Regulation of alkaline phosphatase activity in rat hepatoma cells. Effects of serum proteins, cycloheximide, actinomycin D, chloroquine, dinitrophenol and potassium cyanide

Alkaline phosphatase activity in rat hepatoma cells (R-Y121B) cultured in a monolayer at 0.5% serum was enhanced by serum, bovine serum albumin, casein and gamma-globulin, but ovalbumin, polyvinylpyrrolidone, dexamethasone, insulin and dibutyrylcyclic AMP showed little effect on alkaline phosphatase activity. In addition, cycloheximide, actinomycin D, chloroquine, dinitrophenol and potassium cyanide also increased the enzyme activity, although the incorporation of [14C]leucine into cellular proteins was almost completely inhibited in the presence of these cytotoxic substances. When R-Y121B cell homogenates were incubated at 37 degrees C, alkaline phosphatase activity increased in a pH-dependent manner: the maximal increase was observed at pH 7.1. The magnitudes of the increase differed among cell homogenates and a 4- to 10-fold increase was observed. Alkaline phosphatase in R-Y121B cells was apparently heat-stable, but that in the cells obtained from various treatments was heat labile and the latter activity decreased to less than 50% of the initial activity after 15 min of incubation at 56 degrees C. Alkaline phosphatase in the control and also in the treated cells was more sensitive to L-homoarginine than L-phenylalanine. The Lineweaver-Burk plot showed that the increases in the enzyme activity were accompanied by changes not only in V but also in Km for alkaline phosphatase reaction. Finally, it has been suggested that the increases in alkaline phosphatase activity under various conditions are due to the conversion of the molecule with a low enzyme activity to the molecule with a high enzyme activity in R-Y121B cells.     

Activation of alkaline phosphatase with Mg2+ and Zn2+ in rat hepatoma cells. Accumulation of apoenzyme

In Reuber rat hepatoma cells (R-Y121B), alkaline phosphatase activity increased without de novo enzyme synthesis (Sorimachi, K., and Yasumura, Y. (1986) Biochim. Biophys. Acta 885, 272-281). The enzyme was partially purified by butanol extraction from the particulate fractions. The incubation of the extracted alkaline phosphatase with the cytosol fraction induced a large increase in enzyme activity (5-10-fold of control). The dialyzed cytosol was more effective than the undialyzed cytosol during an early period of incubation at 37 degrees C. This difference between the dialyzed and the undialyzed cytosol fractions was due to endogenous Na+. For maximal activation of the enzyme, both Mg2+ above 1 mM and Zn2+ at low concentrations (below 0.01 mM) were needed, although Zn2+ at high concentrations (above 0.1 mM) showed an inhibitory effect. Zn2+ and Mg2+ alone slightly increased alkaline phosphatase activity. This activation of the enzyme was temperature dependent and was not observed at 0 or 4 degrees C. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate showed that the increase in alkaline phosphatase activity did not involve the fragmentation of the enzyme and that 65Zn2+ bound to it during enzyme activation with 65Zn2+ and Mg2+. The cytosol fraction not only supplied Zn2+ to the nascent enzyme but also increased the maximal enzyme activity more than did direct addition of metal ions. Ferritin and metallothionein contributed to the activation of alkaline phosphatase with the metal ions. Since the binding of Zn2+ and Mg2+ to the nascent alkaline phosphatase is disturbed in Reuber rat hepatoma cells (R-Y121B), the apoenzyme is accumulated inside the cells. The binding of Zn2+ and Mg2+ to the apoenzyme readily takes place in the cell homogenates accompanied by an increase in catalytic activity without new enzyme synthesis.     

Activation of apoalkaline phosphatase by serum albumin with Zn2+ in rat hepatoma cells.

