PURPOSE: The purpose of this study was to analyze the effects of aerobic exercise on the expression of synaptic vesicle transporter and antioxidant enzymes in obesity and to investigate the feasibility of exercise training to reduce AD pathogenesis in the 3xTg-AD mice fed a high fat diet.
METHODS: Male 3 month old 3xTg-AD mice were divided into standard chow(SC, n=10), standard chow+exercise (SC-EXE, n=10), high fat diet (HFD, n=10), and high fat diet+exercise (HFD-EXE, n=10) groups. EXE mice were subjected to treadmill running at a moderate intensity with duration of 30 minutes per day and frequency of 5 days per week for 12 weeks. HFD mice were fed a 60% fat HFD during the same period. Mice were sacrificed and immunohistology and western blot analysis were performed.
RESULTS: Compared with the SC mice, the HFD mice had significantly higher levels of Aβ (p<.01), p-tau/t-tau (p<.01) and defects of Vglut1 (p<.05), VGAT (p<.05), postsynaptic density 95 (p<.01) and GPX (p<.05) in the hippocampus. On the other hand, we found that treadmill running attenuated HFD-induced exacerbations of Aβ (p<.01), p-tau/t-tau (p<.05) and defects of Vglut1 (p<.01), Synaptophysin (p<.05), SOD1 (p<.05) in the hippocampus.
CONCLUSIONS: High fat diet-induced obesity resulted in increased AD neuropathology and decreased synaptic vesicle transporter and antioxidant enzyme in the hippocampus of 3xTg-AD mice. However, aerobic exercise delayed AD-like disease progression, alleviated impaired synaptic function and the decreased expression of antioxidant enzymes in the hippocampus.

1 Chowdhury TG, "Voluntary Wheel Running Exercise Evoked by Food-Restriction Stress Exacerbates Weight Loss of Adolescent Female Rats But Also Promotes Resilience by Enhancing GABAergic Inhibition of Pyramidal Neurons in the Dorsal Hippocampus" 29 (29): 4035-4049, 2019

2 Jolivalt CG, "Type 1 diabetes exaggerates features of Alzheimer’s disease in APP transgenic mice" 223 (223): 422-431, 2010

3 Cho J, "Treadmill running reverses cognitive declines due to Alzheimer disease" 47 (47): 1814-1824, 2015

4 Shin MS, "Treadmill exercise ameliorates symptoms of methimazole-induced hypothyroidism through enhancing neurogenesis and suppressing apoptosis in the hippocampus of rat pups" 31 (31): 214-223, 2013

5 Zhuang PC, "Treadmill Exercise Reverses Depression Model-Induced Alteration of Dendritic Spines in the Brain Areas of Mood Circuit" 13 : 93-, 2019

6 Spires-Jones TL, "The intersection of amyloid beta and tau at synapses in Alzheimer’s disease" 82 (82): 756-771, 2014

7 Hansson GK, "The immune system in atherosclerosis" 12 : 204-212, 2011

8 Bak LK, "The glutamate/GABA-glutamine cycle : aspects of transport, neurotransmitter homeostasis and ammonia transfer" 98 (98): 641-653, 2006

9 Lei M, "Soluble Aβ oligomers impair hippocampal LTP by disrupting glutamatergic/GABAergic balance" 85 : 111-121, 2016

10 Nakandakari SCBR, "Short-term high-fat diet modulates several inflammatory, ER stress, and apoptosis markers in the hippocampus of young mice" 79 : 284-293, 2019

11 Ziebell JM, "Rod microglia : elongation, alignment, and coupling to form trains across the somatosensory cortex after experimental diffuse brain injury" 9 (9): 247-, 2012

12 Pradeepkiran JA, "Protective effects of BACE1 inhibitory ligand molecules against amyloid beta-induced synaptic and mitochondrial toxicities in Alzheimer’s disease" 29 (29): 49-69, 2020

13 Thierry Paillard, "Protective Efects of Physical Exercise in Alzheimer’s Disease and Parkinson’s Disease: A Narrative Review" 대한신경과학회 11 (11): 212-219, 2015

