Pathogenesis of Postprandial Hyperlipemia in Rats Fed Ethanol-Containing Diets

To study the mechanism of the increase in serum lipoproteins which occurs in rats fed alcohol chronically, and especially to assess the role of the intestine, the effects of acute and chronic ethanol administration on lymph and plasma lipids were compared in rats with and without intestinal lymph fistulae. In rats not previously given alcohol, the administration of one dose of a diet containing ethanol (3 g/kg) produced a significant increase in lymph flow, lipid output, and incorporation of dietary fat into lymph lipids when compared with the effects of a control diet containing isocaloric carbohydrate. However, no hyperlipemia developed after ethanol. By contrast, previous feeding of ethanol for several weeks modified the acute effects of ethanol on both lymph and serum lipids. Compared with control animals pair-fed with isocaloric carbohydrate-containing diets, rats which had been fed a diet with 36% of total calories as ethanol for 3-4 wk developed postprandial hyperlipemia when given a single dose of the ethanol-containing or even the ethanol-free diet. This was associated with an increased incorporation of labeled dietary fat and of intravenously injected [(3)H]lysine into plasma lipoproteins of d < 1.006. However, postprandial lymph flow and lipid output were not higher in rats fed alcohol chronically than in their pair-fed controls. Moreover, when rats with lymph fistulae were given intravenous (i.v.) infusions of lymph lipids (to substitute for the diverted intestinal lymph), the ethanol-fed animals still developed hyperlipemia. Incorporation of i.v. lysine into d < 1.006 plasma lipoproteins also remained significantly increased. Thus, under these conditions, alcoholic hyperlipemia does not result from changes in intestinal lymph lipids. Two main factors appear to be involved; the acute effects of ethanol on hepatic lipid metabolism and the development of an increased capacity for lipoprotein synthesis during chronic ethanol feeding. The latter most likely occurs in the liver and it is postulated that it is linked to the associated changes in the hepatic endoplasmic reticulum.     

Excretion of endogenous digoxin-like immunoreactive factors in human urine is a function of urine flow rate

We studied the effect of varying water and salt intake on the renal excretion of endogenous digoxin-like immunoreactive factors (DLIF). DLIF were measured in human urine and serum by competitive displacement of 125I-labeled digoxin from anti-digoxin antibodies. Diuresis was selectively induced in normal healthy humans by acute water ingestion, and natriuresis was preferentially induced by acute saline ingestion. We found the amount of endogenous immunoreactivity excreted in urine to be correlated with urine flow rate but not with urinary sodium excretion. Urinary excretion of DLIF, normalized to creatinine, was 3.6-fold greater at a urine flow rate of 5.5 mL/min than at 0.5 mL/min. On the other hand, saline intake increased urine flow rate 1.9-fold and increased sodium excretion threefold, but did not affect urinary excretion of DLIF. Fractional excretion of DLIF was linearly related to fractional excretion of water. This study demonstrates that normalization of DLIF values to urinary creatinine does not make DLIF excretion independent of urine flow rate and underscores the need for information on urine flow rate when DLIF measurements in urine are being interpreted.     

The influence of streptozotocin-induced diabetes mellitus on fluid and electrolyte handling in rats

Intakes and urine outputs of fluid and electrolytes were measured daily in rats before, and for 3 weeks after, induction of diabetes by intraperitoneal injection of streptozotocin (STZ; 60 mg/kg); control animals received saline. Water intakes and urine outputs were increased on and after the first day after injection with STZ; after a transient period of negative water balance, fluid intakes and urine outputs increased in parallel. Food intake was reduced for the first 3 days after injection of STZ but thereafter there was a steady increase. On the final experimental day, the food intake of the diabetic group was 60% greater than that of the control group. Urinary electrolyte excretion was increased after injection of STZ; at the end of the experiment, the increase in urinary sodium excretion was similar to the increase in intake but the increase in urinary potassium excretion was less. On day 21 after injection of STZ plasma sodium concentration and packed cell volume were significantly reduced in the diabetic group but plasma potassium concentration was not. There was a difference between the measured osmolality and the calculated osmolarity of the plasma of the diabetic animals which was not seen in the controls. This difference was not due to pseudohyponatraemia, but was probably due to the presence of unidentified solutes, since there was a significant gap between the urinary osmolal and osmolar excretion in the diabetic animals that was not present in the control animals.     

Renal divalent cation excretion in secondary hypertension.

