Journal
JOURNAL OF MOLECULAR BIOLOGY
Volume 433, Issue 22, Pages -Publisher
ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD
DOI: 10.1016/j.jmb.2021.167255
Keywords
cysteine synthase; protein-peptide interactions; protein structures; moonlighting proteins; Bioinformatics
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Funding
- CSIR India
- Department of Biotechnology, India
- CSIR SRF fellowships
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The study develops an iterative sequence matching method to reveal the moonlighting biochemistry of cysteine synthase (CS) and validates the predictions through analytical and structural approaches. Experimental results show that five previously unknown CS-binding proteins involved in diverse metabolic processes interact with CS in a species-specific manner. Signature characteristics of protein-protein interactions highly match with known CS-Binder, indicating the potential for further investigation into protein-specific moonlighting properties of multifunctional proteins.
Cysteine Synthase (CS), the enzyme that synthesizes cysteine, performs non-canonical regulatory roles by binding and modulating functions of disparate proteins. Beyond its role in catalysis and regulation in the cysteine biosynthesis pathway, it exerts its moonlighting effect by binding to few other proteins which possess a C-terminal CS-binding motif, ending with a terminal ILE. Therefore, we hypothesized that CS might regulate many other disparate proteins with the CS-binding motif. In this study, we developed an iterative sequence matching method for mapping moonlighting biochemistry of CS and validated our prediction by analytical and structural approaches. Using a minimal protein-peptide interaction system, we show that five previously unknown CS-binder proteins that participate in diverse metabolic processes interact with CS in a species-specific manner. Furthermore, results show that signatures of protein-protein interactions, including thermodynamic, competitive-inhibition, and structural features, highly match the known CS-Binder, serine acetyltransferase (SAT). Together, the results presented in this study allow us to map the extreme multifunctional space (EMS) of CS and reveal the biochemistry of moonlighting space, a subset of EMS. We believe that the integrated computational and experimental workflow developed here could be further modified and extended to study protein-specific moonlighting properties of multifunctional proteins. (C) 2021 The Author(s). Published by Elsevier Ltd.
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