Abstract
The encounter of a Ca2+ ion with a protein and its subsequent binding to specific binding sites is an intricate process that cannot be fully elucidated from experimental observations. We have applied Molecular Dynamics to study this process with atomistic details, using Calbindin D9k (CaB) as a model protein. The simulations show that in most of the time the Ca2+ ion spends within the Debye radius of CaB, it is being detained at the 1st and 2nd solvation shells. While being detained near the protein, the diffusion coefficient of the ion is significantly reduced. However, due to the relatively long period of detainment, the ion can scan an appreciable surface of the protein. The enhanced propagation of the ion on the surface has a functional role: significantly increasing the ability of the ion to scan the protein's surface before being dispersed to the bulk. The contribution of this mechanism to Ca2+ binding becomes significant at low ion concentrations, where the intervals between successive encounters with the protein are getting longer. The efficiency of the surface diffusion is affected by the distribution of charges on the protein's surface. Comparison of the Ca2+ binding dynamics in CaB and its E60D mutant reveals that in the wild type (WT) protein the carboxylate of E60 function as a preferred landing-site for the Ca2+ arriving from the bulk, followed by delivering it to the final binding site. Replacement of the glutamate by aspartate significantly reduced the ability to transfer Ca2+ ions from D60 to the final binding site, explaining the observed decrement in the affinity of the mutated protein to Ca2+.
Highlights
Intracellular calcium plays an essential role in the transduction of most hormonal, neuronal and muscular stimuli
In this study we focused our attention on the 2nd and 3rd aspects of the binding process, using molecular dynamics simulations
Out of the Coulomb cage the ion is unaware of the protein, having a diffusion coefficient of a free ion
Summary
Intracellular calcium plays an essential role in the transduction of most hormonal, neuronal and muscular stimuli. Cells have a multi-components calcium signaling toolkits that can be assembled to create a wide range of spatial and temporal signals. This versatility is exploited to control processes as diverse as fertilization, proliferation, development, learning and memory, contraction and secretion [1]. The signal from the cell surface, which arrives at the intracellular Ca2+ store via a second messenger or via direct electrical contact, opens Ca2+ channels and thereby releases Ca2+ into the cytoplasm. The elevated Ca2+ concentration modulates Ca2+ regulatory proteins at key control points in essential physiological pathways, until the Ca2+ is pumped out of the cytoplasm by a Ca2+ ATPase
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