Stimulation of growth of primary cultured adult rat hepatocytes without growth factors by coculture with nonparenchymal liver cells

DNA synthesis of adult rat parenchymal hepatocytes alone in primary culture can be stimulated only by the addition of humoral growth factors to the culture medium. However, when parenchymal hepatocytes were cocultured with nonparenchymal liver cells from adult rats, their DNA synthesis was markedly stimulated in the absence of added growth factors or calf serum. DNA synthesis of parenchymal hepatocytes was not stimulated by conditioned medium from nonparenchymal liver cells and was greatest when the parenchymal cells were plated on 24-h cultures of nonparenchymal liver cells. A dead feeder layer of nonparenchymal cells was almost as effective as a feeder layer of viable nonparenchymal cells. These results suggest that the stimulation of DNA synthesis in parenchymal hepatocytes was not due to some soluble factors secreted by nonparenchymal liver cells but to an insoluble material(s) produced by the nonparenchymal liver cells. This insoluble material(s) was collagenase- and acid-sensitive, suggesting that it was a protein containing collagen. The effect of nonparenchymal liver cells was specific: coculture with hepatoma cells, liver epithelial cells, or Swiss 3T3 cells did not stimulate DNA synthesis in parenchymal hepatocytes. Added insulin and epidermal growth factor showed additive effects with nonparenchymal cells in the cocultures. These results suggest that DNA synthesis in parenchymal hepatocytes is stimulated not only by various humoral growth factors but also by cell-cell interaction between parenchymal and nonparenchymal hepatocytes, possibly endothelial cells. This cell-cell interaction may be important in repair of liver damage and liver regeneration.     

Ganglioside biosynthesis in rat liver: different distribution of ganglioside synthases in hepatocytes, Kupffer cells, and sinusoidal endothelial cells

The activities of five glycolipid-glycosyltransferases, GL2, GM3, GM2, GM1, and GD1a synthase, were determined in a cell-free system with homogenate protein of total rat liver, isolated hepatocytes, Kupffer cells, and sinusoidal endothelial cells. In rat liver parenchymal and nonparenchymal cells ganglioside synthases were distributed differently. Compared to hepatocytes, Kupffer cells expressed a nearly sevenfold greater activity of GM3 synthase, but only 14% of GM2, 19% of GM1, and 67% of GD1a synthase activity. Sinusoidal endothelial cells expressed a pattern of enzyme activities quite similar to that of Kupffer cells with the exception of higher GM2 synthase activity. Activity of GL2 synthase was distributed unifromly in parenchymal and nonparenchymal cells of rat liver, but differed by sex. It was 1 to 2 orders of magnitude below that of all the other ganglioside synthases investigated. The results indicate GL2 synthase regulates the total hepatic ganglioside content, and hepatocytes but not nonparenchymal liver cells have high enzymatic capacities to form a-series gangliosides more complex than GM3.     

Incorporation of labelled amino acids into proteins of isolated parenchymal and nonparenchymal rat liver cells in the absence and presence of ethanol.

Parenchymal and nonparenchymal cells were isolated from perfused rat livers and incubated at 37 degrees C in the absence and presence of ethanol (50 mM). 1. Nonparenchymal cells prepared by means of centrifugation showed a higher rate of incorporation of L-[U-14C]valine into protein than nonparenchymal cells prepared by means of pronase. Cells prepared by the former method were used for further studies. 2. Protein degradation was present in suspensions of both parenchymal and nonparenchymal cells evidenced by increasing levels of branched amino acids in the intracellular and extracellular compartment during cell incubation. 3. The rate of cellular protein synthesis (corrected for precursor pool specific radioactivity) was of the same order of magnitude in nonparenchymal and parenchymal cells when expressed as nmol valine incorporated per mg protein. This rate was also close to the value found in intact liver by other workers. 4. Approximately 25% of the total radioactivity incorporated during incubation for 2 h was found in proteins released to the medium from parenchymal cells, while the corresponding figure for nonparenchymal cells was 3.5%. 5. Ethanol inhibited incorporation of labelled valine into stationary and medium proteins of parenchymal cells. No such effects were found in nonparenchymal cells. 6. Nonparenchymal cells did not metabolize ethanol while parenchymal cells did, shown by changes in lactate/pyruvate ratio and medium pH. It was concluded that nonparenchymal cells are capable of synthesizing proteins at a rate comparable to that found in parenchymal cells. Protein synthesis in parenchymal cells was inhibited by ethanol, but nonparenchymal protein synthesis was unaffected. This difference may be linked to the ability of the former cell type to metabolize ethanol.     

