Metabolic and Process Engineering for Microbial Production of Protocatechuate from Xylose with Corynebacterium glutamicum

3,4-Dihydroxybenzoate (protocatechuate, PCA) is a phenolic compound naturally found in edible vegetables and medicinal herbs. PCA is of interest in the chemical industry as a building block for novel polymers and has wide potential for pharmaceutical applications due to its antioxidant, anti-inflammatory, and antiviral properties. In the present study, we designed and constructed a novel Corynebacterium glutamicum strain to enable the efficient utilization of O_SCPLOWDC_SCPLOW-xylose for microbial production of PCA. The engineered strain showed a maximum PCA titer of 62.1 {+/-} 12.1 mM (9.6 {+/-} 1.9 g L-1) from O_SCPLOWDC_SCPLOW-xylose as the primary carbon and energy source. The corresponding yield was [Formula], which corresponds to 38 % of the maximum theoretical yield and is 14-fold higher compared to the parental producer strain on O_SCPLOWDC_SCPLOW-glucose. By establishing a one-pot bioreactor cultivation process followed by subsequent process optimization, the same maximum titer and a total amount of 16.5 {+/-} 1.1 g was reached. Downstream processing of PCA from this fermentation broth was realized via electrochemically induced crystallization by taking advantage of the pH-dependent properties of PCA. Since PCA turned out to be electrochemically unstable in combination with several anode materials, a threechamber electrolysis setup was established to crystallize PCA and to avoid direct anode contact. This resulted in a maximum final purity of 95.4 %. In summary, the established PCA production process represents a highly sustainable approach, which will serve as a blueprint for the bio-based production of other hydroxybenzoic acids from alternative sugar feedstocks.