A KDPG sensor RccR governs Pseudomonas aeruginosa carbon metabolism and aminoglycoside antibiotic tolerance.

Pseudomonas aeruginosa harbors sophisticated transcription factor (TF) networks to coordinately regulate cellular metabolic states for rapidly adapting to changing environments. The extraordinary capacity in fine-tuning the metabolic states enables its success in tolerance to antibiotics and evading host immune defenses. However, the linkage among transcriptional regulation, metabolic states and antibiotic tolerance in P. aeruginosa remains largely unclear. By screening the P. aeruginosa TF mutant library constructed by CRISPR/Cas12k-guided transposase, we identify that rccR (PA5438) is a major genetic determinant in aminoglycoside antibiotic tolerance, the deletion of which substantially enhances bacterial tolerance. We further reveal the inhibitory roles of RccR in pyruvate metabolism (aceE/F) and glyoxylate shunt pathway (aceA and glcB), and overexpression of aceA or glcB enhances bacterial tolerance. Moreover, we identify that 2-keto-3-deoxy-6-phosphogluconate (KDPG) is a signal molecule that directly binds to RccR. Structural analysis of the RccR/KDPG complex reveals the detailed interactions. Substitution of the key residue R152, K270 or R277 with alanine abolishes KDPG sensing by RccR and impairs bacterial growth with glycerol or glucose as the sole carbon source. Collectively, our study unveils the connection between aminoglycoside antibiotic tolerance and RccR-mediated central carbon metabolism regulation in P. aeruginosa, and elucidates the KDPG-sensing mechanism by RccR.

cDNA cloning, prokaryotic expression, and functional analysis of squalene synthase (SQS) in Camellia vietnamensis Huang.

Camellia vietnamensis Huang, which belongs to Camellia oleifera, is a traditional Chinese medicinal plant widely planted on Hainan Island. Tea saponin is an important functional component of C. vietnamensis, and squalene is the precursor substance that controls its formation. Squalene synthase (SQS: EC 2.5.1.21) synthesizes squalene from 2 molecules of farnesyl pyrophosphate (FPP). In this study, 1683 bp of the C. vietnamensis SQS gene, designated as CvSQS, was cloned and encoded 414 amino acids. Bioinformatics and phylogenetic tree analysis revealed the high homology of CvSQS with squalene synthases from other plants. For soluble proteins, the carboxy-terminal deleted CvSQS was obtained for expression in Escherichia coli Transetta (DE3), and the recombinant protein with a weight of 42.5 kDa was detected using SDS-PAGE and Western blot. After an enzymatic reaction, the presence of squalene in the product was analyzed using GC-MS detection, which indicated that CvSQS had catalytic activity. The tissue specificity of CvSQS and its presence in seeds at various ripening stages was detected by q-RT PCR. CvSQS had the highest transcriptional level in leaves, followed by seeds, roots, and flowers; the amount of CvSQS in the seeds was highest in September. The identification and functional characterization of CvSQS is essential for further studies on the regulation mechanism of tea saponin in C. vietnamensis.