Hypothyroidism induced by loss of the manganese efflux transporter SLC30A10 may be explained by reduced thyroxine production

SLC30A10 and SLC39A14 are manganese efflux and influx transporters, respectively. Loss-of-function mutations in genes encoding either transporter induce hereditary manganese toxicity. Patients have elevated manganese in the blood and brain and develop neurotoxicity. Liver manganese is increased in patients lacking SLC30A10 but not SLC39A14. These organ-specific changes in manganese were recently recapitulated in knockout mice. Surprisingly, Slc30a10 knockouts also had elevated thyroid manganese and developed hypothyroidism. To determine the mechanisms of manganese-induced hypothyroidism and understand how SLC30A10 and SLC39A14 cooperatively mediate manganese detoxification, here we produced Slc39a14 single and Slc30a10/Slc39a14 double knockout mice and compared their phenotypes with that of Slc30a10 single knockouts. Compared with wild-type controls, Slc39a14 single and Slc30a10/Slc39a14 double knockouts had higher manganese levels in the blood and brain but not in the liver. In contrast, Slc30a10 single knockouts had elevated manganese levels in the liver as well as in the blood and brain. Furthermore, SLC30A10 and SLC39A14 localized to the canalicular and basolateral domains of polarized hepatic cells, respectively. Thus, transport activities of both SLC39A14 and SLC30A10 are required for hepatic manganese excretion. Compared with Slc30a10 single knockouts, Slc39a14 single and Slc30a10/Slc39a14 double knockouts had lower thyroid manganese levels and normal thyroid function. Moreover, intrathyroid thyroxine levels of Slc30a10 single knockouts were lower than those of controls. Thus, the hypothyroidism phenotype of Slc30a10 single knockouts is induced by elevated thyroid manganese, which blocks thyroxine production. These findings provide new insights into the mechanisms of manganese detoxification and manganese-induced thyroid dysfunction.

[1]  S. Mukhopadhyay Familial manganese-induced neurotoxicity due to mutations in SLC30A10 or SLC39A14. , 2017, Neurotoxicology.

[2]  Yingying Yu,et al.  Manganese transporter Slc39a14 deficiency revealed its key role in maintaining manganese homeostasis in mice , 2017, Cell Discovery.

[3]  Jiayu Wei,et al.  Zebrafish slc30a10 deficiency revealed a novel compensatory mechanism of Atp2c1 in maintaining manganese homeostasis , 2017, PLoS genetics.

[4]  M. Febo,et al.  Metal Transporter Zip14 (Slc39a14) Deletion in Mice Increases Manganese Deposition and Produces Neurotoxic Signatures and Diminished Motor Activity , 2017, The Journal of Neuroscience.

[5]  Tao Wang,et al.  Hepatic metal ion transporter ZIP8 regulates manganese homeostasis and manganese-dependent enzyme activity , 2017, The Journal of clinical investigation.

[6]  M. Aschner,et al.  Deficiency in the manganese efflux transporter SLC30A10 induces severe hypothyroidism in mice , 2017, The Journal of Biological Chemistry.

[7]  M. Strawderman,et al.  Early Postnatal Manganese Exposure Causes Lasting Impairment of Selective and Focused Attention and Arousal Regulation in Adult Rats , 2016, Environmental health perspectives.

[8]  M. Aschner,et al.  Structural Elements in the Transmembrane and Cytoplasmic Domains of the Metal Transporter SLC30A10 Are Required for Its Manganese Efflux Activity* , 2016, The Journal of Biological Chemistry.

[9]  Stephen W. Wilson,et al.  Mutations in SLC39A14 disrupt manganese homeostasis and cause childhood-onset parkinsonism–dystonia , 2016, Nature Communications.

[10]  H. Narita,et al.  Direct Comparison of Manganese Detoxification/Efflux Proteins and Molecular Characterization of ZnT10 Protein as a Manganese Transporter* , 2016, The Journal of Biological Chemistry.

[11]  A. Luini,et al.  Identification of p38 MAPK and JNK as new targets for correction of Wilson disease‐causing ATP7B mutants , 2016, Hepatology.

[12]  E. Puffenberger,et al.  Autosomal-Recessive Intellectual Disability with Cerebellar Atrophy Syndrome Caused by Mutation of the Manganese and Zinc Transporter Gene SLC39A8. , 2015, American journal of human genetics.

[13]  Y. Wada,et al.  SLC39A8 Deficiency: A Disorder of Manganese Transport and Glycosylation. , 2015, American journal of human genetics.

