Characterization of a temperature-sensitive fiber mutant of type 5 adenovirus and effect of the mutation on virion assembly

Delineation of interfaces on human alpha-defensins critical for human adenovirus and human papillomavirus inhibition

Human α-defensins are potent anti-microbial peptides with the ability to neutralize bacterial and viral targets. Single alanine mutagenesis has been used to identify determinants of anti-bacterial activity and binding to bacterial proteins such as anthrax lethal factor. Similar analyses of α-defensin interactions with non-enveloped viruses are limited. We used a comprehensive set of human α-defensin 5 (HD5) and human neutrophil peptide 1 (HNP1) alanine scan mutants in a combination of binding and neutralization assays with human adenovirus (AdV) and human papillomavirus (HPV). We have identified a core of critical hydrophobic residues that are common determinants for all of the virus-defensin interactions that were analyzed, while specificity in viral recognition is conferred by specific surface-exposed charged residues. The hydrophobic residues serve multiple roles in maintaining the tertiary and quaternary structure of the defensins as well as forming an interface for virus binding. Many of the important solvent-exposed residues of HD5 group together to form a critical surface. However, a single discrete binding face was not identified for HNP1. In lieu of whole AdV, we used a recombinant capsid subunit comprised of penton base and fiber in quantitative binding studies and determined that the anti-viral potency of HD5 was a function of stoichiometry rather than affinity. Our studies support a mechanism in which α-defensins depend on hydrophobic and charge-charge interactions to bind at high copy number to these non-enveloped viruses to neutralize infection and provide insight into properties that guide α-defensin anti-viral activity.

Human α-defensins are an important component of the innate immune response and provide an initial block against a broad number of infectious agents, including viruses and bacteria. Characteristics of α-defensins that are necessary for their anti-bacterial activity have been identified, but our understanding of determinants required for activity against non-enveloped viruses is limited. In this work, we utilized alanine scan mutagenesis to systematically and comprehensively investigate the role of hydrophobic and charged residues of two α-defensins in binding to and/or neutralization of human adenovirus and human papillomavirus. Our results implicate common core hydrophobic residues as critical for inhibition of these non-enveloped viruses by the two α-defensins, with specificity provided by charged residues unique to each interaction. We also found that the number of α-defensin molecules bound to the virus was a stronger correlate of the anti-viral potency of the α-defensin mutants than their absolute affinity for the viral capsid. Understanding common characteristics of α-defensins important for non-enveloped virus binding will inform rules that govern the function of these abundant and multifaceted peptides in host defense.

In vitro dynamic visualization analysis of fluorescently labeled minor capsid protein IX and core protein V by simultaneous detection

Oncolytic adenoviruses represent a promising therapeutic medicine for human cancer therapy, but successful translation into human clinical trials requires careful evaluation of their viral characteristics. While the function of adenovirus proteins has been analyzed in detail, the dynamics of adenovirus infection remain largely unknown due to technological constraints that prevent adequate tracking of adenovirus particles after infection. Fluorescence labeling of adenoviral particles is one new strategy designed to directly analyze the dynamic processes of viral infection in virus-host cell interactions. We hypothesized that the double labeling of an adenovirus with fluorescent proteins would allow us to properly analyze intracellular viruses and the fate of viral proteins in a live analysis of an adenovirus as compared to single labeling. Thus, we generated a fluorescently labeled adenovirus with both a red fluorescent minor capsid protein IX (pIX) [pIX monomeric red fluorescent protein 1 (mRFP1)] and a green fluorescent minor core protein V (pV) [pV enhanced green fluorescent protein (EGFP)], resulting in Ad5-IX-mRFP1-E3-V-EGFP. The fluorescent signals for pIX-mRFP1 and pV-EGFP were detected within 10 min in living cells. However, a growth curve analysis of Ad5-IX-mRFP1-E3-V-EGFP showed an approximately 150-fold reduced production of the viral progeny at 48 h postinfection as compared to adenovirus type 5. Interestingly, pIX-mRFP1 and pV-EGFP were initially localized in the cytoplasm and nucleolus, respectively, at 18 h postinfection. These proteins were observed in the nucleus during the late stage of infection, and relocalization of the proteins was observed in an adenoviral-replication-dependent manner. These results indicate that simultaneous detection of adenoviruses using dual-fluorescent proteins is suitable for real-time analysis, including identification of infected cells and monitoring of viral spread, which will be required for a complete evaluation of oncolytic adenoviruses.

Characterization of the Adenovirus Fiber Protein

Entry of the adenovirus (Ad) capsids during the early stages of infection is a multistep process that includes initial attachment of the virus capsid to the cell surface followed by internalization of the virus into early endosomes. The Ad fiber protein, a complex of three apparently identical subunits, mediates the initial attachment step. In this chapter, methods for the purification and characterization of the Ad fiber protein are presented. Chromatographic methods for the isolation of the protein from infected cells can yield substantial quantities of protein for biochemical analysis. Protocols for characterization of the protein by Western blot and by indirect immunofluorescence of infected cells are also presented. The specificity of different monoclonal and polyclonal antibodies that recognize Ad fiber is also discussed. Ad fiber from a number of serotypes also contains a posttranslational modification, O-linked N-acetyl-glucosamine; methods for detection and characterization of this modification are also provided. With these tools and protocols, one can address important questions about this protein, which helps direct the tissue tropism of Ad.

