White Matter Lipids as a Ketogenic Fuel Supply in Aging Female Brain: Implications for Alzheimer's Disease

Lauren P Klosinski, Jia Yao, Fei Yin, Alfred N Fonteh, Michael G Harrington, Trace A Christensen, Eugenia Trushina, Roberta Diaz Brinton, Lauren P Klosinski, Jia Yao, Fei Yin, Alfred N Fonteh, Michael G Harrington, Trace A Christensen, Eugenia Trushina, Roberta Diaz Brinton

Abstract

White matter degeneration is a pathological hallmark of neurodegenerative diseases including Alzheimer's. Age remains the greatest risk factor for Alzheimer's and the prevalence of age-related late onset Alzheimer's is greatest in females. We investigated mechanisms underlying white matter degeneration in an animal model consistent with the sex at greatest Alzheimer's risk. Results of these analyses demonstrated decline in mitochondrial respiration, increased mitochondrial hydrogen peroxide production and cytosolic-phospholipase-A2 sphingomyelinase pathway activation during female brain aging. Electron microscopic and lipidomic analyses confirmed myelin degeneration. An increase in fatty acids and mitochondrial fatty acid metabolism machinery was coincident with a rise in brain ketone bodies and decline in plasma ketone bodies. This mechanistic pathway and its chronologically phased activation, links mitochondrial dysfunction early in aging with later age development of white matter degeneration. The catabolism of myelin lipids to generate ketone bodies can be viewed as a systems level adaptive response to address brain fuel and energy demand. Elucidation of the initiating factors and the mechanistic pathway leading to white matter catabolism in the aging female brain provides potential therapeutic targets to prevent and treat demyelinating diseases such as Alzheimer's and multiple sclerosis. Targeting stages of disease and associated mechanisms will be critical.

Keywords: ABAD, Aβ-binding alcohol dehydrogenase; ABAD, Aβ-binding-alcohol-dehydrogenase; ACER3, alkaline ceramidase; AD, Alzheimer's disease; APO-ε4, apolipoprotein ε4; APP, amyloid precursor protein; Aging oxidative stress; Alzheimer's disease; BACE1, beta-secretase 1; BBB, blood brain barrier; CC, corpus callosum; CMRglu, cerebral glucose metabolic rate; COX, complex IV cytochrome c oxidase; CPT1, carnitine palmitoyltransferase 1; Cldn11, claudin 11; Cyp2j6, arachidonic acid epoxygenase; Cytosolic phospholipase A2; DHA, docosahexaesnoic acid; Erbb3, Erb-B2 receptor tyrosine kinase 3; FDG-PET, 2-[18F]fluoro-2-deoxy-d-glucose; GFAP, glial fibrillary acidic protein; H2O2, hydrogen peroxide; HADHA, hydroxyacyl-CoA dehydrogenase; HK, hexokinase; Ketone bodies; LC MS, liquid chromatography mass spectrometer; MAG, myelin associated glycoprotein; MBP, myelin basic protein; MCT1, monocarboxylate transporter 1; MIB, mitochondrial isolation buffer; MOG, myelin oligodendrocyte glycoprotein; MTL, medial temporal lobe; Mitochondria; NEFA, nonesterified fatty acids; Neurodegeneration; OCR, oxygen consumption rate; Olig2, oligodendrocyte transcription factor; PB, phosphate buffer; PCC, posterior cingulate; PCR, polymerase chain reaction; PDH, pyruvate dehydrogenase; PEI, polyethyleneimine; RCR, respiratory control ratio; ROS, reactive oxygen species; S1P, sphingosine; TLDA, TaqMan low density array; WM, white matter; WT, wild type; White matter; cPLA2, cytosolic phospholipase A2.

Figures

Fig. 1
Fig. 1
Mitochondrial function and cytoplasmic phospholipase A2 activity in reproductively aging female mice: A. Respiratory control ratio (RCR = OCRstate 4/OCRstate 3) and B. H2O2 production in isolated whole brain mitochondria from reproductively aging female mice. C. cPLA2 enzyme activity in whole brain tissue homogenate obtained during mitochondrial isolation preparation. (A. N = 6–8; B. N = 6–7; C. N = 5–7.) (*p < 0.05, **p < 0.005 and ***p < 0.0005).
Fig. 2
Fig. 2
Cytoplasmic phospholipase A2-sphingomyelinase pathway activation during reproductive senescence: A. cPLA2 enzyme activity in hippocampal tissue homogenate. B. Arachidonic acid production determined by GC-MS in tissue homogenate obtained during mitochondrial isolation preparation. B. Acid sphingomyelinase enzyme activity in hippocampal tissue homogenate. (A. N = 4–11; B. N = 3,-4; C. N = 7–12.) (*p < 0.05, ***p < 0.0005, ****p < 0.00005).
Fig. 3
Fig. 3
Co-localization of immunoreactivity of reactive astrocytes and cytoplasmic phospholipase A2 in brain slices from the aging female mouse model: white matter tracts were co-labeled with GFAP (FITC) and cPLA2 (CY3) antibodies, and assessed for astrocyte reactivity and cPLA2 cellular localization in the A. fimbria, B. cingulum, C. the Schaffer collateral pathway, and D. anterior commissure during reproductive aging. E. Representative images depicting GFAP (FITC) and cPLA2 (CY3) labeling in the cingulum of reproductively incompetent female mice. (A, B, C, D. N = 4 per group) (*p < 0.05, and ***p < 0.0005).
Fig. 4
Fig. 4
Cytoplasmic phospholipase A2 enzyme activity in cultured astrocytes and neurons following H2O2 exposure: embryonic hippocampal neurons and astrocytes in culture were treated with H2O2 and assessed for cPLA2 activation using an enzyme activity assay. cPLA2 enzyme activity normalized to untreated cells in cultured A. astrocytes and B. neurons. C. cPLA2 enzyme activity normalized to untreated cells in cultured astrocytes following exposure to physiologically relevant concentrations of H2O2. H2O2 concentrations were determined by the levels of H2O2 produced by whole brain mitochondria isolated from reproductively incompetent female mice. D. Levels of cPLA2 enzyme activation in astrocytes and neurons (nmol/min/ml/mg of protein).
Fig. 5
Fig. 5
Myelin and fatty acid metabolism, myelin generation and repair, and inflammation related gene expression in reproductively aging female mice: A. Table depicting the fold change and p-value differences in expression of white matter related genes between reproductively irregular and reproductively incompetent female mice. Red p-value is indicative of upregulation while a green p-value indicates down regulation. Boxes outlined in red reached statistical significance. B. Heatmaps of gene expression organized by function: myelin and fatty acid metabolism, myelin generation and repair, and inflammation. Each gene was normalized and colored based on its relative expression level across 4 reproductive aging groups. This method allows genes that have different magnitude of signal intensity but which belong to the same functional group and share similar expression patterns to be displayed on the same heatmap. (N = 5 per group.)
Fig. 6
Fig. 6
Immunohistochemical and Western blot analysis of white matter integrity in the aging female mouse model: A. Immunohistochemical mapping of myelin basic protein area in the corpus callosum of the aging female mouse model. B. Representative immunohistochemical images mapping myelin basic protein area in the anterior commissure and corpus callosum. Mask of corpus callosum generated via slide book software is highlighted in purple. C. Myelin basic protein expression during reproductive aging in the female mouse. (C. N = 4–10 per group). (*p 

