Antioxidant and antiapoptotic properties of melatonin restore intestinal calcium absorption altered by menadione

The intestinal Ca²⁺ absorption is inhibited by menadione (MEN) through oxidative stress and apoptosis. The aim of this study was to elucidate whether the antioxidant and antiapoptotic properties of melatonin (MEL) could protect the gut against the oxidant MEN. For this purpose, 4-week-old chicks were divided into four groups: (1) controls, (2) treated i.p. with MEN (2.5 μmol/kg of b.w.), (3) treated i.p. with MEL (10 mg/kg of b.w.), and (4) treated with 10 mg MEL/kg of b.w after 2.5 μmol MEN/kg of b.w. Oxidative stress was assessed by determination of glutathione (GSH) and protein carbonyl contents as well as antioxidant enzyme activities. Apoptosis was assayed by the TUNEL technique, protein expression, and activity of caspase 3. The data show that MEL restores the intestinal Ca²⁺ absorption altered by MEN. In addition, MEL reversed the effects caused by MEN such as decrease in GSH levels, increase in the carbonyl content, alteration in mitochondrial membrane permeability, and enhancement of superoxide dismutase and catalase activities. Apoptosis triggered by MEN in the intestinal cells was arrested by MEL, as indicated by normalization of the mitochondrial membrane permeability, caspase 3 activity, and DNA fragmentation. In conclusion, MEL reverses the inhibition of intestinal Ca ²⁺ absorption produced by MEN counteracting oxidative stress and apoptosis. These findings suggest that MEL could be a potential drug of choice for the reversal of impaired intestinal Ca ²⁺ absorption in certain gut disorders that occur with oxidative stress and apoptosis.     

Effects of quercetin and menadione on intestinal calcium absorption and the underlying mechanisms

Quercetin (QT) could be considered as a potential therapeutic agent for different diseases due to its antioxidant, anti-inflammatory, antiviral and anticancer properties. This study was designed to investigate the ability of QT to protect the chick intestine against menadione (MEN) induced injury in vivo and in vitro. Four-week old chicks (Gallus gallus) were treated i.p. with 2.5 μmol of MEN/kg b.w. or with i.l. 50 μM QT or both. QT protected the intestinal Ca²⁺ absorption against the inhibition caused by MEN, but QT alone did not modify. Glutathione (GSH) depletion provoked by MEN in chick enterocytes was abolished by QT treatment, whereas QT alone did not modify the intestinal GSH content. The enhancement of GSH peroxidase activity produced by MEN was blocked by QT treatment. In contrast, superoxide dismutase activity remained high after simultaneous treatment of enterocytes with MEN and QT. The flavonol also avoided changes in the mitochondrial membrane permeability (swelling) produced by MEN. The FasL/Fas/caspase-3 pathway was activated by MEN, effect that was abrogated by QT. In conclusion, QT may be useful in preventing inhibition of chick intestinal Ca²⁺ absorption caused by MEN or other substances that deplete GSH, by blocking the oxidative stress and the FasL/Fas/caspase-3 pathway activation.     

Mitochondrial dysfunction induced by knockdown of mortalin is rescued by Parkin

Mutations in the parkin gene are the most common cause of autosomal recessive Parkinson’s disease (PD). As an E3-ubiquitin ligase, Parkin is associated with mitochondrial dynamics and mitophagy. Mortalin, a molecular chaperone, is located primarily in mitochondria, where it functions to maintain mitochondrial homeostasis and antagonize oxidative stress injury. A reduced expression level of mortalin has been observed in the affected brain regions of PD patients. Mortalin also interacts with a variety of PD-related proteins and plays an indispensible role in helping native protein refolding and importing proteins into the mitochondrial matrix. Thus, the main aims of the present study were to investigate mitochondrial dysfunction induced by knockdown of mortalin and to test whether Parkin overexpression could rescue this effect. We found that lentivirus-mediated knockdown of mortalin in HeLa cells resulted in a collapse of mitochondrial membrane potential, an abnormal accumulation of reactive oxygen species and apparent alterations in mitochondrial morphology under H₂O₂-induced stress conditions. Remarkably, Parkin overexpression rescued these mitochondrial abnormalities. In HeLa cells expressing Parkin, co-immunoprecipitation of endogenous mortalin and wild-type Parkin was detected when they were treated with carbonyl cyanide 3-chlorophenylhydrazone (CCCP). In conclusion, we indicate that the relatively decreased mortalin expression level and its impaired interaction with Parkin could affect its roles in mitochondrial function.     

