Cell carriage, delivery, and selective replication of an oncolytic virus in tumor in patients.

Oncolytic viruses, which preferentially lyse cancer cells and stimulate an antitumor immune response, represent a promising approach to the treatment of cancer. However, how they evade the antiviral immune response and their selective delivery to, and replication in, tumor over normal tissue has not been investigated in humans. Here, we treated patients with a single cycle of intravenous reovirus before planned surgery to resect colorectal cancer metastases in the liver. Tracking the viral genome in the circulation showed that reovirus could be detected in plasma and blood mononuclear, granulocyte, and platelet cell compartments after infusion. Despite the presence of neutralizing antibodies before viral infusion in all patients, replication-competent reovirus that retained cytotoxicity was recovered from blood cells but not plasma, suggesting that transport by cells could protect virus for potential delivery to tumors. Analysis of surgical specimens demonstrated greater, preferential expression of reovirus protein in malignant cells compared to either tumor stroma or surrounding normal liver tissue. There was evidence of viral factories within tumor, and recovery of replicating virus from tumor (but not normal liver) was achieved in all four patients from whom fresh tissue was available. Hence, reovirus could be protected from neutralizing antibodies after systemic administration by immune cell carriage, which delivered reovirus to tumor. These findings suggest new preclinical and clinical scheduling and treatment combination strategies to enhance in vivo immune evasion and effective intravenous delivery of oncolytic viruses to patients in vivo.

JX-594, a targeted oncolytic poxvirus for the treatment of cancer.

JX-594 is a replication-competent Wyeth strain vaccinia virus that was genetically modified to inactive the endogenous thymidine kinase gene and to express human GM-CSF and LacZ genes. In development by Jennerex Inc and licensee Green Cross Corp, the modified virus is a novel therapy for treatment-refractive metastatic malignancies from various sites of origin. Targeted oncolytic virotherapy has demonstrated promise in preclinical studies, and more than ten viral species have subsequently entered clinical trials. JX-594 has been modified to augment the intrinsic targeting and oncolytic potential of the vaccinia virus and to enhance antitumor immunity by the expression of the GM-CSF transgene in situ. In vitro and in vivo animal studies have demonstrated the replication specificity of JX-594 for cancer cell lines and tumors, and the restriction of serum human GM-CSF expression to tumor-bearing animals, resulting in significantly reduced tumor burden and an increase in median survival. In phase I trials, JX-594 was well tolerated, with mild systemic toxicity reported. In a phase I trial in seven patients with melanoma, one partial response and one complete response after surgery were observed. In another phase I trial in patients with hepatic carcinoma, three out of ten evaluable patients had a partial response and six had stable disease; the MTD was also established. A phase II trial in patients (expected n = 30) with unresectable primary hepatocellular carcinoma was recruiting at the time of publication, with completion expected in March 2010, and a phase III trial in patients with hepatocellular carcinoma was planned for the second half of 2010. Further clinical investigations are needed to explore the potential of this agent as a single therapy and as part of multimodal treatment regimens.

Clinical grade OK432-activated dendritic cells: in vitro characterization and tracking during intralymphatic delivery.

Dendritic cells (DC) are under intense preclinical and early clinical evaluation for the immunotherapy of cancer. However, the optimal culture conditions and route of delivery for DC vaccination have not been established. Here we describe the first human application of DC matured with the bacterial agent OK432 (OK-DC), using a short-term serum-free culture protocol, which generates mature DC from CD14+ precursors after 5 days. These cells were prepared within the framework of a National Blood Service facility, demonstrating that DC represent a product which is potentially deliverable alongside current standardized cell therapies within the UK National Health Service. In vitro analysis confirmed that OK-DC were mature, secreted tumor necrosis factor-alpha, interleukin-6, and interleukin-12, and stimulated both T cell and natural killer cell function. To explore effective delivery of OK-DC to lymph nodes, we performed an initial clinical tracking study of radioactively labeled, unpulsed OK-DC after intralymphatic injection into the dorsum of the foot. We showed that injected DC rapidly localized to ipsilateral pelvic lymph nodes, but did not disseminate to more distant nodes over a 48-hour period. There was no significant toxicity associated with OK-DC delivery. These results show that OK-DC are suitable for clinical use, and that intralymphatic delivery is feasible for localizing cells to sites where optimal priming of innate and adaptive antitumor immunity is likely to occur.

The feasibility of establishing a programme of adjuvant autologous vaccination for renal cell carcinoma.

