Laxative Effects of Phlorotannins Derived from Ecklonia cava on Loperamide-Induced Constipation in SD Rats

This study investigated the laxative effects of phlorotannins (Pt) derived from Ecklonia cava (E. cave) on chronic constipation by evaluating alterations in stool parameters, gastrointestinal motility, histopathological structure, mucin secretion, gastrointestinal hormones, muscarinic cholinergic regulation, and fecal microbiota in SD rats with loperamide (Lop)-induced constipation subjected to Pt treatment. Stool-related parameters (including stool number, weight, and water contents), gastrointestinal motility, and length of intestine were significantly enhanced in the Lop+Pt-treated group as compared to the Lop+Vehicle-treated group. A similar recovery was detected in the histopathological and cytological structure of the mid-colon of Lop+Pt-treated rats, although the level of mucin secretion remained constant. Moreover, rats with Lop-induced constipation subjected to Pt treatment showed significant improvements in water channel expression, gastrointestinal hormone secretions, and expression of muscarinic acetylcholine receptors M2/M3 (mAChRs M2/M3) and their mediators of muscarinic cholinergic regulation. Furthermore, the Lop+Pt-treated group showed a significant recovery of Bifidobacteriaceae, Muribaculaceae, Clostridiaceae, and Eubacteriaceae families in fecal microbiota. Taken together, these results provide the first evidence that exposure of SD rats with Lop-induced constipation to Pt improves the constipation phenotype through the regulation of membrane water channel expression, GI hormones, the mAChR signaling pathway, and fecal microbiota.

The role of N-cholinoreceptors in somatovisceral intersystemic interactions in early rat ontogenesis

Interaction of slow-wave rhythmic components of cardiac, respiratory and motor activities was analyzed in non-narcotized of newborn 1-day-old (P1) and 16-day-old (P16) Wistar rat pups under normal and impaired cholinergic regulation. Functional activity of these three systems is rhythmic, and coordination of their functioning is an important element of the mechanism of adaptive rearrangements under changing factors of the external and internal environment. The acetylcholinesterase inhibitor physostigmine (eserine) was used to increase the level of endogenous acetylcholine and enhance cholinergic effects. To reveal the role of N-cholinoreceptors in intersystemic somatovisceral interactions (ISI), we performed blockade of this receptor type with benzohexonium. Administration of physostigmine leads to the development of a number of pathological reactions and a decrease in the level of ISI in all ranges of modulating rhythms in rats of both ages. ISI in younger rats appear to be more resistant to changes in the level of cholinergic activation. Blockade of N-cholinoreceptors causes inhibition of ISI at P1 and partially to their potentialization at P16. The activation of cholinoreactive structures, which occurred against the background of cholinoreceptors blockade, reduces the pathological effects of physostigmine in animals of both ages, but at the same time leads to an attenuation of ISI. This weakening is more pronounced in 16-day old rats, which may indicate the formation of the definitive level of cholinergic regulation in the first weeks of postnatal ontogenesis.

Cholinergic regulation of cardiac pacemaker activity by L-type Cav1.3 channels

Funding Acknowledgements Type of funding sources: Foundation. Main funding source(s): Fondation Recherche Médicale Introduction The cholinergic regulation of heart rate (HR) is mediated by acetylcholine (ACh)-dependent activation of M2-receptors (M2R). Activated M2R promote release of the βγ-subunit of G-proteins to directly gate GIRK1/4 channels (underlying the cardiac IKACh current), while αi-subunits inhibit adenylate cyclase (AC) activity. AC inhibition reduces the intracellular concentration of cAMP, decreasing the activity of ion channels involved in pacemaking, including "funny" f-(HCN4) and L-type Cav1.3 calcium channels. Purpose To determine the role of L-type Cav1.3 channels in cholinergic regulation of heart rate. Methods We recorded the frequency of activation and position of pacemaker leading site in ex vivo sinus nodes and the HR of isolated Langendorff perfused hearts of mice at baseline or during ACh perfusion. We used control wild type (WT) mice, and five genetically modified mouse models: Cav1.3 knockout (KO, ablated Cav1.3-mediated L-type current), GIRK4KO (ablated IKACh current), HCN4-CNBD (selective deletion of cAMP-dependent regulation of HCN4), GIRK4KO/HCN4-CNBD and GIRK4KO/Cav1.3KO. We performed in vivo telemetric recordings of heart rate (HR) in WT and GIRK4KO/Cav1.3KO animals. Results Data from optical mapping experiments showed that, under basal conditions, perfusion of 3 μM ACh significantly reduced the frequency of action potentials in WT (44%), HCN4-CNBD (38%), Cav1.3KO (65%) and GIRK4KO (8%) isolated mouse sinus node tissues. ACh application did not significantly affect the frequency of action potentials recorded in tissue from GIRK4KO/HCN4-CNBD and GIRK4KO/Cav1.3KO animals. Furthermore, in all sinus nodes tested, regardless of genotype, ACh shifted the pacemaker leading site from its normal position by at least 0.7 mm. Upon stimulation of the β-adrenergic pathway by Isoproterenol, to reproduce conditions of accentuated antagonism, 3µM ACh reduced HR in isolated hearts from WT (43.8%), HCN4-CNBD (38.7%), Cav1.3KO (25,4%), GIRK4KO (16.9%) and GIRK4KO/HCN4-CNBD (16.4%) mice. No significant HR reduction was recorded in hearts from GIRK4KO/Cav1.3KO animals. In vivo data indicate that HR reduction induced by combined injection of Hexamethonium ( a Nicotinic acetylcholine receptor blocker) with Carbamoylcholine (CCH, M2 receptor agonist) or with 2-Chloro-N6-Cyclopentyladenosine (CCPA, A1 receptor agonist) is higher in WT than in GIRK4KO/Cav1.3KO animals (68% vs 48% CCH, and 79% vs 62% CCPA, respectively). Conclusion Our data indicate that L-type Cav1.3 channels are involved in cholinergic regulation of heart rate in mice. In addition, when the intracellular concentration of cAMP is elevated (i.e. under conditions of accentuated antagonism), cholinergic regulation of sinus node pacemaking is reliant on Cav1.3 and KACh channels.