1. To determine whether abnormal renal calcium excretion is unique to primary genetic hypertension, blood pressure and 24 h urinary excretion of calcium, magnesium, sodium and creatinine were measured in deoxycorticosterone-saline and two-kidney, one-clip Goldblatt hypertensive rats and in their respective controls on low (0.2%) and high (1.8%) dietary calcium intakes. 2. Calcium supplementation lowered blood pressure (P < 0.05) in deoxycorticosterone-saline rats and in control saline-loaded rats, raised blood pressure in two-kidney, one clip rats, and had no effect in sham-operated control rats. 3. On both diets, calcium excretion was higher in hypertensive than in normotensive rats. The high calcium diet increased urinary calcium excretion in all rats, but the changes in urinary calcium excretion closely paralleled the diet-induced changes in blood pressure. Thus, urinary calcium excretion in deoxycorticosterone-saline animals, in whom calcium lowered blood pressure the most, rose the least (107%). Urinary calcium excretion rose the most in two-kidney, one-clip animals (1113%), whose blood pressure also rose the most. 4. Urinary magnesium excretion was also abnormal in hypertensive rats compared with normotensive rats, falling on the high compared with the low calcium diet in normotensive rats, but not in either hypertensive strain. Furthermore, urinary magnesium excretion was closely linked to urinary calcium excretion in saline-loaded control rats (r = 0.78; P = 0.008), but was dissociated from urinary calcium excretion in deoxycorticosterone-saline rats (r = 0.02; not significant).(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationship between body store of vitamin B6 and plasma pyridoxal-P clearance: metabolic balance studies in humans

Factors that regulate the clearance of plasma pyridoxal-P (PLP) are unknown. Four volunteers were given a diet supplying approximately 12 mumol pyridoxine (PN) per day. The pharmacokinetics of plasma PLP clearance were measured in these subjects before and after 4 weeks of intravenous PN supplementation (122 mumol/day). Urinary B6 excretion, mainly as 4-pyridoxic acid (4-PA), increased progressively after initiation of PN supplementation until a new steady state was reached on day 10 of supplementation, whereupon greater than 93% of the daily injected PN could be recovered in the urine. Hence, urinary excretion is almost the sole route for vitamin B6 elimination. Fasting plasma PLP concentration increased with supplementation and also reached a new steady state at this time. When supplementation was terminated, urinary B6 excretion decreased in 5 days to an amount only slightly higher than that before supplementation. This amount was maintained for 2 months. By comparison, plasma PLP decreased more slowly and remained considerably higher than the presupplementation level for the rest of the study. These data confirm that urinary 4-PA excretion is a better indicator of B6 intake than is plasma PLP content, whereas plasma PLP content is a better indicator of the body store of the vitamin. Plasma clearance and volume of distribution of PLP decreased significantly after supplementation, but half-life t 1/2 did not change. Plasma clearance of PLP, therefore, is dependent on the vitamin B6 status of an individual.     

Plasma and Urinary Dopamine: Studies During Fasting and Exercise and in Tetraplegic Man

Dopamine, noradrenaline and adrenaline were measured in plasma and in urine, using double-isotope derivative techniques, in 46 normal subjects and in 17 tetraplegic patients with physiologically complete cervical spinal cord transections above the sympathetic outflow. Dopamine was present in plasma in normal subjects in a concentration of 0.33 μg/1 ± 0.06 (SEM). Twenty-four hour urinary excretion of dopamine averaged 248 yg ± 22. There was a significant correlation between the 24 h urinary excretion of dopamine and of noradrenaline. In the normal subjects plasma dopamine and the urinary excretion of dopamine did not change during three days of fasting while urinary excretion of adrenaline increased twofold. In the normal subjects exercise significantly increased plasma dopamine from 0.25 μg/1 to 0.43 μg/1, but significantly decreased the urinary excretion of dopamine. Exercise significantly increased the excretion of noradrenaline. In the tetraplegic patients the plasma dopamine concentration and the urinary excretion of dopamine were lower but not significantly different from the corresponding values in the normal subjects. Plasma noradrenaline and the urinary excretion of noradrenaline and adrenaline were significantly lower in the tetraplegic patients. It is concluded that dopamine is present in human plasma in concentrations similar to that of noradrenaline. Free dopamine in plasma and urine of normal subjects is not dependent on food intake. Urinary dopamine may be derived from circulating dopamine. Urinary dopamine does not necessarily appear to reflect changes in plasma dopamine. The relationship between plasma dopamine and changes in adrenergic nervous activity deserves further investigation.     

