Normal brain ageing: models and mechanisms

Normal ageing is associated with a degree of decline in a number of cognitive functions. Apart from the issues raised by the current attempts to expand the lifespan, understanding the mechanisms and the detailed metabolic interactions involved in the process of normal neuronal ageing continues to be a challenge. One model, supported by a significant amount of experimental evidence, views the cellular ageing as a metabolic state characterized by an altered function of the metabolic triad: mitochondria–reactive oxygen species (ROS)–intracellular Ca2+. The perturbation in the relationship between the members of this metabolic triad generate a state of decreased homeostatic reserve, in which the aged neurons could maintain adequate function during normal activity, as demonstrated by the fact that normal ageing is not associated with widespread neuronal loss, but become increasingly vulnerable to the effects of excessive metabolic loads, usually associated with trauma, ischaemia or neurodegenerative processes. This review will concentrate on some of the evidence showing altered mitochondrial function with ageing and also discuss some of the functional consequences that would result from such events, such as alterations in mitochondrial Ca2+ homeostasis, ATP production and generation of ROS.

[1]  Eric M. Blalock,et al.  Decreased G-Protein-Mediated Regulation and Shift in Calcium Channel Types with Age in Hippocampal Cultures , 1999, The Journal of Neuroscience.

[2]  D. Murchison,et al.  Reduced mitochondrial buffering of voltage-gated calcium influx in aged rat basal forebrain neurons. , 2004, Cell calcium.

[3]  B. Ames,et al.  Mitochondrial decay in hepatocytes from old rats: membrane potential declines, heterogeneity and oxidants increase. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[4]  A. Verkhratsky,et al.  Parameters of calcium homeostasis in normal neuronal ageing , 2000, Journal of anatomy.

[5]  L. Frölich,et al.  Impact of aging , 2007, NeuroMolecular Medicine.

[6]  R. Katzman.,et al.  Life span and synapses: will there be a primary senile dementia? , 2001, Neurobiology of Aging.

[7]  A. Verkhratsky,et al.  Calcium and neuronal ageing , 1998, Trends in Neurosciences.

[8]  B. Ames,et al.  Time to Talk SENS: Critiquing the Immutability of Human Aging , 2002, Annals of the New York Academy of Sciences.

[9]  M. Mattson,et al.  A Role for 4‐Hydroxynonenal, an Aldehydic Product of Lipid Peroxidation, in Disruption of Ion Homeostasis and Neuronal Death Induced by Amyloid β‐Peptide , 1997, Journal of neurochemistry.

[10]  E. C. Toescu Mitochondria and Ca2+ signaling , 2000 .

[11]  Federico V Pallardó,et al.  The role of mitochondrial oxidative stress in aging. , 2003, Free radical biology & medicine.

[12]  J. Johnson,et al.  Mitochondrial role in cell aging , 1980, Experimental Gerontology.

[13]  G. Brewer,et al.  Age-related differences in NMDA responses in cultured rat hippocampal neurons , 2001, Brain Research.

[14]  C. Leeuwenburgh,et al.  Method for measuring ATP production in isolated mitochondria: ATP production in brain and liver mitochondria of Fischer-344 rats with age and caloric restriction. , 2003, American journal of physiology. Regulatory, integrative and comparative physiology.

[15]  W. Markesbery,et al.  Four-Hydroxynonenal, a Product of Lipid Peroxidation, is Increased in the Brain in Alzheimer’s Disease , 1998, Neurobiology of Aging.

[16]  David E. Clapham,et al.  The mitochondrial calcium uniporter is a highly selective ion channel , 2004, Nature.

[17]  F. Buttgereit,et al.  A hierarchy of ATP-consuming processes in mammalian cells. , 1995, The Biochemical journal.

[18]  M. Duchen,et al.  Contributions of mitochondria to animal physiology: from homeostatic sensor to calcium signalling and cell death , 1999, The Journal of physiology.

[19]  E. Stadtman Protein oxidation and aging , 2006, Science.

[20]  J. Sastre,et al.  A Ginkgo biloba extract (EGb 761) prevents mitochondrial aging by protecting against oxidative stress. , 1998, Free radical biology & medicine.

