Leeladhar Sammatur

First-in-man application of a novel therapeutic cancer vaccine formulation with the capacity to induce multi-functional T cell responses in ovarian, breast and prostate cancer patients

BackgroundDepoVaxTM is a novel non-emulsion depot-forming vaccine platform with the capacity to significantly enhance the immunogenicity of peptide cancer antigens. Naturally processed HLA-A2 restricted peptides presented by breast, ovarian and prostate cancer cells were used as antigens to create a therapeutic cancer vaccine, DPX-0907.MethodsA phase I clinical study was designed to examine the safety and immune activating potential of DPX-0907 in advanced stage breast, ovarian and prostate cancer patients. A total of 23 late stage cancer patients were recruited and were divided into two dose/volume cohorts in a three immunization protocol.ResultsDPX-0907 was shown to be safe with injection site reactions being the most commonly reported adverse event. All breast cancer patients (3/3), most of ovarian (5/6) and one third of prostate (3/9) cancer patients exhibited detectable immune responses, resulting in a 61% immunological response rate. Immune responses were generally observed in patients with better disease control after their last prior treatment. Antigen-specific responses were detected in 73% of immune responders (44% of evaluable patients) after the first vaccination. In 83% of immune responders (50% of evaluable patients), peptide-specific T cell responses were detected at ≥2 time points post vaccination with 64% of the responders (39% of evaluable patients) showing evidence of immune persistence. Immune monitoring also demonstrated the generation of antigen-specific T cell memory with the ability to secrete multiple Type 1 cytokines.ConclusionsThe novel DepoVax formulation promotes multifunctional effector memory responses to peptide-based tumor associated antigens. The data supports the capacity of DPX-0907 to elicit Type-1 biased immune responses, warranting further clinical development of the vaccine. This study underscores the importance of applying vaccines in clinical settings in which patients are more likely to be immune competent.Trial RegistrationClinicalTrials.gov NCT01095848

Survivin-targeted immunotherapy drives robust polyfunctional T cell generation and differentiation in advanced ovarian cancer patients

DepoVax™ is an innovative and strongly immunogenic vaccine platform. Survivin is highly expressed in many tumor types and has reported prognostic value. To generate tumor-specific immune response, a novel cancer vaccine was formulated in DepoVax platform (DPX-Survivac) using survivin HLA class I peptides. Safety and immune potency of DPX-Survivac was tested in combination with immune-modulator metronomic cyclophosphamide in ovarian cancer patients. All the patients receiving the therapy produced antigen-specific immune responses; higher dose vaccine and cyclophosphamide treatment generating significantly higher magnitude responses. Strong T cell responses were associated with differentiation of naïve T cells into central/effector memory (CM/EM) and late differentiated (LD) polyfunctional antigen-specific CD4+ and CD8+ T cells. This approach enabled rapid de novo activation/expansion of vaccine antigen-specific CD8+ T cells and provided a strong rationale for further testing to determine clinical benefits associated with this immune activation. These data represent vaccine-induced T cell activation in a clinical setting to a self-tumor antigen previously described only in animal models.

A novel breast/ovarian cancer peptide vaccine platform that promotes specific type-1 but not Treg/Tr1-type responses.

In light of lack of efficacy associated with current cancer vaccines, we aimed to develop a novel vaccine platform called DepoVax as a therapeutic vaccine for breast/ovarian cancer. This study was designed to examine the efficacy of this novel platform over conventional emulsion vaccine using human class I MHC transgenic mice. We have developed a water-free depot vaccine formulation (DPX-0907) with high immune activating potential. Naturally processed peptides bound to HLA-A2 molecules isolated from independent breast and ovarian tumor cell lines, but not normal cells, were isolated and used as antigens in DPX-0907 along with a proprietary adjuvant and a T helper peptide epitope. Efficacy of vaccine was tested in immunized HLA-A*0201/H2Dd transgenic mice by measuring the frequency of IFN-γ secreting cells in the draining lymph nodes, and regulatory T-cell frequencies in the spleen. Compared with a water-in-oil emulsion vaccine, DPX-0907 enhanced IFN-γ+CD8+ T cells in vaccine site-draining lymph nodes, as seen by immunofluorescence staining and increased the frequency of IFN-γ+ lymph node cells as seen by enzyme-linked immunosorbent spot assay. Notably, while conventional vaccine formulations elicited elevated levels of splenic Foxp3+CD4+ and IL10-secreting T cells, this was not the case for DPX-0907-based vaccines, with treated animals exhibiting normal levels of regulatory T cells. These data support the unique capabilities of a vaccine formulation containing novel tumor peptides and DPX-0907 to elicit type-1 dominated, specific immunity that may represent a potent clinical therapeutic modality for patients with breast or ovarian carcinoma.

Efficacy of a single dose hepatitis B depot vaccine.

A single dose formulation of a novel hepatitis B vaccine, consisting of an adjuvant emulsion of liposomes in oil was produced at a manufacturing scale and delivered to rabbits. This single dose vaccine generated a significantly higher antibody response than two doses of an alum-adjuvanted control vaccine in the short term, and was as effective as three doses of the control vaccine in the long term.

Development and validation of an HPLC/UV assay for separation and quantification of peptide antigens from a liposomal vaccine delivery platform

The development and validation of an HPLC method for the quantification of eight peptide antigens from the therapeutic cancer vaccine DPX-0907 is described. The antigens were formulated in DepoVax™, a patented liposomal vaccine delivery platform used in a phase 1 study for breast, ovarian, and prostate cancers. A gradient reversed-phase method with UV detection was optimized for separating and quantifying the peptide mixture. Several extraction methods investigated to extract the peptides from the lipids led to poor recovery of one or more of the peptides. A simple, reproducible, and high-recovery extraction procedure for the simultaneous quantification of hydrophilic and hydrophobic peptides was discovered using a liquid-liquid extraction with water-saturated n-butanol and sodium bicarbonate (0.1 M). The method was found to be specific, linear, accurate, precise, and reliable within the range of 50-150% of the nominal concentration for DPX-0907. The validated method was successfully applied to the assay of peptide content in pre-clinical and clinical batches of DPX-0907.