Thermostability/infectivity defect caused by deletion of the core protein V gene in human adenovirus type 5 is rescued by thermo-selectable mutations in the core protein X precursor

Mastadenoviruses represent one of the four major genera of the Adenoviridae family comprising a variety of mammalian pathogens including human adenovirus (Ad), whose genomes encode a gene for minor core protein V (pV), not found in other genera of Adenoviridae. Deletion of other genus-specific genes (gene IX and E3 genes) from the Ad type 5 (Ad5) genome has been studied experimentally in vitro and the results on biological characterization of the mutants support the phylogenetic evidence of those genes being non-essential for Ad viability. On this basis it seemed logical to suggest that a deletion of gene V from the Ad5 genome could also be tolerated. To test this hypothesis we constructed and rescued the first pV-deletion mutant of human Ad5. As compared to Ad5, this mutant formed small plaques, had dramatically reduced thermostability and lower infectivity. A subsequent thermoselection screen of the pV-deleted Ad5 allowed isolation of a suppressor mutant Ad5-dV/TSB with restored biological characteristics. Since replication and viral assembly of Ad5-dV/TSB could still occur in the absence of pV, we conclude that pV is a non-essential component of the virion. The observed rescue of the biological defects appears to be associated with a cluster of point mutations in the gene encoding the precursor for the other core protein, X/Mu. This finding, thus, suggests possible roles of pV and protein X/Mu precursor in viral assembly. It also provides an interesting insight into genetic events that mediate molecular adaptation of viruses to possible changes in the genetic background in the course of their evolutionary divergence. The possible mechanism of the observed genetic suppression is discussed.

Creation and repair of specific DNA double-strand breaks in vivo following infection with adenovirus vectors expressing Saccharomyces cerevisiae HO endonuclease

To study DNA double-strand break (DSB) repair in mammalian cells, the Saccharomyces cerevisiae HO endonuclease gene, or its recognition site, was cloned into the adenovirus E3 or E1 regions. Analysis of DNA from human A549 cells coinfected with the E3::HO gene and site viruses showed that HO endonuclease was active and that broken viral genomes were detectable 12 h postinfection, increasing with time up to approximately 30% of the available HO site genomes. Leftward fragments of approximately 30 kbp, which contain the packaging signal, but not rightward fragments of approximately 6 kbp, were incorporated into virions, suggesting that broken genomes were not held together tightly after cleavage. There was no evidence for DSB repair in E3::HO virus coinfections. In contrast, such evidence was obtained in E1::HO virus coinfections of nonpermissive cells, suggesting that adenovirus proteins expressed in the permissive E3::HO coinfection can inhibit mammalian DSB repair. To test the inhibitory role of E4 proteins, known to suppress genome concatemer formation late in infection (Weiden and Ginsberg, 1994), A549 cells were coinfected with E3::HO viruses lacking the E4 region. The results strongly suggest that the E4 protein(s) inhibits DSB repair.

Adenovirus vector pseudotyping in fiber-expressing cell lines: improved transduction of Epstein-Barr virus-transformed B cells

While adenovirus (Ad) gene delivery vectors are useful in many gene therapy applications, their broad tropism means that they cannot be directed to a specific target cell. There are also a number of cell types involved in human disease which are not transducible with standard Ad vectors, such as Epstein-Barr virus (EBV)-transformed B lymphocytes. Adenovirus binds to host cells via the viral fiber protein, and Ad vectors have previously been retargeted by modifying the fiber gene on the viral chromosome. This requires that the modified fiber be able to bind to the cell in which the vector is grown, which prevents truly specific vector targeting. We previously reported a gene delivery system based on a fiber gene-deleted Ad type 5 (Ad5) vector (Ad5.betagal.DeltaF) and packaging cells that express the viral fiber protein. Expression of different fibers in packaging cells will allow Ad retargeting without modifying the viral chromosome. Importantly, fiber proteins which can no longer bind to the producer cells can also be used. Using this approach, we generated for the first time pseudotyped Ad5.betagal.DeltaF particles containing either the wild-type Ad5 fiber protein or a chimeric fiber with the receptor-binding knob domain of the Ad3 fiber. Particles equipped with the chimeric fiber bound to the Ad3 receptor rather than the coxsackievirus-adenovirus receptor protein used by Ad5. EBV-transformed B lymphocytes were infected efficiently by the Ad3-pseudotyped particles but poorly by virus containing the Ad5 fiber protein. The strategy described here represents a broadly applicable method for targeting gene delivery to specific cell types.