Prostaglandin-vasopressin interactions on the renal handling of calcium and magnesium

The role of prostaglandins in the regulation of sodium and water excretion has been widely studied, but little is known about the influence of prostaglandins (PGs) on the tubular handling of calcium, magnesium or phosphorus. Recent observations have suggested that PGE2 and vasopressin may interact and influence reabsorption of calcium and phosphorus in the cortical collecting duct. The present study investigated the effect of meclofenamate (2 mg/kg), and inhibitor of PG synthesis, on the excretion of calcium, magnesium and phosphorus. Experiments were performed in antidiuretic and water diuretic rats to examine potential PG-vasopressin interactions on the reabsorption of these ions by renal tubules. In antidiuretic rats given meclofenamate, urine osmolality increased whereas urine flow and the fractional excretion of water, urea, sodium, calcium and magnesium decreased by 30 to 50%. In water diuretic animals, urine osmolality and urea excretion were unaltered after meclofenamate administration. Fractional excretion of sodium, water, calcium and magnesium declined approximately 50% in water diuretic rats given meclofenamate. Urinary excretion of PGE2 was not significantly different in water diuretic and antidiuretic rats averaging 262 +/- 78 vs. 167 +/- 35 pg/min, respectively. Meclofenamate significantly reduced urinary excretion of PGE2 in both groups. The results indicate that renal PGs modulate renal tubular reabsorption of calcium and magnesium, as well as sodium and water.     

Alcoholic liver injury in the rat is associated with reduced expression of peroxisome proliferator-alpha (PPARalpha)-regulated genes and is ameliorated by PPARalpha activation

Alcoholic liver disease is associated with a state of hepatic fatty acid overload. We examined the effect of ethanol and different types of dietary fat on the expression of mRNA for liver fatty acid binding protein (L-FABP), peroxisome proliferator-activated receptor-alpha (PPARalpha), and peroxisomal fatty acyl CoA oxidase (FACO). Four groups of rats (n = 5) were fed intragastrically, a liquid diet with or without ethanol (10-16 g/kg/day) for 4 weeks. Pair-fed controls received isocaloric amounts of dextrose. The source of fat was either corn oil or fish oil. Ethanolfed rats developed fatty liver, necrosis, and inflammation; the changes were more severe in the fish oil-ethanol (FE) rats. PPARalpha mRNA levels were not different between groups, although there was a trend toward increased levels in ethanol-fed rats. We calculated L-FABP/PPARalpha and FACO/PPARalpha ratios as a measure of FACO and L-FABP up-regulation relative to PPARalpha expression. Both FACO/PPARalpha and L-FABP/PPARalpha ratios were significantly decreased in FE rats. However, only L-FABP/PPARalpha was decreased in corn oil plus ethanol rats. Also, the level of L-FABP/mRNA correlated inversely with the degree of fatty liver in ethanol-fed rats. Since expression of PPARalpha response genes was impaired in ethanol-fed rats, we determined whether activation of PPARalpha would normalize the PPARalpha response and prevent the pathological changes in ethanol-fed rats. Treatment with clofibrate, a PPARalpha-activating ligand, led to a marked decrease in fatty liver and complete abrogation of necroinflammatory changes in FE rats. Also, nuclear factor kappaB activation and up-regulation of tumor necrosis factor-alpha and cyclooxygenase-2 was also abolished in clofibrate-treated rats. We conclude that adaptive gene regulation of FACO and L-FABP by PPARalpha is impaired in ethanol-fed rats and that treatment with clofibrate, a PPARalpha ligand, prevents alcohol-induced pathological liver injury, possibly by reversing the above changes.     

