The pathways of oxalate formation from phenylalanine,tyrosine, tryptophan and ascorbic acid in the rat

The metabolic pathway by which L-[¹⁴C₁]phenylalanine, L-[¹⁴C₁]tyrosine, L-[¹⁴C₁]tryptophan, and L-[¹⁴C₁]ascorbic acid are converted to [¹⁴C]oxalate have been investigated in the male rate. Only [¹⁴C]oxalate was detected in the urine of rats injected with L-[¹⁴C₁]ascorbic acid, but [¹⁴C]-labeled oxalate, glycolate, glyoxylate, glycolaldehyde, glycine, and serine were recovered from the [¹⁴C₁]-labeled aromatic amino acids. DL-Phenyllactate, an inhibitor of glycolic acid oxidase and glycolic acid dehydrogenase, reduced the amount of [¹⁴C]oxalate recovered in the urine of rats given the [¹⁴C₁]-labeled aromatic amino acids, but increased the amount of [¹⁴C]glycolate formed from L-[¹⁴C₁]-phenylalanine and L-[¹⁴C₁]tyrosine and the amount of [¹⁴C]glycolate produced from [¹⁴C₁]tryptophan. Based on the [¹⁴C]labeled intermediates identified and the relative distribution of the radioactivity, it is postulated that phenylalanine and tyrosine are converted to oxalate via glycolate which is oxidized directly to oxalate by glycolic acid dehydrogenase. Tryptophan is metabolized via glyxylate which is oxidized directly to oxalate by glycolic acid oxidase. Neither glycolate, glyoxylate, glycolic acid oxidase or glycolic acid dehydrogenase are involved in the formation of oxalate from ascorbic acid.     

Oxalic acid metabolism and calcium oxalate formation in Lemna minor L.

Abstract Axenic Lemna minor plants, which form numerous calcium oxalate crystals, were exposed to [¹⁴C]-glycolic acid, -glyoxylic acid, -oxalic acid and -ascorbic acid and prepared for microautoradiography by a technique that preserves only insoluble label to determine specifically the pathway leading to oxalic acid used for crystal formation. Label from glycolic, glyoxylic, and oxalic acids was incorporated into crystals. Label from oxalic acid was also found in starch when exposure to label was done in the light but not dark, while plastids specialized for lipid storage were heavily labelled under both conditions. Incorporation of label from glycolic and glyoxylic acids, but not oxalic acid, was inhibited in the presence of the glycolate oxidase inhibitors, αHPMS (2-pyridylhydroxy methanesulphonic acid) and mHBA (methyl 2-hydroxy-3-butynoic acid), and inhibition of labelling was not due to an effect on uptake. These studies show that the glycolate oxidase pathway to oxalic acid is operational in L. minor and that the product is available for crystal formation. Dark-grown plants form almost four times as many crystal cells (idioblasts) as do light-grown plants, indicating crystal formation is not in response to photorespiratory glycolate production. Label from [1-¹⁴C]ascorbic acid was also incorporated into crystals and labelling was inhibited by mHBA, indicating glycolic acid and/or glyoxylic acid are possible intermediates of ascorbic acid catabolism. The effect of nitrogen source on crystal formation was also investigated. Significantly more crystal idioblasts were formed, on a surface area basis, by plants grown on ammonium than by plants grown on nitrate nitrogen. When grown with mixed ammonium and nitrate, an intermediate number of crystal idioblasts were formed.     

pH Dependence and Kinetics of Glycolate Uptake by Intact Pea Chloroplasts

Experiments in which [1-¹⁴C]glycolate uptake is carried out in conjunction with measurements of stromal pH indicate that only glycolic acid and not the glycolate anion is crossing the pea (Pisum sativum var. Progress No. 9, Agway) chloroplast envelope. This mechanism of glycolate transport appears to be too slow to account for observed photorespiratory carbon fluxes in C₃ plants.     