Fig. 7

Electron microscopic analysis of the…

Fig. 7

Electron microscopic analysis of the structural integrity of white matter in reproductively aging…

Fig. 7
Electron microscopic analysis of the structural integrity of white matter in reproductively aging female mice: representative electron microscopy images of myelinated axons in the anterior commissure of A. reproductively irregular, B. reproductively incompetent and C. aged female mice. Quantitative analysis of the percentage of compromised axons in the D. Schaffer collateral pathway, E. anterior commissure and F. corpus callosum in reproductively aging female mice. (A, B, C. N = 3–4; D. N = 4; E. N = 4; F. N = 3). (*p 

Fig. 8

Electron microscopic analysis of lipid…

Fig. 8

Electron microscopic analysis of lipid droplet accumulation in reproductively aging female mice: representative…

Fig. 8
Electron microscopic analysis of lipid droplet accumulation in reproductively aging female mice: representative electron microscopy images of lipid droplet accumulation in the anterior commissure of A. reproductively irregular, B. reproductively incompetent and C. aged female mice. Average number of lipid droplets per cell body in the D. anterior commissure and E. corpus callosum. (A, B. N = 3–4; C. N = 4; D. N = 4; E. N = 3). (*p 

Fig. 9

Lipid profile of female brain…

Fig. 9

Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events…

Fig. 9
Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events that occur during myelin breakdown. B. Levels of brain lipids in reproductively irregular, reproductively incompetent and aged female mice. Lipids were separated into three categorical panels: ceramides, non-esterified fatty acids and TCA metabolites. Red values are indicative of the peak level of a particular lipid and green values indicate statistical significance. (N = 4–6 per group.)

Fig. 10

Expression of proteins involved in…

Fig. 10

Expression of proteins involved in fatty acid transport and metabolism in the aging…

Fig. 10
Expression of proteins involved in fatty acid transport and metabolism in the aging female mouse model: A. CPT1 protein expression in isolated whole brain mitochondria. B. HADHA protein expression in isolated whole brain mitochondria. C. ABAD protein expression in isolated whole brain mitochondria (A, B, C. N = 3–8). (**p 

Fig. 11

Hippocampal, cortical and plasma ketone…

Fig. 11

Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A.…

Fig. 11
Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A. Hippocampal levels of ketone bodies. B. Cortical levels of ketone bodies. C. Plasma levels of ketone bodies. (A. N = 4 per group; B. N = 5–6; C. N = 3–7). (*p 

Fig. 12

Schematic model of mitochondrial H…

Fig. 12

Schematic model of mitochondrial H 2 O 2 activation of cPLA 2 -sphingomyelinase…

Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.
All figures (12)
Similar articles
Cited by
References
    1. Alzheimer's A. 2015 Alzheimer's disease facts and figures. Alzheimers Dement. 2015;11:332–384. - PubMed
    1. Bartzokis G. Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer's disease. Neurobiol. Aging. 2004;25:5–18. (author reply 49-62) - PubMed
    1. Bartzokis G., Lu P.H., Geschwind D.H., Edwards N., Mintz J., Cummings J.L. Apolipoprotein E genotype and age-related myelin breakdown in healthy individuals: implications for cognitive decline and dementia. Arch. Gen. Psychiatry. 2006;63:63–72. - PubMed
    1. Baumann N., Pham-Dinh D. Biology of oligodendrocyte and myelin in the mammalian central nervous system. Physiol. Rev. 2001;81:871–927. - PubMed
    1. Beal M.F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol. 2005;58:495–505. - PubMed
Show all 119 references
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Fig. 7
Fig. 7
Electron microscopic analysis of the structural integrity of white matter in reproductively aging female mice: representative electron microscopy images of myelinated axons in the anterior commissure of A. reproductively irregular, B. reproductively incompetent and C. aged female mice. Quantitative analysis of the percentage of compromised axons in the D. Schaffer collateral pathway, E. anterior commissure and F. corpus callosum in reproductively aging female mice. (A, B, C. N = 3–4; D. N = 4; E. N = 4; F. N = 3). (*p 

Fig. 8

Electron microscopic analysis of lipid…

Fig. 8

Electron microscopic analysis of lipid droplet accumulation in reproductively aging female mice: representative…

Fig. 8
Electron microscopic analysis of lipid droplet accumulation in reproductively aging female mice: representative electron microscopy images of lipid droplet accumulation in the anterior commissure of A. reproductively irregular, B. reproductively incompetent and C. aged female mice. Average number of lipid droplets per cell body in the D. anterior commissure and E. corpus callosum. (A, B. N = 3–4; C. N = 4; D. N = 4; E. N = 3). (*p 

Fig. 9

Lipid profile of female brain…

Fig. 9

Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events…

Fig. 9
Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events that occur during myelin breakdown. B. Levels of brain lipids in reproductively irregular, reproductively incompetent and aged female mice. Lipids were separated into three categorical panels: ceramides, non-esterified fatty acids and TCA metabolites. Red values are indicative of the peak level of a particular lipid and green values indicate statistical significance. (N = 4–6 per group.)

