Effect of endrin on the hepatic distribution of iron and calcium in female Sprague-Dawley rats.

The distribution of iron and calcium in hepatic subcellular fractions of female rats treated with endrin (1,2,3,4,10,10-hexachloro-6,7-epoxy-1,4,4 alpha,5,6,7,8,8 alpha- octahydroendo,endo-1,4:5,8-dimethanonaphthalene) was determined. Endrin in corn oil was administered orally to rats in single doses of 3, 4.5, or 6 mg/kg, and the animals were killed at 0, 12, 24, 48, or 72 hr post-treatment. Iron and calcium were determined by atomic absorption spectroscopy. The administration of endrin increased the iron content of mitochondria and decreased the iron content of microsomes and nuclei. Significant increases occurred in the calcium content of mitochondria, microsomes, and nuclei. Thus, the results indicate that with respect to the subcellular distribution of iron and calcium, endrin produces differential effects. Vitamin E succinate administration partially prevented the endrin-induced hepatic alterations in iron and calcium homeostasis. Endrin also produced dose- and time-dependent increases in the liver and spleen weight/body weight ratios, while decreasing the thymus weight/body weight ratios. The altered distribution of calcium and iron may contribute to the broad range of effects of endrin.     

Effect of endrin on the hepatic distribution of iron and calcium in female sprague-dawley rats

The distribution of iron and calcium in hepatic subcellular fractions of female rats treated with endrin (1, 2, 3, 4, 10, 10-hexachloro-6, 7-epoxy-1, 4, 4α, 5, 6, 7, 8, 8α-octahydroendo, endo-1, 4:5, 8-dimethanonaphthalene) was determined. Endrin in corn oil was administered orally to rats in single doses of 3, 4.5, or 6 mg/kg, and the animals were killed at 0, 12, 24, 48, or 72 hr posttreatment. Iron and calcium were determined by atomic absorption spectroscopy. The administration of endrin increased the iron content of mitochondria and decreased the iron content of microsomes and nuclei. Significant increases occurred in the calcium content of mitochondria, microsomes, and nuclei. Thus, the results indicate that with respect to the subcellular distribution of iron and calcium, endrin produces differential effects. Vitamin E succinate administration partially prevented the endrin-induced hepatic alterations in iron and calcium homeostasis. Endrin also produced dose- and time-dependent increases in the liver and spleen weight/body weight ratios, while decreasing the thymus weight/body weight ratios. The altered distribution of calcium and iron may contribute to the broad range of effects of endrin.     

Manganese, copper, zinc, and iron concentrations and subcellular distribution in two types of skeletal muscle

To clarify trace element distribution in red and white muscle, and to verify two populations of muscle mitochondria, the iron, zinc, copper, and manganese concentrations of whole muscle and their subcellular fractions were determined. The iron, zinc, copper, and manganese concentrations of red muscle were 1.83, 4.31, 2.05, and 1.67 times higher than those of white muscle, respectively. In skeletal muscle subcellular distribution or iron, zinc, and copper were entirely different and that of manganese was relatively similar as compared with those in liver reported previously. The pattern of mineral distribution in all fractions of red muscle was similar to that of white muscle, but their concentrations in some fractions were different between red and white muscle, e.g., iron, zinc, and manganese in supernatant fraction and copper in nuclear and microsomal fractions. The difference between subsarcolemmal and interfibrillar mitochondria were ascertained by the distribution of trace elements.     

Effects of TCDD upon IkappaB and IKK subunits localized in microsomes by proteomics