Fixation of O(2) during Photorespiration: Kinetic and Steady-State Studies of the Photorespiratory Carbon Oxidation Cycle with Intact Leaves and Isolated Chloroplasts of C(3) Plants

Mass spectrometric techniques were used to trace the incorporation of [¹⁸O]oxygen into metabolites of the photorespiratory pathway. Glycolate, glycine, and serine extracted from leaves of the C₃ plants, Spinacia oleracea L., Atriplex hastata, and Helianthus annuus which had been exposed to [¹⁸O]oxygen at the CO₂ compensation point were heavily labeled with ¹⁸O. In each case one, and only one of the carboxyl oxygens was labeled. The abundance of ¹⁸O in this oxygen of glycolate reached 50 to 70% of that of the oxygen provided after only 5 to 10 seconds exposure to [¹⁸O]oxygen. Glycine and serine attained the same final enrichment after 40 and 180 seconds, respectively. This confirms that glycine and serine are synthesized from glycolate.

The labeling of photorespiratory intermediates in intact leaves reached a mean of 59% of that of the oxygen provided in the feedings. This indicates that at least 59% of the glycolate photorespired is synthesized with the fixation of molecular oxygen. This estimate is certainly conservative owing to the dilution of labeled oxygen at the site of glycolate synthesis by photosynthetic oxygen. We examined the yield of ¹⁸O in glycolate synthesized in vitro by isolated intact spinach chloroplasts in a system which permitted direct sampling of the isotopic composition of the oxygen at the site of synthesis. The isotopic enrichment of glycolate from such experiments was 90 to 95% of that of the oxygen present during the incubation.

The carboxyl oxygens of 3-phosphoglycerate also became labeled with ¹⁸O in 20- and 40-minute feedings with [¹⁸O]oxygen to intact leaves at the CO₂ compensation point. Control experiments indicated that this label was probably due to direct synthesis of 3-phosphoglycerate from glycolate during photorespiration. The mean enrichment of 3-phosphoglycerate was 14 ± 4% of that of glycine or serine, its precursors of the photorespiratory pathway, in 10 separate feeding experiments. It is argued that this constant dilution of label indicates a constant stoichiometric balance between photorespiratory and photosynthetic sources of 3-phosphoglycerate at the CO₂ compensation point.

Oxygen uptake sufficient to account for about half of the rate of ¹⁸O fixation into glycine in the intact leaves was observed with intact spinach chloroplasts. Oxygen uptake and production by intact leaves at the CO₂ compensation point indicate about 1.9 oxygen exchanged per glycolate photorespired. The fixation of molecular oxygen into glycolate plus the peroxisomal oxidation of glycolate to glyoxylate and the mitochondrial conversion of glycine to serine can account for up to 1.75 oxygen taken up per glycolate.

These studies provide new evidence which supports the current formulation of the pathway of photorespiration and its relation to photosynthetic metabolism. The experiments described also suggest new approaches using stable isotope techniques to study the rate of photorespiration and the balance between photorespiration and photosynthesis in vivo.

     

Synthesis of Glycolate from Pyruvate via Isocitrate Lyase by Tobacco Leaves in Light

Tobacco (Nicotiana tabacum var Havana Seed) leaf discs were supplied tracer quantities of [2-¹⁴C]- and [3-¹⁴C]pyruvate for 60 minutes in steady state photosynthesis with 21% or 1% O₂, and the glycolate oxidase inhibitor α-hydroxy-2-pyridinemethanesulfonic acid was then added for 5 or 10 minutes to cause glycolate to accumulate. The [3-¹⁴C]pyruvate was converted directly to glycolate as shown by a 50% greater than equallabeled ¹⁴C in C-2 of glycolate, and the fraction of ¹⁴C in C-2 increased in 1% O₂ to 80% greater than equal-labeled. This suggests the pathway using pyruvate is less O₂-dependent than the oxygenase reaction producing glycolate from the Calvin cycle. The formation of glycolate from pyruvate in the leaf discs was time-dependent and with [2-¹⁴C]- and [3-¹⁴C]pyruvate supplied leaf discs the C-2 of glyoxylate derived from C-2 of isocitrate was labeled asymmetrically in a manner similar to the asymmetrical labeling of C-2 of glycolate under a number of conditions. Thus glycolate was probably formed by the reduction of glyoxylate. Isocitric lyase activity of tobacco leaves was associated with leaf mitochondria, though most of the activity was in the supernatant fraction after differential centrifugation of leaf homogenates. The total enzyme activity was at least 35 micromoles per gram fresh weight per hour. The relative contribution of the pathway to the glycolate pool is unknown, but the results support the existence of a sequence of reactions leading to glycolate synthesis during photosynthesis with pyruvate, isocitrate, and glyoxylate as intermediates.     

