Adenovirus L1 52- and 55-kilodalton proteins are present within assembling virions and colocalize with nuclear structures distinct from replication centers.

Analysis of a temperature-sensitive mutant, Ad5ts369, had indicated that the adenovirus L1 52- and 55-kDa proteins (52/55-kDa proteins) are required for the assembly of infectious virions. By using monoclonal antibodies directed against bacterially produced L1 52-kDa protein, the L1 52/55-kDa proteins were found to be differentially phosphorylated forms of a single 48-kDa polypeptide. Both phosphoforms were shown to be present within all suspected virus assembly intermediates (empty capsids, 50 to 100 molecules; young virions, 1 to 2 molecules) but not within mature virions. The mobilities of these proteins in polyacrylamide gels were affected by reducing agents, indicating that the 52/55-kDa proteins may exist as homodimers within the cell and within assembling particles. Immunofluorescence analysis revealed that the 52/55-kDa proteins localize to regions within the infected nucleus that are distinct from viral DNA replication centers, indicating that replication and assembly of viral components likely occur in separate nuclear compartments. Immunoelectron microscopic studies determined that the 52/55-kDa proteins are found in close association with structures that appear to contain assembling virions. These results are consistent with an active but transient role for the L1 products in assembly of the adenovirus particle, perhaps as scaffolding proteins.     

Temperature-sensitive mutant of adenovirus type 2 blocked in virion assembly: accumulation of light intermediate particles.

A temperature-sensitive mutant of human adenovirus type 2, ts112, was isolated and characterized, ts112 was blocked in a late function required for virus maturation. At restrictive temperature, it accumulated light precursor particles that were able to mature into infectious virions upon temperature shift-down. Use of a mild extraction procedure and a reversible fixation by a cleavable diimido ester permitted the isolation and analysis of these labile intermediates in the adenovirus assembly. These accumulated particles had a sedimentation coefficient of about 600S and a buoyant density of 1.315 g/cm3 in CsCl. They contained a DNA fragment of 7--11S and two nonvirion proteins having molecular weights of 50,000 (50K) and 39.000 (39K), respectively. They resembled in composition and morphology the light intermediate particles found in wild-type adenovirus 2, which were identified as precursors of heavy intermediates, preceding the young virions. The ts112 lesion was apparently located at the exit of either the 50K and/or 39K proteins and at the entry of viral DNA.     

The Adenovirus L4-22K Protein Is Multifunctional and Is an Integral Component of Crucial Aspects of Infection

A variety of cellular and viral processes are coordinately regulated during adenovirus (Ad) infection to achieve optimal virus production. The Ad late gene product L4-22K has been associated with disparate activities during infection, including the regulation of late gene expression, viral DNA packaging, and infectious virus production. We generated and characterized two L4-22K mutant viruses to further explore L4-22K functions during viral infection. Our results show that L4-22K is indeed important for temporal control of viral gene expression not only because it activates late gene expression but also because it suppresses early gene expression. We also show that the L4-22K protein binds to viral packaging sequences in vivo and is essential to recruit two other packaging proteins, IVa2 and L1-52/55K, to this region. The elimination of L4-22K gave rise to the production of only empty virus capsids and not mature virions, which confirms that the L4-22K protein is required for Ad genome packaging. Finally, L4-22K contributes to adenovirus-induced cell death by regulating the expression of the adenovirus death protein. Thus, the adenovirus L4-22K protein is multifunctional and an integral component of crucial aspects of infection.     

Biosynthesis and properties of the adenovirus 2 L1-encoded 52,000- and 55,000-Mr proteins

The adenovirus type 2 L1 region, which is located at 30.7 to 39.2 map units on the viral genome, is transcribed from the major late promoter during both early and late stages of virus replication, and a 52,000-Mr (52K) protein-55K protein doublet has been translated in vitro on L1-specific RNA. To investigate the biosynthesis and properties of the L1 52K and 55K proteins, we prepared antibody against a synthetic peptide encoded near the predicted N terminus. As determined by immunoprecipitation and immunoblot analysis, the antipeptide antibody recognized major 52K and 55K proteins synthesized in adenovirus type 2-infected cells that appeared to be identical to the 52K-55K doublet translated in vitro. The immunoprecipitated 52K and 55K proteins were very closely related, as shown by a peptide map analysis. Both L1 proteins were phosphorylated, and they were phosphorylated at similar sites. No precursor-product relationship was detected between the 52K and 55K proteins by a pulse-chase analysis. Biosynthesis of the L1 52K and 55K proteins began about 6 to 7 h postinfection, after biosynthesis of the early region 1A and early region 1B 19K (175R) T antigens, and reached a maximum rate at about 15 h; the maximum rate was maintained until at least 25 h postinfection. At all times, the 55K protein appeared to be synthesized at a severalfold-higher level than the 52K protein. Both proteins were quite stable and accumulated until late times after infection. Viral DNA replication was not essential for formation of the L1 proteins. Thus, the L1 52K-55K gene appears to be regulated in a manner different from the classical early and late viral genes but similar to the protein encoded by the i-leader (Symington et al., J. Virol. 57:849-856, 1986). The L1 proteins were detected in the cell nucleus by immunofluorescence microscopy with antipeptide antibody and were found to be primarily associated with the nuclear membrane by an immunoblot analysis of subcellular fractions.     

