Intrinsic and extrinsic innervation of the heart in zebrafish (<scp>D</scp>anio rerio)

Stoyek, Matthew R.; Croll, Roger P.; Smith, Frank M.

doi:10.1002/cne.23764

Cited by 59 publications

(86 citation statements)

References 79 publications

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“…In a previous study (57), we described the basic structure of the ICNS in zebrafish, which is consistent with that of humans and other mammalian models (28,33,37,43,44). The isolated zebrafish heart thus has technical advantages that may be exploited to better understand the role of the ICNS in modulating chronotropy (57).…”

Section: New and Noteworthysupporting

confidence: 71%

“…In zebrafish and mammalian species, HCN4 channels contribute a major portion of the diastolic depolarizing current in cardiac pacemaker cells (28,33,37,43,44). Immunohistochemical evi-dence also shows that juxta-pacemaker terminals contain the neurotransmitters acetylcholine (ACh; parasympathetic, cardio-inhibitory) and norepinephrine (NE; sympathetic, cardioexcitatory), providing the neuroeffector substrate for bidrectional autonomic control of pacemaker rate (57). At the atrioventricular region (AVR) a subpopulation of HCN4-expressing cells has been identified (57).…”

Section: New and Noteworthymentioning

confidence: 99%

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Zebrafish heart as a model to study the integrative autonomic control of pacemaker function

Stoyek

Quinn

Croll

et al. 2016

American Journal of Physiology-Heart and Circulatory Physiology

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The cardiac pacemaker sets the heart's primary rate, with pacemaker discharge controlled by the autonomic nervous system through intracardiac ganglia. A fundamental issue in understanding the relationship between neural activity and cardiac chronotropy is the identification of neuronal populations that control pacemaker cells. To date, most studies of neurocardiac control have been done in mammalian species, where neurons are embedded in and distributed throughout the heart, so they are largely inaccessible for whole-organ, integrative studies. Here, we establish the isolated, innervated zebrafish heart as a novel alternative model for studies of autonomic control of heart rate. Stimulation of individual cardiac vagosympathetic nerve trunks evoked bradycardia (parasympathetic activation) and tachycardia (sympathetic activation). Simultaneous stimulation of both vagosympathetic nerve trunks evoked a summative effect. Effects of nerve stimulation were mimicked by direct application of cholinergic and adrenergic agents. Optical mapping of electrical activity confirmed the sinoatrial region as the site of origin of normal pacemaker activity and identified a secondary pacemaker in the atrioventricular region. Strong vagosympathetic nerve stimulation resulted in a shift in the origin of initial excitation from the sinoatrial pacemaker to the atrioventricular pacemaker. Putative pacemaker cells in the sinoatrial and atrioventricular regions expressed adrenergic β2 and cholinergic muscarinic type 2 receptors. Collectively, we have demonstrated that the zebrafish heart contains the accepted hallmarks of vertebrate cardiac control, establishing this preparation as a viable model for studies of integrative physiological control of cardiac function by intracardiac neurons.

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Section: New and Noteworthysupporting

confidence: 71%

Section: New and Noteworthymentioning

confidence: 99%

Zebrafish heart as a model to study the integrative autonomic control of pacemaker function

Stoyek

Quinn

Croll

et al. 2016

American Journal of Physiology-Heart and Circulatory Physiology

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“…These results are similar to those of a previous study utilizing scanning electron microscopy [Sakata et al, 2001]. To observe the innervation of the taste buds, we performed double immunohistochemistry with anti-calretinin and anti-acetylated tubulin antibodies; the later marks nerve fibers [Hagströme and Olsson, 2010;Stoyek et al, 2015]. Acetylated tubulinir nerve fibers formed polygonal networks bellow the barbel epithelium ( Fig.…”

Section: Distribution Of the Taste Buds And Their Innervationsupporting

confidence: 71%

Distribution, Innervation, and Cellular Organization of Taste Buds in the Sea Catfish, Plotosus japonicus

