Metabolic fates of diethylstilboestrol sulphates in the rat.

The metabolic fates and modes of excretion of diethylstilboestrol mono[35S]sulphate and diethylstilboestrol di[35S]sulphate were studied in the rat. Both of the esters were desulphated to some extent in vivo. In addition, significant amounts of radioactivity appeared in the bile as diethylstilboestrol mono[35S]sulphate monoglucuronide. The percentage of the dose appearing in bile as the diconjugate was substantially greater in experiments with diethylstilboestrol mono[35S]sulphate than with diethylstilboestrol di[35S]sulphate. Whole-body radioautography and studies with isolated perfused liver confirmed the liver as the major metabolic organ for both esters. When the metabolite diethylstilboestrol mono[35S]sulphate monoglucuronide isolated from the bile was reinjected, it was excreted in the bile unchanged. Studies in vitro demonstrated that both esters were substrates for arylsulphatase C with Km values in the range 52-76 micrometer. The metabolic fates and modes of excretion of the esters are discussed in relation to the enzyme complement of rat liver.     

Disulphates of 16-oxygenated ketonic c19 steroids as biliary metabolites of androsterone sulphate in female rats

The chemical synthesis of 16β-hydroxyandrosterone was described preparatory to studies of the disulphates of the 16-oxygenated ketonic C₁₉ steroids present in the bile of female rats dosed with [³H]androsterone sulphate. The biliary metabolites were separated by chromatography on Sephadex LH-20 to afford monosulphate and dicon jugate fractions. After solvolysis of the diconjugate fraction, the liberated steroids were separated by partition chromatography on Celite 545 and analyzed by gas chromatography-mass spectrometry. In addition to 3α, 17β-dihydroxy-5α-androstan-16-one isolated previously, 16β-hydroxyandrosterone was identified as a disulphate.     

Biliary excretion of cyclohexylphenyl 4-[35S]sulphate in the guinea pig.

The metabolic fate and mode of excretion of cyclohexylphenyl 4-[35S]sulphate were studied in the guinea pig. Up to 54.8% of the dose appeared in the bile, the majority as unchanged ester. Substantial amounts of hydroxylated cyclohexylphenyl 4-[35S]sulphate were also excreted in the bile together with minor amounts of the corresponding glucuronic acid conjugate. When isolated guinea-pig livers were perfused with cyclohexylphenyl 4-[35S]sulphate the biliary components were the same as those in the intact animal, although the relative concentration of the hydroxylated derivative was significantly greater. When the hydroxylated derivative was re-injected into guinea pigs it was excreted almost entirely unchanged in the bile. However, in the rat, it was excreted in the bile as a glucuronic acid conjugate. These findings are discussed in relation to studies carried out in the rat [Hearse, Powell, Olavesen & Dodgson (1969) Biochem. Pharmacol. 18, 181--195] and to differences in enzyme activities in rat and guinea-pig liver. The results are also discussed in terms of the molecular-weight threshold for the excretion of anions in guinea-pig bile.     

Synthesis of bile acid monosulphates by the isolated perfused rat kidney.

Perfusion of an isolated rat kidney with labelled bile acids, in a protein-free medium, resulted in the urinary excretion of the labelled bile acid, 3% being converted into polar metabolities in 1h. These metabolities were neither glycine nor taurine conjugates, nor bile acid glucuronides, and on solovolysis yielded the free bile acid. On t.l.c. the metabolite of [24-14C]lithocholic acid had the mobility of lithocholate 3-sulphate. The principal metabolite of [24-14C]chenodeoxycholic acid had the mobility of chenodeoxycholate 7-sulphate; trace amounts appeared as chenodeoxycholate 3-sulphate. [35S]sulphate was incorporated in chenodeoxycholic acid by the kidney, resulting in a similar pattern of sulphation. No disulphate salt of chenodeoxycholic acid was detected. These findings lend support to the hypothesis that renal synthesis may account for some of the bile acid sulphates present in urine in the cholestatic syndrome in man.     

