Elucidating the Activation Mechanism of AMPK by Direct Pan-Activator PF-739

Adenosine monophosphate-activated protein kinase (AMPK) is a key energy sensor regulating the cell metabolism in response to energy supply and demand. The evolutionary adaptation of AMPK to different tissues is accomplished through the expression of distinct isoforms that can form up to 12 heterotrimeric complexes, which exhibit notable differences in the sensitivity to direct activators. To comprehend the molecular factors of the activation mechanism of AMPK, we have assessed the changes in the structural and dynamical properties of beta 1- and beta 2-containing AMPK complexes formed upon binding to the pan-activator PF-739. The analysis revealed the molecular basis of the PF-739-mediated activation of AMPK and enabled us to identify distinctive features that may justify the slightly higher affinity towards the beta 1-isoform, such as the beta 1-Asn111 to beta 2-Asp111 substitution, which seems to be critical for modulating the dynamical sensitivity of beta 1- and beta 2 isoforms. The results are valuable in the design of selective activators to improve the tissue specificity of therapeutic treatment.

Automated summary

AMPK is a key energy sensor that regulates cell metabolism in response to energy supply and demand. Different isoforms of AMPK formed heterotrimeric complexes exhibit notable differences in sensitivity to direct activators, with PF-739 playing a role in activating AMPK through specific mechanisms. Understanding these molecular factors can help in designing selective activators for improving tissue specificity in therapeutic treatment.