N G,N G -Dimethyl-l-arginine,a dominant precursor of endogenous dimethylamine in rats

Summary The metabolic significance ofN ^G ,N ^G -dimethyl-l-arginine (DMA) as a precursor of endogenous dimethylamine (DMN) in rats was examined in connection with the wide distribution and active operation of dimethylargininase (EC3.5.3.18) in rat tissues (Kimoto et al., 1993). When [methyl-¹⁴C]DMA was administered intraperitoneally to rats, the radioactive DMN was detected in various tissues as a major radioactive metabolite one hour after injection, and about 65% of the radioactivity administered was recovered in the first 12-h urine as DMN. In the case of the [¹⁴C] DMN-injected rats, almost all the radioactivity was excreted in the 12-h urine as DMN, except for a negligible amount of radioactivity found in urea. The time-dependent decrease in the specific radioactivity of DMA and DMN in urine showed that dimethylargininase was significantly involved in thein vivo formation of DMN by the hydrolytic cleavage of DMA released from methylated proteins and that DMA is a dominant precursor of endogenous DMN in rats.     

Metabolie Fate of Glycyl-14C-prolylhydroxyproline in Young Rats

To examine the origin of urinary hydroxyproline peptides, the metabolism of the radioactive tripeptide, glycyl-¹⁴C-prolylhydroxyproline, was investigated in normal young rats in vivo. The radioactive tripeptide was synthesized from glycine, l-(U-¹⁴C)proline and hydroxy-l-proline in our laboratory. The distributions of the radioactivity in body protein, lipid and soluble fractions were 23.7, 1.8 and 0.12% of the injected dose, respectively, 56 hr after the intraperitoneal injection of the ¹⁴C-tripeptide. The excretions of the radioactivity into expired carbon dioxide and urine were 29.6 and 34.2% of the injected dose, respectively, and large proportions of both the ¹⁴C excretions occurred during the first 12hr.

The results suggest that not a small amount of the glycylprolylhydroxyproline peptide injected is hydrolyzed in tissues of animals and the free proline derived is used for protein synthesis and/or further degraded to expired carbon dioxide.>     

Metabolism of Hymexazol, 3-Hydroxy-5-methylisoxazole,in the Rats

Excretion, distribution and metabolism of the fungicide, hymexazol, (3-hydroxy-5-methylisoxazole), labeled with carbon-14 were examined after administration of a single oral dose to Wistar-strain rats. Hymexazol was rapidly absorbed and distributed in the tissues. During 96 hr, 97% of the total radioactivity was excreted in the urine and 0.89% in the feces, and 0.86% was found in the expired gasses for 24 hr. Two metabolites were detected in the urine, whose chemical structures were determined as 3-(β-d-glucopyranuronosyloxy)-5- methylisoxazole and 5-methyl-3-isoxazolyl sulfate.     

Preparation,characterization, biological activity and metabolism of all-trans retinoyl fluoride

All-trans retinoyl fluoride was prepared by treating all-trans retinoic acid with diethylaminosulfurtrifluoride. The crystalline product, which was characterized by melting point, infrared, ¹H-NMR, ¹⁹F-NMR and elementary analysis, showed λ_max at 382 nm in hexane (ε = 4.98·10⁴ M^?1·cm^?1) and at 392 nm in methanol (ε = 4.60·10⁴ M^?1·cm^?1). Its biological activity in the rat growth assay, relative to all-trans retinyl acetate, was 22% ± 10%. Upon oral administration for 5 days to vitamin A-depleted rats, retinoyl fluoride (1020 μg) was rapidly metabolized to a polar metabolite fraction and, in the intestine, to an unstable retinol-like metabolite, purpotedly 15-fluororetinol. Upon administering intraperitoneally smaller doses (47–94 μg) of [11-³H]retinoyl fluoride, which was synthesized from [11-³H] retinoic acid, radioactive retinoic acid was noted in the liver and plasma but not in the intestine. As expected, a radioactive polar fraction appeared in the intestine and liver, but radioactive retinol, retinyl ester and some common oxidation products were not detected. Of the administered radioactivity, 72% was excreted in the urine, and only 4% was found in the feces over a 7-day period. Hydrolysis of the urine gave a radioactive fraction with a polarity similar to that of retinoic acid. Retinoyl fluoride also reacts readily with glycine to yield N-retinoyl glycine. Thus, the biological activity of retinoyl fluoride can be attributed to the formation of retinoic acid, probably by way of N-retinoyl derivatives. A possible pathway for its metabolism is presented.     

