Cancer Vaccine Clinical Trials Research Articles

The Consequence of Immune Suppressive Cells in the Use of Therapeutic Cancer Vaccines and Their Importance in Immune Monitoring

Evaluating the number, phenotypic characteristics, and function of immunosuppressive cells in the tumor microenvironment and peripheral blood could elucidate the antitumor immune response and provide information to evaluate the efficacy of cancer vaccines. Further studies are needed to evaluate the correlation between changes in immunosuppressive cells and clinical outcomes of patients in cancer vaccine clinical trials. This paper focuses on the role of T-regulatory cells, myeloid-derived suppressor cells, and tumor-associated macrophages in cancer and cancer immunotherapy and their role in immune monitoring.

Prevention is Better Than Cure: The Case for Clinical Trials of Therapeutic Cancer Vaccines in the Prophylactic Setting

Tumor cells frequently express antigens that allow them to be specifically targeted and destroyed by the immune system. Many tumor immunotherapy clinical trials have been conducted, directed at several types of cancer using myriad antigens and multiple immunization strategies. Despite this, only one therapeutic cancer vaccine, sipuleucel-T, has been approved. A groundbreaking study by Jaini et al. recently demonstrated that prophylactic immunization against a breast cancer associated antigen can prevent tumor development, and is far more effective than therapeutic vaccination. This study highlights the urgent need to rethink the clinical testing of tumor immunotherapies; it is time to consider clinical trials of cancer vaccines in the prophylactic setting.

Gene Signature in Melanoma Associated With Clinical Activity

Immunotherapeutic approaches for melanoma and other cancers can impart profound clinical benefit but only for a subset of patients. Interpatient heterogeneity could, in principle, be due to somatic differences in the tumor between individuals or alternatively be accounted for distinct germline polymorphisms in immunoregulatory genes of the host. Analysis of these possibilities has been initiated by investigating gene expression profiling of the tumor microenvironment in the context of clinical trials of cancer vaccines. Distinct gene expression profiles have been identified on pretreatment biopsies that are associated with a positive or negative clinical outcome. These observations suggest that such profiling might be useful as a predictive biomarker for clinical benefit from vaccines and other immunotherapy approaches, and analysis of specific gene products has begun to suggest new therapeutic interventions to overcome mechanisms of tumor resistance.

Clinical and laboratory parameters associated with outcomes in patients with metastatic renal cell carcinoma treated with modified vaccinia Ankara delivering tumor antigen 5T4.

e13132 Background: Two separate studies have been conducted to study the efficacy of modified vaccinia Ankara delivering tumor antigen 5T4 (TroVax) alone, in combination with either interleukin-2 or interferon-α totaling 53 patients (Clin Cancer Res 2008; 14[22], J Immunother 2009; 32[7]). We will review the overall survival of this patient population of <12 months, >12 months and >24 months and provide correlation with their baseline clinical and laboratory parameters. Methods: We have reviewed baseline data of 53 patients. The entire baseline laboratory parameters were assessed. Clinical data such as pathology, diagnosed to initial therapy with TroVax, time of metastases development, the number of metastatic lesions and performance status. Both univariate and multivariate analyses were conducted. Results: Analysis of the data revealed the diagnosed time to start interval of therapy, metastasis to interval of receiving TroVax, the number of metastatic lesions, decreased leucocyte count, decreased platelet count, increased hemoglobin, decreased neutrophils, increased absolute lymphocyte, decreased corrected calcium, decreased lactate dehydrogenase, decreased albumin and decreased alkaline phosphatase correlated to overall survival. Conclusions: Results identify a specific subset of metastatic renal cell carcinoma patients with a favorable outcome based on clinical and laboratory parameters. These results can be applied as inclusion/exclusion criteria for prospective TroVax studies in addition to other cancer vaccine clinical trials. Author Disclosure Employment or Leadership Position Consultant or Advisory Role Stock Ownership Honoraria Research Funding Expert Testimony Other Remuneration Oxford BioMedica Oxford BioMedica

