Nucleic-acid-chaperone activity of retroviral nucleocapsid proteins: significance for viral replication.

Retrovirus particles contain a small, basic protein, the nucleocapsid (NC) protein, that possesses 'nucleic acid chaperone' activity--that is, the NC protein can catalyze the rearrangement of a nucleic acid molecule into the conformation that has the maximal number of base pairs. The molecular mechanism that underlies this effect is not understood. Because the chaperone activity is apparently crucial during the infectious process, NC is a potential target for antiviral therapy.

Localization of DNA binding activity of HIV-1 integrase to the C-terminal half of the protein.

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) is the viral protein required for integration of the HIV-1 genome into host cell DNA. A series of clones expressing portions of IN as lambda cII fusion proteins has been constructed in an Escherichia coli expression system; a Southwestern procedure was used to examine binding of the expressed proteins to DNA oligonucleotides. Proteins expressed by clone pHIP106, encoding the entire IN protein but no other pol sequence, and pKNA101, which expresses an IN fusion protein containing 23 amino acids of HIV-1 reverse transcriptase at its amino terminus, exhibited similar levels of oligonucleotide binding. Little DNA sequence specificity was associated with binding activity and there was a preference for Mn2+ over Mg2+ and Ca2+. Interestingly, the protein expressed by an N-terminal clone containing nucleotides coding for IN amino acids 1-141 (including a conserved His-Cys box) was unable to bind oligonucleotide, whereas the protein expressed by a C-terminal clone containing nucleotides coding for amino acids 142-288 exhibited binding equivalent to that of full-length IN. The C-terminal protein was unreactive with a MAb to the lambda cII leader peptide and with an antipeptide serum directed against amino acids 141-158. These results are consistent with the previously reported internal initiation of IN protein synthesis in E. coli at met 154, and indicate that the C-terminal clone does not express IN amino acids 142-153. These amino acids represent part of a conserved region termed D(35)E, containing amino acids 116-152, which has been implicated in IN DNA binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of HIV-1 integrase in E. coli: immunological analysis of the recombinant protein.

Sequences encoding the human immunodeficiency virus type 1 (HIV-1) integrase gene have been cloned and expressed in Escherichia coli. The expressed protein is a lambda cII fusion protein of 37 kD containing the carboxyl-terminal 23 [corrected] amino acids of reverse transcriptase fused to the entire integrase sequence and is insoluble, a feature which allows partial purification away from soluble bacterial proteins. As judged by its reactivity with HIV positive sera in Western blot and in enzyme-linked immunosorbent assay (ELISA), the recombinant integrase retains antigenicity similar to native protein. Additionally, ELISA data obtained with the cloned protein indicate that patients infected with HIV-1 who are at different stages of progression to AIDS have antibodies reactive with the cloned integrase. HIV-2 positive human sera are also reactive with the cloned integrase. Rabbit antibodies produced against the recombinant protein react both by ELISA and Western blot with the homologous bacterially expressed protein, recognize both virion HIV-1 integrase and reverse transcriptase in Western blots, and immunoprecipitate an HIV-1 virion protein of 34 kD. Unlike human antisera from patients infected with HIV-1 or HIV-2 which are frequently reactive with both HIV-1 and HIV-2 integrase, the rabbit antibodies are type specific, reacting with HIV-1, but not with HIV-2 integrase by Western blot.

Selective packaging of host tRNA's by murine leukemia virus particles does not require genomic RNA.

The 4S RNA contained in RNA tumor virus particles consists of a selected population of host tRNA's. However, the mechanism by which virions select host tRNA's has not been elucidated. We have considered a model which specifies that 35S genomic RNA determines which tRNA's are to be encapsidated as well as the relative amounts of these tRNA's within the virion. The model was tested by comparing the free 4S RNA composition of normal murine leukemia virus (MuLV) particles and noninfectious virions from actinomycin D (ActD)-treated cells, which are deficient in genomic RNA (ActD virions). Viral 4S RNA was analyzed by two-dimensional polyacrylamide gel electrophoresis. Surprisingly, the patterns obtained for control and ActD 4S RNA were identical to each other and were clearly distinct from the cell 4S RNA pattern. The viral patterns had three prominent areas of radioactivity. One of the spots was identified on the basis of its oligonucleotide fingerprint as tRNA (Pro), the primer for MuLV RNA-directed DNA synthesis. These results were obtained with two different MuLV strains, AKR and Moloney, each grown in SC-1 cells. The demonstration that ActD virions contain primer tRNA and in general exhibit the characteristic MuLV tRNA pattern rather than the complete representation of cell 4S RNA leads to the conclusion that genomic RNA is not the major determinant in selective packaging of host tRNA's. A possible role for one or more viral proteins, including reverse transcriptase, is suggested.

