TY - JOUR
T1 - Altering the mechanical properties of self-assembled filaments through engineering of EspA bacterial protein
AU - Elias-Mordechai, Moran
AU - Morhaim, May
AU - Pelah, Maya Georgia
AU - Rostovsky, Irina
AU - Nogaoker, May
AU - Jopp, Jürgen
AU - Zarivach, Raz
AU - Sal-Man, Neta
AU - Berkovich, Ronen
N1 - Publisher Copyright:
© 2024 The Authors
PY - 2025/2/1
Y1 - 2025/2/1
N2 - Protein-based biomaterials are in high demand due to their high biocompatibility, non-toxicity, and biodegradability. In this study, we explore the bacterial E. coli secreted protein A (EspA), which self-assembles into long extracellular filaments, as a potential building block for new protein-based biomaterials. We investigated the morphological and mechanical properties of EspA filaments and how protein engineering can modify them. Our study include three types of filaments: natural EspA filaments, full-length recombinant EspA filaments, and truncated recombinant EspA filaments lacking a third of the original codon region. The recombinant EspA proteins formed curly, thin filaments with higher longitudinal elasticity (shorter persistence length) compared to the natural, linear filaments. Additionally, the recombinant filaments had a radial elastic modulus about an order of magnitude lower than the natural filaments. The truncated recombinant filaments had a higher radial modulus than the full-length ones, and unlike the purely elastic natural filaments, recombinant filaments were less compliant with the applied force that penetrated them. These differences underscore the potential to modulate EspA filament properties through protein sequence mutations. Our findings suggest EspA as a fundamental element for developing a new biomaterial with a hierarchical structure, enabling the fabrication of macroscopic substances from self-assembled EspA-modulated filaments.
AB - Protein-based biomaterials are in high demand due to their high biocompatibility, non-toxicity, and biodegradability. In this study, we explore the bacterial E. coli secreted protein A (EspA), which self-assembles into long extracellular filaments, as a potential building block for new protein-based biomaterials. We investigated the morphological and mechanical properties of EspA filaments and how protein engineering can modify them. Our study include three types of filaments: natural EspA filaments, full-length recombinant EspA filaments, and truncated recombinant EspA filaments lacking a third of the original codon region. The recombinant EspA proteins formed curly, thin filaments with higher longitudinal elasticity (shorter persistence length) compared to the natural, linear filaments. Additionally, the recombinant filaments had a radial elastic modulus about an order of magnitude lower than the natural filaments. The truncated recombinant filaments had a higher radial modulus than the full-length ones, and unlike the purely elastic natural filaments, recombinant filaments were less compliant with the applied force that penetrated them. These differences underscore the potential to modulate EspA filament properties through protein sequence mutations. Our findings suggest EspA as a fundamental element for developing a new biomaterial with a hierarchical structure, enabling the fabrication of macroscopic substances from self-assembled EspA-modulated filaments.
KW - AFM
KW - EspA
KW - Mechanical properties
KW - Protein-based biomaterials
KW - Self-assembly
UR - http://www.scopus.com/inward/record.url?scp=85212869100&partnerID=8YFLogxK
U2 - 10.1016/j.mtbio.2024.101414
DO - 10.1016/j.mtbio.2024.101414
M3 - Article
AN - SCOPUS:85212869100
SN - 2590-0064
VL - 30
JO - Materials Today Bio
JF - Materials Today Bio
M1 - 101414
ER -