Induction of Na-K-ATPase in plasma membranes to rat cecum mucosa by diet: time course and kinetics

Oat β-glucan increased ATPases activity and energy charge in small intestine of rats

Dietary oat or oat products may potentially help to fight against high risk of cardiovascular diseases and β-glucan in oat was considered as a central player. The present study aimed to investigate the effects of dietary oat whole meal or β-glucan on insulin sensitivity and energy metabolism of rats. Rats were fed with control diet, oat whole meal based diet, or control diet with supplemented β-glucan for 4 weeks. Oat whole meal and β-glucan increased insulin sensitivity index. Interestingly, supplementation of oat whole meal or β-glucan induced increases in intestinal Na(+)K(+)-ATPase activity, Ca(2+)Mg(2+)-ATPase activity, and energy charge, particularly in the distal part of small intestine (ileum). Furthermore, amounts of Bifidobacterium and Lactobacillus in colon contents were elevated by oat whole meal or β-glucan. These findings provide an insight into that β-glucan increased insulin sensitivity and benefited intestinal health.

Sennoside-induced secretion is not caused by changes in mucosal permeability or Na+,K(+)-ATPase activity

The effect of sennosides (50 mg kg-1) on the rat colon in-situ was studied 6 h after oral treatment when the laxative effect was maximal. In a second experiment, rhein (4 x 10(-3) M), an active sennoside metabolite, was administered into the lumen of the colon for 1 h. Both sennosides and rhein reduced net H2O and Na+ absorption or reversed it to net secretion. Paracellular permeability, as measured using erythritol as a small marker molecule, was increased 2- to 3-fold; permeability to a large molecule, PEG 1000, was unchanged. The activity of Na+,K(+)-ATPase in the colon mucosa was not affected. There was no damage of the epithelial cells as determined by lactic acid dehydrogenase release. These results indicate that neither inhibition of Na+,K(+)-ATPase nor damage of the colon epithelium are involved in the secretory effect of sennosides or rhein. The increased paracellular permeability of small molecules fits into the concept of stimulation of active chloride secretion by sennosides, which is electrochemically and osmotically balanced by an increase in Na+ and H2O flow via the paracellular pathway.

The influence of high salt intake on intestinal Na,K-ATPase in Wistar and Dahl rats

The Na,K-ATPase of intestinal mucosa was compared in Wistar (W), salt-sensitive (DS) and salt-resistant (DR) Dahl rats fed a low-salt (LS) and high-salt (HS) diet. ATPase activity and the kinetics of its activation by Na+ were determined in three intestinal segments (jejunum, ileum, distal colon). There were demonstrated only small differences in the affinity for Na+ among the strains studied but we found a considerable profile of Na,K-ATPase activity along the intestine in all strains; the activity was higher in jejunum and lower in ileum and distal colon. Chronic salt loading decreased the affinity of Na,K-ATPase for Na+ but had no effect on Vmax. The changes in salt intake were accompanied by different response of plasma aldosterone in particular strains. According to the stimulation of aldosterone level by LS diet the sensitivity of the strains was DR > W > DS. HS diet suppressed aldosterone level to similar values in all strains. The data indicate that the kinetics of intestinal Na,K-ATPase and its response to HS intake is independent of the genotype of the rats.

Regional distribution of Na-K-ATPase specific activity in the large intestine of the rat and man

Segmental heterogeneity of colonic electrolyte transport has been demonstrated in rat and man. We determined whether this is reflected by regional differences in Na-K-ATPase activity. In rats, Na-K-ATPase specific activity was significantly lower in the caecum than in the proximal colon, distal colon, and rectum. In man, biopsy specimens of macroscopically intact mucosa in 26 subjects showed no difference in Na-K-ATPase specific activity along the colon axis. We conclude that Na-K-ATPase distribution may contribute to electrolyte transport differences between rat caecum and colon but not between colonic segments in either rat or man. In an additional series of 11 patients with proximal intestinal resections colonic Na-K-ATPase specific activity was slightly but significantly higher than in controls, possibly representing an adaptive process.

