Sawsan Ibrahim Kreydiyyeh

Diuretic effect and mechanism of action of parsley

This work provides substantial evidence for the advocated diuretic effect of parsley in folk medicine and determines the mechanism of action of the herb. Rats offered an aqueous parsley seed extract to drink, eliminated a significantly larger volume of urine per 24 h as compared to when they were drinking water. These findings were supported by the results of other experiments using an in situ kidney perfusion technique which demonstrated also a significant increase in urine flow rate with parsley seed extract. This effect was still apparent in presence of amiloride, furosemide and in the absence of sodium, but not in the absence of potassium, suggesting that the diuretic effect of the herb is mediated through an increase in K+ retention in the lumen. Parsley extract, was shown on the other hand, to reduce the activity of the Na+-K+ ATPase in both cortex and medulla homogenates. Such an inhibition would decrease apical cellular Na+ reabsorption, lower K+ secretion, increase K+ concentration in the intercellular space and consequently would inhibit passive K+ influx across the tight junctions. The mechanism of action of parsley seems to be mediated through an inhibition of the Na+-K+ pump that would lead to a reduction in Na+ and K+ reabsorption leading thus to an osmotic water flow into the lumen, and diuresis.

Linalool decreases HepG2 viability by inhibiting mitochondrial complexes I and II, increasing reactive oxygen species and decreasing ATP and GSH levels.

Coriander is used as an appetizer, a common food seasoning in Mediterranean dishes, and a remedy for many ailments. In this study we tested the biochemical effect of its essential oil components, in particular linalool, its main component. The oil extract was prepared by hydro-distillation of coriander seeds. The various components were identified by gas chromatography coupled to mass spectroscopy. The effect of the various oil components on the viability of different cell lines (HepG2, Caco2, NIH3t3, MCF7 and Hek293) was examined using MTT assay. Linalool was the most potent and HepG2 cells the most sensitive. A 50% and 100% decrease in the viability of HepG2 was obtained at 0.4 microM and 2 microM linalool, respectively. Whereas none of the other components exerted a significant effect at concentrations lower than 50 microM, myrcene and nerolidol, the structural analogues of linalool, were more potent at 100 microM than the other components decreasing HepG2 viability to 26%. The biochemical effect of linalool on mitochondria isolated from HepG2 showed a concentration-dependent inhibition in complexes I and II activities of the respiratory chain, and a time-dependent decrease in ATP level. In addition, a time-dependent decrease in glutathione (GSH) level and in the reduction of nitroblue tetrazolium was obtained, indicating increase in reactive oxygen species (ROS) generation. Pretreatment with the antioxidants: N-acetyl cysteine (2mM), Trolox (100 microM) and different flavonoids (50 microM) was partially protective against the linalool-induced cell death; the most effective response was that of rutin and apigenin which restored 91% of HepG2 viability. We hereby report a decrease in cell viability of HepG2 cells by linalool and identify the mitochondria as one possible target for its site of action, inhibiting complexes I and II and decreasing ATP. In addition linalool increased ROS generation and decreased GSH level.

Effect of cinnamon, clove and some of their constituents on the Na(+)-K(+)-ATPase activity and alanine absorption in the rat jejunum.

The effect of a water extract of some spices on the in vitro activity of the rat jejunal Na(+)-K(+)-ATPase was investigated. Extracts of nutmeg, cinnamon, clove, cumin, coriander, turmeric and caraway all inhibited the ATPase, while anise seed and white pepper exerted no significant effects. The extracts of clove and cinnamon had the most potent inhibitory effect on the intestinal ATPase as compared to extracts of other spices. They also inhibited the in vitro Na(+)-K(+)-ATPase activity in a crude kidney homogenate and the activity of an isolated dog kidney Na(+)-K(+)-ATPase. The alcoholic extract of cinnamon, compared to the aqueous extract, had a stronger inhibitory action on the jejunal enzyme and a lower IC(50) value, which was not significantly different from the one observed with cinnamaldehyde, the major volatile oil present cinnamon, suggesting that in alcoholic extracts cinnamaldehyde is the major inhibitory component. The IC(50) values of eugenol, aqueous clove extract and ethanolic clove extract all fell within the same range and were not significantly different from each other, suggesting that eugenol is the major inhibitory component in both alcoholic and aqueous extracts. Based on the IC(50) values, the order of sensitivity of the enzyme to the spices extracts is as follows: isolated dog kidney ATPase>rat kidney ATPase>rat intestine ATPase. The aqueous extracts of clove and cinnamon also significantly lowered the absorption of alanine from the rat intestine. It was concluded that the active principle(s) in clove and cinnamon can permeate the membrane of the enterocytes and inhibit the Na(+)-K(+)-ATPase that provides the driving force for many transport processes.