Abstract LB-329: Defining rgulatory T-cells as CD4+CD25hiCD127- or as CD4+CD25hiFoxP3+ in immune monitoring of cancer vaccine clinical trials

Abstract Background: Regulatory T cells (Treg) are widely accepted to play a key role in the immune tolerance and escape of cancer cells. Originally Tregs were identified as being CD4+ T cells expressing high levels of CD25 (IL2 receptor). The identification of the transcription factor FoxP3 resulted in defining Tregs as CD4CD25hiFoxP3+ T cells by staining permeablized cells. Recently Tregs have been identified as CD4CD25hi T cells with low levels of CD127 (IL7 receptor) expressing a CD4+CD25hiCD127- cell surface phenotype. In an ongoing clinical trial with a MHC class II HER2/neu pep tide vaccine we have evaluated these various definitions of Treg phenotypes for immunological monitoring. Methods: Tregs were quantified in disease-free, high risk BCa patients enrolled in adjuvant peptide-based breast cancer vaccine trials. Peripheral blood mononuclear cells (PBMCs) were both permeabilized and stained with CD4, CD25, and FoxP3 monoclonal antibodies and surface stained with CD4, CD25, and CD127. Samples were then analyzed by flow cytometry. The means are compared with t-test and correlation is determined with Pearson's correlation coefficient. Results: 196 PBMC samples from 72 patients were available for Treg quantification. There was a greater mean percentage of cells identified as Treg in permeabilized than nonpermeabilized cells by staining with CD4+CD25hi (5.9±0.1% vs 4.8 ±0.1%, p&amp;lt;0.01) and excellent correlation between the tests (r=0.78, p&amp;lt;0.01). There was a greater mean percentage of cells identified as Tregs by CD4+CD25hi than CD4+CD25hiFoxP3+ (5.9±0.1% vs 3.6±0.1%, p&amp;lt;0.01) with good correlation (r=0.68, p&amp;lt;0.01). There was a greater mean percentage of Tregs by CD4+CD25+ than CD4+CD25+CD127- (4.8±0.1 vs 4.0±0.1, p&amp;lt;0.01) with excellent correlation (r=0.89, p&amp;lt;0.01). There was a greater mean percentage of Tregs by CD4+CD25hiCD127- than Tregs by CD4+ CD25hiFoxP3+ although levels were similar (4.0±0.1 vs 3.6±0.1, p&amp;lt;0.01) and the two tests had good correlation (r=0.58, p&amp;lt;0.01). Conclusion: There was good correlation between various methods of defining Tregs with and without cell membrane permeabilization. Defining Treg cells as either CD4+CD25hiFoxP3+ or CD4+CD25+CD127- appear to be more specific than defining Tregs as CD4+CD25hi alone. Furthermore, defining Treg populations by surface staining as CD4+CD25hiCD127- yields similar levels with good correlation as CD4+CD25hiFoxP3+ and may be the preferred method for immune monitoring. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr LB-329.

Design and synthesis of potent Quillaja saponin vaccine adjuvants.

The success of antitumor and antiviral vaccines often requires the use of an adjuvant, a substance that significantly enhances the immune response to a coadministered antigen. Only a handful of adjuvants have both sufficient potency and acceptable toxicity for clinical investigation. One promising adjuvant is QS-21, a saponin natural product that is the immunopotentiator of choice in many cancer and infectious disease vaccine clinical trials. However, the therapeutic promise of QS-21 adjuvant is curtailed by several factors, including its scarcity, difficulty in purification to homogeneity, dose-limiting toxicity, and chemical instability. Here, we report the design, synthesis, and evaluation of chemically stable synthetic saponins. These novel, amide-modified, non-natural substances exhibit immunopotentiating effects in vivo that rival or exceed that of QS-21 in evaluations with the GD3-KLH melanoma conjugate vaccine. The highly convergent synthetic preparation of these novel saponins establishes new avenues for discovering improved molecular adjuvants for specifically tailored vaccine therapies.

