Studies on phospholipase activities in Neurospora crassa conidia

Cytosol retinyl ester lipoprotein complex from rat liver was capable of transferring its unesterified retinol component to serum aporetinol-binding protein. In the presence of serum albumin and aporetinol-binding protein, 68% of retinyl ester was hydrolyzed and up to 30% of unesterified retinol was transferred from cytosol retinyl ester lipoprotein complex to serum aporetinol-binding protein in 24 h at 30 °C. The reconstituted retinol-retinol-binding protein complex showed biochemical and biophysical properties similar to native retinol-retinol-binding protein. Both native and reconstituted retinol-retinol-binding proteins had identical uv, CD, and fluorescence spectra as well as binding affinity to prealbumin. Treatment of cytosol retinyl ester lipoprotein with sulfhydryl reagent, with 1 n NaCl, or with diisopropyl fluorophosphate (0.14 mm) abolished the hydrolysis of retinyl ester; however, the activity of retinol transfer from cytosol retinyl ester lipoprotein complex to serum retinol-binding protein was still unaffected. The activity of retinol transfer was proportional to the amount of retinol content in the complex and the amount of aporetinol-binding protein. These experiments suggest that the cytosol retinyl ester lipoprotein complex serves three major functions: (i) as a storage form of retinyl ester and retinol; (ii) as an enzyme for hydrolyzing its own retinyl ester ligand; and (iii) as a medium for transfer of unesterified retinol to serum retinol-binding protein.     

Retinyl esterase activity of purified rat liver retinyl ester lipoprotein complex.

Retinyl ester lipoprotein complex from rat liver was shown to possess a retinyl esterase activity toward its own ligand complement. In the presence of serum albumin the retinyl esterase activity at 30 °C was about fivefold larger than the activity at 4 °C, while higher temperatures than 30 °C led to some degradation of retinyl compounds. The pH optimum was 7.8. The esterase activity was markedly enhanced by serum albumin although the serum albumin as such had no retinyl esterase activity. In the presence of serum albumin and under optimal conditions, some 75 to 80% of the total retinyl ester complement of the lipoprotein was hydrolyzed in 24 h. The retinyl esterase activity was totally abolished by treatment with the serine esterase inhibitor diisopropyl fluorophosphate (1.4 × 10^?4 M), by treatment with sulfhydryl reagents, and by detergents (0.2% of Tween 80 and sodium deoxycholate). From this series of experiments it was concluded that the retinyl ester lipoprotein complex possesses the additional physiological function of hydrolyzing its own retinyl ester complement to unesterified retinol which may then combine with serum retinol-binding protein.     

Hepatic uptake of [3H]retinol bound to the serum retinol binding protein involves both parenchymal and perisinusoidal stellate cells

We have studied the hepatic uptake of retinol bound to the circulating retinol binding protein-transthyretin complex. Labeled complex was obtained from the plasma of donor rats that were fed radioactive retinol. When labeled retinol-retinol binding protein-transthyretin complex was injected intravenously into control rats, about 45% of the administered dose was recovered in liver after 56 h. Parenchymal liver cells were responsible for an initial rapid uptake. Perisinusoidal stellate cells initially accumulated radioactivity more slowly than did the parenchymal cells, but after 16 h, these cells contained more radioactivity than the parenchymal cells. After 56 h, about 70% of the radioactivity recovered in liver was present in stellate cells. For the first 2 h after injection, most of the radioactivity in parenchymal cells was recovered as unesterified retinol. The radioactivity in the retinyl ester fraction increased after a lag period of about 2 h, and after 5 h more than 60% of the radioactivity was recovered as retinyl esters. In stellate cells, radioactivity was mostly present as retinyl esters at all time points examined. Uptake of retinol in both parenchymal cells and stellate cells was reduced considerably in vitamin A-deficient rats. Less than 5% of the injected dose of radioactivity was found in liver after 5-6 h (as compared to 25% in control rats), and the radioactivity recovered in liver from these animals was mostly in the unesterified retinol fraction. Studies with separated cells in vitro suggested that both parenchymal and stellate cells isolated from control rats were able to take up retinol from the retinol-retinol binding protein-transthyretin complex. This uptake was temperature dependent.     

