529 Objectives PD-L1 (Programmed Death Ligand 1) is a 40 kDa immune regulatory ligand that binds to PD-1 (Programmed Death 1), which functions as an immune checkpoint and is expressed on activated immune cell types including T cells, B cells, natural killer (NK) cells and many tumor-infiltrating lymphocytes (TILs).[1] PD-L1 binding to PD-1 deactivates these cytotoxic T cells, and as a consequence the expression of PD-L1 in tumors is correlated to immune suppression and poor prognosis. Therefore it may be feasible to use tumor expression of PD-L1 as a predictive marker for anti-PD-1 therapy. The purpose of this work was to evaluate the feasibility of using PET as and in vivo tool to image PD-L1. For this, the human PD-L1 specific mAb 22C3 was chosen as our proof of concept molecule. Methods The anti-human PD-L1 mAb 22C3 and isotype matched control mAb 27F11 were conjugated with DOTA and subsequently radiolabeled with [64Cu]. MicroPET imaging studies were carried out in SCID mice implanted with the LOX human malignant melanoma cell line, known to express PD-L1, 48 hr. after administering either [64Cu]DOTA-22C3 (n=4) or [64Cu]DOTA-27F11 (n=4). Blocking studies were also performed in which the tumor bearing mice received 200 µg of unlabeled 22C3 1 hr. prior to administration of [64Cu]DOTA-22C3 (n=4). In all cases following the 48 hr. imaging scan, the mice were euthanized and biodistribution studies performed. Along with imaging studies, an in vitro homogenate binding assay using LOX xenografts homogenates was performed to measure the binding potential for both [64Cu]DOTA-22C3 and [64Cu]DOTA-27F11. Finally, autoradiographic and PD-L1 IHC staining were performed on the LOX tumors to see if tracer uptake correlated to regions of high PD-L1 expression. Results Displaceable and saturable binding of [64Cu]DOTA-22C3 was observed from the in vitro homogenate binding assay, with [64Cu]DOTA-22C3 binding to a single site with high affinity (Kd = 0.4 nM). For [64Cu]DOTA-27F11 binding in tumor tissue was minimal and not saturable, indicating that there was no measureable specific binding. ComparisonComparison of autoradiography and HC staining of tumor slices confirmed that PD-L1 expression patterns matched [64Cu]DOTA-22C3 binding patterns. A similar correlation was not observed for [64Cu]DOTA-27F11. From the PET Images, tumor uptake in the mice that received [64Cu]DOTA-22C3 was clearly visualized, with uptake higher than [64Cu]DOTA-27F11. In addition, pretreatment with the unlabeled 22C3 reduced tumor uptake of [64Cu]DOTA-22C3 mAb to levels comparable to [64Cu]DOTA-27F11. Biodistribution data at 48 hr. confirmed the PET imaging analysis with tumor uptake of [64Cu]DOTA-22C3 being significantly higher than [64Cu]DOTA-27F11 (p Conclusions The results of this study demonstrate that a PET ligand can specifically target PD-L1-expressing tumors in a mouse model, and support the hypothesis that PD-L1 can be imaged in vivo in the clinic using PET.
The folate receptor (FR) has been established as a promising target for imaging and therapy of cancer (FR-α), inflammation, and autoimmune diseases (FR-β). Several folate based PET radiotracers have been reported in the literature, but an 18F-labeled folate-PET imaging agent with optimal properties for clinical translation is still lacking. In the present study, we report the design and preclinical evaluation of folate-PEG12-NOTA-Al18F (1), a new folate-PET agent with improved potential for clinical applications. Radiochemical synthesis of 1 was achieved via a one-pot labeling process by heating folate-PEG12-NOTA in the presence of in situ prepared Al18F for 15 min at 105 °C, followed by HPLC purification. Specific binding of 1 to FR was evaluated on homogenates of KB (FR-positive) and A549 (FR-deficient) tumor xenografts in the presence and absence of excess folate. In vivo tumor imaging with folate-PEG12-NOTA-Al18F was compared to imaging with 99mTc-EC20 using nu/nu mice bearing either KB or A549 tumor xenografts. Specific accumulation of 1 in tumor and other tissues was assessed by high-resolution micro-PET and ex vivo biodistribution in the presence and absence of excess folate. Radiosynthesis of 1 was accomplished within ∼35 min, affording pure radiotracer 1 in 8.4 ± 1.3% (decay corrected) radiochemical yield with ∼100% radiochemical purity after HPLC purification and a specific activity of 35.8 ± 15.3 GBq/mmol. Further in vitro and in vivo examination of 1 demonstrated highly specific FR-mediated uptake in FR+ tumor, with Kd of ∼0.4 nM (KB), and reduced accumulation in liver. Given its facile preparation and improved properties, the new radiotracer, folate-PEG12-NOTA-Al18F (1), constitutes a promising tool for identification and classification of patients with FR overexpressing cancers.