Effect of polymerase mutations on packaging of primer tRNAPro during murine leukemia virus assembly.

The role of reverse transcriptase in selective encapsidation of the murine leukemia virus (MuLV) tRNA primer, tRNAPro, was investigated by examining the tRNA composition of several nonconditional pol mutants. One mutant, clone 23, which contains an altered polymerase about 40% smaller than the wild-type enzyme (B. I. Gerwin et al., J. Virol. 31:741-751, 1979) had a typical viral tRNA pattern, including normal levels of tRNAPro in free and 70S-associated 4S RNA. Another class of mutants, produced by Moloney murine leukemia virus-infected cell clone M13 and subclone M13/1, does not contain any detectable polymerase protein (A. Shields et al., Cell 14:601-609, 1978) and was found to have reduced amounts of tRNAPro in free 4S RNA. However, the level of tRNAPro associated with the genome was normal in the mutant virions. These results suggest that the reverse transcriptase protein is involved in the initial selection of tRNA primer during virus assembly, but not in the subsequent association of this tRNA with genomic RNA.

Sequence and structural determinants required for priming of plus-strand DNA synthesis by the human immunodeficiency virus type 1 polypurine tract.

At the 3' end of all retroviral genomes there is a short, highly conserved sequence known as the polypurine tract (PPT), which serves as the primer for plus-strand DNA synthesis. We have identified the determinants for in vitro priming by the human immunodeficiency virus type 1 (HIV-1) PPT. We show that when the PPT is removed and placed into different nucleotide contexts, new priming sites are produced at the precise 3' end of the PPT. In addition, we find that a hybrid consisting of a 15- or 20-nucleotide RNA primer annealed to a 35-nucleotide DNA template is competent for initiation of plus-strand synthesis with HIV-1 reverse transcriptase. Thus, no cis-acting elements appear to be required for priming activity. Changes at the 5' end of the PPT have no effect on primer function, whereas the identity of bases at the 3' end is crucial. A primer containing only the 6 G residues from the 3' end of the wild-type PPT sequence and 9 bases of random sequence at the 5' end functions like a wild-type PPT. A short hybrid having a similar helical structure but a primary sequence different from that of the PPT is cleaved imprecisely, resulting in initiation of synthesis at multiple sites; however, total primer extension is close to the wild-type level. We conclude that helical structure as well as the presence of particular bases at the 3' end of the PPT is essential for PPT function.

Synthesis of murine leukemia virus proteins associated with virions assembled in actinomycin D-treated cells: evidence for persistence of viral messenger RNA.

Murine leukemia virus particles assembled in actinomycin D-treated cells were detected by determination of reverse transcriptase [RNA-dependent DNA polymerase (nucleotidyltransferase)] activity and by radioimmunoassay of the major virion protein, p30. The levels of enzyme activity and p30 protein were both 30-40% relative to the control over an 8 hr period, whereas after 3 or 4 hr infectivity was reduced by 95%. Thus, virions produced in the absence of RNA synthesis represent a fairly homogeneous population of defective particles. Although RNA synthesis is not necessary for virus assembly, protein synthesis is required. Treatment of cells with 10 mug/ml of cycloheximide reduced virus production by 80-85% within 2 hr, and by greater than 95% at later times. As might be expected from this finding, viral protein synthesis accompanies virus assembly in actinomycin D-treated cells. Newly synthesized proteins associated with the defective particles were identical with those found in standard virions and were present in the correct proportions. The results demonstrate that viral mRNA persists in cells in which RNA synthesis is blocked and continues to direct viral protein synthesis with a functional half-life of approximately 6-8 hr. Since viral mRNA is not packaged in virions even when viral RNA synthesis is shut off [Levin et al. (1974) J. Virol. 14, 152-161], we propose that murine leukemia virus-infected cells contain two nonequilibrating pools of intracellular viral RNA molecules, one associated with polyribosomes and one which is encapsidated into extracellular particles.

Readthrough suppression in the mammalian type C retroviruses and what it has taught us.

