Cellular and Molecular Mechanisms for Age-Related Cognitive Decline

Jolie D. Barter; Thomas C. Foster

doi:10.1017/9781108554350.003

Chapter 3 - Cellular and Molecular Mechanisms for Age-Related Cognitive Decline

Published online by Cambridge University Press: 30 November 2019

Jolie D. Barter and

Thomas C. Foster

Edited by

Kenneth M. Heilman and

Stephen E. Nadeau

Show author details

Kenneth M. Heilman: Affiliation:
University of Florida
Stephen E. Nadeau: Affiliation:
University of Florida

Book contents

Get access

Summary

Aging is often associated with a progressive decline of cognitive functions, due in part to the susceptibility of specific brain regions to stressors of aging. However, chronological age is a poor predictor of cognition. Cognitive decline is variable in terms of onset and progression, suggesting that biological age, due to differences in biological mechanisms that regulate vulnerability, is a better predictor of cognitive decline. As with humans, animal models exhibit variability in age-related cognitive decline, and this variability has been employed to determine biomarkers and mechanisms of cognitive impairment. Based on these animal models, theories of age-related cognitive decline have evolved. Recent work has focused on senescent physiology, rather than cell death associated with neurodegenerative disease. The results suggest that age-related alterations in redox stress modify Ca2+ regulation to alter learning and memory mechanisms, as well as signaling cascades from the synapse to the nucleus. Furthermore, the stressors of aging, senescent physiology, and environmental factors interact with epigenetic mechanisms contributing variability in gene transcription, resulting in variability in resiliency, onset, and the progression of the aging phenotype.

Keywords

aging epigenetics episodic memory executive function senescent physiology synaptic plasticity

Type: Chapter
Information: Cognitive Changes and the Aging Brain , pp. 16 - 27

DOI: https://doi.org/10.1017/9781108554350.003 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2019

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

de Flores, R, La Joie, R, Chetelat, G. Structural imaging of hippocampal subfields in healthy aging and Alzheimer’s disease. Neuroscience. 2015;309:29–50.CrossRef Google Scholar PubMed

Kerchner, GA, Bernstein, JD, Fenesy, MC, Deutsch, GK, Saranathan, M, Zeineh, MM, et al. Shared vulnerability of two synaptically-connected medial temporal lobe areas to age and cognitive decline: a seven tesla magnetic resonance imaging study. J Neurosci. 2013;33(42):16666–72.CrossRef Google Scholar PubMed

Kirchhoff, BA, Gordon, BA, Head, D. Prefrontal gray matter volume mediates age effects on memory strategies. Neuroimage. 2014;90:326–34.Google Scholar

Raz, N, Gunning, FM, Head, D, Dupuis, JH, McQuain, J, Briggs, SD, et al. Selective aging of the human cerebral cortex observed in vivo: differential vulnerability of the prefrontal gray matter. Cereb Cortex. 1997;7(3):268–82.Google Scholar

Salat, DH, Buckner, RL, Snyder, AZ, Greve, DN, Desikan, RS, Busa, E, et al. Thinning of the cerebral cortex in aging. Cereb Cortex. 2004;14(7):721–30.Google Scholar

Wolf, D, Fischer, FU, de Flores, R, Chetelat, G, Fellgiebel, A. Differential associations of age with volume and microstructure of hippocampal subfields in healthy older adults. Hum Brain Mapp. 2015;36(10):3819–31.CrossRef Google Scholar PubMed

Raz, N, Ghisletta, P, Rodrigue, KM, Kennedy, KM, Lindenberger, U. Trajectories of brain aging in middle-aged and older adults: regional and individual differences. Neuroimage. 2010;51(2):501–11.Google Scholar

Jackson, TC, Rani, A, Kumar, A, Foster, TC. Regional hippocampal differences in AKT survival signaling across the lifespan: implications for CA1 vulnerability with aging. Cell Death Differ. 2009;16(3):439–48.Google Scholar

