Lipidomic and Metallomic Alteration of Caenorhabditis elegans after Acute and Chronic Manganese, Iron, and Zinc Exposure with a Link to Neurodegenerative Disorders.

Parkinson's disease (PD) progresses with the loss of dopaminergic neurons in the substantia nigra pars compacta region of the brain. The superior mechanisms and the cause of this specific localized neurodegeneration is currently unknown. However, experimental evidence indicates a link between PD progression and reactive oxygen species with imbalanced metal homeostasis. Wild-type Caenorhabditis elegans exposed to redox-active metals was used as the model organism to study cellular response to imbalanced metal homeostasis linked to neurodegenerative diseases. Using modern hyphenated techniques such as capillary electrophoresis coupled to inductively coupled plasma mass spectrometry and ultrahigh-performance liquid chromatography mass spectrometry, alterations in the lipidome and metallome were determined in vivo. In contrast to iron, most of the absorbed zinc and manganese were loosely bound. We observed changes in the phospholipid composition for acute iron and manganese exposures, as well as chronic zinc exposure. Furthermore, we focused on the mitochondrial membrane alteration due to its importance in neuronal function. However, significant changes in the inner mitochondrial membrane by determination of cardiolipin species could only be observed for acute iron exposure. These results indicate different intracellular sites of local ROS generation, depending on the redox active metal. Our study combines metallomic and lipidomic alterations as the cause and consequence to enlighten intracellular mechanisms in vivo, associated with PD progression. The mass spectrometry raw data have been deposited to the MassIVE database (https://massive.ucsd.edu) with the identifier MSV000090796 and 10.25345/C51J97C8F.

[1]  R. Dirksen,et al.  Iron Dysregulation in Mitochondrial Dysfunction and Alzheimer’s Disease , 2022, Antioxidants.

[2]  Michael A. Stravs,et al.  A Modular and Expandable Ecosystem for Metabolomics Data Annotation in R , 2022, Metabolites.

[3]  B. Michalke,et al.  Novel Extraction Method for Combined Lipid and Metal Speciation From Caenorhabditis elegans With Focus on Iron Redox Status and Lipid Profiling , 2021, Frontiers in Chemistry.

[4]  S. Bardien,et al.  Toxic Feedback Loop Involving Iron, Reactive Oxygen Species, α-Synuclein and Neuromelanin in Parkinson’s Disease and Intervention with Turmeric , 2021, Molecular Neurobiology.

[5]  B. Bobrowska-Korczak,et al.  Zinc Affects Cholesterol Oxidation Products and Fatty Acids Composition in Rats’ Serum , 2021, Nutrients.

[6]  H. Hayen,et al.  Investigation of cardiolipin oxidation products as a new endpoint for oxidative stress in C. elegans by means of online two-dimensional liquid chromatography and high-resolution mass spectrometry. , 2020, Free radical biology & medicine.

[7]  D. Tang,et al.  Oxidative Damage and Antioxidant Defense in Ferroptosis , 2020, Frontiers in Cell and Developmental Biology.

[8]  Keisha N. Hardeman,et al.  Manganese-induced mitochondrial dysfunction is not detectable at exposures below the acute cytotoxic threshold in neuronal cell types. , 2020, Toxicological sciences : an official journal of the Society of Toxicology.

[9]  Manish Chamoli,et al.  Dysregulated iron metabolism in C. elegans catp-6/ATP13A2 mutant impairs mitochondrial function , 2020, Neurobiology of Disease.

[10]  H. Hayen,et al.  Mass spectrometric investigation of cardiolipins and their oxidation products after two-dimensional heart-cut liquid chromatography. , 2020, Journal of chromatography. A.

[11]  J. Mazat,et al.  Modelling mitochondrial ROS production by the respiratory chain , 2019, Cellular and Molecular Life Sciences.

[12]  Z. Peng,et al.  Reactive Oxygen Species-Induced Lipid Peroxidation in Apoptosis, Autophagy, and Ferroptosis , 2019, Oxidative medicine and cellular longevity.

[13]  B. Michalke,et al.  Iron Redox Speciation Analysis Using Capillary Electrophoresis Coupled to Inductively Coupled Plasma Mass Spectrometry (CE-ICP-MS) , 2019, Front. Chem..