Synthesis of regiospecifically labeled [18O]glycolic acid and [18O]acyldihydroxyacetone phosphate

Methods are detailed for the preparation of [2-18O]glycolate from chloroacetic acid and for the direct conversion of these intermediates to regiospecifically labeled [2-18O]-2-O-acylglycolic acids containing approximately 90% 18O at the C-O-acyl bond. Methods are also detailed for optimization of reaction conditions and yields for each synthetic step in previously published methods for the preparation of 1-O-acyldihydroxyacetone-3-O-phosphate (DHAP) from acyloxyacetic acid (i.e., 2-O-acylglycolic acid), where acyl is tetradecanoyl, hexadecanoyl, or heptadecanoyl. The optimized reaction conditions generate 1-O-acyl DHAP in its acid form, both in high overall yield and in high purity, without requiring a final chromatographic purification of the product, 1-O-acyl DHAP. Combining these new methods, efficient and facile preparations of regiospecifically labeled [1-18O]-1-O-hexadecanoyl DHAP and [1-18O]-1-O-heptadecanoyl DHAP have now been demonstrated, in which approximately 90% 18O is specifically located only at the C-O-acyl position. Some mechanistic postulates are offered to account for the optimized yields, regioselectivities, and high 18O incorporation which are observed in the reactions we have employed to generate 1-O-acyl DHAP from glycolate intermediates.     

Glycolate Metabolism in Thallassiosira pseudonana

The kinetics and nature of glycolate uptake by the marine diatomThallassiosira pseudoncma were examined both in the light anddark. After a 2 h incubation with [1-₁₄C]lglycolate in the light,the major part of the radioactive label taken up was locatedin the protein fraction of the cells. The metabolic inhibitorsisonicotinic acid hydrazide (INH) and a-hydroxypyridyl methanesulphonate(-HPMS) reduced the total assimilation of 14C from [1-₁₄C]glycolateand reduced the percentage of radioactivity found in the proteinfraction. Short-term kinetic experiments showed that [1-₁₄C]lglycolatewas accumulated in the cells unchanged and after 30 s the glycolatepathway intermediates glycine and serine became labelled. After4 min serine was the dominant compound labelled, with smallquantities of labelled glycine also present. The enzyme glycolate:DCPIP oxidoreductase was shown to be present in high enoughconcentrations to account for the observed glycolate assimilation.These results substantiate the existence of the glycolic acidpathway in Th. pseudonana.     

Enzymic formation of glycolate in Chromatium. Role of superoxide radical in a transketolase-type mechanism.

Chromatophores prepared from Chromatium exhibit a light-dependent O2 uptake in the presence of reduced 2,6-dichlorophenolindophenol, the maximum rate observed being 10.8 micronmol (mg of Bchl)-1 h-1 (air-saturated condition). As it was found that the uptake of O2 was markedly inhibited by superoxide dismutase, it is suggested that molecular oxygen is subject to light-dependent monovalent reduction, resulting in the formation of the superoxide anion radical (O2-). By coupling baker's yeast transketolase with illuminated chromatophore preparations, it was demonstrated that [U-14C]-fructose 6-phosphate (6-P) is oxidatively split to produce glycolate, and that the reaction was markedly inhibited by superoxide dismutase and less strongly by catalase. A coupled system containing yeast transketolase and xanthine plus xanthine oxidase showed a similar oxidative formation of glycolate from [U-14C] fructose 6-P. It is thus suggested that photogenerated O2- serves as an oxidant in the transketolase-catalyzed formation of glycolate from the alpha, beta-dihydroxyethyl (C2) thiamine pyrophosphate complex, whereas H2O2 is not an efficient oxidant. The rate of glycolate formation in vitro utilizing O2- does not account for the in vivo rate of glycolate photosynthesis in Chromatium cells exposed to an O2 atmosphere (10 micronmol (mg of Bchl)-1 h-1). However, the enhancement of glycolate formation by the autoxidizable electron acceptor methyl viologen in Chromatium cells in O2, as well as the strong suppression by 1,2-dihydroxybenzene-3,5-disulfonic acid (Tiron), an O2- scavenger, suggest that O2- is involved in the light-dependent formation of glycolate in vivo.     