Fig. 10

Expression of proteins involved in…

Fig. 10

Expression of proteins involved in fatty acid transport and metabolism in the aging…

Fig. 10
Expression of proteins involved in fatty acid transport and metabolism in the aging female mouse model: A. CPT1 protein expression in isolated whole brain mitochondria. B. HADHA protein expression in isolated whole brain mitochondria. C. ABAD protein expression in isolated whole brain mitochondria (A, B, C. N = 3–8). (**p 

Fig. 11

Hippocampal, cortical and plasma ketone…

Fig. 11

Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A.…

Fig. 11
Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A. Hippocampal levels of ketone bodies. B. Cortical levels of ketone bodies. C. Plasma levels of ketone bodies. (A. N = 4 per group; B. N = 5–6; C. N = 3–7). (*p 

Fig. 12

Schematic model of mitochondrial H…

Fig. 12

Schematic model of mitochondrial H 2 O 2 activation of cPLA 2 -sphingomyelinase…

Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.
All figures (12)
Similar articles
Cited by
References
    1. Alzheimer's A. 2015 Alzheimer's disease facts and figures. Alzheimers Dement. 2015;11:332–384. - PubMed
    1. Bartzokis G. Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer's disease. Neurobiol. Aging. 2004;25:5–18. (author reply 49-62) - PubMed
    1. Bartzokis G., Lu P.H., Geschwind D.H., Edwards N., Mintz J., Cummings J.L. Apolipoprotein E genotype and age-related myelin breakdown in healthy individuals: implications for cognitive decline and dementia. Arch. Gen. Psychiatry. 2006;63:63–72. - PubMed
    1. Baumann N., Pham-Dinh D. Biology of oligodendrocyte and myelin in the mammalian central nervous system. Physiol. Rev. 2001;81:871–927. - PubMed
    1. Beal M.F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol. 2005;58:495–505. - PubMed
Show all 119 references
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MeSH terms
[x]
Cite
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Format: AMA APA MLA NLM

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Fig. 8
Fig. 8
Electron microscopic analysis of lipid droplet accumulation in reproductively aging female mice: representative electron microscopy images of lipid droplet accumulation in the anterior commissure of A. reproductively irregular, B. reproductively incompetent and C. aged female mice. Average number of lipid droplets per cell body in the D. anterior commissure and E. corpus callosum. (A, B. N = 3–4; C. N = 4; D. N = 4; E. N = 3). (*p 

Fig. 9

Lipid profile of female brain…

Fig. 9

Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events…

Fig. 9
Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events that occur during myelin breakdown. B. Levels of brain lipids in reproductively irregular, reproductively incompetent and aged female mice. Lipids were separated into three categorical panels: ceramides, non-esterified fatty acids and TCA metabolites. Red values are indicative of the peak level of a particular lipid and green values indicate statistical significance. (N = 4–6 per group.)

Fig. 10

Expression of proteins involved in…

Fig. 10

Expression of proteins involved in fatty acid transport and metabolism in the aging…

Fig. 10
Expression of proteins involved in fatty acid transport and metabolism in the aging female mouse model: A. CPT1 protein expression in isolated whole brain mitochondria. B. HADHA protein expression in isolated whole brain mitochondria. C. ABAD protein expression in isolated whole brain mitochondria (A, B, C. N = 3–8). (**p 

Fig. 11

Hippocampal, cortical and plasma ketone…

Fig. 11

Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A.…

Fig. 11
Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A. Hippocampal levels of ketone bodies. B. Cortical levels of ketone bodies. C. Plasma levels of ketone bodies. (A. N = 4 per group; B. N = 5–6; C. N = 3–7). (*p 

Fig. 12

Schematic model of mitochondrial H…

Fig. 12

Schematic model of mitochondrial H 2 O 2 activation of cPLA 2 -sphingomyelinase…

Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.
All figures (12)
Similar articles
Cited by
References
    1. Alzheimer's A. 2015 Alzheimer's disease facts and figures. Alzheimers Dement. 2015;11:332–384. - PubMed
    1. Bartzokis G. Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer's disease. Neurobiol. Aging. 2004;25:5–18. (author reply 49-62) - PubMed
    1. Bartzokis G., Lu P.H., Geschwind D.H., Edwards N., Mintz J., Cummings J.L. Apolipoprotein E genotype and age-related myelin breakdown in healthy individuals: implications for cognitive decline and dementia. Arch. Gen. Psychiatry. 2006;63:63–72. - PubMed
    1. Baumann N., Pham-Dinh D. Biology of oligodendrocyte and myelin in the mammalian central nervous system. Physiol. Rev. 2001;81:871–927. - PubMed
    1. Beal M.F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol. 2005;58:495–505. - PubMed
Show all 119 references
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MeSH terms
[x]
Cite
Copy Download .nbib
Format: AMA APA MLA NLM

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MeSH PMC Bookshelf Disclaimer

The PubMed wordmark and PubMed logo are registered trademarks of the U.S. Department of Health and Human Services (HHS). Unauthorized use of these marks is strictly prohibited.

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Fig. 9
Fig. 9
Lipid profile of female brain during reproductive aging: A. Sequence of catabolic events that occur during myelin breakdown. B. Levels of brain lipids in reproductively irregular, reproductively incompetent and aged female mice. Lipids were separated into three categorical panels: ceramides, non-esterified fatty acids and TCA metabolites. Red values are indicative of the peak level of a particular lipid and green values indicate statistical significance. (N = 4–6 per group.)
Fig. 10
Fig. 10
Expression of proteins involved in fatty acid transport and metabolism in the aging female mouse model: A. CPT1 protein expression in isolated whole brain mitochondria. B. HADHA protein expression in isolated whole brain mitochondria. C. ABAD protein expression in isolated whole brain mitochondria (A, B, C. N = 3–8). (**p 

Fig. 11

Hippocampal, cortical and plasma ketone…

Fig. 11

Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A.…

Fig. 11
Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A. Hippocampal levels of ketone bodies. B. Cortical levels of ketone bodies. C. Plasma levels of ketone bodies. (A. N = 4 per group; B. N = 5–6; C. N = 3–7). (*p 