A helper-independent adenovirus vector with E1, E3, and fiber deleted: structure and infectivity of fiberless particles

The adenovirus (Ad) fiber protein largely determines viral tropism through interaction with specific cell surface receptors. This molecule may also be involved in virion assembly or maturation, as some previously characterized fiber mutants were defective for processing of viral structural proteins. We previously described packaging cell lines that express Ad type 5 (Ad5) fiber and can complement the temperature-sensitive Ad fiber mutant H5ts142. We have now used these packaging cells to construct a new adenoviral vector (Ad5.betagal.DeltaF) with E1, E3, and L5 (fiber) deleted and analyzed the fiber null phenotype. Ad5.betagal.DeltaF growth was completely helper independent, and fiberless particles were produced by a single final round of growth in 293 cells. Cryoelectron microscopic studies and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed that the structure and composition of these particles was nearly identical to those of first-generation Ad vectors. As expected, fiberless particles had reduced infectivity on epithelial cells, but they retained the ability to infect monocytic cells via an integrin-dependent pathway. These studies provide a novel approach to developing retargeted Ad gene therapy vectors.

Effect of CD4 gene expression on adenovirus replication

The gene encoding the CD4 receptor was introduced into KB cells to establish the KBT4 cell line, a cell line susceptible to infection with human immunodeficiency virus type 1. Adenovirus replication was found to be significantly less in these cells than in the parental KB cells. Similar decreased adenovirus type 5 (Ad5) replication occurred in HeLaT4 cells compared with the original HeLa cells. The presence of CD4 did not alter the cell surface population of KB cell adenovirus receptors, since viral adsorption was similar in the two cell lines. Moreover, addition of soluble CD4 did not reduce viral replication in either KB or KBT4 infected cells. Uncoating of viral DNA was also unchanged in KBT4 cells compared with the parental KB cells. In contrast, migration to or entrance of viral DNA into nuclei and synthesis of early viral RNAs was delayed and reduced in KBT4 cells. These effects were more pronounced for Ad7 than for Ad5. The yields of infectious viruses were the same in both cell lines, however, after transfection of naked viral DNAs to initiate infection. These results imply that the expression of the CD4 gene in KBT4 cells interfered with passage of uncoated virus across endosomal vesicles and/or transfer of uncoated core viral DNA into the nucleus.

Characterization of the structural proteins of hemorrhagic enteritis virus

The structural proteins of hemorrhagic enteritis (HEV), a turkey adenovirus, were analyzed by polyacrylamide gel electrophoresis (PAGE) and Western blotting using polyspecific, monospecific and monoclonal antibodies for detection. In purified HEV preparations, eleven polypeptides with apparent molecular weights ranging from 96,000 to 9,500 (96k to 9.5k), were specifically recognized by convalescent turkey serum. Six of these polypeptides were further characterized by PAGE, Western blotting, ELISA, sucrose gradient centrifugation and electron microscopy. The 96k polypeptide was identified as the hexon polypeptide which is a monomer of the major outer capsid or hexon protein. The 51/52k and 29k polypeptides, identified as the penton base and fiber polypeptides respectively, were the components of the vertex or penton protein. The 57k polypeptide was identified as a homologue of the human adenovirus type 2 (Ad 2) IIIa protein with which it shares a common epitope. Two core proteins with molecular weights of 12.5 and 9.5k were present in purified HEV nucleoprotein cores. The proteins of two HEV isolates, one apathogenic (HEV-A) and one virulent (HEV-V), resembled each other in most respects. However, differences between HEV-A and HEV-V were found in electrophoretic migration of the penton base protein both under native and denatured conditions, and in the electrophoretic migration of the 43/44k polypeptide. Moreover, homologous antiserum against the fiber protein reacted stronger than heterologous antiserum in an ELISA. Single fibers were detected by electron microscopy attached to the penton base proteins of HEV virions and in isolated pentons. The feature of having single fibers is shared with the mammalian adenoviruses and the avian egg drop syndrome 1976 virus (EDS 76 V), but not with the fowl adenoviruses which have double fibers attached to their penton base proteins.

cis and trans requirements for the selective packaging of adenovirus type 5 DNA

Polar packaging of adenovirus DNA into virions is dependent on the presence of cis-acting sequences at the left end of the viral genome. Our previous analyses demonstrated that the adenovirus type 5 (Ad5) packaging domain (nucleotides 194 to 358) is composed of at least five elements that are functionally redundant. A repeated sequence, termed the A repeat, was associated with packaging function. Here we report a more detailed analysis of the requirements for the selective packaging of Ad5 DNA. By introducing site-directed point mutations into specific A repeat sequences, we demonstrate that the A repeats represent cis-acting functional components of the packaging signal. Additional elements, located outside the originally defined packaging domain boundaries and that resemble the A repeat consensus sequence, also are capable of promoting the packaging of viral DNA. The cis-acting components of the packaging signal appear to be subject to certain spatial constraints for function, possibly reflecting a necessity for the coordinate binding of packaging proteins to these sites. In agreement with this idea, we present evidence that the interaction of a limiting trans-acting factor(s) with the packaging domain in vivo is required for efficient encapsidation of the Ad5 genome.