Uptake and degradation of formaldehyde-treated 125I-labelled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated 125I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20-30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

Uptake and degdradation of formaldehyde-treated 125I-labeled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated ¹²⁵I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20–30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

24-Dehydrovitamin D is potent inhibitor of rat liver microsomal vitamin D-25-hydroxylase

A pathway has been described in the skin for the synthesis of 24-dehydrovitamin D3 (delta 24D3) from 24-dehydroprovitamin D3. The physiologic function of delta 24D3 is unknown, but has been proposed as a potential inhibitor of hepatic vitamin D-25-hydroxylase. We validated an assay for vitamin D-25-hydroxylase in rat hepatic microsomes, using nanomolar amounts of [3H]D3 as substrate, and found that delta 24D3 competitively inhibits vitamin D-25-hydroxylase activity. The apparent Ki was approximately 17 nM, indistinguishable from the Km of approximately 15 nM, suggesting that both delta 24D3 and cholecalciferol have similar affinity for the enzyme. We found no [3H]delta 24D3 in serum or liver extracts after repletion of vitamin D-depleted rats with [3H]vitamin D3 for 4 h or 6 days. A dose of 1 microgram delta 24D3 to vitamin D- and calcium-depleted rats was unable to promote any elevation in the 45Ca transport by everted duodenal sacs or to increase levels of plasma calcium: thus no evidence for biological conversion of delta 24D3 to vitamin D3 was observed. Further studies are needed to determine whether delta 24D3 is released from the skin to the circulation and is taken up by the liver, before physiological relevance can be attributed to this inhibitor.     

The involvement of intracellular calcium ion concentration and calmodulin in the 25-hydroxylation of cholecalciferol in ovine and rat liver

The effect of Ca2+ ion concentration on the 25 hydroxylation of tritiated cholecalciferol (3HD3) was investigated using homogenates of ovine liver from vitamin D replete sheep. A significant decrease in the production of 25 hydroxycholecalciferol (25OHD3) was observed when the concentration of Ca2+ in the homogenate was raised above 0.68 mmol/l by the addition of calcium gluconate. Similarly, a final concentration of 37 mumol EGTA/1 (equivalent to a Ca2+ concentration of 26.5 nmol/l) was associated with a 50% reduction of 25OHD3 production. That is, a broad bell-shaped relationship was observed between the production of 25OHD3 and the Ca2+ concentration in the homogenate. These changes in the rate of production of 25OHD3 were reproduced with hepatocytes from vitamin D replete rats, prepared by collagenase perfusion, using the drugs dantrolene sodium (DaNa) to reduce (ED50 = 57 mmol/l) and veratridine to increase (ED50 = 550 mmol/l) the intracellular Ca2+ concentration. Hepatocytes from vitamin D replete rats also showed a reduction in 25 hydroxylation of D3 (ED50 = 6 ng/ml) in response to the addition of 1-25 dihydroxycholecalciferol (1-25 (OH)2D3). The calmodulin antagonists; W7, compound 48/80, trifluoperazine (TFP) and calmidazolium (R24571) were all found to effect a dose response inhibition of the 25 hydroxylation of cholecalciferol by homogenates of ovine liver. R24571 had a similar inhibitory effect (ED50 = 70 mumol/l) upon the 25 hydroxylase enzyme of rat hepatocytes. It is concluded that the 25 hydroxylation of cholecalciferol in liver of vitamin D replete rats and sheep is calcium sensitive and is reduced in the presence of increased concentrations of 1,25(OH)2D3. Calmodulin may also be involved in the regulation of hepatocyte 25-hydroxylase activity by Ca2+.     

