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.     

In vitro incorporation of ( 3 H) methyl choline into phosphatidyl choline of rat liver subcellular fractions

Incubation of a rat liver total homogenate with radioactive choline and subsequent isolation of subcellular fractions, at different times, showed similar patterns of labeling. Incubation of microsomes, mitochondria and purified nuclei isolated from rat liver, showed that all fractions were able to incorporate the precursor into phosphatidyl choline. The specific activity was higher in mitochondria and increased in all cases with added supernatant. The addition of microsomes to mitochondria diminished the incorporation of label. Contamination of mitochondria by microsomes, was negligible as shown by undetectable amounts of cytochrome P₄₅₀, while NADPH₂ cytochrome c reductase showed a 10% contamination. A certain amount of radioactivity was incorporated in the absence of ATP and oxidizable substrates due to the presence of substrates and cofactors in the fraction and/or the supernatant. Labeled fractions reincubated with unlabeled choline, showed no loss of radioactivity, proving that incorporation was not due to simple exchange processes. It is concluded that although rat liver mitochondria can acquire part of their own provision of phosphatidyl choline by transference from microsomes, all organelles and specially mitochondria, can independently synthesize this phospholipid.     

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.     

Studies on mouse liver urate oxidase

Summary Distribution of urate oxidase in subcellular components such as nuclei, mitochondria, lysosomes, microsomes, and cell sap, was investigated by both enzymatic and immunochemical methods. The subcellular components were prepared from mouse liver homogenate by differential centrifugation and the resulting microbody-rich mitochondrial fraction was fractionated by sucrose density gradient centrifugation. The enzymatically determined urate oxidase was distributed mainly in mitochondrial and lysosome fractions. The immunochemically assayed urate oxidase antigen was localized in mitochondrial, lysosome, and microsome fractions. The antigen to enzyme ratio was 1.0 in the mitochondrial and lysosome fractions, and about 2.0 in the microsome fraction.Sucrose density gradient centrifugation of the mitochondrial fraction indicated that the urate oxidase antigen was distributed around three density bands of 1.07, 1.15, and 1.24. The main band (1.24) was consistent with the microbody fraction. From these results, it was suggested that a precursor protein (proenzyme) might be located in the microsome fraction.This work was supported in part by a grant 777007 from the Ministry of Education, Japan, in 1972.     

Subcellular distribution and properties of alkaline inorganic pyrophosphatase of maize leaves.

1. Studies on the distribution of alkaline inorganic pyrophosphatase (pyrophosphate phosphohydrolase, EC 3.6.1.1) in the subcellular fractions of maize leaves showed that the enzyme is present in cytoplasm, chloroplasts and mitochondria. The activity observed in nuclei and microsomes may result from contamination with the mitochondrial fraction. 2. Alkaline pyrophosphatases from three subcellular fractions were purified by fractionation with (NH4)2SO4, followed by ion-exchange and gel-filtration chromatography, and by isoelectric focusing. Highly purified enzyme preparations, with specific activities ranging from 55 to 188 micronmoles/min/mg protein, were obtained. 3. All the enzymes exhibited the maximum activity at pH 8.5 and the Mg2+/PPi ratio of 5. They differed in electrophoretic mobility, pI, and susceptibility to urea and thermal denaturation. This indicates that they represent isoenzymes compartmentized in particular subcellular fractions.     

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.     

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.     

Transfer of proteins synthesized in the cytoplasm into mitochondria. Stimulation of mitochondrial protein synthesis by microsomal fraction]

The in vitro transport into mitochondria of proteins synthesized in the cytoplasm was studied. The system, in which the microsomes synthesize protein in the presence of mitochondria directly during the experiment proved to be the most efficient one. The microsomal fraction significantly stimulated the incorporation of 14C-valine into the isolated mitochondria proteins. The effects of EDTA treatment of the mitochondrial fraction, the dependence of protein synthesis stimulation on the ratio of mitochondria and microsomal proteins and the kinetic pattern of the reaction suggest that the stimulation of the labelled precursor incorporation into mitochondrial proteins is not probably due to the labelled microsomes adsorption on the mitochondria.     

Plasmalogen distribution in the subcellular fractions of the vertebrate brain

Studies have been made on plasmalogen and diacylic forms of phospholipids, i. e. phosphatidylethanolamine and phosphatidylcholine (their relative content and ratio), in subcellular fractions isolated from the brain of the trout Salmo trideus, frog Rana temporaria, pigeon Columba livia, tortoise Testudo horsfieldi, and rabbit. Investigation was carried out on 5 subcellular fractions (myelin, nuclei, microsomes, mitochondria, synaptosomes) as well as on brain homogenates. In all the fractions, relative content of plasmalogens is the lowest in the trout, increasing in parallel with the increase in the complexity of the nervous system and reaching the highest values in pigeons and rabbits.     

