Abstract
It is now widely accepted that protein function is intimately tied with the navigation of energy landscapes. In this framework, a protein sequence is not described by a distinct structure but rather by an ensemble of conformations. And it is through this ensemble that evolution is able to modify a protein’s function by altering its landscape. Hence, the evolution of protein functions involves selective pressures that adjust the sampling of the conformational states. In this work, we focus on elucidating the evolutionary pathway that shaped the function of individual proteins that make-up the mammalian c-type lysozyme subfamily. Using both experimental and computational methods, we map out specific intermolecular interactions that direct the sampling of conformational states and accordingly, also underlie shifts in the landscape that are directly connected with the formation of novel protein functions. By contrasting three representative proteins in the family we identify molecular mechanisms that are associated with the selectivity of enhanced antimicrobial properties and consequently, divergent protein function. Namely, we link the extent of localized fluctuations involving the loop separating helices A and B with shifts in the equilibrium of the ensemble of conformational states that mediate interdomain coupling and concurrently moderate substrate binding affinity. This work reveals unique insights into the molecular level mechanisms that promote the progression of interactions that connect the immune response to infection with the nutritional properties of lactation, while also providing a deeper understanding about how evolving energy landscapes may define present-day protein function.
Highlights
The origin of long-range communication in proteins has been attributed to dynamic interactions of amino acids in the protein three-dimensional (3D) structure (Su€el et al 2003; del Sol et al 2006; Hilser and Thompson 2007; Reynolds et al 2011; Nussinov 2012)
Protein backbone–solvent-coupled mode and HAMLET [Human -lactalbumin Made LEthal to Tumor cells]) and protein–oligosaccharide (lysozyme–(NAG)3 [tri-N-acetyl-D-glucosamine]) complexes of individual proteins in the family we find that ligand sensitive equilibria adjust allosteric interactions that appear to have a central role in target specificity
The Evolution of Conformational Ensembles and the Divergence in Protein Dynamics: EL and LALBA Experimental Detection of Protein Intrinsic Fluctuations in Response to Ligand-Binding When contrasting the experimentally detected intrinsic dynamics of EL and LALBA when bound with calcium as shown in figure 1a and c, it becomes apparent that there are noticeable differences in the detectable low-frequency fluctuations of the two proteins
Summary
The origin of long-range communication in proteins has been attributed to dynamic interactions of amino acids in the protein three-dimensional (3D) structure (Su€el et al 2003; del Sol et al 2006; Hilser and Thompson 2007; Reynolds et al 2011; Nussinov 2012). Recent developments in both experimental and computational modeling of allosteric regulation in protein systems have indicated that internal motions on the subnanosecond time scale are important facilitating the large-scale collective global motions in proteins (Frederick et al 2007; Motlagh et al 2014) These fast, internal protein fluctuations initiate allosteric conformational changes by altering the dynamic ensemble of protein conformational substates (Kumar et al 2000; Ishikawa et al 2008).
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