Effects of a single dose of menadione on the intestinal calcium absorption and associated variables

The effect of a single large dose of menadione on intestinal calcium absorption and associated variables was investigated in chicks fed a normal diet. The data show that 2.5 micro mol of menadione/kg of b.w. causes inhibition of calcium transfer from lumen-to-blood within 30 min. This effect seems to be related to oxidative stress provoked by menadione as judged by glutathione depletion and an increment in the total carbonyl group content produced at the same time. Two enzymes presumably involved in calcium transcellular movement, such as alkaline phosphatase, located in the brush border membrane, and Ca(2+)- pump ATPase, which sits in the basolateral membrane, were also inhibited. The enzyme inhibition could be due to alterations caused by the appearance of free hydroxyl groups, which are triggered by glutathione depletion. Addition of glutathione monoester to the duodenal loop caused reversion of the menadione effect on both intestinal calcium absorption and alkaline phosphatase activity. In conclusion, menadione shifts the balance of oxidative and reductive processes in the enterocyte towards oxidation causing deleterious effects on intestinal Ca(2+) absorption and associated variables, which could be prevented by administration of oral glutathione monoester.     

Mitochondrial dysfunction induced by pancreatitis-associated ascitic fluid

Acute hemorrhagic pancreatitis (AHP) involves multiple organ failure probably caused by the toxic factor(s) released in pancreatitis-associated ascitic fluid (PAAF). We found that PAAF interferes with hepatic mitochondrial respiration resulting in severe disturbances in respiratory control (RCR) and ADP/O ratios. Pancreatitis was induced in dogs by retrograde pancreatic duct infusion and the resultant PAAF was centrifuged, filtered, and frozen until used. Two human PAAFs collected from AHP patients were treated in a similar manner. Rat liver mitochondrial oxygen uptake was measured at 30 degrees C before and after addition of ADP and PAAF. Paired control runs were made using pooled heat-inactivated dog serum. Tests with nine canine PAAFs showed a mean increase of 120% in state 4 respiration (P less than 0.0001). After exposure to PAAF, addition of ADP to previously coupled mitochondria did not induce state 3 respiration. The human PAAFs both showed significant increases in state 4 respiration (P less than 0.01) and a marked decrease in RCR. Dose-response tests with human and canine PAAFs showed a positive correlation between percentage increase in state 4 respiration and the concentration of PAAF used. These results confirm the presence in PAAF of mitotoxic substance(s) which cause irreversible mitochondrial damage. Inhibition of coupled mitochondrial respiration by PAAF with the resultant fall in ATP may be the causative agent for the tissue and organ damage observed in AHP.     

Mechanisms of intestinal calcium absorption

Calcium is absorbed in the mammalian small intestine by two general mechanisms: a transcellular active transport process, located largely in the duodenum and upper jejunum; and a paracellular, passive process that functions throughout the length of the intestine. The transcellular process involves three major steps: entry across the brush border, mediated by a molecular structure termed CaT1, intracellular diffusion, mediated largely by the cytosolic calcium-binding protein (calbindinD(9k) or CaBP); and extrusion, mediated largely by the CaATPase. Chyme travels down the intestinal lumen in approximately 3 h, spending only minutes in the duodenum, but over 2 h in the distal half of the small intestine. When calcium intake is low, transcellular calcium transport accounts for a substantial fraction of the absorbed calcium. When calcium intake is high, transcellular transport accounts for only a minor portion of the absorbed calcium, because of the short sojourn time and because CaT1 and CaBP, both rate-limiting, are downregulated when calcium intake is high. Biosynthesis of CaBP is fully and CaT1 function is approximately 90% vitamin D-dependent. At high calcium intakes CaT1 and CaBP are downregulated because 1,25(OH)(2)D(3), the active vitamin D metabolite, is downregulated.     

Neuromuscular dysfunction induced by acetylcholinesterase inhibition.