Fig. 12

Schematic model of mitochondrial H…

Fig. 12

Schematic model of mitochondrial H 2 O 2 activation of cPLA 2 -sphingomyelinase…

Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.
All figures (12)
Similar articles
Cited by
References
    1. Alzheimer's A. 2015 Alzheimer's disease facts and figures. Alzheimers Dement. 2015;11:332–384. - PubMed
    1. Bartzokis G. Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer's disease. Neurobiol. Aging. 2004;25:5–18. (author reply 49-62) - PubMed
    1. Bartzokis G., Lu P.H., Geschwind D.H., Edwards N., Mintz J., Cummings J.L. Apolipoprotein E genotype and age-related myelin breakdown in healthy individuals: implications for cognitive decline and dementia. Arch. Gen. Psychiatry. 2006;63:63–72. - PubMed
    1. Baumann N., Pham-Dinh D. Biology of oligodendrocyte and myelin in the mammalian central nervous system. Physiol. Rev. 2001;81:871–927. - PubMed
    1. Beal M.F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol. 2005;58:495–505. - PubMed
Show all 119 references
Publication types
MeSH terms
[x]
Cite
Copy Download .nbib
Format: AMA APA MLA NLM
Fig. 11
Fig. 11
Hippocampal, cortical and plasma ketone body levels in the aging female mouse: A. Hippocampal levels of ketone bodies. B. Cortical levels of ketone bodies. C. Plasma levels of ketone bodies. (A. N = 4 per group; B. N = 5–6; C. N = 3–7). (*p 

Fig. 12

Schematic model of mitochondrial H…

Fig. 12

Schematic model of mitochondrial H 2 O 2 activation of cPLA 2 -sphingomyelinase…

Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.
All figures (12)
Fig. 12
Fig. 12
Schematic model of mitochondrial H2O2 activation of cPLA2-sphingomyelinase pathway as an adaptive response to provide myelin derived fatty acids as a substrate for ketone body generation: The cPLA2-sphingomyelinase pathway is proposed as a mechanistic pathway that links an early event, mitochondrial dysfunction and H2O2, in the prodromal/preclinical phase of Alzheimer's with later stage development of pathology, white matter degeneration. Our findings demonstrate that an age dependent deficit in mitochondrial respiration and a concomitant rise in oxidative stress activate an adaptive cPLA2-sphingomyelinase pathway to provide myelin derived fatty acids as a substrate for ketone body generation to fuel an energetically compromised brain.

