Monoterpene double-bond reductases of the (-)-menthol biosynthetic pathway: isolation and characterization of cDNAs encoding (-)-isopiperitenone reductase and (+)-pulegone reductase of peppermint

Random sequencing of a peppermint essential oil gland secretory cell cDNA library revealed a large number of clones that specified redox-type enzymes. Full-length acquisitions of each type were screened by functional expression in Escherichia coli using a newly developed in situ assay. cDNA clones encoding the monoterpene double-bond reductases (-)-isopiperitenone reductase and (+)-pulegone reductase were isolated, representing two central steps in the biosynthesis of (-)-menthol, the principal component of peppermint essential oil, and the first reductase genes of terpenoid metabolism to be described. The (-)-isopiperitenone reductase cDNA has an open reading frame of 942 nucleotides that encodes a 314 residue protein with a calculated molecular weight of 34,409. The recombinant reductase has an optimum pH of 5.5, and K(m) values of 1.0 and 2.2 microM for (-)-isopiperitenone and NADPH, respectively, with k(cat) of 1.3s(-1) for the formation of the product (+)-cis-isopulegone. The (+)-pulegone reductase cDNA has an open reading frame of 1026 nucleotides and encodes a 342 residue protein with a calculated molecular weight of 37,914. This recombinant reductase catalyzes the reduction of the 4(8)-double bond of (+)-pulegone to produce both (-)-menthone and (+)-isomenthone in a 55:45 ratio, has an optimum pH of 5.0, and K(m) values of 2.3 and 6.9 microM for (+)-pulegone and NADPH, respectively, with k(cat) of 1.8s(-1). Deduced sequence comparison revealed that these two highly substrate specific double-bond reductases show less than 12% identity. (-)-Isopiperitenone reductase is a member of the short-chain dehydrogenase/reductase superfamily and (+)-pulegone reductase is a member of the medium-chain dehydrogenase/reductase superfamily, implying very different evolutionary origins in spite of the similarity in substrates utilized and reactions catalyzed.     

Effect of Mentha x piperita essential oil and monoterpenes on cucumber root membrane potential.

Peppermint (Mentha piperita L.) essential oil and its main components were assessed for their ability to interfere with plant plasma membrane potentials. Tests were conducted on root segments isolated from etiolated seedlings of cucumber (Cucumis sativus L.). Increasing the concentration of peppermint essential oil from 5 to 50 ppm caused a decrease in membrane potential (Vm) hyperpolarization of 10-3 mV, whereas concentrations from 100 up to 900 ppm caused an increasing depolarization of Vm (from 5 to 110 mV). When tested at 300 ppm, (+)-menthyl acetate, (-)-limonene and 1,8-cineole did not exert any significant effect on V(m), whereas (+)-menthofuran (73 mV), (+)-pulegone (85 mV), (+)-neomenthol (96 mV), (-)-menthol (105 mV) and (-)-menthone (111 mV) showed increased ability to depolarize V(m). A plot of log of octanol-water partition coefficient (K(ow)) against their depolarizing effect showed a significant negative correlation, suggesting that among all monoterpenoids increased membrane depolarization depends on lower K(ow). However, among monoterpene ketones, alcohols and furans, increased membrane depolarization is associated with a decline in water solubility. The possible effect of monoterpenoids on membrane ion fluxes is also discussed, since changes in the bioelectric potential of cells imply changes in the flux of ions across the plasma membrane     

Metabolism of monoterpenes: demonstration that (+)-cis-isopulegone, not piperitenone, is the key intermediate in the conversion of (-)-isopiperitenone to (+)-pulegone in peppermint (Mentha piperita)