Dolichol and retinol content of rat liver sinusoidal cells after chronic monensin treatment.

Aim of this study was to ascertain whether an impairment of communication between parenchymal and non-parenchymal liver cells involves vitamin A intercellular transport. The following approach was adopted: liver cells were isolated from rats treated chronically with the hydrophobic ionophore monensin i.p. for 3, 5, and 7 weeks and their retinol and dolichol content was assessed. Monensin, which alters membrane flow, was used because it had previously been reported to induce liver steatosis, cholestasis and glycogenolysis after acute treatment and, by preliminary morphological examination, to impair vitamin A transport between stellate cells and hepatocytes. Dolichol was chosen as a biochemical marker because it is a membrane lipid that modulates the fluidity and permeability of the membranes that retinol must cross. After monensin treatment, a load of vitamin A was given to rats three days before sacrifice, to ascertain whether its uptake by sinusoidal liver cells was altered. The main result was a dolichol decrease in hepatocytes and in the Ito-1 subfraction. In this latter, monensin induced a decrease in dolichol content only after vitamin A load. Moreover, while the hepatocytes were able to take up a load of vitamin A normally, the Ito-1 subfraction was no longer able to store retinol. Therefore the polarised transport of retinol between hepatocytes and stellate cells seemed impaired. The behaviour of sinusoidal endothelial cells and Kupffer cells might be ascribed to the functions of these cells and is not significantly modified by monensin. In conclusion, the altered cross-talk between sinusoidal cells in liver pathology might involve retinol as well as cytokines. Different pools of dolichol might have a role in this membrane process in a hydrophobic environment.     

Receptor-mediated introduction of pepstatin-asialofetuin conjugate into lysosomes of rat hepatocytes

Pepstatin was linked through a carboxyl group to asialofetuin (PS-ASF). An analysis by separation of hepatocytes from nonparenchymal cells showed that PS-ASF was taken up by hepatocytes, following intravenous injection into rats. After the injection of PS-ASF, pepstatin concentration in the liver reached a maximum at 2 h and then decreased. In an analysis by differential centrifugation of the liver homogenate from rats injected with PS-ASF, pepstatin showed a lysosomal type subcellular distribution pattern. Isolation studies of tritosomes clearly demonstrated the exclusive accumulation of pepstatin within the lysosomes of livers from rats given PS-ASF (at 2 h after administration). Pepstatin contained in tritosomes was in a free form, as determined by column chromatography of Sephadex G-15. The activity of cathepsin D in the livers was markedly inhibited in rats given PS-ASF. However, the treatment of rats with PS-ASF had no effect on the hepatic lysosomal degradation of endocytosed FITC-labeled asialofetuin (FITC-ASF). Introduction of PS-ASF into the hepatocytes was followed by the immediate and time-dependent excretion of free pepstatin into the bile. Quantification of pepstatin excreted into the bile revealed that the biliary excretion route can account for the disappearance of pepstatin from the liver.     

In vivo uptake of human and rat low density and high density lipoprotein by parenchymal and nonparenchymal cells from rat liver.

The relative contribution of the parenchymal and nonparenchymal rat liver cells to the hepatic uptake of human and rat high density lipoprotein (HDL) and low density lipoprotein (LDL) was determined in vivo. Nonparenchymal cells, isolated 6 h after intravenous injection of iodinated human HDL and LDL, contained respectively 4.2 and 6.3 times the amount of trichloroacetic acid-precipitable radioactivity per mg cell protein as compared to parenchymal cells. For rat iodinated HDL and LDL these factors were 3.4 and 4.1, respectively. These results indicate that nonparenchymal liver cells play a substantial role in the hepatic uptake of human and rat HDL and LDL in vivo.     