Acyl coenzyme A:retinol acyltransferase activity and the vitamin A content of polar bear (Ursus maritimus) liver

Acyl coenzyme A:retinol acyltransferase activity was identified in the microsomes from a polar bear liver. The highest rate of in vitro retinol esterification was 821 pmol/min/mg microsomal protein. The in vitro esterification rate displayed a small dependence upon the concentration of exogenous protein (bovine serum albumin) and even less on the concentration of sulfhydryl-reducing agent (dithiothreitol). Vitamin A was present in the liver at a concentration of 8050 micrograms/g tissue, with 98% of the vitamin in its ester form. Retinyl palmitate was 37.3% of the total liver retinyl esters, while retinyl oleate represented 20.9%, stearate 12.8%, and linoleate 7.7%.     

Retinyl esters are the substrate for isomerohydrolase

Regeneration of 11-cis retinal from all-trans retinol in the retinal pigment epithelium (RPE) is a critical step in the visual cycle. The enzyme(s) involved in this isomerization process has not been identified and both all-trans retinol and all-trans retinyl esters have been proposed as the substrate. This study is to determine the substrate of the isomerase enzyme or enzymatic complex. Incubation of bovine RPE microsomes with all-trans [(3)H]-retinol generated both retinyl esters and 11-cis retinol. Inhibition of lecithin retinol acyltransferase (LRAT) with 10-N-acetamidodecyl chloromethyl ketone (AcDCMK) or cellular retinol-binding protein I (CRBP) diminished the generation of both retinyl esters and 11-cis retinol from all-trans retinol. The 11-cis retinol production correlated with the retinyl ester levels, but not with the all-trans retinol levels in the reaction mixture. When retinyl esters were allowed to form prior to the addition of the LRAT inhibitors, a significant amount of isomerization product was generated. Incubation of all-trans [(3)H]-retinyl palmitate with RPE microsomes generated 11-cis retinol without any detectable production of all-trans retinol. The RPE65 knockout (Rpe65(-/-)) mouse eyecup lacks the isomerase activity, but LRAT activity remains the same as that in the wild-type (WT) mice. Retinyl esters in WT mice plateau at 8 weeks-of-age, but Rpe65(-/-) mice continue to accumulate retinyl esters with age (e.g., at 36 weeks, the levels are 20x that of WT). Our data indicate that the retinyl esters are the substrate of the isomerization reaction.     

Retinyl palmitate hydrolase activity in the bovine retina

Retinyl palmitate hydrolase (RPH) activity of bovine tissues was estimated from retinol formation following incubation of tissue homogenates with all-trans retinyl palmitate. The quantity of retinol produced in the incubation mixture was analyzed by high-performance liquid chromatography. RPH activities of retinal pigment epithelium (RPE), liver, retina, muscle and brain were 194.2, 138.0, 72.5, 25.0 and 5.1 units/gm protein respectively. The RPH activity in the retina was far above that attributable solely to RPE contaminations. The presence of RPH in the retina suggests that retina can utilize retinyl esters for the formation of visual pigments and/or cellular metabolism.     

Charge effects on phospholipid monolayers in relation to cell motility

A new sensitive method for the assay of retinyl ester hydrolase in vitro was developed and applied to liver homogenates of 18 young pigs with depleted-to-adequate liver vitamin A reserves. Radioactive substrate was not required, because the formation of retinol could be adequately quantitated by reversed-phase high-performance liquid chromatography. Optimal hydrolase activity was observed with 500 microM retinyl palmitate, 100 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate, and 2 mg/ml Triton X-100 at pH 8.0. The relative rates of hydrolysis of six different retinyl esters by liver homogenate were: retinyl linolenate (100%), myristate (99%), palmitate (47%), oleate (38%), linoleate (31%), and stearate (29%). The enzyme was found primarily in the membrane-containing fractions of liver (59 +/- 3%, S.E.) and kidney (76 +/- 3%), with considerably lower overall activity in kidney (57-375 nmol/h per g of tissue) than in liver (394-1040 nmol/h per g). Retinyl ester hydrolase activity in these pigs was independent of serum retinol values, which ranged from 3 to 24 micrograms/dl, and of liver vitamin A concentrations from 0 to 32 micrograms/g. Pig liver retinyl ester hydrolase differs from the rat liver enzyme in its substrate specificity, bile acid stimulation, and interanimal variability.     

