Nitroxyl and 'Forbidden Disulfides': Phospholamban Cysteines are Targeted to Enhance SERCA2a Activity

Our enjoyable collaboration with Dr. Jeffrey P. Froehlich focused on the role of phospholamban (PLN) in HNO-induced enhancement of SR Ca2+-ATPase (SERCA2a) activity. We hypothesized that given HNO thiophilic nature it modifies cysteine residues in PLN transmembrane domain, altering its interaction with SERCA2a, thus enhancing pump activity. When HNO, donated by Angeli's salt (AS), was administered to control isolated myocytes, it enhanced both sarcomere shortening and Ca2+ transient. However, when AS/HNO was applied to PLN-/- ventriculocytes, HNO inotropy was reduced by ≅ 50% (the remaining likely stemming from enhanced myofilament sensitivity to Ca2+). PLN centrality to HNO cardiotropic action was confirmed incubating SR vesicles from WT and PLN-/- mice with AS/HNO to measure ATP-dependent Ca2+ uptake by stopped-flow mixing. In WT, HNO increased Ca2+ uptake rate, but it failed to do so in PLN-/- vesicles. The role of cysteines in PLN emerged from studies using ER microsomes from Sf21 insect cells expressing SERCA2a±PLN (WT or Cys 36-41-46→Ala mutant) where we assessed SERCA2a dephosphorylation, a measure of E2P hydrolysis, i.e. a rate-limiting step of SERCA2a activity. AS/HNO augmented SERCA2a dephosphorylation in ER microsomes co-expressing SERCA2a and WT PLN, but this stimulation was absent in microsomes expressing SERCA2a and Cys 36-41-46→Ala mutant PLN. Thus, Jeff's elegant, creative and passionate approach helped us to show that PLN is essential for HNO-induced faster Ca2+ uptake by SERCA2a, suggesting that HNO action occurs, at least partly, via modifications of critical cysteines in PLN transmembrane domain. In Jeff's view, “forbidden” disulfide bonds in PLN are involved, and one of his legacies for us is unearthing the cysteine pairs that are involved in HNO-induced formation of an intramolecular bond that could distort the conformation of PLN, thus perturbing its interaction with SERCA2a and relieving the inhibition.