Hydrogen exchange during oxidoreduction and epimerization at C-3 of C19 steroid sulphates in the rat

Mixtures of 17 beta-hydroxy-5 alpha-[16,16,17 alpha-2H3]androstan-3-one 17-sulphate and 5 alpha-[3 beta (or 3 alpha)-2H]androstane-3 alpha (or 3 beta), 17 beta-diol 17-sulphate were incubated with isolated hepatocytes from female rats or infused intravenously in female rats with bile fistulas. The androstanediols formed were analyzed by gas chromatography-mass spectrometry. Metabolism of 3H-labelled steroids was also studied in corresponding experiments. Isolated hepatocytes rapidly reduced the 3-oxosteroid to the corresponding 3 alpha-hydroxysteroid, which was more rapidly sulphated than the incubated 3 alpha-androstanediol. The 3 alpha-hydroxysteroid was extensively oxidoreduced both in vivo and in isolated hepatocytes. The intermediate formed during oxidoreduction in vivo was incompletely mixed with the infused 3-oxosteroid indicating extrahepatic uptake of the latter. The 3 beta-hydroxysteroid was sulphated without significant oxidoreduction and a minor fraction was converted to 3 alpha-hydroxysteroid both in vivo and in isolated hepatocytes. The incubated 3 beta-hydroxysteroid contributed more to the disulphate of the isolated 3 alpha-hydroxysteroid than to the monosulphate, indicating that the incubated 3-oxosteroid and the intermediate in the inversion were not completely mixed. Deuterium from the 3 beta- or 3 alpha-positions of the incubated [3-2H]androstanediols was not incorporated in androstanediol molecules derived from the 3-oxosteroid. However, both in vivo and in isolated hepatocytes the 5 alpha-[3 alpha-2H]androstane-3 beta,17 beta-diol 17-sulphate molecules which underwent inversion at C-3 retained 50-80% of the deuterium. This indicates that the inversion was not caused by two separate oxidoreductases.     

Glycosaminoglycans of arterial basement membrane-like material from cultured rabbit aortic myomedial cells

Arterial basement membrane-like material was prepared by a sonication-differential centrifugation technique from cultures of rabbit aortic myomedial cells after metabolic labelling with [35S]sulphate and [3H]glucosamine. Labelled glycosaminoglycans were obtained from isolated basement membrane-like material by proteinase digestion and gel filtration. Glycosaminoglycans were identified by a combination of Sephadex G-50 chromatography and sequential degradation with nitrous acid, Streptomyces hyaluronidase, testicular hyaluronidase and chondroitinase ABC. The data showed that heparan sulphate and chondroitin sulphate were the predominant glycosaminoglycans of myomedial basement membrane-like material. Heparan sulphate accounted for about 55% of [3H]glucosamine-labelled glycosaminoglycans. In addition small amounts of hyaluronic acid was present. Only trace amounts of dermatan sulphate was found. The glycosaminoglycans were analysed by DEAE-cellulose chromatography. Two major peaks were found in the chromatogram consistent with the predominance of heparan sulphate and chondroitin sulphate.     

Specific deuterium labelling and computerized gas chromatography -- mass spectrometry in studies on the metabolism in vivo of a steroid sulphate in the rat.

