Issue 47, 2024

Sequence-defined structural transitions by calcium-responsive proteins

Abstract

Biopolymer sequences dictate their functions, and protein-based polymers are a promising platform to establish sequence–function relationships for novel biopolymers. To efficiently explore vast sequence spaces of natural proteins, sequence repetition is a common strategy to tune and amplify specific functions. This strategy is applied to repeats-in-toxin (RTX) proteins with calcium-responsive folding behavior, which stems from tandem repeats of the nonapeptide GGXGXDXUX in which X can be any amino acid and U is a hydrophobic amino acid. To determine the functional range of this nonapeptide, we modified a naturally occurring RTX protein that forms β-roll structures in the presence of calcium. Sequence modifications focused on calcium-binding turns within the repetitive region, including either global substitution of nonconserved residues or complete replacement with tandem repeats of a consensus nonapeptide GGAGXDTLY. Some sequence modifications disrupted the typical transition from intrinsically disordered random coils to folded β rolls, despite conservation of the underlying nonapeptide sequence. Proteins enriched with smaller, hydrophobic amino acids adopted secondary structures in the absence of calcium and underwent structural rearrangements in calcium-rich environments. In contrast, proteins with bulkier, hydrophilic amino acids maintained intrinsic disorder in the absence of calcium. These results indicate a significant role of nonconserved amino acids in calcium-responsive folding, thereby revealing a strategy to leverage sequences in the design of tunable, calcium-responsive biopolymers.

Graphical abstract: Sequence-defined structural transitions by calcium-responsive proteins

Supplementary files

Article information

Article type
Paper
Submitted
20 Aug. 2024
Accepted
06 Nov. 2024
First published
08 Nov. 2024

Polym. Chem., 2024,15, 4864-4874

Sequence-defined structural transitions by calcium-responsive proteins

M. P. Chang, W. Huang, G. M. Shambharkar, K. M. Hernandez and D. J. Mai, Polym. Chem., 2024, 15, 4864 DOI: 10.1039/D4PY00907J

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