Piperitenone is commonly considered to be the key intermediate in the conversion of (-)-isopiperitenone to (+)-pulegone in peppermint; however, [3H]piperitenone gave rise only to the inert metabolite (+)-piperitone when incubated with peppermint leaf discs. Under identical conditions, (-)-[3H]isopiperitenone was efficiently incorporated into (+)-pulegone, (-)-menthone, and (+)-isomenthone in leaf discs, and yielded an additional metabolite identified as (+)-cis-isopulegone; piperitenone was poorly labeled. Moreover, (+)-cis-[3H]isopulegone was rapidly converted to (+)-pulegone, (-)-menthone, and (+)-isomenthone in leaf discs, and the reduction of (+)-[3H]pulegone to (-)-menthone and (+)-isomenthone was similarly documented. Each step of the pathway was demonstrated in a crude soluble preparation from peppermint leaf epidermis and each of the relevant enzymes was partially purified in order to compare relative rates of catalysis. The results of these studies indicate that the endocyclic double bond of (-)-isopiperitenone is reduced to yield (+)-cis-isopulegone, which is isomerized to (+)-pulegone as the immediate precursor of (-)-menthone and (+)-isomenthone, and they rule out piperitenone as an intermediate of the pathway.     

Inhibition by menthol and its related chemicals of compound action potentials in frog sciatic nerves

AimsTransient receptor potential (TRP) vanilloid-1 (TRPV1) and melastatin-8 (TRPM8) channels play a role in transmitting sensory information in primary-afferent neurons. TRPV1 agonists at high concentrations inhibit action potential conduction in the neurons and thus have a local anesthetic effect. The purpose of the present study was to know whether TRPM8 agonist menthol at high concentrations has a similar action and if so whether there is a structure–activity relationship among menthol-related chemicals.Main methodsCompound action potentials (CAPs) were recorded from the frog sciatic nerve by using the air-gap method.Key findings(?)-Menthol and (+)-menthol concentration-dependently reduced CAP peak amplitude with the IC₅₀ values of 1.1 and 0.93 mM, respectively. This (?)-menthol activity was resistant to non-selective TRP antagonist ruthenium red; TRPM8 agonist icilin did not affect CAPs, indicating no involvements of TRPM8 channels. p-Menthane, (+)-limonene and menthyl chloride at 7–10 mM minimally affected CAPs. On the other hand, (?)-menthone, (+)-menthone, (?)-carvone, (+)-carvone and (?)-carveol (in each of which chemicals OH or O group was added to p-menthane and limonene) and (+)-pulegone inhibited CAPs with extents similar to that of menthol. 1,8-Cineole and 1,4-cineole were less effective while thymol and carvacrol were more effective than menthol in inhibiting CAPs.SignificanceMenthol-related chemicals inhibited CAPs and were thus suggested to exhibit local anesthetic effects comparable to those of lidocaine and cocaine as reported previously for frog CAPs. This result may provide information to develop local anesthetics on the basis of the chemical structure of menthol.     

Inhibition of mitochondrial succinate oxidation--similarities and differences between N-methylated beta-carbolines and MPP+.

N-Methylated beta-carbolinium compounds (N-Me-BCs), including 2-N-methyl and 2,9-N,N-dimethyl analogs, structural analogs of 1-methyl-4-phenylpyridinium (MPP+), may be endogenously bioactivated, MPP(+)-like toxins, capable of inducing parkinsonism. Both MPP+ and selected N-Me-BCs inhibit NADH-linked mitochondrial respiration (Complex I). We now show that both also inhibit succinate-supported (Complex II) respiration, the greatest inhibition (80%) being seen for 2,9-dimethylharmanium. Complex I inhibition occurs at MPP+ concentrations (IC50 = 0.17 mM) about one order of magnitude lower than Complex II inhibition (greater than 1.2 mM). In contrast, Complex I and Complex II inhibition by the N-Me-BCs tested occurred at similar concentrations (I, 0.1 mM; II, 0.25 mM) and concentrations similar to Complex I inhibition by MPP+. 2,9-N,N-Dimethyl-BCs, which are the permanently charged BC analogs of MPP+, show inhibitory characteristics similar to MPP+: slow onset of inhibition, potentiation by TPB, and reversal by DNP. The fact that succinate oxidation cannot bypass the Complex II inhibition by N-Me-BCs could enhance any chronic neurotoxicity of N-Me-BCs.     