References

    1. Alzheimer's A. 2015 Alzheimer's disease facts and figures. Alzheimers Dement. 2015;11:332–384.
    1. Bartzokis G. Age-related myelin breakdown: a developmental model of cognitive decline and Alzheimer's disease. Neurobiol. Aging. 2004;25:5–18. (author reply 49-62)
    1. Bartzokis G., Lu P.H., Geschwind D.H., Edwards N., Mintz J., Cummings J.L. Apolipoprotein E genotype and age-related myelin breakdown in healthy individuals: implications for cognitive decline and dementia. Arch. Gen. Psychiatry. 2006;63:63–72.
    1. Baumann N., Pham-Dinh D. Biology of oligodendrocyte and myelin in the mammalian central nervous system. Physiol. Rev. 2001;81:871–927.
    1. Beal M.F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol. 2005;58:495–505.
    1. Blachnio-Zabielska A.U., Persson X.M., Koutsari C., Zabielski P., Jensen M.D. A liquid chromatography/tandem mass spectrometry method for measuring the in vivo incorporation of plasma free fatty acids into intramyocellular ceramides in humans. Rapid Commun. Mass Spectrom. 2012;26:1134–1140.
    1. Blalock E.M., Buechel H.M., Popovic J., Geddes J.W., Landfield P.W. Microarray analyses of laser-captured hippocampus reveal distinct gray and white matter signatures associated with incipient Alzheimer's disease. J. Chem. Neuroanat. 2011;42:118–126.
    1. Blalock E.M., Chen K.C., Sharrow K., Herman J.P., Porter N.M., Foster T.C., Landfield P.W. Gene microarrays in hippocampal aging: statistical profiling identifies novel processes correlated with cognitive impairment. J. Neurosci. 2003;23:3807–3819.
    1. Blalock E.M., Geddes J.W., Chen K.C., Porter N.M., Markesbery W.R., Landfield P.W. Incipient Alzheimer's disease: microarray correlation analyses reveal major transcriptional and tumor suppressor responses. Proc. Natl. Acad. Sci. U. S. A. 2004;101:2173–2178.
    1. Blalock E.M., Grondin R., Chen K.C., Thibault O., Thibault V., Pandya J.D., Dowling A., Zhang Z., Sullivan P., Porter N.M., Landfield P.W. Aging-related gene expression in hippocampus proper compared with dentate gyrus is selectively associated with metabolic syndrome variables in rhesus monkeys. J. Neurosci. 2010;30:6058–6071.
    1. Blass J.P., Sheu R.K., Gibson G.E. Inherent abnormalities in energy metabolism in Alzheimer disease. Interaction with cerebrovascular compromise. Ann. N. Y. Acad. Sci. 2000;903:204–221.
    1. Blazquez C., Woods A., De Ceballos M.L., Carling D., Guzman M. The AMP-activated protein kinase is involved in the regulation of ketone body production by astrocytes. J. Neurochem. 1999;73:1674–1682.
    1. Bligh E.G., Dyer W.J. A rapid method of total lipid extraction and purification. Can. J. Biochem. Physiol. 1959;37:911–917.
    1. Boveris A., Chance B. The mitochondrial generation of hydrogen peroxide. general properties and effect of hyperbaric oxygen. Biochem. J. 1973;134:707–716.
    1. Brickman A.M., Meier I.B., Korgaonkar M.S., Provenzano F.A., Grieve S.M., Siedlecki K.L., Wasserman B.T., Williams L.M., Zimmerman M.E. Testing the white matter retrogenesis hypothesis of cognitive aging. Neurobiol. Aging. 2012;33:1699–1715.
    1. Brinton R.D. Estrogen regulation of glucose metabolism and mitochondrial function: therapeutic implications for prevention of Alzheimer's disease. Adv. Drug Deliv. Rev. 2008;60:1504–1511.
    1. Brinton R.D. The healthy cell bias of estrogen action: mitochondrial bioenergetics and neurological implications. Trends Neurosci. 2008;31:529–537.
    1. Brinton R.D., Yao J., Yin F., Mack W.J., Cadenas E. Perimenopause as a neurological transition state. Nat. Rev. Endocrinol. 2015;11:393–405.
    1. Burger H.G., Hale G.E., Dennerstein L., Robertson D.M. Cycle and hormone changes during perimenopause: the key role of ovarian function. Menopause. 2008;15:603–612.
    1. Burger H., Woods N.F., Dennerstein L., Alexander J.L., Kotz K., Richardson G. Nomenclature and endocrinology of menopause and perimenopause. Expert. Rev. Neurother. 2007;7:S35–S43.
    1. Cabodevilla A.G., Sanchez-Caballero L., Nintou E., Boiadjieva V.G., Picatoste F., Gubern A., Claro E. Cell survival during complete nutrient deprivation depends on lipid droplet-fueled beta-oxidation of fatty acids. J. Biol. Chem. 2013;288:27777–27788.
    1. Cahill G.F., Jr. Fuel metabolism in starvation. Annu. Rev. Nutr. 2006;26:1–22.
    1. Carozzi V.A., Canta A., Oggioni N., Sala B., Chiorazzi A., Meregalli C., Bossi M., Marmiroli P., Cavaletti G. Neurophysiological and neuropathological characterization of new murine models of chemotherapy-induced chronic peripheral neuropathies. Exp. Neurol. 2010;226:301–309.
    1. Cavaletti G., Gilardini A., Canta A., Rigamonti L., Rodriguez-Menendez V., Ceresa C., Marmiroli P., Bossi M., Oggioni N., D'incalci M., De Coster R. Bortezomib-induced peripheral neurotoxicity: a neurophysiological and pathological study in the rat. Exp. Neurol. 2007;204:317–325.
    1. Chou J.L., Shenoy D.V., Thomas N., Choudhary P.K., Laferla F.M., Goodman S.R., Breen G.A. Early dysregulation of the mitochondrial proteome in a mouse model of Alzheimer's disease. J. Proteome. 2011;74:466–479.
    1. Costantini C., Kolasani R.M., Puglielli L. Ceramide and cholesterol: possible connections between normal aging of the brain and Alzheimer's disease. Just hypotheses or molecular pathways to be identified? Alzheimers Dement. 2005;1:43–50.
    1. De Leon M., Bobinski M., Convit A., Wolf O., Insausti R. Usefulness of MRI measures of entorhinal cortex versus hippocampus in AD. Neurology. 2001;56:820–821.
    1. Decarli C., Murphy D.G., Tranh M., Grady C.L., Haxby J.V., Gillette J.A., Salerno J.A., Gonzales-Aviles A., Horwitz B., Rapoport S.I. The effect of white matter hyperintensity volume on brain structure, cognitive performance, and cerebral metabolism of glucose in 51 healthy adults. Neurology. 1995;45:2077–2084.
    1. Di Paola M., Di Iulio F., Cherubini A., Blundo C., Casini A.R., Sancesario G., Passafiume D., Caltagirone C., Spalletta G. When, where, and how the corpus callosum changes in MCI and AD: a multimodal MRI study. Neurology. 2010;74:1136–1142.
    1. Di Paolo G., Kim T.W. Linking lipids to Alzheimer's disease: cholesterol and beyond. Nat. Rev. Neurol. 2011;12:284–296.