Mammalian type C retroviruses use translational suppression to synthesize the enzymes which function in virus replication. The UAG termination codon at the end of the coding region for the viral core proteins is translated as glutamine at a frequency of approximately 5%, allowing synthesis of the enzymes as part of a large fusion protein. This unusual mechanism has several benefits for the virus: first, it modulates the relative levels of synthesis of the core proteins and the enzymes. This is essential for the proper assembly of the virus particle, since the fusion protein alone is apparently unable to assemble into particles. Second, the presence of the core protein moiety in the fusion protein probably provides a mechanism for targeting the enzymes to the virus particle. The mechanism of the suppression phenomenon is now under investigation. Recent studies have revealed that suppression in the viral context is dependent upon a complex cis-acting signal in the viral mRNA, including a pseudoknot beginning 9 nucleotides 3' of the termination codon. In addition, studies with viral mutants have shown that UAA and UGA, like UAG, are efficiently suppressed in the presence of this signal, and have identified the amino acids used in the suppression of these termination codons in reticulocyte lysates. In several cases, this analysis revealed the existence of previously unknown suppressor tRNAs. One important question which has not been answered is whether the suppression mechanism used by the virus has a parallel in the synthesis of host proteins.

Interactions of murine leukemia virus core components: characterization of reverse transcriptase packaged in the absence of 70S genomic RNA.

Virions produced by cells in the presence of actinomycin D (Act D virions) contain reverse transcriptase but are deficient in 70S genomic RNA. To assess the role of genomic RNA in encapsidation of a functional reverse transcriptase and to study the interaction of the enzyme and its template in the cores of intact virions, the reverse transcriptase enzymes of normal and Act D virions were compared. The enzymes were indistinguishable by column chromatography, sedimentation velocity, or template/primer preferences. In addition, these enzymes showed equal sensitivity to inactivation by antibodies directed against Rauscher murine leukemia virus DNA polymerase. The enzymes from Act D and normal virions had similar thermal decay rates and were both protected against heat denaturation by natural and synthetic template/primers. By these criteria, the DNA polymerase molecules synthesized and assembled into virions in the absence of genomic RNA are identical to those packaged under normal conditions. Additional studies designed to measure protection of reverse transcriptase by genomic RNA were carried out by comparing the thermal lability of the enzyme in intact Act D and normal virions. The thermal decay rate of reverse transcriptase in Act D virions was identical to that in control virions. In contrast to the lability of the virion-associated enzyme, however, genomic RNA in control virions was stable to heat treatment.

Analysis of arbovirus ribonucleic acid forms by polyacrylamide gel electrophoresis.

Viral ribonucleic acid (RNA) from Semliki Forest virus- and Sindbis virus-infected cells was analyzed by electrophoresis on polyacrylamide gels. In contrast to earlier results obtained by sucrose density gradient centrifugation, all of the known viral RNA forms (i.e., the 42S, 26S, replicative form, and replicative intermediate) were very clearly separated. The high resolution of the electrophoretic method permitted the identification of two new single-stranded RNA species. In addition, the replicative form was shown to be heterogeneous and to consist of at least two forms. The results suggested that the replicative forms occur in vivo although in relatively small amounts.

Metabolism of viral RNA in murine leukemia virus-infected cells; evidence for differential stability of viral message and virion precursor RNA.

Molecular hybridization techniques were used to examine the stability of viral message and virion precursor RNA in murine leukemia virus-infected cells treated with actinomycin D. Under the conditions used, viral RNA synthesis was inhibited, but viral protein synthesis continued, and the cells produced noninfectious particles (actinomycin D virions) lacking genomic RNA (J. G. Levin and M. J. Rosenak, Proc. Natl. Acad. Sci. U.S.A. 73:1154-1158, 1976). Analysis of total RNA in virions revealed that the amount of hybridizable viral RNA decreased steadily after the addition of actinomycin D and by 8 h was 10% of the control value. Studies on fractionated viral RNA showed that this low level of hybridization is due to residual 70S RNA in the virion population. The results indicated that viral RNA which is destined to be encapsidated into virions has a half-life of approximately 3 to 4 h. In contrast, other intracellular virus-specific RNA molecules appeared to be quite stable and persisted for a long period of time, with a half-life of at least 12 h. These observations support the idea that two independent functional pools of 35S viral RNA exist within the infected cell: one serving as message and the other as precursor to virion RNA. The existence of two viral RNA pools was further documented by the finding that 12 h after the addition of actinomycin D, when virion precursor RNA was depleted, 35S and 21S viral nRNA species could be identified in polyribosomal RNA as well as in total polyadenylated cell RNA. Surprisingly, 35S and mRNA declined more rapidly than did 21S mRNA, which appeared to be increased in amount.

Host effect on arbovirus replication: appearance of defective interfering particles in murine cells.

