Cardiac sympathetic neurons (SNs) finely tune the rate and strength of heart contractions to match blood demand, both at rest and during acute stress, through the release of noradrenaline (NE). Junctional sites at the interface between the two cell types have been observed, although whether direct neurocardiac coupling has a role in heart physiology has not been clearly demonstrated to date. We investigated the dynamics of SN/cardiomyocyte intercellular signalling, both by fluorescence resonance energy transfer-based imaging of cAMP in co-cultures, as a readout of cardiac β-adrenergic receptor activation, and in vivo, using optogenetics in transgenic mice with SN-specific expression of Channelrhodopsin-2. We demonstrate that SNs and cardiomyocytes interact at specific sites in the human and rodent heart, as well as in co-cultures. Accordingly, neuronal activation elicited intracellular cAMP increases only in directly contacted myocytes and cell-cell coupling utilized a junctional extracellular signalling domain with an elevated NE concentration. In the living mouse, optogenetic activation of cardiac SNs innervating the sino-atrial node resulted in an instantaneous chronotropic effect, which shortened the heartbeat interval with single beat precision. Remarkably, inhibition of the optogenetically elicited chronotropic responses required a high dose of propranolol (20-50 mg kg ), suggesting that sympathetic neurotransmission in the heart occurs at a locally elevated NE concentration. Our in vitro and in vivo data suggest that the control of cardiac function by SNs occurs via direct intercellular coupling as a result of the establishment of a specific junctional site.
Extrasystoles lead to several consequences, ranging from uneventful palpitations to lethal ventricular arrhythmias, in the presence of pathologies, such as myocardial ischemia. The role of working versus conducting cardiomyocytes, as well as the tissue requirements (minimal cell number) for the generation of extrasystoles, and the properties leading ectopies to become arrhythmia triggers (topology), in the normal and diseased heart, have not been determined directly in vivo. Here, we used optogenetics in transgenic mice expressing ChannelRhodopsin-2 selectively in either cardiomyocytes or the conduction system to achieve cell typespecific, noninvasive control of heart activity with high spatial and temporal resolution. By combining measurement of optogenetic tissue activation in vivo and epicardial voltage mapping in Langendorffperfused hearts, we demonstrated that focal ectopies require, in the normal mouse heart, the simultaneous depolarization of at least 1,300-1,800 working cardiomyocytes or 90-160 Purkinje fibers. The optogenetic assay identified specific areas in the heart that were highly susceptible to forming extrasystolic foci, and such properties were correlated to the local organization of the Purkinje fiber network, which was imaged in three dimensions using optical projection tomography. Interestingly, during the acute phase of myocardial ischemia, focal ectopies arising from this location, and including both Purkinje fibers and the surrounding working cardiomyocytes, have the highest propensity to trigger sustained arrhythmias. In conclusion, we used cell-specific optogenetics to determine with high spatial resolution and cell type specificity the requirements for the generation of extrasystoles and the factors causing ectopies to be arrhythmia triggers during myocardial ischemia.optogenetics | heart | Purkinje fiber | arrhythmia | cardiac ectopies A berrant heartbeats, caused by the ectopic depolarization of a group of cardiomyocytes, are associated with a wide range of consequences, from the commonly experienced feeling of "palpitation" to the triggering of potentially lethal ventricular arrhythmias in diseased hearts. Physiological conduction of normal heartbeats is orchestrated by the interaction of at least two functionally and anatomically distinct populations of cardiomyocytes: the working cardiomyocytes and the conduction system (i.e., Purkinje fibers at the ventricular level) (1). The electrotonic coupling of myocardial cells protects the heart from abnormal excitation and allows the effect of spontaneous activity in sparse cardiomyocytes to be "sunk" by the surrounding myocardium. As a result, a minimal "critical" number of cardiomyocytes needs to simultaneously depolarize to prevail over such a protective mechanism and generate conducted beats (2-5). When this occurs, the source-sink mismatch (abnormal depolarization current/ myocardial electrotonic sink) is focally overcome, resulting in a premature ventricular contraction (PVC) that, in the presence of arrhythmogenic substrates, may e...
Background: ChR2 is a light-gated ion channel allowing fast non-invasive control of cell membrane potential. Results: We combined bioinformatic modeling and electrophysiology to infer structure/function details on ChR2. Conclusion: We show a complete structural model of the channel, describe the ion-conducting pathway and identify key residues involved in ionic permeability and in photoactivation. Significance: These results expand our knowledge on the structural determinants of ChR2.
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