Reuber rat hepatoma cells (R-Y121B) cultured at 0.5% serum accumulated apoalkaline phosphatase in intact cells. When R-Y121B cells were cultured in the presence of bovine serum albumin, alkaline phosphatase activity increased in the cells, and the associated increase in enzyme activity differed amongst bovine serum albumin preparations. The treatment of bovine serum albumin with activated charcoal not only enhanced the effect of serum albumin on alkaline phosphatase activity, but also cancelled the differences due to different preparations of serum albumin. In contrast, no effect from serum albumin was observed in the increase of alkaline phosphatase activity in R-Y121B cell homogenates incubated at 37 degrees C. The activated-charcoal treatment of bovine serum albumin increased the amount of Zn2+ bound to the protein. When R-Y121B cells were cultured with bovine serum albumin, the concentration of Zn2+ in the cytosol fraction slightly increased. However, the effect of serum albumin on Zn2+ concentration in the cytosol fractions was independent of charcoal treatment. It was concluded that serum albumin with Zn2+ induces the activation of apoalkaline phosphatase due to Zn2+ binding.     

pH-dependent conversion of liver-membranous alkaline phosphatase to a serum-soluble form by n-butanol extraction

Alkaline phosphatase released from rat liver plasma membrane under usual conditions was electrophoretically not identical with a soluble form in serum which was derived from the liver. The liver-membranous alkaline phosphatase, however, was converted to the serum-soluble form when the liver plasma membrane was treated with n-butanol under the acidic conditions lower than pH 6.5. Such pH-dependent conversion of the enzyme was not observed in plasma membrane of rat ascites hepatoma AH-130 cells. The converting activity for alkaline phosphatase was detected not only in plasma membrane but also in lysosomal membrane of rat liver.     

Ectoenzyme release from rat liver and kidney by phosphatidylinositol-specific phospholipase C

Ectoenzyme release from rat liver and kidney by phosphatidylinositol (PI)-specific phospholipase C of Bacillus thuringiensis was studied. Alkaline phosphatase and 5'-nucleotidase were released from rat kidney slices to extents of up to 60% and 30%, respectively. Release of alkaline phosphatase was observed at lower amounts of PI-specific phospholipase C than that of 5'-nucleotidase. Both enzymes were more easily released from microsomal fractions or free cells. From kidney cells, alkaline phosphatase was released without cell lysis, and more than 80% release of alkaline phosphatase was observed at 3.8% hydrolysis of PI. Isoelectric focusing profiles of alkaline phosphatase released by PI-specific phospholipase C were significantly different from the control in the cases of both rat liver and kidney. Lubrol-solubilized alkaline phosphatase was eluted at the void volume of a Toyopearl HW-55 column, while the enzyme obtained by further treatment with PI-specific phospholipase C was eluted in the lower-molecular-weight region corresponding to 100,000-110,000 daltons. Furthermore, Lubrol-solubilized phosphatase became more thermostable on treatment with PI-specific phospholipase C.     

Electrophoretic characterization of hepatic alkaline phosphatase released by phosphatidylinositol-specific phospholipase C. A comparison with liver membrane and serum-soluble forms.

Alkaline phosphatase was solubilized from plasma membrane of rat liver with butanol-ol, bile acids or sodium deoxycholate, and electrophoretically compared with a soluble form in serum which was derived from the liver. The three enzyme preparations from the plasma membrane migrated at the same position on polyacrylamide-gel electrophoresis in the presence of either Triton X-100 or sodium dodecyl sulphate. The mobility of them, however, was distinctly different from that of the serum-soluble form of the liver-derived alkaline phosphatase. On the other hand, phosphatidylinositol-specific phospholipase C isolated from Bacillus cereus was used to release alkaline phosphatase from plasma membrane. The released alkaline phosphatase was demonstrated to have the same mobility as the serum-soluble form on polyacrylamide-gel electrophoresis in the presence or absence of detergents. The phospholipase C also converted the butan-1-ol-extracted membrane form into the serum-soluble form. The results suggest that release of alkaline phosphatase from the liver into serum is not simply caused by a detergent effect of bile salts, but involves an enzymic hydrolysis of phosphatidylinositol, with which alkaline phosphatase may strongly interact in the membrane.     

Purification and characterization of alkaline phosphatase from plasma membranes of rat ascites hepatoma.