Liver takes up retinol-binding protein from plasma

Retinol is transported in plasma bound to a specific transport protein, retinol-binding protein. We prepared 125I-tyramine cellobiose-labeled rat retinol-binding protein and studied its tissue uptake 1, 5, and 24 h after intravenous injection into rats. The liver was the organ containing most radioactivity at all time points studied. After 5 and 24 h, 30 and 22% of the injected dose were recovered in liver, respectively. After separating the liver into parenchymal and nonparenchymal cells in the 5-h group, we found that both cell fractions contained approximately the same amount of radioactivity (per gram of liver). Most of the retinol-binding protein radioactivity in the nonparenchymal cell fraction was in the stellate cells. The implication of these results for a possible transfer mechanism for retinol between parenchymal and stellate cells is discussed.     

Development of vitamin D3 25-hydroxylase activity in rat liver microsomes

The ontogeny of vitamin D3 25-hydroxylase activity has been determined in liver microsomes of rat fetuses and neonates. Production of 25-hydroxyvitamin D3 was low (0.11 pmol/g liver/h) 3 days prior to birth. Production rates were 1.2, 2.2, 1.8, and 2.8 pmol/g liver/h on Day 0, Day 2, Day 7, and Day 15, respectively. 25-Hydroxyvitamin D3 production in neonates increased sixfold from Day 15 to Day 22 to a value twice that of the mothers (17.6 pmol/g liver/h compared with 7.3 pmol/g liver/h). Activity in the maternal microsomes was constant (0.22 to 0.30 pmol/mg protein/h) except for the day of parturition (0.54 pmol/mg protein/h) and Day 22 postpartum (0.44 pmol/mg protein/h). A cytosolic factor, present as early as 3 days prior to birth, was required for vitamin D3 25-hydroxylase activity in the fetuses and stimulated the 25-hydroxylase reaction (up to 2.5-fold) in neonates and mothers. The ability of cytosol to prevent degradation of vitamin D3 was also present in the fetal stage. These data suggest that microsomal vitamin D3 25-hydroxylase activity in rat liver microsomes develops slowly and reaches full activity near the weaning stage. Since the cytosolic factor(s) is/are present in the fetal stage, the limiting component in the maturation of vitamin D3 25-hydroxylase activity in liver microsomes is the development of the cytochrome P-450 vitamin D3 25-hydroxylase.     

Characterization of recombinant CYP2C11: a vitamin D 25-hydroxylase and 24-hydroxylase

Studies were performed to further characterize the male-specific hepatic recombinant microsomal vitamin D 25-hydroxlase CYP2C11, expressed in baculovirus-infected insect cells, and determine whether it is also a vitamin D 24-hydroxylase. 25- and 24-hydroxylase activities were compared with those of 10 other recombinant hepatic microsomal cytochrome P-450 enzymes expressed in baculovirus-infected insect cells. Each of them 25-hydroxylated vitamin D2, vitamin D3, 1alpha-hydroxyvitamin D2 (1alphaOHD2), and 1alpha-hydroxyvitamin D3 (1alphaOHD3). CYP2C11 had the greatest activity with these substrates, except vitamin D3, which had the same activity as four of the other enzymes. The descending order of 25-hydroxylation by CYP2C11 was 1alphaOHD3 > 1alphaOHD2 > vitamin D2 > vitamin D3. Each of the recombinant cytochrome P-450 enzymes 24-hydroxylated 1alphaOHD2. CYP2C11 had the greatest activity. 24-Hydroxylation of 1alphaOHD3 was very low, and there was none with vitamin D3. Only CYP2C11 24-hydroxylated vitamin D2. Structures of vitamin D metabolites, including 24-hydroxyvitamin D2, 1,24(S)-dihydroxyvitamin D2, and 1,24-dihydroxyvitamin D3, were confirmed by HPLC and gas chromatography retention times and characteristic mass spectrometric fragmentation patterns. In male rats, hypophysectomy significantly reduced body weight, liver weight, hepatic CYP2C11 mRNA expression, and 24- and 25-hydroxylation of 1alphaOHD2. Expression of CYP2J3 and CYP2R1 mRNA did not change. In male rat hepatocytes, CYP2C11 mRNA expression and 24- and 25-hydroxylation were significantly reduced after culture for 24 h compared with uncultured cells. Expression of CYP2J3 and CYP2R1 either increased or did not change. It is concluded that CYP2C11 is a male-specific hepatic microsomal vitamin D 25-hydroxylase that hydroxylates vitamin D2, vitamin D3, 1alphaOHD2, and 1alphaOHD3. CYP2C11 is also a vitamin D 24-hydroxylase.     