Properties of liver retinyl ester hydrolase in young pigs

A new sensitive method for the assay of retinyl ester hydrolase in vitro was developed and applied to liver homogenates of 18 young pigs with depleted-to-adequate liver vitamin A reserves. Radioactive substrate was not required, because the formation of retinol could be adequately quantitated by reversed-phase high-performance liquid chromatography. Optimal hydrolase activity was observed with 500 μM retinyl palmitate, 100 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate, and 2 mg/ml Triton X-100 at pH 8.0. The relative rates of hydrolysis of six different retinyl esters by liver homogenate were: retinyl linolenate (100%), myristate (99%), palmitate (47%), oleate (38%), linoleate (31%), and streate (29%). The enzyme was found primarily in the membrane-containing fractions of liver (59±3%, S.E.) and kidney (76±3%), with considerably lower overall activity in kidney (57–375 nmol/h per g of tissue) than in liver (394–1040 nmol/h per g). Retinyl ester hydrolase activity in these pigs was independent of serum retinol values, which ranged from 3 to 24 μg/dl, and of liver vitamin A concentrations from 0 to 32 μg/g. Pig liver retinyl ester hydrolase from the rat liver enzyme in its substrate specificity, bile acid stimulation, and interanimal variability.     

Diacylglycerol O-Acyltransferase Type-1 Synthesizes Retinyl Esters in the Retina and Retinal Pigment Epithelium

Retinyl esters represent an insoluble storage form of vitamin A and are substrates for the retinoid isomerase (Rpe65) in cells of the retinal pigment epithelium (RPE). The major retinyl-ester synthase in RPE cells is lecithin:retinol acyl-transferase (LRAT). A second palmitoyl coenzyme A-dependent retinyl-ester synthase activity has been observed in RPE homogenates but the protein responsible has not been identified. Here we show that diacylglycerol O-acyltransferase-1 (DGAT1) is expressed in multiple cells of the retina including RPE and Müller glial cells. DGAT1 catalyzes the synthesis of retinyl esters from multiple retinol isomers with similar catalytic efficiencies. Loss of DGAT1 in dgat1 ^-/- mice has no effect on retinal anatomy or the ultrastructure of photoreceptor outer-segments (OS) and RPE cells. Levels of visual chromophore in dgat1 ^-/- mice were also normal. However, the normal build-up of all-trans-retinyl esters (all-trans-RE’s) in the RPE during the first hour after a deep photobleach of visual pigments in the retina was not seen in dgat1 ^-/- mice. Further, total retinyl-ester synthase activity was reduced in both dgat1 ^-/- retina and RPE.     

Fatty acid, carotenoid and vitamin A composition of tissues of free living gulls

The aim of this study was to investigate fatty acid and carotenoid profile as well as vitamin A (retinol and retinol esters) content in gull (Larus fucus) tissues. Palmitic (16:0) and stearic (18:0) fatty acids were major saturates in all the tissues studied. Oleic acid (18:1n-9) was the major monounsaturate in the tissue phospholipids varying from 11.9% (liver) up to 18.2% (lung). Arachidonic acid (20:4n-6) was the major unsaturate in the phospholipid fraction in all the tissues. Liver contained the highest total carotenoid concentration which was 5 and 7 fold higher compared to kidney and pancreas. In the liver beta-carotene was major carotenoid. In contrast, in all other tissues beta-carotene was minor fraction with lutein being major carotenoid. Zeaxanthin, canthaxanthin, beta-cryptoxanthin and echinenone were also identified in the gull tissues. Liver and kidney were characterised by the highest vitamin A concentrations (1067.5 and 867.5 microg/g, respectively). Retinol comprised from 55.3% (pancreas) down to 8% (kidney) of the total vitamin A but was not detected in the abdominal fat. Retinyl palmitate was the major retinyl ester in the liver, kidney and heart (44.2; 38.1 and 46.0% of total retinyl esters). In muscles and abdominal fat retinyl stearate was the major retinyl ester fraction. Therefore high proportions of beta-carotene were found in gull liver and peripheral tissues were enriched by lutein and zeaxanthin compared to the liver, a very high concentration of retinyl esters in the kidney was observed and tissue-specificity in retinyl ester proportions in peripheral tissues was found.     