McEwen, BS, Morrison, JH. The brain on stress: vulnerability and plasticity of the prefrontal cortex over the life course. Neuron. 2013;79(1):16–29.CrossRef Google Scholar PubMed

Wang, X, Michaelis, EK. Selective neuronal vulnerability to oxidative stress in the brain. Front Aging Neurosci. 2010;2:12.Google Scholar PubMed

Abd El Mohsen, MM, Iravani, MM, Spencer, JP, Rose, S, Fahim, AT, Motawi, TM, et al. Age-associated changes in protein oxidation and proteasome activities in rat brain: modulation by antioxidants. Biochem Biophys Res Commun. 2005;336(2):386–91.Google Scholar

Dominguez, M, de Oliveira, E, Odena, MA, Portero, M, Pamplona, R, Ferrer, I. Redox proteomic profiling of neuroketal-adducted proteins in human brain: regional vulnerability at middle age increases in the elderly. Free Radic Biol Med. 2016;95:1–15.Google Scholar

Horvath, S, Mah, V, Lu, AT, Woo, JS, Choi, OW, Jasinska, AJ, et al. The cerebellum ages slowly according to the epigenetic clock. Aging (Albany NY). 2015;7(5):294–306.Google Scholar

Kumar, A, Gibbs, JR, Beilina, A, Dillman, A, Kumaran, R, Trabzuni, D, et al. Age-associated changes in gene expression in human brain and isolated neurons. Neurobiol Aging. 2013;34(4):1199–209.Google Scholar

Ianov, L, De Both, M, Chawla, MK, Rani, A, Kennedy, AJ, Piras, I, et al. Hippocampal transcriptomic profiles: subfield vulnerability to age and cognitive impairment. Front Aging Neurosci. 2017;9:383.Google Scholar

Foster, TC. Biological markers of age-related memory deficits: treatment of senescent physiology. CNS Drugs. 2006;20(2):153–66.Google Scholar

Febo, M, Foster, TC. Preclinical magnetic resonance imaging and spectroscopy studies of memory, aging, and cognitive decline. Front Aging Neurosci. 2016;8:158.Google Scholar

Goh, JO, An, Y, Resnick, SM. Differential trajectories of age-related changes in components of executive and memory processes. Psychol Aging. 2012;27(3):707–19.Google Scholar

McAvinue, LP, Habekost, T, Johnson, KA, Kyllingsbaek, S, Vangkilde, S, Bundesen, C, et al. Sustained attention, attentional selectivity, and attentional capacity across the lifespan. Atten Percept Psychophys. 2012;74(8):1570–82.Google Scholar

Guidi, M, Kumar, A, Foster, TC. Impaired attention and synaptic senescence of the prefrontal cortex involves redox regulation of NMDA receptors. J Neurosci. 2015;35(9):3966–77.Google Scholar

Jones, DN, Barnes, JC, Kirkby, DL, Higgins, GA. Age-associated impairments in a test of attention: evidence for involvement of cholinergic systems. J Neurosci. 1995;15(11):7282–92.Google Scholar

Fortenbaugh, FC, DeGutis, J, Germine, L, Wilmer, JB, Grosso, M, Russo, K, et al. Sustained attention across the life span in a sample of 10,000: dissociating ability and strategy. Psychol Sci. 2015;26(9):1497–510.Google Scholar

Bimonte, HA, Nelson, ME, Granholm, AC. Age-related deficits as working memory load increases: relationships with growth factors. Neurobiol Aging. 2003;24(1):37–48.Google Scholar

Bopp, KL, Verhaeghen, P. Aging and verbal memory span: a meta-analysis. J Gerontol B Psychol Sci Soc Sci. 2005;60(5):P223–33.Google Scholar

Brockmole, JR, Logie, RH. Age-related change in visual working memory: a study of 55,753 participants aged 8–75. Front Psychol. 2013;4:12.Google Scholar

Dellu-Hagedorn, F, Trunet, S, Simon, H. Impulsivity in youth predicts early age-related cognitive deficits in rats. Neurobiol Aging. 2004;25(4):525–37.Google Scholar

