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- Title
Brain Insulin Signaling Is Increased in Insulin-Resistant States and Decreases in FOXOs and PGC-1α and Increases in Aβ1-40/42 and Phospho-Tau May Abet Alzheimer Development.
- Authors
Sajan, Mini; Hansen, Barbara; Ivey III, Robert; Sajan, Joshua; Ari, Csilla; Song, Shijie; Braun, Ursula; Leitges, Michael; Farese-Higgs, Margaret; Farese, Robert V.; Ivey, Robert 3rd
- Abstract
Increased coexistence of Alzheimer disease (AD) and type 2 diabetes mellitus (T2DM) suggests that insulin resistance abets neurodegenerative processes, but linkage mechanisms are obscure. Here, we examined insulin signaling factors in brains of insulin-resistant high-fat-fed mice, ob/ob mice, mice with genetically impaired muscle glucose transport, and monkeys with diet-dependent long-standing obesity/T2DM. In each model, the resting/basal activities of insulin-regulated brain protein kinases, Akt and atypical protein kinase C (aPKC), were maximally increased. Moreover, Akt hyperactivation was accompanied by hyperphosphorylation of substrates glycogen synthase kinase-3β and mammalian target of rapamycin and FOXO proteins FOXO1, FOXO3A, and FOXO4 and decreased peroxisome proliferator-activated receptor γ coactivator-1α (PGC-1α) expression. Akt hyperactivation was confirmed in individual neurons of anterocortical and hippocampal regions that house cognition/memory centers. Remarkably, β-amyloid (Aβ1-40/42) peptide levels were as follows: increased in the short term by insulin in normal mice, increased basally in insulin-resistant mice and monkeys, and accompanied by diminished amyloid precursor protein in monkeys. Phosphorylated tau levels were increased in ob/ob mice and T2DM monkeys. Importantly, with correction of hyperinsulinemia by inhibition of hepatic aPKC and improvement in systemic insulin resistance, brain insulin signaling normalized. As FOXOs and PGC-1α are essential for memory and long-term neuronal function and regeneration and as Aβ1-40/42 and phospho-tau may increase interneuronal plaques and intraneuronal tangles, presently observed aberrations in hyperinsulinemic states may participate in linking insulin resistance to AD.
- Subjects
ALZHEIMER'S disease; TYPE 2 diabetes; NEURODEGENERATION; PEPTIDE synthesis; INSULIN resistance; PROTEIN metabolism; BRAIN metabolism; ANIMAL experimentation; BRAIN; CELLULAR signal transduction; DIET; INSULIN; MICE; NERVE tissue proteins; NEURONS; OBESITY; PEPTIDES; PHOSPHORYLATION; PRIMATES; RESEARCH funding; TRANSFERASES
- Publication
Diabetes, 2016, Vol 65, Issue 7, p1892
- ISSN
0012-1797
- Publication type
journal article
- DOI
10.2337/db15-1428