Biochemical studies have shown that microsomes represent an important subcellular fraction for determining 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) effects. Proteomic analysis by two-dimensional gel-mass spectrometry of liver microsomes was undertaken to gain new insight into the actions of TCDD in male and female rats. Proteomic analysis showed TCDD induced several xenobiotic metabolism enzymes as well as a protein at 90kDa identified by mass spectrometry as IkappaB kinase beta/IKK2. This observation led to the discovery of other NF-kappaB binding proteins and kinases in microsomes and effects by TCDD. Western blotting for IKK and IkappaB family members in microsomes showed a distinct pattern from cytosol. IKK1 and IKK2 were both present in microsomes and were catalytically active although, unlike cytosol, IKKgamma/NEMO was not detectable. TCDD exposure produced an elevation in cytosolic and microsomal IKK activity of both genders. The NF-kappaB binding proteins IkappaBbeta and IkappaBgamma were prevalent in microsomes, while IkappaBalpha and IkappaB epsilon proteins were absent. TCDD treatment produced hyperphosphorylation of microsomal IkappaBbeta in both sexes with females being most sensitive. In cytosol, IkappaBalpha, IkappaBbeta, and IkappaB epsilon, but not IkappaBgamma, were clearly observed but were not changed by TCDD. Overall, proteomic analysis indicated the presence of NF-kappaB pathway members in microsomes, selectively altered by dioxin, which may influence immune and inflammatory responses within the liver.     

Induction and suppression of hepatic and extrahepatic microsomal foreign-compound-metabolizing enzyme systems by 2,3,7,8-tetrachlorodibenzo-p-dioxin

The effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on a number of hepatic and extrahepatic foreign-compound-metabolizing enzyme systems in microsomes from rats, rabbits and guinea pigs were investigated.Following TCDD treatment, the N-demethylation of benzphetamine, aminopyrine and ethylmorphine was suppressed in hepatic microsomes from male but not from female rats. However, both cytochrome P-450 and benzpyrene hydroxylase were significantly stimulated in hepatic microsomes from both male and female rate at doses as small as 1 μg TCDD/kg body weight. The inductive effect on rat hepatic microsomal enzymes was considerably more persistent than the suppressive effect. Following a single oral dose of 25 μg TCDD/kg body weight, benzpyrene hydroxylase of male rat liver microsomes remained significantly elevated for 73 days but the suppression of benzphetamine N-demethylase had gone after 35 days.The induction of benzpyrene hydroxylase in male rat liver microsomes by TCDD was independent of the age of the rat and the levels to which this enzyme was increased was similar in male rats of all ages. However, the suppression of benzphetamine N-demethylase in male rat liver microsomes was age related: the suppression was seen only in adult animals and in the very young (10 days old) the enzyme was actually induced by TCDD. Inductive effects appeared in both smooth and rough-surfaced hepatic microsomes from male rats but the suppression of N-demethylidon occurred perhaps the derepression arises through the interaction of TCDD or metabolite of TCDD, with the operator gene itself.     

Influence of dietary cadmium on the distribution of the essential metals copper,zinc and iron in tissues of the rat

The effect of long-term dietary cadmium treatment upon the distribution of the metals copper, iron and zinc has been compared in various organs of male and female rats. The renal accumulation of cadmium was similar in both sexes without a plateau being reached. In contrast, the hepatic accumulation of cadmium was higher in the female than in the male rat and a plateau was observed after 30–35 weeks of dietary cadmium treatment. Most of the cadmium which accumulated in these organs was recovered in the metallothionein fraction and the concentration of hepatic cadmiumthionein in the female rat was correspondingly higher than in the male rat. Accumulation of cadmium was associated with an increased zinc concentration in the liver and an increased copper concentration in the kidney; these increases were correlated with increases in liver and kidney metallothioneins induced by cadmium. Uptake of cadmium into organs other than liver and kidney occurred to a small extent but was not associated with changes in the concentration of copper and zinc. Cadmium also accumulated in the intestinal mucosa where it could be recovered in a fraction corresponding to metallothionein. A loss of iron from the liver and kidney was also observed following dietary cadmium treatment and involved mainly a loss of iron from ferritin.     