[14]  M. Aschner,et al.  SLC30A10 transporter in the digestive system regulates brain manganese under basal conditions while brain SLC30A10 protects against neurotoxicity , 2018, The Journal of Biological Chemistry.

[15]  S. Chirumbolo,et al.  Metals and Parkinson's Disease: Mechanisms and Biochemical Processes. , 2018, Current medicinal chemistry.

[16]  J. V. Van Raamsdonk,et al.  Modeling Parkinson’s Disease in C. elegans , 2018, Journal of Parkinson's disease.

[17]  L. Elia,et al.  Ferritin, cellular iron storage and regulation , 2017, IUBMB life.

[18]  Jennifer Beatriz Silva Morais,et al.  Zinc and Oxidative Stress: Current Mechanisms , 2017, Antioxidants.

[19]  D. Averill-Bates,et al.  Activation of apoptosis signalling pathways by reactive oxygen species. , 2016, Biochimica et biophysica acta.

[20]  P. Crouch,et al.  Editorial: Metals and neurodegeneration: restoring the balance , 2015, Front. Aging Neurosci..

[21]  M. Aschner,et al.  Behavioral and dopaminergic damage induced by acute iron toxicity in Caenorhabditis elegans , 2015 .

[22]  Z. Sheng,et al.  Regulation of mitochondrial transport in neurons. , 2015, Experimental cell research.

[23]  M. Aschner,et al.  Manganese-induced Neurotoxicity: From C. elegans to Humans. , 2015, Toxicology research.

[24]  M. Aschner,et al.  SLC30A10 Is a Cell Surface-Localized Manganese Efflux Transporter, and Parkinsonism-Causing Mutations Block Its Intracellular Trafficking and Efflux Activity , 2014, The Journal of Neuroscience.

[25]  M. Witting,et al.  Optimizing a ultrahigh pressure liquid chromatography-time of flight-mass spectrometry approach using a novel sub-2μm core-shell particle for in depth lipidomic profiling of Caenorhabditis elegans. , 2014, Journal of chromatography. A.

[26]  S. Vanni,et al.  Polyunsaturated phospholipids facilitate membrane deformation and fission by endocytic proteins , 2014, Science.

[27]  S. Sollott,et al.  Mitochondrial reactive oxygen species (ROS) and ROS-induced ROS release. , 2014, Physiological reviews.

[28]  J. Segura-Aguilar,et al.  Protective and toxic roles of dopamine in Parkinson's disease , 2014, Journal of neurochemistry.

[29]  G. Waeber,et al.  Physiology of Iron Metabolism , 2014, Transfusion Medicine and Hemotherapy.

[30]  E. A. Leibold,et al.  Mechanisms of iron metabolism in Caenorhabditis elegans , 2014, Front. Pharmacol..

[31]  Oliver Fiehn,et al.  LipidBlast - in-silico tandem mass spectrometry database for lipid identification , 2013, Nature Methods.

[32]  M. Aschner,et al.  Metal-induced neurodegeneration in C. elegans , 2013, Front. Aging Neurosci..

[33]  P. Oteiza,et al.  Zinc and the modulation of redox homeostasis. , 2012, Free radical biology & medicine.

[34]  Ashutosh Kumar,et al.  Involvement of NADPH oxidase and glutathione in zinc-induced dopaminergic neurodegeneration in rats: Similarity with paraquat neurotoxicity , 2012, Brain Research.

[35]  Xiaole Kong,et al.  Glutathione: a key component of the cytoplasmic labile iron pool , 2011, BioMetals.

[36]  Grace Y Sun,et al.  Effects of fatty acid unsaturation numbers on membrane fluidity and α-secretase-dependent amyloid precursor protein processing , 2011, Neurochemistry International.

[37]  M. Aschner,et al.  Extracellular Dopamine Potentiates Mn-Induced Oxidative Stress, Lifespan Reduction, and Dopaminergic Neurodegeneration in a BLI-3–Dependent Manner in Caenorhabditis elegans , 2010, PLoS genetics.

[38]  Ruth Nussinov,et al.  Zinc ions promote Alzheimer Aβ aggregation via population shift of polymorphic states , 2010, Proceedings of the National Academy of Sciences.

[39]  M. Aschner,et al.  SMF-1, SMF-2 and SMF-3 DMT1 Orthologues Regulate and Are Regulated Differentially by Manganese Levels in C. elegans , 2009, PloS one.