The metabolism of 3beta-hydroxy-5alpha-pregnan-20-one sulphate was studied in bile fistula rats and in isolated perfused livers. Computerized gas chromatography--mass spectrometry, in combination with specific deuterium-labelling, was employed to follow the metabolic transformations. Male animals excreted metabolites into bile more rapidly than females, a finding which could be correlated with the preferential formation of glucuronide conjugates in the male liver. The major metabolic pathway in male rats involved the steps: hydrolysis, 2alpha-hydroxylation, oxidoreduction at C-3 and glucuronide conjugation, yielding 2alpha, 3alpha-dihydroxy-5alpha-pregnan-20-one glucuronide as the major metabolite. Only traces of the injected steroid sulphate were detected in bile from male animals. In contrast, the administered compound was the major steroid excreted in bile of female rats, where the main metabolite was identified as 3beta,15beta-dihydroxy-5alpha-pregnan-20-one sulphate. A minor metabolite, 3beta,16alpha-dihydroxy-5alpha-pregnan-20-one, was found as a monosulphate in female rats and as both a disulphate and a glucuronide conjugate in male rats. The deuterium content of the sulphated 15beta-and 16alpha-hydroxylated metabolites was consistent with metabolic pathways involving direct hydroxylation of the injected steroid sulphate. The results obtained from the liver perfusions were essentially the same as those from the experiments with bile fistula animals. This indicates that all the observed metabolic reactions took place in the liver.     

The metabolism of sodium cortisone 27-[35S]-sulphate in the rat

1. The metabolism of sodium cortisone 21-[(35)S]sulphate was investigated in rats. 2. Quantitative and qualitative experiments showed that substantial amounts of (35)SO(4) (2-) appeared in the urine of free-ranging rats receiving the ester. 3. Whole-body radioautograms indicated considerable biliary elimination of (35)S and also pointed to the liver as the site of metabolism. 4. When female rats with bile-duct cannulae received sodium cortisone 21-[(35)S]sulphate approx. 70% of the dose appeared in the bile as a doubly conjugated steroid (metabolite I). This metabolite was identified as 3alpha-(beta-d-glucopyranuronosido)- 17alpha-hydroxy-21-[(35)S]sulpho-oxy-5alpha-pregnane-11,20-dione. 5. When metabolite I was administered to a rat with a bile-duct cannula 90% of the dose appeared in the bile unchanged. After the administration (intraperitoneally or orally) of metabolite I to free-ranging rats considerable amounts of (35)SO(4) (2-) appeared in the urine. 6. The route by which (35)SO(4) (2-) might be produced from cortisone [(35)S]sulphate in free-ranging animals is discussed.     

The metabolism of dipotassium 2-hydroxy-5-nitrophenyl [S]sulphate, a substrate for lysosomal arylsulphatases A and B

The metabolic fate of dipotassium 2-hydroxy-5-nitrophenyl [³⁵S]sulphate ([³⁵S]NCS), a chromogenic substrate for lysosomal arylsulphatases A and B, has been studied in rats. Intraperitoneal injection of [³⁵S]NCS into free-ranging animals is followed by excretion of the bulk of the radioactivity in the urine within 24hr., less than 13% being eliminated as inorganic [³⁵S]sulphate. Most of the urinary radioactivity can be accounted for as [³⁵S]NCS, but small amounts of a labelled metabolite are also present. Experiments in which [³⁵S]NCS was injected intravenously into anaesthetized rats with bile-duct and bladder cannulae confirm that the ester is rapidly excreted in the urine. However, small amounts of radioactivity appear in bile, mainly in the form of the metabolite detected in urine. When [³⁵S]NCS is perfused through the isolated rat liver, about 35% of the dose is hydrolysed within 3hr. Similar results are obtained if [³⁵S]NCS is injected into anaesthetized rats in which kidney function has been eliminated by ligature of the renal pedicles. The labelled metabolite has been isolated from bile obtained by perfusing several rat livers with blood containing a total of 100mg. of [³⁵S]NCS. It has been identified as 2-β-glucuronosido-5-nitrophenyl [³⁵S]sulphate. The implications of the various findings are discussed. The Appendix describes the preparation of [³⁵S]NCS.     

Demonstration of 8 S-cytoplasmic oestrogen receptor in rat mullerian duct.

