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A phosphorylation signal activates genome-wide transcriptional control by BfmR, the global regulator of <i>Acinetobacter</i> resistance and virulence

Nicole Raustad, Yunfei Dai, Akira Iinishi, Arpita Mohapatra, Mark W. Soo, Everett Hay, Gabrielle M. Hernandez, Edward Geisinger

2025Nucleic Acids Research9 citationsDOIOpen Access PDF

Abstract

The nosocomial pathogen Acinetobacter baumannii is a major threat to human health. The sensor kinase-response regulator system, BfmS-BfmR, is essential to multidrug resistance and virulence in the bacterium and represents a potential antimicrobial target. Important questions remain about how the system controls resistance and pathogenesis. Although BfmR knockout alters expression of >1000 genes, its direct regulon is undefined. Moreover, how phosphorylation controls the regulator is unclear. Here, we address these problems by combining mutagenesis, ChIP-seq, and in vitro phosphorylation to study the functions of phospho-BfmR. We show that phosphorylation is required for BfmR-mediated gene regulation, antibiotic resistance, and sepsis development in vivo. Consistent with activating the protein, phosphorylation induces dimerization and target DNA affinity. Integrated analysis of genome-wide binding and transcriptional profiles of BfmR led to additional key findings: (1) Phosphorylation dramatically expands the number of genomic sites BfmR binds; (2) DNA recognition involves a direct repeat motif widespread across promoters; (3) BfmR directly regulates 303 genes as activator (e.g., capsule, peptidoglycan, and outer membrane biogenesis) or repressor (pilus biogenesis); (4) BfmR controls several non-coding sRNAs. These studies reveal the centrality of a phosphorylation signal in driving A. baumannii disease and disentangle the extensive pathogenic gene-regulatory network under its control.

Topics & Concepts

BiologyVirulenceRegulatorPhosphorylationGenomeGeneticsTranscriptional regulationResponse regulatorCell biologyMicrobiologyBacterial proteinBacteriaGeneTranscription factorAntibiotic Resistance in BacteriaCRISPR and Genetic EngineeringBacterial Genetics and Biotechnology
A phosphorylation signal activates genome-wide transcriptional control by BfmR, the global regulator of <i>Acinetobacter</i> resistance and virulence | Litcius