Moss, MB, Killiany, RJ, Lai, ZC, Rosene, DL, Herndon, JG. Recognition memory span in rhesus monkeys of advanced age. Neurobiol Aging. 1997;18(1):13–19.Google Scholar

Tapp, PD, Siwak, CT, Estrada, J, Holowachuk, D, Milgram, NW. Effects of age on measures of complex working memory span in the beagle dog (Canis familiaris) using two versions of a spatial list learning paradigm. Learn Mem. 2003;10(2):148–60.Google Scholar

Robbins, TW, James, M, Owen, AM, Sahakian, BJ, Lawrence, AD, McInnes, L, et al. A study of performance on tests from the CANTAB battery sensitive to frontal lobe dysfunction in a large sample of normal volunteers: implications for theories of executive functioning and cognitive aging. Cambridge Neuropsychological Test Automated Battery. J Int Neuropsychol Soc. 1998;4(5):474–90.Google Scholar

Rhodes, MG. Age-related differences in performance on the Wisconsin card sorting test: a meta-analytic review. Psychology Aging. 2004;19(3):482–94.Google Scholar

Fisk, JE, Sharp, CA. Age-related impairment in executive functioning: updating, inhibition, shifting, and access. J Clin Exp Neuropsychol. 2004;26(7):874–90.Google Scholar

Ianov, L, Rani, A, Beas, BS, Kumar, A, Foster, TC. Transcription profile of aging and cognition-related genes in the medial prefrontal cortex. Front Aging Neurosci. 2016;8:113.Google Scholar

Small, GW. What we need to know about age related memory loss. BMJ. 2002;324(7352):1502–5.Google Scholar

Cansino, S. Episodic memory decay along the adult lifespan: a review of behavioral and neurophysiological evidence. Int J Psychophysiol. 2009;71(1):64–9.Google Scholar

Uttl, B, Graf, P. Episodic spatial memory in adulthood. Psychol Aging. 1993;8(2):257–73.CrossRef Google Scholar PubMed

Nyberg, L, Lovden, M, Riklund, K, Lindenberger, U, Backman, L. Memory aging and brain maintenance. Trends Cogn Sci. 2012;16(5):292–305.CrossRef Google Scholar PubMed

Foster, TC. Dissecting the age-related decline on spatial learning and memory tasks in rodent models: N-methyl-D-aspartate receptors and voltage-dependent Ca²⁺ channels in senescent synaptic plasticity. Prog Neurobiol. 2012;96(3):283–303.CrossRef Google Scholar PubMed

Khachaturian, ZS. Hypothesis on the regulation of cytosol calcium concentration and the aging brain. Neurobiol Aging. 1987;8(4):345–6.CrossRef Google Scholar PubMed

Michaelis, ML, Johe, K, Kitos, TE. Age-dependent alterations in synaptic membrane systems for Ca²⁺ regulation. Mech Ageing Dev. 1984;25(1–2):215–25.Google Scholar

Landfield, PW, Pitler, TA. Prolonged Ca²⁺-dependent afterhyperpolarizations in hippocampal neurons of aged rats. Science. 1984;226(4678):1089–92.Google Scholar

Rapp, PR, Gallagher, M. Preserved neuron number in the hippocampus of aged rats with spatial learning deficits. Proc Natl Acad Sci USA. 1996;93(18):9926–30.Google Scholar

West, MJ, Coleman, PD, Flood, DG, Troncoso, JC. Differences in the pattern of hippocampal neuronal loss in normal ageing and Alzheimer’s disease. Lancet. 1994;344(8925):769–72.Google Scholar

Barnes, CA, McNaughton, BL. An age comparison of the rates of acquisition and forgetting of spatial information in relation to long-term enhancement of hippocampal synapses. Behav Neurosci. 1985;99(6):1040–8.Google Scholar

Foster, TC, Kumar, A. Susceptibility to induction of long-term depression is associated with impaired memory in aged Fischer 344 rats. Neurobiol Learn Mem. 2007;87(4):522–35.CrossRef Google Scholar PubMed