The amino terminus of the adenovirus fiber protein encodes the nuclear localization signal

Using a recombinant vaccinia virus vector, the fiber protein from adenovirus serotype 2 has been expressed in human cells; the protein expressed was correctly assembled into trimers, glycosylated, and transported to the nucleus. Deletion of amino acids 2-5 (KRAR) resulted in accumulation of fiber in the cytoplasm; fusion of the sequence TKRVRL, found at the beginning of Ad7 fiber, to the N-terminus of this mutant restored correct targeting. Changing the charge of amino acids 91 and 92 within another potential targeting sequence (LKKTK to LEETK) had little effect on nuclear targeting. When fused to the N-terminus of beta-galactosidase and expressed in recombinant vaccinia virus, neither MKRARP nor MTKRVRL (from Ad2 and Ad7 fibers, respectively), were sufficient for efficient transport of the hybrid protein to the nucleus; on the other hand, fusions of either MKRARPSEDTF (from Ad2 fiber) or of MKRPRP (a known targeting sequence from the C-terminus of Ad2 E1A proteins) to beta-galactosidase were localized to the nucleus. These results suggest that sequences at the N-terminus of Ad2 and Ad7 fiber are required for correct nuclear targeting.

Deletion analysis of functional domains in baculovirus-expressed adenovirus type 2 fiber

Various forms of Ad2 fiber were expressed in insect cells using recombinant baculoviruses and phenotypically characterized with respect to the following properties: trimerization, binding to penton base, nuclear targeting, and glycosylation. The morphology and dimensions of full-length fiber produced by invertebrate cells were indistinguishable from those observed in extracts from lytically infected mammalian cells. The domain required for trimer formation was mapped to the C-terminus, between amino acids 541 and 582. The N-terminal domain, between amino acids 1 and 16, negatively influenced the trimerization efficiency. Fiber gene products reduced to the shaft portion of the fiber capsomer formed significant amounts of stable dimers. Recognition with penton base only occurred with trimeric forms of fiber and was apparently not affected by deletion of the first 60 amino acids from the N-terminus. Fiber deleted of the Met1-Gly60 sequence was found to localize within the nucleus at levels similar to those of full-length fiber. All recombinant fibers, including tail-and-know-deleted forms, were found to be glycosylated using three separate assays, (i) in vivo labeling with [3H]glucosamine, (ii) binding to WGA, and (iii) reaction with monoclonal antibody RL2 directed against O-GlcNAc-containing glycopeptide. This implied that Ad2 fiber is a substrate for GlcNAc O-seryl transferase in insect cell cytoplasm and that at least one major glycosylation site is located in the shaft domain, between Met61 and Asn410.

Functional and structural effects of an Ala to Val mutation in the adenovirus serotype 2 fibre

H2ts125 is a fibre-defective, temperature-sensitive mutant of adenovirus serotype 2. H2ts125 fibre is unstable at the non-permissive temperature (ts phenotype), and does not migrate in the same way as the wild-type fibre in an SDS/polyacrylamide gel (elm phenotype). Sequence analysis has shown that H2ts125 carries two mutations on the fibre gene: Leu105 to Phe, and Ala434 to Val. Analysis of the structural modifications occurring in H2ts125 fibre was performed using peptide finger-printing and antipeptide sera as immunological probes. We found that all the detectable structural alterations in the mutant fibre were due to the substitution on codon 434. In addition, the ts phenotype was rescued by a wild-type DNA fragment containing the 3' moiety of the fibre gene and overlapping the 434th codon. Morphological analysis of fibre molecules observed under the electron microscope showed minor but statistically significant differences in the fibre length between mutant and wild-type. The mutant fibre was found to be slightly longer (308.8 +/- 1.9 A) than the wild-type fibre (300.1 +/- 2.1 A). Thus both ts and elm phenotypes were carried by the same Ala434 to Val mutation which probably resulted from a change in the three-dimensional structure of the fibre protein, and not from some proteolytic cleavage.

Relative accessibility of N-acetylglucosamine in trimers of the adenovirus types 2 and 5 fiber proteins

Fiber is an adenovirus capsid protein responsible for virus attachment to the cell surface and contains O-linked N-acetylglucosamine (GlcNAc). Results of both amino acid analysis and Dionex chromatography indicated that 3 to 4 and 1.7 to 2.5 mol of GlcNAc are attached per mol of affinity-purified adenovirus type 2 (Ad2) and Ad5 fibers, respectively. Fiber shares an epitope with nuclear pore proteins containing O-linked GlcNAc, as shown by reactivity to monoclonal antibody RL2 directed against these pore proteins. GlcNAc on fiber was found to serve as an acceptor for the transfer of galactose from UDP-galactose by 4 beta-galactosyl-transferase in Ad2 and Ad5 but not in Ad7; quantitation by labeling with UDP-[U-14C]galactose in this reaction gave a 100-fold-lower estimate of the GlcNAc content of fiber, suggesting that these monosaccharides are buried within fiber trimers and are not accessible to the transferase. Affinity chromatography on lectin-bound Sepharose beads showed that Ad2 and Ad5 fibers bound weakly to wheat germ agglutinin and did not bind to ricin or concanavalin A; weak binding to wheat germ agglutinin suggests either that GlcNAc is not easily accessible or that there are not sufficient GlcNAcs for efficient binding. These data suggest that O-linked GlcNAc might be important for Ad2 and Ad5 fiber assembly or stabilization.

