Chemical synthesis of all-trans-[11-3H]retinoyl beta-glucuronide and its metabolism in rats in vivo.

All-trans-[11-3H]retinoyl beta-glucuronide (RAG) was synthesized in a single step from all-trans-[11-3H]retinoyl fluoride, with a 24% yield. After its intraperitoneal injection into rats, RAG was detected in the blood, liver, intestine and kidney during the following 24 h period. Although the concentration of radiolabelled metabolites decreased with time, RAG predominated at nearly all times in nearly all tissues. Small amounts of retinoic acid (RA) were also universally present, together with unidentified polar metabolites and small amounts of non-polar esters of RA. The major excretion products of RAG in faeces and urine were RA and polar metabolites. Thus RAG, although converted in part to RA in vivo, persists as a major component in blood and tissues for at least 24 h. These observations support the concept that the retinoid beta-glucuronides might serve a physiologically significant role in the function of vitamin A.     

Synthesis of 24S and 24R-hydroxy-[24-3H]vitamin D3 and their metabolism in rachitic rats.

An epimeric mixture of 24-hydroxy-[24-₃H]vitamin D₃ was synthesized by the reduction of 24-ketovitamin D₃ by sodium borotritide. The epimeric mixture was converted to the trimethylsilylether derivatives and subjected to high-pressure liquid chromatography using silica gel columns to separate the 24-hydroxy-[24-₃H]vitamin D₃ isomers. The 24R-hydroxy-[24-₃H] vitamin D₃ induced calcification in rachitic rats while the 24S-hydroxy-[24-₃H] vitamin D₃ had little or no such activity. As both isomers of 24-hydroxy-vitamin D₃ are metabolized to 24,25-dihydroxyvitamin D³, it appears that the 24-hydroxyvitamin D₃-25-hydroxylase does not discriminate between the isomers. Only the R-isomer of 24-hydroxyvitamin D₃ is metabolized to 1,24-dihydroxyvitamin D₃, although only trace amounts of this compound were found 2 days after the administration of 24-hydroxyvitamin D₃. The striking difference in the metabolism of the isomers is the high selectivity of the 1-hydroxylase for R-isomer. It is suggested that the high specificity of biological activity for the R-isomer of 24-hydroxyvitamin D₃ is because of the specificity of the 1-hydroxylation of 24,25-dihydroxyvitamin D₃ for the R configuration.     

Intestinal absorption and metabolism of retinoyl beta-glucuronide in humans, and of 15-[14C]-retinoyl beta-glucuronide in rats of different vitamin A status

In order to prove the hypothesis that humans and animals with adequate vitamin A status do not absorb and metabolize orally administered all-trans retinoyl β-glucuronide, unlabeled retinoyl glucuronide (0.1 mmol) was orally dosed to fasting well-nourished young men. Neither retinoyl glucuronide nor retinoic acid, a possible metabolite, appeared in the blood within 12 h after ingestion. Next, radiolabeled all-trans 15-[¹⁴C]-retinoyl β-glucuronide was chemically synthesized by a new procedure, and fed orally to rats of different vitamin A status. Analysis of blood and other tissues 5 or 24 h after the dose, showed the presence of radioactivity ( 0.5%) in the blood of vitamin A deficient rats, but not in sufficient rats. Livers of all rats contained small, but detectable amounts (0.3 to 1.1% of the dose) of radioactivity. The accumulation of radioactivity in the liver was highest in deficient rats. Analysis of the retinoids showed that the radioactivity in serum and liver was due to retinoic acid formed from retinoyl glucuronide. Within 24 h after the dose, 31 to 40% of the administered radioactivity was excreted in the feces, and 2 to 4.7% of the dose was excreted in the urine. Results of the present studies show that oral administration of retinoyl β-glucuronide did not give rise to detectable changes in blood retinoyl glucuronide and/or retinoic acid concentrations in humans or rats with adequate vitamin A status.     

Synthesis of 1 alpha-hydroxy[7-3H]cholecalciferol and its metabolism in the chick.

