6g0x

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(Difference between revisions)

Current revision

TAILSPIKE PROTEIN OF E. COLI BACTERIOPHAGE HK620 IN COMPLEX WITH PENTASACCHARIDE

Structural highlights

6g0x is a 1 chain structure with sequence from Bphk6. Full crystallographic information is available from OCA. For a guided tour on the structure components use FirstGlance.
Ligands:	, , , , , , ,
Related:	2vji, 2vjj, 2x6w, 2x6x, 2x6y, 2x85
Resources:	FirstGlance, OCA, PDBe, RCSB, PDBsum, ProSAT

Publication Abstract from PubMed

The principles of protein-glycan binding are still not well understood on a molecular level. Attempts to link affinity and specificity of glycan recognition to structure suffer from the general lack of model systems for experimental studies and the difficulty to describe the influence of solvent. We have experimentally and computationally addressed energetic contributions of solvent in protein-glycan complex formation in the tailspike protein (TSP) of E. coli bacteriophage HK620. HK620TSP is a 230 kDa native trimer of right-handed, parallel beta-helices that provide extended, rigid binding sites for bacterial cell surface O-antigen polysaccharides. A set of high-affinity mutants bound hexa- or pentasaccharide O-antigen fragments with very similar affinities even though hexasaccharides introduce an additional glucose branch into an occluded protein surface cavity. Remarkably different thermodynamic binding signatures were found for different mutants; however, crystal structure analyses indicated that no major oligosaccharide or protein topology changes had occurred upon complex formation. This pointed to a solvent effect. Molecular dynamics simulations using a mobility-based approach revealed an extended network of solvent positions distributed over the entire oligosaccharide binding site. However, free energy calculations showed that a small water network inside the glucose-binding cavity had the most notable influence on the thermodynamic signature. The energy needed to displace water from the glucose binding pocket depended on the amino acid at the entrance, in agreement with the different amounts of enthalpy-entropy compensation found for introducing glucose into the pocket in the different mutants. Studies with small molecule drugs have shown before that a few active water molecules can control protein complex formation. HK620TSP oligosaccharide binding shows that similar fundamental principles also apply for glycans, where a small number of water molecules can dominate the thermodynamic signature in an extended binding site.

Solvent Networks Tune Thermodynamics of Oligosaccharide Complex Formation in an Extended Protein Binding Site.,Kunstmann S, Gohlke U, Broeker NK, Roske Y, Heinemann U, Santer M, Barbirz S J Am Chem Soc. 2018 Aug 9. doi: 10.1021/jacs.8b03719. PMID:30044908^[1]

From MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine.

References

↑ Kunstmann S, Gohlke U, Broeker NK, Roske Y, Heinemann U, Santer M, Barbirz S. Solvent Networks Tune Thermodynamics of Oligosaccharide Complex Formation in an Extended Protein Binding Site. J Am Chem Soc. 2018 Aug 9. doi: 10.1021/jacs.8b03719. PMID:30044908 doi:http://dx.doi.org/10.1021/jacs.8b03719

1 Structural highlights
2 Publication Abstract from PubMed
3 References

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OCA

Retrieved from "http://52.214.119.220/wiki/index.php/6g0x"

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 == Publication Abstract from PubMed ==
-Bacteriophage HK620 recognizes and cleaves the Oantigen polysaccharide of E. coli serogroup O18A1 with its tailspike protein (TSP). HK620TSP binds hexasaccharide fragments with low affinity, but single amino acid exchanges generated a set of high-affinity mutants with submicromolar dissociation constants. Isothermal titration calorimetry showed that only small amounts of heat were released upon complex formation via a large number of direct and solvent mediated hydrogen bonds between carbohydrate and protein. At room temperature association was both enthalpy- and entropy-driven emphasizing major solvent rearrangements upon complex formation. Crystal structure analysis showed identical protein and sugar conformers in the TSP complexes regardless of their hexasaccharide affinity. Only in one case a TSP mutant bound a different hexasaccharide conformer. The extended sugar binding site could be dissected in two regions: Firstly, a hydrophobic pocket at the reducing end with minor affinity contributions. Access to this site could be blocked by a single aspartate to asparagine exchange without major loss in hexasaccharide affinity. Secondly, a region where specific exchange of glutamate for glutamine created a site for an additional water molecule. Side chain rearrangements upon sugar binding led to desolvation and additional hydrogen bonding which define this region of the binding site as the high affinity scaffold.
+The principles of protein-glycan binding are still not well understood on a molecular level. Attempts to link affinity and specificity of glycan recognition to structure suffer from the general lack of model systems for experimental studies and the difficulty to describe the influence of solvent. We have experimentally and computationally addressed energetic contributions of solvent in protein-glycan complex formation in the tailspike protein (TSP) of E. coli bacteriophage HK620. HK620TSP is a 230 kDa native trimer of right-handed, parallel beta-helices that provide extended, rigid binding sites for bacterial cell surface O-antigen polysaccharides. A set of high-affinity mutants bound hexa- or pentasaccharide O-antigen fragments with very similar affinities even though hexasaccharides introduce an additional glucose branch into an occluded protein surface cavity. Remarkably different thermodynamic binding signatures were found for different mutants; however, crystal structure analyses indicated that no major oligosaccharide or protein topology changes had occurred upon complex formation. This pointed to a solvent effect. Molecular dynamics simulations using a mobility-based approach revealed an extended network of solvent positions distributed over the entire oligosaccharide binding site. However, free energy calculations showed that a small water network inside the glucose-binding cavity had the most notable influence on the thermodynamic signature. The energy needed to displace water from the glucose binding pocket depended on the amino acid at the entrance, in agreement with the different amounts of enthalpy-entropy compensation found for introducing glucose into the pocket in the different mutants. Studies with small molecule drugs have shown before that a few active water molecules can control protein complex formation. HK620TSP oligosaccharide binding shows that similar fundamental principles also apply for glycans, where a small number of water molecules can dominate the thermodynamic signature in an extended binding site.
-Single amino acid exchange in bacteriophage HK620 tailspike protein results in thousand-fold increase of its oligosaccharide affinity.,Broeker NK, Gohlke U, Muller JJ, Uetrecht C, Heinemann U, Seckler R, Barbirz S Glycobiology. 2012 Aug 24. PMID:22923442<ref>PMID:22923442</ref>
+Solvent Networks Tune Thermodynamics of Oligosaccharide Complex Formation in an Extended Protein Binding Site.,Kunstmann S, Gohlke U, Broeker NK, Roske Y, Heinemann U, Santer M, Barbirz S J Am Chem Soc. 2018 Aug 9. doi: 10.1021/jacs.8b03719. PMID:30044908<ref>PMID:30044908</ref>
 From MEDLINE&reg;/PubMed&reg;, a database of the U.S. National Library of Medicine.<br>

6g0x

From Proteopedia

Current revision

TAILSPIKE PROTEIN OF E. COLI BACTERIOPHAGE HK620 IN COMPLEX WITH PENTASACCHARIDE

Structural highlights

Publication Abstract from PubMed

References

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