Abstract Purpose Programmed cell death-1 receptor (PD-1) and its ligand (PD-L1) are the targets for immunotherapy in many cancer types. Although PD-1 blockade has therapeutic effects, the efficacy differs between patients. Factors contributing to this variability are PD-L1 expression levels and immune cells present in tumors. However, it is not well understood how PD-1 expression in the tumor microenvironment impacts immunotherapy response. Thus, imaging of PD-1-expressing immune cells is of interest. This study aims to evaluate the biodistribution of Zirconium-89 ( 89 Zr)-labeled pembrolizumab, a humanized IgG4 kappa monoclonal antibody targeting PD-1, in healthy cynomolgus monkeys as a translational model of tracking PD-1-positive immune cells. Procedures Pembrolizumab was conjugated with the tetrafluorophenol-N-succinyl desferal-Fe(III) ester (TFP-N-sucDf) and subsequently radiolabeled with 89 Zr. Four cynomolgus monkeys with no previous exposure to humanized monoclonal antibodies received tracer only or tracer co-injected with pembrolizumab intravenously over 5 min. Thereafter, a static whole-body positron emission tomography (PET) scan was acquired with 10 min per bed position on days 0, 2, 5, and 7. Image-derived standardized uptake values (SUV mean ) were quantified by region of interest (ROI) analysis. Results 89 Zr-N-sucDf-pembrolizumab was synthesized with high radiochemical purity (> 99 %) and acceptable molar activity (> 7 MBq/nmol). In animals dosed with tracer only, 89 Zr-N-sucDf-pembrolizumab distribution in lymphoid tissues such as mesenteric lymph nodes, spleen, and tonsils increased over time. Except for the liver, low radiotracer distribution was observed in all non-lymphoid tissue including the lung, muscle, brain, heart, and kidney. When a large excess of pembrolizumab was co-administered with a radiotracer, accumulation in the lymph nodes, spleen, and tonsils was reduced, suggestive of target-mediated accumulation. Conclusions 89 Zr-N-sucDf-pembrolizumab shows preferential uptake in the lymphoid tissues including the lymph nodes, spleen, and tonsils. 89 Zr-N-sucDf-pembrolizumab may be useful in tracking the distribution of a subset of immune cells in non-human primates and humans. Trial Registration ClinicalTrials.gov Identifier: NCT02760225
Programmed death ligand 1 (PD-L1) is an immune regulatory ligand that binds to the T-cell immune check point programmed death 1. Tumor expression of PD-L1 is correlated with immune suppression and poor prognosis. It is also correlated with therapeutic efficacy of programmed death 1 and PD-L1 inhibitors. In vivo imaging may enable real-time follow-up of changing PD-L1 expression and heterogeneity evaluation of PD-L1 expression across tumors in the same subject. We have radiolabeled the PD-L1-binding Affibody molecule NOTA-ZPD-L1_1 with 18F and evaluated its in vitro and in vivo binding affinity, targeting, and specificity. Methods: The affinity of the PD-L1-binding Affibody ligand ZPD-L1_1 was evaluated by surface plasmon resonance. Labeling was accomplished by maleimide coupling of NOTA to a unique cysteine residue and chelation of 18F-AlF. In vivo studies were performed in PD-L1-positive, PD-L1-negative, and mixed tumor-bearing severe combined immunodeficiency mice. Tracer was injected via the tail vein, and dynamic PET scans were acquired for 90 min, followed by γ-counting biodistribution. Immunohistochemical staining with an antibody specific for anti-PD-L1 (22C3) was used to evaluate the tumor distribution of PD-L1. Immunohistochemistry results were then compared with ex vivo autoradiographic images obtained from adjacent tissue sections. Results: NOTA-ZPD-L1_1 was labeled, with a radiochemical yield of 15.1% ± 5.6%, radiochemical purity of 96.7% ± 2.0%, and specific activity of 14.6 ± 6.5 GBq/μmol. Surface plasmon resonance showed a NOTA-conjugated ligand binding affinity of 1 nM. PET imaging demonstrated rapid uptake of tracer in the PD-L1-positive tumor, whereas the PD-L1-negative control tumor showed little tracer retention. Tracer clearance from most organs and blood was quick, with biodistribution showing prominent kidney retention, low liver uptake, and a significant difference between PD-L1-positive (percentage injected dose per gram [%ID/g] = 2.56 ± 0.33) and -negative (%ID/g = 0.32 ± 0.05) tumors (P = 0.0006). Ex vivo autoradiography showed excellent spatial correlation with immunohistochemistry in mixed tumors. Conclusion: Our results show that Affibody ligands can be effective at targeting tumor PD-L1 in vivo, with good specificity and rapid clearance. Future studies will explore methods to reduce kidney activity retention and further increase tumor uptake.
The cathepsin K (CatK) enzyme is abundantly expressed in osteoclasts, and CatK inhibitors have been developed for the treatment of osteoporosis. In our effort to support discovery and clinical evaluations of a CatK inhibitor, we sought to discover a radioligand to determine target engagement of the enzyme by therapeutic candidates using positron emission tomography (PET). L-235, a potent and selective CatK inhibitor, was labeled with carbon-11. PET imaging studies recording baseline distribution of [11 C]L-235, and chase and blocking studies using the selective CatK inhibitor MK-0674 were performed in juvenile and adult nonhuman primates (NHP) and ovariectomized rabbits. Retention of the PET tracer in regions expected to be osteoclast-rich compared with osteoclast-poor regions was examined. Increased retention of the radioligand was observed in osteoclast-rich regions of juvenile rabbits and NHP but not in the adult monkey or adult ovariectomized rabbit. Target engagement of CatK was observed in blocking studies with MK-0674, and the radioligand retention was shown to be sensitive to the level of MK-0674 exposure. [11 C]L-235 can assess target engagement of CatK in bone only in juvenile animals. [11 C]L-235 may be a useful tool for guiding the discovery of CatK inhibitors.
