Publications (25) View all
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Article: A functional recombinant human 4-1BB ligand for immune costimulatory therapy of cancer.
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ABSTRACT: Costimulatory factors hold great promise for development into novel anticancer biotherapeutics. An agonist to 4-1BB is ranked number 8 by National Cancer Institute on the list of 20 agents with high potential for use in treating cancer. We earlier reported on a recombinant murine 4-1BB ligand fusion protein that binds 4-1BB receptor on murine T cells and stimulates their proliferation in tumor-bearing mice. To facilitate clinical translation,we constructed a corresponding recombinant human 4-1BB ligand fusion protein (hIg-h4-1BBLs) and showed its ability to activate human T cells in vitro. Using Chinese hamster ovary cells transformed with a plasmid coexpressing hIg-h4-1BBLs and rat glutamine synthetase, we generated a high-producing clone by sequential selection with methionine sulfoximine. The hIg-h4-1BBLs was partially purified by protein A column chromatography and characterized biochemically and functionally, using human 4-1BB binding and human T-cell proliferation assays, in vitro.Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western Blot confirmed that the hIg-h4-1BBLs is expressed predominantly as a functionally active multimeric protein with the ability to specifically bind to cells expressing human 4-1BB receptor and induce significant T-cell proliferation in vitro using both human and monkey peripheral blood mononuclear cells. The hIg-h4-1BBLs can be produced in large quantities from the high producer clone and developed as a novel immune costimulatory biotherapeutic to treat, alone and in combination with other modalities, various malignant diseases in patients through T-cell activation. Process development of this clinical agent has been discussed with the Food and Drug Administration in a pre-Investigational New Drug meeting and presented to the Office of Biotechnology Activities in a public hearing.Journal of immunotherapy (Hagerstown, Md.: 1997) 02/2011; 34(2):175-82. · 3.20 Impact Factor -
Article: Current good manufacturing practice production of an oncolytic recombinant vesicular stomatitis viral vector for cancer treatment.
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ABSTRACT: Vesicular stomatitis virus (VSV) is an oncolytic virus currently being investigated as a promising tool to treat cancer because of its ability to selectively replicate in cancer cells. To enhance the oncolytic property of the nonpathologic laboratory strain of VSV, we generated a recombinant vector [rVSV(MΔ51)-M3] expressing murine gammaherpesvirus M3, a secreted viral chemokine-binding protein that binds to a broad range of mammalian chemokines with high affinity. As previously reported, when rVSV(MΔ51)-M3 was used in an orthotopic model of hepatocellular carcinoma (HCC) in rats, it suppressed inflammatory cell migration to the virus-infected tumor site, which allowed for enhanced intratumoral virus replication leading to increased tumor necrosis and substantially prolonged survival. These encouraging results led to the development of this vector for clinical translation in patients with HCC. However, a scalable current Good Manufacturing Practice (cGMP)-compliant manufacturing process has not been described for this vector. To produce the quantities of high-titer virus required for clinical trials, a process that is amenable to GMP manufacturing and scale-up was developed. We describe here a large-scale (50-liter) vector production process capable of achieving crude titers on the order of 10(9) plaque-forming units (PFU)/ml under cGMP. This process was used to generate a master virus seed stock and a clinical lot of the clinical trial agent under cGMP with an infectious viral titer of approximately 2 × 10(10) PFU/ml (total yield, 1 × 10(13) PFU). The lot has passed all U.S. Food and Drug Administration-mandated release testing and will be used in a phase 1 clinical translational trial in patients with advanced HCC.Human gene therapy 11/2010; 22(4):489-97. · 4.20 Impact Factor -
Article: Enhanced oncolytic potency of vesicular stomatitis virus through vector-mediated inhibition of NK and NKT cells.
