the P3 region proteins were expressed in vivo and in vitro to characterize the HAV 3D protein and to identify the cleavage site between 3C and 3D. Protein coding sequences were placed under control of a T7 promoter and an EMCV translational initiation signal. T7 RNA polymerase was provided by simultaneous infection of transfected BS-C-1 cells with a recombinant vaccinia virus vTF7-3 (T. R. Fuerst et al., Proc. Natl. Acad. Sci. USA 83, 8122-8126, 1986). Efficient synthesis and processing of P3 proteins occurred to yield 3CD (78 kDa), 3D (54 kDa), 3ABC (33 kDa), 3BC (25 kDa), and 3C (23 kDa). Similar products were produced by translation of T7 transcripts in a rabbit reticulocyte lysate in vitro. The 3C/D cleavage site was mapped by comparing the mobility of 3D in SDS-PAGE with 3D proteins engineered to begin at each of the two proposed cleavage sites; in addition, direct N-terminal sequencing of radiolabeled 3D protein from translation in vitro was performed. The results showed that 3D was formed by cleavage at the glutamine-arginine (Q/R) pair at position 1738 and 1739 of the HAV polyprotein. HAV 3D protein produced by autocatalytic cleavage of P3 precursor proteins in BS-C-1 cells is virtually completely insoluble and sediments after low-speed centrifugation. This is in contrast to the poliovirus 3D protein, produced from a similar construct, a significant portion of which remains soluble. Extracts containing the poliovirus 3D protein manifested high levels of RNA-dependent RNA polymerase activity, whereas those containing the HAV 3D protein showed no detectable activity by the same assay.

RNA duplex unwinding activity of poliovirus RNA-dependent RNA polymerase 3Dpol

The ability of highly purified preparations of poliovirus RNA-dependent RNA polymerase, 3Dpol, to unwind RNA duplex structures was examined during a chain elongation reaction in vitro. Using an antisense RNA prehybridized to an RNA template, we show that poliovirus polymerase can elongate through a highly stable RNA duplex of over 1,000 bp. Radiolabeled antisense RNA was displaced from the template during the reaction, and product RNAs which were equal in length to the template strand were synthesized. Unwinding did not occur in the absence of chain elongation and did not require hydrolysis of the gamma-phosphate of ATP. The rate of elongation through the duplex region was comparable to the rate of elongation on the single-stranded region of the template. Parallel experiments conducted with avian myeloblastosis virus reverse transcriptase showed that this enzyme was not able to unwind the RNA duplex, suggesting that strand displacement by poliovirus 3Dpol is not a property shared by all polymerases.

Nucleotide binding by the poliovirus RNA polymerase

Cross-linking of ribonucleoside triphosphates (NTPs) to specific binding sites on the poliovirus RNA-dependent RNA polymerase has been performed by ultraviolet irradiation and by reduction of oxidized nucleotide-protein complexes. The latter method approached a cross-linking efficiency of 1 NTP/molecule of enzyme. Nucleotide competition experiments suggested that the same binding site is occupied by all NTPs. Analysis of peptides produced by proteinase Glu-C and trypsin digestion and labeled with [32P]GTP indicated that a lysine residue between Met-189 and Lys-228 in the polymerase was cross-linked to NTP. Nucleotide binding was exploited for rapid purification of the enzyme by GTP-agarose affinity chromatography. In addition, a set of cloned, modified polymerase molecules with reduced or absent polymerization activity was analyzed for binding efficiency to a GTP-agarose column. Some mutations eliminated GTP binding, whereas others generated proteins with varying affinities for GTP. Incubation of the poliovirus polymerase with high concentrations of NTP, particularly GTP, resulted in a dramatic protection against heat denaturation and activity loss. These data suggest that nucleotide binding results in an alteration of the enzyme conformation or the stabilization of an ordered conformation.