The role of urea in nitrogen excretion and caecal nitrogen metabolism in Willow ptarmigan

Summary The fate of¹⁴C-urea, injected intraperitoneally in Willow ptarmigan (Lagopus l. lagopus) has been examined. During five hours 13.6% of the injected activity was recovered in expired CO₂ and 3.5% in urine. Expired activity decreased exponentially with time at a rate corresponding to a half life of 104 min. After Neoterramycin treatment recovery in CO₂ decreased to 7.2% and recovery in urine increased to 8.0%. Specific activity of the caecal content was 7 times higher than average at the end of the experiments. The results indicate that only a minor proportion of the urea from the bird's systemic circulation is excreted in the urine, the major part being hydrolyzed by the caecal microorganisms.     

Excretion,Metabolism and Tissue Distribution of A Spin Trapping Agent, α-Phenyl-N-Tert-Butyl-Nitrone (Pbn) in Rats

The objective of this study is using radiolabelled PBN to determine the tissue distribution, excretion, and metabolism of PBN in rats in order to evaluate the effective time to trap free radical in appropriate tissue(s). Our results demonstrated that PBN is rapidly absorbed when it is injected intraperitoneally in the animal. PBN can be used as an effective spin trapping agent for a variety of tissues since it is evenly distributed among a wide range of tissues measured. Since there is no difference in the tissue concentrations and distribution pattern of PBN at 15, 30 and 60min after injection of PBN. it is appropriate to choose any of these time intervals to terminate the experiment and extract the spin adduct. The excretion of PBN, however, is slow. The majority of the radioactivity (70%) was excreted by the first 3 days. Only 5.7% of radioactivity was collected from 3 to 14 days. The remaining 25% of the radioactivity may be in the form of expired ¹⁴CO₂. Trace amounts of radioactivity were recovered in the feces. PBN has probably only one major form of metabolite excreted in the urine. A small amount of the parent compound, however, was also excreted in the urine. The chemical structure of the metabolite(s) is still unknown.     

Lipoic acid metabolism in the rat

dl-[1,6-¹⁴C]Lipoic acid was administered by intraperitoneal injection to rats at the level of 0.5 mg/100 g body weight. Approximately 56% of the radioactivity was recovered in the urine. When acidified and extracted with benzene, 92% of the radioactivity remained in the aqueous phase. Gel-filtration and paper chromatography were used to identify three of the compounds in the benzene extract as lipoic, bisnorlipoic and tetranorlipoic acids. In addition, a keto compound appears to be present. The aqueous phase contained several radioactive components separable by ion-exchange and paper chromatographies. Two of these compounds were identified as lipoate and β-hydroxybisnorlipoate. No evidence for oxidation of the dithiolane ring of lipoic acid was observed. dl-[7,8-¹⁴C]Lipoic acid was administered to rats under the same conditions. The urine contained 81% of the radioactivity, 72% of which remained in the aqueous phase and 28% was extracted into benzene. In contrast to over 30% of the label from dl-(1,6-¹⁴C] lipoate being expired as ¹⁴CO₂, a negligible amount of ¹⁴CO₂ was produced by rats injected with dl-[7,8-¹⁴C]lipoate. The catabolites identified were the same as those found using the 1,6-labeled lipoate. Another dithiolane-intact compound was also isolated. It appears that the rat, similar to Pseudomonas putida LP, metabolizes lipoate mainly via β-oxidation of the valeric acid side chain.     

Precursors of the pyrimidine moiety of thiamine

1. A method was devised for obtaining the pyrimidine moiety of thiamine in a pure form after its excretion into the medium by de-repressed washed-cell suspensions of mutants of Salmonella typhimurium LT2. 2. By using amino acid-requiring mutants, this excretion of pyrimidine moiety was shown to be dependent on the presence of both methionine and glycine. 3. In the presence of either [Me-¹⁴C]methionine or [G-¹⁴C]methionine, methionine-requiring mutants did not incorporate radioactivity into the pyrimidine moiety. 4. In contrast, both [1-¹⁴C]glycine and [2-¹⁴C]glycine were incorporated into the pyrimidine moiety excreted by glycine-requiring mutants, and this occurred with little or no dilution of specific radioactivity. 5. The possible requirement for methionine as a cofactor and the significance of the incorporation of both carbon atoms of glycine are discussed.     

