Archive/A Novel Indigoidine-like NRPS Gene from Arthrobacter antioxidans QL17 Enhances Oxidative Stress Resistance Through Radical Scavenging and Transcriptional Reprogramming
A Novel Indigoidine-like NRPS Gene from Arthrobacter antioxidans QL17 Enhances Oxidative Stress Resistance Through Radical Scavenging and Transcriptional Reprogramming
Xue Yu, Yujie Wu, Wei Zhang et al.
4 de julio de 2026
en

Abstract

Water-soluble blue microbial pigments with antioxidant activity remain rare, and their host-level protective mechanisms are poorly understood. Here, we identified the genetic basis of blue pigment biosynthesis in the glacier-derived strain Arthrobacter antioxidans QL17. Heavy-ion mutagenesis yielded a hyperpigmented mutant (M157) and a pigment-deficient mutant (M186), and pigment yield was positively associated with hydrogen peroxide (H2O2) tolerance. Genome mining identified MWM45_RS16760 as the sole core biosynthetic gene in a candidate nonribosomal peptide synthetase (NRPS)-like cluster. The encoded protein displayed an adenylation–peptidyl carrier protein–thioesterase (A-PCP-TE) architecture with a predicted L-glutamine-specific A domain, and its transcript abundance paralleled pigment production across the three strains. Phylogenetic analysis placed MWM45_RS16760 in a distinct actinomycete-associated indigoidine-like lineage separated from the characterized BpsA and IndC branches. Heterologous expression in Escherichia coli reconstructed a blue-pigment-producing phenotype, increased H2O2 tolerance, and was accompanied by enhanced extracellular DPPH and ABTS radical-scavenging activities in the culture supernatant. Comparative transcriptomics further revealed coordinated activation of oxidative-stress and proteostasis responses alongside repression of tryptophan biosynthesis and flagellar assembly. These findings identify MWM45_RS16760 as a candidate indigoidine-like NRPS associated with blue pigment biosynthesis and oxidative-stress resistance, with heterologous expression linked to enhanced radical scavenging and coordinated transcriptional reprogramming, expanding the phylogenetic and functional diversity of indigoidine-like systems.

Keywords

novelindigoidine-likenrpsgenearthrobacterantioxidansql17enhancesoxidativestressresistancethroughradicalscavengingtranscriptionalreprogrammingantioxidantswater-solublebluemicrobialpigmentsantioxidantactivityremain
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