Processing of the L1 52/55k Protein by the Adenovirus Protease: a New Substrate and New Insights into Virion Maturation

Late in adenovirus assembly, the viral protease (AVP) becomes activated and cleaves multiple copies of three capsid and three core proteins. Proteolytic maturation is an absolute requirement to render the viral particle infectious. We show here that the L1 52/55k protein, which is present in empty capsids but not in mature virions and is required for genome packaging, is the seventh substrate for AVP. A new estimate on its copy number indicates that there are about 50 molecules of the L1 52/55k protein in the immature virus particle. Using a quasi-in vivo situation, i.e., the addition of recombinant AVP to mildly disrupted immature virus particles, we show that cleavage of L1 52/55k is DNA dependent, as is the cleavage of the other viral precursor proteins, and occurs at multiple sites, many not conforming to AVP consensus cleavage sites. Proteolytic processing of L1 52/55k disrupts its interactions with other capsid and core proteins, providing a mechanism for its removal during viral maturation. Our results support a model in which the role of L1 52/55k protein during assembly consists in tethering the viral core to the icosahedral shell and in which maturation proceeds simultaneously with packaging, before the viral particle is sealed.     

The adenovirus L4 100-kilodalton protein is necessary for efficient translation of viral late mRNA species.

When screening a number of adenovirus type 5 (Ad5) temperature-sensitive mutants for defects in viral gene expression, we observed that H5ts1-infected 293 cells accumulated reduced levels of newly synthesized viral late proteins. Pulse-labeling and pulse-chase experiments were used to establish that the late proteins synthesized in H5ts1-infected cells under nonpermissive conditions were as stable as those made in Ad5-infected cells. H5ts1-infected cells contained normal levels of viral late mRNAs. Because these observations implied that translation of viral mRNA species was defective in mutant virus-infected cells, the association of viral late mRNAs with polyribosomes was examined during the late phase of infection at a nonpermissive temperature. In Ad5-infected cells, the majority of the viral L2, L3, L4, pIX, and IVa2 late mRNA species were polyribosome bound. By contrast, these same mRNA species were recovered from H5ts1-infected cells in fractions nearer the top of polyribosome gradients, suggesting that initiation of translation was impaired. During the late phase of infection, neither the polyribosome association nor the translation of most viral early mRNA species was affected by the H5ts1 mutation. This lesion, mapped by marker rescue to the L4 100-kilodalton (kDa) nonstructural protein, has been identified as a single base pair substitution that replaces Ser-466 of the Ad5 100-kDa protein with Pro. A set of temperature-independent revertants of H5ts1 was isolated and characterized. Either true reversion of the H5ts1 mutation or second-site mutation of Pro-466 of the H5ts1 100-kDa protein to Thre, Leu, or His restored both temperature-independent growth and the efficient synthesis of viral late proteins. We therefore conclude that the Ad5 L4 100-kDa protein is necessary for efficient initiation of translation of viral late mRNA species during the late phase of infection.     

Adenovirus core protein synthesis in the absence of viral DNA synthesis late in infection.

The acid extraction of the adenovirus type 5 core proteins V, VII, and pVII (the precursor to VII) from infected cells and the subsequent electrophoresis on a 15% acrylamide-2.5 M urea-0.9 N acetic acid (pH 2.7) gel, revealed that peptide VII has a similar electrophoretic mobility to that of histone H1. The core proteins, which are coded by late adenovirus mRNA, continued to be synthesized late in infection when viral DNA synthesis was inhibited either by cytosine arabinoside in wild-type infections or by shifting adenovirus H5 ts 125-infected cells to the nonpermissive temperature (40 degree C). Only the initiation, not the continuation, of viral DNA replication was essential for core protein synthesis. The synthesis of viral core proteins continued for over 8 h after the cassation of DNA synthesis. This was in contrast to the rapid shutdown of cellular histone synthesis in the absence of cellular DNA synthesis.     

Isolation and characterization of temperature-sensitive mutants of adenovirus type2.