Role of early genes in pathogenesis of adenovirus pneumonia

Intranasal inoculation of type 5 adenovirus into the cotton rat Sigmodon hispidus produces a pneumonia pathologically similar to that in humans, and it, therefore, provides an excellent animal model to investigate the pathogenesis of this disease. The goal of this study was to test the hypothesis that accumulation of viral structural proteins is responsible for a major portion of the cell-damage-producing disease. Since viral DNA replication is essential for synthesis of the viral structural proteins, which are products of late genes, the hypothesis was tested using mutants defective in genes required for DNA synthesis. Most experiments were done with the conditionally lethal temperature-sensitive (ts) mutant H5ts125, which contains a mutation in the early region 2A (E2A) gene encoding the DNA-binding protein. The data show that infection with 1 x 10(9.0) plaque-forming units of H5ts125 induced a pneumonia that was as extensive and qualitatively the same as that after wild-type adenovirus type 5 infection, although H5ts125 did not replicate to produce infectious virus. When cotton rats were infected with 1 x 10(8.0) plaque-forming units of wild-type adenovirus type 5 or H5ts125, the pneumonias that followed were pathologically similar; in the latter phases, however, wild-type virus produced slightly more extensive pneumonia than did H5ts125, probably because its replication permitted infection of more susceptible cells.

Adenovirus type 5 packaging domain is composed of a repeated element that is functionally redundant

Previous analyses have demonstrated that adenovirus DNA is packaged into virions in vivo in a polar, left-to-right fashion. The packaging of viral DNA is dependent on cis-acting elements at the left end of the genome. In this report, we describe a genetic analysis of the sequences that are required for efficient packaging of adenovirus type 5 (Ad5) DNA. Our results demonstrate that the Ad5 packaging domain (nucleotides 194 to 358) is composed of at least five distinct elements that are functionally redundant. An AT-rich repeated sequence motif, the A repeat, is located in four of five of these regions; the fifth region is also AT rich. The efficiency of viral packaging depends on the number of individual A repeats that are present in the viral genome. The deletion of the entire packaging domain resulted in the loss of virus viability. A virus that contains a multimerized oligonucleotide corresponding to A repeat II in place of the packaging domain could package viral DNA, although with reduced efficiency compared with that of the wild-type virus. Our results also suggest that the spacing of specific sequences at the left end of the Ad5 genome are important for enhancer region function in vivo.

Synthesis of human adenovirus type 2 fiber protein in Escherichia coli cells

We have cloned and expressed in Escherichia coli the gene encoding the trimeric fiber protein of human adenovirus type 2. A gene expression system based on bacteriophage T7 RNA polymerase was used. Optimal gene expression was obtained with 1-h induction, at a temperature of 30 degrees C. The synthesized protein constituted about 1% of total host-cell protein. During induction, the growth of bacteria carrying the plasmid containing the fiber gene, was retarded compared with that of bacteria carrying the plasmid without the fiber gene. This toxic effect of fiber protein on bacterial hosts could be diminished by addition of glucose to the medium and by maintaining the pH above 7, thus improving the yield of recombinant fiber protein. The fiber protein produced in E. coli is stable during the course of induction. It is insoluble in buffers at physiological pH, in various salt solutions, and in the presence of nonionic detergents. It can be solubilized in 1% sodium dodecyl sulfate or in urea solutions above 2 M. There are indications that recombinant fiber trimerizes spontaneously, since after the removal of urea by dialysis at pH 8, recombinant fibers runs similarly to native trimeric fiber, on nondenaturing polyacrylamide gels. This trimer has, however, a less compact structure than native Ad2 fiber, since during gel filtration recombinant protein is excluded before native protein. It is also more sensitive to chymotrypsin digestion than native fiber.

O-linked GlcNAc in serotype-2 adenovirus fibre

Serotype-2 adenovirus fibre is shown to possess an O-linked GlcNAc residue and to have affinity for wheat germ agglutinin. The cytoplasmic and nuclear fibres are both glycosylated. Glycosylation seems to take place in the cytoplasm since most of the [14C]GlcN-labelled fibre is found in this compartment, little label being associated with the microsomes. Glycosylation of the fibre was not affected by inhibitors of N- and O-glycosylation. A variation in fibre glycosylation is observed among adenovirus. Among the serotypes tested, only serotype-5 adenovirus (another subgroup C virus) also incorporated [14C]GlcN into its fibre, but did not possess affinity for wheat-germ agglutinin. The GlcNAc is located in the N-terminal two-thirds of the fibre and more probably in the N-terminal one-third. The free or penton-base-associated fibres are similarly glycosylated. These results suggest that glycosylation is not involved in viral adsorption and in assembly with the capsid penton base. Thus, glycosylation might be a characteristic feature of subgroup C viruses.

