ATOX1 is an abbreviation of the full name Antioxidant Protein 1. The nomenclature stems from initial characterization that showed that ATOX1 protected cells from reactive oxygen species. Since then, the primary role of ATOX1 has been established as a copper metallochaperone protein found in the cytoplasm of eukaryotes.[7] A metallochaperone is an important protein that has metal trafficking and sequestration roles. As a metal sequestration protein, ATOX1 is capable of binding free metals in vivo, in order to protect cells from generation of reactive oxygen species and mismetallation of metalloproteins. As a metal trafficking protein, ATOX1 is responsible for shuttling copper from the cytosol to ATPase transporters ATP7A and ATP7B that move copper to the trans-Golgi network or secretory vesicles.[7][8][9] In Saccharomyces cerevisiae, Atx1 delivers Cu(I) to a homologous transporter, Ccc2. The delivery of copper to ATPase transporters is vital for the subsequent insertion of copper into ceruloplasmin, a ferroxidase required for iron metabolism, within the golgi apparatus.[7]
In addition to the metallochaperone function, recent reports have characterized ATOX1 as a cyclin D1transcription factor.[8]
Structure & metal coordination
ATOX1 has a ferrodoxin-like ÎČαÎČÎČαÎČ fold and coordinates to Cu(I) via a MXCXXC binding motif located in between the first ÎČ-sheet and α-helix.[7][9] The metal binding motif is largely solvent exposed in Apo-ATOX1 and a conformational change is induced upon coordination to Cu(I).[9][10] Cu(I) is coordinated in a distorted linear geometry to sulfurs of cystine to form a bond angle of 120°.[9] The overall -1 charge of the primary coordination sphere is stabilized through the secondary coordination sphere that contains a proximal positively charged lysine.[9][10] ATOX1 also binds Hg(II), Cd(II), Ag(I), and cisplatin via this motif, but a physiological role, if any, is not yet known.[9]
Metal transfer
ATOX1 transfers Cu(I) to transporters ATP7A and ATP7B.[7][8][9] Transfer occurs via a ligand exchange mechanism, where Cu(I) transiently adopts a 3-coordinate geometry with cysteine ligands from ATOX1 and the associated transporter.[9] The ligand exchange mechanism allows for faster exchange than a diffusion mechanism and imparts specificity for both the metal and transporter.[11] Since the ligand exchange accelerates that transfer and the reaction has a shallow thermodynamic gradient, it is said to be under kinetic control rather than thermodynamic control.[9][11]
Clinical significance
Although there are presently no known diseases directly associated with ATOX1 malfunction, there is currently active research in a few areas:
There is a link between ATOX1 levels and sensitivity of cells for Pt-based drugs like cisplatin.[9]
The mechanism of ammonium tetrathiomolybdate [NH4]2MoS4 treatment of Wilson's Disease is under review. Since ATOX1 forms a stable complex tetrathiomolybdate, it is being studied as the potential therapeutic target.[12][13]
^ abcdefgBertini I, Gray HB, Steifel EI, Valentine JS (2006). Biological Inorganic Chemistry, Structure and Reactivity. University Science Books. ISBN 978-1891389436.
^ abcdBanci L (2013). Metallomics and the cell. Dordrecht: Springer. ISBN 978-94-007-5561-1.
^ abcdefghijkMaret W, Wedd A (2014). Binding, transport and storage of metal ions in biological cells. [S.l.]: Royal Soc Of Chemistry. ISBN 978-1-84973-599-5.
Wernimont AK, Huffman DL, Lamb AL, O'Halloran TV, Rosenzweig AC (2000). "Structural basis for copper transfer by the metallochaperone for the Menkes/Wilson disease proteins". Nat. Struct. Biol. 7 (9): 766â71. doi:10.1038/78999. PMID10966647. S2CID30817425.
Boultwood J, Strickson AJ, Jabs EW, Cheng JF, Fidler C, Wainscoat JS (2000). "Physical mapping of the human ATX1 homologue (HAH1) to the critical region of the 5q- syndrome within 5q32, and immediately adjacent to the SPARC gene". Hum. Genet. 106 (1): 127â9. doi:10.1007/s004390051020. PMID10982193.
Moore SD, Helmle KE, Prat LM, Cox DW (2003). "Tissue localization of the copper chaperone ATOX1 and its potential role in disease". Mamm. Genome. 13 (10): 563â8. doi:10.1007/s00335-002-2172-9. PMID12420134. S2CID19978302.
Brandenberger R, Wei H, Zhang S, Lei S, Murage J, Fisk GJ, Li Y, Xu C, Fang R, Guegler K, Rao MS, Mandalam R, Lebkowski J, Stanton LW (2005). "Transcriptome characterization elucidates signaling networks that control human ES cell growth and differentiation". Nat. Biotechnol. 22 (6): 707â16. doi:10.1038/nbt971. PMID15146197. S2CID27764390.
Anastassopoulou I, Banci L, Bertini I, Cantini F, Katsari E, Rosato A (2004). "Solution structure of the apo and copper(I)-loaded human metallochaperone HAH1". Biochemistry. 43 (41): 13046â53. doi:10.1021/bi0487591. PMID15476398.
Banci L, Bertini I, Ciofi-Baffoni S, Chasapis CT, Hadjiliadis N, Rosato A (2005). "An NMR study of the interaction between the human copper(I) chaperone and the second and fifth metal-binding domains of the Menkes protein". FEBS J. 272 (3): 865â71. doi:10.1111/j.1742-4658.2004.04526.x. PMID15670166. S2CID1130281.