Structural Basis of the Bivalency of the TRPV1 Agonist DkTx

Author:

Ramanujam Venkatraman1,Crawford Theo1,Cristofori‐Armstrong Ben1,Deuis Jennifer R.2,Jia Xinying1,Maxwell Michael J.1,Jami Sina2,Ma Linlin3,Vetter Irina2,Mobli Mehdi1ORCID

Affiliation:

1. Australian Institute for Bioengineering and Nanotechnology The University of Queensland St Lucia 4072 Queensland Australia

2. Institute for Molecular Biosciences School of Pharmacy The University of Queensland St Lucia 4072 Queensland Australia

3. Griffith Institute for Drug Discovery School of Environment and Science Griffith University Nathan 4111 Queensland Australia

Abstract

AbstractBivalency is a prevalent natural mechanism to enhance receptor avidity. Various two‐domain disulfide‐rich peptides exhibiting bivalent action have been identified from animal venoms. A unique characteristic of these peptides is that they induce a pharmacological response different from that provoked by any of the constituent domains. The enhanced potency and avidity of such peptides is therefore a consequence of their domain fusion by a peptide linker. The role of the linker itself, beyond conjugation, remains unclear. Here, we investigate how the linker affects the bivalency of the capsaicin receptor (TRPV1) agonist DkTx. We recombinantly produced isotope labelled DkTx using a protein splicing approach, to solve the high‐resolution solution structure of DkTx, revealing residual linker order stabilised by linker‐domain interactions leading to biased domain orientations. The significance of this was studied using a combination of mutagenesis, spin relaxation studies and electrophysiology measurements. Our results reveal that disrupting the pre‐organisation of the domains of DkTx is accompanied by reductions in potency and onset of avidity. Our findings support a model of pre‐configured two‐domain binding, in favour of the previously suggested sequential binding model. This highlights the significance of ordered elements in linker design and the natural evolution of these in bivalent toxins.

Funder

Australian Research Council

National Health and Medical Research Council

Publisher

Wiley

Subject

General Chemistry,Catalysis

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