Restricted accessResearch articleFirst published online 2022
Multivariate Assessment of Lipoxidative Metabolites,Trace Biometals,and Antioxidant and Detoxifying Activities in the Cerebrospinal Fluid Define a Fingerprint of Preclinical Stages of Alzheimer’s Disease
There exists considerable interest in the identification of molecular traits during early stages of Alzheimer’s disease (AD). Mild cognitive impairment (MCI) is considered the closest prodromal stage of AD, and to develop gradually from earlier stages although not always progresses to AD. Classical cerebrospinal fluid (CSF) AD biomarkers, amyloid-β peptides and tau/p-tau proteins, have been measured in prodromal stages yet results are heterogeneous and far from conclusive. Therefore, there exists a pressing need to identify a neurochemical signature for prodromal stages and to predict which cases might progress to AD.
Objective:
Exploring potential CSF biomarkers related to brain oxidative and inorganic biochemistry during prodromal stages of the disease.
Methods:
We have analyzed CSF levels of lipoxidative markers (MDA and 8-isoF2α), biometals (Cu, Zn, Se, Mn, and Fe), iron-transport protein transferrin (TFER), antioxidant enzymes (SOD and GPx4), detoxifying enzymes (GST and BuChE), as well as classical amyloid-β and total and phosphorylated tau, in cognitively healthy controls, patients with MCI, and subjects exhibiting subjective memory complaints (SMC).
Results:
Inter-group differences for several variables exhibit differentiable trends along the HC ⟶ SMC ⟶ MCI sequence. More interestingly, the combination of Se, Cu, Zn, SOD, TFER, and GST variables allow differentiable fingerprints for control subjects and each prodromal stage. Further, multivariate scores correlate positively with neurocognitive In-Out test, hence with both episodic memory decline and prediction to dementia.
Conclusion:
We conclude that changes in the CSF biochemistry related to brain oxidative defense and neurometallomics might provide more powerful and accurate diagnostic tools in preclinical stages of AD.
BatureF, GuinnB, PangD, PappasY (2017) Signs and symptoms preceding the diagnosis of Alzheimer’s disease: A systematic scoping review of literature from 1937 to 2016. BMJ Open7, e015746.
BealMF (2005) Oxidative damage as an early marker of Alzheimer’s disease and mild cognitive impairment. Neurobiol Aging26, 585–586.
10.
CataláA, DíazM (2016) Editorial: Impact of lipid peroxidation on the physiology and pathophysiology of cell membranes. Front Physiol7, 423.
11.
DíazM, MarínR (2013) Brain polyunsaturated lipids and neurodegenerative diseases. In Nutraceuticals and Functional Foods: Natural Remedy. Nova Science, Hauppauge, NY, pp. 387–412.
12.
CollinF (2019) Chemical basis of reactive oxygen species reactivity and involvement in neurodegenerative diseases. Int J Mol Sci20, 2407.
13.
CataláA (2009) Lipid peroxidation of membrane phospholipids generates hydroxy-alkenals and oxidized phospholipids active in physiological and/or pathological conditions. Chem Phys Lipids157, 1–11.
14.
LovellMA, EhmannWD, ButlerSM, MarkesberyWR (1995) Elevated thiobarbituric acid-reactive substances and antioxidant enzyme activity in the brain in Alzheimer’s disease. Neurology45, 1594–1601.
15.
AnsariMA, ScheffSW (2010) Oxidative stress in the progression of Alzheimer disease in the frontal cortex. J Neuropathol Exp Neurol69, 155–167.
16.
PraticòD, SungS (2004) Lipid peroxidation and oxidative imbalance: Early functional events in Alzheimer’s disease. J Alzheimers Dis6, 171–175.
17.
YoussefP, ChamiB, LimJ, MiddletonT, SutherlandGT, WittingPK (2018) Evidence supporting oxidative stress in a moderately affected area of the brain in Alzheimer’s disease. Sci Rep8, 11553.
18.
SultanaR, ButterfieldDA (2004) Oxidatively modified GST and MRP1 in Alzheimer’s disease brain: Implications for accumulation of reactive lipid peroxidation products. Neurochem Res29, 2215–2220.
19.
KellerJN, SchmittFA, ScheffSW, DingQ, ChenQ, ButterfieldDA, MarkesberyWR (2005) Evidence of increased oxidative damage in subjects with mild cognitive impairment. Neurology64, 1152–1156.