OBJECTIVE: To report the results of a programme aimed at determining the feasibility of autologous renal cell carcinoma (RCC) tissue collection and vaccine preparation within the setting of a UK National Health Service Cancer Centre. PATIENTS AND METHODS: Patients undergoing nephrectomy for suspected renal tumours were identified from theatre lists between April 2005 and July 2007. Samples of tumour were freshly cut from nephrectomy specimens. If tissue collection failed the reason was recorded prospectively. Cell viability was assessed after sample sieving. Freeze-thaw lysates were prepared from viable tumour cells, and the immunogenicity tested by pulsing onto dendritic cells (DC). RESULTS: Of 84 patients, 83 had a histological diagnosis of RCC; samples were obtained from 29 of these 83 (35%). Reasons for failure in tissue collection included that the tumour was too small or haemorrhagic/necrotic, pre-surgical embolization, and difficulties with fresh tumour collection out of normal working hours. Viable tumour cells were obtained in 12 of the 29 samples (41%); no factor was able to predict the production of viable cells. Unmodified lysates did not activate DC. CONCLUSION: An autologous RCC vaccination programme might fail to generate vaccines for a substantial proportion of eligible patients in the setting of a clinical cancer centre.

OK432-activated human dendritic cells kill tumor cells via CD40/CD40 ligand interactions.

In vivo, dendritic cells (DC) are programmed to orchestrate innate and adaptive immunity in response to pathogen-derived "danger" signals. Under particular circumstances, DC can also be directly cytotoxic against tumor cells, potentially allowing them to release tumor associated Ags from dying cells and then prime antitumor immunity against them. In this study, we describe the innate characteristics of DC (OK-DC) generated in vitro after exposure of immature human myeloid-derived DC to OK432, a penicillin-inactivated and lyophilized preparation of Streptococcus pyrogenes. OK-DC produced proinflammatory cytokines, stimulated autologous T cell proliferation and IFN-gamma secretion, expressed CCR7, and migrated in response to MIP-3beta. Moreover, OK-DC displayed strong, specific cytotoxicity toward tumor cell targets. This cytotoxicity was associated with novel, OK432-induced up-regulation of CD40L on the cell surface of OK-DC, and was absolutely dependent on expression of CD40 on the tumor targets. These data demonstrate that maturation of human DC with OK432, an adjuvant suitable for clinical use, induces direct tumor cell killing by DC, and describes a novel CD40/CD40L-mediated mechanism for specific DC antitumor cytotoxicity.

Optimization of dendritic cell loading with tumor cell lysates for cancer immunotherapy.

The immune response to cancer is critically determined by the way in which tumor cells die. As necrotic, stress-associated death can be associated with activation of antitumor immunity, whole tumor cell antigen loading strategies for dendritic cell (DC)-based vaccination have commonly used freeze-thaw "necrotic" lysates as an immunogenic source of tumor-associated antigens. In this study, the effect of such lysates on the ability of DCs to mature in response to well-established maturation stimuli was examined, and methods to enhance lysate-induced DC activation explored. Freeze-thaw lysates were prepared from murine tumor cell lines and their effects on bone marrow-derived DC maturation and function examined. Unmodified freeze-thaw tumor cell lysates inhibited the toll-like receptor-induced maturation and function of bone marrow-derived DCs, preventing up-regulation of CD40, CD86, and major histocompatibility complex class II, and reducing secretion of inflammatory cytokines [interleukin (IL)-12 p70, tumor necrosis factor-alpha, and IL-6]. Although IL-10 secretion was increased by lysate-pulsed DCs, this was not responsible for the observed suppression of IL-12. Although activation of the nuclear factor-kappaB pathway remained intact, the kinase activity of phosphorylated p38 mitogen-activated protein kinase was inhibited in lysate-pulsed DCs. Lysate-induced DC suppression was partially reversed in vitro by induction of tumor cell stress before lysis, and only DCs loaded with stressed lysates afforded protection against tumor challenge in vivo. These data suggest that ex vivo freeze-thaw of tumor cells does not effectively mimic in vivo immunogenic necrosis, and advocates careful characterization and optimization of tumor cell-derived vaccine sources for cancer immunotherapy.

Autologous versus allogeneic peptide-pulsed dendritic cells for anti-tumour vaccination: expression of allogeneic MHC supports activation of antigen specific T cells, but impairs early naïve cytotoxic priming and anti-tumour therapy.