Novel aspects of vitamin A metabolism in the dog: distribution of lipoprotein retinyl esters in vitamin A-deprived and cholesterol-fed animals

Retinyl ester concentrations in plasma from fasting humans, rabbits and rats are usually negligible. In contrast, plasma from fasting dogs contains appreciable amounts of retinyl esters, associated almost entirely with the low-density lipoproteins. This study was undertaken to gather additional information about the nature and origin of canine retinyl ester-containing lipoproteins. We examined the metabolism of endogenous lipoprotein retinyl esters in adult mongrel dogs with moderate vitamin A deficiency. Four animals were fed a diet of oatmeal and tuna fish that provided only 4% of the vitamin A contained in their control rations (15 vs. 367% of the canine recommended daily intake). There was an initial rapid decline in plasma retinyl esters. However, measurable concentrations persisted in plasma for up to 1 year of restricted vitamin A intake. Total plasma retinyl ester concentrations after 6 months of vitamin A deprivation, extrapolated from best-fit monoexponential decay curves for each animal, ranged from 11 to 89% of control, suggesting that there was sustained secretion of retinyl esters from endogenous stores. Density gradient ultracentrifugation of plasma from fasting vitamin A-deprived dogs showed retinyl esters in the very-low- and low-density lipoproteins. After fat and vitamin A feeding retinyl esters appeared among the very-low-, intermediate- and low-density lipoproteins, consistent with the suggestion that chylomicron retinyl esters are first taken up by the liver, and then resecreted as density less than 1.006-1.063 g/ml lipoproteins. Maximal incorporation of dietary retinyl esters into low-density lipoproteins was not reached until 24-48 h. Intermediate-density and beta-migrating low-density lipoprotein retinyl esters were increased markedly in fasting animals maintained on cholesterol- and saturated fat-enriched diets. These observations provide further evidence for the proposal that the canine liver secretes retinyl ester-containing particles, in amounts governed by dietary composition and vitamin A content. What selective advantage this unusual transport pathway might provide is not apparent.     

Identification of microsomal rat liver carboxylesterases and their activity with retinyl palmitate.

Retinyl esters are a major endogenous storage source of vitamin A in vertebrates and their hydrolysis to retinol is a key step in the regulation of the supply of retinoids to all tissues. Some members of nonspecific carboxylesterase family (EC 3.1.1.1) have been shown to hydrolyze retinyl esters. However, the number of different isoenzymes that are expressed in the liver and their retinyl palmitate hydrolase activity is not known. Six different carboxylesterases were identified and purified from rat liver microsomal extracts. Each isoenzyme was identified by mass spectrometry of its tryptic peptides. In addition to previously characterized rat liver carboxylesterases ES10, ES4, ES3, the protein products for two cloned genes, AB010635 and D50580 (GenBank accession numbers), were also identified. The sixth isoenzyme was a novel carboxylesterase and its complete cDNA was cloned and sequenced (AY034877). Three isoenzymes, ES10, ES4 and ES3, account for more than 95% of rat liver microsomal carboxylesterase activity. They obey Michaelis-Menten kinetics for hydrolysis of retinyl palmitate with Km values of about 1 micro m and specific activities between 3 and 8 nmol.min-1.mg-1 protein. D50580 and AY034877 also hydrolyzed retinyl palmitate. Gene-specific oligonucleotide probing of multiple-tissue Northern blot indicates differential expression in various tissues. Multiple genes are highly expressed in liver and small intestine, important tissues for retinoid metabolism. The level of expression of any one of the six different carboxylesterase isoenzymes will regulate the metabolism of retinyl palmitate in specific rat cells and tissues.     