Norris, CM, Korol, DL, Foster, TC. Increased susceptibility to induction of long-term depression and long-term potentiation reversal during aging. J Neurosci. 1996;16(17):5382–92.Google Scholar

Kumar, A, Foster, TC. Linking redox regulation of NMDAR synaptic function to cognitive decline during aging. J Neurosci. 2013;33(40):15710–15.Google Scholar

Elman, JA, Oh, H, Madison, CM, Baker, SL, Vogel, JW, Marks, SM, et al. Neural compensation in older people with brain amyloid-beta deposition. Nat Neurosci. 2014;17(10):1316–18.CrossRef Google Scholar PubMed

O’Brien, JL, O’Keefe, KM, LaViolette, PS, DeLuca, AN, Blacker, D, Dickerson, BC, et al. Longitudinal fMRI in elderly reveals loss of hippocampal activation with clinical decline. Neurology. 2010;74(24):1969–76.Google Scholar

Foster, TC. Calcium homeostasis and modulation of synaptic plasticity in the aged brain. Aging Cell. 2007;6(3):319–25.CrossRef Google Scholar PubMed

Bodhinathan, K, Kumar, A, Foster, TC. Intracellular redox state alters NMDA receptor response during aging through Ca²⁺/calmodulin-dependent protein kinase II. J Neurosci. 2010;30(5):1914–24.Google Scholar

Foster, TC, Norris, CM. Age-associated changes in Ca(2+)-dependent processes: relation to hippocampal synaptic plasticity. Hippocampus. 1997;7(6):602–12.Google Scholar

Kumar, A, Foster, TC. Enhanced long-term potentiation during aging is masked by processes involving intracellular calcium stores. J Neurophysiol. 2004;91(6):2437–44.Google Scholar

Bodhinathan, K, Kumar, A, Foster, TC. Redox sensitive calcium stores underlie enhanced after hyperpolarization of aged neurons: role for ryanodine receptor mediated calcium signaling. J Neurophysiol. 2010;104(5):2586–93.Google Scholar

Kumar, A, Foster, TC. Intracellular calcium stores contribute to increased susceptibility to LTD induction during aging. Brain Res. 2005;1031(1):125–8.Google Scholar

Homayoun, H, Moghaddam, B. NMDA receptor hypofunction produces opposite effects on prefrontal cortex interneurons and pyramidal neurons. J Neurosci. 2007;27(43):11496–500.Google Scholar

Porges, EC, Woods, AJ, Edden, RA, Puts, NA, Harris, AD, Chen, H, et al. Frontal gamma-aminobutyric acid concentrations are associated with cognitive performance in older adults. Biol Psychiatry Cogn Neurosci Neuroimaging. 2017;2(1):38–44.Google Scholar PubMed

Morgan, CJ, Curran, HV. Acute and chronic effects of ketamine upon human memory: a review. Psychopharmacology (Berl). 2006;188(4):408–24.Google Scholar

Forette, F, Seux, ML, Staessen, JA, Thijs, L, Babarskiene, MR, Babeanu, S, et al. The prevention of dementia with antihypertensive treatment: new evidence from the Systolic Hypertension in Europe (Syst-Eur) study. Arch Intern Med. 2002;162(18):2046–52.Google Scholar

Lovell, MA, Abner, E, Kryscio, R, Xu, L, Fister, SX, Lynn, BC. Calcium channel blockers, progression to dementia, and effects on amyloid beta peptide production. Oxid Med Cell Longev. 2015;2015:787805.Google Scholar

Trompet, S, Westendorp, RG, Kamper, AM, de Craen, AJ. Use of calcium antagonists and cognitive decline in old age. The Leiden 85-plus study. Neurobiol Aging. 2008;29(2):306–8.Google Scholar

Barnes, CA. Memory deficits associated with senescence: a neurophysiological and behavioral study in the rat. J Comp Physiol Psychol. 1979;93(1):74–104.Google Scholar