Role of renal prostaglandins in normal and nephrotic rats with diet-induced hyperfiltration

Changes in glomerular hemodynamics have been observed in animals and humans after a high-protein feeding. It has been postulated that these changes can induce progressive deterioration of renal function favoring loss of glomerular permselectivity properties and subsequent glomerulosclerosis, especially when the renal mass is already reduced surgically or by a disease process. We studied the consequence of long-term protein supplementation on renal function parameters in normal animals and in animals affected by adriamycin nephrosis, a model of renal damage that closely mimics human "minimal change". We also wanted to investigate whether vasodilatory prostaglandins (PGs) generated at the renal level are responsible for the adaptive hemodynamic changes that follow dietary manipulation in normal animals and in animals with experimental nephrosis. The model of glomerular damage we used is characterized by heavy and persistent proteinuria induced in the rat by adriamycin (ADR). Two isocaloric diets were selected containing 20% and 35% protein. High-protein feeding induced a significant increase in glomerular filtration rate in both normal and nephrotic animals. In normal animals the high-protein diet did not modify the urinary excretion of 6-keto-PGF1 alpha, the stable breakdown product of prostacyclin (PGI2), but significantly reduced urinary excretion of prostaglandin E2. In nephrotic rats, the high-protein diet increased urinary excretion of 6-keto-PGF1 alpha, without modifying urinary excretion of prostaglandin E2. Glomerular synthesis of vasodilatory prostaglandins paralleled the urinary excretion pattern. The cyclooxygenase inhibitor indomethacin effectively inhibited urinary excretion of vasodilatory PGs but did not prevent hyperfiltration in normal animals fed the high-protein diet. At variance, when given to nephrotic animals fed the high-protein diet, indomethacin at a dose that reduced 6-keto-PGF1 alpha and prostaglandin E2 urinary excretion by 84% and 93%, respectively, inhibited hyperfiltration. We conclude that the same hemodynamic changes that occur in normal animals given a high-protein diet also take place when glomeruli are uniformly damaged by a disease process as in ADR nephrosis. However, whereas hyperfiltration in normal animals appears to be independent of renal PGs, in nephrotic animals an enhanced renal synthesis of PGI2 appears to play a crucial role in the adaptive changes responsible for hyperfiltration.     

Increased urinary zinc excretion after thermal injury.

Urinary zinc excretion normally plays a minor role in zinc homeostasis; however, urinary zinc excretion is markedly elevated after trauma or surgery, and mechanism(s) for this zinc loss are poorly defined. In this study we evaluated multiple potential mechanisms for increased urinary zinc excretion in patients with thermal injury. We documented that patients with severe thermal injury had markedly elevated urinary zinc excretion. Above 20% total body surface area burn, however, the severity of thermal injury did not correlate with urinary zinc excretion. Serum zinc concentrations were depressed on initial evaluation and gradually increased during the hospital course, whereas peak urinary zinc excretion occurred 2 to 5 weeks after injury. Thus the depression in serum zinc concentration did not temporally relate to the observed pattern of hyperzincuria. Increased urinary zinc excretion also did not temporally relate to urinary excretion of the amino acids cysteine and histidine (both of which tightly bind zinc) nor to urinary 3-methylhistidine excretion, a marker of muscle breakdown. Urinary amylase excretion, a marker of renal tubular dysfunction, did follow the pattern of urinary zinc loss to some extent, although this correlation was not perfect. Increased oral intake of zinc via zinc supplements resulted in significantly increased urinary zinc excretion. Patients receiving total parenteral nutrition (TPN) did not have significantly increased urinary zinc excretion when compared with people receiving their total nutrient intake by mouth.(ABSTRACT TRUNCATED AT 250 WORDS)     

Urinary excretion of homocysteine-thiolactone in humans

BACKGROUND: A metabolite of homocysteine (Hcy), the thioester Hcy-thiolactone, has been implicated in coronary heart disease in humans. Because inadvertent reactions of Hcy-thiolactone with proteins can lead to cell and tissue damage, the ability to detoxify or eliminate Hcy-thiolactone is essential for biological integrity. We examined the hypothesis that the human body eliminates Hcy-thiolactone by urinary excretion. METHODS: We used a sensitive HPLC method with postcolumn derivatization and fluorescence detection to examine Hcy-thiolactone concentrations in human urine and plasma. RESULTS: We discovered a previously unknown pool of Hcy-thiolactone in human urine. Urinary concentrations of Hcy-thiolactone (11-485 nmol/L; n = 19) were approximately 100-fold higher than those in plasma (<0.1-22.6 nmol/L; n = 20). Urinary Hcy-thiolactone accounted for 2.5-28.3% of urinary total Hcy, whereas plasma Hcy-thiolactone accounted for <0.002-0.29% of plasma total Hcy. Urinary concentrations of Hcy-thiolactone, but not of total Hcy, were negatively correlated with urinary pH. Clearance of Hcy-thiolactone, relative to creatinine, was 0.21-6.96. In contrast, relative clearance of Hcy was 0.001-0.003. CONCLUSIONS: The analytical methods described here can be used to quantify Hcy-thiolactone in biological fluids. Using these methods we showed that the human body eliminates Hcy-thiolactone by urinary excretion. Our data also suggest that the protonation status of its amino group affects Hcy-thiolactone excretion.     

