Purification and characterization of a novel abundant protein in rat bile that binds azo dye metabolites and copper

Copper Homeostasis in Mammals, with Emphasis on Secretion and Excretion. A Review

One of the hallmarks of Cu metabolism in mammals is that tissue and fluid levels are normally maintained within a very narrow range of concentrations. This results from the ability of the organism to respond to variations in intake from food and drink by balancing excretion, which occurs mainly via the bile and feces. Although this sounds straightforward and we have already learned a great deal about aspects of this process, the balance between overall intake and excretion occurs over a high background of Cu recycling, which has generally been ignored. In fact, most of the Cu absorbed from the GI tract actually comes from digestive fluids and is constantly “re-used”. A great deal more recycling of Cu probably occurs in the interior, between cells of individual tissues and the fluid of the blood and interstitium. This review presents what is known that is pertinent to understanding these complexities of mammalian Cu homeostasis and indicates where further studies are needed.

Hepatic binding proteins translocating azo dye carcinogen metabolites from cytoplasm into nucleus in rats

When liver cytosol prepared from rats administered [(14)C]-3'-Methyl-N,N-dimethyl-4-aminoazobenzene was subjected to Sephadex gel chromatography, four peaks of radioactivity containing proteins (Peak-I-IV) and one peak devoid of protein (Peak-V) were obtained. Translocation of azo dye metabolites from these various cytosolic fractions into nucleus was studied in an in vitro system and a maximum of about 10% of the radioactivity associated with a particular cytosolic fraction (Peak-II) could translocate into the nuclei. Radioactivity (%) translocated did not increase upon addition of excess nuclei. Passage of this protein fraction through an immobilized protease column reduced the azo dye metabolite translocation by 65%, concomitant with the degradation of proteins. Translocation was not observed with protein-free metabolites extracted from this cytosolic fraction; addition of proteins corresponding to peak-II from normal rat liver cytosol significantly restored the metabolite translocation. This observation suggests that specific cytosolic proteins are involved in the translocation of azo dye carcinogen metabolites from liver cytoplasm into the nucleus. When the liver cytosolic proteins corresponding to this fraction (Peak-II) were iodinated with (125)I-iodine and incubated with purified nuclei, translocation of three specific proteins into nucleus was observed as seen by SDS-PAGE and fluorography of nuclear proteins. Covalent binding of azo dye metabolites to DNA was not observed when cytosolic peak-II fraction containing azo dye metabolites was incubated with isolated liver DNA instead of liver nuclei. This suggests that the interaction of azo dye metabolites with nuclear macromolecules necessitate further prior processing which actually may occur in the nucleus.

Binding of brominated diphenyl ethers to male rat carrier proteins

1. Two [(14)C]-labelled brominated diphenyl ethers, 2,2',4,4',5-pentabromodiphenyl ether (BDE-99) and decabromodiphenyl ether (BDE-209), were separately administered to the male Sprague-Dawley rat as a single oral dose (2.2 mg kg(-1) body weight and 3.0 mg kg(-1), respectively). 2. Very low [(14)C] urine excretion was observed for both congeners (<1% of the dose), and cumulative biliary excretion was approximately 4% for BDE-99 and 9% for BDE-209. 3. More than 6% of the pooled urine from the BDE-99-treated rat was protein-bound to an 18-kDa protein characterized by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and Western immunoblot analysis as alpha(2u)-globulin. Eighteen per cent of the radioactivity from the pooled urine from the BDE-209 treated rat was bound to albumin; no binding to alpha(2u)-globulin was detected. 4. In bile, 27-39% of the radioactivity from the BDE-99-dosed rat was bound to an unidentified 79-kDa protein, whereas essentially all (>87%) of the biliary radioactivity from BDE-209 was bound to the 79-kDa protein. Both parent BDE-99 and-209 and their metabolites were detected by thin layer chromatography in the extracted fraction of this bile protein. 5. By differential centrifugation, the subcellular localization of the (14)C derived from each congener in selected tissues was quantified. The cytosolic [(14)C] from livers of the BDE-209-treated rat was bound to a 14-kDa protein, which was characterized as a fatty acid-binding protein.

Two forms of Wilson disease protein produced by alternative splicing are localized in distinct cellular compartments

Copper is an essential trace element in prokaryotes and eukaryotes and is strictly regulated by biological mechanisms. Menkes and Wilson diseases are human disorders that arise from disruption of the normal process of copper export from the cytosol to the extracellular environment. Recently a gene for Wilson disease (WD)(also named the ATP7B gene) was cloned. This gene encodes a copper transporter of the P-type ATPase. We prepared monoclonal and polyclonal anti-(WD protein) antibodies and characterized the full-length WD protein as well as a shorter form that is produced by alternative splicing in the human brain. We found that the WD protein is localized mainly in the Golgi apparatus, whereas the shorter form is present in the cytosol. These results suggest that the alternative WD proteins act as key regulators of copper metabolism, perhaps by performing distinct roles in the intracellular transport and export of copper.