1. High affinity macromolecular binding of the non-steroidal synthetic oestrogen [3H]diethylstilboestrol and of [3H] oestradiol-17beta in cytosol of Müllerian duct and uterus, and in blood plasma of perinatal rats, was investigated by sucrose density gradient sedimentation. 2. While [3H] oestradiol was bound to both the characteristic 8 S uterine cytoplasmic receptor and a 4 S component of uterine cytosol and plasma of 11-day-old rats, [3H] diethylstilboestrol was bound almost exclusively by the 8 S cytoplasmic receptor. 3. The greatly reduced binding of [3H] diethylstilboestrol to the 4 S plasma plasmic receptor in the Müllerian duct (precursor of the uterus) of 20-day-old foetuses.     

Metabolism of sodium oestrone [35S]sulphate in the guinea pig

Intraperitoneal administration of sodium oestrone [(35)S]sulphate to male and female free-ranging guinea pigs is followed by excretion of most of the radioactivity mainly as inorganic [(35)S]sulphate in the urine within 72h. The remainder of the radioactivity in the urine was found in oestrone [(35)S]sulphate, two unidentified metabolites (A and B) and traces of oestradiol-17beta 3-[(35)S]sulphate. When injected intraperitoneally into animals with bile-duct and bladder cannulae, most of the dose was excreted in the bile. Unchanged oestrone [(35)S]sulphate was the main biliary component excreted in males and females, but the latter also excreted appreciable amounts of oestradiol-17beta 3-[(35)S]sulphate and metabolites A and B. The urine from these animals also contained these metabolites, inorganic [(35)S]sulphate and also oestrone [(35)S]sulphate, but in small amounts. Metabolite A was present only in samples from males. Whole body radioautography pinpointed the liver and kidney as the possible sites of metabolism of the ester. The ester underwent little desulphation in the isolated perfused female guinea-pig liver and in animals in which kidney function had been eliminated, and was excreted unchanged in the bile. These results and the observed low oestrogen sulphatase and arylsulphatase C activities found in guinea-pig liver and kidney support the view that the two enzymes are identical.     

The effects of cycloheximide on the biosynthesis and secretion of proteoglycans by chondrocytes in culture.

Proteoglycans synthesized by rat chondrosarcoma cells in culture are secreted into the culture medium through a pericellular matrix. The appearance of [35S]sulphate in secreted proteoglycan after a 5 min pulse was rapid (half-time, t 1/2 less than 10 min), but that of [3H]serine into proteoglycan measured after a 15 min pulse was much slower (t 1/2 120 min). The incorporation of [3H]serine into secreted protein was immediately inhibited by 1 mM-cycloheximide, but the incorporation of [35S]sulphate into proteoglycans was only inhibited gradually(t 1/2 79 min), suggesting the presence of a large intracellular pool of proteoglycan that did not carry sulphated glycosaminoglycans. Cultures were pulsed with [3H]serine and [35S]sulphate and chased for up to 6 h in the presence of 1 mM-cycloheximide. Analysis showed that cycloheximide-chased cells secreted less than 50% of the [3H]serine in proteoglycan of control cultures and the rate of incorporation into secreted proteoglycan was decreased (from t 1/2 120 min to t 1/2 80 min). Under these conditions cycloheximide interfered with the flow of proteoglycan protein core along the route of intracellular synthesis leading to secretion, as well as inhibiting further protein core synthesis. The results suggested that the newly synthesized protein core of proteoglycan passes through an intracellular pool for about 70-90 min before the chondroitin sulphate chains are synthesized on it, and it is then rapidly secreted from the cell. Proteoglycan produced by cultures incubated in the presence of cycloheximide and labelled with [35S]sulphate showed an increase with time of both the average proteoglycan size and the length of the constituent chondroitin sulphate chain. However, the proportion of synthesized proteoglycans able to form stable aggregates did not alter.     