The organophosphate cholinesterase inhibitor paraoxon produces a dose-dependent necrosis in rat skeletal muscle fibers after a single administration. The pathology, which is initiated at the motor end-plate region, is evident as early as 30 minutes after paraoxon administration and is characterized by dilated mitochondria, expanded sarcoplasmic reticulum, fused and widened subsynaptic folds, and coated cleft vesicles. By 24 hours, a generalized breakdown of muscle fiber architecture is evident with an accompanying infiltration of phagocytes. Electrophysiological studies have shown that paraoxon increases neurotransmitter release and causes spontaneous and impulse-related antidromic nerve activity, both of which can be reduced significantly by reactivation of inhibited acetylcholinesterase (AChE) with pyridine-2-aldoxime methiodide. The severity of the myopathy has been found to be positively correlated to the degree and duration of AChE inhibition. It appears that 2 hours of inhibition, with a critical loss in activity, viz., 85%, is necessary to initiate severe muscle fiber necrosis. Prior nerve transection prevents myopathic development and current data support the hypothesis that the induction of skeletal muscle fiber necrosis is triggered by inhibition of a neurally regulated fraction of AChE.     

Mitochondrial dysfunction induced by callyspongiolide promotes autophagy-dependent cell death

Callyspongiolide is a marine macrolide known to induce caspase-independent cancer cell death. While its toxic effects have been known, the mechanism leading to cell death is yet to be identified. We report that Callyspongiolide R form at C-21 (cally2R) causes mitochondrial dysfunction by inhibiting mitochondrial complex I or II, leading to a disruption of mitochondrial membrane potential and a deprivation of cellular energy. Subsequently, we observed, using electron microscopy, a drastic formation of autophagosome and mitophagy. Supporting these data, LC3, an autophagosome marker, was shown to co-localize with LAMP2, a lysosomal protein, showing autolysosome formation. RNA sequencing results indicated the induction of hypoxia and blocking of EGF-dependent pathways, which could be caused by induction of autophagy. Furthermore, mTOR and AKT pathways preventing autophagy were repressed while AMPK was upregulated, supporting autophagosome progress. Finally, the combination of cally2R with known anti-cancer drugs, such as gefitinib, sorafenib, and rapamycin, led to synergistic cell death, implicating potential therapeutic applications of callyspongiolide for future treatments.     

Enhancement of rat intestinal calcium absorption by vanadate.

Vanadate alters intestinal transport and may have a role in regulating cell function. To determine whether it influences calcium absorption, we tested the effects of acute and chronic vanadate administration on calcium absorption using single-pass perfusion of jejunal and ileal segments of the in vivo rat intestine. Acute vanadate administration increased the lumen-to-mucosa and net fluxes of calcium in both the jejunum and ileum. The increase was largely due to an enhancement of the saturable fluxes of calcium and was observed at 10(-4) M concentration of vanadate, but not at higher or lower concentrations of the oxyanion, except at the highest concentration used, 10(-2) M, where calcium absorption was inhibited. Chronic vanadate administration caused, on the other hand, no changes in calcium absorption. We have demonstrated previously that rat intestinal (Na+ + K+)-ATPase is inhibited by vanadate, an effect that could raise cell sodium and increase the efflux of sodium across the brush border membrane. The results suggest that the vanadate enhancement of calcium absorption may be related to an increased entry of calcium into the mucosa, possibly as a result of an augmented exchange through the Na+/Ca+ antiport system. Alternatively, vanadate may influence access to a calcium channel in the mucosal membrane of the intestinal epithelium, leading to the observed increase in absorption.     

Mitochondrial calcium release as induced by Hg2+

Addition of Hg2+ to mitochondria of rat kidney induces efflux of intramitochondrial Ca2+. This reaction is accompanied by a diminution of the NAD(P)H/NAD(P) ratio and a decrease of the internal negative membrane potential. These effects were enhanced by dithiothreitol. The binding of mercuric ions to mitochondria saturates with a maximal binding of 9 nmol min-1 mg-1. The stoichiometry between Ca2+ released and Hg2+ bound showed that in the presence of dithiothreitol, the binding of approximately 1 nmol of Hg2+/mg of protein suffices to induce the release of the accumulated Ca2+. In the electrophoretic analysis of Hg-labeled mitochondrial proteins it was found that 203Hg2+ bound mainly to proteins that have molecular masses of 20 and 30 kDa. It is proposed that Hg2+-induced Ca2+ release is due to modification of--SH groups of these latter proteins.     