Strategies for Cancer Vaccine Development

Treating cancer with vaccines has been a challenging field of investigation since the 1950s. Over the years, the lack of effective active immunotherapies has led to the development of numerous novel strategies. However, the use of therapeutic cancer vaccines may be on the verge of becoming an effective modality. Recent phase II/III clinical trials have achieved hopeful results in terms of overall survival. Yet despite these encouraging successes, in general, very little is known about the basic immunological mechanisms involved in vaccine immunotherapy. Gaining a better understanding of the mechanisms that govern the specific immune responses (i.e., cytotoxic T lymphocytes, CD4 T helper cells, T regulatory cells, cells of innate immunity, tumor escape mechanisms) elicited by each of the various vaccine platforms should be a concern of cancer vaccine clinical trials, along with clinical benefits. This review focuses on current strategies employed by recent clinical trials of therapeutic cancer vaccines and analyzes them both clinically and immunologically.

Partial CD4 Depletion Reduces Regulatory T Cells Induced by Multiple Vaccinations and Restores Therapeutic Efficacy

A single vaccination of intact or reconstituted-lymphopenic mice (RLM) with a granulocyte macrophage colony-stimulating factor-secreting B16BL6-D5 melanoma cell line induces protective antitumor immunity and T cells that mediate the regression of established melanoma in adoptive immunotherapy studies. We wanted to study if multiple vaccinations during immune reconstitution of the lymphopenic host would maintain a potent antitumor immune response. RLM were vaccinated multiple times over a 40-day period. Spleens were isolated from these mice, activated in vitro, and adoptively transferred into mice bearing 3-day experimental pulmonary metastases. Multiple vaccinations, rather than boosting the immune response, significantly reduced therapeutic efficacy of adoptive immunotherapy and were associated with an increased frequency and absolute number of CD3+CD4+Foxp3+ T regulatory (T(reg)) cells. Anti-CD4 administration reduced the absolute number of T(reg) cells 9-fold. Effector T-cells generated from anti-CD4-treated mice were significantly (P < 0.0001) more therapeutic in adoptive transfer studies than T cells from multiply vaccinated animals with a full complement of CD4+ cells. These results suggest that CD4+ T(reg) cells limit the efficacy of multiple vaccinations and that timed partial depletion of CD4+ T cells may reduce suppression and "tip-the-balance" in favor of therapeutic antitumor immunity. The recent failure of large phase III cancer vaccine clinical trials, wherein patients received multiple vaccines, underscores the potential clinical relevance of these findings.

Paradigm Shifts in Cancer Vaccine Therapy

Cancer vaccines constitute a unique therapeutic modality in that they initiate a dynamic process involving the host's immune response. Consequently, (a) repeated doses (vaccinations) over months may be required before patient clinical benefit is observed and (b) there most likely will be a "dynamic balance" between the induction and maintenance of host immune response elements to the vaccinations vs. host/tumor factors that have the potential to diminish those responses. Thus "patient response" in the form of disease stabilization and prolonged survival may be more appropriate to monitor than strictly adhering to "tumor response" in the form of Response Criteria In Solid Tumors (RECIST) criteria. This can be manifested in the form of enhanced patient benefit to subsequent therapies following vaccine therapy. This article will review these phenomena unique to cancer vaccines with emphasis on prostate cancer vaccines as a prototype for vaccine therapy. The unique features of this modality require the consideration of paradigm shifts both in the way cancer vaccine clinical trials are designed and in the way patient benefit is evaluated.

Analysis of Immunological and Clinical Response Kinetics to WT1 Peptide Vaccine in Patients with AML and MDS: Need for Supplementation of IWG Response Criteria?.

