Intracellular self-assembly and metabolite analysis of key enzymes for L-lysine synthesis based on key components of cellulosomes

Intracellular self-assembly and metabolite analysis of key enzymes for L-lysine synthesis based on key components of cellulosomes

IntroductionCellulosome is a natural multi-enzyme complex in the extracellular space of anaerobic microorganisms, which has the advantages of small molecular weight, multiple binding sites, and strong designability. This study aimed to explore the influence of intracellular self-assembly complexes o...

Full description

Saved in:
Bibliographic Details
Main Authors: Nan Li, Bowen Du, Xiankun Ren, Lu Yang, Peng Du, Piwu Li, Jianbin Wang, Junlin Li, Jing Xiao, Junqing Wang, Ruiming Wang
Format: Article
Language:English
Published: Frontiers Media S.A. 2025-06-01
Series:Frontiers in Microbiology
Subjects:
cellulosome
intracellular assembly
L-lysine
key enzyme gene
metabolite analysis
Online Access:https://www.frontiersin.org/articles/10.3389/fmicb.2025.1596240/full
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:IntroductionCellulosome is a natural multi-enzyme complex in the extracellular space of anaerobic microorganisms, which has the advantages of small molecular weight, multiple binding sites, and strong designability. This study aimed to explore the influence of intracellular self-assembly complexes on L-lysine biosynthesis.MethodsTwo novel L-lysine-engineered bacteria modification strategies were designed, considering the L-lysine biosynthesis pathway using DocA-S3/Coh as an efficient intracellular assembly element: pairwise assembly of key enzymes in cells and multi-enzyme assembly based on scaffolding proteins. Seven strains of key enzyme pairwise-assembled engineered bacteria were constructed, and four strains of multi-enzyme-assembled engineered bacteria were designed based on the scaffold protein genome.ResultsThe production of L-lysine by multi-enzyme-assembled engineered strain Escherichia coli QDE-aspC-DocA-S3-lysC:pET-28a-ScaA was 46.9% higher than that of E. coli QDE, and the conversion rate was increased from 50.9 to 59.8%. By combining specific analyses with metabolomics, 40 core metabolites of the assembled engineered bacteria were identified and mapped to L-lysine-related metabolic pathways, and the mechanism of how intracellular multi-enzyme assembly promoted the efficient synthesis of multiple amino acids was analyzed.ConclusionThis strategy exerts the “proximity effect” among multi-enzyme complexes, improves the transfer efficiency of intermediate metabolites between different catalytic active centers, indirectly improves the catalytic rate of each key enzyme, and provides a novel idea and technical platform for other multi-enzyme intracellular assemblies.
ISSN:1664-302X

Similar Items