Tick saliva protein Evasin-3 modulates chemotaxis by disrupting CXCL8 interactions with glycosaminoglycans and CXCR2

Denisov, Stepan S.; Ippel, Hans; Heinzmann, Alexandra C.A.; Koenen, Rory R.; Ortega‐Gómez, Almudena; Soehnlein, Oliver; Hackeng, Tilman M.; Dijkgraaf, Ingrid

doi:10.1074/jbc.ra119.008902

Cited by 17 publications

(31 citation statements)

References 57 publications

(66 reference statements)

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“…In particular, the 'S5' region (between Cys-5 and Cys-6) is highly positively charged in Class B(I) and neutral or negative in Class B(II), potentially contributing to the more restricted chemokine binding profiles of Class B(I) Evasins. Consistent with this proposal, the recent description of EVA-3 (truncated at both N and C termini) docked to CXCL8 [48] showed that the S5 region of EVA-3 interacts with the b1-strand of CXCL8, which explains why binding of EVA-3 disrupts dimerization (and the related glycosaminoglycan binding) of CXCL8. In addition, this docked structure indicated that the regions of EVA-3 close to the N terminus of the b1-strand and the C terminus of the b3-strand bind to a cavity between the a-helix and N-loop/helical turn of CXCL8.…”

Section: Structural Basis Of Chemokine Recognitionsupporting

confidence: 59%

“…The structure of EVA-3 initially shown by Deruaz et al [8] was refined as an asymmetric dimer containing a cystine knot [39]. The protomer structure was recently confirmed by NMR analysis [48]. Each protomer has a 'knottin' cystine knot topology ( Figure 5A-C), consisting of a single layer b-sheet linked by two long loops, with these elements connected by three disulfide bonds, one of which passes through the macrocycle formed by the other two disulfides.…”

Section: Structure Of Eva-3mentioning

confidence: 93%

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Evasins: Tick Salivary Proteins that Inhibit Mammalian Chemokines

Bhusal

Eaton

Chowdhury

et al. 2020

Trends in Biochemical Sciences

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Section: Structural Basis Of Chemokine Recognitionsupporting

confidence: 59%

Section: Structure Of Eva-3mentioning

confidence: 93%

Evasins: Tick Salivary Proteins that Inhibit Mammalian Chemokines

Bhusal

Eaton

Chowdhury

et al. 2020

Trends in Biochemical Sciences

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“…In contrast, the C6 fold Evasin-3 had high affinity for the CXC chemokines CXCL1 and CXCL8 (and their murine related proteins: CXCL1 and CXCL2). Potent anti-inflammatory activity of Evasins has been demonstrated in several in vivo animal models of disease (255,256).…”

Section: Tick Saliva Protein Evasin-3 and Synthetic Variantsmentioning

confidence: 99%

“…Both synthetic Evasin-3 variants showed high affinity for CXCL8, although lower than the affinity of native Evasin-3 for CXCL8. The long NH 2 -and COOHtermini of native Evasin-3 apparently affect the internal dynamics of its structure, resulting in lower K D values (256).…”

Section: Tick Saliva Protein Evasin-3 and Synthetic Variantsmentioning

confidence: 99%

Targeting Chemokine—Glycosaminoglycan Interactions to Inhibit Inflammation

2020

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Leukocyte migration into tissues depends on the activity of chemokines that form concentration gradients to guide leukocytes to a specific site. Interaction of chemokines with their specific G protein-coupled receptors (GPCRs) on leukocytes induces leukocyte adhesion to the endothelial cells, followed by extravasation of the leukocytes and subsequent directed migration along the chemotactic gradient. Interaction of chemokines with glycosaminoglycans (GAGs) is crucial for extravasation in vivo. Chemokines need to interact with GAGs on endothelial cells and in the extracellular matrix in tissues in order to be presented on the endothelium of blood vessels and to create a concentration gradient. Local chemokine retention establishes a chemokine gradient and prevents diffusion and degradation. During the last two decades, research aiming at reducing chemokine activity mainly focused on the identification of inhibitors of the interaction between chemokines and their cognate GPCRs. This approach only resulted in limited success. However, an alternative strategy, targeting chemokine-GAG interactions, may be a promising approach to inhibit chemokine activity and inflammation. On this line, proteins derived from viruses and parasites that bind chemokines or GAGs may have the potential to interfere with chemokine-GAG interactions. Alternatively, chemokine mimetics, including truncated chemokines and mutant chemokines, can compete with chemokines for binding to GAGs. Such truncated or mutated chemokines are characterized by a strong binding affinity for GAGs and abrogated binding to their chemokine receptors. Finally, Spiegelmers that mask the GAG-binding site on chemokines, thereby preventing chemokine-GAG interactions, were developed. In this review, the importance of GAGs for chemokine activity in vivo and strategies that could be employed to target chemokine-GAG interactions will be discussed in the context of inflammation.

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“…Moreover, the administration of recombinant Evasin-1 reduced skin inflammation and decreased mortality in mice deficient in the chemokine receptor D6, which renders then highly susceptible to inflammation (81). Evasin-3 is specific for the CXC chemokines CXCL8 and CXCL1 and was recently found to disrupt the interaction between CXCL8 and glycosaminoglycans and CXCR2 (Figure 2), which modulate neutrophil migration (82). Several studies have demonstrated the effectiveness of Evasin-3 in different neutrophil-dependent disease models.…”

Section: Recruitment Of Blood-borne Innate Immune Cellsmentioning

confidence: 99%

Tick Salivary Compounds for Targeted Immunomodulatory Therapy

et al. 2020

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Immunodeficiency disorders and autoimmune diseases are common, but a lack of effective targeted drugs and the side-effects of existing drugs have stimulated interest in finding therapeutic alternatives. Naturally derived substances are a recognized source of novel drugs, and tick saliva is increasingly recognized as a rich source of bioactive molecules with specific functions. Ticks use their saliva to overcome the innate and adaptive host immune systems. Their saliva is a rich cocktail of molecules including proteins, peptides, lipid derivatives, and recently discovered non-coding RNAs that inhibit or modulate vertebrate immune reactions. A number of tick saliva and/or salivary gland molecules have been characterized and shown to be promising candidates for drug development for vertebrate immune diseases. However, further validation of these molecules at the molecular, cellular, and organism levels is now required to progress lead candidates to clinical testing. In this paper, we review the data on the immunopharmacological aspects of tick salivary compounds characterized in vitro and/or in vivo and present recent findings on non-coding RNAs that might be exploitable as immunomodulatory therapies.

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Tick saliva protein Evasin-3 modulates chemotaxis by disrupting CXCL8 interactions with glycosaminoglycans and CXCR2

Cited by 17 publications

References 57 publications

Evasins: Tick Salivary Proteins that Inhibit Mammalian Chemokines

Evasins: Tick Salivary Proteins that Inhibit Mammalian Chemokines

Targeting Chemokine—Glycosaminoglycan Interactions to Inhibit Inflammation

Tick Salivary Compounds for Targeted Immunomodulatory Therapy

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