Ensemble refinement shows conformational flexibility in crystal structures of human complement factor D

Federico Forneris,B Tom Burnley,Piet Gros

doi:10.1107/s1399004713032549

Federico Forneris, B Tom Burnley + Show 1 more

Open Access

https://doi.org/10.1107/s1399004713032549

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Abstract

Human factor D (FD) is a self-inhibited thrombin-like serine proteinase that is critical for amplification of the complement immune response. FD is activated by its substrate through interactions outside the active site. The substrate-binding, or `exosite', region displays a well defined and rigid conformation in FD. In contrast, remarkable flexibility is observed in thrombin and related proteinases, in which Na(+) and ligand binding is implied in allosteric regulation of enzymatic activity through protein dynamics. Here, ensemble refinement (ER) of FD and thrombin crystal structures is used to evaluate structure and dynamics simultaneously. A comparison with previously published NMR data for thrombin supports the ER analysis. The R202A FD variant has enhanced activity towards artificial peptides and simultaneously displays active and inactive conformations of the active site. ER revealed pronounced disorder in the exosite loops for this FD variant, reminiscent of thrombin in the absence of the stabilizing Na(+) ion. These data indicate that FD exhibits conformational dynamics like thrombin, but unlike in thrombin a mechanism has evolved in FD that locks the unbound native state into an ordered inactive conformation via the self-inhibitory loop. Thus, ensemble refinement of X-ray crystal structures may represent an approach alternative to spectroscopy to explore protein dynamics in atomic detail.

Highlights

Mammalian complement immune defence and blood coagulation depend on cascades of proteolytic reactions (Neurath & Walsh, 1976; Schenone et al, 2004; Huntington, 2012; Ehrnthaller et al, 2011)
We considered wild-type factor D (FD), the R202A mutant and an additional variant of FD bearing a surface mutation distant from both the exosite and the catalytic site [R106A (R121A)], which was used as a control
The previously reported crystal structure of FD R202A determined at 2.8 Aresolution (Forneris et al, 2010) showed the catalytic site in an active configuration with residual density indicating the presence of disorder, which could not be modelled

Summary

Introduction

Mammalian complement immune defence and blood coagulation depend on cascades of proteolytic reactions (Neurath & Walsh, 1976; Schenone et al, 2004; Huntington, 2012; Ehrnthaller et al, 2011). In these proteolytic cascades, regulatory mechanisms prevent unwanted proteolysis and transform the potentially broad and uncontrolled proteolysis into a finely regulated process (Krem & Di Cera, 2002). This step is critical for rapid and localized amplification of the complement response

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