Decoding Allosteric Regulation by the Acyl Carrier Protein

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2021 Apr 13

PMID 33846262

Citations 9

Authors

Terra Sztain

Thomas G Bartholow

D John Lee

Lorenzo Casalino

Andrew Mitchell

Megan A Young

Jianing Wang

J Andrew McCammon

Michael D Burkart

Affiliations

Soon will be listed here.

Abstract

Enzymes in multistep metabolic pathways utilize an array of regulatory mechanisms to maintain a delicate homeostasis [K. Magnuson, S. Jackowski, C. O. Rock, J. E. Cronan, Jr, 57, 522-542 (1993)]. Carrier proteins in particular play an essential role in shuttling substrates between appropriate enzymes in metabolic pathways. Although hypothesized [E. Płoskoń et al., 17, 776-785 (2010)], allosteric regulation of substrate delivery has never before been demonstrated for any acyl carrier protein (ACP)-dependent pathway. Studying these mechanisms has remained challenging due to the transient and dynamic nature of protein-protein interactions, the vast diversity of substrates, and substrate instability [K. Finzel, D. J. Lee, M. D. Burkart, 16, 528-547 (2015)]. Here we demonstrate a unique communication mechanism between the ACP and partner enzymes using solution NMR spectroscopy and molecular dynamics to elucidate allostery that is dependent on fatty acid chain length. We demonstrate that partner enzymes can allosterically distinguish between chain lengths via protein-protein interactions as structural features of substrate sequestration are translated from within the ACP four-helical bundle to the protein surface, without the need for stochastic chain flipping. These results illuminate details of cargo communication by the ACP that can serve as a foundation for engineering carrier protein-dependent pathways for specific, desired products.

Citing Articles

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Interface Engineering of Carrier-Protein-Dependent Metabolic Pathways.

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