Temperature-sensitive polioviruses containing mutations in RNA polymerase

Site-directed mutagenesis was performed to change the wild-type residue (asparagine) to aspartate, histidine, or tyrosine at amino acid 424 of the poliovirus RNA polymerase, 3Dpol. The mutations were introduced into plasmids containing full-length viral cDNA and plasmids which direct the expression of 3Dpol in Escherichia coli. Mutant viruses, recovered after transfection of HeLa cells with RNA transcripts of the full-length clones, produced small plaques at 32 degrees. In addition, the plaquing efficiency was decreased for all three mutants at 37 degrees, compared to 32 degrees. The polyprotein processing of all mutant viruses was normal at the temperatures tested, suggesting that the mutant plaque phenotypes were not due to incorrect processing of viral proteins. Analyses of viral RNA synthesis in infected cells and of the polymerase activities of mutant enzymes produced in E. coli suggested the following: (1) The his424 mutant enzyme appeared to be defective in the initiation of plus-strand RNA synthesis in HeLa cells. (2) The asp424 mutant enzyme appeared unable to assume proper conformation for active polymerase function when synthesized at 37 degrees. (3) The tyr424 mutant enzyme was totally inactive when synthesized in E. coli at 37 degrees.

Purification, characterization, and comparison of poliovirus RNA polymerase from native and recombinant sources

Poliovirus RNA encodes an RNA-dependent RNA polymerase, designated 3Dpol, that catalyzes the synthesis of both plus and minus strand viral RNA. This enzyme was purified to near homogeneity from poliovirus-infected HeLa cells, recombinant baculovirus-infected insect cells, and from Escherichia coli transformed with an expression plasmid containing poliovirus 3D sequences. The two recombinant expression systems produced significantly higher yields of active enzyme than could be attained from virus-infected HeLa cells. All preparations contained a 52-kDa protein, recognized by antisera raised against 3D expressed as a fusion protein in E. coli. Immunoreactive protein resolved into 3-4 species on isoelectric focusing sodium dodecyl sulfate-polyacrylamide gel electrophoresis two-dimensional gels. Efforts to demonstrate that the multiple spots resulted from phosphorylation were negative. Furthermore, no evidence for autophosphorylation of purified 3Dpol was obtained. Purified 3Dpol from recombinant sources manifested the same specific activities as enzyme from poliovirus-infected HeLa cells in both a poly(A)-dependent poly(U) polymerase assay and a poliovirus RNA-dependent RNA polymerase assay. The products of the latter reaction reached the length of the template (7.5 kilobases) in 20-30 min, indicating an elongation rate of approximately 300 nucleotides/min at 30 degrees C. No products exceeded the length of the template. Intermediate length products were detected, which presumably resulted from pauses in transcription due to template structure. All transcription was dependent on primer. The kinetic parameters of all three purified enzyme preparations were the same; the Km for UTP was 2.4 +/- 0.1 microM in an RNA polymerase activity assay. Product formation was linear for up to 45 min, except for a 3-5-min lag before synthesis began. The lag was independent of enzyme concentration, and independent of the template used. The lag was eliminated by preincubating enzyme, template, primer, and three of the four nucleotide triphosphates, but not by preincubating any subset of these components. This suggested that a preinitiation complex must form as a prerequisite to RNA synthesis. Partially purified preparations of 3Dpol from the three sources showed significant differences in activities and products, including the appearance of primer-independent polymerase activity and production of dimer-length RNA products. These variable properties are likely due to different contaminating activities provided by the different cellular hosts, since upon further purification, all three enzymes exhibited identical properties.