Metabolite production during the biodegradation of the surfactant sodium dodecyltriethoxy sulphate under mixed-culture die-away conditions

Sodium dodecyltriethoxy sulphate (SDTES), either pure or as a component of commercial surfactant mixtures, underwent rapid primary biodegradation by mixed bacterial cultures in OECD screen and river-water die-away tests. Inoculation of [35S]SDTES-containing solutions with OECD screen test media acclimatized to surfactants or their degradation products led to production of various 35S-labelled glycol sulphates and their oxidation products, all known to occur during degradation of [35S]SDTES by pure bacterial isolates. Triethylene glycol monosulphate was the major catabolite together with smaller amounts of di- and monoethylene glycol monosulphates implying, by analogy with pure cultures, that ether-cleavage was the major primary biodegradation step. The oxidation product (carboxylate derivative) of each glycol sulphate was also detected together with metabolites tentatively identified as omega-/beta-oxidation products of the dodecyl chain. Relatively little SO2-4 was liberated directly from SDTES but mixed cultures derived from sewage could metabolize the sulphated glycols to SO2-4. The environmental relevance of these degradation routes was established by following metabolite production from [35S]SDTES in full-scale river-water die-away tests. Triethylene glycol sulphate was formed first, then rapidly oxidized to acetic acid 2-(diethoxy sulphate) which persisted as the major metabolite for 2-3 weeks. Small amounts of sulphated derivatives of di- and monoethylene glycols were also detected during the same period. Very little SO2-4 was formed directly from SDTES but large amounts accompanied the eventual disappearance of glycol sulphate derivatives. None of the 35S-labelled organic metabolites was persistent and, whenever [35S]SDTES was a component of a commercial mixture, all ester sulphate was completely mineralized to 35SO4(2-) within 28 d.     

Enhanced channelling of sulphate through a rapidly exchangeable sulphate pool in response to stimulated glycosaminoglycan synthesis in pancreatic epithelial cells.

The ability of cells to decorate glycosaminoglycans (GAGs) with sulphate in highly specific patterns is important to extracellular matrix biogenesis and placing appropriate glycosulphated ligands on the cell surface. We have examined sulphate metabolism in two pancreatic duct epithelial cell lines - PANC-1 and CFPAC-1 (derived from a cystic fibrosis patient) with a view to understanding how pancreatic cells utilise intracellular sulphate. [35S]Sulphate uptake was rapid and reached near steady state levels within 10 min. However, the intracellular specific activity of [35S]sulphate for PANC-1 and CFPAC-1 reached only 35 and 10%, respectively, of the medium specific activity at 10 min. Therefore, sulphate appears to reside within two compartments; a rapidly exchangeable sulphate pool (RESP) and a slowly exchangeable sulphate pool (SESP). Reducing chloride in the medium, increased the specific activity of [35S]sulphate within cells and increased the size of the inorganic sulphate pool, suggesting that the RESP was enlarged. Sulphate pools were not different in size between the two cell lines in physiological NaCl. Increasing the size of the sulphate pool had no effect on [35S]sulphate:[3H]glucosamine ratios incorporated into glycosaminoglycans (GAGs); however, stimulating the synthesis of GAGs with 4-methylumbelliferyl-beta-d-xyloside, stably elevated [35S]:[3H] ratios. This was due to higher [35S]sulphate incorporation. [35S]Cysteine contributed less than 0.1% of the cells' sulphate requirements. We conclude that in the face of elevated demand for sulphate, pancreatic cells appear to channel a greater proportion through the RESP.     

Precursors in the biosynthesis of vasopressin and oxytocin in the rat. Characteristics of all the components in high-performance liquid chromatography.

