Durable adoptive immunotherapy for leukemia produced by manipulation of multiple regulatory pathways of CD8+ T-cell tolerance.

Tolerizing mechanisms within the host and tumor microenvironment inhibit T-cell effector functions that can control cancer. These mechanisms blunt adoptive immunotherapy with infused T-cells due to a complex array of signals that determine T-cell tolerance, survival, or deletion. Ligation of the negative regulatory receptors CTLA4, PD-1(PDCD1), or LAG3 on T-cells normally hinders their response to antigen through nonredundant biochemical processes that interfere with stimulatory pathways. In this study, we used an established mouse model of T-cell tolerance to define the roles of these inhibitory receptors in regulating CD8(+) T-cell tolerance during adoptive immunotherapy to treat leukemia. Blocking CTLA4 and PD-1 in vivo combined to promote survival of transferred T-cells despite powerful deletional signals that mediate Bim (BCL2L11)-dependent apoptosis. However, this dual blockade was not optimal for stimulating effector function by responding T-cells, which required the additional blockade of LAG3 to induce full expansion and allow the acquisition of robust cytolytic activity. Thus, the cooperation of multiple distinct regulatory pathways was needed for the survival and effector differentiation of adoptively transferred tumor-reactive CD8(+) T-cells. Our work defines the immune escape pathways in which simultaneous blockade could yield durable immunotherapeutic responses that can eradicate disseminated leukemia.

Construction and preclinical evaluation of recombinant Peru-15 expressing high levels of the cholera toxin B subunit as a vaccine against enterotoxigenic Escherichia coli.

Enterotoxigenic Escherichia coli (ETEC) is the leading cause of traveler's diarrhea. The heat-labile (LT) and heat-stable (ST) toxins mediate ETEC induced diarrhea. ETEC strains may express LT, ST, or both LT and ST, with LT-expressing strains accounting for approximately 50-60% of ETEC-related traveler's diarrhea. Cholera toxin (CT) is >80% homologous to LT and vaccination with CT-B subunit (CT-B) -based vaccines elicit a protective immune response against LT-producing ETEC strains. Peru-15 is an oral, single-dose, live-attenuated cholera vaccine candidate that has been investigated in several clinical trials (n>400 subjects) and was proven well tolerated, immunogenic, and efficacious. Peru-15 was genetically engineered to express and secrete high levels of CT-B by cloning ctxB onto a glnA balanced-lethal plasmid under the transcriptional control of a strong constitutive promoter, resulting in Peru-15pCTB. In vitro characterization demonstrated that Peru-15pCTB secreted approximately 30-fold more CT-B than Peru-15 and CT-B was stably produced after 40 generations of growth and throughout simulated Seed Bank and FDP (Final Drug Product) production conditions. In preclinical studies, the geometric mean anti-CT-B IgG titer in the sera of mice inoculated intranasally with two doses of Peru-15pCTB was >32-fold higher than in mice inoculated with Peru-15. Similarly, rabbits orally inoculated with a single dose of Peru-15pCTB developed titers that were approximately 30-fold higher than rabbits inoculated with a single dose of Peru-15. Sera from Peru-15pCTB vaccinated mice and rabbits neutralized LT toxicity in an in vitro assay. Peru-15pCTB has several promising characteristics of an oral, single-dose, bivalent cholera/ETEC vaccine and is advancing towards a Phase 1 clinical trial.