Vitamin K uptake in hepatocytes and hepatoma cells

Hepatocellular carcinoma (HCC) or hepatoma cells have impaired ability to perform vitamin K-dependent carboxylation reactions. Vitamin K can also inhibit growth of HCC cells in vitro. Both carboxylation and growth inhibition are vitamin K dose dependent. We used rat hepatocytes, a vitamin K-growth sensitive (MH7777) and a vitamin K-growth resistant (H4IIE) rat hepatoma cell line to examine vitamin K uptake and vitamin K-mediated microsomal carboxylation. We found that vitamin K is taken up by normal rat hepatocytes against a saturable concentration gradient. The relative rates of uptake by rat hepatocytes and the two rat cell lines MH7777 and H4IIE correlated with their sensitivity to vitamin K-mediated cell growth inhibition. Pooled hepatocytes from liver nodules from rats treated with the hepatocarcinogen diethylnitrosamine (DEN) also had a reduced rate of vitamin K uptake. However, using a cell-free system, microsomes from both normal rat hepatocytes and the two rat hepatoma cell lines had a similar ability to support carboxylation mediated by exogenously added vitamin K. The results support the hypothesis that different sensitivity of hepatoma cells to vitamin K may be due to differences in vitamin K uptake and may be unrelated to the actions of vitamin K on carboxylation.     

Effect of hydrocortisone and nicotinamide on gamma glutamyltransferase in primary cultures of rat hepatocytes

Isolated rat hepatocytes cultured on collagen coated plates exhibit a gradual fetal phenotypic change during time in culture. The fetal liver marker gamma glutamyltransferase (GGT) was used to follow this change. Inasmuch as a significant overgrowth of nonparenchymal liver derived cells is seen frequently in primary cultures of hepatocytes, a technique was utilized that corrects for the presence of nonparenchymal cells. In media supplemented with either hydrocortisone (10(-5) M) or nicotinamide (25 mM) the original epithelial morphology of hepatocytes was preserved for a longer period of time than in unsupplemented media. Hepatocytes in unsupplemented media exhibited an increase in GGT specific activity over time. Hydrocortisone (10(-5) M) induced an increase in GGT activity compared to controls. Nicotinamide (25 mM) inhibited the increase in GGT activity compared to the unsupplemented hepatocytes. Our results indicate that GGT is regulated by hydrocortisone and nicotinamide.     

Altered distribution of hexokinase and glucokinase between parenchymal and nonparenchymal cells of rat liver after methapyrilene intoxication

The cell number as well as the hexokinase and glucokinase activity of liver parenchymal and nonparenchymal cells were studied in methapyrilene treated rats. The number of nonparenchymal cells was doubled after treatment with methapyrilene for two weeks while that of hepatocytes remained constant. The hexokinase activity was increased fourfold in the nonparenchymal cell fraction while it was unchanged in the parenchymal cells. The glucokinase activity was decreased in the hepatocytes to one third. Hence, the increased hexokinase activity was due to a proliferation of nonparenchymal cells rather than to a toxic dedifferentiation of hepatocytes.     

Cell of origin of distinct cultured rat liver epithelial cells, as typed by cytokeratin and surface component selective expression