1. 1 alpha-Hydroxy[7-3H]cholecalciferol (specific radioactivity of 2-Ci/mmol) was synthesized, and its metabolism in chicks studied. 2. 1 alpha-Hydroxy[7-3H]cholecalciferol was metabolized very rapidly in the chick to 1 alpha,25-dihydroxy[7-3H]cholecalciferol and to a metabolite less polar than 1 alpha-hydroxycholecalciferol. Intestine exhibited highest accumulation of 1 alpha-25-dihydroxy[7-3H]cholecalciferol, and liver exhibited highest accumulation of the non-polar metabolite. 3. Tissue uptake of 1 alpha-hydroxy[7-3H]cholecalciferol and its metabolites in chicks that were dosed continuously for 16 days with 1 alpha-hydroxy[7-3H]cholecalciferol did not exceed by very much that observed in tissues obtained from chicks that were dosed with a single injection of 1 alpha-hydroxy[7-3H]cholecalciferol 24 h before killing, except for liver and kidney. 4. Lowest accumulation of metabolites was noted in muscle and bone, and for the latter, highest uptake of 1 alpha,25-dihydroxy[7-3H]cholecalciferol was noted in the epiphysial periosteum and the metaphysis. 5. Formation of 1 alpha,24,25-trihydroxy[7-3H]cholecalciferol was not observed in the chicks that were dosed continuously with 1 alpha-hydroxy[7-3H]cholecalciferol, despite the fact that plasma calcium and phosphorus were normal and despite the presence of renal 24-hydroxylase activity. 6. The vitamin D status of the chicks did not appear to affect the metabolic profile of the administered 1 alpha-hydroxy[7-3H]cholecalciferol.     

Synthesis of [3 beta-3H]-3-epivitamin D3 and its metabolism in the rat

3-Epivitamin D3, the 3 alpha epimer of vitamin D3, was synthesized, and its biological activity in the rat was evaluated. It was found to be approximately 4 times less active on a weight basis than vitamin D3 with respect to intestinal calcium transport, bone calcium mobilization, and calcification score as determined by the line-test assay. Tritiated 3-epivitamin D3 was prepared, and its metabolism in the rat was compared with that of vitamin D3 to investigate the reasons for this diminished activity. 3-Epivitamin D3 was converted to two polar metabolites, for which the chromatographic properties and the origin of biosynthesis (in the liver and kidney, respectively) correspond to 25-hydroxy-3-epivitamin D3 and 1 alpha,25-dihydroxy-3-epivitamin D3. The fact that the concentration of 1 alpha,25-dihydroxy-3-epivitamin D3 in the intestine is half that of 1 alpha,25-dihydroxyvitamin D3 may be one explanation for the reduced biological activity of this epimer.     

Synthesis of 1alpha-hydroxy [6-3H]vitamin D3 and its metabolism to 1alpha, 25-dihydroxy [6-3H]vitamin D3 in the rat.

1alpha-Hydroxy [6-3H]vitamin D3 has been synthesized with a specific activity of 4 Ci/mmol, and its metabolism in rats has been studied. It is rapidly converted to 1alpha,25-dihydroxy [6-3H]vitamin D3 in vivo. Following an intravenous or oral dose, a maximal concentration of 1alpha,25-dihydroxy [6-3H]vitamin D3 is found 2 and 4 hours, respectively, before the maximal intestinal calcium transport response is observed. Similarly, 1alpha,25-dihydroxy[6-3H]vitamin D3 accumulation in bone precedes the bone calcium mobilization response. It appears, therefore, that the biological activity of 1alpha-hydroxyvitamin D3 is largely, if not exclusively, due to its conversion to 1alpha,25-dihydroxy[6-3H]vitamin D3 1alpha-Hydroxy[6-3H]vitamin D3 and 1alpha,25-dihydroxy[6-3H]vitamin D3 appear in intestine equally well after an oral or an intravenous dose of 1alpha-hydroxy[6-3H]vitamin D3. However, much less of both 1alpha-hydroxy[6-3H]vitamin D3 and 1alpha,25-dihydroxy[6-3H]vitamin D3 appears in bone and blood after an oral than after an intravenous dose. A much reduced bone calcium mobilization response is also noted following an oral dose as compared to an intravenous dose of 1alpha-hydroxyvitamin D3, suggesting that oral 1alpha-hydroxyvitamin D3 is not utilized as well as intravenously administered material.     

Synthesis and metabolism of 5beta-[11,12-3H]cholestane-3alpha, 7alpha-diol

5beta-[11,12-3H]Cholestane-3alpha,7alpha-diol was synthesized as follows. 5beta-Cholestane-3alpha,7alpha,12atriol 3,7-diacetate was treated with phosphorus oxychloride in pyridine solution and then the product, 5beta-cholest-11-ene-3alpha,7alpha-diol diacetate, was hydrogenated in acetic acid solution using platinum oxide as a catalyst under an atmosphere of tritium gas. 5beta-[11,12-3H]Cholestane-3alpha,7alpha-diol thus obtained was readily hydroxylated at C-26 by mitochondria in the presence of isocitric acid, magnesium chloride and potassium cyanide.     