[21]  D. Harman Free radical theory of aging: dietary implications , 1972 .

[22]  T. Pozzan,et al.  Microdomains with high Ca2+ close to IP3-sensitive channels that are sensed by neighboring mitochondria. , 1993, Science.

[23]  N. Hattori,et al.  Immunohistochemical detection of 4-hydroxynonenal protein adducts in Parkinson disease. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[24]  T. Wakabayashi Megamitochondria formation ‐ physiology and pathology , 2002, Journal of cellular and molecular medicine.

[25]  M. Michaelis,et al.  Age-related decrease in brain synaptic membrane Ca2+-ATPase in F344/BNF1 rats , 1998, Neurobiology of Aging.

[26]  N. Rothwell,et al.  Cleavage of the Plasma Membrane Na+/Ca2+ Exchanger in Excitotoxicity , 2005, Cell.

[27]  E. Stadtman Protein oxidation and aging. , 1992, Free radical research.

[28]  C. Barnes,et al.  Impact of aging on hippocampal function: plasticity, network dynamics, and cognition , 2003, Progress in Neurobiology.

[29]  R. Denton,et al.  Signal Transduction by Intramitochondrial Ca2+ in Mammalian Energy Metabolism , 1994 .

[30]  P. Landfield,et al.  Ca2+ regulation and gene expression in normal brain aging , 2004, Trends in Neurosciences.

[31]  Which synapses are affected in aging and what is the nature of their vulnerability? A commentary on “life span and synapses: will there be a primary senile dementia?” , 2001, Neurobiology of Aging.

[32]  K. Gunter,et al.  Mitochondrial calcium transport: mechanisms and functions. , 2000, Cell calcium.

[33]  W. Meier-Ruge,et al.  Morphological Alterations of Synaptic Mitochondria during Aging , 1994, Annals of the New York Academy of Sciences.

[34]  J. Morrison,et al.  Life and death of neurons in the aging brain. , 1997, Science.

[35]  V. Skulachev,et al.  High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria , 1997, FEBS letters.

[36]  Philip W. Landfield,et al.  Elevated Postsynaptic [Ca2+]iand L-Type Calcium Channel Activity in Aged Hippocampal Neurons: Relationship to Impaired Synaptic Plasticity , 2001, The Journal of Neuroscience.

[37]  R. Floyd,et al.  Conditions influencing yield and analysis of 8-hydroxy-2'-deoxyguanosine in oxidatively damaged DNA. , 1990, Analytical biochemistry.

[38]  L. Kiedrowski N-methyl-D-aspartate excitotoxicity: relationships among plasma membrane potential, Na(+)/Ca(2+) exchange, mitochondrial Ca(2+) overload, and cytoplasmic concentrations of Ca(2+), H(+), and K(+). , 1999, Molecular pharmacology.

[39]  Zhongmao Guo,et al.  Does oxidative damage to DNA increase with age? , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[40]  A. Verkhratsky,et al.  Mitochondrial polarisation status and [Ca2+]i signalling in rat cerebellar granule neurones aged in vitro , 2004, Neurobiology of Aging.

[41]  B. McEwen Allostasis, Allostatic Load, and the Aging Nervous System: Role of Excitatory Amino Acids and Excitotoxicity , 2000, Neurochemical Research.

[42]  V. Bindokas,et al.  Maturation of vulnerability to excitotoxicity: intracellular mechanisms in cultured postnatal hippocampal neurons. , 2000, Brain research. Developmental brain research.

[43]  D. Nicholls Mitochondrial membrane potential and aging , 2004, Aging cell.

[44]  S. Olshansky,et al.  Biological evidence for limits to the duration of life , 2004, Biogerontology.

[45]  Z. Khachaturian Calcium Hypothesis of Alzheimer's Disease and Brain Aging a , 1994, Annals of the New York Academy of Sciences.

[46]  R. S. Sohal,et al.  Relationship between mitochondrial superoxide and hydrogen peroxide production and longevity of mammalian species. , 1993, Free radical biology & medicine.