Separation and identification of triglycerides, cholesteryl esters, cholesterol, 7-dehydrocholesterol, dolichol, ubiquinone, alpha-tocopherol, and retinol by high performance liquid chromatography with a diode array detector

A simple isocratic high performance liquid chromatography (HPLC) system is described that allows separation and identification of cholesteryl esters, triglycerides, ubiquinone, alpha-tocopherol, dolichol, cholesterol, 7-dehydrocholesterol, and retinol. This consisted of a normal phase cyanopropyl column with 0.1% isopropanol in heptane as the solvent. The effluent was monitored with an LKB model 2140 diode array detector which enabled the lipids to be identified by their characteristic absorption spectra. This system was applied to a sample of dog liver in which cholesteryl esters, retinyl esters, triglycerides, ubiquinone, dolichol, cholesterol, and retinol were identified. Retinyl esters and vitamin D esters were identified by their similarity in absorption spectra to retinol and vitamin D. A system to transfer and store the chromatograms on the VAX PDP-11 or an optical disc is also described.     

Plasma transport and tissue distribution of beta-carotene, vitamin A and retinol-binding protein in domestic cats.

The objective of this study was to determine retinol, retinyl esters and retinol-binding protein (RBP) as well as carotenoids in plasma, urine, liver and kidneys of randomly selected domestic cats. Retinol (240+/-64 ng/ml, mean+/-S.D.) represented one-third of total retinyl esters (736+/-460 ng/ml) in plasma. Retinyl esters were stearate, palmitate and oleate representing 61+/-6, 36+/-13 and 5+/-3% of total retinyl esters, respectively. In half of the cats, retinyl esters (22+/-21 ng/ml) were found in the urine. Vitamin A in the livers (4317+/-1956 microg/g) was significantly higher than in the kidney cortex and medulla (14.16+/-8.92 and 7.59+/-4.52 microg/g, respectively, both P<0.001). RBP was detected in the plasma but not in the urine. Immunoreactive RBP was observed in hepatocytes and in the cells of the proximal tubules. beta-Carotene was present in plasma but never in tissues. The results show that similar to canines differences in vitamin A metabolism in cats are related to the occurrence of retinyl esters in plasma. They differ, however, with regard to the tissue distribution of beta-carotene and the excretion of vitamin A in the urine.     

Hormone-sensitive lipase is a retinyl ester hydrolase in human and rat quiescent hepatic stellate cells

Hepatic stellate cells (HSC) store vitamin A as retinyl esters and control circulating retinol levels. Upon liver injury, quiescent (q)HSC lose their vitamin A and transdifferentiate to myofibroblasts, e.g. activated (a)HSC, which promote fibrosis by producing excessive extracellular matrix. Adipose triglyceride lipase/patatin-like phospholipase domain-containing protein 2 (ATGL/PNPLA2) and adiponutrin (ADPN/PNPLA3) have so far been shown to mobilize retinol from retinyl esters in HSC. Here, we studied the putative role of hormone-sensitive lipase (HSL/LIPE) in HSC, as it is the major retinyl ester hydrolase (REH) in adipose tissue.Lipe/HSL expression was analyzed in rat liver and primary human and rat qHSC and culture-activated aHSC. Retinyl hydrolysis was analyzed after Isoproterenol-mediated phosphorylation/activation of HSL.Primary human HSC contain 2.5-fold higher LIPE mRNA levels compared to hepatocytes. Healthy rat liver contains significant mRNA and protein levels of HSL/Lipe, which predominates in qHSC and cells of the portal tree. Q-PCR comparison indicates that Lipe mRNA levels in qHSC are dominant over Pnpla2 and Pnpla3. HSL is mostly phosphorylated/activated in qHSC and partly colocalizes with vitamin A-containing lipid droplets. Lipe/HSL and Pnpla3 expression is rapidly lost during HSC culture-activation, while Pnpla2 expression is maintained. HSL super-activation by isoproterenol accelerates loss of lipid droplets and retinyl palmitate from HSC, which coincided with a small, but significant reduction in HSC proliferation and suppression of Collagen1A1 mRNA and protein levels.In conclusion, HSL participates in vitamin A metabolism in qHSC. Equivalent activities of ATGL and ADPN provide the healthy liver with multiple routes to control circulating retinol levels.     

