Mechanisms of E3 modulation of immune and inflammatory responses.

Adenoviruses contain genes that have evolved to control the host immune and inflammatory responses; however, it is not clear whether these genes function primarily to facilitate survival of the virus during acute infection or during its persistent phase. These issues have assumed greater importance as the use of adenoviruses as vectors for gene therapy has been expanded. This review will focus on the mechanism of immune evasion mediated by the proteins encoded within the early region 3 (E3) transcription region, which affect the functions of a number of cell surface receptors including Fas, intracellular cell signaling events involving NF-kappaB, and the secretion of pro-inflammatory molecules such as chemokines. The successful use of E3 genes in facilitating allogeneic transplantation and in preventing autoimmune diabetes in several transgenic mouse models will also be described.

Control of adenovirus early gene expression during the late phase of infection.

The adenovirus gene regulatory program occurs in two distinct phases, as defined by the onset of DNA replication. During the early phase, the E1A, E1B, E2, E3, and E4 genes are maximally expressed, while the major late promoter (MLP) is minimally expressed and transcription is attenuated. After the onset of DNA replication, the IVa2 and pIX genes are expressed at high levels, transcription from the MLP is unattenuated and fully activated, and early gene expression is repressed. Although the cis elements and trans-acting factors responsible for the late-phase activation of the MLP have been identified and characterized and the role of DNA replication in activation has been established, the mechanism(s) underlying the commensurate decrease in early gene expression has yet to be elucidated. The results of this study demonstrate that this decrease depends on a fully functional MLP. Specifically, virus mutants with severely deficient transcription from the MLP exhibit a marked increase in expression of the E1A, E1B, and E2 early genes. These increases were observed at the level of transcription initiation, mRNA accumulation, and protein production. In addition, expression from the late gene pIX, which is not contained within the major late transcription unit (MLTU), is also markedly increased. To begin the analysis of the mechanisms underlying these late-phase effects, mixed-infection experiments with mutant and wild-type viruses were performed. The results show that the effects on early gene expression, as measured both at the protein and RNA levels, are mediated in trans and not in cis. These observations are consistent either with a model in which one or more late protein products encoded by the MLTU acts as a repressor of early gene expression or with one in which the wild-type MLP competes with early promoters for limiting transcription factors.

The role of the L4 33K gene in adenovirus infection.

The late phase of adenovirus infection is characterized not only by the synthesis of late proteins and the assembly of new virions, but also by the inhibition of early gene expression and host cell translation. Previous work has demonstrated that both of these inhibitory effects depend upon expression from the major late transcription unit (MLTU), controlled by the major late promoter (MLP). Furthermore, the repression of early gene expression has been shown to be mediated in trans, suggesting a role for one or more MLTU-encoded soluble factor(s). A possible candidate for such a factor is the L4-encoded 33K gene product, a protein conserved throughout the Mastadenoviridae, but of no known function. To test the role of this protein in viral infection, a stop codon was placed at the 20th position of the 33K ORF. Viable virus with genomes containing the mutation were recovered in an overlap recombination assay. Phenotypic analysis revealed that the mutant virus had a significant deficiency in both kinetics of replication and final yield, as compared to the wild-type virus. Detailed analysis of infected cells showed that there was no detectable change in the regulation of expression of several early genes and the pIX gene. This suggests either that 33K is not involved in this late phase phenomenon or that this function is replaceable by another late protein(s). Late protein synthesis and accumulation were similar to those in wild-type-infected cells. However, the reduced yield of infectious mutant virus could be accounted for by a marked deficiency in the accumulation of intermediate particles and completed capsids, suggesting a role for 33K in the process of assembly. In addition there was a small but reproducible deficiency in the shutoff of host cell translation. These results show that the 33K protein plays an important, although apparently not essential, function in the late phase of virus infection.