AI-Based Methods for Cryptic Pocket Detection Are Fast and Qualitative Compared to Quantitatively Predictive Simulations

Artificial intelligence (AI) models have advanced rapidly, driving breakthroughs in protein structure prediction, functional annotation, and conformational exploration. Among these, molecular dynamics (MD)-inspired generative models such as AlphaFlow and BioEmu show strong potential for capturing conformational ensembles. In this study, we benchmark these models alongside physics-based MD simulations to evaluate their ability to detect cryptic pockets in proteins. Identifying such transient pockets remains a vital goal in drug discovery, as they can offer new avenues for targeting proteins traditionally challenging to modulate. We also assess two specialized residue-level predictors, PocketMiner and CryptoBank. Using the interferon inhibitory domain of Zaire Ebola VP35 (VP35), TEM-1 {beta}-lactamse with the M182T substitution (TEM {beta}-lactamase), and their mutants, we test whether each method can detect pockets and capture the effects of point mutations known to enhance or suppress pocket formation. All methods successfully identify pockets in VP35 and distinguish between opening and closing mutants. However, in TEM, where pocket opening is subtle, the methods perform inconsistently. These results highlight the promise of AI-based and simulation-based strategies in cryptic pocket discovery while pointing to the need for further improvements to achieve robust, system-independent predictions.