Replicates in Biocatalysis Experiments: Machine Learning for Enzyme Cascade Optimization

The optimization of enzyme cascades is a complex and resource-demanding task due to the multitude of parameters and synergistic effects involved. Machine learning can support the identification of optimal reaction conditions, for example, in the case of Bayesian optimization (BO), by proposing new experiments based on Gaussian process regression (GPR) and expected improvement (EI). Here, in this research BO is used to optimize the concentrations of the reaction components of an enzyme cascade. The productivity-cost-ratio is chosen as the optimization objective in order to achieve the highest possible productivity, which was normalized to the costs of the materials used to prevent convergence to ever-increasing enzyme concentrations. To reduce the experimental effort, contrary to common practice in biological experiments, replicates were not used; instead, the algorithm's proposed experiments and inherent uncertainty quantification were relied upon. This approach balances parameter space exploration and exploitation, which is critical for the efficient and effective identification of optimal reaction conditions. At the optimized reaction conditions identified in this study, the productivity-cost ratio is doubled to 38.6 mmol L-1 h-1 <euro>-1 compared to a reference experiment. The parameter optimization required only 52 experiments while being robust to outlying experimental results. An in vitro enzyme cascade for mevalonate phosphorylation and ATP regeneration was optimized for productivity and productivity-cost-ratio using Bayesian optimization (BO) for the proposal of new experiments with an expected improvement. In four BO rounds, the optimal compound concentrations were found to reach an optimum, while avoiding replicated experiments and being robust to outlying experimental results. Institute and/or researcher Twitter usernames: @Luetz_Lab: @RosenthalKatrin; @ericvonlieres. image