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ABSTRACT: Recombinant oncolytic viruses represent a promising alternative option for the treatment of malignant cancers. We have reported earlier the safety and efficacy of recombinant vesicular stomatitis virus (VSV) vectors in a rat model of hepatocellular carcinoma (HCC). However, the full potential of VSV therapy is limited by a sudden decline in intratumoral virus replication observed early after viral administration, a phenomenon that coincides with an accumulation of inflammatory cells within infected lesions. To overcome the antiviral function of these cells, we present a recombinant virus, rVSV-UL141, which expresses a protein from human cytomegalovirus known to downregulate the natural killer (NK) cell-activating ligand CD155. The modified vector resulted in an inhibition of NK cell recruitment in vitro, as well as decreased intratumoral accumulations of NK and NKT cells in vivo. Administration of rVSV-UL141 through hepatic artery infusion in immune-competent Buffalo rats harboring orthotopic, multi-focal HCC lesions resulted in a one-log elevation of intratumoral virus replication over a control rVSV vector, which translated to enhance tumor necrosis and substantial prolongation of survival. Moreover, these results were achieved in the absence of apparent toxicities. The present study suggests the applicability of this strategy for the development of effective and safe oncolytic agents to treat multi-focal HCC, and potentially a multitude of other cancers, in the future.Cancer gene therapy 11/2008; 16(3):266-78. · 3.13 Impact Factor -
Article: Myeloid derived suppressor cells as a vehicle for tumor-specific oncolytic viral therapy.
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ABSTRACT: One of the several impediments to effective oncolytic virus therapy of cancer remains a lack of tumor-specific targeting. Myeloid derived suppressor cells (MDSCs) are immature myeloid cells induced by tumor factors in tumor-bearing hosts. The biodistribution kinetics of MDSC and other immune cell types in a murine hepatic colon cancer model was investigated through the use of tracking markers and magnetic resonance imaging (MRI). MDSCs were superior to other immune cell types in preferential migration to tumors in comparison to other tissues. Based on this observation, we engineered a strain of vesicular stomatitis virus (VSV), an oncolytic rhabdovirus, that bound MDSCs and used them as a delivery vehicle. Improving VSV binding efficiency to MDSCs extended the long-term survival of mice bearing metastatic colon tumors, compared to systemic administration of wild-type VSV alone. Survival was further extended by multiple injections of the engineered virus without significant toxicity. Notably, direct tumor killing was accentuated by promoting MDSC differentiation towards the classically activated M1-like phenotype. Our results offer a preclinical proof of concept for using MDSCs to facilitate and enhance the tumor-killing activity of tumor-targeted oncolytic therapeutics.Cancer Research 03/2013; · 7.86 Impact Factor -
Article: The potential of recombinant vesicular stomatitis virus-mediated virotherapy against metastatic colon cancer.
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ABSTRACT: Colorectal cancer (CRC) is the fourth most frequently diagnosed cancer and the second leading cause of cancer-related mortality in the United States. The liver and lung are the most common sites of distant metastasis of CRC. The approval of newer chemotherapeutic agents such as oxaliplatin, irinotecan, bevacizumab, cetuximab and panitumumab has significantly improved survival, yet the majority of patients still succumb to the disease in less than 2 years. Novel therapeutic agents that can provide significant clinical benefit for metastatic CRC patients are needed. Oncolytic vesicular stomatitis virus (VSV) is a promising tool as a cancer therapeutic agent. In this study, we examined the feasibility of repeated intravenous infusions of rVSV in multiple CRC lung metastases, compared with repeated hepatic arterial administration in multifocal CRC liver metastasis in immune competent rats. We established a multifocal liver metastases model or the multiple lung metastases model using a CRC cell line, RCN-H4, implanted into syngeneic F344/DuCrj rats. 4.0x106 plaque-forming units (pfu) of recombinant VSV vectors expressing mutant (L289A) Newcastle disease virus fusion protein [rVSV-NDV/F(L289A)] were administered 3 times for 3 consecutive days locally via the hepatic artery for liver metastases or systemically via the penial vein for lung metastases. In the liver metastasis model, significantly enhanced survival was observed with rVSV-NDV/F(L289A)-treated rats (P=0.0196). Median survival was 110 and 25 days, respectively. In addition, 4 out of 7 of the rVSV-NDV/F(L289A)-treated rats demonstrated long-term survival exceeding 100 days. The long-term surviving rats were sacrificed to evaluate for residual malignancy. Liver tumors were not detected. In the lung metastasis model, median survival was 10 [VSV-NDV/F(L289A)-treated rats] and 7 days (control). Although survival was significantly prolonged (P<0.001), none of the rats achieved long-term survival. VSV virotherapy has potential for CRC liver and lung metastases, although systemic venous delivery is much less effective than locoregional delivery such as hepatic arterial infusion.International Journal of Molecular Medicine 12/2012; · 1.98 Impact Factor
