Abstract
Selenium is an important nutrient. The lack of selenium will suppress expression of various enzymes that will lead to cell abnormality and diseases. However, high concentrations of free selenium are toxic to the cell because it adversely affects numerous cell metabolic pathways. In Methanococcus vannielii, selenium transport in the cell is established by the selenium-binding protein, SeBP. SeBP sequesters selenium during transport, thus regulating the level of free selenium in the cell, and delivers it specifically to the selenophosphate synthase enzyme. In solution, SeBP is an oligomer of 8.8-kDa subunits. It is a symmetric pentamer. The solution structure of SeBP was determined by NMR spectroscopy. Each subunit of SeBP is composed of an alpha-helix on top of a 4-stranded twisted beta-sheet. The stability of the five subunits stems mainly from hydrophobic interactions and supplemented by hydrogen bond interactions. The loop containing Cys(59) has been shown to be important for selenium binding, is flexible, and adopts multiple conformations. However, the cysteine accessibility is restricted in the structure, reducing the possibility of the binding of free selenium readily. Therefore, a different selenium precursor or other factors might be needed to facilitate opening of this loop to expose Cys(59) for selenium binding.
Highlights
Studies examining selenium metabolism focused on the toxic potential of this unique element
The insertion of the selenocysteine amino acid in a specific location in a protein is directed by the in-frame UGA codon and requires the products of four genes selA, selB, selC, and selD in E. coli [7,8,9]
This protein was purified from the organism as a 42-kDa protein and referred to as the selenium-binding protein (SeBP)3 [12, 13]
Summary
SeBP, selenium-binding protein; DSC, differential scanning calorimetry; DTT, dithiothreitol; r.m.s.d., root mean-squared deviation; PDB, Protein Data Bank. A total of 0.25 equivalents of selenium per SeBP subunit was observed [14]. This stoichiometry suggests a 1:4 coordination ratio of the selenium by the cysteines. Despite all of these biochemical data, it is still not clear how SeBP can bind selenium with high selectivity and transport it to the proper biosynthetic pathways. Our study attempts to address, at the atomic level, the high stability of the SeBP oligomer, its mechanism for selenium binding, the accessibility of the cysteine residue, and possible transport of the selenium to the proper enzyme. Solving the SeBP structure is the first step in obtaining a full picture of how this potentially toxic element can be safely managed as an important nutrient for a healthy organism
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