In vivo conversion of [3H]myoinositol to [3H]chiroinositol in rat tissues.

We report here the in vivo conversion of [3H]myoinositol to [3H]chiroinositol. After labeling intraperitoneally with [3H]myoinositol for 3 days to reach radioisotope equilibrium in urine, [3H]chiroinositol was isolated from tissues and purified after 6 N HCl hydrolysis by two sequential paper chromatographies and high performance liquid chromatography (HPLC). Percent conversion of [3H]myoinositol to [3H]chiroinositol was highest in urine (36%), liver (8.8%), muscle (8.8%), and blood (7.6%) with intestine, brain, kidney, spleen, and heart decreasing in percentage from 2.8 to 0.7%. Labeling of other inositol isomers including scyllo-, neo-, and epi-, and mucoinositol was minimal, approximately 0.06% of [3H]myoinositol. Glucose was unlabeled, but glucuronate, the product of myoinositol oxidation, was labeled up to 1.5% of the [3H] myoinositol. Acid hydrolysates of combined inositol-containing phospholipids contain significant labeled chiroinositol. [3H]Phosphatidylinositols and [3H]glycosylphosphatidylinositols were extracted from liver, muscle, and blood, isolated by thin layer chromatography, and inositols purified by HPLC after acid hydrolysis. Percent conversion of [3H]myoinositol to [3H] chiroinositol was highest in blood (60.4%) followed by muscle (7.7%) and liver (2.2%).     

Synthesis of [11-2H2], [8-2H2], [7-2H2], [6-2H2], [5-2H2], [4-2H2] and [3-2H2] cis-9-octadecenoates

Deuterated oleates have been synthesized by semihydrogenation of acetylenic intermediates. [11-²H₂]Oleate was prepared by two-carbon chain extension of the C₁₆ alcohol obtained from [1-²H₂]octyl bromide and 7-octyn-1-ol. [8-²H₂] and [7-²H₂]oleates were both prepared from dimethyl suberate, tetradeutero intermediate C₁₆ alcohols were synthesized from [1,8-²H₄] and [2,7-²H₄]octane diols by monobromination, conversion to deuterated 9-decyn-1-ols and reaction with octyl bromide. Oxidation gave [8-²H₂]-9-octadecynoate and [2,7-²H₂]-9-octadecynoate, after semihydrogenation of the latter, deuterons at C-2 were removed by exchange with aqueous alkali. [6-²H₂] and [5-²H₂]oleates were obtained from methyl 5-tetradecynoate, semihydrogenation, deuterium exchange at C-2 and two malonate extensions gave [6-²H₂]oleate; reduction with lithium aluminum deuteride, two malonate extensions and semihydrogenation gave the [5-²H₂] ester. [4-²H₂] and [3-²H₂]oleates were both obtained from methyl 7-cis-hexadecenoate, exchange of the α protons and chain extension gave the [4-²H₂] ester and reduction with lithium aluminum deuteride and chain extension gave the [3-²H₂] ester.     

Synthesis of 25-hydroxy[23,24-3H]vitamin D3

A synthesis of 25-hydroxy[23,24-³H]vitamin D₃ leading to a radiochemically pure product with a specific acitivity of 78 Ci/mmol is described. The structure of the product was confirmed by comparison with unlabeled material and its biological activity was established by in vitro conversion to 1α,25-dihydroxy[23,24-³H]vitamin D₃ using the chick kidney 1α-hydroxylase system.     

Comparison between D-[3-3H]- and D-[5-3H]glucose and fructose utilization in pancreatic islets from control and hereditarily diabetic rats

The metabolism of D-glucose and/or D-fructose was investigated in pancreatic islets from control rats and hereditarily diabetic GK rats. In the case of both D-glucose and D-fructose metabolism, a preferential alteration of oxidative events was observed in islets from GK rats. The generation of 3HOH from D-[5-3H]glucose (or D-[5-3H]fructose) exceeded that from D-[3-3H]glucose (or D-[3-3H]fructose) in both control and GK rats. This difference, which is possibly attributable to a partial escape from glycolysis of tritiated dihydroxyacetone phosphate, was accentuated whenever the rate of glycolysis was decreased, e.g., in the absence of extracellular Ca(2+) or presence of exogenous D-glyceraldehyde. D-Mannoheptulose, which inhibited D-glucose metabolism, exerted only limited effects upon D-fructose metabolism. In the presence of both hexoses, the paired ratio between D-[U-14C]fructose oxidation and D-[3-3H]fructose or D-[5-3H]fructose utilization was considerably increased, this being probably attributable, in part at least, to a preferential stimulation by the aldohexose of mitochondrial oxidative events. Moreover, this coincided with the fact that D-mannoheptulose now severely inhibited the catabolism of D-[5-3H]fructose and D-[U-14C]fructose. The latter situation is consistent with both the knowledge that D-glucose augments D-fructose phosphorylation by glucokinase and the findings that D-mannoheptulose, which fails to affect D-fructose phosphorylation by fructokinase, inhibits the phosphorylation of D-fructose by glucokinase.     

