Histopathological responses in the CNS following inoculation with a non-neurovirulent mutant (1716) of herpes simplex virus type 1 (HSV 1): relevance for gene and cancer therapy.

The RL1 gene of herpes simplex virus (HSV) encodes a polypeptide, ICP34.5 which is a specific virulence determinant. RL1 null mutants fail to replicate in both the PNS and CNS and are incapable of causing encephalitis. Additionally, RL1 null mutants have the capacity to replicate in actively dividing cells but fail to replicate in growth arrested or terminally differentiated cells. This selective replication phenotype has highlighted their use as both tumour killing agents and gene delivery vehicles particularly to the nervous system. Before their full potential can be assessed, however, it is necessary to determine the pathological and immune responses induced following direct intracerebral inoculation. Fourteen mice were injected in the left cerebral hemisphere with a high dose of the HSV-1, RL1 null mutant 1716. At regular time intervals up to 28 days, the mice were killed and the distribution of virus antigen, histopathological changes and immune responses in the CNS determined by H & E staining and immunohistochemistry. Control mice were injected with either wild type HSV-1 or buffer. At early times post-inoculation with 1716, there is a low grade meningoencephalitis with a limited inflammatory response. This is accompanied by virus antigen expression confined to the site of inoculation. By 28 days the CNS is histopathologically normal; virus antigen and immune responses are no longer detectable. These findings demonstrate that infection of the CNS by RL1 null mutants of HSV results in a finite, self-limiting response and highlights their potential for therapeutic use.

Selective astrocytic transgene expression in vitro and in vivo from the GFAP promoter in a HSV RL1 null mutant vector--potential glioblastoma targeting.

Due to the lack of any effective therapy, novel approaches are currently being explored for the treatment of primary brain tumours. It has previously been demonstrated that variants of HSV-1 which are deleted in the RL1 gene and fail to produce the virulence factor ICP34.5 are potential candidates for tumour therapy. The RL1 variant 1716 replicates selectively within tumour cells and has the potential to deliver a therapeutic or tumour killing gene directly to the site of tumour growth. As many intracerebral tumours are glial and predominantly astrocytic in origin, we have evaluated the ability of 1716 to deliver a reporter gene specifically to astrocytes in vivo and in vitro using a 2.2 kb fragment which controls expression of the glial fibrillary acidic protein (GFAP), an astrocyte specific protein. Two 1716 variants, 1774 and 1775, were constructed which contain the GFAP-promoter element linked to the E. coli beta-galactosidase gene, inserted into the HSV-1 UL43 and US5 loci, respectively. In primary cultures, human primary tumour cell lines and established tumour cell lines in vitro, 1774 and 1775 gave high levels of expression of beta-galactosidase specifically in astrocytes. In vivo following intracerebral inoculation, both viruses demonstrated high levels of beta-galactosidase expression predominantly in astrocytes. These results indicate that the GFAP promoter element could be used for efficient and selective transgene delivery to human gliomas.

Expression of HSV Proteins in Bacteria.

Expression of herpes simplex virus (HSV) polypeptides in bacterial expression systems has provided a useful tool for the generation of large quantities of specific viral proteins for use in both biochemical and functional analysis, and as immunogens for antisera production. Proteins can be expressed either in the full-length native form or as fusion proteins with affinity tails.

The herpes simplex virus virulence factor ICP34.5 and the cellular protein MyD116 complex with proliferating cell nuclear antigen through the 63-amino-acid domain conserved in ICP34.5, MyD116, and GADD34.

The herpes simplex virus (HSV) virulence factor ICP34.5, the mouse myeloid differentiation protein MyD116, and the hamster growth arrest and DNA damage protein GADD34 share a 63-amino-acid carboxyl domain which has significant homologies to otherwise divergent proteins. Here we report that both ICP34.5 and its cellular homolog MyD116 complex through the conserved domain with proliferating cell nuclear antigen. In addition, HSV infection induces a novel 70-kDa cellular protein detectable by antisera to both ICP34.5 and GADD34, demonstrating that this novel protein possesses homology with the 63-amino-acid conserved domain.

Selective in vitro replication of herpes simplex virus type 1 (HSV-1) ICP34.5 null mutants in primary human CNS tumours--evaluation of a potentially effective clinical therapy.

