We have previously demonstrated potent
antitumor effects of PARP
targeted alpha-therapy with astatine-211-MM4 ([211At]MM4)
in neuroblastoma preclinical models, although differential sensitivity
suggests it is unlikely to be curative as a single-agent in all tumor
types. Alpha-particle induced DNA damage can elicit an immune response
that results in T-cell activation against tumor cells; however, tumor
cells can evade immune surveillance through expression of programmed
death ligand 1 (PD-L1). Therefore, we investigated the effects of
α particle therapy in combination with immune-checkpoint blockade
using astatine-211-MM4 and anti-programmed death receptor 1 (anti-PD-1)
immunotherapy in a syngeneic mouse model of glioblastoma. We characterized
the sensitivity of four human glioblastoma cell lines to [211At]MM4 in vitro. To evaluate [211At]MM4
treatment effects on hematological tissues, complete blood counts
were performed after a single dose at 12, 24, or 36 MBq/kg. In vivo
efficacy was evaluated in a syngeneic mouse model of glioblastoma
using GL26 glioblastoma cells in CB57BL/6J mice treated with either
36 MBq/kg [211At]MM4, anti-PD-1 antibody, or a combination
of the two. Following a single dose of [211At]MM4, lymphocytes
are significantly decreased compared to control at both 72 h and 1
week following treatment followed by recovery of counts by 2 weeks.
However, neutrophils showed an increase with all dose levels of [211At]MM4 exhibiting higher levels than control. The average
best tumor responses for combination, anti-PD-1, and [211At]MM4 were 100%, 83.6%, and 58.2% decrease in tumor volume, respectively.
Average progression free intervals for combination, anti-PD-1, [211At]MM4, and control groups was 65, 36.4, 23.2, and 3 days,
respectively. The percentages of disease-free mice at the end of the
study for combination and anti-PD-1 were 100% and 60%, while [211At]MM4 and control groups were both 0%. In summary, combination
therapy was more effective than either single agent in all response
categories analyzed, highlighting the potential for PARP targeted
alpha-therapy to enhance PD-1 immune-checkpoint blockade.
