Heterogeneity of calcium clock functions in dormant, dysrhythmically and rhythmically firing single pacemaker cells isolated from SA node

Kim, Mary S.; Maltsev, Alexander V.; Monfredi, Oliver; Мальцева, Л А; Wirth, Ashley; Florio, Maria Cristina; Tsutsui, Kenta; Riordon, Daniel R.; Parsons, Sean P.; Tagirova, Syevda; Ziman, Bruce D.; Stern, Michael D.; Lakatta, Edward G.

doi:10.1016/j.ceca.2018.07.002

Cited by 46 publications

(99 citation statements)

References 27 publications

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“…We have also recently observed similar non-AP-firing behaviours in a population of enzymatically isolated guinea pig and human SAN cells: these cells have LCRs but do not fire APs [34,35]. A large population of these dormant isolated SAN cells begin to fire spontaneous APs in response to increases in intracellular cAMP [34,36]. Such dormant cell behaviour within SAN tissue can potentially contribute to pacemaker function via (i) having a role in entrainment of oscillators that are heterogeneous both in phase and amplitude to self-organize into synchronized signals that underlie rhythmic impulse that emanate from the SAN; and (ii) their recruitment to fire APs in response to adrenergic receptor activation or AP silencing in response to cholinergic receptor stimulation.…”

Section: Some San Cells Have Lcrs But Do Not Fire Apssupporting

confidence: 55%

“…only a fraction of cells (~25%) embedded in SAN tissue participate in generating AP in any given electrical impulse that emanate from SAN node. We have also recently observed similar non-AP-firing behaviours in a population of enzymatically isolated guinea pig and human SAN cells: these cells have LCRs but do not fire APs [34,35]. A large population of these dormant isolated SAN cells begin to fire spontaneous APs in response to increases in intracellular cAMP [34,36].…”

Section: Some San Cells Have Lcrs But Do Not Fire Apsmentioning

confidence: 69%

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Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Bychkov

Juhaszova

Tsutsui

et al. 2020

Preprint

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The current functional paradigm of sinoatrial node (SAN), the heart's natural pacemaker, postulates the entrainment of full-scale action potentials (APs) at one common frequency and does not involve any subcellular events or subthreshold signals. SAN cells studied in isolation, however, generate subcellular, spontaneous, rhythmic, local Ca 2+ releases (LCRs) and, while each LCR is a small, subthreshold signal, the emergent LCR ensemble signal critically contributes to generation of spontaneous APs and accounts for the heterogeneity of AP firing rates of these cells.We hypothesized that cells embedded in SAN tissue also generate heterogeneous subthreshold LCR signals of different rates and amplitudes and that self-organization of the LCRs within and among cells critically contributes to the ignition of APs that emerge from the SAN to excite the heart. To this end we combined immunolabeling with a novel technique to image microscopic Ca 2+ dynamics, including both LCRs and AP-induced Ca 2+ transients (APCTs) within and among individual pacemaker cells across the entire mouse SAN.Immunolabeling identified a meshwork of HCN4(+)/CX43(-) non-striated cells of different morphologies that extended along the crista terminalis from the superior vena cava to the inferior vena cava, becoming intertwined with a network of striated cells, rich in F-actin and CX43, but devoid of HCN4 immunolabeling. The earliest APCTs within a given pacemaker cycle occurred within a small area of HCN4 meshwork below the superior vena cava, just medial to the crista terminalis. Although subsequent APCT appearance throughout the SAN at low magnification resembled a continuous propagation pattern, higher magnification imaging revealed that APCT appearance at different sites within the SAN was patchy and discontinuous. Both LCR dynamics and APCTs were markedly heterogeneous 3 in amplitudes and frequencies among SAN cells: in some cells, APCT occurrence was preceded by diastolic LCRs occurring in the same cell; other cells did not generate spontaneous APCTs, but had subthreshold LCRs only, which preceded APCT generation by adjacent cells; APCTs of various frequencies were generated steadily or in bursts.In summary, we discovered a novel, microscopic Ca 2+ signalling paradigm of SAN operation that could not be detected with low-resolution, macroscopic tissue methods employed in prior studies: synchronized macroscopic signals within the SA node, including full-scale APs, emerge from heterogeneous microscopic subthreshold Ca 2+ signals. This multiscale, complex process of impulse generation within the SAN resembles the emergence of organized signals from heterogeneous local signals generated within clusters of neurons within neuronal networks.

