A Unique Binding Mode of P1' Leu-containing Target Sequences for Sortase A Results in Alternative Cleavage

Overview

Journal RSC Chem Biol

Publisher Royal Society of Chemistry

Specialty Biology

Date 2024 Jan 5

PMID 38179192

Authors

Brandon A Vogel

Jadon M Blount

Hanna M Kodama

Noah J Goodwin-Rice

Devin J Andaluz

Sophie N Jackson

John M Antos

Jeanine F Amacher

Affiliations

Soon will be listed here.

Abstract

Sortase enzymes are cysteine transpeptidases that attach environmental sensors, toxins, and other proteins to the cell surface in Gram-positive bacteria. The recognition motif for many sortases is the cell wall sorting signal (CWSS), LPXTG, where X = any amino acid. Recent work from ourselves and others has described recognition of additional amino acids at a number of positions in the CWSS, specifically at the Thr (or P1) and Gly (or P1') positions. In addition, although standard cleavage occurs between these two residues (P1/P1'), we previously observed that the SrtA enzyme from will cleave after the P1' position when its identity is a Leu or Phe. The stereochemical basis of this alternative cleavage is not known, although homologs, , SrtA from or do not show alternative cleavage to a significant extent. Here, we use protein biochemistry, structural biology, and computational biochemistry to predict an alternative binding mode that facilitates alternative cleavage. We use SrtA (spySrtA) as our model enzyme, first confirming that it shows similar standard/alternative cleavage ratios for LPAT, LPAT, and LPAT sequences. Molecular dynamics simulations suggest that when P1' is Leu, this amino acid binds in the canonical S1 pocket, pushing the P1 Thr towards solvent. The P4 Leu (L̲PATL) binds as it does in standard binding, resulting in a puckered binding conformation. We use P1 Glu-containing peptides to support our hypotheses, and present the complex structure of spySrtA-LPALA to confirm favorable accommodation of Leu in the S1 pocket. Overall, we structurally characterize an alternative binding mode for spySrtA and specific target sequences, expanding the potential protein engineering possibilities in sortase-mediated ligation applications.

Citing Articles

Amino acid variability at W194 of Staphylococcus aureus sortase A alters nucleophile specificity.

Kodama H, Lindblom K, Walkenhauer E, Antos J, Amacher J Protein Sci. 2024; 33(12):e5212.

PMID: 39548757 PMC: 11568364. DOI: 10.1002/pro.5212.

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