Metabolism of Monoterpenes: Demonstration of (+)-Neomenthyl-beta-d-Glucoside as a Major Metabolite of (-)-Menthone in Peppermint (Mentha Piperita)

(-)-Menthone, the major monoterpene component of the essential oil of maturing peppermint (Mentha piperita L.) leaves (6 micromoles per leaf) is rapidly metabolized at the onset of flowering with a concomitant rise in the level of (-)-menthol (to about 2 micromoles per leaf). Exogenous (-)-[G-(3)H]menthone is converted into (-)-[(3)H]menthol as the major steam-volatile product in leaf discs in flowering peppermint (10% of incorporated tracer); however, the major portion of the incorporated tracer (86%) resided in the nonvolatile metabolites of (-)-[G-(3)H]menthone. Acid hydrolysis of the nonvolatile material released over half of the radioactivity to the steamvolatile fraction, and the major component of this fraction was identified as (+)-neomenthol by radiochromatographic analysis and by synthesis of crystalline derivatives, thus suggesting the presence of a neomenthyl glycoside. Thin layer chromatography, ion exchange chromatography, and gel permeation chromatography on Bio-Gel P-2 allowed the purification of the putative neomenthyl glycoside, and these results suggested that the glycoside contained a single, neutral sugar residue. Hydrolysis of the purified glycoside, followed by reduction of the resulting sugar moiety with NaB(3)H(4), generated a single labeled product that was subsequently identified as glucitol by radio gas-liquid chromatography of both the hexatrimethylsilyl ether and hexaacetate derivative, and by crystallization to constant specific radioactivity of both the alditol and the corresponding hexabenzoate. These results, along with studies on the hydrolysis of the glycoside by specific glycosidases, strongly suggest that (+)-neomenthyl-beta-d-glucoside is a major metabolite of (-)-menthone in flowering peppermint. This is the first report on the occurrence of a neomenthyl glycoside, and the first evidence implicating glycosylation as an early step in monoterpene catabolism.     

Metabolism of Monoterpenes : EVIDENCE FOR COMPARTMENTATION OF l-MENTHONE METABOLISM IN PEPPERMINT (MENTHA PIPERITA) LEAVES

Previous studies have shown that the monoterpene ketone l-[G-(3)H]-menthone is reduced to the epimeric alcohols l-menthol and d-neomenthol in leaf discs of flowering peppermint (Mentha piperita L.), and that a portion of the menthol is converted to menthyl acetate while the bulk of the neomenthol is transformed to neomenthyl-beta-d-glucoside (Croteau, Martinkus 1979 Plant Physiol 64: 169-175). The metabolic disposition of the epimeric reduction products of the ketone, which is a major constituent of peppermint oil, is highly specific, in that little neomenthyl acetate and little menthyl glucoside are formed. However, when l-[3-(3)H]menthol and d-[3-(3)H]neomenthol are separately administered to leaf discs, both menthyl and neomenthyl acetates and menthyl and neomenthyl glucosides are formed with nearly equal facility, suggesting that the metabolic specificity observed with the ketone precursor was not a function of the specificity of the transglucosylase or transacetylase but rather a result of compartmentation of each stereospecific dehydrogenase with the appropriate transferase. A UDP-glucose:monoterpenol glucosyltransferse, which utilized d-neomenthol or l-menthol as glucose acceptor, was demonstrated in the 105,000g supernatant of a peppermint leaf homogenate, and the enzyme was partially purified and characterized. Co-purification of the acceptor-mediated activities, and differential activation and inhibition studies, provided strong evidence that the same UDP-glucose-dependent enzyme could transfer glucose to either l-menthol or d-neomenthol. Determination of K(m) and V for the epimeric monoterpenols provided nearly identical values. The acetylcoenzyme A:monoterpenol acetyltransferase previously isolated from peppermint extracts (Croteau, Hooper 1978 Plant Physiol 61: 737-742) was re-examined using l-[3-(3)H]menthol and d-[3-(3)H]neomenthol as acetyl acceptors, and the K(m) and V for both epimers were, again, very similar. These results demonstrate that the specific in vivo conversion of l-menthone to l-menthyl acetate and d-neomenthyl-beta-d-glucoside cannot be attributed to the selectivity of the transferases, and they clearly indicate that the metabolic specificity observed is a result of compartmentation effects.     