Primary tumours of the central nervous system (CNS) are an important cause of cancer-related deaths in adults and children. CNS tumours are mostly glial cell in origin and are predominantly astrocytomas. Conventional therapy of high-grade gliomas includes maximal resection followed by radiation treatment. The addition of adjuvant chemotherapy provides little improvement in survival time and hence assessment of novel therapies is imperative. We have evaluated the potential therapeutic use of the herpes simplex virus (HSV) mutant 1716 in the treatment of primary brain tumours. The mutant is deleted in the RL1 gene and fails to produce the virulence factor ICP34.5. 1716 replication was analysed in both established human glioma cell lines and in primary cell cultures derived from human tumour biopsy material. In the majority of cultures, virus replication occurred and consequential cell death resulted. In the minority of tumour cell lines which are non-permissive for mutant replication, premature shut-off of host cell protein synthesis was induced in response to lack of expression of ICP34.5. Hence RL1-negative mutants have the distinct advantage of providing a double hit phenomenon whereby cell death could occur by either pathway. Moreover, 1716, by virtue of its ability to replicate selectively within a tumour cell, has the potential to deliver a 'suicide' gene product to the required site immediately. It is our opinion that HSV which fails to express ICP34.5 could provide an effective tumour therapy.

The transcripts from the sequences flanking the short component of Marek's disease virus during latent infection form a unique family of 3'-coterminal RNAs.

We have constructed a cDNA library using poly(A)+ RNA from the stably transformed Marek's disease virus cell line MKT-1 and isolated cDNAs specific to the short internal repeat region of the BamHI-A fragment of the viral genome. Four distinct classes of cDNA were identified through sequence analysis of the 5' and 3' termini of each clone isolated, and a representative of each class was chosen for complete sequencing. These cDNAs were mapped on the basis of the genomic nucleotide sequence of this region, and a family of 3'-coterminal overlapping transcripts consisting of several highly spliced species, was identified. PCR was used to amplify specific regions of each cDNA, which were subcloned and used to generate riboprobes. These riboprobes hybridized to a variety of transcripts in poly(A)+ RNA fractions isolated from cells either lytically or latently infected with Marek's disease virus.

Replication, establishment of latent infection, expression of the latency-associated transcripts and explant reactivation of herpes simplex virus type 1 gamma 34.5 mutants in a mouse eye model.

The herpes simplex virus type 1 (HSV-1) gamma 34.5 gene is located within a region that is transcriptionally active during latent HSV-1 infection. To determine whether the gamma 34.5 gene deletion affects latency-associated transcript (LAT) gene expression or latent HSV-1 infection, a gamma 34.5 gene deletion mutant, 1716, and a stop codon insertion mutant, 1771, were studied in the mouse eye model. Although the gamma 34.5 gene is not essential, 1716 and 1771 replicated poorly in mouse eyes and trigeminal ganglia (TG). When mice were inoculated with 1716, infectious virus was detected in eyes only on the first day post-infection (p.i.), and was not detected at any time point in TG. Following inoculation with 1771, a small amount of virus was detected in the eyes on days 2 and 4 p.i., and in the TG of one animal on day 2 p.i. Reactivation of virus from mice latently infected with 1716 (0/30 TG) and 1771 (1/20 TG) was extremely low compared with the parental strain, 17+, and appropriate rescuants (80 to 100% reactivation), even though latent 1716 DNA was detected by PCR in 50% of TG. These results differ from those obtained following footpad inoculation; in the footpad there was limited 1716 replication and reactivatable latent infection was established in some dorsal root ganglia. The data support the hypothesis that the role of gamma 34.5 may be tissue and/or cell type specific. The synthesis, processing, and stability of the 2.0 kb LAT during 1716 and 1771 replication was not affected by these mutations in the gamma 34.5 gene. However, during latent infection of 1716 in mice the LATs were not detectable in TG by Northern blot, and were present in reduced amounts (approximately 10-fold less) during 1771 latency. The LATs from 1716 were barely detectable in a few neurons by in situ hybridization. Therefore, the gamma 34.5 gene might (i) affect replication in the eye, and reduce the amount of virus available to establish latent infection, be directly involved in (ii) establishment of latency, and/or (iii) the reactivation process.

Characterization of the herpes simplex virus type 1 strain 17+ neurovirulence gene RL1 and its expression in a bacterial system.

The DNA sequence of herpes simplex virus type 1 (HSV-1) strain 17+ in the region coding for the polypeptide ICP34.5 predicts a protein of 248 amino acids with a proposed M(r) of 26,158. The entire RL1 open reading frame was cloned into the expression vector pET8c to enable over-expression of ICP34.5 in Escherichia coli. The expressed protein was partially purified and used as an immunogen to produce a polyclonal antiserum in rabbits. Construction of an ICP34.5 null mutant (1771), demonstrated that the predicted open reading frame for ICP34.5 in strain 17+ is correct and confirmed that HSV-1 strain 17+ ICP34.5 specifically determines neurovirulence. The specificity of the anti-serum directed against the E. coli-expressed ICP34.5 was defined by Western blotting of wild-type and RL1-negative infected cell extracts.