产乙醇酸氧化酶的重组毕赤酵母的构建及催化合成乙醛酸的研究

乙醇酸氧化酶（Go）是植物光呼吸途径中的一种关键酶,可以催化乙醇酸生产乙醛酸。从新鲜菠菜叶中提取总RNA,利用RT-PCR技术获得编码GO基因的cDNA片断。通过基因重组将GO基因克隆到载体pA0815中,构建了胞内表达载体pA0815／GO,重组质粒经电转整合至甲醇营养酵母GS115染色体。在混合碳源为10g/L山梨醇和0．5g/L甲醇的培养条件下,细胞的GO酶活达到474IU／g（DCW）。利用该重组毕赤酵母作为催化剂生产乙醛酸,结果表明：在乙醇酸浓度为0．25mol／L,重组酵母湿菌体为10dL,黄素单核苷酸（FMN）浓度为0．01mmol／L,pH8．0,20℃,反应18h后乙醛酸的产率达到51．8％。     

13C NMR investigation of the anomeric specificity of CMP-N-acetylneuraminic acid synthetase from Escherichia coli.

The anomeric specificity of Escherichia coli CMP-N-acetylneuraminic acid (CMP-NeuAc) synthetase was investigated by NMR using 13C-labeled N-acetylneuraminic acid (NeuAc). Consumption of the beta-anomer of [2-13C]N-acetylneuraminic acid was observed upon addition of enzyme, with a concomitant appearance of an anomeric resonance for CMP-N-acetylneuraminic acid. Inhibition by substrate analogues the anomeric oxygen was determined in a similar manner using [2-13C,(50 atom %)18O]N-acetylneuraminic acid. An upfield shift of 1.5 Hz in the anomeric resonance of both the [13C]NeuAc substrate and CMP-[13C]NeuAc product was observed due to the 18O substitution. This result implies conservation of the NeuAc oxygen. Results of steady-state kinetic analysis suggest a sequential-type mechanism and therefore no covalent intermediate. Thus, CMP-beta-NeuAc is probably formed by a direct transfer of the anomeric oxygen of beta-NeuAc to the alpha-phosphate of CTP.     

Metabolism of [13C5]hydroxyproline in vitro and in vivo: implications for primary hyperoxaluria

Hydroxyproline (Hyp) metabolism is a key source of glyoxylate production in the body and may be a major contributor to excessive oxalate production in the primary hyperoxalurias where glyoxylate metabolism is impaired. Important gaps in our knowledge include identification of the tissues with the capacity to degrade Hyp and the development of model systems to study this metabolism and how to suppress it. The expression of mRNA for enzymes in the pathway was examined in 15 different human tissues. Expression of the complete pathway was identified in liver, kidney, pancreas, and small intestine. HepG2 cells also expressed these mRNAs and enzymes and were shown to metabolize Hyp in the culture medium to glycolate, glycine, and oxalate. [(18)O]- and [(13)C(5)]Hyp were synthesized and evaluated for their use with in vitro and in vivo models. [(18)O]Hyp was not suitable because of an apparent tautomerism of [(18)O]glyoxylate between enol and hydrated forms, which resulted in a loss of isotope. [(13)C(5)]Hyp, however, was metabolized to [(13)C(2)]glycolate, [(13)C(2)]glycine, and [(13)C(2)]oxalate in vitro in HepG2 cells and in vivo in mice infused with [(13)C(5)]Hyp. These model systems should be valuable tools for exploring various aspects of Hyp metabolism and will be useful in determining whether blocking Hyp catabolism is an effective therapy in the treatment of primary hyperoxaluria.     