The metabolism and excretion of methylglucamine (N-methyl-D-glucamine) in the rat

Methylglucamine is a commonly used cation in radiocontrast media. The present study sheds light on its fate in the rat. When administered intraperitoneally, 93% of the compound was excreted unchanged in the urine in 24 hr. When administered orally, about 15% of the dose was found in the urine, about 40% in the faeces and 20% in expired air in 24 hr. When administered orally to rats whose gut flora had been depleted by treatment with neomycin sulphate, 19% was excreted in the urine, 69% in the faeces and 3% in expired air in 72 hr. This indicated that the gut flora played a role in the degradation of the compound and its eventual loss as expired carbon dioxide.     

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.     

The metabolism and disposition of 3-methylindole in goats

The metabolism and disposition of 3-methylindole (3MI), a ruminal metabolite of L-tryptophan which causes acute pulmonary edema and emphysema (APE) when administered to cattle, goats, and sheep was investigated. Goats given jugular infusions of [¹⁴C] 3MI excreted 87 to 92% of the infused radioactivity in the urine, 0.4 to 0.9% in expired air, and negligible amounts in the feces over a period of three days. Composite urine samples were fractionated into 10 peaks by ion exchange chromatography, which represented 80% of the urinary radioactivity. A major route of metabolism involved formation of 3-methyloxindole and suggests that a mixed function oxidase (MFO), pyrrolooxygenase, may be the major metabolic system involved. A minor route of metabolism involved oxidation of the methyl carbon of 3MI.     

Isolation of Trilobatin,a Sweet Dihydrochalcone-Glucoside from Leaves of Vitis piasezkii Maxim. and V. saccharifera Makino

The effect of melanoidin, prepared with a D-glucose and glycine system, on cholesterol metabolism in rats was examined. Male rats of the Wistar strain weighing ca. 140 g were fed a high-cholesterol diet supplemented with nondialyzable melanoidin for three weeks. The dietary melanoidin suppressed elevation of the cholesterol level in both plasma and liver, while the cholesterol levels in feces and the contents of the caecum decreased unexpectedly. Neutral steroids other than cholesterol also decreased. However, chromatograhy of fecal steroids indicated that melanoidin markedly affected the intestinal metabolism of neutral steroids, including cholesterol. On the other hand, the fecal recovery of radioactivity from orally ingested 26 [27]-¹⁴C cholesterol was promoted by the added melanoidin, although the radioactive species were not identified. This suggested that the cholesterol level decreased due to the interference of melanoidin in the intestinal absorption of cholesterol.     

Metabolism of Isoxathion,O, O-Diethyl O-(5-Phenyl-3-isoxazolyl) phosphorothioate in the Rats

Excretion, distribution and metabolism of the insecticide, Isoxathion, administered orally in male Wistar-strain rats, were investigated with a carbon-14 labeled chemical. During 96 hr, approximately 85% and 14% of the total radioactivity were excreted in the urine and feces. Distribution of isoxathion after oral administration in the rats was investigated by means of whole-body autoradiographic technique and measurement of radioactivity in the tissues. At least eleven radioactive metabolites were detected, four of which were structurally determined. They were 3-hydroxy-5-phenylisoxazole, 3-(β-d-glucopyranuronosyloxy)-5-phenylisoxazole, 5-phenyl-3-isoxazolyl sulfate and hippuric acid.     

Benzoic acid conjugation in tuatara

The excretion and metabolism of orally administered [¹⁴C]-labelled benzoic acid (100 mg/kg) was examined in the reptile Sphenedon punctatus (tuatara). The major excreted metabolite was chromatographically and electrophoretically identical with ornithuric acid. Conjugation with glycine or glucuronic acid was not detected. 7–21 percent of the dose was recovered from the urine and faeces, the bulk of the excreted radioactivity being eliminated in the first seven days. Free benzoic acid and conjugates were excreted in the first week but only conjugates could be detected in fauces collected at later intervals. These results are discussed in relation to the taxonomic position of tuatara.     