Effect of chronic ethanol treatment on the t-butyl hydroperoxide-dependent lipid peroxidation in rat liver

1. The effect of chronic ethanol consumption on the level of the t-butyl hydroperoxide (Bu'OOH)-induced lipid peroxidation in rat liver homogenate and subcellular fractions was measured using chemiluminescence technique and malondialdehyde formation. 2. It was shown that under the action of ethanol the rate of lipid peroxidation was decreased in the whole and "postnuclear" liver homogenates. 3. Ethanol significantly decreased the intensity of lipid peroxidation in microsomes, but did not affect the Bu'OOH-dependent process in mitochondria. 4. The level of lipid peroxidation was reduced after incubation of the total particulate fraction (mitochondria plus microsomes) with the undialysed cytosol from ethanol-treated rat liver. Dialysis of the cytosol prevented depressive effect of ethanol treatment on lipid peroxidation. 5. Reduced glutathione (0.1-1.0 mM) was shown to decrease the rate of lipid peroxidation in rat liver microsomes, but did not affect its level in mitochondria. 6. Pyrazole injections to rats reduced and phenobarbital treatment increased the level of the Bu'OOH-dependent lipid peroxidation in liver microsomes. 7. The data obtained indicate that the Bu'OOH-dependent lipid peroxidation is not an appropriate marker of the ethanol-induced oxidative stress in rat liver cells.     

Effects of adrenocorticotropic hormone and dexamethasone on adrenal and hepatic alpha-tocopherol concentrations

Studies were done to determine the effects of ACTH treatment on adrenal alpha-tocopherol (alpha-T) concentrations in female rats. Administration of dexamethasone (DEX) to inhibit endogenous ACTH secretion increased whole adrenal alpha-T levels as well as the fractional amount in adrenal cytosol. Adrenal ascorbic acid (AA) concentrations were unaffected by DEX. DEX treatment also had no effect on hepatic AA content but decreased alpha-T concentrations in the liver. The subcellular distribution of alpha-T in the liver was not altered by DEX. Administration of ACTH to DEX-treated animals decreased adrenal alpha-T content and restored the pattern of subcellular distribution to that seen in controls. ACTH had no effect on hepatic alpha-T concentrations or subcellular distribution. ACTH treatment also had no effect on AA concentrations in adrenals or livers. The results demonstrate that ACTH has a role in the regulation of adrenal alpha-T but the mechanism(s) involved remain to be determined. The data also indicate that glucocorticoids such as DEX directly influence hepatic alpha-T levels independent of their effects on ACTH secretion.     

Interaction of rifampicin with hepatocyte organoids in rats and its intracellular distribution

Interaction of rifampicin with isolated subcellular fractions of the rat liver (binding and dissociation of the complexes) and intracellular distribution of the antibiotic were studied in the presence of the main organoids taken in the ratio close to the natural volume ratio of the hepatocyte cell components. The nuclei and mitochondria were most active during drug binding. The microsomes were less important. Rifampicin formed mobile complexes with organoids and was easily released from the subcellular fractions recovering its activity on washing. The intracellular distribution was the following: 37.7 per cent of rifampicin in the active form was accumulated in cytosol and the remaining amount was reversibly bound in the fractions of the nuclei, mitochondria and microsomes. The characteristic features of the cell pharmacokinetics of rifampicin, i.e. significant concentration in cytosol, possible deposition in the subcellular structures and at the same time the capacity for recovery of the activity might define the antimicrobial potential of this antibiotic in respect to the intracellular microorganisms.     

Partitioning of bile acids into subcellular organelles and the in vivo distribution of bile acids in rat liver.

1. The subcellular distribution of conjugates of cholic acid and chenodeoxycholic acid between cytosol, nuclei, mitochondria and microsomes in rat liver has been determined. 2. The partition coefficients for the distribution of these bile acids between subcellular fractions and buffer have been measured and used to construct a compartmental model of the amounts of conjugated bile acids present in the different subcellular organelles in vivo. 3. This model indicates that a large percentage of the bile acid in the rat liver is found in the nuclear fraction; 42% of the cholic acid conjugates and 27% of the chenodeoxycholic acid conjugates. Substantial amounts of bile acid are also present in microsomes and mitochondria suggesting that published estimates of the amounts of bile acids in these fractions are underestimates. 4. The model also allows the amount of bile acid which is in free solution in cytosol to be determined; 10.9% of the cholic acid conjugates and 4.1% of the chenodeoxycholic acid conjugates in rat liver were present in this fraction. Knowlege of the amount of free bile acid allows possible roles of the cytosolic bile binding proteins to be assessed.     

