Michael Honer1, Luca Gobbi2, Henner Knust2, Hiroto Kuwabara3,4, Dieter Muri2, Matthias Koerner2, Heather Valentine3,4, Robert F Dannals3, Dean F Wong3,4,5,6,7, Edilio Borroni2. 1. Roche Pharma Research and Early Development, Roche Innovation Center Basel, F. Hoffmann-La Roche Ltd., Basel, Switzerland michael.honer@roche.com. 2. Roche Pharma Research and Early Development, Roche Innovation Center Basel, F. Hoffmann-La Roche Ltd., Basel, Switzerland. 3. PET Center, Division of Nuclear Medicine, Russell H. Morgan Department of Radiology, Johns Hopkins University School of Medicine, Baltimore, Maryland. 4. Section of High Resolution Brain PET, PET Center, Division of Nuclear Medicine, Russell H. Morgan Department of Radiology, Johns Hopkins University School of Medicine, Baltimore, Maryland. 5. Solomon H. Snyder Department of Neuroscience, Johns Hopkins University School of Medicine, Baltimore, Maryland. 6. Department of Psychiatry and Behavioral Sciences, Johns Hopkins University School of Medicine, Baltimore, Maryland; and. 7. Department of Neurology, Johns Hopkins University School of Medicine, Baltimore, Maryland.
Abstract
Tau aggregates and amyloid-β (Aβ) plaques are key histopathologic features in Alzheimer disease (AD) and are considered targets for therapeutic intervention as well as biomarkers for diagnostic in vivo imaging agents. This article describes the preclinical in vitro and in vivo characterization of 3 novel compounds-RO6958948, RO6931643, and RO6924963-that bind specifically to tau aggregates and have the potential to become PET tracers for future human use. Methods: RO6958948, RO6931643, and RO6924963 were identified as high-affinity competitors at the 3H-T808 binding site on native tau aggregates in human late-stage AD brain tissue. Binding of tritiated compounds to brain tissue sections of AD patients and healthy controls was analyzed by macro- and microautoradiography and by costaining of tau aggregates and Aβ plaques on the same tissue section using specific antibodies. All 3 tracer candidates were radiolabeled with a PET nuclide and tested in vivo in tau-naïve baboons to assess brain uptake, distribution, clearance, and metabolism. Results: 3H-RO6958948, 3H-RO6931643, and 3H-RO6924963 bound with high affinity and specificity to tau aggregates, clearly lacking affinity for concomitant Aβ plaques in human AD Braak V tissue sections. The specificity of all 3 radioligands for tau aggregates was supported, first, by binding patterns in AD sections comparable to the tau-specific radioligand 3H-T808; second, by very low nonspecific binding in brain tissue devoid of tau pathology, excluding significant radioligand binding to any other central nervous system target; and third, by macroscopic and microscopic colocalization and quantitative correlation of radioligand binding and tau antibody staining on the same tissue section. RO6958948, RO6931643, and RO6924963 were successfully radiolabeled with a PET nuclide at high specific activity, radiochemical purity, and yield. After intravenous administration of 18F-RO6958948, 11C-RO6931643, and 11C-RO6924963 to baboons, PET scans indicated good brain entry, rapid washout, and a favorable metabolism pattern. Conclusion: 18F-RO6958948, 11C-RO6931643, and 11C-RO6924963 are promising PET tracers for visualization of tau aggregates in AD. Head-to-head comparison and validation of these tracer candidates in AD patients and healthy controls will be reported in due course.