The 5'-terminal nucleotides of hepatitis A virus RNA, but not poliovirus RNA, are required for infectivity

A series of plasmids containing hepatitis A virus (HAV) cDNA was constructed such that positive-strand HAV RNA could be transcribed with T7 RNA polymerase. The plasmids differed in the number of 5'-terminal nucleotides representing the junctions between vectors and HAV sequences that were present in the transcripts. When these transcripts were used to transfect cultured BS-C-1 cells, it was found that only those transcripts that contained all of the 5'-terminal HAV nucleotides, in addition to one or more nucleotides from the vector, were capable of initiating an infectious cycle leading to production of progeny virus. Transcripts that contained one 5'-terminal nucleotide from the vector sequence but were missing two uridylate residues corresponding to the first two nucleotides of HAV sequences, or were missing U and C residues corresponding to nucleotides 2 and 3 of the HAV sequence, were not infectious. A similar plasmid containing poliovirus cDNA was engineered to produce transcripts similarly lacking the first two uridylate residues of the poliovirus RNA sequence. These transcripts were infectious.

Expression and characterization of poliovirus proteins 3BVPg, 3Cpro, and 3Dpol in recombinant baculovirus-infected Spodoptera frugiperda cells

As an initial step toward investigating the roles of poliovirus proteins in viral RNA replication, a baculovirus expression system was used to produce poliovirus proteins from the P3 region. Spodoptera frugiperda (Sf9) cells were infected with a recombinant baculovirus, vETL-PoV3A*BCD, which contains cDNA coding for poliovirus proteins 3D, 3C, 3B, and a portion of 3A protein sequence. Immunofluorescence microscopy revealed that the majority of 3D (polymerase) was in the cytoplasm of recombinant baculovirus-infected Sf9 cells. In the same cells, the 3C (protease) and 3B (VPg) proteins appeared to be located in distinct subcellular regions, possibly membrane structures, suggesting that the expressed polyprotein was cleaved to generate mature proteins. Processing of the polypeptide was confirmed by immunoblot analysis which demonstrated that 3Cpro sequences were active in cleavage of the polyproteins 3A*BCD and 3CD. Over 95% of the 3D sequences accumulated in the form of mature 3Dpol, with only low levels of 3CD remaining. The majority of 3Dpol remained in the supernatant after low speed centrifugation of sonicated cells. The 3Dpol had RNA-dependent RNA polymerase activity as measured by elongation of an oligo(U) primer using a poly(A) template. The protein 3CDpro was active in cleaving P1 protein. The yield and activities of the poliovirus proteins expressed will facilitate future biochemical studies.

High-level synthesis of cowpea mosaic virus RNA polymerase and protease in Escherichia coli

An expression system for the production of polymerase proteins of cowpea mosaic virus (CPMV) in Escherichia coli cells is described. High-level synthesis of proteins containing protease and polymerase moieties (110-kDa protein) and polymerase alone (87-kDa protein) were obtained from cells containing different plasmid constructions. Precursor and processed forms of CPMV proteins were detected by immunoblotting with antisera directed against 170-kDa precursor polyprotein and 24-kDa viral protease. Crude lysates and supernatant fractions of the lysates from E. coli cells harboring the various plasmid constructions were analysed for poly(A)-oligo(U) polymerase activity and found to be negative for CPMV activity under conditions where similar expression systems for the production of poliovirus RNA polymerase activity were positive. Thus, conditions for CPMV RNA replication may indeed be different from those for poliovirus even though the genomic organization of these viruses is similar.

Enzymatic activity of poliovirus RNA polymerase synthesized in Escherichia coli from viral cDNA

Plasmids have been constructed that contain DNA sequences that direct the expression of the poliovirus RNA-dependent RNA polymerase, in the form of recombinant fusion proteins. Inclusion of an additional gene for the poliovirus protease results in cleavage of the fusion protein to yield a 52-kDa, enzymatically active, polymerase protein, apparently identical to the functional enzyme isolated from virus-infected HeLa cells. A large amount of polymerase protein accumulates as particulate or insoluble material in bacteria, and this protein has little or no activity. However, significant amounts of soluble, active enzyme are recovered, such that the resulting specific activity of crude bacterial extracts is greater than that obtained from virus-infected HeLa cells. Purification of the enzyme from Escherichia coli is readily accomplished, and yields a preparation that will copy poliovirion RNA as template, in the presence of oligo(U) primer. The availability of cloned DNA sequences encoding catalytically active RNA polymerase will allow genetic manipulations to initiate structure-function studies of this enzyme.