Protein binding, nuclear translocation and biliary secretion of metabolites of 3'-methyl-N,N-dimethyl-4-aminoazobenzene during hepatocarcinogenesis in rats

1. The hepatic content, biliary excretion, cytosolic protein binding and nuclear translocation of metabolites of i.v. administered 14C-3'-methyl-N,N-dimethyl-4-aminoazobenzene (3'-methyl-DAB) were investigated in rats at various stages of 2-acetamidofluorene (AAF)-induced hepatocarcinogenesis. 2. At nodular and post-nodular stages biliary excretion of radioactive metabolites was decreased, although hepatic content of radioactivity was similar to controls not dosed with AAF. The secretion in bile of a major azo dye binding protein was also decreased at these stages. 3. Binding of dye metabolites to cytosolic proteins was decreased by 40% at nodular and post-nodular stages compared to controls. 4. Translocation in vitro of dye metabolites from cytosol to nucleus at nodular and post-nodular stages was 40% less than that of controls. Since specific soluble proteins control translocation from cytosol into the nucleus (and bile), this decreased binding of metabolites may explain the diminished translocation of carcinogen metabolites into the nucleus.

Mechanisms of metal transport across liver cell plasma membranes

The liver's pivotal role in the homeostasis of essential trace metals and detoxification of exogenous metals is attributed to its ability to efficiently extract metals from plasma, metabolize, store, and redistribute them in various forms either into bile or back into the bloodstream. Bidirectional transport across the sinusoidal plasma membrane allows the liver to control plasma concentrations and therefore availability to other tissues. In contrast, transport across the canalicular membrane is largely, but not exclusively, unidirectional and is a major excretory pathway. Although each metal has relatively distinct hepatic transport characteristics, some generalizations can be made. First, movement of metals from plasma to bile follows primarily a transcellular route. The roles of the paracellular pathway and of ductular secretion appear minimal. Second, intracellular binding proteins and in particular metallothionein play only indirect roles in transmembrane flux. The amounts of metallothionein normally secreted into plasma and bile are quite small and cannot account for total metal efflux. Third, metals traverse liver cell plasma membranes largely by facilitated diffusion, and by fluid-phase, adsorptive, and receptor-mediated endocytosis/exocytosis. There is currently no evidence for primary active transport. Because of the high rate of hepatocellular membrane turnover, metal transport via endocytic vesicles probably makes a larger contribution than previously recognized. Finally, there is significant overlap in substrate specificity on the putative membrane carriers for the essential trace metals. For example, zinc and copper share many transport characteristics and apparently compete for at least one common transport pathway. Similarly, canalicular transport of five of the metals discussed in this overview (Cu, Zn, Cd, Hg, and Pb) is linked to biliary GSH excretion. These metals may be transported as GSH complexes by the canalicular glutathione transport system(s). Unfortunately, none of the putative membrane carrier proteins have been studied at the subcellular or molecular level. Our knowledge of their biochemical properties is rudimentary and rests almost entirely on indirect evidence obtained in vivo or in intact cell systems. The challenge for the future is to isolate and characterize these putative metal carriers, and to determine how they are functionally regulated.

Site-directed inactivation of human lung acidic glutathione S-transferase by 1-chloro-2,4-dinitrobenzene in the absence of glutathione

Human lung acidic glutathione S-transferase is irreversibly inhibited by 1-chloro-2,4-dinitrobenzene (CDNB) in the absence of the co-substrate glutathione (GSH). The time-dependent inactivation is pseudo-first-order and demonstrates saturation kinetics, suggesting that inactivation occurs from an EI complex. The Ki was 0.14 mM; and kobs was 0.32 min-1 at 0.6 mM CDNB. The enzyme was protected against CDNB inactivation by GSH. The other two classes of glutathione S-transferase, the basic and near-neutral, are not significantly inactivated by CDNB. Incubation with [14C]CDNB indicated covalent binding to all three classes of transferase. One peptide fraction was found to be radiolabelled in both the basic and acidic transferases when these were incubated with [14C]CDNB and GSH, cleaved with cyanogen bromide, and chromatographed by HPLC. Incubation in the absence of GSH yielded one and two additional labelled peptide fractions for the basic and acidic transferases, respectively. Our results suggest that while CDNB arylates all three classes of human transferases, only the acidic transferase possesses a specific GSH-sensitive CDNB binding site, binding to which leads to time-dependent inactivation.