Background: Current habits in clinical trial design rightfully require patients to go off protocol in case of early disease progression to protect them from further exposure to ineffective treatments. This policy may not be adequate for leukemia vaccines as an effective clinical response would require an initial time interval to induce immunity, which can be expected to take several weeks.Methods: We here correlated immunological and clinical response kinetics from patients treated with WT1 peptide-based vaccine within a clinical phase II study. Patients received intra/subcutaneous vaccinations of 62.5 mcg GM-CSF days 1–4 and on day 3 0.2 mg WT1.126–134 peptide and 1 mg keyhole limpet hemocyanin. Vaccination was biweekly x 4 followed by 4-weekly (cohort 1) or continuously biweekly (cohort 2). Early disease progression was allowed, if inclusion criteria were still met and chemotherapy not required. WT1-specific T cell responses were measured by tetramer and cytokine flow cytometry. Clinical response assessment followed IWG-MDS criteria, capturing stable disease and hematologic improvement. In patients responding following initial progression, the date for calculation of TTF remained the starting date of therapy, whereas response duration was calculated as usual from the date the response was first noted.Results: Of 26 evaluable pts 18 had active disease at time of enrollment, additional 8 patients had high-risk CR. The percentage of patients with WT1 tetramer response continuously increased from 28% prior to vaccination to 60% at week 4, 76% at week 10, and 79% at week 18 (p<0.01) and to 100% in the 6 patients reaching week 42 of protocol treatment. WT1 peptide specific cytokine response increased from 19% pre-vaccine to 48% of patients at week 10 (p=0.05). According to strict IWG criteria, 9 SD (53%) were observed. However, if initial disease progression was accepted, one patient was re-classified as CR lasting 12 months after initial progression for 42 days and a total of 13 patients were classified as SD. Duration of early progression ranged from 35–70 days, median 42 days. There was no stabilization of disease observed in any patient with early progression beyond 10 weeks. Thus, kinetics of early disease progression and subsequent clinical efficacy of vaccination matched kinetics of induction of T cell responses.Conclusions: The additional clinical efficacy of vaccination observed after initial disease progression in five of our patients including the long-lasting CR support the concept of continuing treatment through early disease progression with a vaccine causing minimal toxicity, if continuation does not disadvantage the patient. Acknowledgment of early disease progression with subsequent efficacy requires amendment of current rules for cancer vaccine clinical trials with respect to patient management as well as evaluation of outcome.

Enhanced immune responses to an adenovirus CEA vaccine in CD4+CD25+ regulatory T-cell inactivated mice

Evaluation of: Elia L, Aurisicchio L, Facciabene A et al. CD4+CD25+ regulatory T-cell inactivation in combination with adenovirus vaccines enhances T-cell responses and protects mice from tumor challenge. Cancer Gene Ther. DOI: 10.1038/sj.cgt.7701004 (2006) (Epub ahead of print).Numerous cancer vaccine clinical trials have been carried out using various antigen-delivery systems and adjuvants. However, the therapeutic outcomes in patients have been minimal. There are numerous reasons for this and one of the current hypotheses is the inhibitory effects of regulatory T cells (Treg) on T-cell effectors. Since most tumor antigens are self antigens, antitumor responses to these antigens are dampened by Treg that are present to prevent autoreactive T cells from damaging healthy tissue. The paper by Elia and colleagues describes an alternative strategy to overcome the suppressive effects of Treg cells and generate enhanced cellular responses.