Serial passage of Semliki Forest virus (SFV) in chicken embryo cells had little effect on SFV yield; however, high multiplicity infection of murine cells with one of the late passage pools (passage 9 SFV) resulted in a virus yield 10- to 20-fold lower than that obtained with earlier passage virus and 80-fold lower than the corresponding yield in chicken cells. This effect was accompanied by a striking decrease in the levels of 42S and 26S RNA and by increased proportions of a small single-stranded viral RNA (molecular weight, 9 x 10(5)) and of a low-molecular-weight replicative form. There was also a reduction in the number of specific membranous structures previously associated with the group A arbovirus replication complex. These results suggested that passage 9 SFV contained defective interfering particles which were detected more readily after one passage in a murine indicator host cell. Identical results were obtained with two different murine cell lines: one a leukemia virus-free clone of AKR cells and the other JLS-V9 cells chronically infected with Rauscher leukemia virus. Host production of RNA tumor virus particles apparently did not affect arbovirus replication.

Translational readthrough of the murine leukemia virus gag gene amber codon does not require virus-induced alteration of tRNA.

An in vitro system to assay translational readthrough of the UAG termination codon at the murine leukemia virus (MuLV) gag-pol junction was developed by using rabbit reticulocyte lysates programmed by SP6-generated Moloney MuLV gag-pol mRNA. Under conditions in which the suppressor activity of the lysate was dependent on addition of tRNA, it could be shown that readthrough synthesis was stimulated to approximately the same extent by equivalent amounts of tRNA from MuLV-infected and uninfected NIH 3T3 cells. Analysis of glutamine tRNA, which mediates suppression in vivo, showed that the level of glutamine acceptor activity and the chromatographic profile of glutamine isoacceptors were unchanged following virus infection. On the basis of these results, we conclude that the suppressor tRNA occurs normally within the tRNA population of uninfected cells and need not be induced in response to virus infection.

Human immunodeficiency virus type 1 nucleocapsid protein promotes efficient strand transfer and specific viral DNA synthesis by inhibiting TAR-dependent self-priming from minus-strand strong-stop DNA.

During the first strand transfer in reverse transcription, minus-strand strong-stop DNA [(-) SSDNA] is annealed to the 3' end of the acceptor RNA in a reaction mediated by base-pairing between terminal repeat sequences in the RNA and their complement in the DNA. The large stem-loop structure in the repeat region known as TAR could interfere with this annealing reaction. We have developed an in vitro human immunodeficiency virus type 1 (HIV-1) system to investigate the effect of TAR on strand transfer. Mutational analysis demonstrates that the presence of TAR in the donor and acceptor templates inhibits strand transfer and is correlated with extensive synthesis of heterogeneous DNAs formed by self-priming from (-) SSDNA. These DNAs are not precursors to the transfer product. Interestingly, products of self-priming are not detected in HIV-1 endogenous reactions; this suggests that virions contain a component which prevents self-priming. Our results show that the viral nucleocapsid protein (NC), which can destabilize secondary structures, drastically reduces self-priming and dramatically increases the efficiency of strand transfer. In addition, the data suggest that the ability to eliminate self-priming is a general property of NC which is manifested during reverse transcriptase pausing at sites of secondary structure in the template. We conclude that this activity of NC is critical for achieving highly efficient and specific viral DNA synthesis. Our findings raise the possibility that inactivation of NC could provide a new approach for targeting reverse transcription in anti-HIV therapy.

Mutating a conserved motif of the HIV-1 reverse transcriptase palm subdomain alters primer utilization.

In order to investigate how primer grip residues of human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) contribute toward the architecture of its palm subdomain and neighboring structural elements, the DNA polymerase and ribonuclease H (RNase H) activities of enzymes bearing aromatic substitutions at Trp229 and Tyr232 of the catalytically-competent p66 subunit were evaluated. Although all mutants retained RNase H function, the manner in which different RNA-DNA hybrids were hydrolyzed was affected. Depending on the nature of the substitution, DNA-dependent DNA synthesis was (i) unaffected, (ii) interrupted shortly after initiation, or (iii) stalled when the replication machinery encountered an intramolecular duplex on the single-stranded template. Evaluating (-) strand strong-stop DNA synthesis on an RNA template derived from the viral genome raises the additional possibility that DNA and RNA primers might be differentially recognized by the retroviral polymerase. In support of this, all mutants were unable to extend the HIV-1 polypurine tract (PPT) RNA primer into (+) strand DNA, despite supporting the equivalent event from an oligodeoxynucleotide primer. Collectively, our data illustrate that subtle alterations to primer grip architecture may manifest themselves in discrimination between oligoribo- and oligodeoxyribonucleic acid primers.