Tau aggregates and amyloid-β (Aβ) plaques are key histopathologic features in Alzheimer disease (AD) and are considered targets for therapeutic intervention as well as biomarkers for diagnostic in vivo imaging agents. This article describes the preclinical in vitro and in vivo characterization of 3 novel compounds-RO6958948, RO6931643, and RO6924963-that bind specifically to tau aggregates and have the potential to become PET tracers for future human use. Methods:RO6958948, RO6931643, and RO6924963 were identified as high-affinity competitors at the 3H-T808 binding site on native tau aggregates in human late-stage AD brain tissue. Binding of tritiated compounds to brain tissue sections of ADpatients and healthy controls was analyzed by macro- and microautoradiography and by costaining of tau aggregates and Aβ plaques on the same tissue section using specific antibodies. All 3 tracer candidates were radiolabeled with a PET nuclide and tested in vivo in tau-naïve baboons to assess brain uptake, distribution, clearance, and metabolism. Results:3H-RO6958948, 3H-RO6931643, and 3H-RO6924963 bound with high affinity and specificity to tau aggregates, clearly lacking affinity for concomitant Aβ plaques in humanAD Braak V tissue sections. The specificity of all 3 radioligands for tau aggregates was supported, first, by binding patterns in AD sections comparable to the tau-specific radioligand 3H-T808; second, by very low nonspecific binding in brain tissue devoid of tau pathology, excluding significant radioligand binding to any other central nervous system target; and third, by macroscopic and microscopic colocalization and quantitative correlation of radioligand binding and tau antibody staining on the same tissue section. RO6958948, RO6931643, and RO6924963 were successfully radiolabeled with a PET nuclide at high specific activity, radiochemical purity, and yield. After intravenous administration of 18F-RO6958948, 11C-RO6931643, and 11C-RO6924963 to baboons, PET scans indicated good brain entry, rapid washout, and a favorable metabolism pattern. Conclusion:18F-RO6958948, 11C-RO6931643, and 11C-RO6924963 are promising PET tracers for visualization of tau aggregates in AD. Head-to-head comparison and validation of these tracer candidates in ADpatients and healthy controls will be reported in due course.
Authors: David T Chien; Shadfar Bahri; A Katrin Szardenings; Joseph C Walsh; Fanrong Mu; Min-Ying Su; William R Shankle; Arkadij Elizarov; Hartmuth C Kolb Journal: J Alzheimers Dis Date: 2013 Impact factor: 4.472
Authors: Abbas M Walji; Eric D Hostetler; Harold Selnick; Zhizhen Zeng; Patricia Miller; Idriss Bennacef; Cristian Salinas; Brett Connolly; Liza Gantert; Marie Holahan; Stacey O'Malley; Mona Purcell; Kerry Riffel; Jing Li; Jaume Balsells; Julie A OBrien; Stacey Melquist; Aileen Soriano; Xiaoping Zhang; Aimie Ogawa; Serena Xu; Elizabeth Joshi; Joseph Della Rocca; Fred J Hess; Joel Schachter; David Hesk; David Schenk; Arie Struyk; Kerim Babaoglu; Talakad G Lohith; Yaode Wang; Kun Yang; Jianmin Fu; Jeffrey L Evelhoch; Paul J Coleman Journal: J Med Chem Date: 2016-05-05 Impact factor: 7.446