Effect of ethanol on the DNA-polymerase activity in the liver subcellular fractions of adult and old rats

The effect of 5% ethanol on DNA polymerase activity in nuclei, mitochondria, microsomes and cytosol of intact and regenerating liver of adult and old rats has been studied. No changes in DNA polymerase activity were detected in subcellular fractions of adult rat liver. On the contrary, the increased activity of intact liver nuclei and decreased activity of regenerating liver microsomes was observed with ageing. These age-dependent peculiarities of DNA polymerase activity in response to 5% ethanol may be related to changes in the enzyme molecules or microenvironment associated with ageing.     

Lipoperoxidation in hepatic subcellular compartments of diabetic rats

It is known that an accumulation of lipoperoxidative aldehydes malondialdehyde (MDA) and 4-hydroxynonenal (HNE) takes place in liver mitochondria during aging. The existence and role of an increased extra- and intra-cellular oxidative stress in diabetes, an aging-accelerating disease, is currently under discussion. This report offers evidence that lipoperoxidative aldehydes accumulate in liver microsomes and mitochondria at a higher rate in spontaneously diabetic BB/WOR rats than in control non-diabetic animals (HNE content, diabetes vs. control: microsomes 80.6+/-19.9 vs. 25.75+/-3.6 pmol/mg prot, p = .024; mitochondria 77.4+/-15.4 vs. 26.5+/-3.5 pmol/mg prot, p = .0103). Liver subcellular fractions from diabetic rats, when exposed to the peroxidative stimulus ADP/Fe, developed more lipoperoxidative aldehydes than those from non diabetic rats (HNE amount, diabetes vs. control: microsomes 3.60+/-0.37 vs. 2.33+/-0.22 nmol/mg prot, p = .014; mitochondria 3.62+/-0.26 vs. 2.30+/-0.17 nmol/mg prot, p = .0009). Liver subcellular fractions of diabetic rats developed more fluorescent chromolipids related to HNE-phospholipid adducts, either after in vitro peroxidation (microsomes: p = .0045; mitochondria: p = .0023) or by exposure to exogenous HNE (microsomes: p = .049; mitochondria: p = .0338). This higher susceptibility of diabetic liver membranes to the non-enzymatic attack of HNE may be due to an altered phospholipid composition. Moreover, a decreased activity of the HNE-metabolizing systems can be involved: diabetic liver mitochondria and microsomes were unable to consume exogenous HNE at the same rate as non-diabetic membranes; the difference was already significant after 5' incubation (microsomes p<.001; mitochondria p<.001). These data show an increased oxidative stress inside the hepatocytes of diabetic rats; the impairment of the HNE-metabolizing systems can play a key role in the maintenance and propagation of the damage.     

Electrolyte composition of cow and calf tissues in health and in acute digestive disturbances]

Sodium, potassium, calcium, magnesium, manganese, zinc and chloride contents in the blood plasma of calves at parturition have been established to correspond to their levels in blood of cows during their calving period. Iron and inorganic phosphorus contents in calves blood plasma appeared to increase and copper content to be lower in this period as compared to postnatal period. By the third day of postnatal ontogenesis sodium concentration in calves blood decreased, copper level increased and the rest indices of water-salts metabolism in calves and adult animals were alike. Digestion disturbances in the calves were accompanied by changes in levels and magnitude of Na+/K+ ratio, magnesium, iron, copper, manganese and zinc contents in blood, liver and kidneys as well as Ca++/Pi ratio in mitochondria and cytosol of liver and jejunum mucose layer cells in comparison with clinically healthy animals.     

