Biomimetic Metabolism of Kaurenoic Acid Validated by Microsomal Reactions

The cytochrome P450 is a remarkable family of enzymes with widespread occurrence in animals and plants. In humans, they catalyze phase I metabolism reactions, such as oxidations and hydroxylations, playing a significant role in xenobiotics detoxification. Although mechanistic details of the catalytic cycle of cytochrome P450 are known, and human isoforms have their crystal structure solved, mimicking cytochrome P450 reactions using in vitro systems is still challenging. For this reason, biological assays using isolated enzymes or microsomal fractions are typically required to study the oxidative metabolism of new drugs before approval by regulatory agencies. Here we demonstrate that a series of metalloporphyrin catalysts generate the same oxidative product in vitro as a liver microsomal assay. The bioactive diterpene kaurenoic acid was chosen as a substrate model because it is a component of widely used phytomedicines in Brazil, such as guaco syrups and copaiba waxes. We evaluated the influence of reaction parameters such as catalyst type, oxygen donor type, solvent, and catalyst concentration on substrate consumption. Three products had their structures proposed by mass spectrometry, and among them, a dihydroxylated oxidation product was detected as a major metabolite after liver microsomal biotransformation and using porphyrin catalysts. We envision that the use of metalloporphyrins could be a useful strategy for biomimetic oxidation of kaurenic terpenes.