Restoring hippocampal glucose metabolism rescues cognition across Alzheimer’s disease pathologies

Paras S. Minhas(Neurosciences Institute), Jeffrey R. Jones(Salk Institute for Biological Studies), Amira Latif‐Hernandez(Stanford University), Yuki Sugiura(Meiji University), Aarooran S. Durairaj(Stanford University), Qian Wang(Stanford University), Siddhita D. Mhatre(Stanford University), Takeshi Uenaka(Stanford University), Joshua Crapser(Stanford University), Travis E. Conley(Stanford University), Hannah Ennerfelt(Stanford University), Yoo Jin Jung(Stanford University), Ling Liu(Princeton University), Praveena Prasad(Pennsylvania State University), Brenita C. Jenkins(Pennsylvania State University), Yeonglong Albert Ay(Stanford University), Matthew Matrongolo(Stanford University), Ryan Goodman(Salk Institute for Biological Studies), Traci Fang Newmeyer(Salk Institute for Biological Studies), Kelly J. Heard(Salk Institute for Biological Studies), Austin Kang(Salk Institute for Biological Studies), Edward N. Wilson(Stanford University), Tao Yang(Stanford University), Erik M. Ullian(University of California, San Francisco), Geidy E. Serrano(Banner Sun Health Research Institute), Thomas G. Beach(Banner Sun Health Research Institute), Marius Wernig(Stanford University), Joshua D. Rabinowitz(Princeton University), Makoto Suematsu(Meiji University), Frank M. Longo(Neurosciences Institute), Melanie R. McReynolds(Pennsylvania State University), Fred H. Gage(Salk Institute for Biological Studies), Katrin I. Andreasson(Neurosciences Institute)
Science
August 22, 2024
10.1126/science.abm6131
Cited by 193Open Access
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Abstract

Impaired cerebral glucose metabolism is a pathologic feature of Alzheimer's disease (AD), with recent proteomic studies highlighting disrupted glial metabolism in AD. We report that inhibition of indoleamine-2,3-dioxygenase 1 (IDO1), which metabolizes tryptophan to kynurenine (KYN), rescues hippocampal memory function in mouse preclinical models of AD by restoring astrocyte metabolism. Activation of astrocytic IDO1 by amyloid β and tau oligomers increases KYN and suppresses glycolysis in an aryl hydrocarbon receptor-dependent manner. In amyloid and tau models, IDO1 inhibition improves hippocampal glucose metabolism and rescues hippocampal long-term potentiation in a monocarboxylate transporter-dependent manner. In astrocytic and neuronal cocultures from AD subjects, IDO1 inhibition improved astrocytic production of lactate and uptake by neurons. Thus, IDO1 inhibitors presently developed for cancer might be repurposed for treatment of AD.

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