Jack G. Stevens

Latent herpes simplex virus in spinal ganglia of mice.

Herpes simplex virus establishes a persistent, latent infection in spinal ganglia after mice have recovered from posterior paralysis. Infectious virus is replicated when these ganglia are explanted and maintained as organ cultures in vitro.

A latent, nonpathogenic HSV-1-derived vector stably expresses β-galactosidase in mouse neurons

A genetically engineered herpes simplex virus variant was constructed for use as a stable gene vector for neurons. To inhibit replication, the agent possessed a deletion in the immediate early gene ICP4, and to minimize reactivation from the latent state, the gene encoding the latency-associated transcript was deleted. The E. coli beta-galactosidase gene under the control of the Maloney murine leukemia virus long terminal repeat promoter was inserted into the ICP4 region. When introduced into the peripheral nervous system, this virus established latent infections and stably expressed beta-galactosidase in primary sensory neurons. Expression of beta-galactosidase over a more limited time period was observed when the latent infection was established in motor neurons of the hypoglossal nucleus. Agents of this general design have considerable potential for use as gene vectors for studies of neuronal function and correction of genetic defects affecting neurons.

Herpes simplex virus latent phase transcription facilitates in vivo reactivation

The biological role of latent phase transcripts was studied in a rabbit model of herpes simplex virus type I (HSV-I) ocular reactivation. Virus X10-13, a variant of HSV which does not express latency associated transcripts (LAT), has been previously shown to establish latent infection in mouse sensory nerve ganglia, and LAT(-) virus can be recovered upon explantation and cocultivation of ganglia. In the rabbit, we show here that this virus replicates normally on the cornea and conjunctiva and establishes latent infections in corresponding trigeminal ganglionic neurons. However, X10-13 is not efficiently reactivated after iontophoresis of 0.01% epinephrine into the cornea. In contrast, XC-20, a LAT(+) derivative of X10-13 in which LAT expression had been restored by marker rescue of X10-13 with a cloned HSV-I EcoRI J + K fragment, reactivated at a significantly higher rate. Control experiments indicated that XC-20 and X10-13 established latent infections in an equivalent number of neurons. We conclude that latent phase transcription of HSV facilitates ganglionic reactivation and subsequent ocular shedding of the reactivated virus.

A herpes simplex virus transcript abundant in latently infected neurons is dispensable for for establishment of the latent state

We have previously reported that a novel herpes simplex virus RNA transcript partially overlapping the gene encoding ICPO and expressed from the opposite DNA strand is abundant in sensory neurons of mice harboring a latent infection [J.G. Stevens, E.K. Wagner, G.B. Devi-Rao, M.L. Cook, and L.T. Feldman, Science 235, 1056-1059 (1987)]. This finding suggested that this transcript might be involved in establishment, maintenance, or reactivation of latent virus. To determine the function of this latency-associated transcript (LAT), we have examined the latency characteristics of a deletion mutant which is unable to express the LAT gene. Although no viral transcripts could be found in the lumbosacral ganglia of mice surviving rear footpad infection with this deletion virus, a latent infection had been established since infectious virus could be induced and detected after explanation and cocultivation of ganglia with permissive cells in culture. These results indicate that HSV-1 LAT expression is not an absolute requirement for establishment of the latent state.

Pathways of viral gene expression during acute neuronal infection with HSV-1

Pathways of viral gene expression were investigated during the acute phase of sensory ganglionic infection with HSV-1. To facilitate these studies we constructed KOS/62-3, an HSV-1 vector in which the Escherichia coli lac-Z gene was inserted behind both copies of the promoter for the viral latency-associated transcripts. Following footpad inoculation of mice with the virus, acutely infected dorsal root ganglion (DRG) neurons were assayed by dual immunofluorescence for the presence of beta-galactosidase and HSV viral antigens. Most infected neurons stained for either beta-galactosidase or viral antigens. Less than 0.2% of neurons staining for viral antigens also expressed beta-galactosidase, and less than 10% of neurons expressing beta-galactosidase also stained for viral antigen. As a consequence of these findings, we propose that there are essentially two populations of HSV-infected neurons during the acute phase of ganglionic infection. In one population of neurons there is abundant viral protein synthesis but minimal transcription of latency-associated transcripts, whereas in a second population of neurons viral gene expression is severely restricted except for the synthesis of latency-associated transcripts. Since DRG neurons are a heterogeneous population of cells, we further sought to determine whether either pathway of gene expression was more likely to occur in a particular neuronal phenotype. To accomplish this, antibodies were used to characterize the DRG neuronal phenotypes acutely infected with the virus. The results indicated that the pathway of neuronal infection characterized by transcription of abundant latency-associated transcripts and minimal viral protein synthesis was much more likely to occur in DRG neurons expressing the cellular antigen SSEA-3. These data indicate that the neuron plays a major role in regulating the outcome of infection with HSV. Finally, we sought to determine whether DNA replication occurs in the course of establishment of a latent infection. We found that the DNA content of neurons latently infected with KOS(M) strain HSV was not affected by treatment with nucleotide analogues during the acute phase of ganglionic infection, suggesting that viral DNA replication does not occur during the establishment of latent infection.