Nakamura

Matsuyama²,

Kirino³

et al. 2017

Brain Behav Evol

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The gustatory system of the sea catfish Plotosus japonicus, like that of other catfishes, is highly developed. To clarify the details of the morphology of the peripheral gustatory system of Plotosus, we used whole-mount immunohistochemistry to investigate the distribution and innervation of the taste buds within multiple organs including the barbels, oropharyngeal cavity, fins (pectoral, dorsal, and caudal), and trunk. Labeled taste buds could be observed in all the organs examined. The density of the taste buds was higher along the leading edges of the barbels and fins; this likely increases the chance of detecting food. In all the fins, the taste buds were distributed in linear arrays parallel to the fin rays. Labeling of nerve fibers by anti-acetylated tubulin antibody showed that the taste buds within each sensory field are innervated in different ways. In the barbels, large nerve bundles run along the length of the organ, with fascicles branching off to innervate polygonally organized groups of taste buds. In the fins, nerve bundles run along the axis of fin rays to innervate taste buds lying in a line. In each case, small fascicles of fibers branch from large bundles and terminate within the basal portions of the taste buds. Serotonin immunohistochemistry demonstrated that most of the taste buds in all the organs examined contained disk-shaped serotonin-immunopositive cells in their basal region. This indicates a similar organization of the taste buds, in terms of the existence of serotonin-immunopositive basal cells, across the different sensory fields in this species.

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“…However, there is no direct evidence as yet for the presence of HO-1 in the pacemaker cells of the mammalian heart. In zebrafish, the cardiac pacemaker cells are located at the sinoatrial boundary (Tessadori et al, 2012;Stoyek et al, 2015). In this study, we found evidence that HO-1 is located in the presumptive pacemaker cells of the developing zebrafish heart.…”

Section: Presence Of Ho-1 In the Hearts Of Fishsupporting

confidence: 51%

Evidence for a role of heme oxygenase-1 in the control of cardiac function in zebrafish (Danio rerio) larvae exposed to hypoxia

Tzaneva

Perry

2016

Journal of Experimental Biology

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Carbon monoxide (CO) is a gaseous neurotransmitter produced from the breakdown of heme via heme oxygenase-1 (HO-1; hypoxiainducible isoform) and heme oxygenase-2 (HO-2; constitutively expressed isoform). In mammals, CO is involved in modulating cardiac function. The role of the HO-1/CO system in the control of heart function in fish, however, is unknown and investigating its physiological function in lower vertebrates will provide a better understanding of the evolution of this regulatory mechanism. We explored the role of the HO-1/CO system in larval zebrafish (Danio rerio) in vivo by investigating the impact of translational gene knockdown of HO-1 on cardiac function. Immunohistochemistry revealed the presence of HO-1 in the pacemaker cells of the heart at 4 days post-fertilization and thus the potential for CO production at these sites. Sham-treated zebrafish larvae (experiencing normal levels of HO-1) significantly increased heart rate ( f H ) when exposed to hypoxia (Pw O2 =30 mmHg). Zebrafish larvae lacking HO-1 expression after morpholino knockdown (morphants) exhibited significantly higher f H under normoxic (but not hypoxic) conditions when compared with sham-treaded fish. The increased f H in HO-1 morphants was rescued ( f H was restored to control levels) after treatment of larvae with a CO-releasing molecule (40 µmol l −1 CORM). The HO-1-deficient larvae developed significantly larger ventricles and when exposed to hypoxia they displayed higher cardiac output ( _ Q) and stroke volume (SV). These results suggest that under hypoxic conditions, HO-1 regulates _ Q and SV presumably via the production of CO. Overall, this study provides a better understanding of the role of the HO-1/CO system in controlling heart function in lower vertebrates. We demonstrate for the first time the ability for CO to be produced in presumptive pacemaker cells of the heart where it plays an inhibitory role in setting the resting cardiac frequency.

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Intrinsic and extrinsic innervation of the heart in zebrafish (Danio rerio)

Cited by 59 publications

References 79 publications

Zebrafish heart as a model to study the integrative autonomic control of pacemaker function

Zebrafish heart as a model to study the integrative autonomic control of pacemaker function

Distribution, Innervation, and Cellular Organization of Taste Buds in the Sea Catfish, <b><i>Plotosus japonicus</i></b>

Evidence for a role of heme oxygenase-1 in the control of cardiac function in zebrafish (Danio rerio) larvae exposed to hypoxia

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