Immunotransplant
Encyclopedia
Immunotransplant is a maneuver used to make vaccines more powerful. It refers to the process of infusing vaccine-primed T lymphocytes into lymphodepleted recipients for the purpose of enhancing the proliferation and function of those T cells and increasing immune protection induced by that vaccine.
The concept takes advantage of data from animal and studies in vaccinology and the homeostasis of T cells and has applications in the treatment of infectious disease, immunodeficiency syndromes, and cancer.
A number of pre-clinical and clinical studies have demonstrated that vaccines against pathogens, bystander (non-pathogenic) proteins, tumor-associated antigens, or whole tumor cells, can induce specific T-cell mediated immune responses. A number of approaches have been considered to amplify T cell mediated immune responses(e.g. IL-2, CTLA-4, IL-7, CD137), and some of these have shown clinical efficacy in eliminating particular types of cancer, most notably melanoma and renal cell carcinoma.
To expand this immunotransplant concept to the amplification of anti-cancer immunity, researchers at Stanford University developed a pre-clinical lymphoma model using a in situ, CpG-base vaccine to induce anti-tumor immunity and demonstrated that this immunity was enhanced 10-40 fold by immunotransplant. The above studies by Levitsky et al., were an important precedent for this work. In fact the Hopkins published preliminary results of a clinical study testing the basic immunotransplant concept in acute myeloid leukemia demonstrating encouraging signals of enhanced anti-tumor immunity. To continue the clinical translation of this approach, in August 2009 the Stanford group initiated a phase I/II clinical trial for patients with newly diagnosed mantle cell lymphoma
. That study uses a whole-cell, CpG-activated, autologous tumor vaccine to induce anti-tumor immunity followed by leukapheresis and re-infusion of the vaccine-primed cells immediately after standard autologous transplant. Initial results of this study were presented at the ASCO 2011 Annual Meeting showing successful data towards the primary endpoint: amplification of anti-tumor T-cell responses.
The concept takes advantage of data from animal and studies in vaccinology and the homeostasis of T cells and has applications in the treatment of infectious disease, immunodeficiency syndromes, and cancer.
Vaccines
Historically, the effect of vaccines -particularly against pathogens- has been assessed by measurement of their induction of a B-cell-mediated -or humoral- immune response, i.e. the production of pathogen-specific antibodies. In the study of both infectious diseases and cancer, a majority of potential immune targets are only expressed intra-cellularly, and are thus inaccessible to antibody-mediated elimination. T-cell mediated immunity, by contrast, has the potential to recognize targets expressed either extra- or intra-cellularly and has therefore been studied extensively for treatment of these diseases.A number of pre-clinical and clinical studies have demonstrated that vaccines against pathogens, bystander (non-pathogenic) proteins, tumor-associated antigens, or whole tumor cells, can induce specific T-cell mediated immune responses. A number of approaches have been considered to amplify T cell mediated immune responses(e.g. IL-2, CTLA-4, IL-7, CD137), and some of these have shown clinical efficacy in eliminating particular types of cancer, most notably melanoma and renal cell carcinoma.
T-Cell Homeostasis and Homeostatic Proliferation
The use of immunotransplant to enhance T cell-mediated immune responses, derive from studies of T cell homeostasis. The total cohort of T cells in an organism maintain homeostasis – a consistent total number of T cells in the peripheral blood. Transient elevations in peripheral blood T cell counts cause the whole population to diminish, transient depletions cause the whole population to proliferate, generally maintaining a roughly total T cell count. The latter situation –lymphodepletion– has been studied extensively and the proliferation of mature T cells upon transfer into the lymphopenic host is referred to as “lymphodepletion-induced” or “homeostatic” proliferation. It has been shown that homeostatic proliferation induces not only quantitative changes in T cell cohorts, but qualitative changes as well, such as increased function and the development of a memory-cell phenotype. The mechanism of these changes has been shown to be primarily due to upregulation of a group of cytokines including IL-7 and IL-15 induced by lymphodepletion. Additionally, lymphodepletion is a non-selective method of eliminating several known regulatory, or immunosuppressive, subsets of immune cells, such as regulatory T cells.Clinical Trials Of T-Cell Adoptive Transfer
These observations have prompted several clinical studies of infusing pathogen- or tumor-specific T cells into lymphodepleted patients. A group at the National Cancer Institute demonstrated remarkable efficacy by infusing melanoma-specific T cells (obtained by growing tumor-infiltrating T cells ex vivo) into melanoma patients treated with lymphodepleting chemotherapy. In a series of studies of this approach, up to 70% of treated patients were shown to have regressions of their tumors, many of which had been considerable in size and refractory to other therapies. These findings compare favorably with standard-of-care therapies for melanoma which generally lead to tumor regressions in only ~10-12% of patients.Pre-Clinical Studies And Clinical Trials Of Vaccine-Primed T-Cell Adoptive Transfer (I.E. Immunotransplant)
Because of the logistic difficulty of obtaining tumor-specific T cells via the ex vivo expansion of tumor-infiltrating cells, a number of studies have examined inducing these cells in vivo by vaccination. Levitsky et al., at John Hopkins, in a series of pre-clinical studies demonstrated that vaccine-induced T cells could be considerably more effective when re-infused into lymphodepleted recipients. Subsequently, a clinical study in patients with multiple myeloma conducted by June et al, demonstrated that a standard vaccination against pneumonia could induce a T-cell-mediated response to the vaccine and that re-infusing these T cells after an extremely lymphodepletive therapy –autologous stem cell transplant – could significantly enhance that response.To expand this immunotransplant concept to the amplification of anti-cancer immunity, researchers at Stanford University developed a pre-clinical lymphoma model using a in situ, CpG-base vaccine to induce anti-tumor immunity and demonstrated that this immunity was enhanced 10-40 fold by immunotransplant. The above studies by Levitsky et al., were an important precedent for this work. In fact the Hopkins published preliminary results of a clinical study testing the basic immunotransplant concept in acute myeloid leukemia demonstrating encouraging signals of enhanced anti-tumor immunity. To continue the clinical translation of this approach, in August 2009 the Stanford group initiated a phase I/II clinical trial for patients with newly diagnosed mantle cell lymphoma
Mantle cell lymphoma
Mantle cell lymphoma is one of the rarest of the non-Hodgkin's lymphomas , comprising about 6% of NHL cases. There are only about 15,000 patients presently in the U.S. While it is difficult to treat and seldom considered cured, investigations into better treatments are actively pursued worldwide...
. That study uses a whole-cell, CpG-activated, autologous tumor vaccine to induce anti-tumor immunity followed by leukapheresis and re-infusion of the vaccine-primed cells immediately after standard autologous transplant. Initial results of this study were presented at the ASCO 2011 Annual Meeting showing successful data towards the primary endpoint: amplification of anti-tumor T-cell responses.