A reverse-phase high performance liquid-chromatography (h.p.l.c.) protocol has been developed, whereby all the major known posterior-pituitary components that are derived from the processing of pro-oxytocin and pro-vasopressin can be separated one from another. Thus, in a single chromatographic step, it has been possible to separate vasopressin (VP), oxytocin (OT), oxytocin-neurophysin (rOT-Np), vasopressin-neurophysin (rVP-Np) and vasopressin-glycopeptide (rVP-GP) from acid extracts of the neurointermediate lobes of rat pituitary glands. All these peptides except rVP-GP were labelled in the neural lobe by 24h after a hypothalamic injection of [35S]cysteine, whereas all except VP were labelled by 24h after a similar injection of [3H]leucine. Three major labelled proteins were isolated from 20 min [35S]cysteine-injected rats when extracts of the supraoptic nucleus were subjected to Sephadex G-75 chromatography, h.p.l.c. and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Immunoprecipitation with antisera raised against rat neurophysins, VP and OT revealed 21000- and 19000-mol.wt. common precursors to VP and rVP-Np and a 15000-mol.wt. common precursor to OT and rOT-Np. Some immunoreactive rVP-Np could occasionally be detected in the Vo of Sephadex G-75 chromatograms of Wistar rat supraoptic-nucleus extracts, but no evidence of [35S]neurophysin in this fraction was obtained from h.p.l.c. fingerprinting of its S-carboxymethylated tryptic digests. Radioimmunoassay for rVP-Np and rOT-Np revealed that about 70-80% of the total recovered immunoreactive neurophysin (IR-Np) in the supraoptic nucleus eluted from Sephadex G-75 and h.p.l.c. in the positions of rVP-Np and rOT-Np. Evidence is presented for an approx. 20000-mol.wt. rOT-Np in both Wistar and Brattleboro rats and for an approx. 20000-mol.wt. component in the Brattleboro rat that is recognized by vasopressin-neurophysin antisera.     

Synthesis and secretion of sulphated glycoproteins by rabbit oviduct explants in vitro

The ability of rabbit oviduct explants to incorporate radiolabelled precursors into specific secretory products was investigated. Ampullary and isthmic oviduct segments were cultured in the presence of [3H]glucosamine or [35S]sodium sulphate. Medium samples were analysed for the presence of secreted, labelled macromolecules. Explants incorporated the [3H]glucosamine and secreted labelled glycoproteins in vitro. SDS gel electrophoresis and subsequent fluorographic analysis of culture medium demonstrated a differential secretion of glycoproteins between the ampulla and the isthmus. Although ampullary tissue secreted a greater amount of labelled glycoproteins during the sampling period, the major secretory constituent of Mr approximately 66,000 was common to both oviduct segments. Tissue incubated with [35S]sodium sulphate also secreted a labelled glycoprotein or subunit of Mr approximately 66,000. The results indicate that rabbit oviduct explants are capable of synthesis and secretion of specific sulphated glycoproteins in vitro and that there is a difference in the type and amount of secretion produced between the two oviduct segments.     

Dehydroepiandrosterone sulphate in rat brain: incorporation from blood and metabolism in vivo

The incorporation of [7-³H]dehydroepiandrosterone[³⁵S]sulphate into brain tissue elements from the circulatory system and its metabolic fate in the brain were studied in developing rats. Approximately 0.037 % of [³H] and 0.023% of [³⁵S] were incorporated into the brain within 15 min after the intracardiac injection of the labelled steroid. More than one-half of the incorporated [³H] was recovered as free steroid, whereas the rest was recovered as sulphate. The ³H/³⁵S ratio in the sulphate fraction suggested that the sulphate entered the brain with the sulphate linkage intact. Upon intracerebral injection of the double-labelled steroid, approximately 6 per cent of the radioactivity was recovered in the brain at 30 min after the injection and 1 per cent was recovered at 1 h after the injection. Of the remaining radioactivity recovered from the brain, 5 per cent was found in the free steroid fraction, probably formed by hydrolysis of the sulphate; 90 per cent was in the sulphate ester fraction; and the rest was in the fraction of more polar compounds. To identify the metabolites, [4-¹⁴C]dehydroepiandrosterone sulphate was injected into the rat brain. Significant amounts of radioactivity were found in androstenediol sulphate, which was isolated from the brain. This compound was apparently derived from dehydroepiandrosterone sulphate by reduction of the 17-keto group to a 17β-hydroxyl group without prior hydrolysis. There was suggestive evidence that free androstenediol was also formed in the brain in this experiment.     

