A limited innate immune response is induced by a replication-defective herpes simplex virus vector following delivery to the murine central nervous system.

Herpes simplex virus type 1 (HSV-1)-based vectors readily transduce neurons and have a large payload capacity, making them particularly amenable to gene therapy applications within the central nervous system (CNS). Because aspects of the host responses to HSV-1 vectors in the CNS are largely unknown, we compared the host response of a nonreplicating HSV-1 vector to that of a replication-competent HSV-1 virus using microarray analysis. In parallel, HSV-1 gene expression was tracked using HSV-specific oligonucleotide-based arrays in order to correlate viral gene expression with observed changes in host response. Microarray analysis was performed following stereotactic injection into the right hippocampal formation of mice with either a replication-competent HSV-1 or a nonreplicating recombinant of HSV-1, lacking the ICP4 gene (ICP4-). Genes that demonstrated a significant change (P < .001) in expression in response to the replicating HSV-1 outnumbered those that changed in response to mock or nonreplicating vector by approximately 3-fold. Pathway analysis revealed that both the replicating and nonreplicating vectors induced robust antigen presentation but only mild interferon, chemokine, and cytokine signaling responses. The ICP4- vector was restricted in several of the Toll-like receptor-signaling pathways, indicating reduced stimulation of the innate immune response. These array analyses suggest that although the nonreplicating vector induces detectable activation of immune response pathways, the number and magnitude of the induced response is dramatically restricted compared to the replicating vector, and with the exception of antigen presentation, host gene expression induced by the nonreplicating vector largely resembles mock infection.

Herpes simplex virus type 1 shows multiple interactions with sulfonated compounds at binding, penetration, and cell-to-cell passage.

Herpes simplex virus type 1 (HSV-1) uses multicomponent mechanisms for binding, penetration, and cell-to-cell passage. These processes are affected by polysulfonated compounds. In this paper we have addressed the question of whether the same or different interactions of HSV-1 with polysulfonated compounds are involved in binding, penetration, and passage. For this, we have compared the inhibitory dose-response for a series of polysulfonated and cationic compounds known to block HSV-1 infections. These comparisons were done at the level of binding, penetration, and cell-to-cell passage. Variations in the parameters of the dose-response curves - IC(50) and Hill coefficients (n (H)) - are consistent with HSV-1 having multiple interactions with sulfonated cellular components in all these processes. Some of the interactions seem to be common to the three processes, while others are particular for each one.

Biochip sensors for the rapid and sensitive detection of viral disease.

Recent advances in DNA and protein microarray methodology and the emerging technology of cell-based sensors have massively increased the speed and sensitivity with which we can detect viral infections. The advantages of the multi-parameter microarray technologies could be combined with the speed and sensitivity of cell-based systems to give 'cell-omic' sensors.

Design of a herpes simplex virus type 2 long oligonucleotide-based microarray: global analysis of HSV-2 transcript abundance during productive infection.

The design and construction of a long (75-mer) oligonucleotide-based DNA microarray for herpes simplex virus type 2 transcripts is described. This array is utilized to generate an analysis of HSV-2 transcript abundance as a function of conditions of infection of human cells, and global patterns of HSV-2 transcript abundance are compared with those for HSV-1. General similarities in patterns along with notable differences in specific details are noted. These results reveal a marked conservation in the program of gene activity between phenotypically diverged strains.

Inhibition of the stress-activated kinase, p38, does not affect the virus transcriptional program of herpes simplex virus type 1.

To investigate the impact of stress kinase p38 activation on HSV-1 transcription, we performed a global transcript profile analysis of viral mRNA using an oligonucleotide-based DNA microarray. RNA was isolated from Vero cells infected with the KOS strain of HSV-1 in the presence or absence of SB203580, a pyridinyl imidazole inhibitor of p38. Under conditions that eliminated ATF2 activation but had no effect on c-Jun, and reduced virus yield by 85-90%, no effect on accumulation of viral IE, DE, or L transcripts was observed by array analysis or selected Northern blot analysis at 2, 4, and 6 h post infection. Results of array data from cells infected with the ICP27 mutant d27-1 in the presence or absence of SB203580 only reflected the known restricted transcription phenotype of the ICP27 mutant. This result is consistent with a role for p38 activation on virus replication lying downstream of the essential role of ICP27 in DE and perhaps late transcription regulation. No effect of SB203580 on transcription was detected after infection with the ICP0 mutant 7134, at 0.5 or 5.0 PFU/cell, though decreases in the rate of accumulation of all kinetic classes of mRNA could be detected, relative to wt virus. These results indicate that inhibiting p38 activity in Vero cells, while significantly reducing wt virus yield, demonstrated no obvious impact on the program of viral transcription.

General and specific alterations in programming of global viral gene expression during infection by VP16 activation-deficient mutants of herpes simplex virus type 1.

