The rapidly advancing field of cancer immunotherapy is currently limited by the scarcity of noninvasive and quantitative technologies capable of monitoring the presence and abundance of CD8+ T cells and other immune cell subsets. In this study, we describe the generation of 89Zr-desferrioxamine-labeled anti-CD8 cys-diabody (89Zr-malDFO-169 cDb) for noninvasive immuno-positron emission tomography (immuno-PET) tracking of endogenous CD8+ T cells. We demonstrate that anti-CD8 immuno-PET is a sensitive tool for detecting changes in systemic and tumor-infiltrating CD8 expression in preclinical syngeneic tumor immunotherapy models including antigen-specific adoptive T cell transfer, agonistic antibody therapy (anti-CD137/4-1BB), and checkpoint blockade antibody therapy (anti-PD-L1). The ability of anti-CD8 immuno-PET to provide whole body information regarding therapy-induced alterations of this dynamic T cell population provides new opportunities to evaluate antitumor immune responses of immunotherapies currently being evaluated in the clinic.
A new tripodal tris(hydroxypyridinone) bifunctional chelator for gallium allows easy production of (68)Ga-labelled proteins rapidly under mild conditions in high yields at exceptionally high specific activity and low concentration.
Significance Anti-CD8 immuno-PET imaging agents provide the potential to monitor the localization, migration, and expansion of CD8-expressing cells noninvasively in vivo. Shown here is the successful generation of functional anti-CD8 imaging agents based on engineered antibodies for use in a variety of preclinical disease and immunotherapeutic models.
A novel bifunctional chelator combines a dithiocarbamate group for binding the positron‐emitter 64Cu (red spheres) for PET imaging and a bisphosphonate group (green ellipsoids) for strong binding to several inorganic materials, such as MRI contrast agents based on superparamagnetic iron oxide nanoparticles and rare‐earth metal oxides. The dual PET–MR imaging capabilities of this approach are demonstrated in vivo by imaging lymph nodes using both imaging modalities.
The combination of radionuclide-based imaging modalities such as single photon emission computed tomography (SPECT) and positron emission tomography (PET) with magnetic resonance imaging (MRI) is likely to become the next generation of clinical scanners. Hence, there is a growing interest in the development of SPECT- and PET-MRI agents. To this end, we report a new class of dual-modality imaging agents based on the conjugation of radiolabeled bisphosphonates (BP) directly to the surface of superparamagnetic iron oxide (SPIO) nanoparticles. We demonstrate the high potential of BP-iron oxide conjugation using (⁹⁹m)Tc-dipicolylamine(DPA)-alendronate, a BP-SPECT agent, and Endorem/Feridex, a liver MRI contrast agent based on SPIO. The labeling of SPIOs with (⁹⁹m)Tc-DPA-alendronate can be performed in one step at room temperature if the SPIO is not coated with an organic polymer. Heating is needed if the nanoparticles are coated, as long as the coating is weakly bound as in the case of dextran in Endorem. The size of the radiolabeled Endorem (⁹⁹m)Tc-DPA-ale-Endorem) was characterized by TEM (5 nm, Fe₃O₄ core) and DLS (106 ± 60 nm, Fe₃O₄ core + dextran). EDX, Dittmer-Lester, and radiolabeling studies demonstrate that the BP is bound to the nanoparticles and that it binds to the Fe₃O₄ cores of Endorem, and not its dextran coating. The bimodal imaging capabilities and excellent stability of these nanoparticles were confirmed using MRI and nanoSPECT-CT imaging, showing that (⁹⁹m)Tc and Endorem co-localize in the liver and spleen In Vivo, as expected for particles of the composition and size of (⁹⁹m)Tc-DPA-ale-Endorem. To the best of our knowledge, this is the first example of radiolabeling SPIOs with BP conjugates and the first example of radiolabeling SPIO nanoparticles directly onto the surface of the iron oxide core, and not its coating. This work lays down the basis for a new generation of SPECT/PET-MR imaging agents in which the BP group could be used to attach functionality to provide targeting, stealth/stability, and radionuclides to Fe₃O₄ nanoparticles using very simple methodology readily amenable to GMP.
The proliferation and trafficking of T lymphocytes in immune responses are crucial events in determining inflammatory responses. To study whole body T lymphocyte dynamics non-invasively in vivo, we have generated anti-CD4 and -CD8 cys-diabodies (cDbs) derived from the parental antibody hybridomas GK1.5 and 2.43, respectively, for 89Zr-immunoPET detection of helper and cytotoxic T cell populations. Methods Anti-CD4 and -CD8 cys-diabodies were engineered, produced via mammalian expression, purified using immobilized metal affinity chromatography, and characterized for T cell binding. The cys-diabodies were site-specifically conjugated to maleimide-desferrioxamine for 89Zr radiolabeling and subsequent microPET/CT acquisition and ex vivo biodistribution in both wild type mice and a model of hematopoietic stem cell (HSC) transplantation. Results ImmunoPET and biodistribution studies demonstrate targeting and visualization of CD4 and CD8 T cell populations in vivo in the spleen and lymph nodes of wild type mice, with specificity confirmed through in vivo blocking and depletion studies. Subsequently, a murine model of HSC transplantation demonstrated successful in vivo detection of T cell repopulation at 2, 4, and 8 weeks post-HSC transplant using the 89Zr-radiolabeled anti-CD4 and -CD8 cDbs. Conclusion These newly developed anti-CD4 and -CD8 immunoPET reagents represent a powerful resource to monitor T cell expansion, localization and novel engraftment protocols. Future potential applications of T cell targeted immunoPET include monitoring immune cell subsets in response to immunotherapy, autoimmunity, and lymphoproliferative disorders, contributing overall to preclinical immune cell monitoring.