The effect of methionine on the metabolism of serine and glycine in vitamin B-12-deficient rats

The effect of methionine supplementation on glycine and serine metabolism was studied in vitamin B-12-deficient rats which received only 0.2% methionine in the diet. In the perfused liver, incorporation of the C-2 of glycine to the C-3 of serine was increased by addition of methionine to the perfusate. The oxidation of [1-¹⁴C]glycine to ¹⁴CO₂ was however depressed. Unlike methionine, glycine did not have any significant effect on the liver folate coenzyme distribution. Oxidation of [3-¹⁴C]serine to ¹⁴CO₂ both in vivo and in perfused liver was increased by methionine. A major portion of the C-3 radioactivity however was recovered in glucose. Data presented indicate that the rate of oxidation of [2-¹⁴C]histidine to ¹⁴CO₂ is more sensitive indicator of folate deficiency than the rate of oxidation of [3-¹⁴C] serine to ¹⁴CO₂ although both are presumably tetrahydrofolate dependent.     

Metabolism of oral cephalothin and related cephalosporins in the rat

The fate of orally administered [¹⁴C]cephalothin has been studied in the rat. This antibiotic undergoes degradation in the gut followed by the subsequent absorption of a portion of the degradation products. About 50% of the administered radioactivity appears in the urine as a mixture of thienylacetylglycine, thienylacetamidoethanol and an unidentified polar metabolite. Evidence is presented indicating that thienylacetamidoethanol arises by the enzymic reduction of a metabolic intermediate, thienylacetamidoacetaldehyde. The metabolic fate of cephalothin is very similar to that of cephaloram reported earlier. The fate of [¹⁴C]cephaloridine and 7-phenoxy[1-¹⁴C]acetamidocephalosporin was also investigated. In addition to the expected metabolites, about 5% of the cephaloridine dose is absorbed unchanged. With 7-phenoxy[1-¹⁴C]acetamidocephalosporin, 15% of the dose is recovered in urine as deacetyl-7-phenoxy[1-¹⁴C]acetamidocephalosporin.     

Excretion of estrone,estradiol, and progesterone in the urine and feces of the female cotton-top tamarin (Saguinus oedipus oedipus)

The excretion of three gonadal steroids was studied in the urine and feces of female cotton-top tamarins (Saguinus oedipus oedipus). Each steroid, ¹⁴C-estrone, ¹⁴C-estradiol, and ¹⁴C-progesterone, was injected into a separate female cotton-top tamarin. Urine and feces were collected at 8 hr intervals for 5 days on the three tamarins. Samples were analyzed to determine the proportion of free and conjugated steroids. Steroid excretion patterns were determined by sequential ether extraction, enzyme hydrolysis, and chromatography. Labeled estrone was excreted in a slow and continuous manner into the urine (57%) and feces (43%) with 90% of the steroid conjugated. The nonconjugated form had an elution profile identical to ³H estrone, but the conjugated portion was not completely hydrolyzed by enzyme. Labeled estradiol was excreted primarily in the urine (87%) and was released rapidly. Over 90% of the injected ¹⁴C-estradiol was excreted in urine as a conjugate, of which 41% was converted to an estrone conjugate and the remaining 59% was excreted as a polar estradiol conjugate. Labeled progesterone was excreted primarily in the feces (95%), 61% of which was free steroid. Four to six individual peaks of radioactivity were found when using celite chromatography and high performance liquid chromatography (HPLC), indicating that progesterone is metabolized into several urinary and fecal metabolites. One of these peaks matched ³H-progesterone and others may be pregnanediols, pregnanetriols, and 17-hydroxyprogesterone. These steroidal excretion patterns help explain the atypical hormonal patterns seen during the tamarin ovarian cycle.     