In vitro effect of eugenol and cinnamaldehyde on membrane potential and respiratory chain complexes in isolated rat liver mitochondria

The effect of water extracts of cinnamon and clove on rat mitochondrial F(0)F1ATPase was investigated. Both spices stimulated ATP hydrolysis. Gas chromatography analysis of the water extracts, confirmed the presence of eugenol and cinnamaldehyde as major components in clove and cinnamon, respectively. Both components (1) stimulated ATPase significantly at concentrations equal or greater then 0.3 mM; (2) reduced mitochondrial membrane potential: a 50% decrease in Deltapsi was obtained at 7.56 and 11.6 micromoles/mg protein for eugenol and cinnmaldehyde, respectively; (3) inhibited NADH oxidase or complex I of the respiratory chain with a 50% inhibition at 15 and 20 micromoles/mg protein for eugenol and cinnamaldehyde respectively; (4) had no effect on succinate dehydrogenase activity. The study proposes the mitochondria as a target for the action of the spices resulting in derangement of mitochondrial functions, particularly at proton transferring sites.

The mechanism underlying the laxative properties of parsley extract.

Parsley has been claimed in folk medicine to possess laxative properties attributed to the presence therein of some volatile oils that are more concentrated in seeds than in stems or leaves. The advocated physiological effect of parsley, does not have, however, any proven scientific background and relies mainly on simple observations and empirical information. This work aims at providing the scientific evidence that would confirm or reject the claimed laxative role of parsley, and at determining its mechanism of action if present. A perfusion technique was used to measure the net fluid absorption from the rat colon. The addition of an aqueous extract of parsley seeds to the perfusion buffer, and the omission of sodium, both reduced significantly net water absorption from the colon, as compared to the control. Parsley, added to a sodium-free buffer did not lead to any further significant change in water absorption as compared to parsley alone inferring that with parsley sodium absorption was already inhibited. Since K+ and Cl- secretion depends on the activity of the NaKCl2 transporter, the latter was inhibited with furosemide which increased significantly net water absorption. When parsley and furosemide were added together, net water absorption was significantly higher than with parsley alone and significantly lower than with furosemide alone. In addition, parsley extract was shown to inhibit the in vitro activity of the Na+-K+ATPase in a colon homogenate and the activity of a partially purified dog kidney ATPase. The results suggest that parsley acts by, inhibiting sodium and consequently water absorption through an inhibition of the Na+-K+ pump, and by stimulating the NaKCl, transporter and increasing electrolyte and water secretion.

Tea extract inhibits intestinal absorption of glucose and sodium in rats

The effect of tea extract on the intestinal absorption of glucose and sodium was studied in rats. Tea extract reduced the mucosal uptake of glucose and its portal plasma concentration, but was without any effect on its serosal transport. The mucosal uptake of sodium was similarly inhibited. The tea extract reduced also the in vitro activity of the Na(+)-K+ ATPase in an intestinal mucosal homogenate. These data are consistent with the hypothesis that an active ingredient in tea reduced sodium extrusion from the enterocytes by inhibiting the Na(+)-K+ pump, thus destroying the gradient needed for the mucosal transport of glucose.

Binding of 125I-Insulin on Capillary Endothelial and Myofiber Cell Membranes in Normal and Streptozotocin-Induced Diabetic Perfused Rat Hearts

A heart-perfusion technique was employed to measure 125I-insulin binding on capillary endothelial and myocyte cell membranes in Sprague-Dawley rats. Animals were anesthetized, and the anterior chest wall excised to expose the mediastinal contents. The right and left superior and inferior venae cavae were dissected and tied, and another tie was passed around the aorta. A polyethylene catheter was introduced into the aortic lumen from cephalad to caudad to sit with its tip above the aortic valve. Another catheter was introduced into the cavity of the right atrium and both were anchored by sutures. Oxygenated Ringer-Lock buffer containing 20 mM/L K+ and 125I-insulin was perfused at a rate of 1 mL/min via the aortic catheter. Concomitantly, the distal ascending aorta and venae cavae were ligated. The effluent was collected from the right atrial catheter at the same infusion rate. Animals were divided into two groups, the normal group and streptozotocin-induced diabetic group. Heart perfusion was done on both groups either without or after treatment with detergent (CHAPS) to remove the capillary endothelial lining. A physical model for 125I-insulin sequestration as a ligand to its receptors on endothelial and/or myocyte plasma membranes was proposed. The model described a reversible binding of ligand on cellular surface receptor concentration to fit a conservation equation and a first order Bessel function. The binding constants (kn), reversal constants (k-n), dissociation constants kd = k-n/kn, and residency time constants tau = 1/k-n of 125I-insulin in normal untreated, normal CHAPS-treated, diabetic untreated, and diabetic CHAPS-treated hearts were estimated using a theoretically generated curve-fit to the data. Since insulin receptor binding on the capillary endothelial cell surfaces may serve to transport insulin from the intravascular to the subendothelial space, and since streptozotocin-induced diabetes was shown to diminish receptor autophosphorylation and kinase activity and hence internalization of insulin, then one can conclude the following from the data. In the normal heart, removal of the capillary endothelial lining with CHAPS did not alter kn, k-n, kd, and tau of insulin binding as compared to the normal untreated, whereas in the diabetic untreated heart these constants were altered, compared to the diabetic treated. Furthermore, the kn and k-n values in the diabetic CHAPS-treated hearts were the same as for the normals untreated and CHAPS-treated, respectively. In conclusion, the dissociation constants and residency time constants of all groups indicated the possible existence of two types of insulin receptors: the capillary endothelial cell surface insulin receptors with lower residency time (low affinity receptor or combination of insulin and IGF-1 receptors) and the myocyte plasma membrane insulin receptors with higher residency times (high affinity).