The cell of origin of the nonparenchymal epithelioid cells that emerge in liver cell cultures is unknown. Cultures of rat hepatocytes and several types of nonparenchymal cells obtained by selective tissue dispersion procedures were typed with monoclonal antibodies to rat liver cytokeratin and vimentin, polyvalent antibodies to cow hoof cytokeratins and porcine lens vimentin, and monoclonal antibodies to surface membrane components of ductular oval cells and hepatocytes. Immunoblot analysis revealed that, in cultured rat liver nonparenchymal epithelial cells, the anti-rat hepatocyte cytokeratin antibody recognized a cytokeratin of relative mass (Mr) 55,000 and the anti-cow hoof cytokeratin antibody reacted with a cytokeratin of Mr 52,000, while the anti-vimentin antibodies detected vimentin in both cultured rat fibroblasts and nonparenchymal epithelial cells. Analyses on the specificity of anti-cytokeratin and anti-vimentin antibodies toward the various cellular structures of liver by double immunofluorescence staining of frozen tissue sections revealed unique reactivity patterns. For example, hepatocytes were only stained with anti-Mr 55,000 cytokeratin antibody, while the sinusoidal cells reacted only with the anti-vimentin antibodies. In contrast, epithelial cells of the bile ductular structures and mesothelial cells of the Glisson capsula reacted with all the anti-cytokeratin and anti-vimentin antibodies. It should be stressed, however, that the reaction of the anti-vimentin antibodies on bile ductular cells was weak. The same analysis on tissue sections using the anti-ductular oval cell antibody revealed that it reacted with bile duct structures but not with the Glisson capsula. The anti-hepatocyte antibody reacted only with the parenchymal cells. The differential reactivity of the anti-cytokeratin and anti-vimentin antibodies with the various liver cell compartments was confirmed in primary cultures of hepatocytes, sinusoidal cells, and bile ductular cells, indicating that the present panel of antibodies to intermediate filament constituants allowed a clear-cut distinction between cultured nonparenchymal epithelial cells, hepatocytes, and sinusoidal cells. Indirect immunofluorescence microscopy on nonfixed and paraformaldehyde-fixed cultured hepatocytes and bile ductular cells further confirmed that both anti-hepatocyte and anti-ductular oval cell antibodies recognized surface-exposed components on the respective cell types.(ABSTRACT TRUNCATED AT 400 WORDS)     

Metabolism of the human serum beta-hexosaminidase isoenzymes in the rat: an in vivo and in vitro study

Plasma clearance of purified human serum beta-hexosaminidase isoenzymes was studied in the rat. The serum beta-hexosaminidase isoenzymes (A, B and P) showed a slow clearance from circulation compared to their tissue counterparts. After desialylation, the clearance rate of all serum isoenzymes was markedly enhanced. The uptake of native as well as desialylated serum beta-hexosaminidase isoenzymes was studied in rat liver nonparenchymal cells and hepatocytes. No detectable uptake of any native serum isoenzyme was noticed in either cell type. However, when these isoenzymes were desialylated by neuraminidase treatment, isoenzymes A and B were taken up by the nonparenchymal cells. No uptake was observed for the P form. None of the desialylated serum forms was taken up by hepatocytes.     

26-Hydroxylation of 1alpha,25-dihydroxyvitamin D3 does not occur under physiological conditions

The 26-hydroxylation of 1alpha,25-dihydroxyvitamin D3 in rats in vitro and in vivo was studied under physiological conditions. Incubation of 1alpha,25-dihydroxy-[26,27-3H]vitamin D3 with rat kidney or rat liver homogenate showed formation of a metabolite that was identified as 1alpha,25(S),26-trihydroxy-[26,27-3H]vitamin D3 by comigration on three different HPLC systems and a periodate cleavage reaction. This metabolite was not generated by hydroxylation of 1alpha,25-dihydroxy-[26,27-3H]vitamin D3 itself but by an enzymatic conversion of a precursor that was formed nonenzymatically in substantial amounts upon storage of 1alpha,25-dihydroxy-[26,27-3H]vitamin D3 in ethanol at -20 degrees C under argon for more than three weeks. An in vivo metabolism study in rats dosed with a physiological dose of 1alpha,25-dihydroxy-[26,27-3H]vitamin D3 confirmed the absence of 26-hydroxylation of the hormone. As expected at 6 h postinjection of purified 1alpha,25-dihydroxy-[26,27-3H]vitamin D3, 1alpha,24(R),25-trihydroxy-[26,27-3H]vitamin D3, as well as traces of (23S,25R)-1alpha,25-dihydroxy-[3H]vitamin D3-lactone were detected and identified on straight phase and reverse phase HPLC in serum, kidney, and liver.