Templated Trimerization of the Phage L Decoration Protein on Capsids

Overview

Journal bioRxiv

Date 2024 Sep 16

PMID 39282432

Authors

Brianna M Woodbury

Rebecca L Newcomer

Andrei T Alexandrescu

Carolyn M Teschke

Affiliations

Soon will be listed here.

Abstract

The 134-residue phage L decoration protein (Dec) forms a capsid-stabilizing homotrimer that has an asymmetric tripod-like structure when bound to phage L capsids. The N-termini of the trimer subunits consist of spatially separated globular OB-fold domains that interact with the virions of phage L or the related phage P22. The C-termini of the trimer form a three-stranded intertwined spike structure that accounts for nearly all the interactions that stabilize the trimer. A Dec mutant with the spike residues 99-134 deleted (Dec ) was used to demonstrate that the stable globular OB-fold domain folds independently of the C-terminal residues. However, Dec was unable to bind phage P22 virions, indicating the C-terminal spike is essential for stable capsid interaction. The full-length Dec trimer is disassembled into monomers by acidification to pH <2. These monomers retain the folded globular OB-fold domain structure, but the spike is unfolded. Increasing the pH of the Dec monomer solution to pH 6 allowed for slow trimer formation over the course of days. The infectious cycle of phage L is only around an hour, however, implying Dec trimer assembly is templated by the phage capsid. The Thermodynamic Hypothesis holds that protein folding is determined by the amino acid sequence. Dec serves as an unusual example of an oligomeric folding step that is kinetically accelerated by a viral capsid template. The capsid templating mechanism could satisfy the flexibility needed for Dec to adapt to the unusual quasi-symmetric binding site on the mature phage L capsid.

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