JNK modulates the effect of caspases and NF-κB in the TNF-α-induced down-regulation of Na+/K+ATPase in HepG2 cells

An inhibition of the Na+/K+ATPase was previously shown to accompany and potentiate apoptosis in different experimental models. Since TNF‐α is known to be a pro and anti‐apoptotic cytokine, this work was undertaken to study the effect of TNF‐α on the Na+/K+ATPase in HepG2 cells and to determine the signaling pathway involved. Cells were incubated for 1 h with TNF‐α in presence and absence of PDTC, SP600125 and FK009, respective inhibitors of NF‐KB, c‐JNK, and caspases. The activity of the pump was assayed by measuring the ouabain‐inhibitable release of inorganic phosphate, and changes in its expression were monitored by western blot analysis. TNF‐α decreased significantly the activity and protein expression of the Na+/K+ATPase. NF‐κB and caspases were found to be the main effectors of the cytokine, mediating respectively down‐regulation and up‐regulation of the pump. Their activity was however modulated at 1 h by c‐JNK, which stimulated the caspases and inhibited NF‐κB, resulting in a net inhibition of the ATPase, and probably favoring the apoptotic pathway. J. Cell. Physiol. 216: 615–620, 2008,

Interleukin-1β Increases Urine Flow Rate and Inhibits Protein Expression of Na+/K+-ATPase in the Rat Jejunum and Kidney

The effect of interleukin-1beta (IL-1beta) on urine flow rates and Na(+)/K(+)-ATPase activity and expression was studied in rat intestinal and renal epithelia. The cytokine produced a significant diuretic effect and increased urine flow rate by around 10-fold compared with the control. This effect was considered to be secondary to the well-documented natriuretic effect of the cytokine described in the literature. On the other hand, we have shown previously that IL-1beta inhibits glucose absorption from the jejunum. As sodium excretion and glucose absorption are both dependent on Na(+)/K(+)-ATPase activity, the effect of the cytokine on the renal and intestinal pump was investigated. IL-1beta inhibited, in a dose-dependent manner, the activity of Na(+)/K(+)-ATPase in villus and crypt jejunal cells and in medullary and cortical kidney cells. Western blot analysis revealed a decrease in the protein expression of the enzyme, which was confirmed by the radiolabeled ouabain binding assay. The results suggest that the diuretic and natriuretic effect of IL-1beta and its inhibitory effect on glucose absorption are all due to downregulation of the Na(+)/K(+) pump in the kidney and jejunum.

Insulin down-regulates the Na+/K+ ATPase in enterocytes but increases intestinal glucose absorption.

The effect of insulin on [(14)C] 3-O-methyl-d-glucose (3OMG) absorption in the rat jejunum was studied using an in situ perfusion technique. Insulin increased apical glucose entry into the cells and decreased intestinal retention suggesting that serosal glucose transport was enhanced by the hormone. This enhanced uptake was ascribed to an increase in the expression of glucose transporters as confirmed by Western blot analysis and not to a higher sodium gradient, since insulin reduced the activity and protein expression of the Na(+)/K(+) ATPase. To separate the glycemic from the insulinemic effect on glucose transport, the effect of the hormone was investigated in vitro using cultured Caco-2 cells. The cells also showed an increase in [(14)C] 3OMG uptake and intracellular glucose levels when treated with insulin and a lower Na(+)/K(+) ATPase activity. Phloretin, an inhibitor of GLUT2 was used to determine if these transporters are targeted by the hormone. The results showed that the effect of insulin on glucose uptake and intracellular glucose was still enhanced in presence of phloretin. Considering the inhibitory effect of the hormone on the Na(+)/K(+) ATPase, it was concluded that insulin acts by increasing the number of glucose transporters, a hypothesis that was confirmed by Western blot analysis.