Antigenic and immunogenic properties of a hepatitis A virus capsid protein expressed in Escherichia coli

We have constructed a recombinant plasmid producing, in bacteria, a hepatitis A virus (HAV) capsid protein that may be useful as a subunit vaccine. HAV VP1 coding sequences were fused in-frame to NH2-terminal Escherichia coli TrpE coding sequences under the control of the tryptophan promoter. In the absence of exogenous tryptophan, E. coli containing this recombinant plasmid produced high levels of an 88-kilodalton fusion protein that was recognized in immunoblots by antibodies to TrpE and HAV. The TrpE/HAV VP1 protein was gel-purified and used to immunize rabbits. The resulting antiserum reacted with denatured HAV VP1 in immunoblots but did not react with intact virus. However, subsequent inoculation of an immunized animal with a subimmunogenic dose of inactivated, whole HAV resulted in the rapid appearance of a stable, virus-neutralizing antibody response.

Expression of hepatitis A virus capsid sequences in insect cells

A cDNA coding for hepatitis A virus (HAV) VP1 and portions of the flanking VP3 and P2 sequences was inserted into the genome of Autographa californica nuclear polyhedrosis virus under the control of the polyhedrin promoter and translational start codon. Cells infected with recombinant virus produced high levels of a 55 kDa protein, identified as containing HAV VP1 by reactivity with anti-VP1 serum. The expressed protein also reacted on immunoblots with human HAV convalescent sera as well as sera from rabbits immunized with intact HAV. This protein was found predominantly in the cytoplasm of infected insect cells, probably as an insoluble aggregate.

Formation of poliovirus RNA polymerase 3D in Escherichia coli by cleavage of fusion proteins expressed from cloned viral cDNA

The poliovirus polymerase 3D was synthesized in Escherichia coli by cleavage of fusion proteins expressed from cloned viral cDNA inserted into several plasmid expression vectors. Cleavage was accomplished by the action of viral protease 3C sequences expressed in the same bacteria, either from a second plasmid or from the same plasmid, cloned so as to produce contiguous sequences in the same protein. In the case of two plasmids, protease 3C functioned in trans to cleave the fusion protein at or very near the normal Gln/Gly cleavage site. When protease and polymerase sequences were produced in the same protein, the protease sequences acted in the precursor form to release the polymerase from itself. Thus, cleavage can occur to generate polymerase 3D both as an intermolecular reaction and, very likely, also as an intramolecular event.

Poliovirus snapback double-stranded RNA isolated from infected HeLa cells is deficient in poly(A)

A portion of poliovirus double-stranded RNA (25 to 50%) isolated from infected HeLa cells contains hairpin loops at one end of the duplex structure. These structures rapidly reformed double-stranded molecules after denaturation and appeared as molecules of up to two times genome length upon electrophoresis in denaturing agarose gels. A second form of poliovirus double-stranded RNA was readily denaturable into genome length strands. When the hairpin RNA was treated with S1 nuclease, subsequent denaturation resulted in formation of strands of up to genome length. Hairpin molecules contained very little, if any, poly(A) sequences, suggesting that the hairpin forms after nucleolytic removal of the 3' end of plus-strand templates. We conclude that the hairpin double-stranded RNA found in infected cells is likely generated by intracellular nicking and self-priming and that it does not represent an intermediate in the process of RNA replication.