The metabolism of dl-(1,6-14C)lipoic acid in the rat

dl-[1,6-¹⁴C]Lipoic acid was synthesized and administered to rats or incubated in vitro with rat liver systems. The urinary excretion of radioactivity after labeled lipoate was administered intraperitoneally at a level of 0.5 mg/100 g body weight was maximal at 3–6 hr, with 60% of the injected radioactivity recovered within 24 hr. Respiratory ¹⁴CO₂ from the same animals is maximal at 3 hr, after which it falls off markedly. Approximately 30% of the injected radioactivity was recovered as ¹⁴CO₂ within 24 hr. The excretion of radioactivity after lipoate was administered by stomach tube was similar to that after intraperitoneal injection. Localization of radioactivity in the body was greatest in liver, intestinal contents, and muscle in all cases. Ionexchange and paper chromatographies of 24-hr pooled urine revealed several watersoluble radioactive metabolites. Incubation of [¹⁴C]lipoate with homogenates or mitochondrial preparations in vitro resulted in the production of ¹⁴CO₂, which was decreased by incubation with unlabeled fatty acids and unaffected by the addition of carnitine or (+)-decanoylcarnitine. The rat, like certain bacteria, metabolizes lipoate via β-oxidation of the valeric acid side chain and by other metabolic reactions on the dithiolane ring, which render the molecule more water soluble.     

The metabolism of [2-14C]indole in the rat

1. [2-¹⁴C]Indole has been synthesized from [¹⁴C]formate and o-toluidine via N[¹⁴C]-formyltoluidine. 2. When fed to rats, the ¹⁴C of [¹⁴C]indole (dose 70–80mg./kg. body wt.) is fairly rapidly excreted, and in 2 days an average of 81% appears in the urine, 11% in the faeces and 2·4% as carbon dioxide in the expired air. 3. Radioactivity is excreted in the urine as indoxyl sulphate (50% of the dose), indoxyl glucuronide (11%), oxindole (1·4%), isatin (5·8%), 5-hydroxyoxindole conjugates (3·1%), N-formylanthranilic acid (0·5%) and unchanged indole (0·07%). The faeces contain indoxyl sulphate (0·4% of the dose) and indole (0·2%), but the major metabolites have not been identified. 4. Fed to rats with biliary cannulae an average of 5·6% of a dose of [¹⁴C]indole (20–60mg./kg. body wt.) is excreted in the bile in 2 days. Radioactivity is present as indoxyl sulphate (0·8% dose) and 5-hydroxyoxindole conjugates (0·6%). 5. Rats further metabolize indoxyl into N-formylanthranilic acid and anthranilic acid, and oxindole into 5-hydroxyoxindole. 6. With rat-liver microsomes plus supernatant under aerobic conditions, indole gives indoxyl, oxindole, possibly isatin, N-formylanthranilic acid and anthranilic acid, but under anaerobic conditions gives only oxindole. Similarly, under aerobic conditions, oxindole gives 5-hydroxyoxindole, anthranilic acid and o-aminophenylacetic acid. 7. Indole is metabolized by two pathways, one via indoxyl to isatin, N-formylanthranilic acid and anthranilic acid, and the other via oxindole to 5-hydroxyoxindole and possibly to o-aminophenylacetic and anthranilic acid. 8. The following new compounds are described: 4-hydroxy-2-nitrophenylacetic acid, 3-, 4- and 5-benzyloxy-2-nitrophenylacetic acid, 5- and 7-hydroxyoxindole and 5-aminoacridine indoxyl sulphate.     

The tissue distribution and the pattern of excretion of [14C]-13-labeled 12, 13-epoxytrichothec-9-ene in mice and rats

The distribution in the mouse tissues of 13-[14C]-12,13-epoxtrichothec-9-ene administered intravenously was determined by whole-body autoradiography and by tracing the radioactivity of the tissues oxidized in an Auto Sample Oxidizer. The appearance of the label in urine and feces was also followed by the tracer technique. The distributions of radioactivity in tissues as determined by the two methods were almost identical. On the autoradiograms of mice killed 10 min after the injection, marked blackening of the film was observed at the sites corresponding to the liver, kidney, and bladder with urine, and much less darkening at other sites. The radioactivities contained in the liver, kidney, urine and small intestine were 13.3, 2.3, 2.6 and 10.2% of the dose, respectively. The labeled toxin was rapidly excreted into urine and feces, 56.0 and 4.9% in 6 hr and 66.7 and 28.0% in 24 hr after injection, respectively. Oral administration of the labeled toxin to mother mice resulted in the appearance of radioactivity in the stomach contents of 7-day suckling mice, thus demonstrating indirectly the secretion of the toxin into the milk. An attempt to show a respiratory route of excretion in rats given the radioactive compound orally or intravenously failed to detect any radioactivity in the expired CO2 collected for 6 hr, suggesting that the 14C in the epoxy ring was intact.