Murine leukemia virus mutant with a frameshift in the reverse transcriptase coding region: implications for pol gene structure.

The molecular defect in the nonconditional B-tropic MuLV pol mutant, clone 23 (Gerwin et al., J. Virol. 31:741-751, 1979), has been characterized by recombinant DNA technology. The entire mutant genome was cloned from an EcoRI digest of integrated cellular DNA into bacteriophage lambda Charon 4A and then subcloned at the EcoRI site of pBR322. NIH-3T3 cells transfected with the plasmid clone, termed pRTM (RTM, reverse transcriptase mutant), reproduced the properties of clone 23 virus-infected cells. In vivo ligation experiments involving cotransfection of subclones of pRTM and wild-type murine leukemia virus localized the defect in the clone 23 genome to an approximately 400-base-pair region in the pol gene between the SalI and XhoI sites. Sequence analysis of this region in the wild-type and mutant genomes revealed that the mutant has one additional C residue located 231 bases downstream of the last base of the SalI recognition site. This 1-base insertion brings three TGA termination codons into phase. Thus, the mutation in clone 23 leads to premature termination of translation, explaining the presence in clone 23 virions of a truncated polymerase with low levels of enzymatic activity. It was previously shown that the gag precursor is cleaved normally in clone 23-infected cells; therefore, if a virus-coded protease is involved in this cleavage, it must be encoded by sequences upstream of the reverse transcriptase region of the pol gene. This consideration, coupled with the observed molecular weight of the mutant polymerase and our precise determination of its C terminus, have led to a proposal for the genetic organization of the murine leukemia virus pol gene.

Identification of amino acids inserted during suppression of UAA and UGA termination codons at the gag-pol junction of Moloney murine leukemia virus.

Expression of the murine leukemia virus pol gene occurs by translational readthrough of an in-frame UAG codon between the gag and pol coding regions. In a previous study, we mutated the UAG codon to UAA or UGA and demonstrated that both of these termination codons could be suppressed in reticulocyte lysates and in infected cells with the same efficiency as UAG. We now report the identity of the amino acids inserted in vitro in response to UAA and UGA in fusion products containing the gag-pol junction region. The results show that UAA, like UAG, directs the incorporation of glutamine, whereas UGA directs the incorporation of three amino acids, arginine, cysteine, and tryptophan. To our knowledge, this is the first report indicating misreading of UAA as glutamine and UGA as arginine and cysteine in higher eukaryotes. Interestingly, although our protein synthesis system presumably contains other known UAG and UGA suppressors, these tRNAs did not suppress the termination codons in our experiments. Thus, it seems possible that the sequence surrounding the gag-pol junction not only promotes suppression but also helps determine which tRNAs function in suppression.

A large deletion in the connection subdomain of murine leukemia virus reverse transcriptase or replacement of the RNase H domain with Escherichia coli RNase H results in altered polymerase and RNase H activities.

The functional relationship between the polymerase and RNase H domains of reverse transcriptase (RT) was investigated by studying the activities of AKR murine leukemia virus (MuLV) enzymes. In addition to the wild type, an RNase H-minus RT missing the entire RNase H domain and two other mutants having abnormal polymerase:RNase H ratios were expressed. These mutants include (i) a chimeric protein in which the MuLV RNase H domain was replaced by the entire Escherichia coli RNase H sequence and (ii) an RT with a 126 amino acid deletion in a region analogous to the "connection" subdomain in the p66 subunit of human immunodeficiency virus type 1 RT (Kohlstaedt, L. A., Wang, J., Friedman, J. M., Rice, P. A., & Steitz, T. A. (1992) Science 256, 1783-1790). With the wild-type RT, the major RNase H cleavage reaction was coordinated with DNA synthesis and occurred at a position corresponding to 15 nucleotides from the 3'-terminus of the DNA primer. Additional cleavages closer to the 5'-end of the RNA were explained in terms of a model relating binding of the RNA.DNA hybrid substrate and enzyme structure. The chimeric RT behaved like E. coli RNase H, exhibited 300-fold higher RNase H activity than wild-type RT, and was limited in its ability to synthesize DNA. Qualitative and quantitative changes in the polymerase and RNase H activities of the deletion mutant were also observed. The RNase H domain appeared to function independently of the polymerase domain, supporting the idea that the proper spatial relationship between the two active centers was disrupted by the mutation. Taken together, our results indicate that alteration of the normal polymerase:RNase H ratio can have profound effects on both polymerase and RNase H cleavage activities, as expected for an enzyme with two interdependent domains.