Abstract
Four crystal structures of human YKL-39 were solved in the absence and presence of chitooligosaccharides. The structure of YKL-39 comprises a major (β/α)8 triose-phosphate isomerase barrel domain and a small α + β insertion domain. Structural analysis demonstrates that YKL-39 interacts with chitooligosaccharides through hydrogen bonds and hydrophobic interactions. The binding of chitin fragments induces local conformational changes that facilitate tight binding. Compared with other GH-18 members, YKL-39 has the least extended chitin-binding cleft, containing five subsites for sugars, namely (-3)(-2)(-1)(+1)(+2), with Trp-360 playing a prominent role in the sugar-protein interactions at the center of the chitin-binding cleft. Evaluation of binding affinities obtained from isothermal titration calorimetry and intrinsic fluorescence spectroscopy suggests that YKL-39 binds to chitooligosaccharides with Kd values in the micromolar concentration range and that the binding energies increase with the chain length. There were no significant differences between the Kd values of chitopentaose and chitohexaose, supporting the structural evidence for the five binding subsite topology. Thermodynamic analysis indicates that binding of chitooligosaccharide to YKL-39 is mainly driven by enthalpy.
Highlights
Human YKL-39 is currently recognized as a biomarker for osteoarthritis
The results suggest that Tyr-243 at subsite ϩ3 plays a minor role in proteinsugar interactions and had no great influence on the overall binding properties of YKL-39
This study provides structural and thermodynamic insights into the binding of chitooligosaccharides to human YKL-39, a specific biomarker for osteoarthritis
Summary
Results: Crystal structures of YKL-39 reveal that chitooligosaccharide induces local conformational changes to stabilize sugar1⁄7protein complexes and that the protein contains five binding subsites for sugars. Conclusion: YKL-39 binds to chitooligosaccharide through enthalpic reactions. Significance: Our findings suggest how YKL-39 interacts with GlcNAc moieties of the natural ligands, which may possibly activate local tissue inflammation. Four crystal structures of human YKL-39 were solved in the absence and presence of chitooligosaccharides. Structural analysis demonstrates that YKL-39 interacts with chitooligosaccharides through hydrogen bonds and hydrophobic interactions. Compared with other GH-18 members, YKL-39 has the least extended chitin-binding cleft, containing five subsites for sugars, namely (؊3)(؊2)(؊1)(؉1)(؉2), with Trp360 playing a prominent role in the sugar-protein interactions at the center of the chitin-binding cleft. Thermodynamic analysis indicates that binding of chitooligosaccharide to YKL-39 is mainly driven by enthalpy
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