Labeling of Anti-HER2 Nanobodies with Astatine-211: Optimization and the Effect of Different Coupling Reagents on Their in Vivo Behavior.

The use of nanobodies (Nbs) as vehicles in targeted alpha therapy (TAT) has gained great interest because of their excellent properties. They combine high in vivo affinity and specificity of binding with fast kinetics. This research investigates a novel targeted therapy that combines the α-particle emitter astatine-211 (211At) and the anti-HER2 Nb 2Rs15d to selectively target HER2+ cancer cells. Two distinctive radiochemical methodologies are investigated using three different coupling reagents. The first method uses the coupling reagents, N-succinimidyl 4-(1,2-bis- tert-butoxycarbonyl)guanidinomethyl-3-(trimethylstannyl)benzoate (Boc2-SGMTB) and N-succinimidyl-3-(trimethylstannyl)benzoate ( m-MeATE), which are both directed to amino groups on the Nb, resulting in random conjugation. The second method aims at obtaining a homogeneous tracer population, via a site-specific conjugation of the N-[2-(maleimido)ethyl]-3-(trimethylstannyl)benzamide (MSB) reagent onto the carboxyl-terminal cysteine of the Nb. The resulting radioconjugates are evaluated in vitro and in vivo. 2Rs15d is labeled with 211At using Boc2-SGMTB, m-MeATE, and MSB. After astatination and purification, the binding specificity of the radioconjugates is validated on HER2+ cells, followed by an in vivo biodistribution assessment in SKOV-3 xenografted mice. α-camera imaging is performed to determine uptake and activity distribution in kidneys/tumors. 2Rs15d astatination resulted in a high radiochemical purity >95% for all radioconjugates. The biodistribution studies of all radioconjugates revealed comparable tumor uptake (higher than 8% ID/g at 1 h). [211At]SAGMB-2Rs15d showed minor uptake in normal tissues. Only in the kidneys, a higher uptake was measured after 1 h, but decreased rapidly after 3 h. Astatinated Nbs consisting of m-MeATE or MSB reagents revealed elevated uptake in lungs and stomach, indicating the presence of released 211At. α-Camera imaging of tumors revealed a homogeneous activity distribution. The radioactivity in the kidneys was initially concentrated in the renal cortex, while after 3 h most radioactivity was measured in the medulla, confirming the fast washout into urine. Changing the reagents for Nb astatination resulted in different in vivo biodistribution profiles, while keeping the targeting moiety identical. Boc2-SGMTB is the preferred reagent for Nb astatination because of its high tumor uptake, its low background signals, and its fast renal excretion. We envision [211At]SAGMB-2Rs15d to be a promising therapeutic agent for TAT and aim toward efficacy evaluation.

[1]  P. Dahm-Kähler,et al.  Intraperitoneal α-Emitting Radioimmunotherapy with 211At in Relapsed Ovarian Cancer: Long-Term Follow-up with Individual Absorbed Dose Estimations , 2019, The Journal of Nuclear Medicine.

[2]  N. Devoogdt,et al.  Targeted Nanobody-Based Molecular Tracers for Nuclear Imaging and Image-Guided Surgery , 2019, Antibodies.

[3]  N. Devoogdt,et al.  An Efficient Method for Labeling Single Domain Antibody Fragments with 18F Using Tetrazine- Trans-Cyclooctene Ligation and a Renal Brush Border Enzyme-Cleavable Linker. , 2018, Bioconjugate chemistry.

[4]  V. Chudasama,et al.  Minireview: Addressing the retro-Michael instability of maleimide bioconjugates. , 2018, Drug discovery today. Technologies.

[5]  M. Pomper,et al.  Brush border enzyme-cleavable linkers: Evaluation for reducing renal uptake of radiolabeled prostate-specific membrane antigen inhibitors. , 2018, Nuclear medicine and biology.

[6]  U. Haberkorn,et al.  Targeted α-Therapy of Metastatic Castration-Resistant Prostate Cancer with 225Ac-PSMA-617: Swimmer-Plot Analysis Suggests Efficacy Regarding Duration of Tumor Control , 2018, The Journal of Nuclear Medicine.

[7]  T. Lahoutte,et al.  Evaluation of an Anti-HER2 Nanobody Labeled with 225Ac for Targeted α-Particle Therapy of Cancer. , 2018, Molecular pharmaceutics.

[8]  J. Tavernier,et al.  Theranostic Radiolabeled Anti-CD20 sdAb for Targeted Radionuclide Therapy of Non-Hodgkin Lymphoma , 2017, Molecular Cancer Therapeutics.

[9]  N. Devoogdt,et al.  131I-labeled Anti-HER2 Camelid sdAb as a Theranostic Tool in Cancer Treatment , 2017, Clinical Cancer Research.

[10]  Marleen Keyaerts,et al.  Non-invasive assessment of murine PD-L1 levels in syngeneic tumor models by nuclear imaging with nanobody tracers , 2017, Oncotarget.