Adenovirus L1 52- and 55-kilodalton proteins are required for assembly of virions

A variant of adenovirus type 5 that contained a mutation within the L1 52- and 55-kilodalton (52/55K) protein-coding region was isolated. The mutant, termed ts369, produced L1 52/55K proteins with a two-amino-acid substitution and was temperature sensitive. Temperature-shift experiments indicated that the ts369 defect was late in the viral growth cycle. DNA replication and synthesis of late proteins occurred normally in ts369-infected cells at the nonpermissive temperature, but mature virions were not produced. Rather, capsidlike particles associated with the left-terminal region of the viral chromosome accumulated. These incomplete particles could not be chased into mature virions when the infected cells were shifted to the permissive temperature. However, previously synthesized proteins could be assembled into virions in the presence of a protein synthesis inhibitor upon shiftdown from the nonpermissive temperature, suggesting that the inactivation of the L1 52/55K proteins was reversible. These results indicate that the adenovirus L1 52/55K proteins play a role in the assembly of infectious virus particles.

Characterization of group II avian adenoviruses with a panel of monoclonal antibodies

The interaction between a panel of ten monoclonal antibodies and hemorrhagic enteritis virus, a group II avian adenovirus, was determined. The monoclonal antibodies reacted with all nine isolates of group II avian adenoviruses, but not with any of five types of group I avian adenoviruses. All ten monoclonal antibodies recognized antigenic determinants on the hexon protein of hemorrhagic enteritis virus when analyzed by immunoprecipitation and immunoblotting. They reacted only with the native hexon protein and not with protein denatured by sodium dodecyl sulfate or guanidine-HCl/urea treatment combined with reduction and carboxymethylation. Based on the results of competitive binding assays, the panel of monoclonal antibodies could be subdivided into two groups, which recognized different antigenic domains of the hemorrhagic enteritis virus hexon protein. The monoclonal antibodies in group 1 neutralized hemorrhagic enteritis virus infectivity while the monoclonal antibodies of group 2 did not. Group 1 consisted of eight monoclonal antibodies which could be further subdivided into subgroups 1A, 1B, 1C and 1D. The subdivision of the monoclonal antibodies was based on the degree of blocking in the competitive binding assays and differences in their ability to induce enhancement. In general, the monoclonal antibodies had a higher avidity for the virulent isolate of hemorrhagic enteritis virus than for the avirulent hemorrhagic enteritis virus isolate.

Characterization of adenovirus particles made by deletion mutants lacking the fiber gene

H2dl802, H2dl807, and H5dl1021 are defective deletion mutants of human adenovirus which do not make the capsid protein fiber yet which can make substantial amounts of virus particles. Virions made by the mutants contain very little fiber (which comes from helper virus contaminants in the deletion virus stocks): less than 6% as much as that contained by wild-type virions. This demonstrates that fiber is not an essential structural component of the adenovirus virion and suggests that fiber is nonessential for virion assembly. These fiber-deficient particles are poorly adsorbed to cells, consistent with the proposed role of fiber in virus attachment. Further, virion protein precursors, including that of the virion protease, are poorly processed in these particles, suggesting a relationship between the presence of fiber and the maturation of the virus particle.

Adenovirus early region 4 is required for efficient virus particle assembly

H2dl807, a defective deletion mutant of human adenovirus type 2 lacking parts of early regions 3 and 4 and all of late region 5, was severely defective for virus particle assembly on HeLa cells, producing about 1% of the normal yield of particles. On Vero cells, H2dl807 produced only 5% as many particles as wild type, while on W162 cells, a Vero cell derivative which supports the growth of early region 4 mutants, H2dl807 produced nearly 40% of the wild-type level of particles. Two other defective deletion mutants, H2dl802 and H5dl1021, which lack parts of early region 3 and which are incapable of making fiber, the product of late region 5, were wild type for virus assembly. These data suggest that the cause of the assembly defect of H2dl807 is the lack of a diffusible early region 4 product. H2dl807-infected Vero cells accumulated nearly wild-type amounts of viral late proteins in the nucleus and cytoplasm. Thus, the defect of the mutant in assembly on Vero cells is not due to a general lack of late proteins. Finally, the fact that H2dl802 and H5dl1021 make wild-type amounts of virus particles suggests that fiber is not essential for adenovirus assembly.