14 Tuon T, "Physical training exerts neuroprotective effects in the regulation of neurochemical factors in an animal model of Parkinson’s disease" 227 : 305-312, 2012

15 García-Mesa Y, "Physical exercise protects against Alzheimer’s disease in 3xTgAD mice" 24 (24): 421-454, 2011

16 Schoenfeld TJ, "Physical exercise prevents stress-induced activation of granule neurons and enhances local inhibitory mechanisms in the dentate gyrus" 33 (33): 7770-7777, 2013

17 Revilla S, "Physical exercise improves synaptic dysfunction and recovers the loss of survival factors in 3xTg-AD mouse brain" 81 : 55-63, 2014

18 Franciosi S, "Novel cerebrovascular pathology in mice fed a high cholesterol diet" 4 : 42-, 2009

19 Zolezzi JM, "Neuroprotective Effects of Ferruginol, Jatrophone, and Junicedric Acid Against Amyloid-β Injury in Hippocampal Neurons" 63 (63): 705-723, 2018

20 Shin MK, "Neuropep-1ameliorates learning and memory deficits in an Alzheimer’s disease mouse model, increases brain-derived neurotrophic factor expression in the brain, and causes reduction of amyloid beta plaques" 35 (35): 990-1001, 2014

21 Lizarbe B, "Neurochemical Modifications in the Hippocampus, Cortex and Hypothalamus of Mice Exposed to Long-Term High-Fat Diet" 12 : 985-, 2019

22 Vershinin M, "Multiplemotor based transport and its regulation by Tau" 104 (104): 87-92, 2007

23 Knafo S, "Morphological alterations to neurons of the amygdala and impaired fear conditioning in a transgenic mouse model of Alzheimer’s disease" 219 (219): 41-51, 2009

24 Bettio L, "Modulation of synaptic plasticity by exercise" 147 : 295-322, 2019

25 Mazzone GL, "Modulation of extrasynaptic GABAergic receptor activity influences glutamate release and neuronal survival following excitotoxic damage to mouse spinal cord neurons" 128 : 175-185, 2019

26 Chuang YF, "Midlife adiposity predicts earlier onset of Alzheimer’s dementia, neuropathology and presymptomatic cerebral amyloid accumulation" 21 (21): 910-915, 2016

27 Profenno LA, "Meta-analysis of Alzheimer’s disease risk with obesity, diabetes, and related disorders" 67 (67): 505-512, 2010

28 Kim J, "Maternal Protein Restriction Altered Insulin Resistance and Inflammation-Associated Gene Expression in Adipose Tissue of Young Adult Mouse Offspring in Response to a HighFat Diet" 12 (12): E1103-, 2020

29 "Korean Dementia observatory"

30 Diehl T, "Insulin resistance in Alzheimer’s disease" 183 : 26-40, 2017

31 Baek SH, "Inhibition of Drp1Ameliorates Synaptic Depression, Aβ Deposition, and Cognitive Impairment in an Alzheimer’s Disease Model" 37 (37): 5099-6010, 2017

32 Soehnlein O, "Hypercholesterolemia links hematopoiesis with atherosclerosis" 24 : 129-136, 2013

33 Lin B, "High-Fat-Diet Intake Enhances Cerebral Amyloid Angiopathy and Cognitive Impairment in a Mouse Model of Alzheimer’s Disease, Independently of Metabolic Disorders" 5 (5): e003154-, 2016

34 Guerriero RM, "Glutamate and GABA imbalance following traumatic brain injury" 15 (15): 27-, 2015

35 Quevenco FC, "GABA and glutamate moderate beta-amyloid related functional connectivity in cognitively unimpaired old-aged adults" 22 : 101776-, 2019

36 Wang R, "Exercise-induced brain-derived neurotrophic factor expression : Therapeutic implications for Alzheimer’s dementia" 48 : 109-121, 2018