[14]  Andrey S Selyunin,et al.  A Conserved Structural Motif Mediates Retrograde Trafficking of Shiga Toxin Types 1 and 2 , 2015, Traffic.

[15]  Benjamin T. Porebski,et al.  Modelling of Thyroid Peroxidase Reveals Insights into Its Enzyme Function and Autoantigenicity , 2015, PloS one.

[16]  T. Kambe,et al.  The Physiological, Biochemical, and Molecular Roles of Zinc Transporters in Zinc Homeostasis and Metabolism. , 2015, Physiological reviews.

[17]  K. Hayes,et al.  Cation Diffusion Facilitator family: Structure and function , 2015, FEBS letters.

[18]  M. Aschner,et al.  SLC30A10: A novel manganese transporter , 2015, Worm.

[19]  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.

[20]  S. Sauvé,et al.  Neurobehavioral Function in School-Age Children Exposed to Manganese in Drinking Water , 2014, Environmental health perspectives.

[21]  Andrea Ballabio,et al.  Wilson Disease Protein ATP7B Utilizes Lysosomal Exocytosis to Maintain Copper Homeostasis , 2014, Developmental cell.

[22]  Philip A. Huebner,et al.  Pathology of inherited manganese transporter deficiency , 2014, Annals of neurology.

[23]  Bung-Nyun Kim,et al.  Relationship between blood manganese levels and children's attention, cognition, behavior, and academic performance--a nationwide cross-sectional study. , 2013, Environmental research.

[24]  A. Linstedt,et al.  Shiga toxin–binding site for host cell receptor GPP130 reveals unexpected divergence in toxin-trafficking mechanisms , 2013, Molecular biology of the cell.

[25]  Wei Zhang,et al.  ZIP14 and DMT1 in the liver, pancreas, and heart are differentially regulated by iron deficiency and overload: implications for tissue iron uptake in iron-related disorders , 2013, Haematologica.

[26]  Sean C Nisam,et al.  Early life versus lifelong oral manganese exposure differently impairs skilled forelimb performance in adult rats. , 2013, Neurotoxicology and teratology.

[27]  R. Butterworth Parkinsonism in cirrhosis: pathogenesis and current therapeutic options , 2013, Metabolic Brain Disease.

[28]  Liping Huang,et al.  The SLC30 family of zinc transporters - a review of current understanding of their biological and pathophysiological roles. , 2013, Molecular aspects of medicine.

[29]  D. Eide,et al.  The SLC39 family of zinc transporters. , 2013, Molecular aspects of medicine.

[30]  E. Bontempi,et al.  Tremor, olfactory and motor changes in Italian adolescents exposed to historical ferro-manganese emission. , 2012, Neurotoxicology.

[31]  D. Ford,et al.  Efflux function, tissue-specific expression and intracellular trafficking of the Zn transporter ZnT10 indicate roles in adult Zn homeostasis. , 2012, Metallomics : integrated biometal science.

[32]  R. Wevers,et al.  Syndrome of hepatic cirrhosis, dystonia, polycythemia, and hypermanganesemia caused by mutations in SLC30A10, a manganese transporter in man. , 2012, American journal of human genetics.

[33]  B. Oostra,et al.  Mutations in SLC30A10 cause parkinsonism and dystonia with hypermanganesemia, polycythemia, and chronic liver disease. , 2012, American journal of human genetics.

[34]  M. Knutson,et al.  Physiologic implications of metal-ion transport by ZIP14 and ZIP8 , 2012, BioMetals.

[35]  A. Linstedt,et al.  Manganese Blocks Intracellular Trafficking of Shiga Toxin and Protects Against Shiga Toxicosis , 2012, Science.

[36]  T. Takeo,et al.  Reduced Glutathione Enhances Fertility of Frozen/Thawed C57BL/6 Mouse Sperm after Exposure to Methyl-Beta-Cyclodextrin1 , 2011, Biology of reproduction.

[37]  R. Cousins,et al.  Zip14 is a complex broad-scope metal-ion transporter whose functional properties support roles in the cellular uptake of zinc and nontransferrin-bound iron. , 2011, American journal of physiology. Cell physiology.

[38]  F. Parvez,et al.  Environmental Health Perspectives Environmental Health Perspectives Manganese Exposure from Drinking Water and Children's Classroom Behavior in Bangladesh Manganese Exposure from Drinking Water and Children's Classroom Behavior in 10349 and P30 Es 09089, and a Training Grant (5d43tw005724) from the , 2022 .