Inhibition of lipid peroxidation by a novel compound (CV-2619) in brain mitochondria and mode of action of the inhibition

Lipid peroxidation in rat brain mitochondria was induced by NADH in the presence of ADP and FeCl3. CV-2619 inhibited the lipid peroxidation in a concentration-dependent manner; the concentration giving 50% inhibition (IC50) was 84 microM. In addition, the inhibitory effect of CV-2619 was strongly enhanced by adding substrates of mitochondrial respiration; when succinate, glutamate, or succinate plus glutamate was added, the IC50 of CV-2619 was changed to 1.1, 10, or 0.5 microM, respectively. Metabolites of CV-2619 also inhibited the lipid peroxidation. The inhibitory effect of CV-2619 on mitochondrial lipid peroxidation disappeared when TTFA, an inhibitor of complex II in mitochondrial respiratory chain, was added. The results indicate that in mitochondria CV-2619 is changed to its reduced form which inhibits lipid peroxidation.     

Inhibition of brain mitochondrial respiration by dopamine and its metabolites: implications for Parkinson's disease and catecholamine-associated diseases

A structure-potency study examining the ability of dopamine (DA), its major metabolites and related amine and acetate congeners to inhibit NADH-linked mitochondrial O(2) consumption was carried out to elucidate mechanisms by which DA could induce mitochondrial dysfunction. In the amine studies, DA was the most potent inhibitor of respiration (IC(50) 7.0 mm) compared with 3-methoxytryramine (3-MT, IC(50) 19.6 mm), 3,4-dimethoxyphenylethylamine (IC(50) 28.6 mm), tyramine (IC(50) 40.3 mm) and phenylethylamine (IC(50) 58.7 mm). Addition of monoamine oxidase (MAO) inhibitors afforded nearly complete protection against inhibition by phenylethylamine, tyramine and 3,4-dimethoxyphenylethylamine, indicating that inhibition arose from MAO-mediated pathways. In contrast, the inhibitory effects of DA and 3-MT were only partially prevented by MAO blockade, suggesting that inhibition might also arise from two-electron catechol oxidation and quinone formation by DA and one-electron oxidation of the 4-hydroxyphenyl group of 3-MT. In the phenylacetate studies, 3,4-dihydroxyphenylacetic acid (DOPAC) was equipotent with DA in inhibiting respiration (IC(50) 7.4 mm), further implicating the catechol reaction as the cause of inhibition. All other carboxylate congeners; phenylacetic acid (IC(50) 13.0 mm), 4-hydroxyphenylacetic acid (IC(50) 12.1 mm), 4-hydroxy-3-methoxyphenylacetic acid (HVA, IC(50) 12.0 mm) and 3,4-dimethoxyphenylacetic acid (IC(50) 10.2 mm), were equipotent respiratory inhibitors and two- to fourfold more potent than their corresponding amine. These latter findings suggest that the phenylacetate ion can also contribute independently to mitochondrial inhibition. In summary, mitochondrial respiration can be inhibited by DA and its metabolites by four distinct MAO-dependent and independent mechanisms.     

Effect of Peroxide, Sodium, and Calcium on Brain Mitochondrial Respiration In Vitro: Potential Role in Cerebral Ischemia and Reperfusion

Mitochondrial pyruvate-supported respiration was studied in vitro under conditions known to exist following ischemia, i.e., elevated extramitochondrial Ca2+, Na+, and peroxide. Ca2+ alone (7-10 nmol/mg) decreased state 3 and increased state 4 respiration to 81 and 141% of control values, respectively. Sodium (15 mM) and/or tert-butyl hydroperoxide (tBOOH; up to 2,000 nmol/mg protein) alone had no effect on respiration; however, Na+ or tBOOH in combination with Ca2+ dramatically altered respiration. Respiratory inhibition induced by Ca2+ and tBOOH does not involve pyruvate dehydrogenase (PDH) inhibition since PDH flux increased linearly with tBOOH concentration (R = 0.96). Calcium potentiated tBOOH-induced mitochondrial NAD(P)H oxidation and shifted the redox state of cytochrome b from 67 to 47% reduced. Calcium (5.5 nmol/mg) plus Na+ (15 mM) decreased state 3 and increased state 4 respiratory rates to 55 and 202% of control values, respectively. Sodium- as well as tBOOH-induced state 3 inhibition required mitochondrial Ca2+ uptake because ruthenium red addition before Ca2+ addition negated the effect. The increase in state 4 respiration involved Ca2+ cycling since ruthenium red immediately returned state 4 rates back to control values. The mechanisms for the observed Ca2(+)-, Na(+)-, and tBOOH-induced alterations in pyruvate-supported respiration in vitro are discussed and a multifactorial etiology for mitochondrial respiratory dysfunction following cerebral ischemia in vivo is proposed.     