    1. Ding F., Yao J., Rettberg J.R., Chen S., Brinton R.D. Early decline in glucose transport and metabolism precedes shift to ketogenic system in female aging and Alzheimer's mouse brain: implication for bioenergetic intervention. PLoS One. 2013;8
    1. Du H., Guo L., Yan S., Sosunov A.A., Mckhann G.M., Yan S.S. Early deficits in synaptic mitochondria in an Alzheimer's disease mouse model. Proc. Natl. Acad. Sci. U. S. A. 2010;107:18670–18675.
    1. Ebert D., Haller R.G., Walton M.E. Energy contribution of octanoate to intact rat brain metabolism measured by 13C nuclear magnetic resonance spectroscopy. J. Neurosci. 2003;23:5928–5935.
    1. Erten-Lyons D., Woltjer R., Kaye J., Mattek N., Dodge H.H., Green S., Tran H., Howieson D.B., Wild K., Silbert L.C. Neuropathologic basis of white matter hyperintensity accumulation with advanced age. Neurology. 2013;81:977–983.
    1. Farooqui A.A., Horrocks L.A. Brain phospholipases A2: a perspective on the history. Prostaglandins Leukot. Essent. Fatty Acids. 2004;71:161–169.
    1. Farooqui A.A., Horrocks L.A. Phospholipase A2-generated lipid mediators in the brain: the good, the bad, and the ugly. Neuroscientist. 2006;12:245–260.
    1. Federico A., Cardaioli E., Da Pozzo P., Formichi P., Gallus G.N., Radi E. Mitochondria, oxidative stress and neurodegeneration. J. Neurol. Sci. 2012;322:254–262.
    1. Filippov V., Song M.A., Zhang K., Vinters H.V., Tung S., Kirsch W.M., Yang J., Duerksen-Hughes P.J. Increased ceramide in brains with Alzheimer's and other neurodegenerative diseases. J. Alzheimers Dis. 2012;29:537–547.
    1. Finch C.E., Felicio L.S., Mobbs C.V., Nelson J.F. Ovarian and steroidal influences on neuroendocrine aging processes in female rodents. Endocr. Rev. 1984;5:467–497.
    1. Fonteh A.N., Cipolla M., Chiang J., Arakaki X., Harrington M.G. Human cerebrospinal fluid fatty acid levels differ between supernatant fluid and brain-derived nanoparticle fractions, and are altered in Alzheimer's disease. PLoS One. 2014;9
    1. Ge Y., Grossman R.I., Babb J.S., Rabin M.L., Mannon L.J., Kolson D.L. Age-related total gray matter and white matter changes in normal adult brain. Part II: quantitative magnetization transfer ratio histogram analysis. AJNR Am. J. Neuroradiol. 2002;23:1334–1341.
    1. Gibson G.E., Huang H.M. Oxidative Stress in Alzheimer's disease. Neurobiol. Aging. 2005;26:575–578.
    1. Gibson G.E., Blass J.P., Beal M.F., Bunik V. The alpha-ketoglutarate–dehydrogenase complex: a mediator between mitochondria and oxidative stress in neurodegeneration. Mol. Neurobiol. 2005;31:43–63.
    1. Gibson G.E., Sheu K.F., Blass J.P. Abnormalities of mitochondrial enzymes in Alzheimer disease. J. Neural Transm. 1998;105:855–870.
    1. Gilmore S., Peakall R., Robertson J. Organelle DNA haplotypes reflect crop-use characteristics and geographic origins of Cannabis sativa. Forensic Sci. Int. 2007;172:179–190.
    1. Glatz J.F., Luiken J.J., Bonen A. Membrane fatty acid transporters as regulators of lipid metabolism: implications for metabolic disease. Physiol. Rev. 2010;90:367–417.
    1. Gosden R.G., Laing S.C., Flurkey K., Finch C.E. Graafian follicle growth and replacement in anovulatory ovaries of ageing C57BL/6J mice. J. Reprod. Fertil. 1983;69:453–462.
    1. Guzman M., Blazquez C. Ketone body synthesis in the brain: possible neuroprotective effects. Prostaglandins Leukot. Essent. Fatty Acids. 2004;70:287–292.
    1. Han X., Holtzman D.M., Mckeel D.W., Jr., Kelley J., Morris J.C. Substantial sulfatide deficiency and ceramide elevation in very early Alzheimer's disease: potential role in disease pathogenesis. J. Neurochem. 2002;82:809–818.
    1. Han W.K., Sapirstein A., Hung C.C., Alessandrini A., Bonventre J.V. Cross-talk between cytosolic phospholipase A2 alpha (cPLA2 alpha) and secretory phospholipase A2 (sPLA2) in hydrogen peroxide-induced arachidonic acid release in murine mesangial cells: sPLA2 regulates cPLA2 alpha activity that is responsible for arachidonic acid release. J Biol Chem. 2003;278:24153–24163.
    1. Hansson O., Zetterberg H., Buchhave P., Londos E., Blennow K., Minthon L. Association between CSF biomarkers and incipient Alzheimer's disease in patients with mild cognitive impairment: a follow-up study. Lancet Neurol. 2006;5:228–234.
    1. He X., Huang Y., Li B., Gong C.X., Schuchman E.H. Deregulation of sphingolipid metabolism in Alzheimer's disease. Neurobiol. Aging. 2010;31:398–408.
    1. Herholz K. Cerebral glucose metabolism in preclinical and prodromal Alzheimer's disease. Expert. Rev. Neurother. 2010;10:1667–1673.
    1. Hoyer S. Abnormalities of glucose metabolism in Alzheimer's disease. Ann. N. Y. Acad. Sci. 1991;640:53–58.
    1. Hoyer S., Nitsch R., Oesterreich K. Predominant abnormality in cerebral glucose utilization in late-onset dementia of the Alzheimer type: a cross-sectional comparison against advanced late-onset and incipient early-onset cases. J. Neural Transm. Park. Dis. Dement. Sect. 1991;3:1–14.
    1. Irwin R.W., Yao J., Hamilton R.T., Cadenas E., Brinton R.D., Nilsen J. Progesterone and estrogen regulate oxidative metabolism in brain mitochondria. Endocrinology. 2008;149:3167–3175.
    1. Jagust W., Reed B., Mungas D., Ellis W., Decarli C. What does fluorodeoxyglucose PET imaging add to a clinical diagnosis of dementia? Neurology. 2007;69:871–877.
    1. Jahanshad N., Kochunov P.V., Sprooten E., Mandl R.C., Nichols T.E., Almasy L., Blangero J., Brouwer R.M., Curran J.E., De Zubicaray G.I., Duggirala R., Fox P.T., Hong L.E., Landman B.A., Martin N.G., Mcmahon K.L., Medland S.E., Mitchell B.D., Olvera R.L., Peterson C.P., Starr J.M., Sussmann J.E., Toga A.W., Wardlaw J.M., Wright M.J., Hulshoff Pol H.E., Bastin M.E., Mcintosh A.M., Deary I.J., Thompson P.M., Glahn D.C. Multi-site genetic analysis of diffusion images and voxelwise heritability analysis: a pilot project of the ENIGMA-DTI working group. NeuroImage. 2013;81:455–469.
    1. Kadish I., Thibault O., Blalock E.M., Chen K.C., Gant J.C., Porter N.M., Landfield P.W. Hippocampal and cognitive aging across the lifespan: a bioenergetic shift precedes and increased cholesterol trafficking parallels memory impairment. J. Neurosci. 2009;29:1805–1816.
