Human SNF5 arming of double-deleted vaccinia virus shows oncolytic and cytostatic activity against central nervous system atypical teratoid/rhabdoid tumor cells.

Central nervous system (CNS) atypical teratoid/rhabdoid tumor (AT/RT) is a rare, aggressive tumor that most often affects very young children. The common decisive molecular defect in AT/RT has been shown to be a single genetic alteration, i.e., the loss of hSNF5 gene that encodes for a subunit of the SWI/SNF complex that modulates chromatin remodeling activities. As a result, AT/RT cells display unregulated cell proliferation due to the dysfunction of an important epigenetic control. We have previously demonstrated the preclinical efficacy of the oncolytic double-deleted vaccinia virus (VVDD) against AT/RT. Here we report the establishment of a modified VVDD engineered to express wild type hSNF5 gene. We show that this reconstructed vaccinia virus retains comparable infectivity and in vitro cytotoxicity of the parent strain. However, in addition, hSNF5-arming of VVDD results in a decreased cell cycle S phase population and down-regulation of cyclin D1. These findings suggest that hSNF5-arming of VVDD may increase the efficacy in the treatment of AT/RT and validates, as a proof-of-concept, an experimental approach to enhance the effective use of novel modified oncolytic viruses in the treatment of tumors with loss of a tumor suppressor gene function.

Oncolytic measles virus efficacy in murine xenograft models of atypical teratoid rhabdoid tumors.

BACKGROUND: Atypical teratoid rhabdoid tumor (AT/RT) is a rare, highly malignant pediatric tumor of the central nervous system that is usually refractory to available treatments. The aggressive growth, propensity to disseminate along the neuroaxis, and young age at diagnosis contribute to the poor prognosis. Previous studies have demonstrated the efficacy of using oncolytic measles virus (MV) against localized and disseminated models of medulloblastoma. The purpose of this study was to evaluate the oncolytic potential of MV in experimental models of AT/RT. METHODS: Following confirmation of susceptibility to MV infection and killing of AT/RT cells in vitro, nude mice were injected with BT-12 and BT-16 AT/RT cells stereotactically into the caudate nucleus (primary tumor model) or lateral ventricle (disseminated tumor model). Recombinant MV was administered either intratumorally or intravenously. Survival was determined for treated and control animals. Necropsy was performed on animals showing signs of progressive disease. RESULTS: All cell lines exhibited significant killing when infected with MV, all formed syncytia with infection, and all generated infectious virus after infection. Orthotopic xenografts displayed cells with rhabdoid-like cellular morphology, were negative for INI1 expression, and showed dissemination within the intracranial and spinal subarachnoid spaces. Intratumoral injection of live MV significantly prolonged the survival of animals with intracranial and metastatic tumors. CONCLUSION: These data demonstrate that AT/RT is susceptible to MV killing and suggest that the virus may have a role in treating this tumor in the clinical setting.

Oncolytic efficacy of recombinant vesicular stomatitis virus and myxoma virus in experimental models of rhabdoid tumors.

PURPOSE: Rhabdoid tumors are highly aggressive pediatric tumors that are usually refractory to available treatments. The purpose of this study was to evaluate the therapeutic potential of two oncolytic viruses, myxoma virus (MV) and an attenuated vesicular stomatitis virus (VSV(DeltaM51)), in experimental models of human rhabdoid tumor. EXPERIMENTAL DESIGN: Four human rhabdoid tumor cell lines were cultured in vitro and treated with live or inactivated control virus. Cytopathic effect, viral gene expression, infectious viral titers, and cell viability were examined at various time points after infection. To study viral oncolysis in vivo, human rhabdoid tumor cells were implanted s.c. in the hind flank or intracranially in CD-1 nude mice and treated with intratumoral (i.t.) or i.v. injections of live or UV-inactivated virus. Viral distribution and effects on tumor size and survival were assessed. RESULTS: All rhabdoid tumor cell lines tested in vitro were susceptible to productive lethal infections by MV and VSV(DeltaM51). I.t. injection of live MV or VSV(DeltaM51) dramatically reduced the size of s.c. rhabdoid tumor xenografts compared with control animals. I.v. administration of VSV(DeltaM51) or i.t. injection of MV prolonged the median survival of mice with brain xenografts compared with controls (VSV(DeltaM51): 25 days versus 21 days, log-rank test, P = 0.0036; MV: median survival not reached versus 21 days, log-rank test, P = 0.0007). Most of the MV-treated animals (4 of 6; 66.7%) were alive and apparently "cured" when the experiment was arbitrarily ended (>180 days). CONCLUSIONS: These results suggest that VSV(DeltaM51) and MV could be novel effective therapies against human rhabdoid tumor.