Construction of a Convenient Screening Method for P-Hydroxybenzoate Hydroxylase To Enable Efficient Gallic Acid and Pyrogallol Biosynthesis

BackgroundGallic acid (GA) and pyrogallol are phenolic hydroxyl compounds and have diverse biological activities. Microbial-based biosynthesis of GA and pyrogallol has been emerged as an ecofriendly method to replace the traditional chemical synthesis. In GA and pyrogallol biosynthetic pathways, the low hydroxylation activity of p-hydroxybenzoate hydroxylase (PobA) towards 3,4-dihydroxybenzoic acid (3,4-DHBA) limited the high-level biosynthesis of GA and pyrogallol.ResultsThis work reported a high active PobA mutant (Y385F/T294A/V349A PobA) towards 3,4-DHBA. This mutant was screened out from a PobA random mutagenesis library through a novel naked eye visual screening method. In vitro enzyme assay showed this mutant has a kcat/Km of 0.059 μM-1s-1 towards 3,4-DHBA, which was 4.92-fold higher than the reported mutant (Y385F/T294A PobA). Molecular docking simulation provided the mechanism explanation of the high activity. Expression of this mutant in E. coli BW25113 (F’) can generate 830 ± 33 mg/L GA from 1000 mg/L 3,4-DHBA. After that, we utilized this mutant to assemble a de novo GA biosynthetic pathway. Subsequently, this pathway was introduced into a 3,4-DHBA-producing strain (E. coli BW25113 (F’)ΔaroE) to achieve 301 ± 15 mg/L GA production from simple carbon sources. Similarly, assembling this mutant into a de novo pyrogallol biosynthetic pathway enabled 129 ± 15 mg/L pyrogallol production.ConclusionsThis work established an efficient screening method and generated a high active PobA mutant. Assembling this mutant into GA and pyrogallol biosynthetic pathways achieved the de novo production of these two compounds. Besides, this mutant has great potential for GA or pyrogallol derivatives production. The screening method could be used for other GA biosynthesis-related enzymes.

A growth-based, high-throughput selection platform enables remodeling of 4-hydroxybenzoate hydroxylase active site

ABSTRACTWe report an aerobic, growth-based selection platform founded on NADP(H) redox balance restoration in Escherichia coli, and demonstrate its application in high-throughput evolution of oxygenase. A single round of selection enabled Pseudomonas aeruginoasa 4-hydroxybenzoate hydroxylase (PobA) to accept 3,4-dihydroxybenzoic acid efficiently, an essential step toward gallic acid biosynthesis. The best variant DA015 exhibited more than 5-fold higher catalytic efficiency compared to previously engineered enzymes. Structural modeling suggests precise re-organization of active site hydrogen bond network, which is difficult to obtain without deep navigation of combinatorial sequence space. We envision universal application of this selection platform in engineering NADPH-dependent oxidoreductases.

Structural comparison of p-hydroxybenzoate hydroxylase (PobA) from Pseudomonas putida with PobA from other Pseudomonas spp. and other monooxygenases

The crystal structure is reported of p-hydroxybenzoate hydroxylase (PobA) from Pseudomonas putida, a possible drug target to combat tetracycline resistance, in complex with flavin adenine dinucleotide (FAD). The structure was refined at 2.2 Å resolution with four polypeptide chains in the asymmetric unit. Based on the results of pairwise structure alignments, PobA from P. putida is structurally very similar to PobA from P. fluorescens and from P. aeruginosa. Key residues in the FAD-binding and substrate-binding sites of PobA are highly conserved spatially across the proteins from all three species. Additionally, the structure was compared with two enzymes from the broader class of oxygenases: 2-hydroxybiphenyl 3-monooxygenase (HbpA) from P. nitroreducens and 2-methyl-3-hydroxypyridine-5-carboxylic acid oxygenase (MHPCO) from Mesorhizobium japonicum. Despite having only 14% similarity in their primary sequences, pairwise structure alignments of PobA from P. putida with HbpA from P. nitroreducens and MHPCO from M. japonicum revealed local similarities between these structures. Key secondary-structure elements important for catalysis, such as the βαβ fold, β-sheet wall and α12 helix, are conserved across this expanded class of oxygenases.