Alkaline phosphatase was purified from plasma membranes of rat ascites hepatoma AH-130, the homogenate of which had 50-fold higher specific activity than that found in the liver homogenate. The presence of Triton X-100, 0.5%, was essential to avoid its aggregation and to stabilize its activity. The purified enzyme, a glycoprotien, was homogeneous in polyacrylamide gel electrophoresis. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate indicated a protein molecular weight of 140,000. The addition of beta-mercaptoethanol caused the dissociation of the alkaline phosphatase into two subunits of identical molecular weight, 72,000. Isoelectric focusing revealed that the pI of this enzyme is 4.7. The pH optimum for the purified enzyme was 10.5 or higher with p-nitrophenylphosphate, and slightly lower pH values (pH 9.5--10.2) were obtained when other substrates were used. Of the substrates tested, p-nitrophenylphosphate (Km-0.3 mM) was most rapidly hydrolyzed. Vmax values of other substrates relative to that of p-nitrophenylphosphate were as follows; beta-glycerophosphate, 76%; 5'-TMP, 82%; 5'-AMP, 62%; 5'-IMP, 43%; glucose-6-phosphate, 39%; ADP, 36% and ATP, 15%. More than 90% of the activity of the purified enzyme was irreversibly lost when it was heated at 55 degrees C for 30 min, or exposed either to 10 mM beta-mercaptoethanol for 10 min to 3 M urea for 30 min, or to an acidic pH below pH 5.0 for 2 h. Of the effects by divalent cations, Mg2+ activated the enzyme by 20% whereas Zn2+ strongly inhibited it by 95% at 0.5 mM. EDTA at higher than 1 mM inactivated the enzyme irreversibly, although the effect of EDTA at lower than 0.1 mM was reversible by the addition of divalent cations, particularly by Mg2+. The enzyme was most strongly inhibited by L-histidine among the amino acids tested, and also strongly inhibited by imidazole. These results suggest that alkaline phosphatase of rat hepatoma AH-130 is very similar to that of rat liver in most of the properties reported so far.     

Cell growth in arginine- and ornithine-deprived medium and conversion of glutamate to ornithine and arginine in rat hepatoma cells

Summary A subline growing in medium without arginine and ornithine was established from a rat Reuber hepatoma cell line (R-Y121B·cho). The subline designated R-Y117B·cho was able to grow in glutamine, arginine and ornithine-free, glutamate-supplemented medium. Arginine synthesis from glutamate requires four urea cycle enzymes and another two enzymes, glutamate semialdehyde dehydrogenase and ornithine aminotransferase. Since R-Y121B·cho cells have all the urea cycle enzymes, two other enzyme activities were determined. The activities of ornithine aminotransferase and glutamate semialdehyde dehydrogenase were similar in R-Y117B·cho and its parental R-Y121B·cho cells, but R-Y117B·cho cells had higher conversion of glutamate to arginine than parental cells.     

Differences in distribution of esterase between cell fractions of rat liver homogenates prepared in various media. Relevance to the lysosomal location of the enzyme in the intact cell

The distribution of esterase in subcellular fractions of rat liver homogenates was compared with that of the lysosomal enzyme acid phosphatase and the microsomal enzyme glucose 6-phosphatase. Most of the esterase from sucrose homogenate sediments with glucose 6-phosphatase and about 8% is recovered in the supernatant. However, up to 53% of the esterase can be washed from microtome sections of unfixed liver, in which less cellular damage would be expected than that caused by homogenization. About 40% of both esterase and acid phosphatase are recovered in the soluble fraction after homogenization in aqueous glycerol or in a two-phase system (Arcton 113-0.25m-sucrose), although glucose 6-phosphatase is still recovered in the microsomal fraction of such homogenates. The esterase of the microsomal fraction prepared from a sucrose homogenate is much more readily released by treatment with 0.26% deoxycholate than are other constituents of this fraction. The release of esterase from the microsomal fraction by the detergent and its concomitant release with acid phosphatase after homogenization in glycerol or the two-phase system suggests that a greater proportion of esterase may be present in lysosomes of the intact cell than is indicated by the results of standard fractionation procedures.     

Release of alkaline phosphatase from human osteosarcoma cells by phosphatidylinositol phospholipase C: effect of tunicamycin

Alkaline phosphatase (orthophosphoric-monoester phosphohydrolase [alkaline optimum], EC 3.1.3.1) expressed in two human osteosarcoma cell lines (Saos-2 and KTOO5) in culture was the tissue nonspecific type and was released from the plasma membrane by phosphatidylinositol (PI) phospholipase C. Despite a difference of 10-fold between the two cell lines in the amount of alkaline phosphatase expressed, the phospholipase solubilized nearly all of the phosphatase from resuspended cells of the two lines. Alkaline phosphatase released with Nonidet-P40 from Saos-2 cells had a Mr of 445,000 by gradient gel electrophoresis in the absence of detergent; that released by PI-phospholipase C was 200,000. The subunit Mr of both solubilized forms was 86,000. Thus, tetrameric alkaline phosphatase in the membrane is attached by a PI-glycan moiety and is converted to dimers when released by PI-phospholipase C. Tunicamycin treatment of Saos-2 cells in culture affected the release of alkaline phosphatase by a high concentration of PI-phospholipase C, but not by a low concentration; both the rate and extent of release were lower from treated cells. However, the enzyme released from the treated cells was in two forms with different molecular weights; it seems that both glycosylated and nonglycosylated dimers were transported to the cell surface and incorporated into the plasma membrane. Glycosylation does not appear to be necessary for alkaline phosphatase to be anchored in the membrane via PI.     