[40]  Rachel M. Devay,et al.  Coassembly of Mgm1 isoforms requires cardiolipin and mediates mitochondrial inner membrane fusion , 2009, The Journal of cell biology.

[41]  J. Koh,et al.  Cytosolic labile zinc accumulation in degenerating dopaminergic neurons of mouse brain after MPTP treatment , 2009, Brain Research.

[42]  V. Hristova,et al.  Identification of a Novel Zn2+-binding Domain in the Autosomal Recessive Juvenile Parkinson-related E3 Ligase Parkin* , 2009, Journal of Biological Chemistry.

[43]  Amornpan Ajjimaporn,et al.  Zinc rescues dopaminergic SK–N–SH cell lines from methamphetamine-induced toxicity , 2008, Brain Research Bulletin.

[44]  Michael P. Murphy,et al.  How mitochondria produce reactive oxygen species , 2008, The Biochemical journal.

[45]  Y. Kohgo,et al.  Body iron metabolism and pathophysiology of iron overload , 2008, International journal of hematology.

[46]  M. Breteler,et al.  Epidemiology of Parkinson's disease , 2006, The Lancet Neurology.

[47]  Michael O. Hengartner,et al.  Finding function in novel targets: C. elegans as a model organism , 2006, Nature Reviews Drug Discovery.

[48]  Amornpan Ajjimaporn,et al.  Metallothionein provides zinc-mediated protective effects against methamphetamine toxicity in SK-N-SH cells , 2005, Brain Research Bulletin.

[49]  I. Reynolds,et al.  Zinc causes loss of membrane potential and elevates reactive oxygen species in rat brain mitochondria. , 2005, Mitochondrion.

[50]  C. Olanow,et al.  Manganese‐Induced Parkinsonism and Parkinson's Disease , 2004, Annals of the New York Academy of Sciences.

[51]  E. Leibold,et al.  Cytosolic Aconitase and Ferritin Are Regulated by Iron inCaenorhabditis elegans * , 2003, The Journal of Biological Chemistry.

[52]  P. Cras,et al.  Case–control study of environmental risk factors for Parkinson's disease in Belgium , 2002, European Journal of Epidemiology.

[53]  G. Paradies,et al.  Reactive oxygen species affect mitochondrial electron transport complex I activity through oxidative cardiolipin damage. , 2002, Gene.

[54]  Sten Orrenius,et al.  Cytochrome c release from mitochondria proceeds by a two-step process , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[55]  K. Lam,et al.  A conformational change in cytochrome c of apoptotic and necrotic cells is detected by monoclonal antibody binding and mimicked by association of the native antigen with synthetic phospholipid vesicles. , 1999, Biochemistry.

[56]  G. Dryhurst,et al.  Iron- and manganese-catalyzed autoxidation of dopamine in the presence of L-cysteine: possible insights into iron- and manganese-mediated dopaminergic neurotoxicity. , 1998, Chemical research in toxicology.

[57]  Yong Y. He,et al.  The Role of Zinc in Selective Neuronal Death After Transient Global Cerebral Ischemia , 1996, Science.

[58]  M. Zeidel,et al.  The relationship between membrane fluidity and permeabilities to water, solutes, ammonia, and protons , 1995, The Journal of general physiology.

[59]  D. Choi,et al.  Zinc toxicity on cultured cortical neurons: Involvement of N-methyl-d-aspartate receptors , 1994, Neuroscience.

[60]  C. Marsden,et al.  Increased Nigral Iron Content and Alterations in Other Metal Ions Occurring in Brain in Parkinson's Disease , 1989, Journal of neurochemistry.

[61]  N. Munakata [Genetics of Caenorhabditis elegans]. , 1989, Tanpakushitsu kakusan koso. Protein, nucleic acid, enzyme.

[62]  G. Sparagna,et al.  Role of cardiolipin alterations in mitochondrial dysfunction and disease. , 2007, American journal of physiology. Cell physiology.

[63]  T. Scherstén,et al.  1H-n.m.r. evaluation of the ferricytochrome c-cardiolipin interaction. Effect of superoxide radicals. , 1990, The Biochemical journal.

[64]  J. Stauber,et al.  Manganese catalysis of dopamine oxidation. , 1989, The Science of the total environment.