37 Liu PZ, "Exercise-Mediated Neurogenesis in the Hippocampus via BDNF" 12 : 52-, 2018

38 Maesako M, "Exercise is more effective than diet control in preventing high fat diet-induced β-amyloid deposition and memory deficit in amyloid precursor protein transgenic mice" 287 (287): 23024-23033, 2012

39 Morland C, "Exercise induces cerebral VEGF and angiogenesis via the lactate receptor HCAR1" 8 : 15557-, 2017

40 Liang X, "Exercise improves depressive symptoms by increasing the number of excitatory synapses in the hippocampus of CUS-Induced depression model rats" 374 : 112115-, 2019

41 Kar S, "Exercise Training Promotes Cardiac Hydrogen Sulfide Biosynthesis and Mitigates Pyroptosis to Prevent High-Fat Diet-Induced Diabetic Cardiomyopathy" 8 (8): E638-, 2019

42 Kim D, "Exercise Attenuates High-Fat Dietinduced Disease Progression in 3xTg-AD Mice" 49 (49): 676-686, 2017

43 de Souza RF, "Endurance training on rodent brain antioxidant capacity : A meta-analysis" 145 : 1-9, 2019

44 Asadbegi M, "Effects of thymol on amyloid-β-induced impairments in hippocampal synaptic plasticity in rats fed a high-fat diet" 137 : 338-350, 2018

45 Lee MK, "Effects of resistance exercise on antioxidant enzyme activities and apoptosis-related protein expression of hippocampus in OLETF rats" 26 (26): 457-467, 2018

46 Kang DW, "Effects of aquatic exercise on insulinlike growth factor-1, brain-derived neurotrophic factor, vascular endothelial growth factor, and cognitive function in elderly women" 132 : 110842-, 2020

47 Kirvell SL, "Down-regulation of vesicular glutamate transporters precedes cell loss and pathology in Alzheimer’s disease" 98 (98): 939-950, 2006

48 Cavalier M, "Disturbance of Metabotropic Glutamate Receptor-Mediated LongTerm Depression(mGlu-LTD)of Excitatory Synaptic Transmission in the Rat Hippocampus After Prenatal Immune Challenge" 44 (44): 609-616, 2019

49 Dixit R, "Differential regulation of dynein and kinesin motor proteins by tau" 319 (319): 1086-1089, 2008

50 Hascup ER, "Dietinduced insulin resistance elevates hippocampal glutamate as well as VGLUT1 and GFAP expression in AβPP/PS1 mice" 148 (148): 219-237, 2019

51 Samadi M, "Dietary pattern in relation to the risk of Alzheimer’s disease : a systematic review" 40 (40): 2031-2043, 2019

52 Ho L, "Diet-induced insulin resistance promotes amyloidosis in a transgenic mouse model of Alzheimer’s disease" 18 (18): 902-904, 2004

53 Talbot K, "Demonstrated brain insulin resistance in Alzheimer’s disease patients is associated with IGF-1 resistance, IRS-1 dysregulation, and cognitive decline" 122 (122): 1316-1338, 2012

54 Rollins CPE, "Contributions of a high-fat diet to Alzheimer’s disease-related decline : A longitudinal behavioural and structural neuroimaging study in mouse models" 21 : 101606-, 2019

55 Liraz O, "ApoE4 induces Aβ42, tau, and neuronal pathology in the hippocampus of young targeted replacement apoE4 mice" 8 : 16-, 2013

56 Ding Y, "Amyloid Beta Oligomers Target to Extracellular and Intracellular Neuronal Synaptic Proteins in Alzheimer’s Disease" 10 : 1140-, 2019

57 Oyelami T, "Age-dependent concomitant changes in synaptic dysfunction and GABAergic pathway in the APP/PS1 mouse model" 76 (76): 282-293, 2016

58 Zhang BB, "A Nitric OxideDependent Presynaptic LTP at Glutamatergic Synapses of the PVN Magnocellular Neurosecretory Cells in vitro in Rats" 13 : 283-, 2019