Synthesis and rapid purification of UDP-[6-3H]galactose

UDP[6-3H]galactose of high specificity can be obtained by oxidation of the C-6 hydroxymethyl group of UDP-galactose by galactose oxidase and subsequent reduction by sodium borotritide. One-step purification of the nucleotide sugar involves anion-exchange chromatography on a Pharmacia Mono Q column. Radiolabeled UDP-N-acetylgalactosamine can also be synthesized and purified by this procedure. Both nucleotide sugars can be used for sugar incorporation studies using the appropriate glycosyltransferase.     

Benzodiazepine receptor binding in vivo with [3H]-Ro 15-1788

In vivo benzodiazepine receptor binding has generally been studied by "ex vivo" techniques. In this investigation, we identify the conditions where [3H]-Ro 15-1788 labels benzodiazepine receptors by true "in vivo" binding, i.e. where workable specific to nonspecific ratios are obtained in intact tissues without homogenization or washing. [3H]-Flunitrazepam and [3H]-clonazepam did not exhibit useful in vivo receptor binding.     

Uptake and metabolism ofl-[3H]glutamate andl-[3H]glutamine in adult rat cerebellar slices

Using very low concentrations (1 mumol range) of L-2-3-[3H]glutamate, (3H-Glu) or L-2-3-[3H]glutamine (3H-Gln), we have previously shown by autoradiography that these amino acids were preferentially taken up in the molecular layer of the cerebellar cortex. Furthermore, the accumulation of 3H-Glu was essentially glial in these conditions. We report here experiments in which uptake and metabolism of either (3H-Glu) or (3H-Gln) were studied in adult rat cerebellar slices. Both amino acids were rapidly converted into other metabolic compounds: after seven minutes of incubation in the presence of exogenous 3H-Glu, 70% of the tissue accumulated radioactivity was found to be in compounds other than glutamate. The main metabolites were Gln (42%), alpha-ketoglutarate (25%) and GABA (1,4%). In the presence of exogenous 3H-Gln the rate of metabolism was slightly slower (50% after seven minutes of incubation) and the metabolites were also Glu (29%), alpha-ketoglutarate (15%) and GABA (5%). Using depolarizing conditions (56 mM KCl) with either exogenous 3H-Glu or 3H-Gln, the radioactivity was preferentially accumulated in glutamate compared to control. From these results we conclude: i) there are two cellular compartments for the neurotransmission-glutamate-glutamine cycle; one is glial, the other neuronal; ii) these two cellular compartments contain both Gln and Glu; iii) transmitter glutamate is always in equilibrium with the so-called metabolic pool of glutamate; iv) the regulation of the glutamate-glutamine cycle occurs at least at two different levels: the uptake of glutamate and the enzymatic activity of the neuronal glutaminase.     

Synthesis of methyl [18-2H3], [17-2H2], [16-2H2], [14-2H2] and [12-2H2] cis-9-octadecenoates

Methyl [17-²H₂]oleate was prepared by stepwise reduction from 17-oxooleate in 24% yield. Methyl [18-²H₃], [16-²H₂], [14-²H₂] and [12-²H₂] oleates were synthesized from appropriately deuterated octylbromides by conversion to deuterated 7-hexadecyn-1-ols and chain extention to deuterated stearolates followed by semihydrogenation; overall yields were about 17%.     

Studies on the in vitro metabolism of [3H]cortisol and [3H]oestradiol by sheep skin and wool roots.

The in vitro metabolism of [3H]cortisol, [3H]cortisone and [3H]estradiol-17 beta by adult sheep skin and wool follicle tissue (wool roots) was examined. The main metabolic product of the incubation of [3H]cortisol with sheep skin was [3H]cortisone, and the conversion was reversible. Wool roots were unable to carry out detectable interconversion, nor did this tissue give rise to other significant metabolites. Sheep skin and wool roots both rapidly converted [3H]oestradiol-17 beta to [3H]oestrone and the conversion could be carried out by follicle and non-follicle skin structures. It is suggested that sheep skin contains both 11 beta- and 17 beta-hydroxysteroid dehydrogenases, but that wool follicles contain only the latter enzyme.