Restriction of human adenovirus replication in Chinese hamster cell lines and their hybrids with human cells

We have found that the replication of human adenovirus (Ad2) is restricted in multiple Chinese hamster cell lines including CHO and V79. The major site of restriction involves differential accumulation of late viral proteins as demonstrated by immunofluorescence assay and polyacrylamide gel electrophoresis with and without prior immunoprecipitation. Synthesis of fiber and penton base are markedly reduced, whereas others, such as the 100K polypeptide, are synthesized efficiently. This pattern of restriction is similar to that previously reported for Ad2 infection of several monkey cell lines; however, the restriction is more marked in the Chinese hamster cell lines. The restriction is most likely due to a deficient cellular function since stable cell hybrids between V79 or CHO and human cells are permissive for virus replication. By analysis of a series of hybrids with reduced numbers of human chromosomes, fiber synthesis was correlated with the presence of the short arm of human chromosome 3. More hybrids showed restoration of fiber synthesis than production of progeny virus, suggesting that more than one unlinked function is required for the latter.

Isolation and characterization of temperature-sensitive mutants of adenovirus type 7

Fifty temperature-sensitive mutants, which replicate at 32 degrees C but not at 39.5 degrees C, were isolated after mutagenesis of the vaccine strain of adenovirus type 7 with hydroxylamine (mutation frequency of 9.0%) or nitrous acid (mutation frequency of 3.8%). Intratypic complementation analyses separated 46 of these mutants into seven groups. Intertypic complementation tests with temperature-sensitive mutants of adenovirus type 5 showed that the mutant in complementation group A failed to complement H5ts125 (a DNA-binding protein mutant), that mutants in group B and C did not complement adenovirus type 5 hexon mutants, and that none of the mutants was defective in fiber production. Further phenotypic characterization showed that at the nonpermissive temperature the mutant in group A failed to make immunologically reactive DNA-binding protein, mutants in groups B and C were defective in transport of trimeric hexons to the nucleus, mutants in groups D, E, and F assembled empty capsids, and mutants in group G assembled DNA-containing capsids as well as empty capsids. The mutants of the complementation groups were physically mapped by marker rescue, and the mutations were localized between the following map coordinates: groups B and C between 50.4 and 60.2 map units (m.u.), groups D and E between 29.6 and 36.7 m.u., and group G between 36.7 and 42.0 m.u. or 44.0 and 47.0 m.u. The mutant in group A proved to be a double mutant.

A thermolabile mutant of adenovirus 5 resulting from a substitution mutation in the protein VIII gene

The mutant adenoviruses H5sub304 and H5RIr were isolated sequentially from adenovirus 5 wild type by selection for the loss of EcoRI restriction endonuclease sites by Jones and Shenk (Cell 13:181-188, 1978). sub304 lacks the site at 84.0 map units (m.u.), and RIr lacks both that and the site at 75.9 m.u. A set of derivatives of RIr that lack the site at 75.9 m.u. accumulated virus more slowly at 38.8 or 39.5 degrees C than those with the site present, as measured by low-multiplicity passage or single-step replication cycles, respectively. Since the EcoRI site at 75.9 m.u. is predicted to lie in the gene encoding the precursor to virion polypeptide VIII (pVIII), the failure to accumulate virus rapidly could lie either in some step in processing and assembly of virions or in an increased virion thermolability. The latter possibility was shown to be the case, as all strains mutated at the EcoRI 75.9 m.u. site were extremely thermolabile in vitro, even at 37 degrees C. CsCl equilibrium density centrifugation of heated crude stocks of RIr and sub304 demonstrated that loss of infectivity in RIr was accompanied by physical disruption of virions. Polyacrylamide gel electrophoresis of infected cell extracts or of purified virions showed that pVIII of RIr had an apparent molecular weight that was slightly greater than that of sub304, and mature RIr and sub304 virions displayed polypeptide VIIIs which appeared to be of identical molecular weights. Nucleotide sequence analysis of RIr demonstrated that it contained a 9-base-pair (bp) substitution for 6 bp found in sub304, leading to a loss of the EcoRI site and a predicted insertion of a single amino acid. Comparison of the sequence of sub304 with the published sequence of adenovirus 2 revealed two changes, a single transversion at bp 1,722 and a bp deletion at 1,749, leading to the loss of a TaqI site. The predicted reading frame change would lead to a stop codon at bp 1,885. This raises the question of whether adenovirus 2 and adenovirus 5 use the same reading fame for pVIII.

Adenovirus 3 fiber polypeptide gene: implications for the structure of the fiber protein

The nucleotide sequence of a 1,330-base-pair-long DNA segment located between map coordinates 88.5 and 92.3 in the adenovirus type 3 (Ad3) genome was determined. Transcripts from the r-strand of the region were mapped by S1 nuclease analysis and by in vitro translation of RNA, selected by filter hybridization. The results revealed that the sequenced region encodes the Ad3 fiber polypeptide with a molecular weight of 34,800. A comparison between the predicted amino acid sequences of the Ad3 and the Ad2 fiber polypeptides revealed that they have almost identical secondary structures, consisting of a tail, a shaft, and a knob. A striking difference between Ad2 and Ad3 fibers was that the shaft of the Ad3 fiber was significantly shorter, containing only 6 repeat units compared with 22 in the Ad2 fiber. The secondary structure suggests that the fiber is a dimeric structure, as proposed earlier (N.M. Green, N.G. Wrigley, W.C. Russell, S.R. Martin, and A.D. McLachlan, EMBO J. 2:1357-1365, 1983), with the size of the polypeptide determining the length of the fiber protein.