Calcium distribution in islets of Langerhans: a study of calcium concentrations and of calcium accumulation in B cell organelles.

Calcium concentrations of various pancreatic B cell organelles have been determined by X-ray microanalysis of areas of frozen sections of unfixed rat islets of Langerhans. Highest concentrations were detected in storage granules and in mitochondria, although calcium was also present in nuclei, in areas of endoplasmic reticulum and of cytoplasm. Accumulation of 45Ca by isolated organelles has been studied in homogenates and isolated subcellular fractions of rat islets of Langerhans. In the presence of a permeant anion (oxalate or phosphate), accumulation of 45Ca into mitochondria and microsomes was strongly stimulated by ATP. This net uptake was diminished during incubation of homogenates or of a mitochondria plus storage granule-rich fraction in the presence of cyclic AMP, dibutyryl cyclic GMP; 2:4-dinitrophenol or of ruthenium red. Investigations of the characteristics of 45Ca accumulation by homogenates prepared from storage granule-depleted islets showed no differences from those of normal islets, suggesting that the granules do not represent an important labile pool of calcium. With the exception of cyclic AMP and cyclic GMP none of the insulin secretagogues tested (glucose, leucine, arginine, adrenalin, noradrenalin, theophylline, glibenclamide) altered calcium accumulation by islet homogenates. On the basis of absolute calcium levels and of 45Ca uptake studies it is concluded that islet B cells contain a readily exchangeable mitochondrial calcium pool, and an endoplasmic reticulum pool containing a lower concentration of calcium which is also readily exchangeable. The storage granules, despite their high calcium content, do not appear to constitute a labile pool. It seems likely that the labile mitochondria and endoplasmic reticulum pools play a predominant role in the regulation of cytoplasmic free calcium levels, which may in turn be important in the regulation of rates of insulin secretion.     

Effect of undernutrition on DNA and RNA synthesis in subcellular fractions from different regions of the developing rat brain

The effect of undernutrition on the incorporation of [methyl-³H]thymidine into DNA and of 5-[³H]uridine into RNA of cerebral hemispheres, cerebellum, and brain stem was studied in vivo and in vitro in rats. The labeling of DNA from nuclei and mitochondria and of RNA from nuclei, mitochondria, microsomes, and soluble fractions, was also measured in vitro. The results demonstrate that nucleic acid synthesis is impaired and delayed during undernutrition. Specific effects were observed for the different brain regions and subcellular fractions: at 10 days nuclear and mitochondrial DNA and RNA synthesis was impaired, whereas at 30 days only the mitochondrial nucleic acid synthesis was affected.The delay of DNA and RNA labeling, caused by undernutrition, was most evident in the cerebellum, probably due to its intense cell proliferation during postnatal development. The specific sensitivity of mitochondria as compared to other subcellular fractions, may be due to the intense biogenesis and/or turnover of nucleic acids in brain mitochondria not only during postnatal development, but also in the adult animal.     

Progesterone in the uterus. VII. Uptake of cortisol and incorporation of progesterone under simultaneous application of cortisol into rat uterus

After injection of radioactively labelled Cortisol, the distribution of the radioactivity in the subcellular fractions of the rat uterus (nuclei, mitochondria, microsomes and 105 000 × g supernatant) was studied. In all fractions, radioactivity was observed and maxima were found 10, 20 and 50 min. after injection of the labelled hormone. Radioactivity was measured in all subcellular fractions even 180 min. after application of labelled cortisol. Additionally, radiolabelled progesterone and unlabelled cortisol in the ratio 1:1 or 1:2 (moles:moles) were injected into the animals. Studying the uptake of labelled progesterone in the subcellular fractions of the uterine tissue, revealed that no competition of unlabelled cortisol could be observed 10, 20 and 50 min. after application of the hormone mixture, compared with the control experiments. The results of this study give evidence that the progesterone uptake into rat uterus is specific and cannot be influenced by unlabelled cortisol.     

Characterization of electron transport enzymes in the envelope of rat liver nuclei.