Regulation of goby intestinal ion absorption by the calcium messenger system

The role of the calcium messenger system in the regulation of ion absorption across the teleost intestine was studied using pharmacological intervention. Radiochloride transport was independent of external Ca2+ over the range 10 microM to 2.5 mM. Treatment with the Ca2+ ionophore A23187 (to hyperpolarization of the apical membrane potential of intestinal epithelial cells. The Ca2+-calmodulin antagonists trifluoperazine (TFP) and calmidazolium (R24571) produced opposite effects, i.e., stimulation of Cl- absorption and cellular depolarization. Treatment with TFP or R24571 will block or override the inhibitory action of A23187. These data suggest a regulatory role for Ca2+ in the control of intestinal NaCl absorption and mediation via calmodulin.     

Copper-sodium linkage during intestinal absorption: inhibition by amiloride.

The possible association between copper and sodium small intestinal absorption in the rat was investigated in the presence or absence of the electrolyte transport inhibitors amiloride, acetazolamide, and furosemide, at pharmacologic concentrations, using an in situ perfusion procedure. Amiloride (1 mM) produced a significant decrease in copper, net water, and sodium absorption, in solutions with sodium. Copper tissue retention was not altered, but was much higher in the absence of sodium. Acetazolamide and furosemide (1 mM), in separate experiments, had no effect on copper removal from the lumen, but generally reduced sodium and water transport. The presence or absence of sodium in the perfusate influenced rates of copper uptake. These data are compatible with a more effective passage of copper across the enterocyte basolateral membrane in the presence of sodium than in its absence.     

Mitochondrial calcium function and dysfunction in the central nervous system

The ability of isolated brain mitochondria to accumulate, store and release calcium has been extensively characterized. Extrapolation to the intact neuron led to predictions that the in situ mitochondria would reversibly accumulate Ca²⁺ when the concentration of the cation in the vicinity of the mitochondria rose above the ‘set-point’ at which uptake and efflux were in balance, storing Ca²⁺ as a complex with phosphate, and slowly releasing the cation when plasma membrane ion pumps lowered the cytoplasmic free Ca²⁺. Excessive accumulation of the cation was predicted to lead to activation of the permeability transition, with catastrophic consequences for the neuron. Each of these predictions has been confirmed with intact neurons, and there is convincing evidence for the permeability transition in cellular Ca²⁺ overload associated with glutamate excitotoxicity and stroke, while the neurodegenerative disease in which possible defects in mitochondrial Ca²⁺ handling have been most intensively investigated is Huntington's Disease. In this brief review evidence that mitochondrial Ca²⁺ transport is relevant to neuronal survival in these conditions will be discussed.     

Modulation of intestinal absorption of calcium]

1. Absorption of ingested calcium (2 ml of a 10mM CaCl2 solution + 45Ca) by the adult rat was shown to be facilitated by the simultaneous ingestion of an active carbohydrate, L-arabinose. As the carbohydrate concentration is increased from 10 to 200 mM, the adsorption of calcium is maximized at a level corresponding to about twice the control adsorption level. 2. A similar doubling of calcium adsorption is obtained when a 100 mM concentration of any one of a number of other carbohydrates (gluconic acid, mannose, glucosamine, sorbitol, lactose, raffinose, stachyose) is ingested simultaneously with a 10 mM CaCl2 solution. 3. Conversely, the simultaneous ingestion of increasing doses (10 to 100 mM) of phosphate (NaH2PO4) with a 10 mM CaCl2 solution results in decreased 45Ca absorption and retention by the adult rat. 4. The maximum inhibition of calcium adsorption by phosphate is independent of the concentration of the ingested calcium solution (from 5 to 50 mM CaCl2). 5. The simultaneous ingestion of CaCl2 (10 mM) with lactose and sodium phosphate (50 and 10 mM, respectively) shows that the activating effect of lactose upon 45Ca adsorption may be partly dissimulated by the presence of phosphate. 6. These various observations indicate that, within a large concentration range (2 to 50 mM CaCl2), calcium adsorption appears to be a precisely modulated diffusion process. Calcium absorption varies (between minimum and maximum levels) as a function of the state of saturation by the activators (carbohydrates) and inhibitors (phosphate) of the calcium transport system.