Studies on the Reduction of Terpenes with Sodium in Aqueous-ammonia

On reduction of (?)-menthone by various methods, generally, a mixture of (?)-menthol and (+)-neomenthol has been obtained. In the present work, it is found that (?)-menthol can be prepared almost quantitatively from (?)-menthone by treatment with sodium in aqueous-ammonia.     

Pharmacological activity of (R)-(+)-pulegone, a chemical constituent of essential oils

(R)-(+)-Pulegone is a monoterpene found in essential oils from plants of the Labiatae family. This compound is a major constituent of Agastache formosanum oil. In this study, the effect of (R)-(+)-pulegone on the central nervous system was evaluated. (R)-(+)-Pulegone caused a significant decrease in ambulation and an increase in pentobarbital-induced sleeping time in mice, indicating a central depressant effect. (+)-Pulegone also significantly increased the latency of convulsions as assessed by the pentylenetetrazole (PTZ) method. The antinociceptive properties of this monoterpene were studied in chemical and thermal models of nociception. Chemical nociception induced in the first and second phase of the subplantar formalin test was significantly inhibited by (R)-(+)-pulegone and was not blocked by naloxone. Thermal nociception was also significantly inhibited while (R)-(+)-pulegone increased the reaction latency of the mice in the hot plate test. These results suggest that (R)-(+)-pulegone is a psychoactive compound and has the profile of an analgesic drug.     

Phosphoglyceride biosynthesis by brain microsomes: centrophenoxine, SaH-42-348, and DH-990 inhibit phospholipid N-methylation

The effects of centrophenoxine, SaH-42-348, and DH-990 on several enzymes involved in aminophospholipid biosynthesis in brain have been examined in vitro. Relatively high concentrations of centrophenoxine were required to achieve 50% inhibition of the microsomal enzymes CDP-ethanolamine:1,2-diacylglycerol ethanolaminephosphotransferase (EPT), CDP-choline:1,2-diacylglycerol cholinephosphotransferase (CPT), phosphatidyl-N-methylethanolamine N-methyltransferase (PME-NMT), and phosphatidyl-N,N-dimethylethanolamine N-methyltransferase (PDE-NMT). Intermediate concentrations of SaH-42-348 inhibited CPT (IC50 = 2.0 mM), EPT (IC50 = 1.9 mM), PME-NMT (IC50 = 0.19 mM), and PDE-NMT (IC50 = 0.17 mM). Of the three drugs tested, DH-990 was the most potent inhibitor of the phospholipid-synthesizing enzymes. Phosphatidylserine decarboxylase, a mitochondrial inner-membrane enzyme [A. K. Percy, J. F. Moore, M. A. Carson, and C. J. Waechter (1983) Arch. Biochem. Biophys. 223, 484-494], was virtually unaffected by the three drugs added at millimolar concentrations. Kinetic analyses indicated that the inhibitory action of DH-990 on the brain enzymes was noncompetitive with respect to all substrates. The relatively high sensitivity of CPT (IC50 = 0.6 mM), EPT (IC50 = 2.2 mM), PME-NMT (IC50 = 2.5 microM), and PDE-NMT (IC50 = 2.5 microM) to inhibition by DH-990 in brain microsomes suggests that this compound may be useful for cellular studies on the possible relationships between phospholipid metabolism and neurobiological functions.     