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Section: Some San Cells Have Lcrs But Do Not Fire Apssupporting

confidence: 55%

Section: Some San Cells Have Lcrs But Do Not Fire Apsmentioning

confidence: 69%

Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Bychkov

Juhaszova

Tsutsui

et al. 2020

Preprint

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“…Though such simplification was beneficial for computational modeling and enabled the development of relatively straightforward biophysical models based on non-linear dynamics and oscillatory theory, it recently became evident that this simple “random collision model” is inadequate to explain the emerging experimental results which highlight microdomain-specific regulation of cardiomyocyte physiology (reviewed in details elsewhere, Zaccolo and Pozzan, 2002 ; Warrier et al, 2007 ; Best and Kamp, 2012 ; Balycheva et al, 2015 ; Vinogradova et al, 2018 ). In the SAN, these include findings on a complex spatial-temporal coupling between the membrane- and Ca 2+ clocks confirmed in various species, including human ( Kim et al, 2018 ; Tsutsui et al, 2018 ), synchronization of spontaneous LCRs between discrete RyR clusters ( Stern et al, 2014 ; Torrente et al, 2016 ), compartmentalized autonomic regulation of pacemaker ion channels which relies on tightly confined cAMP signaling ( Barbuti et al, 2004 ; St Clair et al, 2017 ; Vinogradova et al, 2018 ), as well as microdomain-specific remodeling of ion channels secondary to structural alterations including changes in scaffolding proteins ( Le Scouarnec et al, 2008 ; Alcalay et al, 2013 ; Bryant et al, 2018 ). The emerging results demonstrate that the functioning of the complex pacemaking machinery at the cellular level depends on tightly regulated spatiotemporal signals which are restricted to precise subcellular microdomains and associated with discrete clusters of different ion channels, transporters and regulatory receptors.…”

Section: Introductionmentioning

confidence: 92%

“…These data correlate well with the distribution of transversal-axial tubule system within the SAN: primary pacemakers with the fastest spontaneous beating rate do not have T-tubules, express the smallest I Ca,L which predominantly rely on extratubular LTCCs, and have the highest pacemaker current I f , while subsidiary SAN pacemakers possess a rudimentary T-tubule network which results in a significant increase of I Ca,L and decrease in I f . Subsequently, two recent reports from Lakatta’s group demonstrated in guinea pig ( Kim et al, 2018 ) and human SANCs ( Tsutsui et al, 2018 ) several populations of cells which show rhythmic pacemaking activity, dysrhythmic firing, and no spontaneous activity (i.e., ‘dormant’ cells). Dysrhythmic and dormant SANCs have smaller and desynchronized LCR activity than rhythmic SANCs; however, in response to sympathetic stimulation, all dysrhythmic cells and a third of dormant SANCs increased their LCR activity and developed automaticity resulting in spontaneous electrical beating ( Kim et al, 2018 ).…”

Section: Functional Macro- and Micro-architecture Of The Sanmentioning

confidence: 99%

Functional Microdomains in Heart’s Pacemaker: A Step Beyond Classical Electrophysiology and Remodeling

Lang

Glukhov

2018

Front. Physiol.

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Spontaneous beating of the sinoatrial node (SAN), the primary pacemaker of the heart, is initiated, sustained, and regulated by a complex system that integrates ion channels and transporters on the cell membrane surface (often referred to as “membrane clock”) with subcellular calcium handling machinery (by parity of reasoning referred to as an intracellular “Ca2+ clock”). Stable, rhythmic beating of the SAN is ensured by a rigorous synchronization between these two clocks highlighted in the coupled-clock system concept of SAN timekeeping. The emerging results demonstrate that such synchronization of the complex pacemaking machinery at the cellular level depends on tightly regulated spatiotemporal signals which are restricted to precise sub-cellular microdomains and associated with discrete clusters of different ion channels, transporters, and regulatory receptors. It has recently become evident that within the microdomains, various proteins form an interacting network and work together as a part of a macromolecular signaling complex. These protein–protein interactions are tightly controlled and regulated by a variety of neurohormonal signaling pathways and the diversity of cellular responses achieved with a limited pool of second messengers is made possible through the organization of essential signal components in particular microdomains. In this review, we highlight the emerging understanding of the functionality of distinct subcellular microdomains in SAN myocytes and their functional role in the accumulation and neurohormonal regulation of proteins involved in cardiac pacemaking. We also demonstrate how changes in scaffolding proteins may lead to microdomain-targeted remodeling and regulation of pacemaker proteins contributing to SAN dysfunction.