Intracellular distribution of fumarase in various animals

The subcellular distribution of fumarase was investigated in the liver of various animals and in several tissues of the rat. In the rat liver, fumarase was predominantly located in the cytosolic and mitochondrial fractions, but not in the peroxisomal fraction. The amount of fumarase associated with the microsomes was less than 5% of the total enzyme activity. The investigation of the intracellular distribution of hepatic fumarase of the rat, mouse, rabbit, dog, chicken, snake, frog, and carp revealed that the amount of the enzyme located in the cytosol was comparable to that in the mitochondria of all these animals. The subcellular distribution of the enzyme in the kidney, brain, heart, and skeletal muscle of rat, and in hepatoma cells (AH-109A) was also investigated. Among these tissues, the brain was the only exception, having no fumarase activity in the cytosolic fraction, and the other tissues showed a bimodal distribution of fumarase in the cytosol and the mitochondria. The mitochondrial fumarase was predominantly located in the matrix. About 10% of the total fumarase was found in the outer and inner membrane, although it was unclear whether this fumarase was originally located in these fractions. No fumarase activity was detected in the intermembranous space.     

Effect of age and dietary protein level on tissue mineral levels in female rats

Mineral (phosphorus, sulfur, potassium, calcium, magnesium, iron, zinc, copper, and manganese) concentrations were measured in plasma, and several tissues from female Wistar rats (young: 3-wk-old; mature: 6-mo-old) were fed on a dietary regimen designed to study the combined or singular effects of age and dietary protein on mineral status. Three diets, respectively, contained 5, 15, and 20% of bovine milk casein. Nephrocalcinosis chemically diagnosed by increased calcium and phosphorus in kidney was prevented in rats fed a 5% protein diet. Renal calcium and phosphorus were more accumulated in young rats than mature rats. A 5% protein diet decreased hemoglobin and blood iron. The hepatic and splenic iron was increased by a 5% protein diet in mature rats but was not altered in young rats. Mature rats had higher iron in brain, lung, heart, liver, spleen, kidney, muscle, and tibia than young rats. A 5% protein diet decreased zinc in plasma and liver. Zinc in tibia was increased with dietary protein level in young rats but was not changed in mature rats. A 5% protein diet decreased copper concentration in plasma of young rats but not in mature rats. Mature rats had higher copper in plasma, blood, brain, lung, heart, liver, spleen, and kidney than young rats. With age, manganese concentration was increased in brain but decreased in lung, heart, liver, kidney, and muscle. These results suggest that the response to dietary protein regarding mineral status varies with age.     

The in vivo disposition of aflatoxin B1 in rat liver

The disposition of a non-toxic i.p. dose of [3H]-aflatoxin B1 (0.70 micrograms/kg) in the blood, plasma, and liver was studied in male Wistar rats. Uptake into the blood, plasma, and liver was biphasic; there was an initial rapid rise (0-2 hr) followed by a second phase (2-12 hr) of a gradual increase. Most of the radioactivity in the blood was bound noncovalently to albumin. Distribution of radioactivity in the subcellular fractions of liver showed that the microsomes exhibited the highest labeling which increased over the time course; labeling of the cytosol reached a maximum at 2 hr then decreased to a new steady state, whereas the mitochondria and nuclei reached a plateau. When the content of aflatoxin B1 in the nuclear subfractions was examined, greater than 92% of the total radioactivity was found in the deoxyribonucleoprotein fraction, and 84% of this was bound noncovalently. These results suggest that aflatoxin B1 is transported from the site of injection through the blood to the liver and its subcellular and subnuclear fractions primarily in a noncovalent form.     

The effects of age and sex on seven elements of Sprague-Dawley rat organs

This study reports age-related changes in 7 element (iron, copper, zinc, manganese, mercury, cadmium and lead) concentrations in the liver, kidney and brain of male and female Sprague-Dawley rats from 1 to 364 days of age. Atomic absorption spectrometry was used for the measurements. Copper, mercury and cadmium in the male and female kidneys increased from weaning until 127 days of age, as did iron concentrations in the female liver and kidney. After 127 days, especially, the copper concentration in the female kidney and cadmium concentration in the male and female kidney increased further. Consistent and statistically significant (P less than 0.05) sex differences in element concentrations were found for three elements (iron, copper and zinc). Except for the zinc concentration in the liver from 50 to 72 days, iron (in liver and kidney), zinc (in kidney) and copper (in liver, kidney and brain) concentrations in female rats during the adult stage, were all higher than those of male rats. Isolated differences for other elements (manganese, mercury and cadmium) were also found. The data will be helpful when setting up long-term animal investigations of the biological effect of elements.     