    1. Koek M.M., Muilwijk B., Van Der Werf M.J., Hankemeier T. Microbial metabolomics with gas chromatography/mass spectrometry. Anal. Chem. 2006;78:1272–1281.
    1. Lebel C., Gee M., Camicioli R., Wieler M., Martin W., Beaulieu C. Diffusion tensor imaging of white matter tract evolution over the lifespan. NeuroImage. 2012;60:340–352.
    1. Li L., Ruau D.J., Patel C.J., Weber S.C., Chen R., Tatonetti N.P., Dudley J.T., Butte A.J. Disease risk factors identified through shared genetic architecture and electronic medical records. Sci. Transl. Med. 2014;6
    1. Lin M.T., Beal M.F. Mitochondrial dysfunction and oxidative stress in neurodegenerative diseases. Nature. 2006;443:787–795.
    1. Ling Y.H., Liebes L., Zou Y., Perez-Soler R. Reactive oxygen species generation and mitochondrial dysfunction in the apoptotic response to Bortezomib, a novel proteasome inhibitor, in human H460 non-small cell lung cancer cells. J. Biol. Chem. 2003;278:33714–33723.
    1. Lu P.H., Lee G.J., Tishler T.A., Meghpara M., Thompson P.M., Bartzokis G. Myelin breakdown mediates age-related slowing in cognitive processing speed in healthy elderly men. Brain Cogn. 2013;81:131–138.
    1. Malaplate-Armand C., Florent-Bechard S., Youssef I., Koziel V., Sponne I., Kriem B., Leininger-Muller B., Olivier J.L., Oster T., Pillot T. Soluble oligomers of amyloid-beta peptide induce neuronal apoptosis by activating a cPLA2-dependent sphingomyelinase-ceramide pathway. Neurobiol. Dis. 2006;23:178–189.
    1. Marner L., Nyengaard J.R., Tang Y., Pakkenberg B. Marked loss of myelinated nerve fibers in the human brain with age. J. Comp. Neurol. 2003;462:144–152.
    1. Moreira P.I., Cardoso S.M., Santos M.S., Oliveira C.R. The key role of mitochondria in Alzheimer's disease. J. Alzheimers Dis. 2006;9:101–110.
    1. Morris A.A. Cerebral ketone body metabolism. J. Inherit. Metab. Dis. 2005;28:109–121.
    1. Mosconi L. Brain glucose metabolism in the early and specific diagnosis of Alzheimer's disease. FDG-PET studies in MCI and AD. Eur. J. Nucl. Med. Mol. Imaging. 2005;32:486–510.
    1. Mosconi L., De Santi S., Brys M., Tsui W.H., Pirraglia E., Glodzik-Sobanska L., Rich K.E., Switalski R., Mehta P.D., Pratico D., Zinkowski R., Blennow K., De Leon M.J. Hypometabolism and altered cerebrospinal fluid markers in normal apolipoprotein E E4 carriers with subjective memory complaints. Biol. Psychiatry. 2008;63:609–618.
    1. Mosconi L., De Santi S., Li J., Tsui W.H., Li Y., Boppana M., Laska E., Rusinek H., De Leon M.J. Hippocampal hypometabolism predicts cognitive decline from normal aging. Neurobiol. Aging. 2008;29:676–692.
    1. Mosconi L., Mistur R., Switalski R., Brys M., Glodzik L., Rich K., Pirraglia E., Tsui W., De Santi S., De Leon M.J. Declining brain glucose metabolism in normal individuals with a maternal history of Alzheimer disease. Neurology. 2009;72:513–520.
    1. Mosconi L., Mistur R., Switalski R., Tsui W.H., Glodzik L., Li Y., Pirraglia E., De Santi S., Reisberg B., Wisniewski T., De Leon M.J. FDG-PET changes in brain glucose metabolism from normal cognition to pathologically verified Alzheimer's disease. Eur. J. Nucl. Med. Mol. Imaging. 2009;36:811–822.
    1. Mosconi L., Berti V., Glodzik L., Pupi A., De Santi S., De Leon M.J. Pre-clinical detection of Alzheimer's disease using FDG-PET, with or without amyloid imaging. J. Alzheimers Dis. 2010;20:843–854.
    1. Mosconi L., De Leon M., Murray J., Lezi E., Lu J., Javier E., Mchugh P., Swerdlow R.H. Reduced mitochondria cytochrome oxidase activity in adult children of mothers with Alzheimer's disease. J. Alzheimers Dis. 2011;27:483–490.
    1. Mosconi L., Herholz K., Prohovnik I., Nacmias B., De Cristofaro M.T., Fayyaz M., Bracco L., Sorbi S., Pupi A. Metabolic interaction between ApoE genotype and onset age in Alzheimer's disease: implications for brain reserve. J. Neurol. Neurosurg. Psychiatry. 2005;76:15–23.
    1. Mosconi L., Pupi A., De Leon M.J. Brain glucose hypometabolism and oxidative stress in preclinical Alzheimer's disease. Ann. N. Y. Acad. Sci. 2008;1147:180–195.
    1. Mosconi L., Sorbi S., De Leon M.J., Li Y., Nacmias B., Myoung P.S., Tsui W., Ginestroni A., Bessi V., Fayyazz M., Caffarra P., Pupi A. Hypometabolism exceeds atrophy in presymptomatic early-onset familial Alzheimer's disease. J. Nucl. Med. 2006;47:1778–1786.
    1. Nilsen J., Irwin R.W., Gallaher T.K., Brinton R.D. Estradiol in vivo regulation of brain mitochondrial proteome. J. Neurosci. 2007;27:14069–14077.
    1. Panov A., Orynbayeva Z., Vavilin V., Lyakhovich V. Fatty acids in energy metabolism of the central nervous system. Biomed. Res. Int. 2014;2014:472459.
    1. Persson X.M., Blachnio-Zabielska A.U., Jensen M.D. Rapid measurement of plasma free fatty acid concentration and isotopic enrichment using LC/MS. J. Lipid Res. 2010;51:2761–2765.
    1. Prior J.C. Perimenopause: the complex endocrinology of the menopausal transition. Endocr. Rev. 1998;19:397–428.
    1. Quehenberger O., Armando A., Dumlao D., Stephens D.L., Dennis E.A. Lipidomics analysis of essential fatty acids in macrophages. Prostaglandins Leukot. Essent. Fatty Acids. 2008;79:123–129.
    1. Rasgon N.L., Silverman D., Siddarth P., Miller K., Ercoli L.M., Elman S., Lavretsky H., Huang S.C., Phelps M.E., Small G.W. Estrogen use and brain metabolic change in postmenopausal women. Neurobiol. Aging. 2005;26:229–235.
    1. Reiman E.M., Caselli R.J., Yun L.S., Chen K., Bandy D., Minoshima S., Thibodeau S.N., Osborne D. Preclinical evidence of Alzheimer's disease in persons homozygous for the epsilon 4 allele for apolipoprotein E. N. Engl. J. Med. 1996;334:752–758.
    1. Reiman E.M., Chen K., Alexander G.E., Caselli R.J., Bandy D., Osborne D., Saunders A.M., Hardy J. Functional brain abnormalities in young adults at genetic risk for late-onset Alzheimer's dementia. Proc. Natl. Acad. Sci. U. S. A. 2004;101:284–289.
    1. Rogers G.W., Brand M.D., Petrosyan S., Ashok D., Elorza A.A., Ferrick D.A., Murphy A.N. High throughput microplate respiratory measurements using minimal quantities of isolated mitochondria. PLoS One. 2011;6
    1. Rowe W.B., Blalock E.M., Chen K.C., Kadish I., Wang D., Barrett J.E., Thibault O., Porter N.M., Rose G.M., Landfield P.W. Hippocampal expression analyses reveal selective association of immediate-early, neuroenergetic, and myelinogenic pathways with cognitive impairment in aged rats. J. Neurosci. 2007;27:3098–3110.