[39]  M. Auffhammer Hidden Costs of Energy: Unpriced Consequences of Energy Production and Use , 2011, Environmental Health Perspectives.

[40]  A. Linstedt,et al.  Identification of a gain-of-function mutation in a Golgi P-type ATPase that enhances Mn2+ efflux and protects against toxicity , 2010, Proceedings of the National Academy of Sciences.

[41]  Donna Mergler,et al.  Intellectual Impairment in School-Age Children Exposed to Manganese from Drinking Water , 2010, Environmental health perspectives.

[42]  Li Li,et al.  A mouse knockout library for secreted and transmembrane proteins , 2010, Nature Biotechnology.

[43]  Joel Schwartz,et al.  Early Postnatal Blood Manganese Levels and Children's Neurodevelopment , 2010, Epidemiology.

[44]  H. Riojas-Rodríguez,et al.  Intellectual Function in Mexican Children Living in a Mining Area and Environmentally Exposed to Manganese , 2010, Environmental health perspectives.

[45]  G. Stanwood,et al.  Preweaning manganese exposure causes hyperactivity, disinhibition, and spatial learning and memory deficits associated with altered dopamine receptor and transporter levels , 2010, Synapse.

[46]  A. Linstedt,et al.  Manganese-induced Trafficking and Turnover of the cis-Golgi Glycoprotein GPP130 , 2010, Molecular biology of the cell.

[47]  J. Arnaud,et al.  Trace elements status in multinodular goiter. , 2010, Journal of trace elements in medicine and biology : organ of the Society for Minerals and Trace Elements.

[48]  M. Aschner,et al.  Manganese and its Role in Parkinson’s Disease: From Transport to Neuropathology , 2009, NeuroMolecular Medicine.

[49]  D. Nebert,et al.  Slc39a14 Gene Encodes ZIP14, A Metal/Bicarbonate Symporter: Similarities to the ZIP8 Transporter , 2008, Molecular Pharmacology.

[50]  M. Bitner-Glindzicz,et al.  Hepatic cirrhosis, dystonia, polycythaemia and hypermanganesaemia—A new metabolic disorder , 2008, Journal of Inherited Metabolic Disease.

[51]  D. Perl,et al.  The Neuropathology of Manganese-Induced Parkinsonism , 2007, Journal of neuropathology and experimental neurology.

[52]  A. Kortenkamp,et al.  Combined Exposure to Anti-Androgens Exacerbates Disruption of Sexual Differentiation in the Rat , 2007, Environmental health perspectives.

[53]  R. Zoeller,et al.  General Background on the Hypothalamic-Pituitary-Thyroid (HPT) Axis , 2007, Critical reviews in toxicology.

[54]  Maryse Bouchard,et al.  Hair Manganese and Hyperactive Behaviors: Pilot Study of School-Age Children Exposed through Tap Water , 2006, Environmental health perspectives.

[55]  R. Cousins,et al.  Zip14 (Slc39a14) mediates non-transferrin-bound iron uptake into cells , 2006, Proceedings of the National Academy of Sciences.

[56]  T. Ganz,et al.  Interleukin-6 regulates the zinc transporter Zip14 in liver and contributes to the hypozincemia of the acute-phase response. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[57]  R. Nicholson,et al.  Structure–function analysis of a novel member of the LIV‐1 subfamily of zinc transporters, ZIP14 , 2005, FEBS letters.

[58]  Zhongqi Cheng,et al.  Water Manganese Exposure and Children’s Intellectual Function in Araihazar, Bangladesh , 2004, Environmental health perspectives.

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

[60]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[61]  L. Braverman,et al.  Werner and Ingbar's the Thyroid: A Fundamental and Clinical Text , 1991 .

[62]  M. Nishida,et al.  Manganese ion as a goitrogen in the female mouse. , 1985, Endocrinologia japonica.

[63]  N. Autissier,et al.  Effects of manganese ions on thyroid function in rat , 1983, Archives of Toxicology.

[64]  A. Guyton,et al.  Textbook of Medical Physiology , 1961 .

[65]  F. Parvez,et al.  Manganese exposure from drinking water and children's academic achievement. , 2012, Neurotoxicology.

[66]  A. Misiewicz,et al.  [Effect of occupational environment containing manganese on thyroid function]. , 1993, Endokrynologia Polska.

[67]  N. Autissier,et al.  [The effect of Mn2+ on thyroid iodine metabolism in rats]. , 1977, Comptes rendus des seances de la Societe de biologie et de ses filiales.