Subcellular distribution of tissue radiocopper following intravenous administration of 67Cu-labeled Cu-PTSM

The subcellular distribution of radiocopper in the brain and liver of rats has been determined following i.v. administration of Cu-PTSM, pyruvaldehyde bis(N⁴-methylthiosemicarbazonato)copper(II), labeled with copper-67. Homogenized tissue samples were separated by differential centrifugation into four subcellular fractions: (I) cell membrane + nuclei; (II) mitochondria; (III) microsomes; and (IV) cell cytosol. Upon sacrifice at 10 min post-Cu-PTSM injection, brain fractions, I, II, III and IV contain 35 ± 12, 11 ± 3, 2.8 ± 1.3 and 51 ± 7% of brain activity, respectively (n = 4). In animals sacrificed 24 h post-injection the subcellular fractions of brain tissue show little change from the radiocopper distribution seen at 10 min post-injection, although the mitochondrial fraction may contain slightly more tracer and the cytosolic fraction slightly less (I, 40 ± 10%; II, 18 ± 5%; III, 3.4 ± 1.5%; and IV, 38 ± 5%; n = 5). Subcellular fractions I, II, III and IV of liver contain 25 ± 5, 12 ± 3, 17 ± 4 and 46 ± 6% of ⁶⁷Cu tracer in animals sacrificed 10 min post-Cu-PTSM injection. An identical subcellular distribution of ⁶⁷Cu, was found in the liver following i.v. administration of ionic radiocopper (as Cu-citrate). The liver and brain cytosolic fractions at 10 min post-injection were further separated by Sephadex column chromatography. In liver cytosol, three different radiocopper components with molecular weights of about 140,000, 41,000–46,000 and 10,000–16,000 Da were found. In the brain supernatant fraction, most of the radiocopper was bound to a single low molecular weight cytosolic component (14,000–16,000 Da). These results suggest that the intracellular decomposition of tracer Cu-PTSM may result in the radiocopper entering the normal cellular pools for copper ions.     

Effect of sodium valproate on subcellular fraction enzymes in rat liver

Previous observations that valproic acid (VPA) causes hepatic damage prompted us to investigate the effect of large doses of the drug (0.6, 1.2 and 1.8 mmol/kg/day) on a number of liver enzymes located on different subcellular fractions. In mitochondria, glutamate dehydrogenase, aspartate aminotransferase and ornithine carbamoyltransferase were significantly increased (1.8 mmol/kg/day). In microsomes, gamma-glutamyltransferase activity increased significantly (1.8 mmol/kg) and cytochrome P-450 content decreased significantly (1.2 and 1.8 mmol/kg). In cytosol, both aspartate and alanine aminotransferase activities were increased at all dose levels. These results indicate that VPA induces dose-dependent changes in some liver enzyme activities.     

Effect of clofibrate treatment on lipid peroxidation in rat liver homogenate and subcellular fractions

1. A study was made of the effect of hypolipidemic drug clofibrate on the level of lipid peroxidation in homogenates and subcellular fractions of rat liver. The intensity of lipid peroxidation was measured using chemiluminescence technique and malondialdehyde formation. 2. It was shown that under the action of clofibrate the levels of Fe/ADP-ascorbate-, as well as t-butyl hydroperoxide (Bu'OOH)-induced lipid peroxidation were decreased in the whole and "post-nuclear" liver homogenates. Dilution of the homogenates prevented depressing effect of clofibrate on lipid peroxidation. 3. Clofibrate significantly decreased the level of the Bu'OOH-dependent lipid peroxidation, but did not affect the activity of the Fe/ADP-ascorbate-induced reaction in rat liver mitochondria and microsomes. 4. Peroxidative alteration of membrane lipids in vivo was evaluated by determining the extent of conjugated dienes formation (absorption at 233 nm). It was shown that clofibrate did not increase the level of ultraviolet absorption of lipids from rat liver subcellular fractions. 5. The data obtained indicate that cytosol from the clofibrate treated rat liver contains a factor(s) which prevents lipid peroxidation in the mitochondria and microsomes.