Photorespiration stoichiometry in leaves estimated by combined physical and stereochemical methods: allowance for isomerase-catalyzed 3H losses in ribulose bisphosphate regeneration

We showed previously [K.R. Hanson and R.B. Peterson (1986) Arch. Biochem. Biophys. 246, 332-346] that under steady-state photosynthetic conditions the fraction of ribulose bisphosphate oxidized and the fraction of glycolate carbon photorespired (the stoichiometry of photorespiration) may be estimated in leaves by a combination of physical and stereochemical methods. The calculations assumed that when (3R)-D-[3-3H1,3-14C]glyceric acid is supplied to illuminated leaf discs the only loss of 3H from the combined photosynthetic and photorespiratory system is the result of glycolate oxidase action; i.e., the isomerase-catalyzed losses in the regeneration of ribulose bisphosphate are negligible. The present study of tobacco leaf discs under zero-photorespiration conditions (low O2 and high CO2 concentrations), and also of maize leaf discs, shows that some 3H losses occur (between 8 and 13% of the 3H at C-1 of ribulose 5-phosphate). The calculated loss varied moderately with temperature but did not vary when the flux of ribulose bisphosphate formation was altered by changing the irradiance. The calculated loss under zero-photorespiration conditions, therefore, may be used to calculate ribulose bisphosphate and glycolate partitioning under other conditions. Earlier experiments on the influence of O2 and CO2 concentrations of temperature on the partitioning of ribulose bisphosphate and glycolate have been reexamined. The loss corrections decreased all values for the fraction of ribulose bisphosphate oxidized and increased all values for the stoichiometry of photorespiration. Essentially all stoichiometry values were above the theoretical lower limit of 25%. The previous conclusion that the stoichiometry of photorespiration substantially exceeds 25% at higher O2 concentrations and higher temperatures is unchanged. The results with maize leaf discs implied that there is very little oxidation of ribulose 1,5-bisphosphate under normal-air conditions; i.e., photorespiration is indeed suppressed, not merely hidden, by efficient refixation of CO2.     

Stereochemical determination of carbon partitioning between photosynthesis and photorespiration in C3 plants: use of (3R)-D-[3-3H1, 3-14C]glyceric acid

When (3R)-D-[3-3H1,3-14C]glyceric acid is supplied in tracer amounts to illuminated tobacco leaf discs, the acid penetrates to the chloroplasts without loss of 3H, and is phosphorylated there. Subsequent metabolism associated with the reductive photosynthetic cycle fully conserves 3H. Oxidation of ribulose bisphosphate (RuBP) by RuBP carboxylase-oxygenase (EC 4.1.1.39) results in the formation of (2R)-[2-3H1, 14C]glycolic acid which, on oxidation by glycolate oxidase (EC 1.1.3.1), releases 3H to water. Loss of 3H from the combined photosynthetic and photorespiratory systems is, therefore, associated with the oxidative photorespiratory loop. Assuming steady-state conditions and a basic metabolic model, the fraction of RuBP oxidized and the photorespiratory carbon flux relative to gross or net CO2 fixation can be calculated from the fraction of supplied 3H retained in the triose phosphates exported from the chloroplasts. This retention can be determined from the 3H:14C ratio for glucose obtained from isolated sucrose. The dependence of 3H retention upon O2 and CO2 concentrations can be deduced by assuming simple competitive kinetics for RuBP carboxylase-oxygenase. The experimental results confirmed the stereochemical assumptions made. Under conditions of negligible photorespiration 3H retention was essentially complete. The change in 3H retention with O2 and CO2 concentrations were investigated. For leaf discs (upper surface up) in normal air, it was estimated that 39% of the RuBP was oxidized, 32% of the fixed CO2 was photorespired, and the photorespiration rate was 46% of the net photosynthetic CO2 fixation rate. These are minimal estimates, as it is assumed that the only source of photorespired CO2 is glycine decarboxylation.     