Di DomenicoF, PupoG, GiraldoE, BadìaM-C, MonllorP, LloretA, SchininàME, GiorgiA, CiniC, TramutolaA, ButterfieldDA, ViñaJ, PerluigiM (2016) Oxidative signature of cerebrospinal fluid from mild cognitive impairment and Alzheimer disease patients. Free Radic Biol Med91, 1–9.
22.
BuccellatoFR, AncaMD, FenoglioC, ScarpiniE, GalimbertiD (2021) Role of oxidative damage in Alzheimer’s disease and neurodegeneration: From pathogenic mechanisms to biomarker discovery. Antioxidants10, 1353.
23.
VistoliG, De MaddisD, CipakA, ZarkovicN, CariniM, AldiniG (2013) Advanced glycoxidation and lipoxidation end products (AGEs and ALEs): An overview of their mechanisms of formation. Free Radic Res47(Suppl 1), 3–27.
24.
KehmR, BaldenspergerT, RaupbachJ, HöhnA (2021) Protein oxidation - Formation mechanisms, detection and relevance as biomarkers in human diseases. Redox Biol42, 101901.
25.
Pérez-SalaD, DominguesR (2019) Lipoxidation targets: From basic mechanisms to pathophysiology. Redox Biol23, 101208.
26.
GonzaloH, BrievaL, TatzberF, JovéM, CacabelosD, CassanyéA, Lanau-AnguloL, BoadaJ, SerranoJCE, GonzálezC, HernándezL, PeraltaS, PamplonaR, Portero-OtinM (2012) Lipidome analysis in multiple sclerosis reveals protein lipoxidative damage as a potential pathogenic mechanism. J Neurochem123, 622–634.
Domínguez-GonzálezM, PuigpinósM, JovéM, NaudiA, Portero-OtínM, PamplonaR, FerrerI (2018) Regional vulnerability to lipoxidative damage and inflammation in normal human brain aging. Exp Gerontol111, 218–228.
29.
LovellMA, XieC, MarkesberyWR (1998) Decreased glutathione transferase activity in brain and ventricular fluid in Alzheimer’s disease. Neurology51, 1562–1566.
30.
MazzettiAP, FiorileMC, PrimaveraA, Lo BelloM (2015) Glutathione transferases and neurodegenerative diseases. Neurochem Int82, 10–18.
31.
KumarA, DhullDK, GuptaV, ChannanaP, SinghA, BhardwajM, RuhalP, MittalR (2017) Role of Glutathione-S-transferases in neurological problems. Expert Opin Ther Pat27, 299–309.
32.
OpazoC, HuangX, ChernyRA, MoirRD, RoherAE, WhiteAR, CappaiR, MastersCL, TanziRE, InestrosaNC, BushAI (2002) Metalloenzyme-like activity of Alzheimer’s disease beta-amyloid. Cu-dependent catalytic conversion of dopamine, cholesterol, and biological reducing agents to neurotoxic H(2)O(2). J Biol Chem277, 40302–40308.
FredericksonCJ, KohJ-Y, BushAI (2005) The neurobiology of zinc in health and disease. Nat Rev Neurosci6, 449–462.
40.
ZhangS, RocourtC, ChengW-H (2010) Selenoproteins and the aging brain. Mech Ageing Dev131, 253–260.
41.
SavaskanNE, UferC, KühnH, BorchertA (2007) Molecular biology of glutathione peroxidase 4: From genomic structure to developmental expression and neural function. Biol Chem388, 1007–1017.
42.
SussuliniA, Hauser-DavisRA (2018) Metallomics applied to the study of neurodegenerative and mental diseases. Adv Exp Med Biol1055, 21–37.
43.
SchragM, MuellerC, OyoyoU, SmithMA, KirschWM (2011) Iron, zinc and copper in the Alzheimer’s disease brain: A quantitative meta-analysis. Some insight on the influence of citation bias on scientific opinion. Prog Neurobiol94, 296–306.
44.
SinghA, KukretiR, SasoL, KukretiS (2019) Oxidative stress: A key modulator in neurodegenerative diseases. Molecules24, 1583.
45.
PortetF, OussetPJ, VisserPJ, FrisoniGB, NobiliF, ScheltensP, VellasB, TouchonJ (2006) Mild cognitive impairment (MCI) in medical practice: A critical review of the concept and new diagnostic procedure. Report of the MCI Working Group of the European Consortium on Alzheimer’s Disease. J Neurol Neurosurg Psychiatry77, 714–718.