Binding of sulfobromophthalein to rat and human ligandins: characterization of a binding-site peptide

Photoaffinity techniques were employed to affect the covalent binding of [35S]sulfobromophthalein to proteins of rat and human liver cytosol. In rat liver cytosol at low concentrations, sulfobromophthalein bound to the 22 kDa subunit of ligandin. In human liver cytosol, binding to a 23.5 kDa subunit was observed. At higher concentrations, sulfobromophthalein also bound to 12, 23.5, 37, and 42 kDa peptides. When the peptides resulting from CNBr cleavage of [35S]sulfobromophthalein-ligandin complex were resolved by high-performance liquid chromatography, radioactivity was associated with two peptides. The peptide containing 80% of the radioactivity was isolated and characterized. Its molecular weight is 3.4 kDa, it contains the single tryptophan residue of ligandin and has a glutamate (glutamine) as the N-terminal amino acid.

Intestinal uptake and retention of copper in the suckling rat, Rattus rattus--IV. Mechanisms of intestinal copper accumulation

Copper-67, administered either parenterally or via the maternal milk, accumulates principally in the intestine and liver of the 6-day-old pup. Most of the 67Cu in the soluble fraction of the intestine is associated with the heterogeneous Cu-complex, which is located predominantly in the ileum. The rates of uptake and loss of 67Cu in the liver and intestine indicate that enterohepatic circulation of Cu in the neonate is appreciable. Whilst the concentration of Cu in the bile of the 13-day-old pup is high (16-fold greater than that in the adult male rat), translocation of Cu from both the liver and duodenum to the ileum probably occurs via the blood, rather than by the reabsorption of biliary Cu. Although the Cu-complex normally seems to be retained within the distal intestine until the enterocytes are desquamated, Cu in this form is utilized when the Cu-intake of the neonate is restricted.

Strain-related patterns of biliary excretion and hepatic distribution of copper in the rat

Biliary copper excretion was studied in male, bile-cannulated rats of the inbred strains Fischer, Brown Norway, WAG/Rij and Lewis. After intravenous injection of 10, 30 and 50 micrograms copper per 100 gm body weight, two patterns of copper excretion were observed; their profiles varied with the copper dose and the strain of the rats used. The lowest amounts of copper were excreted by Fischer rats, the highest by WAG/Rij rats; this was related to the effect of the copper dose on both patterns. The subcellular distribution of copper in the liver was studied in Fischer and Brown Norway rats after doses of 50, 100, and 200 micrograms per 100 gm body weight. Brown Norway rats accumulated more copper in the liver, although the copper concentration was the same in both strains 1 hr after injection of all doses. Fischer rats accumulated proportionally more copper in lysosomal and nuclear mitochondrial fractions whereas Brown Norway rats accumulated proportionally more copper in the cytosol. Gel filtration of liver supernatants revealed that the amount of copper accumulating in the protein presumed to be metallothionein was 2 to 3 times higher in Brown Norway rats, whereas in the Fischer rats more copper eluted in the void volume fraction. We conclude that both biliary copper excretion and copper distribution in the liver are under genetic control. Because of its low copper excretion and reduced binding of copper to metallothionein the Fischer rat, compared to other strains, may be a suitable model for studying the involvement of the liver in copper intoxication.

Biliary copper excretion in the chicken

A series of experiments were performed to examine the nature of biliary copper excretion in the chicken. Gallbladder and hepatic bile were collected from chickens fed diets that altered copper excretion. Bile was fractionated using gel filtration chromatography and SDS-PAGE. Chicks fed the control diet excreted copper that was bound primarily to a protein aggregate of greater than 600,000 daltons and secondarily, to a 7400 dalton compound. When biliary copper levels were elevated, the distribution of copper associated with the binding compounds was changed. Both the proportion and the absolute amounts of copper in the secondary pool increased dramatically when biliary copper increased. The excretion patterns observed in the control animals are believed to represent the steady-state distribution of copper in bile. A similar distribution was observed with rat bile that was obtained under steady-state conditions. These distribution patterns differ from those reported by other investigators who examined biliary copper excretion in the rat using different experimental conditions.

Biliary excretion of metallothionein and a possible degradation product in rats injected with copper and zinc

The concentrations of metallothionein-I (MT-I) and related immunoreactive products in bile from adult female rats were measured by radioimmunoassay. Concentrations in normal animals were 20-30 ng/ml, but increased to 600 and 75 ng/ml after injection of Cu2+ and Zn2+ respectively (3 mg of metal/kg body wt.). However, only 1-2% of the biliary Cu was bound to MT, and less than 1% of the total liver MT in control or Cu2+-injected rats appeared to be secreted in intact form into bile. Other major immunoreactive components in bile from Cu2+-injected rats included an aggregated form of MT-I and a possible degradation product of the isoprotein.

Biliary proteins

The study of biliary proteins has grown enormously in the last 10 years. Although much has been recently learned about the nature, origin and hepatobiliary transport of these proteins, little is known of their function in bile or their effect on its physical state. This review will focus on description of the proteins and mechanisms by which they are secreted into bile.