Release of alkaline phosphodiesterase I from rat kidney plasma membrane produced by the phosphatidylinositol-specific phospholipase C of Bacillus thuringiensis

The release of plasma-membrane-bound enzymes by phosphatidylinositol-specific phospholipase C obtained from Bacillus thuringiensis was investigated. Among the ectoenzymes of plasma membrane tested, alkaline phosphodiesterase I was released markedly from rat kidney cortex slices, in addition to alkaline phosphatase and 5'-nucleotidase. Other membrane-bound enzymes; alanine aminopeptidase, leucine aminopeptidase, dipeptidyl peptidase, leucine aminopeptidase, dipeptidyl peptidase IV, esterase and gamma-glutamyl transpeptidase could not be liberated from the treated slices. Alkaline phosphodiesterase I was released linearly from rat kidney slices with the concentration of phosphatidylinositol-specific phospholipase C, but little enzyme was released from rat liver slices. Alkaline phosphodiesterase I separated from kidney tissue with n-butanol still retained phosphatidylinositol and was transformed into a lower molecular weight form by phosphatidylinositol-specific phospholipase C. This suggests an important function for phosphatidylinositol in the binding of alkaline phosphodiesterase I to the plasma membrane of rat kidney cells. The alkaline phosphodiesterase I released from rat kidney had a molecular weight of about 240,000 and an isoelectric point (pI) of 5.4. The enzyme hydrolyzed the phosphodiester linkage of p-nitrophenyl-thymidine 5'-monophosphate at pH 8.9 and had a Km value of 0.3 mM. The enzyme was activated by Mg2+ and Ca2+, but was inhibited by EDTA. Strong inhibition took place on the addition of adenosine 5'-phosphosulfate or the nucleotide pyrophosphates, i.e., UDP-galactose and alpha, beta-methylene ATP.     

Incorporation of human liver and placental alkaline phosphatases into liposomes and membranes is via phosphatidylinositol

As assessed by incorporation into liposomes and by adsorption to octyl-Sepharose, the integrity of the membrane anchor for the purified tetrameric forms of alkaline phosphatase from human liver and placenta was intact. Any treatment that resulted in a dimeric enzyme precluded incorporation and adsorption. An intact anchor also allowed incorporation into red cell ghosts. The addition of hydrophobic proteins inhibited incorporation into liposomes to varying degrees. Alkaline phosphatase was 100% releasable from liposomes and red cell ghosts by a phospholipase C specific for phosphatidylinositol. There was no appreciable difference in the rates of release of placental and liver alkaline phosphatases, although both were approximately 250 x slower in liposomes and 100 x slower in red cell ghosts than the enzyme's release from a suspension of cultured osteosarcoma cells. Both enzymes were released by phosphatidylinositol phospholipase C as dimers and would not reincorporate or adsorb to octyl-Sepharose. However, the enzyme incorporated, resolubilized by Triton X-100, and cleansed of the detergent by butanol treatment was tetrameric by gradient gel electrophoresis, was hydrophobic, and could reincorporate into fresh liposomes. A monoclonal antibody to liver alkaline phosphatase inhibited the enzyme's incorporation into liposomes, and abolished its release from liposomes and its conversion to dimers by phosphatidylinositol phospholipase C.     

Pharmacologic properties of a phosphate ester of dopamine

The 3 or 4 phosphate ester of dopamine (PD) was hydrolyzed by homogenates of rat tissues to give inorganic phosphate (Pi) and dopamine. The rate of hydrolysis of PD by kidney homogenates was increased by exogenous MgCl2 but not CaCl2 or KCl. The activity of brain, heart or liver homogenates was insensitive to the added salts. Several lines of evidence indicate that alkaline phosphatase activity contributes to the high rate of PD hydrolysis by the kidney but not brain homogenate. The intravenous infusion of PD at 12 mumole/kg in one hr to anesthetized rats increased the dopamine content of the plasma, kidney and heart without altering brain or liver dopamine. The results suggest that PD may be more effective than dopamine for increasing dopamine levels of the kidney. In addition, the hydrolysis of PD by brain homogenates, which is independent of alkaline phosphatase activity, suggests that specific enzymes exist for the metabolism of PD.     