Uptake and metabolism of retinol in cultured Sertoli cells: evidence for a kinetic model

When cultured Sertoli cells derived from 20-day-old weanling rats were supplied [3H]retinol bound to serum retinol binding protein-transthyretin complex, [3H]retinol was rapidly incorporated and [3H]retinyl esters were synthesized. Within 28 h after administration, 83% of the labeled retinoids were accounted for as retinyl esters (64% as retinyl palmitate). Sertoli cells derived from vitamin A deficient rats and supplied [3H]retinol in culture under identical conditions likewise incorporated [3H]retinol and synthesized retinyl esters. In contrast to normal Sertoli cells, vitamin A deficient Sertoli cells eventually metabolized virtually all of the cellular [3H]retinol to retinyl esters. The primary metabolic fate of retinol administered to Sertoli cell cultures was the synthesis of retinyl esters under all conditions tested. However, administration of [3H]retinol bound to serum retinol binding protein gave metabolic profiles having a higher proportion of retinyl esters and lower proportions of unresolved polar material than administration of [3H]retinol alone. The kinetics of retinol uptake and intracellular retinyl ester synthesis in cultured Sertoli cells was complex. An initial, rapid phase of [3H]retinol incorporation lasting 30 min was followed by a slower rate of incorporation and a concomitant decrease in the intracellular concentration of [3H]retinol. During the time course the specific activity of [3H]retinyl palmitate eventually exceeded that of intracellular [3H]retinol. These observations suggest that two intracellular pools of retinol may exist in Sertoli cells.     

Fatty-acyl esters of retinol (vitamin A) in the liver of the harp seal (Phoca groenlandica), hooded seal (Cystophora cristata), and California sea lion (Zalophus californianus).

The fatty-acid composition of retinyl esters in the livers of two species of phocid seal, the harp seal (Phoca groenlandica, n = 20) and the hooded seal (Cystophora cristata, n = 15), and one species of otariid seal, the California sea lion (Zalophus californianus, n = 6), was determined. Vitamin A ranged in concentration from 4 to 1024 nmol retinol/g liver for the phocids and from 381 to 979 nmol/g liver for the otariids. In most of the livers, retinyl palmitate was not the principal ester, and the palmitate + stearate + oleate trio of retinyl esters represented less than 50% of the total. In all samples, the retinyl esters contained 20:1, 20:4, 20:5, and 22:6 in unusually large amounts. Retinyl esters tended to be richer than whole-liver lipids in 20:5 + 22:6, whereas whole-liver lipids were richer in 18:0 and 18:2. Therefore, the pool of acyl donors used for the esterification of retinol may be distinct from that used for other lipids. Birth-to-weaning changes were seen only in the harp seals. In the pups, the hepatic vitamin-A concentration increased 454%, while the proportion of 18:0 and 20:1 in the retinyl esters rose and that of 14:0 + 16:1 and 20:4 fell. Concomitantly, in their mothers, the proportion of 20:4 increased but that of 16:0 and 18:0 decreased.     

Plasma transport and tissue distribution of β-carotene, vitamin A and retinol-binding protein in domestic cats

The objective of this study was to determine retinol, retinyl esters and retinol-binding protein (RBP) as well as carotenoids in plasma, urine, liver and kidneys of randomly selected domestic cats. Retinol (240±64 ng/ml, mean±S.D.) represented one-third of total retinyl esters (736±460 ng/ml) in plasma. Retinyl esters were stearate, palmitate and oleate representing 61±6, 36±13 and 5±3% of total retinyl esters, respectively. In half of the cats, retinyl esters (22±21 ng/ml) were found in the urine. Vitamin A in the livers (4317±1956 μg/g) was significantly higher than in the kidney cortex and medulla (14.16±8.92 and 7.59±4.52 μg/g, respectively, both P<0.001). RBP was detected in the plasma but not in the urine. Immunoreactive RBP was observed in hepatocytes and in the cells of the proximal tubules. β-Carotene was present in plasma but never in tissues. The results show that similar to canines differences in vitamin A metabolism in cats are related to the occurrence of retinyl esters in plasma. They differ, however, with regard to the tissue distribution of β-carotene and the excretion of vitamin A in the urine.     