Urinary pH as a determinant of prostaglandin E2 excretion by the conscious rat

The urinary excretion of prostaglandin E2 (PGE2) was measured in conscious rats under conditions which produced either acid or alkaline urine, but a similar change in fluid and solute excretion. Oral isotonic saline increased both urine flow and sodium excretion but did not alter urinary PGE2 output (which remained constant at 80 pmol/3 h per rat) or urine pH (6.2). When the urine was made alkaline (pH 7.8) by oral sodium bicarbonate or carbonate, urinary PGE2 was approximately 3-fold greater (P less than 0.001) than the control (pH 6.2). The urine flow and sodium output were also increased. When the urine was made acidic (pH 5.7) by oral ammonium chloride, urinary PGE2 excretion was reduced (P less than 0.01) to approximately half the control output. The urine flow and sodium output increased. Within a group of 12 rats receiving oral isotonic saline a positive linear correlation coefficient (P less than 0.002) was established between urine pH and PGE2 excretion. The results indicate that urine pH may be a determinant of PGE2 excretion in unrestrained, conscious rats. It seems likely that this effect of pH is mediated by a change in the passive reabsorption of PGE2 in the distal nephron, although alternative explanations such as altered tubular secretion or synthesis cannot be categorically excluded.     

Nicotine renal excretion rate influences nicotine intake during cigarette smoking

We examined the hypothesis that rate of elimination of nicotine affects nicotine intake during cigarette smoking. Elimination rate was altered by administering ammonium chloride or sodium bicarbonate throughout the day. Nicotine intake during unrestricted cigarette smoking was measured using metabolic clearance data obtained after i.v. nicotine infusion together with blood and urinary nicotine concentrations measured during 24-hr periods of cigarette smoking. Compared with placebo treatment (urine pH 5.6), urinary acidification (pH 4.5) increased (208%) renal clearance and, to a lesser extent (41%), total clearance and increased (by 7.2 mg) daily urinary excretion of nicotine. Urinary alkalinization (pH 6.7) resulted in a decrease (78%) in renal clearance with a small decrease (3.7 mg) in daily nicotine excretion. Average blood nicotine concentrations were similar in placebo and bicarbonate treatment conditions, but were 15% lower during acid loading. Daily intake of nicotine was 18% greater during acid loading. The compensatory increase in nicotine consumption was only partial, replacing about half the excess urinary nicotine loss. This is the first direct demonstration that rate of elimination can influence self-determined drug consumption in humans.     

Adaptation to increased dietary salt intake in the rat. Role of endogenous nitric oxide.

Previous studies have suggested that nitric oxide (NO) plays a role in regulation of renal vascular tone and sodium handling. We questioned whether the effects of NO synthase inhibition on renal function are direct or due to increased renal perfusion pressure (RPP) and whether stimulation of endogenous NO activity plays a role in adaptation to increased dietary salt intake. Intrarenal arterial infusion of the NO synthase inhibitor NG-monomethyl-L-arginine (L-NMMA) in control rats resulted in decreased glomerular filtration rate, renal vasoconstriction, natriuresis, and proteinuria. When RPP was held at basal levels with suprarenal aortic snare, L-NMMA had similar hemodynamic effects but decreased sodium excretion and did not induce proteinuria. Exposure of rats to high salt intake (1% NaCl drinking water) for 2 wk induced increased serum concentration and urinary excretion of the NO decomposition products, NO2 + NO3. Urinary NO2 + NO3 and sodium excretion were significantly correlated. Compared with controls, chronically salt-loaded rats also demonstrated enhanced renal hemodynamic responses to NO synthase inhibition. We conclude that the endogenous NO system directly modulates renal hemodynamics and sodium handling and participates in the renal adaptation to increased dietary salt intake. Enhanced NO synthesis in response to increased salt intake may facilitate sodium excretion and allow maintenance of normal blood pressure.     

Urinary kallikrein and plasma renin activity as determinants of renal blood flow. The influence of race and dietary sodium intake.