Distribution of aminoacyl-t-RNA-synthetase activity in rabbit liver cells during disruption of protein biosynthesis in experimental myocardia infarct

Distribution of the aminoacyl-tRNA synthetase activity has been studied in the normal rabbit liver cells and in the model of protein synthesis damage, i.e. under experimental myocardial infarction (EMI). The activity of a number of aminoacyl-tRNA synthetases in postmitochondrial and postribosomal extracts from rabbit liver homogenate has been determined to increase 12 h after EMI. Gel filtration of the postribosomal extract on Sepharose 6B shows that the activity of aminoacyl-tRNA synthetases is distributed among the fractions with Mr 1.82 x 10(6), 0.84 x 10(6) and 0.12 = 0.35 x 10(6). The first two fractions (high-molecular-weight aminoacyl-tRNA synthetase complexes) contain arginyl-, glutamyl-, isoleucyl-, leucyl-, lysyl- and valyl-tRNA synthetases, whereas the low-molecular-weight fraction contains alanyl-, arginyl-, glycyl-, phenylalanyl-, seryl-, threonyl-, tryptophanyl- and tyrosyl-tRNA synthetases. In a case of EMI all the aminoacyl-tRNA synthetases translocate from the complexes with Mr 1.82 x 10(6) into the complexes with Mr 0.84 x 10(6), what provided evidence for the possibility to regulate protein synthesis by changes in compartmentalization of aminoacyl-tRNA synthetases.     

Brown Fat AKT2 Is a Cold-Induced Kinase that Stimulates ChREBP-Mediated De Novo Lipogenesis to Optimize Fuel Storage and Thermogenesis

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Implications of the integrated rate law for the reactions of Paracoccus denitrificans nitrite reductase.

The integrated rate law for the reaction of the nitrite reductase of Paracoccus denitrificans, a cytochrome cd, has been established for turnover assays using donor ferrocytochromes c and either nitrite or molecular oxygen as the ultimate acceptor. The time course for the concentration of ferrocytochrome follows the law: formula: (see text), where S is the concentration of donor ferrocytochrome c, So is the initial concentration, t is time, and u1, u2, and u3 are empirical parameters that are constant for a given experiment but depend upon the initial substrate concentration. In particular, all the u1 increase with decreasing initial ferrocytochrome concentration. Saturation of reaction rates at high donor ferrocytochrome concentrations was not observed. The parameter u1 was proportional to the enzyme concentration while u2 and u3 were not. The form of the integrated rate law and the behavior of the u1 impose severe restrictions on possible kinetic schemes for the activity of the enzyme. Contemporary mechanisms that have been proposed for mitochondrial oxidase aa3 are examined and found to be inadequate to explain the reactivity of cytochrome cd. The simplest interpretations of the cytochrome cd data suggest that the enzyme does not bind the ferri and ferro forms of donor cytochromes c with equal affinity and that the enzyme is subject to inhibition by a product of reaction. Eucaryotic horse cytochrome c reacts with the Paracoccus cytochrome cd with 77% of the activity when Paracoccus cytochrome c550 is used as the electron donor.     

