Litcius/Paper detail

Water-organizing motif continuity is critical for potent ice nucleation protein activity

Jordan Forbes, Akalabya Bissoyi, Lukas Eickhoff, Nàama Reicher, Thomas Hansen, Christopher G. Bon, Virginia K. Walker, Thomas Koop, Yinon Rudich, Ido Braslavsky, Peter L. Davies

2022Nature Communications41 citationsDOIOpen Access PDF

Abstract

Bacterial ice nucleation proteins (INPs) can cause frost damage to plants by nucleating ice formation at high sub-zero temperatures. Modeling of Pseudomonas borealis INP by AlphaFold suggests that the central domain of 65 tandem sixteen-residue repeats forms a beta-solenoid with arrays of outward-pointing threonines and tyrosines, which may organize water molecules into an ice-like pattern. Here we report that mutating some of these residues in a central segment of P. borealis INP, expressed in Escherichia coli, decreases ice nucleation activity more than the section's deletion. Insertion of a bulky domain has the same effect, indicating that the continuity of the water-organizing repeats is critical for optimal activity. The ~10 C-terminal coils differ from the other 55 coils in being more basic and lacking water-organizing motifs; deletion of this region eliminates INP activity. We show through sequence modifications how arrays of conserved motifs form the large ice-nucleating surface required for potency.

Topics & Concepts

Ice nucleusNucleationEscherichia coliStructural motifBiophysicsChemistryTandemCrystallographySequence motifMotif (music)MoleculeBiologyCell biologyDNAMaterials scienceBiochemistryPhysicsComposite materialGeneAcousticsOrganic chemistryPhysiological and biochemical adaptationsnanoparticles nucleation surface interactionsPlant Stress Responses and Tolerance