Host factor-induced template modification during synthesis of poliovirus RNA in vitro

Poliovirus RNA polymerase, 3Dpol, transcribes poliovirus RNA in vitro in the presence of a host factor (HF) preparation from uninfected HeLa cells to yield heterogeneous-size product RNAs. The products include some molecules larger than the template that represent self-primed elongations of the template from a 3'-terminal hairpin. We showed that transcription proceeded through the formation of a modified RNA intermediate that was generated by nucleolytic cleavage of the template by HF in the absence of nucleoside triphosphates. Cleavage resulted in the loss of the original poly(A) 3' end and the generation of new, heterogeneous 3' ends that formed self-priming structures that could then be elongated by 3Dpol or reverse transcriptase. The two stages of the reaction, (i) cleavage to yield self-priming templates and (ii) subsequent chain elongation to yield heterogeneous-size products up to nearly dimer length, could be separated. RNAs whose original 3' ends were chemically oxidized so as to prevent chain elongation showed no reduction in template activity after preincubation with HF. We conclude that an HF preparation that contains a low level of nuclease activity is sufficient to activate RNA templates for transcription by 3Dpol to generate up to apparent dimer-length products. This reaction likely has little relevance to the mechanism of poliovirus RNA replication in vivo. It is likely that numerous other factors or activities, in addition to 3Dpol, would also result in transcription of poliovirus RNA in vitro.

Synthesis of plus- and minus-strand RNA from poliovirion RNA template in vitro

The poliovirus RNA polymerase, 3Dpol, was used to synthesize RNA in vitro in the presence of a host factor preparation from uninfected HeLa cells and poliovirion RNA as the template. The transcription products included molecules approximately twice the length of the template, apparently resulting from hairpin formation and template-directed elongation, as previously reported (D. C. Young, D. M. Tuschall, and J. B. Flanegan, J. Virol. 54:256-264, 1985). Other polyadenylated template RNAs also yielded products that were twice the length of the template. The polarity of the products synthesized from plus-strand poliovirus RNA template was analyzed by Southern blotting using labeled product RNA to probe single-stranded poliovirus DNAs cloned into M13 vectors. The results demonstrated that host factor-mediated polymerase products contain newly synthesized plus-strand sequences as well as the expected minus-strand sequences. Polymerase products primed with oligo(U) were all of minus-strand polarity.

Two forms of poliovirus VPg result from amino acid modification of a single viral protein

The protein (VPg) covalently attached to the 5' terminus of poliovirus RNA has been reported to resolve into two forms, separable by electrofocusing, yet the viral gene sequence predicts only one apparent gene for VPg. The two VPg species were separated and analyzed for structural differences. The protein contains no phosphorylated amino acid residues other than the junction tyrosine linked to the nucleic acid moiety. After isolation, the acidic form of VPg remains stable, but the more basic form again generates a distribution of both species. This suggests some lability or modification of at least one amino acid residue postsynthesis. The position of the alteration in the protein was localized to the amino-terminal tryptic peptide, containing nine amino acids.

Structure of poliovirus replicative intermediate RNA. Electron microscope analysis of RNA cross-linked in vivo with psoralen derivative

The structure of the poliovirus replicative intermediate RNA was examined by electron microscopy after cross-linking in vivo with 4'-aminomethyl-4,5',8-trimethylpsoralen. After purification from infected cells, undenatured RI appeared as a double-stranded backbone of genome length, with an average of three (and occasionally up to eight) nascent, single-stranded tails. After denaturation, however, only single strands of heterogeneous length were visualized, indicating that the RI in the cell contains little or no duplex structure, and thus nascent chains are only transiently hydrogen-bonded to their template over short regions. The double-stranded backbone of undenatured RI, observed previously by others and in these experiments, is due to collapse of complementary chains during the deproteinization and purification procedures. The effectiveness of the in vivo cross-linking procedure was demonstrated by the complete inhibition of viral RNA synthesis in treated cells and by direct binding of [3H]AMT to RI molecules in vivo. Mature polio virions are impermeable to AMT; however, growth of virus in cells incubated with AMT in the dark resulted in normal yields of virus particles containing RNA genomes, whose infectivity could be subsequently photo-inactivated. The frequency of AMT-induced cross-linking was determined by analyses of double-stranded poliovirus RNA (RF). Cross-linking in vitro followed by spreading for electron microscopy under denaturing conditions yielded bubbled duplex structures with a minimum of one interstrand cross-link per 80 base-pairs. RF cross-linked in vivo also showed extensive cross-linking, decreased about fivefold from the in vitro cross-linked value. Thus, the failure to detect cross-linked RI under these conditions indicates that extensive base-pairing does not exist in vivo.

