The Duodenal Mucosal Bicarbonate Secretion : Role of Melatonin in Neurohumoral Control and Cellular Signaling

Sjöblom, Markus

January 2003

<p>The duodenal lumen is exposed to aggressive factors with a high potential to cause damage to the mucosa. Bicarbonate secretion by the duodenal mucosa is accepted as the primary important defense mechanism against the hydrochloric acid intermittently expelled from the stomach.</p><p>The present thesis concerns the influence of the central nervous system and the effects of the hormone melatonin on bicarbonate secretion in anesthetized rats in vivo. Effects of melatonin on intracellular calcium signaling by duodenal enterocyte in vitro were examined in tissues of both human and rat origin. The main findings were as follows:</p><p>Melatonin is a potent stimulant of duodenal mucosal bicarbonate secretion and also seems to be involved in the acid-induced stimulation of the secretion. Stimulation elicited in the central nervous system by the α1-adrenoceptor agonist phenylephrine induced release of melatonin from the intestinal mucosa and a four-fold increase in alkaline secretion. The melatonin antagonist luzindole abolished the duodenal secretory response to administered melatonin and to central nervous phenylephrine but did not influence the release of intestinal melatonin. Central nervous stimulation was also abolished by synchronous ligation of the vagal trunks and the sympathetic chains at the sub-laryngeal level. </p><p>Melatonin induced release of calcium from intracellular stores and also influx of extracellular calcium in isolated duodenal enterocytes. Enterocytes in clusters functioned as a syncytium.</p><p>Overnight fasting rapidly and profoundly down-regulated the responses to the duodenal secretagogues orexin-A and bethanechol but not those to melatonin or vasoactive intestinal polypeptide.</p><p>In conclusion, the results strongly suggest that intestinal melatonin plays an important role in central nervous elicited stimulation of duodenal mucosal bicarbonate secretion. Sensitivity of this alkaline secretion to some peripheral stimulators markedly depends on the feeding status.</p>

Physiology

alkaline secretion

central nervous system

duodenal enterocyte

duodenal ulcer

duodenum

enterochromaffin cell

human

intraarterial

intracellular calcium

intracerebroventricular

melatonin

rat

vagal nerve

Fysiologi

Physiology

Fysiologi

The Duodenal Mucosal Bicarbonate Secretion : Role of Melatonin in Neurohumoral Control and Cellular Signaling

Sjöblom, Markus

January 2003

The duodenal lumen is exposed to aggressive factors with a high potential to cause damage to the mucosa. Bicarbonate secretion by the duodenal mucosa is accepted as the primary important defense mechanism against the hydrochloric acid intermittently expelled from the stomach. The present thesis concerns the influence of the central nervous system and the effects of the hormone melatonin on bicarbonate secretion in anesthetized rats in vivo. Effects of melatonin on intracellular calcium signaling by duodenal enterocyte in vitro were examined in tissues of both human and rat origin. The main findings were as follows: Melatonin is a potent stimulant of duodenal mucosal bicarbonate secretion and also seems to be involved in the acid-induced stimulation of the secretion. Stimulation elicited in the central nervous system by the α1-adrenoceptor agonist phenylephrine induced release of melatonin from the intestinal mucosa and a four-fold increase in alkaline secretion. The melatonin antagonist luzindole abolished the duodenal secretory response to administered melatonin and to central nervous phenylephrine but did not influence the release of intestinal melatonin. Central nervous stimulation was also abolished by synchronous ligation of the vagal trunks and the sympathetic chains at the sub-laryngeal level. Melatonin induced release of calcium from intracellular stores and also influx of extracellular calcium in isolated duodenal enterocytes. Enterocytes in clusters functioned as a syncytium. Overnight fasting rapidly and profoundly down-regulated the responses to the duodenal secretagogues orexin-A and bethanechol but not those to melatonin or vasoactive intestinal polypeptide. In conclusion, the results strongly suggest that intestinal melatonin plays an important role in central nervous elicited stimulation of duodenal mucosal bicarbonate secretion. Sensitivity of this alkaline secretion to some peripheral stimulators markedly depends on the feeding status.