Ethanol suppresses ureagenesis in rat hepatocytes: role of acetaldehyde

We proposed previously that closure of voltage-dependent anion channels (VDAC) in the mitochondrial outer membrane after ethanol exposure leads to suppression of mitochondrial metabolite exchange. Because ureagenesis requires extensive mitochondrial metabolite exchange, we characterized the effect of ethanol and its metabolite, acetaldehyde (AcAld), on total and ureagenic respiration in cultured rat hepatocytes. Ureagenic substrates increased cellular respiration from 15.8 ± 0.9 nmol O(2)/min/10(6) cells (base line) to 29.4 ± 1.7 nmol O(2)/min/10(6) cells in about 30 min. Ethanol (0-200 mM) suppressed extra respiration after ureagenic substrates (ureagenic respiration) by up to 51% but not base line respiration. Urea formation also declined proportionately. Inhibition of alcohol dehydrogenase, cytochrome P450 2E1, and catalase with 4-methylpyrazole, trans-1,2-dichloroethylene, and 3-amino-1,2,3-triazole restored ethanol-suppressed ureagenic respiration by 46, 37, and 66%, respectively. By contrast, inhibition of aldehyde dehydrogenase with phenethyl isothiocyanate increased the inhibitory effect of ethanol on ureagenic respiration by an additional 60%. AcAld, an intermediate product of ethanol oxidation, suppressed ureagenic respiration with an apparent IC(50) of 125 μM. AcAld also inhibited entry of 3-kDa rhodamine-conjugated dextran in the mitochondrial intermembrane space of digitonin-permeabilized hepatocytes, indicative of VDAC closure. In conclusion, AcAld, derived from ethanol metabolism, suppresses ureagenesis in hepatocytes mediated by closure of VDAC.     

Nitric oxide and platelet energy metabolism

This study was undertaken to determine whether nitric oxide (NO) can affect platelet responses through the inhibition of energy production. It was found that NO donors: S-nitroso-N-acetylpenicyllamine, SNAP, (5-50 microM) and sodium nitroprusside, SNP, (5-100 microM) inhibited collagen- and ADP-induced aggregation of porcine platelets. The corresponding IC50 values for SNAP and SNP varied from 5 to 30 microM and from 9 to 75 microM, respectively. Collagen- and thrombin-induced platelet secretion was inhibited by SNAP (IC50 = 50 microM) and by SNP (IC50 = 100 microM). SNAP (20-100 microM), SNP (10-200 microM) and collagen (20 microg/ml) stimulated glycolysis in intact platelets. The degree of glycolysis stimulation exerted by NO donors was similar to that produced by respiratory chain inhibitors (cyanide and antimycin A) or uncouplers (2,4-dinitrophenol). Neither the NO donors nor the respiratory chain blockers affected glycolysis in platelet homogenate. SNAP (20-100 microM) and SNP (50-200 microM) inhibited oxygen consumption by platelets. The effect of SNP and SNAP on glycolysis and respiration was not reduced by 1H-[1,2,4]oxadiazolo-[4,3-a]quinoxalin-1-one, a selective inhibitor of NO-stimulated guanylate cyclase. SNAP (5-100 microM) and SNP (10-300 microM) inhibited the activity of platelet cytochrome oxidase and had no effect on NADH:ubiquinone oxidoreductase and succinate dehydrogenase. Blocking of the mitochondrial energy production by antimycin A slightly affected collagen-evoked aggregation and strongly inhibited platelet secretion. The results indicate that: 1) in porcine platelets NO is able to diminish mitochondrial energy production through the inhibition of cytochrome oxidase, 2) the inhibitory effect of NO on platelet secretion (but not aggregation) can be attributed to the reduction of mitochondrial energy production.     