Molecular Targeting With Cancer Vaccines

The last decade has resulted in the identification of a multitude of tumor-associated antigens and the initiation of clinical trials to determine whether cancer patients can be vaccinated. In this issue, Carbone et al present an extensive analysis of the immunogenicity and potential clinical efficacy of vaccinating advanced-stage cancer patients against specific K-ras and p53 mutations present in their tumors. This report provides long-term follow-up after vaccination over a period of several years, so the length of time between initiation and publication of the trial allows evaluation of the data in the context of the evolution of more refined methods of vaccination. The authors also present data detailing the pitfalls of the clinical application of targeted therapy, which includes the need to evaluate large numbers of patients to find the few patients who may derive therapeutic benefit. Finally, the authors demonstrate an intriguing association between the development of an antigen-specific immune response and prolonged survival. The vaccination strategy used in the trial was to incubate mutated K-ras and p53 peptide sequences with peripheral-blood mononuclear cells obtained from each patient. Presumably, antigen-presenting cells present in the peripheral blood would uptake K-ras and p53 peptides, process the peptides, and present the fragments in the context of class I major histocompatibility complex molecules, resulting in the stimulation of antigen-specific cytotoxic CD8 T cells. It has only been in the last decade that clinical trials of cancer vaccines have been able to demonstrate any reproducible and detectable antigen-specific immunity resulting from such immunizations. As in the initial studies of this approach, Carbone et al describe low to moderate peptide-specific T-cell immunity developing in a minority of patients. Subsequent to the initiation of this trial, more potent antigen-presenting cells have been identified, such as dendritic cells. Over the last several years, methods have been developed to purify dendritic cells from the peripheral blood and to use them clinically to present tumor antigens to T cells. Methods continue to evolve to optimize the efficacy of dendritic cell vaccines. Potentially, the use of such professional antigen-presenting cells could increase the number of patients able to develop immune responses after vaccination. The authors also describe the lack of immunogenicity of vaccination in patients with rapidly progressing diseases such as pancreatic cancer. Findings such as this have resulted in a re-evaluation of the clinical application of cancer vaccines. Most cancer vaccine trials now focus on immunization in the adjuvant setting, aiming to prevent cancer relapse rather than to treat measurable disease. Even the most potent infectious disease vaccines are generally not used for treating established infections; likewise, cancer vaccines may have greatest benefit in the management of micrometastatic disease or even in the prevention of cancer in high-risk populations. The explosion in the identification of tumor antigens was fueled by advances in molecular technology and immunology. Similarly, the identification of molecular targets that affect growth pathways in cancer has resulted in the generation of novel and promising cancer therapies. Data presented by Carbone et al underscore the need to develop rapid and inexpensive methods to screen patients for genetic alterations that may predict clinical efficacy of novel reagents. The authors evaluated nearly 300 patients to find the 14% of individuals whose tumors contained the appropriate mutations and were eligible for enrollment by clinical criteria. Recent studies with other forms of targeted cancer therapy, such as gefitinib in the treatment of lung cancer, highlight the need to choose patients most likely to respond to intervention, as Carbone et al did in this clinical trial. It is frustrating to refer patients for screening for such trials only to find out that they are ineligible for a particular therapy. However, studies such as this demonstrate that there is a need for persistence to define the utility of a promising approach. Hopefully, more rapid clinical successes resulting from early-stage studies enrolling only the most appropriate patient populations will facilitate the entry of novel agents into clinical practice. The most provocative aspect of the trial is the association of a specific type of immune response with prolonged JOURNAL OF CLINICAL ONCOLOGY E D I T O R I A L VOLUME 23 NUMBER 22 AUGUST 1 2005

Enumerating Antigen-Specific T-Cell Responses in Peripheral Blood

Detection of the circulating antigen-specific T-cell response to immunization is an important biologic end point in clinical trials of cancer vaccines. Typically employed assays are peptide MHC tetramer, ELISpot, and intracellular cytokine analysis. Although there is no agreement on the definition of a positive response in these assays, many groups have chosen a number of T cells greater than 2 standard deviations above the mean of the negative controls. The authors wished to determine how well this cutoff performed for each of these assays in detecting positive and negative T-cell responses to a model antigen, the immunodominant HLA-A*0201-restricted epitope of cytomegalovirus (CMV) pp65. For each assay, the mean + 2 standard deviations of the response for CMV seronegatives was the point that best separated the two groups. Using this value, each assay had a sensitivity of 87.5% and specificity of 95% to 100% and exhibited a high degree of concordance (kappa 0.76-0.9) with the other two. The authors conclude that currently available immunologic assays perform well in detecting biologically relevant levels of antigen-specific T cells. These assays will better define the quantity and quality of protective immune responses to viral disease and offer insight into the requirements for protective anti-cancer immunity.

