Cytochrome P450s are heme-thiolate enzymes that have been broadly applied in pharmaceutical and biosynthesis because of their efficient oxidation at inert carbons. Extensive engineering campaigns are applied to P450s to explore new non-natural substrates and reactions; however, achieving high coupling efficiency is one of the main challenges. The undesirable uncoupling reactions result in the extra consumption of expensive cofactor NAD(P)H, and lead to the accumulation of reactive oxygen species and the inactivation of enzymes and organisms. Using protein engineering methods, these limitations can be overcome by engineering and fine-tuning P450s. A systemic perspective of the enzyme structure and the catalytic mechanism is essential for P450 engineering campaigns for higher coupling efficiency. This review provide an overview on factors contributing to uncoupling and protein engineering approaches to minimize uncoupling and thereby generating efficient and robust P450s for industrials use. Contributing uncoupling factors are classified into three main groups: i) substrate binding pocket; ii) ligand access tunnel(s); and iii) electron transfer pathway(s). Finally, we draw future directions for combinations of effective state-of-the-art technologies and available software/online tools for P450s engineering campaigns.

Glucosinolate-producing plants have long been recognized for both their distinctive benefits to human nutrition and their resistance traits against pathogens and herbivores. Despite the accumulation of glucosinolates (GLS) in plants is associated with their resistance to various biotic and abiotic stresses, the defensive and biological activities of GLS are commonly conveyed by their metabolic products. In view of this, metabolism is considered the driving factor upon the interactions of GLS-producing plants with other organisms, also influenced by plant and plant attacking or digesting organism characteristics. Several microbial pathogens and insects have evolved the capacity to detoxify GLS-hydrolysis products or inhibit their formation via different means, highlighting the relevance of their metabolic abilities for the plants\' defense system activation and target organism detoxification. Strikingly, some bacteria, fungi and insects can likewise produce their own myrosinase (MYR)-like enzymes in one of the most important adaptation strategies against the GLS-MYR plant defense system. Knowledge of GLS metabolic pathways in herbivores and pathogens can impact plant protection efforts and may be harnessed upon for genetically modified plants that are more resistant to predators. In humans, the interest in the implementation of GLS in diets for the prevention of chronic diseases has grown substantially. However, the efficiency of such approaches is dependent on GLS bioavailability and metabolism, which largely involves the human gut microbiome.Among GLS-hydrolytic products, isothiocyanates (ITC) have shown exceptional properties as chemical plant defense agents against herbivores and pathogens, along with their health-promoting benefits in humans, at least if consumed in reasonable amounts. Deciphering GLS metabolic pathways provides critical information for catalyzing all types of GLS towards the generation of ITCs as the biologically most active metabolites. This review provides an overview on contrasting metabolic pathways in plants, bacteria, fungi, insects and humans towards GLS activation or detoxification. Further, suggestions for the preparation of GLS containing plants with improved health benefits are presented.