ABSTRACT
Background B7-H4 is a cell surface ligand overexpressed by tumors to inhibit T cell functions and evade the immune system. B7-H4 is minimally expressed in normal tissues but is highly expressed by various cancer cells and tumor-associated macrophages (TAM). Despite its importance as an immune checkpoint inhibitor, no imaging techniques specifically targeting B7-H4 have been established. To close this gap, we sought to assess the ability of a monoclonal antibody (mAb) based immunoPET radiotracer to visualize B7-H4 in human and murine prostate cancer models.
Methods Anti-B7-H4 mAb clone 2H9 was functionally characterized for binding to the human and mouse B7-H4 protein. The antibody was conjugated with chelator p-SCN-Bn-Deferoxamine (DFO) and labeled with radioisotope Zirconium-89 (89Zr) to obtain immunoPET tracer 89Zr-2H9-mAb. The biolayer interferometry method was used to test the binding kinetics of DFO-2H9-mAb compared to that of parental 2H9 mAb. A group of six athymic nude mice with human DU145 prostate tumor xenograft underwent MicroPET imaging after tail vein injection of ∼150µCi 89Zr-2H9-mAb or non-binding 89Zr-Isotype-mAb. Next, immunocompetent C57BL/6J mice with TRAMP-C2 tumors each were injected with either PBS (n=8), cold 2H9 mAb (10mg/kg) to block B7-H4 (n=6), or chlodronate liposome (15mg/kg) to cause total macrophage depletion (n=6), followed by 89Zr-2H9-mAb MicroPET imaging. An ex vivo biodistribution assay was performed after 144 hr post radiotracer injection. Tumor radiotracer binding, quantified as a percentage injected dose per gram (%ID/g), was compared between different experimental groups using two-way ANOVA with Bonferroni or Tukey corrections.
Results Immunoconjugation yielded a 2.59 ± 0.08 chelator-to-antibody ratio, and the binding of DFO conjugated 2H9-mAb was similar to that of parental 2H9 mAb, with unaffected affinity in targeting B7-H4 protein moiety. The radiochemical purity of 89Zr-2H9-mAb tracer was yielded >95% with an average specific activity of 5µCi/µg antibody. DU145 tumor xenografts demonstrated significantly stronger radiotracer binding at 24, 48, 72, 96, and 120 hr than the non-binding isotype control group. In TRAMP-C2 tumor xenografts, the radiotracer binding in B7-H4 blocked tumors was significantly lower than in the non-blocked PBS-injected group. Macrophage depletion resulted in a significant decrease in tumor binding compared to the control group. 89Zr-2H9-mAb could efficiently distinguish tumors with high sensitivity, showing a high correlation between PET imaging and bio-distribution. More importantly, the immunohistochemistry of the harvested tumor revealed no significant difference between the three groups, as discernible through in vivo PET imaging.
Conclusion This study highlights the potential of B7-H4 immunoPET imaging for monitoring immunotherapy response. With the emerging potential of B7-H4 blocking as an immunotherapeutic, immunoPET imaging could be readily expanded to patient stratification and therapy monitoring. B7-H4 imaging could augment our understanding of B7-H4 dynamics in response to various therapeutic interventions in clinical trials. The new B7-H4 immunoPET probe is, in principle, clinically translatable.
Competing Interest Statement
The authors have declared no competing interest.