Translation of cancer immunotherapies

In response to our commentary defining potential barriers to development of novel immunotherapy opportunities, Skipper and colleagues describe a unique cancer immunotherapy consortium developed by the Ludwig Institute for Cancer Research (LICR) and joined by the Cancer Research Institute (CRI). The LICR-CRI cancer vaccine collaborative (CVC) funds units in roughly 20 institutions. These units participate in a set of coordinated cancer vaccine clinical trials focused on vaccination with a limited number of tumor antigens identified at LICR and evaluates both the generation of antigen-specific immune responses as well as clinical outcomes. As director of both institutes, Dr. Old has marshaled their vast collective resources in a visionary manner to create a multi-institutional mini-Manhattan Project. CVC's funding base allows the organization to circumvent some of the regulatory and 'public-private partnership' barriers outlined in our commentary. However, the LICR-CRI CVC is arguably so unique, it represents the exception that proves the rule.

Bayesian Approaches to Joint Cure‐Rate and Longitudinal Models with Applications to Cancer Vaccine Trials

Complex issues arise when investigating the association between longitudinal immunologic measures and time to an event, such as time to relapse, in cancer vaccine trials. Unlike many clinical trials, we may encounter patients who are cured and no longer susceptible to the time-to-event endpoint. If there are cured patients in the population, there is a plateau in the survival function, S(t), after sufficient follow-up. If we want to determine the association between the longitudinal measure and the time-to-event in the presence of cure, existing methods for jointly modeling longitudinal and survival data would be inappropriate, since they do not account for the plateau in the survival function. The nature of the longitudinal data in cancer vaccine trials is also unique, as many patients may not exhibit an immune response to vaccination at varying time points throughout the trial. We present a new joint model for longitudinal and survival data that accounts both for the possibility that a subject is cured and for the unique nature of the longitudinal data. An example is presented from a cancer vaccine clinical trial.

Current developments in cancer vaccines and cellular immunotherapy.

This article reviews the immunologic basis of clinical trials that test means of tumor antigen recognition and immune activation, with the goal to provide the clinician with a mechanistic understanding of ongoing cancer vaccine and cellular immunotherapy clinical trials. Multiple novel immunotherapy strategies have reached the stage of testing in clinical trials that were accelerated by recent advances in the characterization of tumor antigens and by a more precise knowledge of the regulation of cell-mediated immune responses. The key steps in the generation of an immune response to cancer cells include loading of tumor antigens onto antigen-presenting cells in vitro or in vivo, presenting antigen in the appropriate immune stimulatory environment, activating cytotoxic lymphocytes, and blocking autoregulatory control mechanisms. This knowledge has opened the door to antigen-specific immunization for cancer using tumor-derived proteins or RNA, or synthetically generated peptide epitopes, RNA, or DNA. The critical step of antigen presentation has been facilitated by the coadministration of powerful immunologic adjuvants, the provision of costimulatory molecules and immune stimulatory cytokines, and the ability to culture dendritic cells. Advances in the understanding of the nature of tumor antigens and their optimal presentation, and in the regulatory mechanisms that govern the immune system, have provided multiple novel immunotherapy intervention strategies that are being tested in clinical trials.

Multiparameter cytokine-specific affinity matrix assay for the determination of frequencies and phenotype of antigen-reactive T cells