Adaptation of electrolyte transport in rat large intestine after proximal resection. I. Cecum and colon after 60% jejunoilectomy

Electrolyte transport was studied in rat cecum and colon adapting to 60% resection of the small intestine. Four weeks after surgery, the absorbing gross surface area, dry and wet weight, net absorption in vivo of sodium, chloride and volume, net potassium secretion, transmural electrical potential difference and mucosal Na-K-ATPase specific activity were determined. In the cecum, all tissue mass parameters were increased compared to sham-operated controls. Net transport was stimulated per organ but not per unit mass, and potential difference and Na-K-ATPase remained unaffected. In the colon, surface area and wet weight increased slightly while dry weight and electrolyte transport were not influenced. Thus, by enlargement without a change in cell function, the cecum but not the colon contributes to electrolyte homoeostasis after 60% jejunoilectomy in the rat. Na-K-ATPase specific activity and electrical potential difference were higher in the colon than the cecum, suggesting segmental heterogeneity of the larger bowel with respect to Na-K-ATPase-linked active sodium absorption.

Inhibition by loperamide of deoxycholic acid induced intestinal secretion

The effect of loperamide on deoxycholic acid (DOC)-induced secretion was studied in ligated loops of the rat jejunum and colon in vivo. In controls, loperamide slightly augmented fluid absorption. 3 mmol DOC caused net fluid secretion. Loperamide reduced this secretion in the colon and reversed it to absorption in the jejunum. Na-K-ATPase specific activity and cAMP levels were measured in the jejunum, and [14C]erythritol clearance as an index of mucosal permeability in the colon. In the jejunum this opiate analogue affected neither basal or DOC-depressed Na-K-ATPase, nor mucosal cAMP. In the colon it reduced a large increase of the erythritol clearance caused by DOC. It is suggested that loperamide interferes with DOC-induced intestinal secretion in part by lowering mucosal permeability.

Effect of diphenolic laxatives on Na+-K+-activated ATPase and cyclic nucleotide content of rat colon mucosa in vivo

1. The effect of bisacodyl and oxyphenisation on the Na+-K+- and Mg2+-activated ATPase and on the mucosa levels of cAMP and cGMP was investigated in transporting ligated loops of the rat colon in acute studies and in chronic feeding experiments 2. The specific activity of the Na+-K+-ATPase was lowered in both types of experiments, concomitantly with a reduction in net sodium absorption. The specific activity of the Mg2+-activated ATPase was unaffected. 3. The cAMP content per mg protein was elevated and the cGMP content decreased in the acute experiments in which the effect on transport was most marked. The content of cyclic nucleotides returned to normal within 2 h whereas absorption, Na+-K+-ATPase specific activity and the mucosal potential difference were still significantly depressed at that time. In chronic experiments with bisacodyl, cAMP was not affected and cGMP was increased in colon loops exhibiting reduced absorption. 4. The results indicate that the inhibition of the Na+-K+-activated ATPase by diphenolic laxatives may play a role in the inhibition of intestinal fluid absorption caused by these compounds. The increase of cAMP in acute experiments could point to a cAMP-mediated stimulation of secretory processes under this condition.

Decreased cyclic GMP levels in rat cecum mucosa during adaptive stimulation of Na-K-ATPase

In rat cecal mucosa, Na-K-ATPase specific activity and sodium and fluid absorption were increased by giving polyethylene glycol administration with the drinking water. Whereas cyclic AMP levels were unchanged, cyclic GMP was reduced by about 50%. This finding suggests a regulatory role of cyclic GMP in intestinal sodium and fluid absorption.

Nucleic acid and protein content of rat cecum mucosa in dietary adaptation-growth by cellular hyperplasia

The deoxyribonucleic acid (DNA), ribonucleic acid (RNA) and protein content of the isolated cecum mucosa was determined in control rats and rats with adaptive cecum growth induced by dietary polyethylene glycol. Feeding the polymer resulted in an increase in the total amount of mucosal nucleic acids and protein which was statistically significant after 2-4 days and reached twice the control value after 2 months. During growth, the protein/DNA, protein/RNA and RNA/DNA ratios remained unaltered, indicating hyperplasia and not hypertrophy of the epithelial cells. The water content of the mucosa increased from 75 to 81% during adaptation, possibly related to the stimulation in active sodium transport reported earlier. Recalculation of parallel Na-K-ATPase data on the basis of DNA demonstrated a doubling of Na-K-ATPase activity per mg DNA in the fully adapted cell.