不同因子对荞麦中草酸含量的影响

用不同化合物从根部喂养麦幼苗,测定其根叶中草酸含量的变化。结果表明：异柠檬酸、抗坏血酸及其前体物均可不同程度地降低荞麦根叶中草酸含量;而乙醇酸与乙醛酸则显著提高其草酸含量,表明荞麦叶片草酸合成主要来自乙醇酸途径,而非来自抗坏血酸等途径。水培条件下,以铵态氮或尿素等作唯一氮源时,荞麦中草酸含量远低于以硝态氮培养的;将谷氨酸或丝氨酸加到含硝态氮培养液中也能显著降低其草酸含量,不同氮素影响荞麦草酸含量可能与乙醇酸途径有关。     

Carbon-Isotope Composition of Biochemical Fractions and the Regulation of Carbon Balance in Leaves of the C3-Crassulacean Acid Metabolism Intermediate Clusia minor L. Growing in Trinidad

Carbon-isotope ratios ([delta]13Cs) were measured for various bio-chemical fractions quantitatively extracted from naturally exposed and shaded leaves of the C3-Crassulacean acid metabolism (CAM) intermediate Clusia minor, sampled at dawn and dusk on days during the wet and dry seasons in Trinidad. As the activity of CAM increased in response to decreased availability of water and higher photon flux density, organic acids and soluble sugars were enriched in 13C by approximately 3.5 to 4%[per mille (thousand) sign] compared to plants sampled during the wet season. The induction of CAM was accompanied by a doubling in size of the reserve carbohydrate pools. Moreover, stoichiometric measurements indicated that degradation of both chloroplastic reserves and soluble sugars were necessary to supply phosphoenolpyruvate for the synthesis of organic acids at night. Results also suggest that two pools of soluble sugars exist in leaves of C. minor that perform CAM, one a vacuolar pool enriched in 13C and the second a transport pool depleted in 13C. Estimates of carbon-isotope discrimination expressed during CAM, derived from the trafficking among inorganic carbon, organic acids, and carbohydrate pools overnight, ranged from 0.9 to 3.1%[per mille (thousand) sign]. The [delta]13C of structural material did not change significantly between wet and dry seasons, indicating that most of the carbon used in growth was derived from C3 carboxylation.     

High glycolate oxidase activity is required for survival of maize in normal air

A mutant in the maize (Zea mays) Glycolate Oxidase1 (GO1) gene was characterized to investigate the role of photorespiration in C4 photosynthesis. An Activator-induced allele of GO1 conditioned a seedling lethal phenotype when homozygous and had 5% to 10% of wild-type GO activity. Growth of seedlings in high CO2 (1%-5%) was sufficient to rescue the mutant phenotype. Upon transfer to normal air, the go1 mutant became necrotic within 7 d and plants died within 15 d. Providing [1-14C]glycolate to leaf tissue of go1 mutants in darkness confirmed that the substrate is inefficiently converted to 14CO2, but both wild-type and GO-deficient mutant seedlings metabolized [1-14C]glycine similarly to produce [14C]serine and 14CO2 in a 1:1 ratio, suggesting that the photorespiratory pathway is otherwise normal in the mutant. The net CO2 assimilation rate in wild-type leaves was only slightly inhibited in 50% O2 in high light but decreased rapidly and linearly with time in leaves with low GO. When go1 mutants were shifted from high CO2 to air in light, they accumulated glycolate linearly for 6 h to levels 7-fold higher than wild type and 11-fold higher after 25 h. These studies show that C4 photosynthesis in maize is dependent on photorespiration throughout seedling development and support the view that the carbon oxidation pathway evolved to prevent accumulation of toxic glycolate.     