Analysis of Theiler's virus isolates from persistently infected mouse nervous tissue

The DA strain of Theiler's virus causes a chronic progressive demyelination in mice following intracerebral inoculation. Virus was isolated from chronically infected mice, and then grown in cell culture, and the isolates were compared with the parent virus used for inoculation. No defective interfering particles or temperature-sensitive virus were recovered, and capsid proteins appeared identical by SDS-PAGE. One of three isolates had evidence of genomic mutation by Tl ribonuclease oligonucleotide fingerprinting. The significance of these findings with regard to the generation and maintenance of persistence and to adaptation to cell culture is discussed. Also of interest was the marked difference between the DA fingerprint and that of GD VII, a serologically related strain with different biological activity.

Characterization of a cell culture persistently infected with the DA strain of Theiler's murine encephalomyelitis virus

We established a persistent infection in L 929 cells with the DA strain of Theiler's murine encephalomyelitis virus. Our studies showed that only a small number of cells in the cultures contained infectious virus or viral antigen. A role for interferon in the maintenance of persistence was suggested. Viral isolates from the cultures were not temperature sensitive, nor did they contain viral capsid polypeptide mutations or defective interfering particles. T1 oligonucleotide maps showed evidence of mutation in two of three isolates.

Two forms of VPg on poliovirus RNAs

The protein (VPg) linked to the 5' termini of poliovirus RNAs resolved into two species when subjected to non-equilibrium electrofocusing. The differently charged forms of VPg were not due to protein phosphorylation nor to variability of the number of phosphate residues associated with the nucleotide moiety remaining after RNase digestion of the nucleoprotein. Single-stranded viral RNA isolated from mature virions contained predominantly the more basic form of VPg, whereas unpackaged single-stranded RNa remaining in cells at the end of the virus replication cycle contained predominantly the more acidic form of VPg. Replicative-form (RF) molecules also contained both species of VPg, with the more acidic form representing the major species. Both plus and minus RNA strands in RF had similar VPg compositions; however, there appeared to be a strongly selective loss of VPg from only the minus strand in RF, particularly at late times postinfection.

Heterogeneity of the 3' end of minus-strand RNA in the poliovirus replicative form

The 3' terminus of the strand (minus strand) complementary to poliovirion RNA (plus strand) has been examined to see whether this sequence extends to the 5'-nucleotide terminus of the plus strand, or whether minus-strand synthesis terminates prematurely, perhaps due to the presence of a nonreplicated nucleotide primer for initiation of plus-strand synthesis. The 3' terminus was labeled with 32P using [5'-32P]pCp and RNA ligase, and complete RNase digests were performed with RNases A, T1, and U2. 32P-oligonucleotides were analyzed for size by polyacrylamide-urea gel electrophoresis. The major oligonucleotide products formed were consistent with the minus strand containing 3' ends complementary and flush with the 5' end of the plus strand. However, a variable proportion of the isolated minus strands from different preparations were heterogeneous in length and appeared to differ from each other by the presence of one, two, or three 3'-terminal A residues.

Strand-specific attachment of avidin-spheres to double-stranded poliovirus RNA

Poliovirus-specific double-stranded RNA molecules containing covalently attached protein were coupled with a biotin ester through the protein moiety. Subsequent interaction of the RNA-biotin with avidin attached to electronopaque plastic spheres led to the formation of complexes that were easily visualized in the electron microscope. Avidinspheres were associated only with one end of the RNA-biotin molecules, as seen in the electron microscope. Avidin-sphere attachment to poliovirus double-stranded RNA is strand specific, as shown by molecular hybridization of strand-specific probes to the separated strands of denatured complexes. [3H]DNA complementary to polio virion RNA hybridized exclusively to the strands bearing associated spheres [(+) strands] whereas 125I-labeled virion RNA hybridized predominantly with strands without spheres [(-)strands]. This biotin-avidin labeling technique provides a means for the isolation of full-length poliovirus (-) strands and may provide a general means for isolation of double-stranded polynucleotides containing tightly attached protein.