PURPOSE Molecular imaging of CD4+ T cells throughout the body has implications for monitoring autoimmune disease and immunotherapy of cancer. Given the key role of these cells in regulating immunity, it is important to develop a biologically inert probe. GK1.5 cys-diabody (cDb), a previously developed anti-mouse CD4 antibody fragment, was tested at different doses to assess its effects on positron emission tomography (PET) imaging and CD4+ T cell viability, proliferation, CD4 expression, and function. PROCEDURES The effect of protein dose on image contrast (lymphoid tissue-to-muscle ratio) was assessed by administering different amounts of 89Zr-labeled GK1.5 cDb to mice followed by PET imaging and ex vivo biodistribution analysis. To assess impact of GK1.5 cDb on T cell biology, GK1.5 cDb was incubated with T cells in vitro or administered intravenously to C57BL/6 mice at multiple protein doses. CD4 expression and T cell proliferation were analyzed with flow cytometry and cytokines were assayed. RESULTS For immunoPET imaging, the lowest protein dose of 2 µg 89Zr-labeled GK1.5 cDb resulted in significantly higher % injected dose/gram in inguinal lymph nodes (ILN) and spleen compared to the 12 µg protein dose. In vivo administration of GK1.5 cDb at the high dose of 40 µg caused a transient decrease in CD4 expression in spleen, blood, lymph nodes, and thymus, which recovered within 3 days post-injection; this effect was reduced, although not abrogated, when 2 µg was administered. Proliferation was inhibited in vivo in ILN but not the spleen by injection of 40 µg GK1.5 cDb. Concentrations of GK1.5 cDb in excess of 25 nM significantly inhibited CD4+ T cell proliferation and interferon-γ production in vitro. Overall, using low dose GK1.5 cDb minimized biological effects on CD4+ T cells. CONCLUSIONS Low dose GK1.5 cDb yields high-contrast immunoPET images with minimal effects on T cell biology in vitro and in vivo, and may be a useful tool for investigating CD4+ T cells in the context of preclinical disease models. Future approaches to minimizing biological effects may include the creation of monovalent fragments or selecting anti-CD4 antibodies which target alternative epitopes.
Prostate stem cell antigen (PSCA) is expressed on the cell surface in 83%–100% of local prostate cancers and 87%–100% of prostate cancer bone metastases. In this study, we sought to develop immunoPET agents using 124I- and 89Zr-labeled anti-PSCA A11 minibodies (scFv-CH3 dimer, 80 kDa) and evaluate their use for quantitative immunoPET imaging of prostate cancer. Methods A11 anti-PSCA minibody was alternatively labeled with 124I- or 89Zr-desferrioxamine and injected into mice bearing either matched 22Rv1 and 22Rv1× PSCA or LAPC-9 xenografts. Small-animal PET data were obtained and quantitated with and without recovery coefficient–based partial-volume correction, and the results were compared with ex vivo biodistribution. Results Rapid and specific localization to PSCA-positive tumors and high-contrast imaging were observed with both 124I-and 89Zr-labeled A11 anti-PSCA minibody. However, the differences in tumor uptake and background uptake of the radiotracers resulted in different levels of imaging contrast. The nonresidualizing 124I-labeled minibody had lower tumor uptake (3.62 ± 1.18 percentage injected dose per gram [%ID/g] 22Rv1×PSCA, 3.63 ± 0.59 %ID/g LAPC-9) than the residualizing 89Zr-labeled minibody (7.87 ± 0.52 %ID/g22Rv1×PSCA, 9.33 ±0.87 %ID/gLAPC-9, P <0.0001 for each), but the 124I-labeled minibody achieved higher imaging contrast because of lower nonspecific uptake and better tumor–to–soft-tissue ratios (22Rv1×PSCA:22Rv1 positive-to-negative tumor, 13.31 ± 5.59 124I-A11 and 4.87 ± 0.52 89Zr-A11, P = 0.02). Partial-volume correction was found to greatly improve the correspondence between small-animal PET and ex vivo quantification of tumor uptake for immunoPET imaging with both radionuclides. Conclusion Both 124I-and 89Zr-labeled A11 anti-PSCA minibody showed high-contrast imaging of PSCA expression in vivo. However, the 124I-labeled A11 minibody was found to be the superior imaging agent because of lower nonspecific uptake and higher tumor–to–soft-tissue contrast. Partial-volume correction was found to be essential for robust quantification of immunoPET imaging with both 124I- and 89Zr-labeled A11 minibody.
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