46.
Peña-CasanovaJ, Gramunt-FombuenaN, Quiñones-UbedaS, Sánchez-BenavidesG, AguilarM, BadenesD, MolinuevoJL, RoblesA, BarqueroMS, PaynoM, AntúnezC, Martínez-ParraC, Frank-GarcíaA, FernándezM, AlfonsoV, SolJM, BlesaR (2009) Spanish Multicenter Normative Studies (NEURONORMA Project): Norms for the Rey-Osterrieth complex figure (copy and memory), and free and cued selective reminding test. Arch Clin Neuropsychol24, 371–393.
47.
Peña-CasanovaJ, Quiñones-UbedaS, Gramunt-FombuenaN, QuintanaM, AguilarM, MolinuevoJL, SerradellM, RoblesA, BarqueroMS, PaynoM, AntúnezC, Martínez-ParraC, Frank-GarcíaA, FernándezM, AlfonsoV, SolJM, BlesaR (2009) Spanish Multicenter Normative Studies (NEURONORMA Project): Norms for the Stroop color-word interference test and the Tower of London-Drexel. Arch Clin Neuropsychol24, 413–429.
48.
Casals-CollM, Sánchez-BenavidesG, Meza-CavazosS, ManeroRM, AguilarM, BadenesD, MolinuevoJL, RoblesA, BarqueroMS, AntúnezC, Martínez-ParraC, Frank-GarcíaA, FernándezM, BlesaR, Peña-CasanovaJ (2014) Spanish multicenter normative studies (NEURONORMA project): Normative data and equivalence of four BNT short-form versions. Arch Clin Neuropsychol29, 60–74.
ZigmondAS, SnaithRP (1983) The hospital anxiety and depression scale. Acta Psychiatr Scand67, 361–370.
51.
DunbarM, FordG, HuntK, DerG (2000) A confirmatory factor analysis of the Hospital Anxiety and Depression scale: Comparing empirically and theoretically derived structures. Br J Clin Psychol39, 79–94.
52.
Mesa-HerreraF, Quinto-AlemanyD, DíazM (2019) A sensitive, accurate, and versatile method for the quantification of superoxide dismutase activities in biological preparations. Reactive Oxygen Species7, 10–20.
53.
HabigWH, PabstMJ, JakobyWB (1974) Glutathione S-transferases. The first enzymatic step in mercapturic acid formation. J Biol Chem249, 7130–7139.
54.
LawrenceRA, BurkRF (1976) Glutathione peroxidase activity in selenium-deficient rat liver. 1976. Biochem Biophys Res Commun425, 503–509.
55.
EllmanGL, CourtneyKD, AndresVJ, Feather-StoneRM (1961) A new and rapid colorimetric determination of acetylcholinesterase activity. Biochem Pharmacol7, 88–95.
56.
BradfordMM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem72, 248–254.
57.
OhkawaH, OhishiN, YagiK (1979) Assay for lipid peroxides in animal tissues by thiobarbituric acid reaction. Anal Biochem95, 351–358.
58.
ButterfieldDA, Boyd-KimballD (2020) Mitochondrial oxidative and nitrosative stress and Alzheimer disease. Antioxidants (Basel)9, 818.
59.
LovellMA, MarkesberyWR (2007) Oxidative DNA damage in mild cognitive impairment and late-stage Alzheimer’s disease. Nucleic Acids Res35, 7497–7504.
60.
McLimansKE, ClarkBE, PlagmanA, PappasC, KlinedinstB, AnatharamV, KanthasamyA, WilletteAA (2019) Is cerebrospinal fluid superoxide dismutase 1 a biomarker of tau but not amyloid-induced neurodegeneration in Alzheimer’s disease?Antioxid Redox Signal31, 572–578.
61.
DíazM, Mesa-HerreraF, MarínR (2021) DHA and its elaborated modulation of antioxidant defenses of the brain: Implications in aging and AD neurodegeneration. Antioxidants (Basel)10, 907.
62.
Casañas-SánchezV, PérezJA, FabeloN, Quinto-AlemanyD, DíazML (2015) Docosahexaenoic (DHA) modulates phospholipid-hydroperoxide glutathione peroxidase (Gpx4) gene expression to ensure self-protection from oxidative damage in hippocampal cells. Front Physiol6, 203.
63.