[11]  F. Mottaghy,et al.  225Ac-PSMA-617 for PSMA-Targeted α-Radiation Therapy of Metastatic Castration-Resistant Prostate Cancer , 2016, The Journal of Nuclear Medicine.

[12]  J. Pinkas,et al.  Understanding How the Stability of the Thiol-Maleimide Linkage Impacts the Pharmacokinetics of Lysine-Linked Antibody-Maytansinoid Conjugates. , 2016, Bioconjugate chemistry.

[13]  Marleen Keyaerts,et al.  Targeted alpha therapy using short-lived alpha-particles and the promise of nanobodies as targeting vehicle , 2016, Expert opinion on biological therapy.

[14]  Nick Devoogdt,et al.  (18)F-nanobody for PET imaging of HER2 overexpressing tumors. , 2016, Nuclear medicine and biology.

[15]  B. Blount,et al.  Thyroid Antagonists (Perchlorate, Thiocyanate, and Nitrate) and Childhood Growth in a Longitudinal Study of U.S. Girls , 2015, Environmental health perspectives.

[16]  H. Jensen,et al.  N-[2-(maleimido)ethyl]-3-(trimethylstannyl)benzamide, a molecule for radiohalogenation of proteins and peptides. , 2015, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.

[17]  S. Muyldermans,et al.  Radiolabeled nanobodies as theranostic tools in targeted radionuclide therapy of cancer , 2014, Expert opinion on drug delivery.

[18]  S. Muyldermans,et al.  Site-specific labeling of cysteine-tagged camelid single-domain antibody-fragments for use in molecular imaging. , 2014, Bioconjugate chemistry.

[19]  S. Muyldermans,et al.  Targeted Radionuclide Therapy with A 177Lu-labeled Anti-HER2 Nanobody , 2014, Theranostics.

[20]  S. Muyldermans,et al.  Imaging and radioimmunotherapy of multiple myeloma with anti-idiotypic Nanobodies , 2014, Leukemia.

[21]  Eva Forssell-Aronsson,et al.  Biodistribution and dosimetry of free 211At, 125I- and 131I- in rats. , 2013, Cancer biotherapy & radiopharmaceuticals.

[22]  Serge Muyldermans,et al.  Nanobodies: natural single-domain antibodies. , 2013, Annual review of biochemistry.

[23]  P. De Baetselier,et al.  Nanobody-based targeting of the macrophage mannose receptor for effective in vivo imaging of tumor-associated macrophages. , 2012, Cancer research.

[24]  Nick Devoogdt,et al.  Preclinical screening of anti‐HER2 nanobodies for molecular imaging of breast cancer , 2011, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[25]  M. Zalutsky,et al.  Astatine-211: production and availability. , 2011, Current radiopharmaceuticals.

[26]  C. Vanhove,et al.  Localization, mechanism and reduction of renal retention of technetium-99m labeled epidermal growth factor receptor-specific nanobody in mice. , 2011, Contrast media & molecular imaging.

[27]  L. Jacobsson,et al.  The α-Camera: A Quantitative Digital Autoradiography Technique Using a Charge-Coupled Device for Ex Vivo High-Resolution Bioimaging of α-Particles , 2010, The Journal of Nuclear Medicine.

[28]  S. Muyldermans,et al.  In Vitro Analysis and In Vivo Tumor Targeting of a Humanized, Grafted Nanobody in Mice Using Pinhole SPECT/Micro-CT , 2010, Journal of Nuclear Medicine.

[29]  A. Merlo,et al.  Targeted alpha-radionuclide therapy of functionally critically located gliomas with 213Bi-DOTA-[Thi8,Met(O2)11]-substance P: a pilot trial , 2010, European Journal of Nuclear Medicine and Molecular Imaging.

[30]  L. Jacobsson,et al.  Intraperitoneal α-Particle Radioimmunotherapy of Ovarian Cancer Patients: Pharmacokinetics and Dosimetry of 211At-MX35 F(ab′)2—A Phase I Study , 2009, Journal of Nuclear Medicine.

[31]  T. Waldmann,et al.  Preparation and in vivo evaluation of linkers for 211At labeling of humanized anti-Tac. , 2001, Nuclear medicine and biology.

[32]  T. Bäck,et al.  Dry-distillation of astatine-211 from irradiated bismuth targets: a time-saving procedure with high recovery yields. , 2001, Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine.

[33]  P. Bunn,et al.  Determination of the immunoreactive fraction of radiolabeled monoclonal antibodies by linear extrapolation to binding at infinite antigen excess. , 1984, Journal of immunological methods.

[34]  V D Nefedov,et al.  Astatine , 1982 .

[35]  M. Zalutsky,et al.  Astatine-211 labeled anti-HER2 5F7 single domain antibody fragment conjugates: radiolabeling and preliminary evaluation. , 2018, Nuclear medicine and biology.

[36]  Eva Forssell-Aronsson,et al.  Similarities and differences between free 211At and 125I- transport in porcine thyroid epithelial cells cultured in bicameral chambers. , 2001, Nuclear medicine and biology.