Fourteen temperature-sensitive mutants of human adenovirus type2, which differed in their plaquing efficiencies at at the permissive and nonpermissive temperatures by 4 to 5 orders of magnitude, were isolated. These mutants, which could be assigned to seven complementation groups, were tested for their capacity to synthesize adenovirus DNA at the nonpermissive temperature. Three mutants in three different complementation groups proved deficient in viral DNA synthesis. The DNA-negative mutant H2ts206 complemented the DNA-negative mutants H5ts36 and H5ts125, whereas mutant H2ts201 complemented H5ts36 only. Among the DNA-negative mutants, H2ts206 synthesized the smallest amount of viral DNA at the nonpermissive temperature (39.5 C). Data obtained in temperature shift experiments indicated that a very early function was involved in temperature sensitivity. In keeping with this observation, early virus-specific mRNA was not detected in cells infected with H2ts206 and maintained at 39.5 C. Prolonged (52 h) incubation of cells infected with H2ts206 at the nonpermissive temperature led to the synthesis of a high-molecular-weight form of viral DNA.     

Phenotypic characterization of temperature-sensitive mutants of vaccinia virus with mutations in a 135,000-Mr subunit of the virion-associated DNA-dependent RNA polymerase

The phenotypic defects of three temperature-sensitive (ts) mutants of vaccinia virus, the ts mutations of which were mapped to the gene for one of the high-molecular-weight subunits of the virion-associated DNA-dependent RNA polymerase, were characterized. Because the virion RNA polymerase is required for the initiation of the viral replication cycle, it has been predicted that this type of mutant is defective in viral DNA replication and the synthesis of early viral proteins at the nonpermissive temperature. However, all three mutants synthesized both DNA and early proteins, and two of the three synthesized late proteins as well. RNA synthesis in vitro by permeabilized mutant virions was not more ts than that by the wild type. Furthermore, only one of three RNA polymerase activities that was partially purified from virions assembled at the permissive temperature displayed altered biochemical properties in vitro that could be correlated with its ts mutation: the ts13 activity had reduced specific activity, increased temperature sensitivity, and increased thermolability under a variety of preincubation conditions. Although the partially purified polymerase activity of a second mutant, ts72, was also more thermolabile than the wild-type activity, the thermolability was shown to be the result of a second mutation within the RNA polymerase gene. These results suggest that the defects in these mutants affect the assembly of newly synthesized polymerase subunits into active enzyme or the incorporation of RNA polymerase into maturing virions; once synthesized at the permissive temperature, the mutant polymerases are able to function in the initiation of subsequent rounds of infection at the nonpermissive temperature.     

Role for the L1-52/55K protein in the serotype specificity of adenovirus DNA packaging

The packaging of adenovirus (Ad) DNA into virions is dependent upon cis-acting sequences and trans-acting proteins. We studied the involvement of Ad packaging proteins in the serotype specificity of packaging. Both Ad5 and Ad17 IVa2 and L4-22K proteins complemented the growth of Ad5 IVa2 and L4-22K mutant viruses, respectively. In contrast, the Ad5 L1-52/55K protein complemented an Ad5 L1-52/55K mutant virus, but the Ad17 L1-52/55K protein did not. The analysis of chimeric proteins demonstrated that the N-terminal half of the Ad5 L1-52/55K protein mediated this function. Finally, we demonstrate that the L4-33K and L4-22K proteins have distinct functions during infection.     

Temperature-Sensitive Mutants of Vesicular Stomatitis Virus: Synthesis of Virus-Specific Proteins

Viral proteins synthesized in L cells infected with temperature-sensitive (ts) mutants of vesicular stomatitis (VS) virus at permissive (31 C) and nonpermissive (39 C) temperatures were compared by polyacrylamide gel electrophoresis. Mutant ts 5, deficient in synthesis of viral ribonucleic acid (RNA⁻), failed to synthesize any of the five identifiable viral proteins at 39 C. Each of three RNA⁺ mutants, representing three separate complementation groups, showed distinctive patterns of viral protein synthesis at nonpermissive temperature. Equivalent amounts of ³H-amino acids were incorporated into the five viral proteins made in cells infected with RNA⁺ mutant ts 45 at 31 and 39 C. Complete virions of ts 45 could be identified by electron microscopy of infected cells incubated at the nonpermissive temperature; the defect in ts 45 appeared to be due in part to greater thermolability of virions as compared with the wild-type. RNA⁺ mutant ts 23 was deficient in synthesis of viral envelope protein S and failed to make detectable virions at the nonpermissive temperature. Infection of cells at 39 C with the third RNA⁺ mutant, ts 52, resulted in synthesis of all five viral proteins, but the peak of radioactivity representing the viral membrane glycoprotein migrated more rapidly on gels than coelectrophoresed authentic virion ¹⁴C-glycoprotein or viral ³H-glycoprotein extracted from cells infected at 31 C. These data and results of experiments on incorporation of radioactive glucosamine suggest that the primary defect in mutant ts 52 at nonpermissive temperature is failure of glycosylation of the viral glycoprotein. The viral structural proteins made in cells infected with ts 52 at the nonpermissive temperature did not assemble into sedimentable components as they did at permissive temperature; this observation indicates failure of insertion of the nonglycosylated protein (G′) into cell membrane. In support of this hypothesis was the finding that antiviral-antiferritin hybrid antibody did not detect VS viral antigen on the plasma membrane of L cells infected at 39 C with ts 52. In contrast, VS viral antigen localized in plasma membrane of L cells infected at 39 C with mutants ts 23 and ts 45 was readily detected by electron microscopy and fluorescence microscopy.     