[47]  Ian J. Reynolds,et al.  Glutamate-induced neuron death requires mitochondrial calcium uptake , 1998, Nature Neuroscience.

[48]  J. Vaupel,et al.  Broken Limits to Life Expectancy , 2002, Science.

[49]  K. Hoyt,et al.  The role of intracellular Na+ and mitochondria in buffering of kainate‐induced intracellular free Ca2+ changes in rat forebrain neurones , 1998, The Journal of physiology.

[50]  O. Hansson,et al.  Mitochondrial Control of Acute Glutamate Excitotoxicity in Cultured Cerebellar Granule Cells , 1998, The Journal of Neuroscience.

[51]  E. C. Toescu Mitochondria and Ca(2+) signaling. , 2000, Journal of cellular and molecular medicine.

[52]  A. Yashin,et al.  Biodemographic trajectories of longevity. , 1998, Science.

[53]  L. Capasso,et al.  Roman conquest, lifespan, and diseases in ancient Italy , 2003, The Lancet.

[54]  S. Laughlin,et al.  An Energy Budget for Signaling in the Grey Matter of the Brain , 2001, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[55]  J. Morrison,et al.  The aging brain: morphomolecular senescence of cortical circuits , 2004, Trends in Neurosciences.

[56]  L Manzo,et al.  Neuronal cell death: a demise with different shapes. , 1999, Trends in pharmacological sciences.

[57]  M. Duchen,et al.  Glutamate‐induced mitochondrial depolarisation and perturbation of calcium homeostasis in cultured rat hippocampal neurones , 1999, The Journal of physiology.

[58]  K. Gunter,et al.  Transport of calcium by mitochondria , 1994, Journal of bioenergetics and biomembranes.

[59]  G. Davey,et al.  Energy Thresholds in Brain Mitochondria , 1998, The Journal of Biological Chemistry.

[60]  J. Miquel,et al.  An update on the mitochondrial-DNA mutation hypothesis of cell aging. , 1992, Mutation research.

[61]  H. Esterbauer,et al.  Chemistry and biochemistry of 4-hydroxynonenal, malonaldehyde and related aldehydes. , 1991, Free radical biology & medicine.

[62]  M. Mattson,et al.  Impairment of Glucose and Glutamate Transport and Induction of Mitochondrial Oxidative Stress and Dysfunction in Synaptosomes by Amyloid β‐Peptide: Role of the Lipid Peroxidation Product 4‐Hydroxynonenal , 1997, Journal of neurochemistry.

[63]  S. Dirusso,et al.  Traumatic brain injury in the elderly: increased mortality and worse functional outcome at discharge despite lower injury severity. , 2002, The Journal of trauma.

[64]  A. Verkhratsky,et al.  Changes in Mitochondrial Status Associated with Altered Ca2+ Homeostasis in Aged Cerebellar Granule Neurons in Brain Slices , 2002, The Journal of Neuroscience.

[65]  E. Toescu,et al.  Metabolic Substrates of Neuronal Aging , 2004, Annals of the New York Academy of Sciences.

[66]  P. Chan Mitochondria and Neuronal Death/Survival Signaling Pathways in Cerebral Ischemia , 2004, Neurochemical Research.

[67]  R. Weindruch,et al.  Age-related increase in mitochondrial proton leak and decrease in ATP turnover reactions in mouse hepatocytes. , 1998, The American journal of physiology.

[68]  L. Kiedrowski N-methyl-D-aspartate Excitotoxicity : Relationships among Plasma Membrane Potential , Na 1 / Ca 2 1 Exchange , Mitochondrial Ca 2 1 Overload , and Cytoplasmic Concentrations of Ca 2 1 , H 1 , and K 1 , 1999 .

[69]  K. Hensley,et al.  Oxidative stress in brain aging Implications for therapeutics of neurodegenerative diseases , 2002, Neurobiology of Aging.

[70]  R. Hayes,et al.  The effect of age on outcome following traumatic brain injury in rats. , 1991, Journal of neurosurgery.

[71]  G. Holmes,et al.  Age-dependent effects of glutamate toxicity in the hippocampus. , 1996, Brain research. Developmental brain research.