Hydrolysis of retinyl esters by non-specific carboxylesterases from rat liver endoplasmic reticulum.

The four most important non-specific carboxylesterases from rat liver were assayed for their ability to hydrolyse retinyl esters. Only the esterases with pI 6.2 and 6.4 (= esterase ES-4) are able to hydrolyse retinyl palmitate. Their specific activities strongly depend on the emulsifier used (maximum rate: 440 nmol of retinol liberated/h per mg of esterase). Beside retinyl palmitate, these esterases cleave palmitoyl-CoA and monoacylglycerols with much higher rates, as well as certain drugs (e.g. aspirin and propanidid). However, no transacylation between palmitoyl-CoA and retinol occurs. Retinyl acetate also is a substrate for the above esterases and for another one with pI 5.6 (= esterase ES-3). Again the emulsifier influences the hydrolysis by these esterases (maximum rates: 475 nmol/h per mg for ES-4 and 200 nmol/h per mg for ES-3). Differential centrifugation of rat liver homogenate reveals that retinyl palmitate hydrolase activity is highly enriched in the plasma membranes, but only moderately so in the endoplasmic reticulum, where the investigated esterases are located. Since the latter activity can be largely inhibited with the selective esterase inhibitor bis-(4-nitrophenyl) phosphate, it is concluded that the esterases with pI 6.2 and 6.4 (ES-4) represent the main retinyl palmitate hydrolase of rat liver endoplasmic reticulum. In view of this cellular localization, the enzyme could possibly be involved in the mobilization of retinol from the vitamin A esters stored in the liver. However, preliminary experiments in vivo have failed to demonstrate such a biological function.     

Orally Ingested 13C2-Retinol is Incorporated into Hepatic Retinyl Esters in a Nonhuman Primate (Macaca mulatta) Model of Hypervitaminosis A