Tricyclic antidepressants inhibit voltage-dependent calcium channels and Na(+)-Ca2+ exchange in rat brain cortex synaptosomes

We have used a resting (5 mM K+) or depolarizing (60 mM K+) choline-based medium, and a nondepolarizing sodium-based or choline-based medium, to characterize the inhibitory potential of tricyclic antidepressants against the voltage-dependent calcium channels or the Na(+)-Ca2+ exchange process, respectively, in synaptosomes from rat brain cortex. Imipramine, desipramine, amitriptyline, and clomipramine inhibited net K(+)-induced 45Ca uptake with similar IC50 values (26-31 microM), and this uptake was also inhibited by diltiazem with an IC50 of 36 microM; these results indicate an inhibition of voltage-dependent calcium channels by tricyclic antidepressants. The net uptake of 45Ca induced by Na(+)-Ca2+ exchange was also inhibited by the four tricyclic antidepressants tested, but not by diltiazem; imipramine (IC50 = 94 microM) was a more potent inhibitor of this process than desipramine (IC50 = 151 microM), and the IC50 values of amitriptyline (107 microM) and clomipramine (97 microM) were similar to that of imipramine. Some degree (approximately 25%) of brain calcium channel blockade could be present at the steady-state concentrations of tricyclic antidepressants expected to occur therapeutic use of these compounds to treat depression or panic disorder.     

Similar nature of inhibition of mitochondrial respiration of heart tissue and malignant cells by methylglyoxal. A vital clue to understand the biochemical basis of malignancy

The effect of methylglyoxal on the oxygen consumption of mitochondria of heart and of several other organs of normal animals of different species has been tested. The results indicate that methylglyoxal (3.5 mM) strongly inhibits ADP-stimulated -oxoglutarate and malate plus pyruvate-dependent respiration of exclusively heart mitochondria of normal animals of different species. Whereas, with the same substrates, but at a higher concentration of methylglyoxal (7.5 mM), the respiration of mitochondria of other organs of normal animals is not inhibited. Methylglyoxal also inhibits the respiration of slices of rat and toad hearts. But this inhibition is less pronounced. However, methylglyoxal (15 mM) fails to have any effect on perfused toad heart. Using rat heart mitochondria as a model, the effect of methylglyoxal on the oxygen consumption was also tested with different respiratory substrates, electron donors at different segments of the mitochondrial respiratory chain and site-spe inhibitors to identify the specific respiratory complex which might be involved in the inhibitory effect of methylglyoxal. The results strongly suggest that methylglyoxal inhibits the electron flow through complex I of rat heart mitochondrial respiratory chain. Moreover, lactaldehyde (0.6 mM), a catabolite of methylglyoxal, can exert a protective effect on the inhibition of rat heart mitochondrial respiration by methylglyoxal (2.5 mM). The effect of methylglyoxal on heart mitochondria as described in the present paper is strikingly similar to the results of our previous work with mitochondria of Ehrlich ascites carcinoma cells and leukemic leukocytes. We have recently proposed a new hypothesis on cancer which suggests that excessive ATP formation in cells may lead to malignancy. The above mentioned similarity apparently provides a solid experimental foundation for the proposed hypothesis which has been discussed.     

Purification of beta-glucosidase from olive (Olea europaea L.) fruit tissue with specifically designed hydrophobic interaction chromatography and characterization of the purified enzyme

An olive (Olea europaea L.) β-glucosidase was purified to apparent homogeneity by salting out with ammonium sulfate and using specifically designed sepharose-4B-L-tyrosine-1-napthylamine hydrophobic interaction chromatography. The purification was 155 fold with an overall enzyme yield of 54%. The molecular mass of the protein was estimated as ca. 65 kDa. The purified β-glucosidase was effectively active on p-/o-nitrophenyl-β-D-glucopyranosides (p-/o-NPG) with K(m) values of 2.22 and 14.11 mM and V(max) values of 370.4 and 48.5 U/mg, respectively. The enzyme was competitively inhibited by δ-gluconolactone and glucose against p-NPG as substrate. The K(i) and IC(50) values of δ-gluconolactone were determined as 0.016 mM and 0.23 mM while the enzyme was more tolerant to glucose inhibition with K(i) and IC(50) values of 6.4 mM and 105.5 mM, respectively, for p-NPG. The effect of various metal ions on the purified β-glucosidase was investigated. Of the ions tested, only the Fe(2+) increased the activity while Cd(2+) Pb(2+) Cu(2+), Ni(+), and Ag(+) exhibited different levels of inhibitory effects with K(i) and IC(50) values of 4.29×10(-4) and 0.38×10(-4), 1.26×10(-2) and 5.3×10(-3), 2.26×10(-4) and 6.1×10(-4), 1.04×10(-4) and 0.63×10(-4), 3.21×10(-3) and 3.34×10(-3) mM, respectively.     