SinghalSS, SinghSP, SinghalP, HorneD, SinghalJ, AwasthiS (2015) Antioxidant role of glutathione S-transferases: 4-Hydroxynonenal, a key molecule in stress-mediated signaling. Toxicol Appl Pharmacol289, 361–370.
64.
AwasthiYC, SharmaR, SinghalSS (1994) Human glutathione S-transferases. Int J Biochem26, 295–308.
65.
GreenoughMA, CamakarisJ, BushAI (2013) Metal dyshomeostasis and oxidative stress in Alzheimer’s disease. Neurochem Int62, 540–555.
66.
BologninS, MessoriL, ZattaP (2009) Metal ion physiopathology in neurodegenerative disorders. Neuromolecular Med11, 223–238.
67.
GerhardssonL, LundhT, MinthonL, LondosE (2008) Metal concentrations in plasma and cerebrospinal fluid in patients with Alzheimer’s disease. Dement Geriatr Cogn Disord25, 508–515.
68.
LoefM, SchrauzerGN, WalachH (2011) Selenium and Alzheimer’s disease: A systematic review. J Alzheimers Dis26, 81–104.
69.
LovellMA, RobertsonJD, TeesdaleWJ, CampbellJL, MarkesberyWR (1998) Copper, iron and zinc in Alzheimer’s disease senile plaques. J Neurol Sci158, 47–52.
70.
MolinaJA, Jiménez-JiménezFJ, AguilarMV, MeseguerI, Mateos-VegaCJ, González-MuñozMJ, de BustosF, PortaJ, Ortí-ParejaM, ZurdoM, BarriosE, Martínez-ParaMC (1998) Cerebrospinal fluid levels of transition metals in patients with Alzheimer’s disease. J Neural Transm105, 479–488.
71.
UllahI, ZhaoL, HaiY, FahimM, AlwayliD, WangX, LiH (2021) “Metal elements and pesticides as risk factors for Parkinson’s disease - A review”. Toxicol Rep8, 607–616.
72.
KovatsiL, TouliouK, AndMT, KazisA (2006) Cerebrospinal fluid levels of calcium, magnesium, copper and zinc in patients with Alzheimer’s disease and mild cognitive impairment. Trace Elem Electrolytes23, 247–250.
73.
DuK, LiuM, PanY, ZhongX, WeiM (2017) Association of serum manganese levels with Alzheimer’s disease and mild cognitive impairment: A systematic review and meta-analysis. Nutrients9, 231.
74.
MillerLM, WangQ, TelivalaTP, SmithRJ, LanzirottiA, MiklossyJ (2006) Synchrotron-based infrared and X-ray imaging shows focalized accumulation of Cu and Zn co-localized with beta-amyloid deposits in Alzheimer’s disease. J Struct Biol155, 30–37.
75.
StoltenbergM, BushAI, BachG, SmidtK, LarsenA, RungbyJ, LundS, DoeringP, DanscherG (2007) Amyloid plaques arise from zinc-enriched cortical layers in APP/PS1 transgenic mice and are paradoxically enlarged with dietary zinc deficiency. Neuroscience150, 357–369.
PagliaG, MiedicoO, CristofanoA, VitaleM, AngiolilloA, ChiaravalleAE, CorsoG, Di CostanzoA (2016) Distinctive pattern of serum elements during the progression of Alzheimer’s disease. Sci Rep6, 22769.
78.
CardosoBR, OngTP, Jacob-FilhoW, JaluulO, FreitasMI d’Ávila, CozzolinoSMF (2010) Nutritional status of selenium in Alzheimer’s disease patients. Br J Nutr103, 803–806.
79.
DongJ, AtwoodCS, AndersonVE, SiedlakSL, SmithMA, PerryG, CareyPR (2003) Metal binding and oxidation of amyloid-β within isolated senile plaque cores: Raman microscopic evidence. Biochemistry42, 2768–2773.
80.
LeskovjanAC, KretlowA, LanzirottiA, BarreaR, VogtS, MillerLM (2011) Increased brain iron coincides with early plaque formation in a mouse model of Alzheimer’s disease. Neuroimage55, 32–38.
81.
TorrealbaE, Garcia-MoralesP, CejudoJC, DiazM, Rodriguez-EsparragonF, FabreO, Mesa-HerreraF, MarinR, Sanchez-GarciaF, Rodriguez-PerezA, GramuntN (2019) In-Out-Test: A new paradigm for sorting the wheat from the chaff in prodromal Alzheimer’s disease. J Alzheimers Dis67, 265–277.