Isolation of Paracoccus denitrificans cytochrome cd1: comparative kinetics with other nitrite reductases

The dissimilatory nitrite reductase of the cytochrome cd₁ type was purified from Paracoccus denitrificans (ATCC 13543) by a novel procedure that avoided conventional ion-exchange techniques. The characterization of this enzyme was extended to include amino acid composition, extinction coefficients, and kinetic properties not previously reported. Cytochromes cd₁ from Alicaligenes faecalis and Pseudomonas aeruginosa were also isolated and assayed with electron donor proteins. The enzymes from all three sources were shown to obey the same integrated rate law. Cross-reactivities were measured in which a reduced donor protein from one strain was assayed with cytochrome cd₁ from another strain using nitrite as ultimate acceptor. Donors included c-type cytochromes and azurins. In general, the enzymes showed specificity for a donor from the same strain; interspecies cross-reactions were typically slower on the order of 10-fold than corresponding native rates. Notable exceptions were Paracoccus cytochrome cd₁, which alone reacted with eukaryotic horse cytochrome c at appreciable rates, and the Pseudomonas cd₁-Alcaligenesc554 reaction, which was 4-fold faster than the native Alcaligenes cd₁-Alcaligenesc554 reaction. For all three enzymes, competitive kinetics were measured in which the alternative substrates, nitrite and oxygen, competed for enzyme in the same assay. It was found that the competitive kinetics were dominated by nonenzymatic reactions involving an enzyme product, nitric oxide.     

Subcellular distribution and properties of rabbit liver aminoacyl-tRNA synthetases under myocardial ischemia

Subcellular distribution of aminoacyl-tRNA synthetase activities has been studied in normal rabbit liver and under experimental myocardial ischemia (EMI). An increase in the activity of a number of aminoacyl-tRNA synthetases in postmitochondrial and postribosomal supernatants from rabbit liver has been determined 12 hr after EMI. Gel chromatography of the postribosomal supernatant on Sepharose 6B shows that aminoacyl-tRNA synthetase activities are distributed among the fractions with M_r 1.82×10⁶, 0.84×10⁶ (high-M_r aminoacyl-tRNA synthetase complexes) and 0.12–0.35×10⁶. In the case of EMI aminoacyl-tRNA synthetase activities are partly redistributed from the 1.82×10⁶ complex into the 0.84×10⁶ complex. The catalytic properties of both free and complex leucyl-tRNA synthetases have been compared. K_M for all the substrates are the values of the same order in norm and under EMI. A decrease in some aminoacyl-tRNA synthetase activities associated with polyribosomes has been observed 12 hr after EMI. The interaction of aminoacyl-tRNA synthetases with polyribosomes stimulates the catalytic activity of some enzymes and protects them from heat inactivationin vitro. It is assumed that the changes in association of aminoacyl-tRNA synthetases with high-M_r complexes and compartmentalization of these enzymes on polyribosomes may be related to the alteration of protein biosynthesis under myocardial ischemia.     

Role of aminoacyl-tRNA-synthetases in changes in the rate of protein biosynthesis in the rabbit liver during myocardial ischemia

Composition of high-molecular-weight aminoacyl-tRNA synthetases complexes from rabbit liver both in norm and after 12 h experimental myocardial ischemia (EMI) has been investigated. Partial redistribution of aminoacyl-tRNA synthetases activity from 1820 kD complex into 840 kD complex was observed in case of EMI which resulted in changes of protein biosynthesis rate in cell-free system.     

Purification and properties of Paracoccus denitrificans azurin

The isolation of an azurin type Cu protein from Paracoccus denitrificans (ATCC 13543) is described and some properties are reported. The purified protein has a molecular weight of 13,790 in a single polypeptide chain and contains one Cu atom per molecule. Its spectrum is typical of Type I, “blue” Cu proteins in showing an intense band at 595 nm; but it also shows a weaker absorption band at 448 nm. Its standard reduction potential has been measured to be +230 mV, which is the lowest potential observed to date for azurins isolated from bacterial sources. The purified protein shows fivefold greater electron transport activity with membrane fragments than with the soluble nitrite reductase of Paracoccus. This argues against the latter as the primary physiological oxidase system for azurin.