Chemical synthesis of 1-O-alkyl and 1-O-acyl dihydroxyacetone-3-phosphate

A method for the chemical synthesis of 1-O-hexadecyl dihydroxyacetone-3-phosphate is described. The synthesis was started with the preparation of O-hexadecyl glycolic acid by condensing 1-iodohexadecane with ethyl glycolate in the presence of silver oxide, followed by saponification and free acid liberation with HC1. O-Hexadecyl glycolic acid was converted to the acid chloride (with oxalyl chloride) which was condensed with diazomethane in diethyl ether to form hexadecyloxy diazoacetone. The diazoketone was decomposed by H₃PO₄ in dioxane to give the desired product, 1-O-hexadecyl dihydroxyacetone-3-phosphate. The product was purified by chromatography on silicic acid column followed by an acid wash. The final yield was 50% starting from O-hexadecyl glycolic acid. Analytical, spectral (IR, NMR) and chromatographic properties of 1-O-hexadecyl dihydroxyacetone-3-phosphate are described. The method described here may be used to prepare different acyl and alkyl derivatives of dihydroxyacetone phosphate in good yield as illustrated by describing the procedure for the synthesis of 1-O-palmitoyl dihydroxyacetone-3-phosphate, 1-O-hexadecyl dihydroxyacetone-3-[³²P] phosphate and the dimethyl ketal of 1-O-palmitoyl [2-¹⁴C]dihydroxyacetone phosphate.     

Metabolism of carbon tetrachloride to phosgene

Aerobic incubation of hepatic microsomal fractions in the presence of carbon tetrachloride, NADPH and cysteine resulted in the formation of phosgene which was identified by gas chromatography/mass spectrometry as the adduct, 2-oxothiazolidine-4-carboxylic acid, formed by its reaction with cysteine. [¹³C]-Carbon tetrachloride was metabolized to 2-[¹³C]-oxothiazolidine-4-carboxylic acid the , when carbon tetrachloride was incubated in the presence of [¹⁸O]-O₂, 2- [¹⁸O]-oxothiazolidine-4-carboxylic acid was formed. The reaction was inhibited by carbon monoxide showing the involvement of the cytochrome P-450-dependent mixed function oxidase system. The metabolism of carbon tetrachloride to phosgene may play a role in the production of hepatotoxicity by this compound.     

Determination of deoxycholic acid pool size and input rate using [24-13C]deoxycholic acid and serum sampling

We have developed an isotope dilution method for determination of deoxycholic acid pool size and input rate which employs oral administration of 50 mg of [24-13C]deoxycholic acid and serum sampling. The method has been validated by classical isotope dilution technique using [24-14C]deoxycholic acid and bile sampling in five patients with colonic adenomas. Excellent agreement between pool sizes and input rates determined with 13C/12C isotope ratio measurements in serum and 14C measurements in bile was obtained when isotope ratios were measured in the conjugated fraction of deoxycholic acid in serum. We conclude that pool size and input rate of deoxycholic acid can accurately be determined by blood sampling after oral administration of [24-13C]deoxycholic acid, therewith eliminating the use of radioactive tracers and the need for bile sampling.     

A radio-gas chromatographic method for determining the specific radioactivity of glycolic acid in -14C-labeled leaf tissue.

A method for the extraction and quantitative determination of both the mass and radioactivity of glycolic acid from -14C-labeled leaf tissue is described. The recoveries of both mass and radioactivity from standard [1-14C]glycolic acid solutions averaged 98 percent, and recovery of radioactivity added to plant samples as [1-14C]glycolic acid was over 90 percent after the complete procedure. The method was reliable with total samples containing as little as 130 nmol of glycolic acid. The mass of glycolic acid recovered from sunflower leaf tissue was proportional to the amount of tissue extracted. In experiments with different plant material, the amount of glycolic acid varied between 530 and 1120 nmol/dm-2 of leaf tissue. The specific radioactivity of the glycolic acid in sunflower leaf tissue during photosynthesis in -14CO(2) was never more than 20 percent of the specific radioactivity of the -14CO(2) supplied.