The solubilization of tetrameric alkaline phosphatase from human liver and its conversion into various forms by phosphatidylinositol phospholipase C or proteolysis

When membrane-bound human liver alkaline phosphatase was treated with a phosphatidylinositol (PI) phospholipase C obtained from Bacillus cereus, or with the proteases ficin and bromelain, the enzyme released was dimeric. Butanol extraction of the plasma membranes at pH 7.6 yielded a water-soluble, aggregated form that PI phospholipase C could also convert to dimers. When the membrane-bound enzyme was solubilized with a non-ionic detergent (Nonidet P-40), it had the Mr of a tetramer; this, too, was convertible to dimers with PI phospholipase C or a protease. Butanol extraction of whole liver tissue at pH 6.6 and subsequent purification yielded a dimeric enzyme on electrophoresis under nondenaturing conditions, whereas butanol extraction at pH values of 7.6 or above and subsequent purification by immunoaffinity chromatography yielded an enzyme with a native Mr twice that of the dimeric form. This high molecular weight form showed a single Coomassie-stained band (Mr = 83,000) on electrophoresis under denaturing conditions in sodium dodecyl sulfate, as did its PI phospholipase C cleaved product; this Mr was the same as that obtained with the enzyme purified from whole liver using butanol extraction at pH 6.6. These results are highly suggestive of the presence of a butanol-activated endogenous enzyme activity (possibly a phospholipase) that is optimally active at an acidic pH. Inhibition of this activity by maintaining an alkaline pH during extraction and purification results in a tetrameric enzyme. Alkaline phosphatase, whether released by phosphatidylinositol (PI) phospholipase C or protease treatment of intact plasma membranes, or purified in a dimeric form, would not adsorb to a hydrophobic medium. PI phospholipase C treatment of alkaline phosphatase solubilized from plasma membranes by either detergent or butanol at pH 7.6 yielded a dimeric enzyme that did not absorb to the hydrophobic medium, whereas the untreated preparations did. This adsorbed activity was readily released by detergent. Likewise, alkaline phosphatase solubilized from plasma membranes by butanol extraction at pH 7.6 would incorporate into phosphatidylcholine liposomes, whereas the enzyme released from the membranes by PI phospholipase C would not incorporate. The dimeric enzyme purified from a butanol extract of whole liver tissue carried out at pH 6.6 did not incorporate. We conclude that PI phospholipase C converts a hydrophobic tetramer of alkaline phosphatase into hydrophilic dimers through removal of the 1,2-diacylglycerol moiety of phosphatidylinositol. Based on these and others' findings, we devised a model of alkaline phosphatase's conversion into its various forms.     

Development of radioimmunoassay for thromboxane B2

A simple method for the preparation of rat liver urate oxidase is described. The enzyme was purified from rat liver homogenate by cell fractionation, detergent treatment, alkali treatment, and affinity chromatography on 8-aminoxanthine-bound Sepharose 4B. This enzyme preparation had a specific activity of 9.1 U/mg of protein and was purified about 1000-fold from the liver homogenate. After sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis followed by staining with Coomassie brilliant blue, this preparation yielded one protein band at a position corresponding to a molecular weight of 33,000.     

Purification and partial characterization of alkaline phosphatase of matrix vesicles from fetal bovine epiphyseal cartilage. Purification by monoclonal antibody affinity chromatography