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“…Likewise, by convention, the AP firing interval (APFI) in isolated SANC in a given "steady state" is usually referred to as "the" APFI, but the presence of beat-to-beat APFI variability (APFIV) indicates that, as in vivo, true "steady state" of AP firing in single SANC in vitro is never achieved (Kim et al, 2018;Li et al, 2016;Monfredi et al, 2014;Monfredi et al, 2013;Opthof, VanGinneken, Bouman, & Jongsma, 1987;Papaioannou, Verkerk, Amin, & de Bakker, 2013;Rocchetti, Malfatto, Lombardi, & Zaza, 2000;Sirenko et al, 2016;Tsutsui et al, 2018;Wilders & Jongsma, 1993;Yaniv, Ahmet, et al, 2014;Zaniboni, Cacciani, & Lux, 2014;Zaza & Lombardi, 2001). Further, the nonlinear relationship of the APFIV to the APFI in SANC in vitro (Zaza & Lombardi, 2001), suggests that mechanisms intrinsic to pacemaker cells are involved in APFIV.…”

Section: Introductionmentioning

confidence: 99%

Ca²⁺and Membrane Potential Transitions During Action Potentials are Self-Similar to Each Other and to Variability of AP Firing Intervals Across the Broad Physiologic Range of AP Intervals During Autonomic Receptor Stimulation

Yang¹,

Morrell²,

Lyashkov

et al. 2020

Preprint

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Variability of heart pacemaker cell action potential (AP) firing intervals (APFI) means that pacemaker mechanisms do not achieve equilibrium during AP firing. We tested whether mechanisms that underlie APFI, in rabbit sinoatrial cells are self-similar within and across the physiologic range of APFIs effected by autonomic receptor stimulation. Principal Component Analyses demonstrated that means and variabilities of APFIs and local Ca2+ releases kinetics, of AP induced Ca2+-transient decay times, of diastolic membrane depolarization rates, of AP repolarization times, of simulated ion current amplitudes, are self-similar across the broad range of APFIs (264 to 786 ms). Further, distributions of both mean APFIs and mean Ca2+ and membrane potential dependent coupled-clock function kinetics manifested similar power law behaviors across the physiologic range of mean APFIs. Thus, self-similar variability of clock functions intrinsic to heart pacemaker cells determines both the mean APFI and its interval variability, and vice versa.

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Heterogeneity of calcium clock functions in dormant, dysrhythmically and rhythmically firing single pacemaker cells isolated from SA node

Cited by 46 publications

References 27 publications

Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Functional Microdomains in Heart’s Pacemaker: A Step Beyond Classical Electrophysiology and Remodeling

Ca²⁺and Membrane Potential Transitions During Action Potentials are Self-Similar to Each Other and to Variability of AP Firing Intervals Across the Broad Physiologic Range of AP Intervals During Autonomic Receptor Stimulation

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Heterogeneity of calcium clock functions in dormant, dysrhythmically and rhythmically firing single pacemaker cells isolated from SA node

Cited by 46 publications

References 27 publications

Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Synchronized cardiac impulses emerge from multi-scale, heterogeneous local calcium signals within and among cells of heart pacemaker tissue

Functional Microdomains in Heart’s Pacemaker: A Step Beyond Classical Electrophysiology and Remodeling

Ca2+and Membrane Potential Transitions During Action Potentials are Self-Similar to Each Other and to Variability of AP Firing Intervals Across the Broad Physiologic Range of AP Intervals During Autonomic Receptor Stimulation

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Ca²⁺and Membrane Potential Transitions During Action Potentials are Self-Similar to Each Other and to Variability of AP Firing Intervals Across the Broad Physiologic Range of AP Intervals During Autonomic Receptor Stimulation