BACKGROUND: Dendritic cells (DC) pulsed with MHC class I-restricted tumour associated antigen (TAA) peptides have been widely tested in pre-clinical models and early clinical studies for their ability to prime cytotoxic T cell (CTL) responses. The effect of co-expression of allogeneic MHC antigens on DC immunogenicity has not been addressed, and has implications for the feasibility of clinical applications. OBJECTIVE: This study compared DC from autologous H-2(b) or semi-allogeneic F1 H-2(bxk) mice pulsed with the H-2(b)-restricted model ovalbumin (OVA) peptide SIINFEKL, and compared in vitro and in vivo their ability to (i) activate specific OT1 cells, (ii) prime naïve CTL, and (iii) protect against B16.OVA challenge. Peptide-pulsed autologous and allogeneic DC were also tested in naïve human CTL priming assays. RESULTS: Semi-allogeneic DC expressed higher levels of co-stimulatory molecules. On pulsing with SIINFEKL they triggered greater proliferation of OT1 cells in vitro and in vivo, but were less effective at naïve CTL priming and tumour protection. Autologous human DC were similarly more potent at naïve CTL priming against the melanoma-associated TAA MART-1 in vitro. CONCLUSION: The expression of allogeneic MHC antigens on peptide-pulsed DC impairs naïve CTL priming and anti-tumour effects, despite effective TAA presentation both in vitro and in vivo.

CD40-mediated death and cytokine secretion in colorectal cancer: a potential target for inflammatory tumour cell killing.

CD40, a member of the tumour necrosis factor family, is expressed in a variety of epithelial cells. Although soluble CD40 agonists are growth-inhibitory, membrane-presented CD40 ligand (CD40L) induces extensive apoptosis in carcinoma cells. This study investigated whether CD40 is expressed in human colorectal carcinoma (CRC) cells and explored the functional consequences of CD40 ligation. CD40 expression in a panel of CRC lines was assessed by flow cytometry and in resected human CRCs by immunohistochemistry. CRC cells were treated in vitro with soluble CD40 agonists or cocultured with fibroblasts expressing membrane-bound CD40 ligand. Apoptosis was determined by flow cytometry using Annexin V/propidium iodide labelling and by a DNA fragmentation assay. Cytokine secretion induced by CD40 ligation was quantified by a multiplex-bead array approach. We show that CD40 is expressed in a proportion of established CRC lines in culture and that receptor expression is functional. Activation of CD40 by membrane-presented CD40L, but not soluble agonists, causes high levels of death in CD40-positive CRC cells and induces secretion of proinflammatory cytokines. In agreement with our in vitro observations, immunohistochemical studies demonstrated that CD40 is highly expressed in a proportion of colorectal cancer specimens. The high level of susceptibility of CRC cells to CD40-killing combined with the ability of CD40 to induce concomitant secretion of proinflammatory cytokines suggest that CD40 ligation may represent a novel mechanism for elimination of CRC cells and render CD40 a promising therapeutic target for the eradication of colorectal tumours.

Allogeneic tumor cells expressing fusogenic membrane glycoproteins as a platform for clinical cancer immunotherapy.

PURPOSE: Fusogenic membrane glycoproteins (FMG), such as the vesicular stomatitis virus G glycoprotein (VSV-G), represent a new class of gene therapy for cancer that cause cytotoxic fusion on expression in tumor cells. In addition, FMG-mediated tumor cell death stimulates antitumor immunity, suggesting potential applications for FMG-expressing cellular vaccines. This study addresses the promise of FMG-expressing allogeneic tumor cells, which are most practical for clinical use, as a novel platform for ex vivo and in situ vaccination. EXPERIMENTAL DESIGN: Murine B16 melanoma-derived cell lines expressing autologous or allogeneic MHC class I, expressing fusogenic or nonfusogenic VSV-G, were used to vaccinate mice in vivo against a live tumor challenge. Exosome-like vesicles released by fusing allogeneic cells (syncitiosomes) and intratumoral injection of fusing vaccines were also tested as novel therapeutic strategies for their antitumor effects. RESULTS: Expression of fusogenic VSV-G enhanced the immunogenicity of an allogeneic cellular vaccine, which was more effective than a fusing autologous vaccine. Allogeneic syncitiosomes were only as effective as cellular vaccines when administered with adjuvant, demonstrating that syncitiosomes cannot account entirely for the mechanism of immune priming. Intratumoral injection of FMG-expressing allogeneic cells led to significant tumor regression using both fusogenic or nonfusogenic VSV-G. However, specific priming against tumor-associated antigenic epitopes and protection against secondary rechallenge only occurred if the initial vaccine was competent for cell fusion. CONCLUSIONS: FMG-expressing allogeneic tumor cells are a potent source of antitumor vaccines. Syncitiosomes given with adjuvant and intratumoral injection of fusing cells represent novel strategies well-suited to clinical translation.