Abstract
Dps (DNA-binding protein from starved cells) are dodecameric assemblies belonging to the ferritin family that can bind DNA, carry out ferroxidation, and store iron in their shells. The ferritin-like trimeric pore harbors the channel for the entry and exit of iron. By representing the structure of Dps as a network we have identified a charge-driven interface formed by a histidine aspartate cluster at the pore interface unique to Mycobacterium smegmatis Dps protein, MsDps2. Site-directed mutagenesis was employed to generate mutants to disrupt the charged interactions. Kinetics of iron uptake/release of the wild type and mutants were compared. Crystal structures were solved at a resolution of 1.8-2.2 Å for the various mutants to compare structural alterations vis à vis the wild type protein. The substitutions at the pore interface resulted in alterations in the side chain conformations leading to an overall weakening of the interface network, especially in cases of substitutions that alter the charge at the pore interface. Contrary to earlier findings where conserved aspartate residues were found crucial for iron release, we propose here that in the case of MsDps2, it is the interplay of negative-positive potentials at the pore that enables proper functioning of the protein. In similar studies in ferritins, negative and positive patches near the iron exit pore were found to be important in iron uptake/release kinetics. The unique ionic cluster in MsDps2 makes it a suitable candidate to act as nano-delivery vehicle, as these gated pores can be manipulated to exhibit conformations allowing for slow or fast rates of iron release.
Highlights
DNA-binding protein from starved cells (Dps) are nano-compartments that can oxidize and store iron rendering protection from free radicals
By representing the structure of Dps as a network we have identified a charge-driven interface formed by a histidine aspartate cluster at the pore interface unique to Mycobacterium smegmatis Dps protein, MsDps2
The pore size of the ferritin-like trimeric interface allows for iron transport, and the pore cluster stabilizing the interface is composed of charged interactions of the His141–Asp138 pair forming a convenient cloud of opposite charges (Figs. 1B, 2A, and 6A)
Summary
DNA-binding protein from starved cells (Dps) are nano-compartments that can oxidize and store iron rendering protection from free radicals. By representing the structure of Dps as a network we have identified a charge-driven interface formed by a histidine aspartate cluster at the pore interface unique to Mycobacterium smegmatis Dps protein, MsDps. The pore enclosed by this trimeric interface is funnelshaped having a wide mouth facing the solvent side, and constricts toward the interior (Fig. 1) This pore is lined by hydrophilic residues, mainly negatively charged species like aspartate, which are thought to trap and encourage the internalization of iron. Earlier we had explored the concepts of graph theory to identify groups (clusters) of highly interacting residues, strong interfaces in terms of noncovalent global connectivity from protein structures [32,33,34] Using such an approach, here we have identified a tight histidine-aspartate cluster at the ferritin-like trimeric pore. This is not surprising, because large conformational changes are destabilizing and energetically unfavorable
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