    1. Sanchez-Mejia R.O., Mucke L. Phospholipase A2 and arachidonic acid in Alzheimer's disease. Biochim. Biophys. Acta. 2010;1801:784–790.
    1. Santoro N. The menopausal transition. Am. J. Med. 2005;118(Suppl. 12B):8–13.
    1. Schaeffer E.L., Da Silva E.R., Novaes B.D.E.A., Skaf H.D., Gattaz W.F. Differential roles of phospholipases A2 in neuronal death and neurogenesis: implications for Alzheimer disease. Prog. Neuro-Psychopharmacol. Biol. Psychiatry. 2010;34:1381–1389.
    1. Schmittgen T.D., Livak K.J. Analyzing real-time PCR data by the comparative CT method. Nat. Protoc. 2008;3:1101–1108.
    1. Silverman D.H., Geist C.L., Kenna H.A., Williams K., Wroolie T., Powers B., Brooks J., Rasgon N.L. Differences in regional brain metabolism associated with specific formulations of hormone therapy in postmenopausal women at risk for AD. Psychoneuroendocrinology. 2011;36:502–513.
    1. Sprooten E., Knowles E.E., Mckay D.R., Goring H.H., Curran J.E., Kent J.W., Jr., Carless M.A., Dyer T.D., Drigalenko E.I., Olvera R.L., Fox P.T., Almasy L., Duggirala R., Kochunov P., Blangero J., Glahn D.C. Common genetic variants and gene expression associated with white matter microstructure in the human brain. NeuroImage. 2014;97:252–261.
    1. Stacpoole P.W. The pyruvate dehydrogenase complex as a therapeutic target for age-related diseases. Aging Cell. 2012;11:371–377.
    1. Stephenson D.T., Lemere C.A., Selkoe D.J., Clemens J.A. Cytosolic phospholipase A2 (cPLA2) immunoreactivity is elevated in Alzheimer's disease brain. Neurobiol. Dis. 1996;3:51–63.
    1. Stephenson D., Rash K., Smalstig B., Roberts E., Johnstone E., Sharp J., Panetta J., Little S., Kramer R., Clemens J. Cytosolic phospholipase A2 is induced in reactive glia following different forms of neurodegeneration. Glia. 1999;27:110–128.
    1. Sun G.Y., Xu J., Jensen M.D., Simonyi A. Phospholipase A2 in the central nervous system: implications for neurodegenerative diseases. J. Lipid Res. 2004;45:205–213.
    1. Swerdlow R.H., Khan S.M. The Alzheimer's disease mitochondrial cascade hypothesis: an update. Exp. Neurol. 2009;218:308–315.
    1. Tang Y., Nyengaard J.R., Pakkenberg B., Gundersen H.J. Age-induced white matter changes in the human brain: a stereological investigation. Neurobiol. Aging. 1997;18:609–615.
    1. Tiwari-Woodruff S., Morales L.B., Lee R., Voskuhl R.R. Differential neuroprotective and antiinflammatory effects of estrogen receptor (ER)alpha and ERbeta ligand treatment. Proc. Natl. Acad. Sci. U. S. A. 2007;104:14813–14818.
    1. Tournier C., Thomas G., Pierre J., Jacquemin C., Pierre M., Saunier B. Mediation by arachidonic acid metabolites of the H2O2-induced stimulation of mitogen-activated protein kinases (extracellular-signal-regulated kinase and c-Jun NH2-terminal kinase) Eur. J. Biochem. 1997;244:587–595.
    1. Trushina E., Dutta T., Persson X.M., Mielke M.M., Petersen R.C. Identification of altered metabolic pathways in plasma and CSF in mild cognitive impairment and Alzheimer's disease using metabolomics. PLoS One. 2013;8
    1. Veech R.L., Chance B., Kashiwaya Y., Lardy H.A., Cahill G.F., Jr. Ketone bodies, potential therapeutic uses. IUBMB Life. 2001;51:241–247.
    1. Vlassenko A.G., Vaishnavi S.N., Couture L., Sacco D., Shannon B.J., Mach R.H., Morris J.C., Raichle M.E., Mintun M.A. Spatial correlation between brain aerobic glycolysis and amyloid-beta (Abeta) deposition. Proc. Natl. Acad. Sci. U. S. A. 2010;107:17763–17767.
    1. Weber M.T., Maki P.M., Mcdermott M.P. Cognition and mood in perimenopause: a systematic review and meta-analysis. J. Steroid Biochem. Mol. Biol. 2014;142:90–98.
    1. Weber M.T., Rubin L.H., Maki P.M. Cognition in perimenopause: the effect of transition stage. Menopause. 2013;20:511–517.
    1. Xu J., Yu S., Sun A.Y., Sun G.Y. Oxidant-mediated AA release from astrocytes involves cPLA2 and iPLA2. Free Radic. Biol. Med. 2003;34:1531–1543.
    1. Yao J., Chen S., Mao Z., Cadenas E., Brinton R.D. 2-Deoxy-d-glucose treatment induces ketogenesis, sustains mitochondrial function, and reduces pathology in female mouse model of Alzheimer's disease. PLoS One. 2011;6
    1. Yao J., Hamilton R.T., Cadenas E., Brinton R.D. Decline in mitochondrial bioenergetics and shift to ketogenic profile in brain during reproductive senescence. Biochim. Biophys. Acta. 2010;1800:1121–1126.
    1. Yao J., Irwin R., Chen S., Hamilton R., Cadenas E., Brinton R.D. Ovarian hormone loss induces bioenergetic deficits and mitochondrial beta-amyloid. Neurobiol. Aging. 2012;33:1507–1521.
    1. Yao J., Irwin R.W., Zhao L., Nilsen J., Hamilton R.T., Brinton R.D. Mitochondrial bioenergetic deficit precedes Alzheimer's pathology in female mouse model of Alzheimer's disease. Proc. Natl. Acad. Sci. U. S. A. 2009;106:14670–14675.
    1. Yao J., Rettberg J.R., Klosinski L.P., Cadenas E., Brinton R.D. Shift in brain metabolism in late onset Alzheimer's disease: implications for biomarkers and therapeutic interventions. Mol. Asp. Med. 2011;32:247–257.
    1. Yap L.P., Garcia J.V., Han D., Cadenas E. The energy-redox axis in aging and age-related neurodegeneration. Adv. Drug Deliv. Rev. 2009;61:1283–1298.
    1. Yin F., Boveris A., Cadenas E. Mitochondrial energy metabolism and redox signaling in brain aging and neurodegeneration. Antioxid. Redox Signal. 2014;20:353–371.
    1. Yin F., Yao J., Sancheti H., Feng T., Melcangi R.C., Morgan T.E., Finch C.E., Pike C.J., Mack W.J., Cadenas E., Brinton R.D. The perimenopausal aging transition in the female rat brain: decline in bioenergetic systems and synaptic plasticity. Neurobiol. Aging. 2015;36:2282–2295.
    1. Zhang L., Dean D., Liu J.Z., Sahgal V., Wang X., Yue G.H. Quantifying degeneration of white matter in normal aging using fractal dimension. Neurobiol. Aging. 2007;28:1543–1555.
    1. Zhao L., Morgan T.E., Mao Z., Lin S., Cadenas E., Finch C.E., Pike C.J., Mack W.J., Brinton R.D. Continuous versus cyclic progesterone exposure differentially regulates hippocampal gene expression and functional profiles. PLoS One. 2012;7

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