Authors: Eric D Hostetler; Abbas M Walji; Zhizhen Zeng; Patricia Miller; Idriss Bennacef; Cristian Salinas; Brett Connolly; Liza Gantert; Hyking Haley; Marie Holahan; Mona Purcell; Kerry Riffel; Talakad G Lohith; Paul Coleman; Aileen Soriano; Aimie Ogawa; Serena Xu; Xiaoping Zhang; Elizabeth Joshi; Joseph Della Rocca; David Hesk; David J Schenk; Jeffrey L Evelhoch Journal: J Nucl Med Date: 2016-05-26 Impact factor: 10.057
Authors: J Logan; J S Fowler; N D Volkow; A P Wolf; S L Dewey; D J Schlyer; R R MacGregor; R Hitzemann; B Bendriem; S J Gatley Journal: J Cereb Blood Flow Metab Date: 1990-09 Impact factor: 6.200
Authors: Peter T Nelson; Irina Alafuzoff; Eileen H Bigio; Constantin Bouras; Heiko Braak; Nigel J Cairns; Rudolph J Castellani; Barbara J Crain; Peter Davies; Kelly Del Tredici; Charles Duyckaerts; Matthew P Frosch; Vahram Haroutunian; Patrick R Hof; Christine M Hulette; Bradley T Hyman; Takeshi Iwatsubo; Kurt A Jellinger; Gregory A Jicha; Enikö Kövari; Walter A Kukull; James B Leverenz; Seth Love; Ian R Mackenzie; David M Mann; Eliezer Masliah; Ann C McKee; Thomas J Montine; John C Morris; Julie A Schneider; Joshua A Sonnen; Dietmar R Thal; John Q Trojanowski; Juan C Troncoso; Thomas Wisniewski; Randall L Woltjer; Thomas G Beach Journal: J Neuropathol Exp Neurol Date: 2012-05 Impact factor: 3.685
Authors: Kerstin Sander; Tammaryn Lashley; Priya Gami; Thibault Gendron; Mark F Lythgoe; Jonathan D Rohrer; Jonathan M Schott; Tamas Revesz; Nick C Fox; Erik Årstad Journal: Alzheimers Dement Date: 2016-02-15 Impact factor: 21.566
Authors: Val J Lowe; Geoffry Curran; Ping Fang; Amanda M Liesinger; Keith A Josephs; Joseph E Parisi; Kejal Kantarci; Bradley F Boeve; Mukesh K Pandey; Tyler Bruinsma; David S Knopman; David T Jones; Leonard Petrucelli; Casey N Cook; Neill R Graff-Radford; Dennis W Dickson; Ronald C Petersen; Clifford R Jack; Melissa E Murray Journal: Acta Neuropathol Commun Date: 2016-06-13 Impact factor: 7.801
Authors: Hiroto Kuwabara; Robert A Comley; Edilio Borroni; Michael Honer; Kelly Kitmiller; Joshua Roberts; Lorena Gapasin; Anil Mathur; Gregory Klein; Dean F Wong Journal: J Nucl Med Date: 2018-08-10 Impact factor: 10.057
Authors: Dean F Wong; Robert A Comley; Hiroto Kuwabara; Paul B Rosenberg; Susan M Resnick; Susanne Ostrowitzki; Cristina Vozzi; Frank Boess; Esther Oh; Constantine G Lyketsos; Michael Honer; Luca Gobbi; Gregory Klein; Noble George; Lorena Gapasin; Kelly Kitzmiller; Josh Roberts; Jeff Sevigny; Ayon Nandi; James Brasic; Chakradhar Mishra; Madhav Thambisetty; Abhay Mogekar; Anil Mathur; Marilyn Albert; Robert F Dannals; Edilio Borroni Journal: J Nucl Med Date: 2018-05-04 Impact factor: 10.057
Authors: Rik Ossenkoppele; Antoine Leuzy; Hanna Cho; Carole H Sudre; Olof Strandberg; Ruben Smith; Sebastian Palmqvist; Niklas Mattsson-Carlgren; Tomas Olsson; Jonas Jögi; Erik Stormrud; Young Hoon Ryu; Jae Yong Choi; Adam L Boxer; Maria L Gorno-Tempini; Bruce L Miller; David Soleimani-Meigooni; Leonardo Iaccarino; Renaud La Joie; Edilio Borroni; Gregory Klein; Michael J Pontecorvo; Michael D Devous; Sylvia Villeneuve; Chul Hyoung Lyoo; Gil D Rabinovici; Oskar Hansson Journal: Eur J Nucl Med Mol Imaging Date: 2020-11-19 Impact factor: 9.236
Authors: Antoine Leuzy; Tharick A Pascoal; Olof Strandberg; Philip Insel; Ruben Smith; Niklas Mattsson-Carlgren; Andréa L Benedet; Hannah Cho; Chul H Lyoo; Renaud La Joie; Gil D Rabinovici; Rik Ossenkoppele; Pedro Rosa-Neto; Oskar Hansson Journal: Eur J Nucl Med Mol Imaging Date: 2021-05-27 Impact factor: 9.236