Nuclei and microsomes were prepared from the livers of normal, phenobarbital (PB)-treated and beta-naphthoflavone (beta-NF)-treated rats, and the contents of several enzymes in both subcellular fractions were examined. In normal rats, the enzyme activities in the nuclear fraction were about one-third of those of microsomes on a phospholipid basis. The induction of some particular enzymes by the drugs was observed with nuclei as well as with microsomes. Cytochrome P-450 and NADPH-cytochrome c reductase were increased by PB treatment and cytochrome P-448 was induced by beta-NF treatment both in nuclei and in microsomes. The extents of inhibition of nuclear enzyme activities by the antibodies against corresponding microsomal enzymes were almost the same as those of the microsomal activities. It was concluded that a microsomal type electron transport system exists in rat liver nuclei, and that nuclear drug-oxidizing activities are inducible by PB or beta-NF as their microsomal counterparts are.     

Optimal assay and subcellular location of phosphatidylglycerol synthesis in lung

Synthesis of phosphatidylglycerol from CDPdiacylglycerol and glycerol 3-phosphate by membranous subcellular fractions of rat lung and liver was optimal when assayed in the presence of bovine serum albumin and Triton X-100. Specific activities of glycerolphosphate phosphatidyltransferase in all membranous subcellular fractions of lung were several times higher than the corresponding fractions from liver. Distribution of this enzyme in subcellular fractions of lung or liver closely parallel the activity of the mitochondrial enzymes monoamine oxidase and succinate cytochrome c reductase. The phosphatidylglycerol-synthesizing activity in microsomes of both lung and liver was a minor fraction of total tissue activity and could be interpreted as due either to contamination with outer mitochondrial membrane or to a small amount of activity innate to microsomes. These results suggest that phosphatidylglycerol, which is believed to be a component of pulmonary surfactant, is synthesized by lung at a rapid rate relative to liver and that the subcellular distribution of its synthesis is similar in both tissues, with mitochondria as the major site.     

Coordinated regulation of free Ca2+ by isolated organelles from a rat insulinoma

Experiments aimed at the partial reconstitution of the intracellular transport systems regulating the cytosolic free Ca2+ homeostasis are reported. Rat insulinoma subcellular fractions enriched in mitochondria, endoplasmic reticulum (microsomes), and secretory granules were studied. The ambient free Ca2+ concentration maintained by the separate or combined organelles was determined with a Ca2+-selective minielectrode. The data demonstrate that ambient [Ca2+] is established by the microsomes, not by the mitochondria or the secretory granules, in the range of resting cytosolic Ca2+ concentrations (0.1-0.2 microM Ca2+). Furthermore, the microsomes are able to deplete largely the mitochondria of their exchangeable calcium. Nonetheless, both mitochondria and microsomes, but not secretory granules, function as a coordinated unit to restore the previous ambient [Ca2+] following its perturbation. Thus, mitochondria play a major role in bringing down rapidly ambient [Ca2+] to the submicromolar range, whereas the endoplasmic reticulum acts as a relay in the transport mechanisms which lower [Ca2+] to the resting level.     

Subcellular distribution of transferrin-bound zinc incorporated by phytohemagglutinin-stimulated and unstimulated human lymphocytes

The distribution of transferrin-bound zinc incorporated by phytohemagglutinin-stimulated and unstimulated human lymphocytes has been studied as a function of time in four subcellular fractions (nuclei, mitochondria, microsomes, and soluble). In untreated lymphocytes, the percent of total incorporated zinc in each fraction remains relatively constant over 72 h in culture. However, there is a time-dependent change in the percent of total incorporated zinc in all fractions isolated from phytohemagglutinin-stimulated cells, and this change is most apparent for the nuclear and soluble fractions. Apparently some sustained production of energy is required for this change in subcellular distribution of zinc to occur. Additionally, the uptake of cytoplasmic zinc by purified lymphocyte nuclei has been studied. Uptake is rapid and occurs maximally under conditions known to be optimal for stimulation of nuclear adenylate cyclase.     