Physical location of a herpes simplex virus type-1 gene function(s) specifically associated with a 10 million-fold increase in HSV neurovirulence

In this paper we present a technique developed to physically locate the HSV-1 gene(s) which restore neurovirulence to a non-neurovirulent HSV intertypic recombinant described in the preceding report. In brief, tissue culture cells are co-transfected with unit length RE6 DNA and restriction endonuclease fragmented HSV-1 (strain 17 Syn+) DNA. In this way, random recombinations between RE6 and 17 Syn+ are produced. An in vivo enrichment in mouse brains is then employed to select recombinants which have incorporated the HSV-1 gene(s) associated with neurovirulence. In each of five cases where neurovirulent recombinants were isolated by this procedure, restriction enzyme and Southern DNA transfer analysis revealed that HSV-1 information from 0.71 to 0.83 map units had been incorporated into the RE6 genome. Confirmation of the role of this portion of the genome for HSV neurovirulence was obtained by similar cotransfection and in vivo rescue experiments performed with an electrophoretically purified HSV-1 DNA fragment which encompasses this region. Subsequent genome structure analysis of neurovirulent recombinants generated by this procedure revealed that only type-1 information from 0.71 to 0.83 map units had been incorporated into RE6. Thus an HSV-1 gene function(s) which resides in this region of the viral DNA is associated with a 10 million-fold increase in the neurovirulence of the virus. Potential applications of this in vivo selection technique are discussed.

Latent herpetic infections following experimental viraemia.

The spectrum of tissues harbouring latent herpes simplex virus following intravenous inoculation of mice was defined by in vitro co-cultivation techniques. The virus could be detected in central and peripheral nervous systems (including adrenal medulla), but could not be found in any non-neural tissues. Spinal ganglia were the organs most commonly involved. The relationship of these findings to the natural history of herpetic infections is discussed.

Intraaxonal transport of Herpes simplex virus in the rat central nervous system

Light and electron microscopic observation 3--4 days after microinjection of Herpes simplex virus (HSV) into the left neostriatum of rat demonstrated the following results. (1) Virus labeled nerve cells were found in the ipsilateral substantia nigra; a large number of infected neurons were in the zona compacta and some were in the zona reticulata. No virus infection was evident in the contralateral side. (2) Virus labeled neurons were found in the cortex, a greater number ipsilaterally than contralaterally, and in the dorsal raphé nuclei. Cortical microinjection of HSV led to infection of some cortical cells but no neostriatal cells. We conclude, therefore, that spread of the virus to the cortex, the substantia nigra and the dorsal raphé following neostriatal injection was by retrograde axonal transport. (3) The left neostriatum, where HSV was injected, showed a surprisingly small number of virus infected neurons. The infected neurons were mostly the large neurons; the majority of medium sized neurons were well preserved. There was massive degeneration of nerve terminals throughout the neuropil. Most of these degenerating nerve terminals are considered to be afferent fibers.

Long-term expression of a reporter gene from latent herpes simplex virus in the rat hippocampus

A problem in utilizing herpes simplex virus (HSV) as a vector for expression of foreign genes in CNS neurons has been the inability to facilitate long-term expression of the engineered genes. Previously, we showed that the murine moloney leukemia virus LTR would drive beta-galactosidase (beta-gal) transcription for extended periods from the latent viral genome in sensory, but not motor neurons. In this communication we further evaluate the utility of the LTR promoter for use in long-term expression vectors. Following stereotactic injection of 8117/43 (an ICP4 minus, non-replicating virus with the LTR driving the beta-gal gene, or KD6 (an ICP4 minus non-replicating virus not expressing beta-gal) into the hippocampus of rats, polymerase chain reaction (PCR) analysis of viral DNA after 2 months indicated that latent infections were established. Assaying by both x-gal staining and reverse transcriptase PCR we demonstrate that (1) beta-gal can be detected for at least 6 months in hippocampal neurons, and (2) although the number of beta-gal transcripts in these cells drops considerably by 2 weeks, they can be detected during the period studied. These studies indicate that the LTR promoter is active and affords long-term expression in the CNS, albeit at comparatively low levels compared to those observed at acute times.

Latent characteristics of selected herpesviruses.

Publisher Summary The Herpesvirus group essentially consists of many agents, individuals of which infect most of the members of the animal kingdom. The classification of an agent as a herpesvirus is based entirely upon the distinctive morphology of the virion and certain other additional properties shared by most members of this group. Many herpesviruses establish a unique relationship with their host in which initial infection is followed by the persistence of the agent, commonly for the life of host. This phenomenon is commonly called “latency.” In context to tissues harboring latent viruses, the herpesviruses can be further divided into three subgroups—namely, those associated exclusively with either nervous tissues, lymphoid tissues, or epithelial tissues. This chapter focuses on Herpes simplex virus (HSV), Epstein-Barr Virus (EBV), and the Lucke agent, which are well-studied representatives from each subgroup. It discusses the basic aspects of the latent state, particularly as they exist in the intact host. Essentially, herpesviruses establish latent infections from which they can be subsequently reactivated.