Lymphocytes generated by in vivo priming and in vitro sensitization demonstrate therapeutic efficacy against a murine tumor that lacks apparent immunogenicity.

The adoptive transfer of sensitized lymphocytes is an effective means to mediate the regression of established tumors. However, successful therapy can only be demonstrated in animal models where tumors are intrinsically immunogenic, capable of eliciting systemic immunity. To explore the potential of this therapeutic approach to tumors of less immunogenicity, we have selected and used a murine tumor, MCA 102, for the current study because all attempts to immunize syngeneic mice failed. We report here that inoculation of mice with a mixture of tumor cells and a bacterial adjuvant, Corynebacterium parvum led to the production of sensitized, but not fully functional, lymphocytes in the draining lymph nodes (LN). These cells, termed pre-effector cells, could nevertheless further differentiate to acquire full immunologic function by an established in vitro sensitization culture method. In adoptive immunotherapy experiments, transfer of as few as 1.5 X 10(7) in vitro sensitized cells not only reduced established pulmonary MCA 102 metastases but also prolonged survival and cured tumors in a majority of the treated animals. In order to elicit pre-effector cells in vivo, inoculation with both tumor cells and C. parvum was essential. Although a broad range of numbers of MCA 102 tumor cells appeared to be effective, generation of pre-effector cells was dependent on the dose of C. parvum. We have found that a C. parvum dose of 25 micrograms was optimal, whereas higher doses of the adjuvant had suppressive effects. Analysis of the kinetics of their appearance revealed that the generation of pre-effector cells was transient. They were detectable 7 days after in vivo priming followed by a rapid decline. Furthermore, pre-effector cells were detected only in the regional draining LN. No reactivity was demonstrable in the spleen, mesenteric LN, PBL, or bone marrow. Taken together, these results expand the scope of immunotherapy by demonstrating the feasibility of manipulating a limited and obscure immune response to the MCA 102 tumor for therapeutic efficacy.