Daselaar, SM, Iyengar, V, Davis, SW, Eklund, K, Hayes, SM, Cabeza, RE. Less wiring, more firing: low-performing older adults compensate for impaired white matter with greater neural activity. Cereb Cortex. 2015;25(4):983–90.Google Scholar

Kumar, A, Foster, TC. Neurophysiology of old neurons and synapses. In: Riddle, DR, editor. Brain Aging: Models, Methods, and Mechanisms. Frontiers in Neuroscience. Boca Raton, FL, 2007.Google Scholar

Neuman, KM, Molina-Campos, E, Musial, TF, Price, AL, Oh, KJ, Wolke, ML, et al. Evidence for Alzheimer’s disease-linked synapse loss and compensation in mouse and human hippocampal CA1 pyramidal neurons. Brain Struct Funct. 2015;220(6):3143–65.Google Scholar

Mormino, EC, Brandel, MG, Madison, CM, Marks, S, Baker, SL, Jagust, WJ. Aβ deposition in aging is associated with increases in brain activation during successful memory encoding. Cereb Cortex. 2012;22(8):1813–23.Google Scholar

Kennedy, KM, Rodrigue, KM, Bischof, GN, Hebrank, AC, Reuter-Lorenz, PA, Park, DC. Age trajectories of functional activation under conditions of low and high processing demands: an adult lifespan fMRI study of the aging brain. Neuroimage. 2015;104:21–34.Google Scholar

Reuter-Lorenz, PA, Park, DC. Human neuroscience and the aging mind: a new look at old problems. J Gerontol B Psychol Sci Soc Sci. 2010;65(4):405–15.Google Scholar

Davis, SW, Dennis, NA, Daselaar, SM, Fleck, MS, Cabeza, R. Que PASA? The posterior-anterior shift in aging. Cereb Cortex. 2008;18(5):1201–9.Google Scholar

Oberman, L, Pascual-Leone, A. Changes in plasticity across the lifespan: cause of disease and target for intervention. Prog Brain Res. 2013;207:91–120.Google Scholar

Kumar, A, Yegla, B, Foster, TC. Redox signaling in neurotransmission and cognition during aging. Antioxid Redox Signal. 2018;28:1724–1745.Google Scholar

Harman, D. Aging and oxidative stress. J Int Fed Clin Chem. 1998;10(1):24–7.Google Scholar

Lee, WH, Kumar, A, Rani, A, Foster, TC. Role of antioxidant enzymes in redox regulation of N-methyl-D-aspartate receptor function and memory in middle-aged rats. Neurobiol Aging. 2014;35(6):1459–68.Google Scholar

Lee, WH, Kumar, A, Rani, A, Herrera, J, Xu, J, Someya, S, et al. Influence of viral vector-mediated delivery of superoxide dismutase and catalase to the hippocampus on spatial learning and memory during aging. Antioxid Redox Signal. 2012;16(4):339–50.Google Scholar

Streit, WJ, Xue, QS, Tischer, J, Bechmann, I. Microglial pathology. Acta Neuropathol Commun. 2014;2:142.Google Scholar

Rafnsson, SB, Deary, IJ, Smith, FB, Whiteman, MC, Rumley, A, Lowe, GD, et al. Cognitive decline and markers of inflammation and hemostasis: the Edinburgh Artery Study. J Am Geriatr Soc. 2007;55(5):700–7.Google Scholar

Scheinert, RB, Asokan, A, Rani, A, Kumar, A, Foster, TC, Ormerod, BK. Some hormone, cytokine and chemokine levels that change across lifespan vary by cognitive status in male Fischer 344 rats. Brain Behav Immun. 2015;49:216–32.Google Scholar

Bean, LA, Ianov, L, Foster, TC. Estrogen receptors, the hippocampus, and memory. Neuroscientist. 2014;20(5):534–45.Google Scholar

Foster, TC. Interaction of rapid signal transduction cascades and gene expression in mediating estrogen effects on memory over the life span. Front Neuroendocrinol. 2005;26(2):51–64.Google Scholar

Bean, LA, Kumar, A, Rani, A, Guidi, M, Rosario, AM, Cruz, PE, et al. Re-opening the critical window for estrogen therapy. J Neurosci. 2015;35(49):16077–93.Google Scholar

