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Target Concepts:
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Query: UNIPROT:P05109 (
S100A8
)
1,212
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Calcium-binding S100 proteins are thought to play a central role in calcium-mediated signal transduction pathways. They consist of two helix-loop-helix, calcium-binding EF-hand domains. A characteristic feature is their tendency to form homo- and/or heterodimeric complexes. This report presents for the first time a functional "in vivo" approach to the analysis of S100 protein dimerization. Using the two-hybrid system we analyzed the dimerization of MRP8 (
S100A8
) and MRP14 (S100A9), two S100 proteins expressed in myeloid cells. It is reported that the MRP8-MRP14 heteromer is the clearly preferred complex in both man and mouse. The ability to homodimerize, however, appears to be restricted to the murine MRPs. Interaction analysis of chimeric murine/human MRP14 proteins indicates, that the C-terminal
EF-hand domain
plays a prominent role in MRP8-MRP14 interaction and determines the specificity of dimerization. Site-directed mutagenesis of four evolutionary conserved hydrophobic amino acids, which have been recently supposed to be essential for S100 protein dimerization, suggests that at least one of these, namely the most N-terminal located residue, is not critical for dimerization.
...
PMID:Analysis of the MRP8-MRP14 protein-protein interaction by the two-hybrid system suggests a prominent role of the C-terminal domain of S100 proteins in dimer formation. 986 28
The EF hand, a helix-loop-helix structure, is one of the most common motifs found in animal genomes, and EF-hand Ca(2+)-binding proteins (EFCaBPs) are widely distributed throughout the cell. However, researchers remain confounded by a lack of understanding of how peptide sequences code for specific functions and by uncertainty about the molecular mechanisms that enable EFCaBPs to distinguish among many diverse cellular targets. Such knowledge could define the roles of EFCaBPs in health and disease and ultimately enable control or even design of Ca(2+)-dependent functions in medicine and biotechnology. In this Account, we describe our structural and biochemical research designed to understand the sequence-to-function relationship in EFCaBPs. The first structural goal was to define conformational changes induced by binding Ca(2+), and our group and others established that solution NMR spectroscopy is well suited for this task. We pinpointed residues critical to the differences in Ca(2+) response of calbindin D(9k) and calmodulin (CaM), homologous EFCaBPs from different functional classes, by using direct structure determination with site-directed mutagenesis and protein engineering. Structure combined with biochemistry provided the foundation for identifying the fundamental mechanism of cooperativity in the binding of Ca(2+) ions: this cooperativity provides EFCaBPs with the ability to detect the relatively small changes in concentration that constitute Ca(2+) signals. Using calbindin D(9k) as a model system, studies of the structure and fast time scale dynamics of each of the four ion binding states in a typical
EF-hand domain
provided direct evidence that site-site communication lowers the free energy cost of reorganization for binding the second ion. Our work has also extended models of how EFCaBPs interact with their cellular targets. We determined the unique dimeric architecture of S100 proteins, a specialized subfamily of EFCaBPs found exclusively in vertebrates. We described the implications for how these proteins transduce signals and went on to characterize interactions with peptide fragments of important cellular targets. Studies of the CaM homolog centrin revealed novel characteristics of its binding of Ca(2+) and its interaction with its cellular target Kar1. These results provided clear examples of how subtle differences in sequence fine-tune EFCaBPs to interact with their specific targets. The structural approach stands at a critical crossroad, shifting in emphasis from descriptive structural biochemistry to integrated biology and medicine. We present our dual-molecular-switch model for Ca(2+) regulation of gating functions of voltage-gated sodium channels in which both CaM and an intrinsic
EF-hand domain
serve as coupled Ca(2+) sensors. A second example involves novel EFCaBP extracellular function, that is, the role of
S100A8
/S100A9 heterodimer in the innate immune response to bacterial pathogens. A mechanism for the antimicrobial activity of
S100A8
/S100A9 was discovered. We describe interactions of
S100A8
/S100A9 and S100B with the cell surface receptor for advanced glycation end products. Biochemical and structural studies are now uncovering the mechanisms by which EFCaBPs work and are helping to define their biological activities, while simultaneously expanding knowledge of the roles of these proteins in normal cellular physiology and the pathology of disease.
...
PMID:Relating form and function of EF-hand calcium binding proteins. 2131 91
