NMR Solution Structure and Backbone Dynamics of the CC Chemokine Eotaxin-3<sup>,</sup>

Ye, Jiqing; Mayer, Kristen L.; Mayer, Michael R.; Stone, Martin J.

doi:10.1021/bi010252s

Cited by 35 publications

(35 citation statements)

References 61 publications

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“…These derived order parameters are sensitive to local motions on the ps-ns timescale. Overall, both proteins exhibit dynamic behavior typical of other chemokines (1,58,59,61), with an aperiodic flexible N-terminal segment encompassing the first 15 or so residues that are most important for chemokine receptor binding, as has been found for other CXC chemokines (12,42). This is followed by ordered regular secondary structure elements, with the loop between the first two ␤-strands showing some flexibility, and a flexible C-terminal segment past the ␣-helix.…”

Section: Discussionmentioning

confidence: 68%

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Nguyen

Kwakman

Chan

et al. 2011

Antimicrob Agents Chemother

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The platelet chemokines neutrophil-activating peptide-2 (NAP-2) and thrombocidin-1 (TC-1) differ by only two amino acids at their carboxy-terminal ends. Nevertheless, they display a significant difference in their direct antimicrobial activities, with the longer NAP-2 being inactive and TC-1 being active. In an attempt to rationalize this difference in activity, we studied the structure and the dynamics of both proteins by nuclear magnetic resonance (NMR) spectroscopy. Using 15 N isotope-labeled protein, we confirmed that the two monomeric proteins essentially have the same overall structure in aqueous solution. However, NMR relaxation measurements provided evidence that the negatively charged carboxy-terminal residues of NAP-2 experience a restricted motion, whereas the carboxy-terminal end of TC-1 moves in an unrestricted manner. The same behavior was also seen in molecular dynamic simulations of both proteins. Detailed analysis of the protein motions through model-free analysis, as well as a determination of their overall correlation times, provided evidence for the existence of a monomer-dimer equilibrium in solution, which seemed to be more prevalent for TC-1. This finding was supported by diffusion NMR experiments. Dimerization generates a larger cationic surface area that would increase the antimicrobial activities of these chemokines. Moreover, these data also show that the negatively charged carboxy-terminal end of NAP-2 (which is absent in TC-1) folds back over part of the positively charged helical region of the protein and, in doing so, interferes with the direct antimicrobial activity.

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Section: Discussionmentioning

confidence: 68%

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Nguyen

Kwakman

Chan

et al. 2011

Antimicrob Agents Chemother

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“…We found that receptor-binding regions of all three chemokines are highly flexible, suggesting that they also undergo induced fit to the receptor during their binding events. [167][168][169] Increases in Flexibility Induced by Ligand Binding. Despite the conventional view of binding in terms of inducedfit interactions governed by enthalpy-entropy compensation, several dynamics studies have indicated regions of proteins whose flexibility actually increases upon ligand binding.…”

Section: Effects Of Ligand Bindingmentioning

confidence: 99%

Fast Time Scale Dynamics of Protein Backbones: NMR Relaxation Methods, Applications, and Functional Consequences

2006

Self Cite

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“…Structural studies have been carried out on a number of chemokines [33][34][35][36][37][38][39][40][41][42][43][44][45][46][47], indicating a significant level of homology at the tertiary structure level across the whole chemokine family. The prominent feature in a typical chemokine structure (Fig.…”

Section: Chemokine Tertiary Structurementioning

confidence: 99%

Engineering Chemokines to Develop Optimized HIV Inhibitors

Hartley¹,

Offord²

2005

CPPS

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Since the discovery that to enter target cells HIV uses receptors for the class of proteins known as chemokines, attempts have been made to generate anti-HIV molecules based on the chemokine ligands. A significant level of knowledge of the structure-activity relationships of chemokines has been amassed since the beginning of the 1990s. This, together with work that has elucidated the mechanisms underlying the inhibitory activity of chemokines, has guided not only the rational design of anti-HIV chemokine analogues, but also strategies by which chemokine variants with potent anti-HIV activity can be isolated from large libraries by phage display. This review summarizes the current knowledge about the structure-activity relationships and receptor biology of chemokines that is relevant to the development of analogues with anti-HIV activity. We present specific examples of engineered chemokine analogues with potent anti-HIV activity and describe the challenges that will need to be faced if these molecules are to be further developed for clinical applications. Finally, we discuss how these challenges might be met through further engineering of the molecules.

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NMR Solution Structure and Backbone Dynamics of the CC Chemokine Eotaxin-3^,

Cited by 35 publications

References 61 publications

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Fast Time Scale Dynamics of Protein Backbones: NMR Relaxation Methods, Applications, and Functional Consequences

Engineering Chemokines to Develop Optimized HIV Inhibitors

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NMR Solution Structure and Backbone Dynamics of the CC Chemokine Eotaxin-3,

Cited by 35 publications

References 61 publications

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Exploring Platelet Chemokine Antimicrobial Activity: Nuclear Magnetic Resonance Backbone Dynamics of NAP-2 and TC-1

Fast Time Scale Dynamics of Protein Backbones: NMR Relaxation Methods, Applications, and Functional Consequences

Engineering Chemokines to Develop Optimized HIV Inhibitors

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Product

Resources

About

NMR Solution Structure and Backbone Dynamics of the CC Chemokine Eotaxin-3^,