DNA synthesis and DNA polymerase activity in Leydig cells of diethylstilbestrol-stimulated mouse testes

Using a modification of the collagenase dispersion method of Dufau et al., we examined changes in DNA synthesis produced by estrogens in the interstitial cells of mice that develop malignant Leydig cell tumors after prolonged estrogen administration. Previous work in cryptorchid mice indicated that during continuous estrogen administration [3H]thymidine incorporation into DNA rises to a maximum in 3 to 4 days and then falls to approximately base levels within 2 to 3 weeks. This was confirmed both in Leydig cell concentrates of estrogen-treated mice after either injection with [3H]thymidine or incubation with [3H]thymidine in vitro. This DNA synthesis was blocked by hydroxyurea. DNA synthesis in cells of estrogen-treated BALB/c mice of the Huseby substrain, which have a high incidence of Leydig cell tumors, was 5 to 11 times that in untreated controls. Cells from estrogen-treated C3H/Bi mice, which have a low incidence of Leydig cell tumors, showed only a 2- to 3-fold increase. In the Huseby substrain the rise of DNA synthesis is a peak and subsequent recession were paralleled by a rise and fall in DNA polymerase alpha activity. DNA polymerase beta did not show this variation. In C3H/Bi mice, neither polymerase showed significant change. The evidence suggests that the early estrogen-stimulated DNA synthesis is probably replicative and is associated with increased DNA polymerase alpha activity.

Isolation of a transcriptionally active chromosome from chloroplasts of Euglena gracilis

A transcriptionally active chromosome has been isolated in highly purified form from choroplasts of Euglena gracilis, It contains chloroplast DNA, DNA-dependent RNA polymerase, and other proteins. Transcription occurs at low levels of endogenous DNA, and is indifferent to high levels of exogenous DNA. RNA chain elongation continues for several hours in vitro, and RNA chain initiation, determined by [gamma-32P]ATP incorporation, is continuous for at least 1 h in vitro. Maximal rates for RNA synthesis require only a divalent cation and the four ribonucleoside triphosphates. Apparent Km values for adenosine triphosphate, cytidine triphosphate, guanosine triphosphate, and uridine triphosphate are 4.0, 0.6, 2.5, and 2.3 muM, respectively. As would be expected for a DNA-dependent RNA polymerase, RNA synthesis is inhibited by actinomycin D. However, rifampicin and streptolydigin, inhibitors of procaryotic RNA synthesis, and alpha-amanitin, an inhibitor of eucaryotic nuclear RNA polymerases II and III, do not inhibt the RNA synthesis reaction. Heparin, which is a potent inhibitor of the initiation of RNA synthesis by a nontemplate bound RNA polymerase, also does not inhibit RNA synthesis. Isolation of transcriptionally active chromosomes should prove to be a useful method to study the mechanism of selective RNA transcription of eucaryotic chromosomes.

DNA polymerase activity of cultured rheumatoid synovial cells

Cultured synovial cells from 8 patients with rheumatoid arthritis (RA) and 7 subjects without joint disease were assayed and comapred for RNA-directed and DNA-directed DNA polymerase activity. No activity was found in either RA or control specimens using a synthetic RNA template that specificically detects oncornavirus RNA-directed DNA polymerase. The DNA-directed DNA polymerase activity of RA specimens was increased (P less than 0.10) in the high-speed pellet fraction of cell lysates. The possible relationship of these finding to virus infection in RA is disscussed.

Circular chloroplast DNA from Euglena gracilis

Chloroplast DNA of the protozoan flagellate, Euglena gracilis, exists as circular molecules, 40 mum in contour length, as shown by electron microscopy and buoyant density analyses.