Evidence that the penton base of adenovirus is involved in potentiation of toxicity of Pseudomonas exotoxin conjugated to epidermal growth factor

When KB cells are incubated for 1 h with human adenovirus type 2 or type 5 (1 microgram/ml) and a conjugate of epidermal growth factor and Pseudomonas exotoxin (EGF-PE), protein synthesis is inhibited by 80 to 90%. Under these conditions, neither adenovirus nor EGF-PE alone has any effect on host protein synthesis. Thus, adenovirus enhances the toxicity of EGF-PE. A number of antibodies to intact virus and capsid components were tested for their ability to block the enhancing activity and virus uptake. At appropriate dilutions, antibodies prepared against intact virus and penton base blocked the enhancing activity without affecting virus uptake. Antibodies against hexon and fiber blocked virus uptake and enhancing activity in parallel. These studies suggest that the penton base is important in lysis of the vesicles which contain adenovirus and EGF-PE, and this base allows virus and toxin to enter the cytoplasm.

Evidence that the penton base of adenovirus is involved in potentiation of toxicity of Pseudomonas exotoxin conjugated to epidermal growth factor

When KB cells are incubated for 1 h with human adenovirus type 2 or type 5 (1 microgram/ml) and a conjugate of epidermal growth factor and Pseudomonas exotoxin (EGF-PE), protein synthesis is inhibited by 80 to 90%. Under these conditions, neither adenovirus nor EGF-PE alone has any effect on host protein synthesis. Thus, adenovirus enhances the toxicity of EGF-PE. A number of antibodies to intact virus and capsid components were tested for their ability to block the enhancing activity and virus uptake. At appropriate dilutions, antibodies prepared against intact virus and penton base blocked the enhancing activity without affecting virus uptake. Antibodies against hexon and fiber blocked virus uptake and enhancing activity in parallel. These studies suggest that the penton base is important in lysis of the vesicles which contain adenovirus and EGF-PE, and this base allows virus and toxin to enter the cytoplasm.

Polarity in adenovirus recombination

The distributions of the crossovers necessary to generate ts+ genomes have been examined in a collection of clonally unrelated ts+ recombinants from a set of ts X ts adenovirus crosses. In a cross between two parents that are grossly heterologous between map units 80.2 and 91.5, the distribution of crossovers was significantly skewed toward the left-hand end of the genome, with a declining frequency proceeding rightward. This gradient of recombination was modified by the removal of the right-hand heterology and by the presence of another region of heterology between map units 3.67 and 10.11. In a cross where the ts markers were flanked by both heterologies, no gradient was observed and ts+ recombinants were characterized by a higher rate of supernumerary crossovers. In a cross designed so that one ts marker was internal to two heterologies, crossovers were found disproportionately between the second ts marker and the nearby heterology. In addition, ts+ recombinants formed by crossing over internal to the heterologies again were accompanied by a high frequency of supernumerary crossovers. Finally, ts+ recombinant frequencies in crosses identical except for the presence of either one or two flanking heterologies were markedly lower in the latter case. These data, taken together, suggest that a major pathway of adenovirus recombination initiates at, or near, the molecular termini and is perhaps driven by the displaced single strands produced during DNA replication. Internal initiation, on the other hand, may employ these single strands to form genetic "patches."

The genetic analysis of adenovirus recombination in triparental and superinfection crosses

Previous genetic and molecular data suggest that adenovirus genomes can undergo several rounds of recombination before being encapsidated (C. S. H. Young and S. J. Silverstein, Virology 101, 503-515). Two predictions of this hypothesis have been tested. The first is that infection with three differentially marked parental viruses should lead to the appearance of recombinants with genetic contributions from all three parents. In a triparental cross, involving two strains with different ts mutations in chimeric Ad5/Ad2+ND1 backgrounds, and a third strain containing both ts mutations in an Ad5 background, it was demonstrated that multiple recombinations, involving distinguishable restriction endonuclease sites and host range markers from all three parents, were common. The second prediction, from previous kinetic data, is that cells are recombinationally proficient from the eclipse period well into the exponential rise period. This has been tested by superinfecting singly infected cultures, both during eclipse and in early exponential phase. Recombinant viruses were produced in these superinfections, demonstrating that the early to late switch in the replicative cycle does not inhibit recombination. From the temporal appearance of recombinants moreover, it seems likely that recombination functions, and the DNA structures necessary to initiate recombination, are present well into the late phase of replication.