Antioxidant activity and laxative effects of tannin-enriched extract of Ecklonia cava in loperamide-induced constipation of SD rats

To investigate the role of tannin-enriched extracts of Ecklonia cava (TEE) on the regulation of oxidative balance and laxative activity in chronic constipation, we investigated alterations after exposure to TEE, on constipation phenotypes, muscarinic cholinergic regulation, and oxidative stress responses in the transverse colons of SD rats with loperamide (Lop)-induced constipation. This extract contains high levels of total condensed tannin content (326.5 mg/g), and exhibited high inhibitory activity against 2,2-diphenyl-1-picrylhydrazyl (DPPH) radicals. TEE treatment induced significant improvements in reactive oxygen species (ROS) production, superoxide dismutase (SOD) expression and nuclear factor erythroid 2-related factor 2 (Nrf2) phosphorylation in primary smooth muscles of rat intestine cells (pRISMCs) and transverse colon of constipation model. Also, Lop+TEE treated groups showed alleviated outcomes for the following: most stool parameters, gastrointestinal transit, and intestine length were remarkably recovered; a similar recovery pattern was observed in the histopathological structure, mucin secretion, water channel expression and gastrointestinal hormones secretion in the transverse colon; expressions of muscarinic acetylcholine receptors M2/M3 (mAChR M2/M3) and their mediators on muscarinic cholinergic regulation were significantly recovered. Taken together, these results provide the first evidence that TEE stimulates oxidative stress modulation and muscarinic cholinergic regulation when exerting its laxative effects in chronic constipation models.

Cholinergic regulation of cardiac pacemaker activity by l-type cav1.3 channels

Introduction The cholinergic regulation of heart rate (HR) is mediated by acetylcholine (ACh)-dependent activation of M2-receptors (M2R). Activated M2R promote release of the βγ-subunit of G-proteins to directly gate GIRK1/4 channels (underlying the cardiac IKACh current), while αi-subunits inhibit adenylate cyclase (AC) activity. AC inhibition reduces the intracellular concentration of cAMP, decreasing the activity of ion channels involved in pacemaking, including “funny” f-(HCN4) and L-type Cav1.3 calcium channels. Purpose To determine the importance of L-type Cav1.3 channels in the cholinergic regulation of heart rate. Methods We recorded the frequency and the position of the pacemaker leading site in ex vivo sinus nodes and the HR of isolated Langendorff perfused hearts of mice in control or during ACh perfusion. We used control wild type (WT) mice, and five genetically modified mouse models: Cav1.3 knockout (KO, ablated Cav1.3-mediated L-type current), GIRK4KO (ablated IKACh current), HCN4-CNBD (selective deletion of cAMP-dependent regulation of HCN4), GIRK4KO/HCN4-CNBD and GIRK4KO/Cav1.3KO. Results Data from optical mapping experiments showed that, under basal conditions, perfusion of 3 μM ACh significantly reduced the frequency of action potentials in WT (44%), HCN4-CNBD (38%), Cav1.3KO (65%) and GIRK4KO (8%) isolated mouse sinus node tissues. ACh application did not significantly affect the frequency of action potentials recorded in tissue from GIRK4KO/HCN4-CNBD and GIRK4KO/Cav1.3KO animals. Furthermore, in all the sinus node tissues tested, regardless of the genotypes, ACh shifted the pacemaker leading site from its normal position by at least 0.7 mm. Upon stimulation of the β-adrenergic pathway by Isoproterenol, to reproduce conditions of accentuated antagonism, 3μM ACh reduced HR in isolated hearts from WT (43.8%), HCN4-CNBD (38.7%), Cav1.3KO (25,4%), GIRK4KO (16.9%) and GIRK4KO/HCN4-CNBD (16.4%) mice. No significant HR reduction was recorded in hearts from GIRK4KO/Cav1.3KO animals. Conclusion Our data indicate that L-type Cav1.3 channels are involved in cholinergic regulation of heart rate in mice. In addition, when the intracellular concentration of cAMP is elevated (i.e. under conditions of accentuated antagonism), the cholinergic regulation of sinus node pacemaking is predominantly ensured by Cav1.3 and KACh channels. Funding Acknowledgement Type of funding source: Foundation. Main funding source(s): “Fondation pour la recherche medicale” FRM