Phospholipids and Alzheimer’s Disease: Alterations, Mechanisms and Potential Biomarkers
Abstract
:1. Introduction
2. Phospholipid Changes in Alzheimer’s Disease
2.1. Alzheimer’s Disease
2.2. Phospholipid Changes in the Brain of Individuals with Alzheimer’s Disease
2.3. Phospholipid Changes in the CSF and Blood of Individuals with Alzheimer’s Disease
3. Lipids as Biomarkers for Alzheimer’s Disease Diagnosis and as Targets for Potential Novel Treatment Strategies
3.1. Sulfatides
3.2. Ceramide
3.3. Lipid Rafts
4. Conclusions
Abbreviations
Aβ | Amyloid beta peptide |
AD | Alzheimer’s disease |
Apo E | apolipoprotein E |
APP | Amyloid Precursor Protein |
CDR | clinical dementia rating |
CSF | cerebrospinal fluid |
CTF | Amyloid Precursor Protein C-terminal fragments |
ESI-MS | electrospray mass spectrometry |
GC | gas chromatography |
HPG | subiculum of the hippocampus and parahippocampal gyrus |
HPLC | high-performance liquid chromatography |
IPL | inferior parietal lobe |
MFG | middle frontal gyrus |
MTG | middle temporal gyrus |
PC | phosphatidylcholine |
PE | phosphatidylethanolamine |
PI | phosphatidylinositol |
PPE | ethanolamine plasmalogen |
sAPP | soluble Amyloid Precursor Protein N-terminal fragments α or β |
SM | sphingomyelin |
SMFG | superior-middle frontal gyrus |
SMTG | superior-middle temporal gyrus |
SFG | superior frontal gyrus |
STG | superior temporal gyrus |
TLC | thin layer chromatography |
- Conflict of InterestThe authors declare no conflict of interest.
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Lipid class | Change/Normalization | Sample size/Examined brain regions/Analytical method | Reference |
---|---|---|---|
PI | decreased/wet weight | 9 AD and 9 controls/HPG, SMTG, IPL and cerebellum/TLC | [14] |
PI | decreased/wet weight | 17 AD and 18 controls/anterior temporal cortex/TLC | [15] |
PI | decreased/relative | 45 AD and 11 controls/SMFG, STG, IPL, occipital cortex and cerebellum/31P NMR | [21] |
PE | decreased/wet weight | 9 AD and 9 controls/HPG, SMTG, IPL and cerebellum/TLC | [14] |
PE | decreased/DNA | 10 AD and 10 controls/frontal, primary auditory and parietal cortex/photometrical phosphorus determination | [16] |
PPE | decreased/relative | 9 AD and 9 controls/middle-temporal cortex/HPLC and TLC | [18] |
PPE | decreased/phosphate | 15 AD and 13 controls/frontal cortex, hippocampus and white matter/HPLC and GC | [19] |
PPE | decreased/relative | 45 AD and 11 controls/SMFG, STG, IPL, occipital cortex and cerebellum/31P NMR | [21] |
PPE | decreased/protein | 6 CDR = 0; 6 CDR = 0.5; 6 CDR = 1; 6 CDR = 2; 6 CDR = 5/white and gray matter from SFG, STG, IPL and cerebellum/ESI-MS | [22] |
PC | unchanged/wet weight | 9 AD and 9 controls/HPG, SMTG, IPL and cerebellum/TLC | [14] |
PC | decreased/DNA | 10 AD and 10 controls/frontal, primary auditory and parietal cortex/HPLC–fluorimetric detection | [16] |
PC | unchanged/wet weight | 6 AD and 4 controls/gray matter from frontal cortex, parietal and temporal region/HPLC | [17] |
PC | decreased/phosphate | 15 AD and 13 controls/frontal cortex, hippocampus and white matter/HPLC and GC | [19] |
SM | decreased/protein | 9 AD and 6 controls/gray matter from frontotemporal area/enzymatic assay–HPLC | [24] |
SM | decreased/relative | 7 AD and 7 controls/MFG, SFG and cerebellum/ESI-MS | [25] |
SM | increased/relative | 30 AD and 26 controls/MFG, MTG and cerebellum/ESI-MS | [26] |
SM | increased/relative | 45 AD and 11 controls/SMFG, STG, IPL, occipital cortex and cerebellum/31P NMR | [21] |
ceramide | increased/protein | 6 CDR = 0; 6 CDR = 0.5; 6 CDR = 1; 6 CDR = 2; 6 CDR = 5/white and gray matter from MFG, STG, IPL and cerebellum/ESI-MS | [22] |
ceramide | increased/protein | 9 AD and 6 controls/gray matter from frontotemporal area/enzymatic assay–HPLC | [24] |
ceramide | increased/relative | 7 AD and 7 controls/MFG, SFG and cerebellum/ESI-MS | [25] |
sulfatide | decreased/protein | 6 CDR = 0; 6 CDR = 0.5; 6 CDR = 1; 6 CDR = 2; 6 CDR = 5/white and gray matter from MFG, STG, IPL and cerebellum/ESI-MS | [23] |
Lipid class | Change | Sample size/Sample collection | Reference |
---|---|---|---|
PC | decreased lysoPC/PC | 30 AD and 31 controls/post mortem | [30] |
PC | increased PC metabolites | 12 AD and 30 controls/lumbar puncture | [31] |
SM | increase in prodromal AD | 21 AD and 16 controls/lumbar puncture | [35] |
ceramide | increase | 16 AD and 14 controls/lumbar puncture | [32] |
sulfatide | decrease | 19 CDR = 0; 20 CDR = 0.5/lumbar puncture | [33] |
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Kosicek, M.; Hecimovic, S. Phospholipids and Alzheimer’s Disease: Alterations, Mechanisms and Potential Biomarkers. Int. J. Mol. Sci. 2013, 14, 1310-1322. https://doi.org/10.3390/ijms14011310
Kosicek M, Hecimovic S. Phospholipids and Alzheimer’s Disease: Alterations, Mechanisms and Potential Biomarkers. International Journal of Molecular Sciences. 2013; 14(1):1310-1322. https://doi.org/10.3390/ijms14011310
Chicago/Turabian StyleKosicek, Marko, and Silva Hecimovic. 2013. "Phospholipids and Alzheimer’s Disease: Alterations, Mechanisms and Potential Biomarkers" International Journal of Molecular Sciences 14, no. 1: 1310-1322. https://doi.org/10.3390/ijms14011310
APA StyleKosicek, M., & Hecimovic, S. (2013). Phospholipids and Alzheimer’s Disease: Alterations, Mechanisms and Potential Biomarkers. International Journal of Molecular Sciences, 14(1), 1310-1322. https://doi.org/10.3390/ijms14011310