We investigated the relationship of the kallikrein-kinin system and the renin-angiotensin system in the regulation of blood pressure, salt and water excretion, and renal blood flow. Normotensive and hypertensive black and white men were studied during unresticted sodium intake as well as on a 10-meq/day sodium intake; potassium intake was held constant throughout the study (80 meq/day). During unrestricted sodium intake, urinary kallikrein activity was greater in white normotensives than white hypertensives or black normotensives. There was no difference (P greater than 0.05) between white and black hypertensives or between black normotensives and black hypertensives. All groups had greater urinary kallikrein activity on low sodium vs. unrestricted sodium intake, but the increase in black hypertensives was small, and they excreted significantly less kallikrein than the ogher groups on the low sodium diet. Plasma renin activity showed similar increments after sodium restriction in all groups. Urinary kallikrein activity correlated with renal blood flow in all groups except the black normotensives on low sodium intake. Renal blood flow could be correlated uniformly with log (urinary kallikrein activity/supine plasma renin activity) in all groups on either diet. Urinary sodium and potassium excretion and urine volume were not different among the groups. We conclude: (a) important racial differences exist in urinary kallikrein activity that are unrelated to sodium or potassium excretion or urine volume; (b) dietary sodium restriction further delineates racial differences and suggests alternative pathophysiologic mechanisms for huma hypertension; (c) urinary kallikrein activity correlates with renal blood flow; and (d) our data support the concept that the kallikrein-kinin system and the renin-angiotensin system contribute to the regulation of renal blood flow and may account for racial differences in renal vascular resistance.     

Effect of oophorectomy and calcium deprivation on bone mass in the rat

1. The effects of a low calcium diet and of oophorectomy, separately and together, on cortical and trabecular bone mass, have been examined in mature female rats. 2. Calcium deprivation caused a significant decrease of weight, cortical cross-sectional area and ratio of cortical to total area in the femur, it significantly reduced the volume of trabecular bone and increased the percentage of osteoid surface in the tail vertebrae, and in addition increased the urinary excretion of phosphate and, initially, of hydroxyproline. 3. Oophorectomy caused similar though smaller changes in trabecular bone and urine, whereas the effects of oophorectomy on cortical bone were greater on a low calcium intake than on a normal intake. 4. The ash weight of the femora, expressed as a percentage of the total dry weight, was unaffected by calcium deprivation or oophorectomy alone but was significantly reduced when the two occurred together. 5. The percentage of resorption surfaces in the vertebrae tended to increase on the low calcium diet and after oophorectomy on the normal diet but decreased after oophorectomy on a low calcium diet. 6. It is concluded that oophorectomy and calcium deficiency each reduce bone mass in the adult rat but the greatest effect is seen when they are combined.     

Potassium depletion downregulates chloride-absorbing transporters in rat kidney.

Potassium depletion (KD) causes renal chloride wasting, suggesting defect(s) in Cl- reabsorption in renal tubules. To determine whether alterations in expression of the major Cl- transporter genes might contribute to the chloride wasting, we analyzed their expression in renal cortex and medulla of animals placed on KD diet. Feeding KD diet to rats resulted in significant hypokalemia at 14 d but not at 6 d. Northern hybridization revealed that mRNA levels for the apical Na-K-2Cl cotransporter in the medulla decreased by 56 and 51% at 6 and 14 d of KD diet, respectively. Functional studies in tubular suspensions from medullary thick ascending limb demonstrated that the Na-K-2Cl cotransporter activity decreased by approximately 45 and approximately 37% at 6 and 14 d of KD diet, respectively. mRNA levels for the thiazide-sensitive Na-Cl cotransporter decreased by 57 and 64% at 6 and 14 d of KD diet. Decreased expression of the apical Na-Cl and the Na-K-2Cl cotransporters became evident at 48 and 72 h of KD, respectively. Urinary chloride excretion increased at 48 h and further increased at 72 h of KD, correlating with suppression of the Na-Cl and the Na-K-2Cl transporters. Our results indicate that increased urinary chloride loss in KD results from suppression of the chloride-absorbing transporters. Downregulation of chloride transporters in KD is an early event and can lead to hypochloremia and subsequently hypovolemia and decreased glomerular filtration rate.     

Effect of volume expansion on renal citrate and ammonia metabolism in KCl-deficient rats.

