Catalytic peptide-based coacervates for enhanced function through structural organization and substrate specificity

Reis, David Q. P.; Pereira, Sara; Ramos, Ana P.; Pereira, Pedro M.; Morgado, Leonor; Calvário, Joana; Henriques, Adriano O.; Serrano, Mónica; Pina, Ana S.

Catalytic peptide-based coacervates for enhanced function through structural organization and substrate specificity

David Q. P. Reis, Sara Pereira, Ana P. Ramos, Pedro M. Pereira, Leonor Morgado, Joana Calvário, Adriano O. Henriques, Mónica Serrano and Ana S. Pina ()
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David Q. P. Reis: Av. da República
Sara Pereira: Av. da República
Ana P. Ramos: Av. da República
Pedro M. Pereira: Av. da República
Leonor Morgado: Universidade NOVA de Lisboa
Joana Calvário: Av. da República
Adriano O. Henriques: Av. da República
Mónica Serrano: Av. da República
Ana S. Pina: Av. da República

Nature Communications, 2024, vol. 15, issue 1, 1-12

Abstract: Abstract Liquid-liquid phase separation (LLPS) in living cells provides innovative pathways for synthetic compartmentalized catalytic systems. While LLPS has been explored for enhancing enzyme catalysis, its potential application to catalytic peptides remains unexplored. Here, we demonstrate the use of coacervation, a key LLPS feature, to constrain the conformational flexibility of catalytic peptides, resulting in structured domains that enhance peptide catalysis. Using the flexible catalytic peptide P7 as a model, we induce reversible biomolecular coacervates with structured peptide domains proficient in hydrolyzing phosphate ester molecules and selectively sequestering phosphorylated proteins. Remarkably, these coacervate-based microreactors exhibit a 15,000-fold increase in catalytic efficiency compared to soluble peptides. Our findings highlight the potential of a single peptide to induce coacervate formation, selectively recruit substrates, and mediate catalysis, enabling a simple design for low-complexity, single peptide-based compartments with broad implications. Moreover, LLPS emerges as a fundamental mechanism in the evolution of chemical functions, effectively managing conformational heterogeneity in short peptides and providing valuable insights into the evolution of enzyme activity and catalysis in prebiotic chemistry.

Date: 2024
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DOI: 10.1038/s41467-024-53699-z

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