In vitro kinetics of the rat brain succinate dehydrogenase inhibition by hexachlorophene.

Brain succinate dehydrogenase (SDH) activity was inhibited by in vitro hexachlorophene (HCP) with a half inhibitory concentration (IC50) of 0.65 x 10(-3) M. The HCP exerted noncompetitive inhibition at 0.5 mM (IC50) on SDH activity. The brain SDH demands more energy of activation (deltaE) in the presence of HCP. The ionizable groups of SDH such as the sulfhydral group of cysteine and alpha-amino groups of cysteine were not altered qualitatively in the presence of HCP.     

The endogenous amine 1-methyl-1,2,3,4- tetrahydroisoquinoline prevents the inhibition of complex I of the respiratory chain produced by MPP(+)

The endogenous monoamine 1-methyl-1,2,3,4-tetrahydroisoquinoline has been shown to prevent the neurotoxic effect of MPP(+) and other endogenous neurotoxins, which produce a parkinsonian-like syndrome in humans. We have tested its potential protective effect in vivo by measuring the protection of 1-methyl-1,2,3,4-tetrahydroisoquinoline in the neurotoxicity elicited by MPP(+) in rat striatum by tyrosine hydroxylase immunocytochemistry. Because we know that cellular damage caused by MPP(+) is primarily the result of mitochondrial respiratory inhibition at the complex I level, we have extended the study further to understand this protective mechanism. We found that the inhibitory effect on the mitochondrial respiration rate induced by MPP(+) in isolated rat liver mitochondria and striatal synaptosomes was prevented by addition of 1-methyl-1,2,3,4-tetrahydroisoquinoline. This compound has no antioxidant capacity; therefore, this property is not involved in its protective effect. Thus, we postulate that the preventive effect that 1-methyl-1,2,3,4-tetrahydroisoquinoline has on mitochondrial inhibition for MPP(+) could be due to a "shielding effect," protecting the energetic machinery, thus preventing energetic failure. These results suggest that this endogenous amine may protect against the effect of several parkinsonism-inducing compounds that are associated with progressive impairment of the mitochondrial function.     

Hepatic antioxidant-sensitive respiration. Effect of ethanol, iron and mitochondrial uncoupling.

The addition of the antioxidants (+)-cyanidanol-3, butylated hydroxyanisole and ascorbate to the perfused rat liver resulted in a decrease in the rate of oxygen consumption. This basal antioxidant-sensitive respiration of 110-130nmol X min-1 X (g of liver)-1 represents 5-7% of total respiration. Increased antioxidant-sensitive respiratory rates are found after the infusion of increasing concentrations of ethanol (1.8-72.2mM) or iron (35.5-248.5 microM). This respiratory component exhibits a dependence on ethanol or iron concentration, with maximal rates of 200-255 and 330nmol X min-1 X (g of liver)-1 respectively. After the addition of 100 microM-2,4-dinitriphenol, an antioxidant-sensitive respiratory component of 230nmol X min-1 X (g of liver)-1 is found, which is not observed at lower concentrations of the uncoupler (5-50 microM). The lack of effect of the antioxidants used on mitochondrial respiration [the preceding paper, Videla, Villena, Donoso, Giulivi & Boveris (1984) Biochem. J. 223, 879-883] and on the glycolytic rate of the perfused liver suggests that the basal and chemically induced antioxidant-sensitive respiration observed are related to oxygen required for one-electron transfer reactions associated with the generation of active species of oxygen and lipid peroxidation in the liver cell.