Alkaline phosphatase of matrix vesicles isolated from fetal bovine epiphyseal cartilage was purified to apparent homogeneity using monoclonal antibody affinity chromatography. The enzyme from the butanol extract of matrix vesicles bound specifically to the immobilized antibody-Sepharose in the presence of 2% Tween 20 whereas the major portion of nonspecific protein was removed by this single step. Of various agents tested, 0.6 M 2-amino-2-methyl-1-propanol, pH 10.2, was the most effective in eluting 80-100% of the enzyme initially applied. Both Tween 20 and 2-amino-2-methyl-1-propanol associated with the eluted enzyme were effectively removed by the sequential application of DEAE-cellulose and Sepharose CL-6B chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the enzyme preparation treated with sodium dodecyl sulfate and mercaptoethanol showed the presence of a dominant band (using silver staining) corresponding to a molecular weight of 81,000. This molecular weight was nearer reported values for rat liver (Ohkubo, A., Langerman, N., and Kaplan, M. M. (1974) J. Biol Chem. 249, 7174-7180) and porcine kidney (Cathala, G., Brunel, C., Chapplet-Tordo, D., and Lazdunski, M. (1975) J. Biol. Chem. 250, 6040-6045) alkaline phosphatase, than to previously reported values for chicken (Cyboron, G. W., and Wuthier, R. E. (1981) J. Biol. Chem. 256, 7262-7268) and fetal calf (Fortuna, R., Anderson, H. C., Carty, R. P., and Sajdera, S. W. (1980) Calcif. Tissue Int. 30, 217-225) cartilage matrix vesicle alkaline phosphatase. The purified alkaline phosphatase was activated by micromolar Mg2+. The amino acid composition of cartilage alkaline phosphatase was found to be similar to that previously described for porcine kidney (Wachsmuth, E. D., and Hiwada, K. (1974) Biochem. J. 141, 273-282). Double immunoprecipitation data indicated that monoclonal antibody against cartilage alkaline phosphatase cross-reacted with fetal bovine liver or kidney enzyme but failed to react with calf intestinal or rat cartilage enzyme. Thus these observations suggest that alkaline phosphatase of matrix vesicles from calcifying epiphyseal cartilage is a liver-kidney-bone isozyme.     

Alkaline lysis of mammalian cells for sedimentation analysis of nuclear DNA. Conformation of released DNA as monitored by physical, electron microscopic and enzymological techniques.

The degree of single strandedness of the DNA released from rat liver nuclei by various alkaline lysing solutions (including some with sodium dodecyl sulfate) was determined both before and after sedimentation in alkaline sucrose gradients employing electron microscopy, melting profiles, circular dichroism measurements, and digestibility by S1 nuclease. Regardless of the technique employed, the results obtained following alkaline sucrose gradient centrifugation of the DNA are consistent. The DNA was completely single stranded as judged by electron microscopy, circular dichroism spectra, and digestibility by S1 nuclease, an enzyme that specifically hydrolyzes single-stranded DNA. This was not true if the DNA was analyzed following alkaline lysis of the nuclei but before centrifugation. Under conditions which gave a complete transition to the single-stranded state, as judged by melting profiles and circular dichroism spectra, only 10-15% of the DNA was hydrolyzed by S1 nuclease. An increase in the susceptibility of the released DNA to S1 nuclease was observed with increases in the pH of the lysing solution. In order to release DNA which was single stranded as judged by both physical and enzymological techniques, the rat liver nuclei were lysed for 30 min with a 0.3 M NaOH lysing solution containing 0.5% dodecyl sulfate, 0.3 M NaCl and 0.03 M EDTA.     

Purification and characterization of alkaline phosphatase from rat kidney.

Alkaline phosphatase [EC 3.1.3.1.] was purified about 250-fold from rat kidney, and its enzymological properties were studied. Kidney homogenate was extracted with n-butanol, passed through Sephadex G-200 and chromatographed on a DEAE-cellulose column. The peak from the DEAE-cellulose column was subjected to isoelectric focusing, and the alkaline phosphatase activity was separated into two peaks. The molecular weights of alkaline phosphatase in these peaks were 4.8.X10(4) and 1.0X10(5), as determined by SDS-polyacrylamide gel electrophoresis. Anti-serum against alkaline phosphatase from rat kidney was prepared, and was shown to neutralize the activity from kidney, liver or bone, but not that from intestine.     

Continuous culture of Reuber hepatoma cells in serum-free arginine-, glutamine- and tyrosine-deprived chemically defined medium

The rat hepatoma cell line, H4-II-E, was grown serially over a 1-year period and about 30 passages in arginine-, glutamine-, and tyrosine-deprived and ornithine-supplemented Eagle's minimum essential medium with no supplements other than biotin. The adapted cell line, R-Y121B, proliferates in the above mentioned medium with a doubling time of about 4 days and maintains hepatic "marker" enzymes such as tyrosine aminotransferase, phenylalanine hydroxylase, and all the enzymes of the urea cycle.