When rats with desoxycorticosterone acetate (DOCA)-induced potassium chloride deficiency are given sodium chloride there is simultaneously a partial correction of metabolic alkalosis and a marked reduction in urinary citrate excretion and renal citrate content. To examine DOCA's role in this phenomenon and to determine how sodium chloride alters renal metabolism, rats were made KC1 deficient using furosemide and a KC1-deficient diet. Renal citrate and ammonia metabolism were then studied after chronic oral sodium chloride administration or acute volume expansion with isotonic mannitol. Although both maneuvers partially corrected metabolic alkalosis, sodium chloride raised serum chloride concentration while mannitol significantly decreased it. Urinary citrate excretion decreased to 10% of control in rats given NaCl and to 50% of control in rats infused with mannitol. The filtered load of citrate was constant or increased indicating increased tubular citrate reabsorption. Renal cortical citrate content also decreased approximately 50%. Renal cortical slices from KCl-deficient rats incubated in low or normal chloride media produced equal amounts of 14CO2 from (1, 5-14C) citrate. In addition, urinary ammonia excretion increased by over 300% in both groups. This occurred in the mannitol group despite increased urinary pH and flow rate indicating a rise in renal ammonia production. It seems that neither DOCA nor an increase in serum chloride concentration explains the experimental results. Rather, it appears that volume expansion is responsible for increased renal tubular citrate reabsorption and renal ammonia production. As these renal metabolic responses ordinarily occur in response to acidosis, the data are consistent with the hypothesis that volume expansion reduces renal cell pH in 3KCl-deficient rats.     

Lowering effects of onion intake on oxidative stress biomarkers in streptozotocin-induced diabetic rats

The protective effect of onion against oxidative stress in streptozotosin-induced diabetic rats was investigated in comparison with that of quercetin aglycone. We measured oxidative stress biomarkers involving the susceptibility of the plasma against copper ion-induced lipid peroxidation, which was estimated by the amounts of thiobarbituric acid-reactive substances (TBARS) and cholesteryl ester hydroperoxides, and urine TBARS and 8-hydroxydeoxyguanosine contents. After the 12-week feeding period, plasma glucose levels and these biomarkers increased in diabetic rats compared to normal rats. In diabetic rats fed a 6.0% onion diet (quercetin equivalent: 0.023%), quercetin metabolites accumulated in the plasma at concentrations of approximately 35 microM. Onion intake decreased plasma glucose levels and lowered the oxidative stress biomarkers. On the other hand, quercetin metabolites in the plasma of rats fed a diet with 0.023% quercetin aglycone were found at lower concentrations (14.2 microM) than the rats fed the onion diet. Furthermore, oxidative stress biomarkers were higher in the quercetin diet group compared to the onion diet group. These results strongly suggest that onion intake suppresses diabetes-induced oxidative stress more effectively than the intake of the same amount of quercetin aglycone alone.     

Effect of inhibition of gamma-glutamyltranspeptidase on biliary and urinary excretion of glutathione-derived thiols and methylmercury

Acivicin (AT-125; 6.25-200 mumol/kg i.v.) inhibited hepatic, biliary and renal gamma-glutamyltranspeptidase (GGT) activity up to 88, 99 and 97%, respectively, in 4-week-old rats. This inhibition of GGT by acivicin resulted in a 10- to 12-fold increase in the biliary excretion of reduced (GSH) and oxidized glutathione. Because the biliary excretion of cysteinylglycine (Cys-Gly), Cys-Gly disulfide, cysteine (Cys) and cystine concomitantly decreased (63-99%), the biliary excretion rate of total glutathione-derived thiols and disulfides did not change. In contrast, acivicin treatment dramatically elevated the urinary excretion rate of glutathione-derived thiols in a dose-dependent fashion, resulting in a 390-fold increase at the highest dosage. This mainly originated from enhancement of urinary excretion of GSH (up to 7200-fold), although the excretion of Cys and Cys-Gly into urine was also increased. Acivicin treatment did not affect hepatic and renal levels of GSH but, at high dosages, reduced the concentration of Cys in these organs. GSH and oxidized glutathione concentrations in serum were increased, whereas cystine was diminished in acivicin-treated rats. Inhibition of GGT by acivicin (100 mumol/kg i.v.) failed to influence the biliary excretion of methylmercury but increased urinary excretion 34-fold. Even though the urinary thiol excretion was much higher than the biliary thiol excretion in the acivicin-treated rats, methylmercury was preferentially excreted into bile rather than urine, indicating the importance of the liver as an excretory organ for methylmercury.(ABSTRACT TRUNCATED AT 250 WORDS)