During productive infection by herpes simplex virus 1 (HSV-1), viral gene expression occurs in a temporally regulated cascade in which transcription of the viral immediate-early (IE) genes is strongly stimulated by the virion protein VP16. We have employed an oligonucleotide microarray to examine the effect of VP16 mutations on the overall pattern of viral gene expression following infection of HeLa cells. This microarray detects essentially all HSV-1 transcripts with relative and absolute levels correlating well with known kinetics of expression. This analysis revealed that deletion of the VP16 activation domain sharply reduced overall viral gene expression; moreover, the pattern of this reduced expression varied greatly from the pattern of a wild-type (wt) infection. However, when this mutant virus was delivered at a high multiplicity of infection or in the presence of the cellular stress inducer hexamethylene bisacetamide, expression was largely restored to the wt levels and pattern. Infection with virions that deliver wt VP16 protein at the start of infection but synthesize only truncated VP16 resulted in a normal kinetic cascade. This suggests that newly synthesized VP16 does not play a significant role in the expression of later classes of transcripts. The VP16 activation domain comprises two subregions. Deletion of the C-terminal subregion resulted in minimal changes in the level and profile of gene expression compared to a normal (wt) cascade. In contrast, deletion of the N-terminal subregion reduced the overall expression levels and skewed the relative levels of IE transcripts but did not significantly alter the kinetic pattern of early and late transcript expression. We conclude that the general activation of IE gene transcription by VP16, but not the specific ratios of IE transcripts, is necessary for the subsequent ordered expression of viral genes. Moreover, this report establishes the feasibility of microarray analysis for globally assessing viral gene expression programs as a function of the conditions of infection.

Rapid visualization at high resolution of pathogens by atomic force microscopy: structural studies of herpes simplex virus-1.

A relatively crude preparation of herpes simplex virus was rapidly visualized by atomic force microscopy after exposure to conditions that produced gradual degradation of the virions. Images were obtained of 1) the intact, enveloped virus; 2) the underlying capsid with associated tegument proteins along with fragments of the membrane; 3) the capsomeres composing the capsid and their surface arrangement; 4) damaged and partially degraded capsids with missing capsomeres; and 5) the DNA extruded from damaged virions. These images provide a unique perspective on the structures of individual virus particles. Atomic force microscopy can thus be used as a diagnostic tool to provide a rapid way to obtain high-resolution images of human pathogens from crude preparations. It is a useful technique that complements X-ray-based structure determination, cryo-electron microscopy techniques, and optical microscopies in the field of molecular pathogenesis.

The region of the HSV-1 latency-associated transcript required for epinephrine-induced reactivation in the rabbit does not include the 2.0-kb intron.

Previous studies have localized the region of the latency-associated transcript (LAT) of HSV-1 responsible for epinephrine-induced reactivation in the rabbit eye model to the first 1.5 kb of the primary transcript. This region extends from the 5prime prime or minute exon of the primary LAT transcript through the 5prime prime or minute half of the LAT 2.0-kb intron. To determine whether the 5prime prime or minute end of the LAT intron contributes to the induced reactivation phenotype, three recombinant viruses containing deletions within this portion of the LAT intron were constructed. The three recombinants, containing deletions spanning a combined region of 969 bp at the 5prime prime or minute end of the LAT intron, reactivated with the wild-type frequency of 17syn+. These results indicate that the elements governing induced reactivation reside within the first 699 bp of the primary LAT transcript encoding the 5prime prime or minute LAT exon.

Altering the expression kinetics of VP5 results in altered virulence and pathogenesis of herpes simplex virus type 1 in mice.

While many herpes simplex virus (HSV) structural proteins are expressed with strict-late kinetics, the HSV virion protein 5 (VP5) is expressed as a "leaky-late" protein, such that appreciable amounts of VP5 are made prior to DNA replication. Our goal has been to determine if leaky-late expression of VP5 is a requirement for a normal HSV infection. It had been shown previously that recombinant viruses in which the VP5 promoter was replaced with promoters of other kinetic classes (including a strict late promoter) exhibited no alterations in replication kinetics or virus yields in vitro. In contrast, here we report that alterations in pathogenesis were observed when these recombinants were analyzed by experimental infection of mice. Following intracranial inoculation, a recombinant expressing VP5 from a strict-late promoter (U(L)38) exhibited an increased 50% lethal dose and a 10-fold decrease in virus yields in the central nervous system, while a recombinant expressing VP5 from an early (dUTPase) or another leaky-late (VP16) promoter exhibited wild-type neurovirulence. Moreover, following infection of the footpad, changing the expression kinetics of VP5 from leaky-late to strict-late resulted in 100-fold-less virus in the spinal ganglia during the acute infection than produced by either the parent virus or the rescued virus. These data indicate that the precise timing of appearance of the major capsid protein plays a role in the pathogenesis of HSV infections and that changing the expression kinetics has different effects in different cell types and tissues.