Mutational Analysis of the Pro-peptide of a Marine Intracellular Subtilisin Protease Supports Its Role in Inhibition

Overview

Journal Proteins

Date 2018 Jun 17

PMID 29907987

Citations 4

Authors

Gro E K Bjerga

Oivind Larsen

Hasan Arsin

Adele Williamson

Antonio Garcia-Moyano

Ingar Leiros

Pal Puntervoll

Affiliations

Soon will be listed here.

Abstract

Intracellular subtilisin proteases (ISPs) have important roles in protein processing during the stationary phase in bacteria. Their unregulated protein degrading activity may have adverse effects inside a cell, but little is known about their regulatory mechanism. Until now, ISPs have mostly been described from Bacillus species, with structural data from a single homolog. Here, we study a marine ISP originating from a phylogenetically distinct genus, Planococcus sp. The enzyme was successfully overexpressed in E. coli, and is active in presence of calcium, which is thought to have a role in minor, but essential, structural rearrangements needed for catalytic activity. The ISP operates at alkaline pH and at moderate temperatures, and has a corresponding melting temperature around 60 °C. The high-resolution 3-dimensional structure reported here, represents an ISP with an intact catalytic triad albeit in a configuration with an inhibitory pro-peptide bound. The pro-peptide is removed in other homologs, but the removal of the pro-peptide from the Planococcus sp. AW02J18 ISP appears to be different, and possibly involves several steps. A first processing step is described here as the removal of 2 immediate N-terminal residues. Furthermore, the pro-peptide contains a conserved LIPY/F-motif, which was found to be involved in inhibition of the catalytic activity.

Citing Articles

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Characterization of a novel cold-adapted intracellular serine protease from the extremophile Or1.

Rasmussen C, Scavenius C, Thogersen I, Harwood S, Larsen O, Bjerga G Front Microbiol. 2023; 14:1121857.

PMID: 36910232 PMC: 9995970. DOI: 10.3389/fmicb.2023.1121857.

Mutational analysis of the pro-peptide of a marine intracellular subtilisin protease supports its role in inhibition.

Bjerga G, Larsen O, Arsin H, Williamson A, Garcia-Moyano A, Leiros I Proteins. 2018; 86(9):965-977.

PMID: 29907987 PMC: 6220982. DOI: 10.1002/prot.25528.

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