In the last 30 years, the field of cyclic adenosine 3\',5\'-monophosphate (cAMP) signalling has witnessed a transformative development with the realization that cAMP is compartmentalized and that spatial regulation of cAMP is critical for faithful signal propagation and hormonal specificity. This recognition has changed our understanding of cAMP signalling from the canonical model, where a linear pathway connects a plasma membrane receptor to intracellular effectors and their targets, to a model where signal transduction occurs within a complex network of alternative branches and where an individual receptor leads to activation of a limited fraction of the network, enabled by local regulation of independent signalling units, resulting in a specific functional outcome. The cardiac myocyte has served as the cell model for many of the original findings leading to this paradigm. In this review, we cover some of the evidence supporting this new perspective and discuss how this model is providing novel mechanistic insight into cardiac myocyte physiology. With a focus on the regulation of cardiac rhythm, we consider how this model can provide an original framework for the identification of disease mechanisms. This article is part of the theme issue \'The heartbeat: its molecular basis and physiological mechanisms\'.

β-adrenergic receptors (βARs) play pivotal roles in regulating cardiac excitation-contraction (E-C) coupling. Global signalling of β1ARs up-regulates both the influx of Ca2+ through sarcolemmal L-type Ca2+ channels (LCCs) and the release of Ca2+ from the sarcoplasmic reticulum (SR) through the ryanodine receptors (RyRs). However, we recently found that β2AR stimulation meditates \'offside compartmentalization\', confining β1AR signalling into subsarcolemmal nanodomains without reaching SR proteins. In the present study, we aim to investigate the new question, whether and how compartmentalized β1AR signalling regulates cardiac E-C coupling.
By combining confocal Ca2+ imaging and patch-clamp techniques, we investigated the effects of compartmentalized βAR signalling on E-C coupling at both cellular and molecular levels. We found that simultaneous activation of β2 and β1ARs, in contrast to global signalling of β1ARs, modulated neither the amplitude and spatiotemporal properties of Ca2+ sparks nor the kinetics of the RyR response to LCC Ca2+ sparklets. Nevertheless, by up-regulating LCC current, compartmentalized β1AR signalling synchronized RyR Ca2+ release and increased the functional reserve (stability margin) of E-C coupling. In circumstances of briefer excitation durations or lower RyR responsivity, compartmentalized βAR signalling, by increasing the intensity of Ca2+ triggers, helped stabilize the performance of E-C coupling and enhanced the Ca2+ transient amplitude in failing heart cells.
Given that compartmentalized βAR signalling can be induced by stress-associated levels of catecholamines, our results revealed an important, yet unappreciated, heart regulation mechanism that is autoadaptive to varied stress conditions.

Although the cAMP-dependent protein kinase (PKA) is ubiquitously expressed, it is sequestered at specific subcellular locations throughout the cell, thereby resulting in compartmentalized cellular signaling that triggers site-specific behavioral phenotypes. We developed a three-step engineering strategy to construct an optogenetic PKA (optoPKA) and demonstrated that, upon illumination, optoPKA migrates to specified intracellular sites. Furthermore, we designed intracellular spatially segregated reporters of PKA activity and confirmed that optoPKA phosphorylates these reporters in a light-dependent fashion. Finally, proteomics experiments reveal that light activation of optoPKA results in the phosphorylation of known endogenous PKA substrates as well as potential novel substrates.