The mechanism responsible for the metabolism of vitamin A during hypervitaminosis is largely unknown. This study investigated hepatic ¹³C-retinol uptake in hypervitaminotic A rhesus monkeys. We hypothesized that individual retinyl esters would be enriched in ¹³C after a physiologic dose of ¹³C₂-retinyl acetate, thus suggesting de novo in vivo hepatic retinol esterification. Male rhesus macaques (n = 16; 11.8 ± 2.9 y) each received 3.5 µmol 14, 15-¹³C₂-retinyl acetate. Blood was drawn at baseline and 5 h and 2, 4, 7, 14, 21, and 28 d after administration. Liver biopsies were collected 7 d before and 2 d after dose administration (n = 4) and at 7, 14, and 28 d after dose administration (n = 4 per time point). ¹³C enrichments of retinol and retinyl esters HPLC-purified from liver samples were measured by using gas chromatography–combustion–isotope ratio mass spectrometry. ¹³C enrichment of total vitamin A and individual retinyl esters were significantly greater 2 d after dose administration compared with baseline levels. In contrast, the concentration of isolated retinyl esters did not always increase 2 d after treatment. Given that the liver biopsy site differed between monkeys, these data suggest that the accumulation of hepatic retinyl esters is a dynamic process that is better represented by combining analytical techniques. This sensitive methodology can be used to characterize vitamin A trafficking after physiologic doses of ¹³C-retinol. In this nonhuman primate model of hypervitaminosis A, hepatic retinyl esters continued to accumulate with high liver stores.Abbreviations: GCCIRMS, gas chromatography–combustion–isotope ratio mass spectrometry, IRMS, isotope ratio mass spectrometry, PS/LO, ratio of retinyl palmitate plus stearate to retinyl linoleate plus oleateVitamin A is critical for vision, reproduction, and cellular differentiation.¹⁸ All tissue vitamin A originates as dietary vitamin A, which is predominantly available as preformed vitamin A (that is, retinyl esters)³ and the provitamin A carotenoids. Retinyl esters are cleaved to retinol in the intestinal lumen, and unesterified retinol is absorbed into the enterocyte.²⁵ Retinol is esterified within the intestinal mucosa^23,31 and then packaged into chylomicrons. These particles are exocytosed and transported into the general circulation,⁴ where they are degraded to chylomicron remnants and taken up by the liver.^5,9 Once in hepatic parenchymal cells, retinyl esters are rapidly hydrolyzed to retinol and, depending on the animals’ vitamin A status, retinol is secreted back into plasma bound to retinol-binding protein or transferred to stellate cells, reesterified, and stored.⁶ Thus, vitamin A in the liver occurs in 2 forms: as retinol and esterified to various fatty acids. Analysis of hepatic retinyl esters within 30 min of intravenous injection of labeled chylomicron retinyl ester in vitamin-A–sufficient rats recovered 80% to 90% of the dose. During vitamin A sufficiency, a majority of labeled chylomicron retinyl esters are taken up by the liver before subsequent hydrolysis.⁵Little is known about the storage and metabolism of vitamin A during hypervitaminosis A,^32,49 despite the wide use of retinoids pharmaceutically.⁴⁸ An early study involving hypervitaminotic A rats characterized increased concentrations of retinyl esters as percentages of total vitamin A in the plasma profile during excessive consumption of vitamin A.³² This study further identified that retinyl esters were transported in the serum by means of lipoproteins, thus mediating the vitamin''s nonspecific delivery to body tissues.³² Increased plasma levels of retinyl esters as a percentage of total vitamin A also occurred in human patients^10,28,49 and rhesus monkeys⁴¹ from the same colony as those used in the current study. Numerous case studies in humans document various symptoms of hypervitaminosis A, including dermatologic, hepatic, and neurologic pathologies.^{27,30,35,47,48} Hepatic pathologies include abnormal liver function tests consistent with accumulation of lipid-storing droplets. Similar accumulation of lipid droplets has been reported to occur in rhesus monkeys from the same colony as those in the current study.³⁹Previously, liver vitamin A concentrations in captive rhesus monkeys were reported to range from 11.9 ± 5.4 to 18.8 ± 6.4 μmol retinol/g liver,^8,33,39 which are several fold higher than the concentrations considered excessive (that is, 0.70 to 1.05 μmol/g liver) and toxic (that is, 1.05 μmol/g liver) in humans.³⁶ Hepatic vitamin A concentrations in 2 wild-caught control rhesus monkeys in a vitamin A deficiency study were 1.07 and 1.08 μmol retinol/g liver.³⁸ Systematic inquiry to uncover the source of the high liver vitamin A concentrations found that the dietary vitamin A intake of captive rhesus monkeys exceeds National Research Council recommendations.⁴⁰ Consistent with these excessive dietary vitamin A levels, clinical markers of hypervitaminosis A were present.⁸ To monitor the trafficking of a vitamin A dose during chronic hypervitaminosis A, we treated rhesus monkeys from the same colony as those cited earlier with ¹³C₂-retinyl acetate and collected liver biopsies as part of a study reported elsewhere.⁸ The main goal of the previous report was to validate a vitamin A assessment technique using the heavy stable isotope of carbon.In the current study, we hypothesized that isotope ratio mass spectrometry (IRMS) could be used to detect accumulation of individual hepatic retinyl esters and provide evidence of de novo in vivo hepatic retinol esterification after treatment of rhesus macaques with a physiologic dose of ¹³C₂-retinyl acetate. The ¹³C abundance of HPLC-purified hepatic retinyl esters collected at baseline was compared with that of posttreatment samples. Here we show that hepatic retinyl esters continue to accumulate in a nonhuman primate model by using state-of-the-art analytical methods and ¹³C-labeled retinol as a tracer.