Mark A. B. Kreutzberger, Le Tracy Yu, Thi H. Bui, Maria C. Hancu, Michael D. Purdy, Tomasz Osinski, Peter M. Kasson, Edward H. Egelman* and Jeffrey D. Hartgerink*,
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引用次数: 0
Abstract
Collagens are ubiquitous in biology: functioning as the backbone of the extracellular matrix, forming the primary structural components of key immune system complexes, and fulfilling numerous other structural roles in a variety of systems. Despite this, there is limited understanding of how triple helices, the basic collagen structural units, pack into collagenous assemblies. Here we use a peptide self-assembly system to design collagenous assemblies based on the C1q collagen-like region. Using cryo-EM we solved a structure of one assembly to 3.5 Å resolution and built an atomic model. From this, we identify a triple helix conformation with no superhelical twist, starkly in contrast to the canonical right-handed triple helix. This nontwisting region allows for unique hydroxyproline stacking between adjacent triple helices and also results in the formation of an exposed cavity with rings of hydrophobic amino acids packed symmetrically. We find no precedent for such an arrangement of collagen triple helices and designed assemblies with substituted amino acids in various locations to probe key stabilizing amino acid interactions in the complex. The stability of these altered complexes behaves as predicted by our atomic model. Our findings, combined with the extremely limited experimental structural data on triple helix packing in the literature, suggest that collagen and collagen-like assemblies may adopt a far more varied conformational landscape than previously appreciated. We hypothesize that this is particularly likely in packed assemblies of triple helices, adjacent to the termini of these helices and at discontinuities in the required Xaa-Yaa-Gly repeating primary sequence, a discontinuity found in the majority of this class of proteins and in many collagen-associated diseases.
The atomic structure of the N-terminal domain of C1q was solved using cryo-EM. This revealed collagen triple helices lacking the canonical superhelical twist, a folding motif not previously observed.
期刊介绍:
ACS Central Science publishes significant primary reports on research in chemistry and allied fields where chemical approaches are pivotal. As the first fully open-access journal by the American Chemical Society, it covers compelling and important contributions to the broad chemistry and scientific community. "Central science," a term popularized nearly 40 years ago, emphasizes chemistry's central role in connecting physical and life sciences, and fundamental sciences with applied disciplines like medicine and engineering. The journal focuses on exceptional quality articles, addressing advances in fundamental chemistry and interdisciplinary research.
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