A major challenge in Phase I clinical trials of cancer vaccines is how to identify the optimal regimen and/or dosing for Phase II and III trials. Immunologic responses to tumor-associated antigens (TAA) could potentially serve as surrogate markers. Assays which detect cytokine production and/or secretion by antigen (Ag)-reactive T cells are increasingly being used to monitor such responses in clinical trials. A potential problem of these assays is high non-specific background and/or inability to easily identify the T-cell phenotype. We designed an assay, termed cytokine-specific affinity matrix (Multi-CSAM™) assay, 1 1 Provisional U.S. Patent and Trademark's Application Number 60/263,929. which can determine the frequencies of phenotypically identifiable antigen (Ag)-reactive T cells. The assay relies on the tightly regulated production and secretion of cytokine by Ag-activated cells, capture of secreted cytokine by an artificial cytokine-specific cell-surface affinity matrix and flow-cytometric detection of bound cytokine with a fluorochrome-labeled anti-cytokine mAb. In an attempt to minimize non-specific background, the assay excludes non-viable cells by using the cell-impermeant DNA-binding dye TO-PRO-3, and selects activated cells on the basis of CD69 expression. Furthermore, the phenotype of the Ag-reactive T cells is identified using the CD4 and CD8 T-cell markers. Thus, using an appropriately modified two-laser benchtop instrument, a single sample can be evaluated by five-color multiparametric flow-cytometry that employs a combination of appropriately labeled mAbs. The five colors selected are anti-IFNγ-PE, the dye TO-PRO-3, anti-CD69-PerCP, anti-CD4-FITC and anti-CD8-PE/Texas Red. Although our ultimate goal is to identify T cells reactive to TAA, as a first step this report demonstrates that Multi-CSAM can be used to detect the reactivity to TT and Candida.

Clinical Translation of Peptide-Based Vaccine Trials: The HER-2/neu Model

In the development of targeted cancer immunotherapies, the choice of antigen is obviously critical to the design of any therapeutic strategy, but particularly so for tumor vaccines, which must distinguish malignant cells from normal cells. Investigations a decade ago focused on mutated tumor antigens, or viral tumor antigens, with the belief that these foreign or abnormal proteins would be best recognized by the host immune system. Within the last 10 years, however, several tumor antigens have been identified on the basis of recognition by infiltrating T cells in tumor samples. Studies on melanoma, in particular, have revealed that in addition to some mutated tumor antigens, several aberrantly expressed normal proteins, as well as tissue-specific differentiation factors, are recognized by the host immune system. Similar studies in other solid tumors have revealed that certain oncogenes overexpressed in malignant cells, such as p53 and HER-2/neu, are also recognized by host T cells. Our group has been investigating the HER-2/neu oncogenic protein as a vaccine target in patients with HER-2/neu-overexpressing cancers. However, several issues unique to the design of human clinical trials of cancer vaccines must be addressed when translating preclinical experiments to human clinical trials. First, HER-2/neu protein expression can vary depending on the tumor type. How would expression differences impact clinical trial design? Secondly, what are the issues in clinical trial design that are critical to the successful execution of a phase I study of a peptide-based vaccine? Thirdly, what types and amounts of clinical material are readily available for immunologic analysis and can be obtained with little distress and risk to the patients enrolled in the study? Finally, what steps must be implemented for a laboratory assay to evolve to meet the validation criteria needed for application as an immunologic monitoring tool?

Development of non-live vectors and procedures (liposomes, pseudo-viral particles, toxin, beads, adjuvants…) as tools for cancer vaccines

Recombinant virus encoding tumor antigens are the most used vectors in human clinical trials of cancer vaccines because of their ability to target exogenous antigen in the endogenous MHC class I pathway and to elicit CTL. However, their use requires different constraining procedures to avoid their spreading. The immunosuppression of cancer patients may also increase their intrinsic toxicity. Therefore, the development of non-live vectors may avoid these drawbacks. Different groups now clearly demonstrated that particulate antigens when they are phagocytosed could be targeted in the MHC class I pathway. They also induce CTL in mice which when immunized with these particulate antigens were protected against a challenge with tumors expressing this antigen. Other strategies using toxins or antigens fused or incorporated into various oil or lipid based chemical adjuvants have also suceeded in the induction of CTL response and in some cases have been shown to be efficient as cancer vaccine.

Interpreting cancer vaccine clinical trials.

A number of cancer vaccine strategies have entered initial Phase I clinical testing. In this review, Dr. Glenn Dranoff discusses the prospects that appropriate immunologic monitoring of patients in these trials can help delineate important differences among the various immunization strategies and prioritize the most promising approaches for further clinical development.