Kumar, A, Foster, TC. 17beta-estradiol benzoate decreases the AHP amplitude in CA1 pyramidal neurons. J Neurophysiol. 2002;88(2):621–6.Google Scholar

Foster, TC, Sharrow, KM, Kumar, A, Masse, J. Interaction of age and chronic estradiol replacement on memory and markers of brain aging. Neurobiol Aging. 2003;24(6):839–52.Google Scholar

Vedder, LC, Bredemann, TM, McMahon, LL. Estradiol replacement extends the window of opportunity for hippocampal function. Neurobiol Aging. 2014;35(10):2183–92.Google Scholar

Lopez-Grueso, R, Gambini, J, Abdelaziz, KM, Monleon, D, Diaz, A, El Alami, M, et al. Early, but not late onset estrogen replacement therapy prevents oxidative stress and metabolic alterations caused by ovariectomy. Antioxid Redox Signal. 2014;20(2):236–46.Google Scholar

Moorthy, K, Sharma, D, Basir, SF, Baquer, NZ. Administration of estradiol and progesterone modulate the activities of antioxidant enzyme and aminotransferases in naturally menopausal rats. Exp Gerontol. 2005;40(4):295–302.Google Scholar

McCarrey, AC, Resnick, SM. Postmenopausal hormone therapy and cognition. Horm Behav. 2015;74:167–72.Google Scholar

Aenlle, KK, Foster, TC. Aging alters the expression of genes for neuroprotection and synaptic function following acute estradiol treatment. Hippocampus. 2010;20(9):1047–60.Google Scholar

Blalock, EM, Chen, KC, Sharrow, K, Herman, JP, Porter, NM, Foster, TC, et al. Gene microarrays in hippocampal aging: statistical profiling identifies novel processes correlated with cognitive impairment. J Neurosci. 2003;23(9):3807–19.Google Scholar

Prolla, TA. DNA microarray analysis of the aging brain. Chem Senses. 2002;27(3):299–306.Google Scholar

VanGuilder, HD, Bixler, GV, Brucklacher, RM, Farley, JA, Yan, H, Warrington, JP, et al. Concurrent hippocampal induction of MHC II pathway components and glial activation with advanced aging is not correlated with cognitive impairment. J Neuroinflammation. 2011;8:138.Google Scholar

Fraga, MF, Ballestar, E, Paz, MF, Ropero, S, Setien, F, Ballestar, ML, et al. Epigenetic differences arise during the lifetime of monozygotic twins. Proc Natl Acad Sci USA. 2005;102(30):10604–9.Google Scholar

Starnawska, A, Tan, Q, McGue, M, Mors, O, Borglum, AD, Christensen, K, et al. Epigenome-wide association study of cognitive functioning in middle-aged monozygotic twins. Front Aging Neurosci. 2017;9:413.Google Scholar

Leu, YW, Yan, PS, Fan, M, Jin, VX, Liu, JC, Curran, EM, et al. Loss of estrogen receptor signaling triggers epigenetic silencing of downstream targets in breast cancer. Cancer Res. 2004;64(22):8184–92.CrossRef Google Scholar PubMed

Moreno-Piovano, GS, Varayoud, J, Luque, EH, Ramos, JG. Long-term ovariectomy increases BDNF gene methylation status in mouse hippocampus. J Steroid Biochem Mol Biol. 2014;144 Pt B:243–52.Google Scholar

Carter, SD, Mifsud, KR, Reul, JM. Distinct epigenetic and gene expression changes in rat hippocampal neurons after Morris water maze training. Front Behav Neurosci. 2015;9:156.CrossRef Google Scholar PubMed

Han, Y, Han, D, Yan, Z, Boyd-Kirkup, JD, Green, CD, Khaitovich, P, et al. Stress-associated H3K4 methylation accumulates during postnatal development and aging of rhesus macaque brain. Aging Cell. 2012;11(6):1055–64.Google Scholar