Oxygen-dependent desulphation of monomethyl sulphate by Agrobacterium sp. M3C

Agrobacterium sp. M3C, previously isolated from canal-water for its ability to grow on monomethyl sulphate, degraded this ester with stoichiometric liberation of inorganic sulphate. In contrast with the biodegradation of monomethyl sulphate in Hyphomicrobium sp., and of other longer-chain alkyl sulphates in Pseudomonas spp., the pathway in Agrobacterium appeared not to involve a sulphatase enzyme capable of catalysing ester-bond hydrolysis. No such sulphatase was detectable under a range of conditions of bacterial culture, or using various methods for preparing cell-extracts, or different assay conditions. There was no incorporation of ¹⁸O-label from H₂ ¹⁸O into the liberated inorganic sulphate. No methanol was detectable during biodegradation, and the organism was incapable of growth on methanol, and did not produce methanol dehydrogenase activity when grown on monomethyl sulphate. Tracer studies using mono[¹⁴C]-methyl sulphate indicated that formate serine and glycine were produced during the biodegradation. The presence of these amino acids, together with high activity of hydroxypyruvate reductase, indicated the operation of the serine pathway common in methylotrophs. Use of an oxygen electrode in conjunction with monomethyl[³⁵S]sulphate showed that release of ³⁵SO₄ ^2- was dependent on availability of O₂, and that there was equimolar stoichiometry among monomethyl sulphate degraded, O₂ consumed and ³⁵SO₄ ^2- released. A proposed pathway for the degradation involved an initial mono-oxygenation to methanediol monosulphate with subsequent elimination of SO₄ ^2- and concomitant formation of formaldehyde. The pathway was compared with degradation mechanisms for other C₁ compounds and for other sulphate esters.     

Kinetic measurements of the biliary excretion of metabolized compounds.

1. Rats received constant infusions of bromosulphophthalein or [carboxy-14C]cholic acid at a range of concentrations. 2. Kinetic parameters describing the biliary excretion of the compounds were determined. 3. The biliary excretion of both compounds could be described by the same kinetic parameters already calculated for phenolphthalein disulphate, which is excreted in the bile unchanged.     

The metabolism of N-triphenylmethylmorpholine in the dog and rat

1. Rats were given N-triphenyl[(14)C]methylmorpholine, triphenyl[(14)C]carbinol, N-triphenylmethyl[G-(3)H]morpholine or [G-(3)H]morpholine as single oral doses; the routes of excretion were examined. 2. Dogs were given single oral doses of N-triphenyl[(14)C]methylmorpholine. 3. (14)C-labelled metabolites were excreted mainly in the faeces in both rats and dogs; no (14)CO(2) was expired and less than 3% remained in the carcass and skin after 96hr. 4. (3)H-labelled metabolites were excreted rapidly in urine; part of the label was found in the expired gases and over 10% remained in the carcass and skin after 96hr. 5. Differences in excretion pattern between the sexes were noticed in rats but not in dogs. 6. N-Triphenylmethylmorpholine was rapidly hydrolysed to form triphenylcarbinol and morpholine in the stomach; morpholine was absorbed rapidly and excreted largely unchanged, though some was degraded, since some of the (3)H was found in water. 7. Triphenylcarbinol was absorbed only slowly and was oxidized to p-hydroxyphenyldiphenylcarbinol. 8. Both triphenylcarbinol and its p-hydroxy derivative were found in urine, bile and faeces in the free form and conjugated with glucuronic acid. The proportion of conjugates was higher in rat bile than in faeces. 9. Traces of o-hydroxyphenyldiphenylcarbinol and m-hydroxyphenyldiphenylcarbinol were detected as metabolites both free and conjugated.