Evolution tunes functional sub-state interconversion to boost enzyme function

Enzymes do not operate as static structures, but continuously fluctuate between different conformations. Enzymes therefore dynamically sample conformations with varying catalytic activity. However, it remains largely unexplored whether evolution can exploit the conformational dynamics between sub-states to improve activity. Here, we dissect the evolutionary trajectory of the β-lactamase OXA-48 toward improved ceftazidime hydrolysis. Evolution relieved conformational bottlenecks by promoting alternate functional sub-states, gradually shifting the rate-limiting step from substrate binding to sub-state interconversion, and finally to the chemical step. Reorganization of the conformational landscape enhanced OXA-48's ability to hydrolyze ceftazidime and introduced a trade-off in its native activity against meropenem. This trade-off stemmed from catalytic incompatibility between the native and the evolved sub-state populations. Our findings highlight the transitions between functional sub-states as a mechanism of natural selection, shaping functional divergence and offering new strategies for enzyme and antibiotic engineering.