Co-evolving motions at protein− protein interfaces of two-component signaling systems identified by covariance analysis
Biochemistry, 2008•ACS Publications
Short-lived protein interactions determine signal transduction specificity among genetically
amplified, structurally identical two-component signaling systems. Interacting protein pairs
evolve recognition precision by varying residues at specific positions in the interaction
surface consistent with constraints of charge, size, and chemical properties. Such positions
can be detected by covariance analyses of two-component protein databases. Here,
covariance is shown to identify a cluster of co-evolving dynamic residues in two-component …
amplified, structurally identical two-component signaling systems. Interacting protein pairs
evolve recognition precision by varying residues at specific positions in the interaction
surface consistent with constraints of charge, size, and chemical properties. Such positions
can be detected by covariance analyses of two-component protein databases. Here,
covariance is shown to identify a cluster of co-evolving dynamic residues in two-component …
Short-lived protein interactions determine signal transduction specificity among genetically amplified, structurally identical two-component signaling systems. Interacting protein pairs evolve recognition precision by varying residues at specific positions in the interaction surface consistent with constraints of charge, size, and chemical properties. Such positions can be detected by covariance analyses of two-component protein databases. Here, covariance is shown to identify a cluster of co-evolving dynamic residues in two-component proteins. NMR dynamics and structural studies of both wild-type and mutant proteins in this cluster suggest that motions serve to precisely arrange the site of phosphoryl transfer within the complex.
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