Development of a new fusion-enhanced oncolytic immunotherapy platform based on herpes simplex virus type 1

Development of a new fusion-enhanced oncolytic immunotherapy platform based on herpes simplex virus type 1

Oncolytic viruses preferentially replicate in tumors as compared to normal tissue and promote immunogenic cell death and induction of host systemic anti-tumor immunity. HSV-1 was chosen for further development as an oncolytic immunotherapy in this study as it is highly lytic, infects human tumor cel...

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Bibliographic Details
Published in:Journal for immunotherapy of cancer 2019-08, Vol.7 (1), p.214-214, Article 214
Main Authors: Thomas, Suzanne, Kuncheria, Linta, Roulstone, Victoria, Kyula, Joan N, Mansfield, David, Bommareddy, Praveen K, Smith, Henry, Kaufman, Howard L, Harrington, Kevin J, Coffin, Robert S
Format: Article
Language:eng
Subjects:
Anenestic effect
Antibodies
Antigens
Apoptosis
Biochemistry
Breast cancer
Cancer
Cancer patients
Care and treatment
Cell death
Chromosomal proteins
Clinical trials
Cold sores
Drug approval
FDA approval
Genes
Glycoproteins
Herpes simplex
Herpes simplex virus
Herpes simplex-1
Herpes viruses
Herpesvirus infections
Immune response
Immune system
Immunotherapy
Leukemia
Ligands
Lung cancer
Lymphomas
Melanoma
Necrosis
Oncolytic viruses
Patients
Proteins
Response rates
T cells
Tumor antigens
Tumors
Virus replication
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Summary:Oncolytic viruses preferentially replicate in tumors as compared to normal tissue and promote immunogenic cell death and induction of host systemic anti-tumor immunity. HSV-1 was chosen for further development as an oncolytic immunotherapy in this study as it is highly lytic, infects human tumor cells broadly, kills mainly by necrosis and is a potent activator of both innate and adaptive immunity. HSV-1 also has a large capacity for the insertion of additional, potentially therapeutic, exogenous genes. Finally, HSV-1 has a proven safety and efficacy profile in patients with cancer, talimogene laherparepvec (T-VEC), an oncolytic HSV-1 which expresses GM-CSF, being the only oncolytic immunotherapy approach that has received FDA approval. As the clinical efficacy of oncolytic immunotherapy has been shown to be further enhanced by combination with immune checkpoint inhibitors, developing improved oncolytic platforms which can synergize with other existing immunotherapies is a high priority. In this study we sought to further optimize HSV-1 based oncolytic immunotherapy through multiple approaches to maximize: (i) the extent of tumor cell killing, augmenting the release of tumor antigens and danger-associated molecular pattern (DAMP) factors; (ii) the immunogenicity of tumor cell death; and (iii) the resulting systemic anti-tumor immune response. To sample the wide diversity amongst clinical strains of HSV-1, twenty nine new clinical strains isolated from cold sores from otherwise healthy volunteers were screened across a panel of human tumor cell lines to identify the strain with the most potent tumor cell killing ability, which was then used for further development. Following deletion of the genes encoding ICP34.5 and ICP47 to provide tumor selectivity, the extent of cell killing and the immunogenicity of cell death was enhanced through insertion of a gene encoding a truncated, constitutively highly fusogenic form of the envelope glycoprotein of gibbon ape leukemia virus (GALV-GP-R ). A number of further armed derivatives of this virus were then constructed intended to further enhance the anti-tumor immune response which was generated following fusion-enhanced, oncolytic virus replication-mediated cell death. These viruses expressed GMCSF, an anti-CTLA-4 antibody-like molecule, CD40L, OX40L and/or 4-1BB, each of which is expected to act predominantly at the site and time of immune response initiation. Expression of these proteins was confirmed by ELISA and/or
ISSN:2051-1426
2051-1426