Selective protection of nuclear thioredoxin-1 and glutathione redox systems against oxidation during glucose and glutamine deficiency in human colonic epithelial cells

Little is known about the relative sensitivities of antioxidant systems in nuclei, mitochondria, and cytoplasm. The present study examined the oxidation of the thiol-dependent antioxidant systems in these subcellular compartments under conditions of limited energy supply of human colonic epithelial HT-29 cells induced by depletion of glucose (Glc) and glutamine (Gln) from the culture medium. Increased oxidation of dichlorofluoroscein (DCF) indicated an increased level of reactive oxygen species (ROS). Redox Western blot analysis showed oxidation of cytosolic thioredoxin-1 (Trx1) and mitochondrial thioredoxin-2 (Trx2) by 24 h, but little oxidation of nuclear Trx1. The Trx1 substrate, redox factor-1 (Ref-1), was also oxidized in cytosol but was reduced in nuclei. Protein S-glutathionylation (PrSSG), expressed as a ratio of protein thiol (PrSH), was also increased in the cytosol, while nuclear PrSSG/PrSH was not. Taken together, the data show that oxidative stress induced by depletion of Glc and Gln affects the redox states of proteins in the cytoplasm and mitochondria more than those in the nucleus. These results indicate that the nuclear compartment has better protection against oxidative stress than cytoplasm or mitochondria. These results further suggest that energy and/or substrate supply may contribute to sensitivity of mitochondrial and cytoplasmic systems to oxidative damage.     

The subcellular localization of enzymes of dolichol metabolism in rat liver

Dolichyl phosphate is an intermediate in the glycosylation of N-glycosamidic linked glycoproteins in mammalian systems, and its availability may be a limiting factor in glycoprotein biosynthesis. The basic kinetics and subcellular distribution of enzymes which may influence the concentration of dolichyl phosphate in rat liver have therefore been investigated. These include dolichyl phosphate phosphatase, dolichol phosphokinase, dolichyl fatty acyl ester synthetase, GDP-mannose dolichyl phosphate mannosyl transferase, and UDP-glucose dolichyl phosphate glucosyl transferase. The specific activity of the enzymes was highest in the microsomes, except for dolichyl phosphate phosphatase and dolichyl fatty acyl ester synthetase, which were most concentrated in the plasma membrane and the cytosol fraction, respectively. The nuclei contained all of the enzyme activities while the mitochondria and cytoplasm were generally less active. The presence of both dolichol phosphokinase and dolichyl phosphate phosphatase in microsomes and nuclei, which contain the highest glycosyl transferase activities, may provide a means for direct enzymatic control of levels of dolichyl phosphate.     

Effect of CDP-choline on the biosynthesis of nucleic acids and proteins in brain regions during hypoxia

The effect of CDP-choline on the in vivo incorporation of labeled precursors into DNA, RNA, and proteins in cerebral hemispheres, cerebellum, and brainstem of guinea pigs after hypoxic treatment was studied. The labeling of macromolecules extracted from the various subcellular fractions of these brain regions was also determined. Hypoxic treatment affected macromolecular labeling to a different extent in the three brain regions examined. CDP-choline treatment was not able to reverse the effect of hypoxia on DNA labeling, but it was able to remove the effect of hypoxia on RNA and protein labeling. The action of CDP-choline was particularly evident on the labeling of RNA in nuclei and mitochondria of the cerebellum and on the labeling of proteins in microsomes of the three brain regions examined.     

Intracellular distribution of heat-induced stress glycoproteins

Cellular heat stress results in elevated heat-shock protein (HSP) synthesis and in thermotolerance development. Recently, we demonstrated that protein glycosylation is also an integral part of the stress response with the identification of two major stress glycoproteins, GP50, associated with thermotolerance, and P-SG67, the “prompt” stress glycoprotein induced immediately during acute heat stress. In the present study, we characterized the subcellular location and redistribution of these proteins during the cellular injury and recovery phase. In unheated and heated CHO cells, both stress glycoproteins were present in each subcellular fraction isolated by differential centrifugation. However, the subcellular redistribution in the course of cellular recovery after heat stress was specific for each stress glycoprotein. GP50 was present in all subcellular fractions before heat stress, but showed relatively little redistribution after heat stress. By 24 h of recovery following stress, GP50 showed partial depletion from lysosomes and microsomes, and was mainly present in the mitochondria. Glycosylated P-SG67 was redistributed in a more complex fashion. It was seen predominantly in the lysosomes and microsomes immediately following heat-stress, but after 6 h of recovery following heat stress, it largely disappeared from the microsomes and was present mainly in the cytosol. By 24 h of recovery following heat stress, it was found predominantly in the nucleus-rich fraction and mitochondria. The localization of GP50 and P-SG67 by subcellular fractionation is consistent with immunolocalization studies and contrasts with the translocation of HSP70 after heat stress from cytosol to nuclei and nucleoli. These results reflect a characteristic distribution for each stress glycoprotein; their presence in virtually all subcellular fractions suggests multifunctional roles for the various stress glycoproteins in the cellular heat stress response. J. Cell. Biochem. 66:98–111, 1997. © 1997 Wiley-Liss, Inc.