Dependence of the encapsidation function of the adenovirus L1 52/55-kilodalton protein on its ability to bind the packaging sequence

The adenovirus IVa2 and L1 52/55-kDa proteins are involved in the assembly of new virus particles. Both proteins bind to the packaging sequence of the viral chromosome, and the lack of expression of either protein results in no virus progeny: the absence of the L1 52/55-kDa protein leads to formation of only empty capsids, and the absence of the IVa2 protein results in no capsid assembly. Furthermore, the IVa2 and L1 52/55-kDa proteins interact with each other during adenovirus infection. However, what is not yet clear is when and how this interaction occurs during the course of the viral infection. We defined the domains of the L1 52/55-kDa protein required for interaction with the IVa2 protein, DNA binding, and virus replication by constructing L1 52/55-kDa protein truncations. We found that the N-terminal 173 amino acids of the L1 52/55-kDa protein are essential for interaction with the IVa2 protein. However, for both DNA binding and complementation of the pm8001 mutant virus, which does not express the L1 52/55-kDa protein, the amino-terminal 331 amino acids of the L1 52/55-kDa protein are necessary. These results suggest that the production of infectious virus particles depends on the ability of the L1 52/55-kDa protein to bind to DNA.     

Adenovirus structural protein IIIa is involved in the serotype specificity of viral DNA packaging

The packaging of the adenovirus (Ad) genome into a capsid displays serotype specificity. This specificity has been attributed to viral packaging proteins, the IVa2 protein and the L1-52/55K protein. We previously found that the Ad17 L1-52/55K protein was not able to complement the growth of an Ad5 L1-52/55K mutant virus, whereas two other Ad17 packaging proteins, IVa2 and L4-22K, could complement the growth of Ad5 viruses with mutations in the respective genes. In this report, we investigated why the Ad17 L1-52/55K protein was not able to complement the Ad5 L1-52/55K mutant virus. We demonstrate that the Ad17 L1-52/55K protein binds to the Ad5 IVa2 protein in vitro and the Ad5 packaging domain in vivo, activities previously associated with packaging function. The Ad17 L1-52/55K protein also associates with empty Ad5 capsids. Interestingly, we find that the Ad17 L1-52/55K protein is able to complement the growth of an Ad5 L1-52/55K mutant virus in conjunction with the Ad17 structural protein IIIa. The same result was found with the L1-52/55K and IIIa proteins of several other Ad serotypes, including Ad3 and Ad4. The Ad17 IIIa protein associates with empty Ad5 capsids. Consistent with the complementation results, we find that the IIIa protein interacts with the L1-52/55K protein in vitro and associates with the viral packaging domain in vivo. These results underscore the complex nature of virus assembly and genome encapsidation and provide a new model for how the viral genome may tether to the empty capsid during the encapsidation process.     

Vaccinia virus A30L protein is required for association of viral membranes with dense viroplasm to form immature virions

The previously uncharacterized A30L gene of vaccinia virus has orthologs in all vertebrate poxviruses but no recognizable nonpoxvirus homologs or functional motifs. We determined that the A30L gene was regulated by a late promoter and encoded a protein of approximately 9 kDa. Immunoelectron microscopy of infected cells indicated that the A30L protein was associated with viroplasm enclosed by crescent and immature virion membranes. The A30L protein was also present in mature virions and was partially released by treatment with a nonionic detergent and reducing agent, consistent with a location in the matrix between the core and envelope. To determine the role of the A30L protein, we constructed a stringent conditional lethal mutant with an inducible A30L gene. In the absence of inducer, synthesis of viral early and late proteins occurred but the proteolytic processing of certain core proteins was inhibited, suggesting an assembly block. Inhibition of virus maturation was confirmed by electron microscopy. Under nonpermissive conditions, we observed aberrant large, dense, granular masses of viroplasm with clearly defined margins; viral crescent membranes that appeared normal except for their location at a distance from viroplasm; empty immature virions; and an absence of mature virions. The data indicated that the A30L protein is needed for vaccinia virus morphogenesis, specifically the association of the dense viroplasm with viral membranes.