Lorna A. Samaniego

The immediate-early (IE) proteins of herpes simplex virus (HSV) function on input genomes and affect many aspects of host cell metabolism to ensure the efficient expression and regulation of the remainder of the genome and, subsequently, the production of progeny virions. Due to the many and varied effects of IE proteins on host cell metabolism, their expression is not conducive to normal cell function and viability. This presents a major impediment to the use of HSV as a vector system. In this study, we describe a series of ICP4 mutants that are defective in different subsets of the remaining IE genes. One mutant, d109, does not express any of the IE proteins and carries a green fluorescent protein (GFP) transgene under the control of the human cytomegalovirus IE promoter (HCMVIEp). d109 was nontoxic to Vero and human embryonic lung (HEL) cells at all multiplicities of infection tested and was capable of establishing persistent infections in both of these cell types. Paradoxically, the genetic manipulations that were required to eliminate toxicity and allow the genome to persist in cells for long periods of time also dramatically lowered the level of transgene expression. Efficient expression of the HCMVIEp-GFP transgene in the absence of ICP4 was dependent on the ICP0 protein. In d109-infected cells, the level of transgene expression was very low in most cells but abundant in a small subpopulation of cells. However, expression of the transgene could be induced in cells containing quiescent d109 genomes weeks after the initial infection, demonstrating the functionality of the persisting genomes.

ICP4, ICP0, and ICP27 are the immediate-early (IE) regulatory proteins of herpes simplex virus that have the greatest effect on viral gene expression and growth. Comparative analysis of viral mutants defective in various subsets of these IE genes should help elucidate how these proteins affect cellular and viral processes. This study focuses on the mutant d97, which is defective for the genes encoding ICP4, ICP0, and ICP27 and expresses the bacterial beta-galactosidase (beta-gal) gene from the ICP0 promoter. Together with the d92 virus (ICP4- ICP27-) and the ICP0-complementing cell line L7, d97 provided a unique opportunity to evaluate ICP0 function in the absence of the regulatory activities specified by ICP4 and ICP27. The pattern of protein synthesis in d97-infected cells was unique relative to other IE gene mutants in that it was similar to that seen in the absence of prior viral protein synthesis, possibly approximating the effect of cellular factors and virion components alone. Inactivation of ICP0 in the absence of ICP4 produced a significant decrease in the levels of the early mRNAs ICP6 and thymidine kinase (tk). There was also a marginal reduction in the levels of the IE ICP22 mRNA, and this was most notable at low multiplicity of infection (MOI). In d97-infected L7 cells, the levels of the viral mRNAs were mostly restored to those observed in infections with d92. Nuclear runoff transcription analysis demonstrated that the presence of ICP0 resulted in an increase in the transcription rates of the analyzed genes. The transcription rates of the early genes were dramatically reduced in the absence of ICP0. At low MOI, the transcription rates of ICP6 and tk were comparable to the rate of transcription of a cellular gene. Relevant to the potential use of d97 as a transfer vector, it was also determined that the absence of ICP0 reduced the cellular toxicity of the virus compared to that of d92. The beta-gal transgene expressed from an IE promoter was detected for up to 14 days postinfection; however, the level of beta-gal expression declined dramatically after 1 day postinfection. In the presence of ICP0, the level of expression of beta-gal was increased; however the infected monolayer was destroyed by 3 days postinfection. Therefore, deletion of ICP0 in the absence of ICP4 and ICP27 reduces toxicity and lowers the level of expression of genes from the viral genome.

Two of the five immediate-early gene products, ICP4 and ICP27, expressed by herpes simplex virus type 1 have profound effects on viral gene expression and are absolutely essential for virus replication. Functional interactions between ICP4 and ICP27 may contribute to establishing the program of viral gene expression that ensues during lytic infection. To evaluate this possibility, viral mutants simultaneously deleted for ICP27 and defined functional domains of ICP4 were constructed. These mutant viruses allowed a comparison of gene expression as a function of different domains of ICP4 in the presence and absence of ICP27. Gene expression in the absence of both ICP4 and ICP27 was also examined. The results of this study demonstrate a clear involvement for ICP27 in the induction of early genes, in addition to its known role in enhancing late gene expression during viral infection. In the absence of both ICP4 and ICP27, viral early gene expression, as measured by the accumulation of thymidine kinase and ICP6 messages was dramatically reduced relative to the amounts of these messages seen in the absence of only ICP4. Therefore, elevated levels of early gene expression as a consequence of ICP27 occurred in the absence of any ICP4 activity. Evidence is also presented regarding the modulation of the ICP4 repression function by ICP27. When synthesized in the absence of ICP27, a mutant ICP4 protein was impaired in its ability to repress transcription from the L/ST promoter in the context of viral infection and in vitro. This defect correlated with the loss of the ability of this mutant protein to bind to its recognition sequence when produced in infected cells in the absence of ICP27. These observations indicate that ICP27 can regulate the activity of at least one domain of the ICP4 protein as well as contribute to elevated early gene expression independently of ICP4.