Physiology

alkaline secretion

central nervous system

duodenal enterocyte

duodenal ulcer

duodenum

enterochromaffin cell

human

intraarterial

intracellular calcium

intracerebroventricular

melatonin

rat

vagal nerve

Fysiologi

Physiology

Fysiologi

Effects of Orexins, Guanylins and Feeding on Duodenal Bicarbonate Secretion and Enterocyte Intracellular Signaling

Bengtsson, Magnus Wilhelm

January 2008

<p>The duodenal epithelium secretes bicarbonate ions and this is regarded as the primary defence mechanism against the acid discharged from the stomach. For an efficient protection, the duodenum must also function as a sensory organ identifying luminal factors. Enteroendocrine cells are well-established intestinal “taste” cells that express signaling peptides such as orexins and guanylins. Luminal factors affect the release of these peptides, which may modulate the activity of nearby epithelial and neural cells.</p><p>The present thesis considers the effects of orexins and guanylins on duodenal bicarbonate secretion. The duodenal secretory response to the peptides was examined in anaesthetised rats <i>in situ</i> and the effects of orexin-A on intracellular calcium signaling by human as well as rat duodenal enterocytes were studied <i>in vitro</i>.</p><p>Orexin-A, guanylin and uroguanylin were all stimulants of bicarbonate secretion. The stimulatory effect of orexin-A was inhibited by the OX₁-receptor selective antagonist SB-334867. The muscarinic antagonist atropine on the other hand, did not affect the orexin-A-induced secretion, excluding involvement of muscarinic receptors. Orexin-A induced calcium signaling in isolated duodenocytes suggesting a direct effect at these cells. Interestingly, orexin-induced secretion and calcium signaling as well as mucosal orexin-receptor mRNA and OX₁-receptor protein levels were all substantially downregulated in overnight fasted rats compared with animals with continuous access to food. Further, secretion induced by Orexin-A was shown to be dependent on an extended period of glucose priming.</p><p>The uroguanylin-induced bicarbonate secretion was reduced by atropine suggesting involvement of muscarinic receptors. The melatonin receptor antagonist luzindole attenuated the secretory response to intra-arterially administered guanylins but had no effect on secretion when the guanylins were given luminally. </p><p>In conclusion, the results suggest that orexin-A as well as guanylins may participate in the regulation of duodenal bicarbonate secretion. Further, the duodenal orexin system is dependent on the feeding status of the animals.</p>

Physiology

alkaline secretion

carbohydrates

central nervous system

cholinergic stimulation

duodenum

enteric nervous system

enterochromaffin cell

fasting

feeding

glucose

guanylyl cyclase C

humans

hypocretin

intra-arterial

in situ

intracerebroventricular

luminal acid

luzindole

orexin-B

SB-334867

Fysiologi

Effects of Orexins, Guanylins and Feeding on Duodenal Bicarbonate Secretion and Enterocyte Intracellular Signaling

Bengtsson, Magnus Wilhelm

January 2008

The duodenal epithelium secretes bicarbonate ions and this is regarded as the primary defence mechanism against the acid discharged from the stomach. For an efficient protection, the duodenum must also function as a sensory organ identifying luminal factors. Enteroendocrine cells are well-established intestinal “taste” cells that express signaling peptides such as orexins and guanylins. Luminal factors affect the release of these peptides, which may modulate the activity of nearby epithelial and neural cells. The present thesis considers the effects of orexins and guanylins on duodenal bicarbonate secretion. The duodenal secretory response to the peptides was examined in anaesthetised rats in situ and the effects of orexin-A on intracellular calcium signaling by human as well as rat duodenal enterocytes were studied in vitro. Orexin-A, guanylin and uroguanylin were all stimulants of bicarbonate secretion. The stimulatory effect of orexin-A was inhibited by the OX1-receptor selective antagonist SB-334867. The muscarinic antagonist atropine on the other hand, did not affect the orexin-A-induced secretion, excluding involvement of muscarinic receptors. Orexin-A induced calcium signaling in isolated duodenocytes suggesting a direct effect at these cells. Interestingly, orexin-induced secretion and calcium signaling as well as mucosal orexin-receptor mRNA and OX1-receptor protein levels were all substantially downregulated in overnight fasted rats compared with animals with continuous access to food. Further, secretion induced by Orexin-A was shown to be dependent on an extended period of glucose priming. The uroguanylin-induced bicarbonate secretion was reduced by atropine suggesting involvement of muscarinic receptors. The melatonin receptor antagonist luzindole attenuated the secretory response to intra-arterially administered guanylins but had no effect on secretion when the guanylins were given luminally. In conclusion, the results suggest that orexin-A as well as guanylins may participate in the regulation of duodenal bicarbonate secretion. Further, the duodenal orexin system is dependent on the feeding status of the animals.

Physiology

alkaline secretion

carbohydrates

central nervous system

cholinergic stimulation

duodenum

enteric nervous system

enterochromaffin cell

fasting

feeding

glucose

guanylyl cyclase C

humans

hypocretin

intra-arterial

in situ

intracerebroventricular

luminal acid

luzindole

orexin-B

SB-334867

Fysiologi