Kenworthy, CA, Sengupta, A, Luz, SM, Ver Hoeve, ES, Meda, K, Bhatnagar, S, et al. Social defeat induces changes in histone acetylation and expression of histone modifying enzymes in the ventral hippocampus, prefrontal cortex, and dorsal raphe nucleus. Neuroscience. 2014;264:88–98.Google Scholar

Oh, JE, Chambwe, N, Klein, S, Gal, J, Andrews, S, Gleason, G, et al. Differential gene body methylation and reduced expression of cell adhesion and neurotransmitter receptor genes in adverse maternal environment. Transl Psychiatry. 2013;3:e218.Google Scholar

Ianov, L, Riva, A, Kumar, A, Foster, TC. DNA methylation of synaptic genes in the prefrontal cortex is associated with aging and age-related cognitive impairment. Front Aging Neurosci. 2017;9:249.Google Scholar

Foster, TC, Sharrow, KM, Masse, JR, Norris, CM, Kumar, A. Calcineurin links Ca²⁺ dysregulation with brain aging. J Neurosci. 2001;21(11):4066–73.Google Scholar

Penner, MR, Parrish, RR, Hoang, LT, Roth, TL, Lubin, FD, Barnes, CA. Age-related changes in Egr1 transcription and DNA methylation within the hippocampus. Hippocampus. 2016;26(8):1008–20.Google Scholar

Penner, MR, Roth, TL, Chawla, MK, Hoang, LT, Roth, ED, Lubin, FD, et al. Age-related changes in Arc transcription and DNA methylation within the hippocampus. Neurobiol Aging. 2011;32(12):2198–210.Google Scholar

Grinan-Ferre, C, Puigoriol-Illamola, D, Palomera-Avalos, V, Perez-Caceres, D, Companys-Alemany, J, Camins, A, et al. Environmental enrichment modified epigenetic mechanisms in SAMP8 mouse hippocampus by reducing oxidative stress and inflammaging and achieving neuroprotection. Front Aging Neurosci. 2016;8:241.Google Scholar

Weaver, IC, Champagne, FA, Brown, SE, Dymov, S, Sharma, S, Meaney, MJ, et al. Reversal of maternal programming of stress responses in adult offspring through methyl supplementation: altering epigenetic marking later in life. J Neurosci. 2005;25(47):11045–54.Google Scholar

Zhang, TY, Keown, CL, Wen, X, Li, J, Vousden, DA, Anacker, C, et al. Environmental enrichment increases transcriptional and epigenetic differentiation between mouse dorsal and ventral dentate gyrus. Nat Commun. 2018;9(1):298.Google Scholar

Cechinel, LR, Basso, CG, Bertoldi, K, Schallenberger, B, de Meireles, LC, Siqueira, IR. Treadmill exercise induces age and protocol-dependent epigenetic changes in prefrontal cortex of Wistar rats. Behav Brain Res. 2016;313:82–7.CrossRef Google Scholar PubMed

Cosin-Tomas, M, Alvarez-Lopez, MJ, Sanchez-Roige, S, Lalanza, JF, Bayod, S, Sanfeliu, C, et al. Epigenetic alterations in hippocampus of SAMP8 senescent mice and modulation by voluntary physical exercise. Front Aging Neurosci. 2014;6:51.Google Scholar

Feil, R. Environmental and nutritional effects on the epigenetic regulation of genes. Mutat Res. 2006;600(1–2):46–57.Google Scholar

Rani, A, O’Shea, A, Ianov, L, Cohen, RA, Woods, AJ, Foster, TC. miRNA in circulating microvesicles as biomarkers for age-related cognitive decline. Front Aging Neurosci. 2017;9:323.Google Scholar

Freedman, JE, Gerstein, M, Mick, E, Rozowsky, J, Levy, D, Kitchen, R, et al. Diverse human extracellular RNAs are widely detected in human plasma. Nat Commun. 2016;7:11106.Google Scholar

Book contents

Chapter 3 - Cellular and Molecular Mechanisms for Age-Related Cognitive Decline

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive