Neurons differentially activate the herpes simplex virus type 1 immediate-early gene ICP0 and ICP27 promoters in transgenic mice

Herpes simplex virus type 1 (HSV-1) immediate-early (IE) proteins are required for the expression of viral early and late proteins. It has been hypothesized that host neuronal proteins regulate expression of HSV-1 IE genes that in turn control viral latency and reactivation. We investigated the ability of neuronal proteins in vivo to activate HSV-1 IE gene promoters (ICP0 and ICP27) and a late gene promoter (gC). Transgenic mice containing IE (ICP0 and ICP27) and late (gC) gene promoters of HSV-1 fused to the Escherichia coli beta-galactosidase coding sequence were generated. Expression of the ICP0 and ICP27 reporter transgenes was present in anatomically distinct subsets of neurons in the absence of viral proteins. The anatomic locations of beta-galactosidase-positive neurons in the brains of ICP0 and ICP27 reporter transgenic mice were similar and included cerebral cortex, lateral septal nucleus, cingulum, hippocampus, thalamus, amygdala, and vestibular nucleus. Trigeminal ganglion neurons were positive for beta-galactosidase in adult ICP0 and ICP27 reporter transgenic mice. The ICP0 reporter transgene was differentially regulated in trigeminal ganglion neurons depending upon age. beta-galactosidase-labeled cells in trigeminal ganglia and cerebral cortex of ICP0 and ICP27 reporter transgenic mice were confirmed as neurons by double labeling with antineurofilament antibody. Nearly all nonneuronal cells in ICP0 and ICP27 reporter transgenic mice and all neuronal and nonneuronal cells in gC reporter transgenic mice were negative for beta-galactosidase labeling in the absence of HSV-1. We conclude that factors in neurons are able to differentially regulate the HSV-1 IE gene promoters (ICP0 and ICP27) in transgenic mice in the absence of viral proteins. These findings are important for understanding the regulation of the latent and reactivated stages of HSV-1 infection in neurons.     

Binding sites for the herpes simplex virus immediate-early protein ICP4 impose an increased dependence on viral DNA replication on simple model promoters located in the viral genome.

We examined the ability of binding sites for the herpes simplex virus immediate-early protein ICP4 to alter the regulation of closely linked promoters by placing strong ICP4 binding sites upstream or downstream of simple TATA promoters in the intact viral genome. We found that binding sites strongly reduced the levels of expression at early times postinfection and that this effect was partially overcome after the onset of viral DNA replication. These data confirm that DNA-bound ICP4 can inhibit the activity of a closely linked promoter and raise the possibility that ICP4 binding sites contribute to temporal regulation during infection.     

Repression of gene expression upon infection of cells with herpes simplex virus type 1 mutants impaired for immediate-early protein synthesis.

Herpes simplex virus type 1 (HSV-1) mutants defective in immediate-early (IE) gene expression do not readily enter productive replication after infection of tissue culture cells. Instead, their genomes are retained in a quiescent, nonreplicating state in which the production of viral gene products cannot be detected. To investigate the block to virus replication, we used the HSV-1 triple mutant in1820K, which, under appropriate conditions, is effectively devoid of the transactivators VP16 (a virion protein), ICP0, and ICP4 (both IE proteins). Promoters for the HSV-1 IE ICP0 gene or the human cytomegalovirus (HCMV) major IE gene, cloned upstream of the Escherichia coli lacZ coding sequences, were introduced into the in1820K genome. The regulation of these promoters and of the endogenous HSV-1 IE promoters was investigated upon conversion of the virus to a quiescent state. Within 24 h of infection, the ICP0 promoter became much less sensitive to transactivation by VP16 whereas the same element, when used to transform Vero cells, retained its responsiveness. The HCMV IE promoter, which is not activated by VP16, also became less sensitive to the HCMV functional homolog of VP16. Both elements remained available for transactivation by HSV-1 IE proteins at 24 h postinfection, showing that the in1820K genome was not irreversibly inactivated. The promoters controlling the HSV-1 ICP4, ICP22, and ICP27 genes also became essentially unresponsive to transactivation by VP16. The ICP0 promoter was induced when hexamethylene bisacetamide was added to cultures at the time of infection, but the response to this agent was also lost by 24 h after infection. Therefore, promoter elements within the HSV-1 genome are actively repressed in the absence of IE gene expression, and repression is not restricted specifically to HSV-1 IE promoters.     

Identification of a motif in the C terminus of herpes simplex virus regulatory protein ICP4 that contributes to activation of transcription.

Expression of most viral genes during productive infection by herpes simplex virus is regulated by the viral protein ICP4 (also called IE175 or Vmw175). The N-terminal portion of ICP4 contains well-defined transactivation, DNA binding, and dimerization domains that contribute to promoter regulation. The C-terminal half of ICP4 contributes to the activity of ICP4, but the functional motifs have not been well mapped. To localize functional motifs in the C-terminal half of ICP4, we have compared the relative specific activities of ICP4 variants in transient-transfection assays. Deletion of the C-terminal 56 residues reduces the specific activity more than 10-fold. Mutational analysis identified three consecutive residues (1252 to 1254) that are conserved in ICP4 orthologs and are essential for full activity, especially in the context of ICP4 variants with a deletion in the N-terminal transactivation domain. Recombinant viruses that encode variants of ICP4 with mutations in the N-terminal transactivation domain and/or the extreme C terminus were constructed. The phenotypes of these recombinant viruses support the hypothesis that efficient promoter activation by ICP4 requires motifs at both the N and C termini. The data suggest that the C terminus of ICP4 functions not as an independent transactivation domain but as an enhancer of the ICP4 N-terminal transactivation domain. The data provide further support for the hypothesis that some ICP4 motifs required for promoter activation are not required for promoter repression and suggest that ICP4 utilizes different cellular factors for activation or repression of viral promoters.