The interplay between glucose and aromatic compound regulation by two IclR-type transcription factors, LigR1 and LigR2, in Pseudomonas putida KT2440

The rhizosphere is a hotspot of microbial activity where plants release a diverse array of aromatic compounds, including shikimate pathway intermediates and monolignols. Pseudomonas putida KT2440, renowned for its metabolic versatility in this niche, uses largely uncharacterized regulatory and enzymatic strategies to utilize these compounds. We investigated two IclR-type transcriptional regulators, LigR1 and LigR2, that control expression of the uncharacterized lig1 and lig2 operons. We demonstrate that ligR1 deletion caused growth defects on glucose and 4-hydroxybenzoate accompanied by cell elongation and aggregation. Structural and functional analyses reveal that LigR1 and LigR2 activate the lig1 operon but repress the lig2 operon. LigR1 binding of 4-hydroxybenzoate induced repression by triggering tetramerization and increasing DNA-binding activity. In contrast, LigR2 responded to quinate, protocatechuate and 4-hydroxybenzoate to potently induce lig2 operon expression by relieving repression. While both operons cooperate in metabolizing these compounds, we propose the lig1 operon mediates influx through its major facilitator superfamily (MFS) transporter (PP_2604), whereas the lig2 operon catalyzes breakdown via a protocatechuate intermediate and the meta-cleavage pathway, supplying oxaloacetate to the TCA cycle. Importantly, we show that P. putida repurposes shikimate pathway intermediates for energy production. These findings challenge the canonical biosynthetic view of the shikimate pathway and redefine the metabolic flexibility of soil pseudomonads. We reveal a novel mechanism enabling P. putida to thrive in the chemically complex rhizosphere and open new avenues for exploring alternate roles of the shikimate pathway, emphasizing transcriptional regulators as tools to deconvolute complex metabolic landscapes.