harman and harmol

beta-Carboline alkaloids are derived as a result of condensation between indoleamine (e.g. tryptamine) and short-chain carboxylic acid (e.g. pyruvic acid) or aldehyde (e.g. acetaldehyde), a reaction that occurs readily at room temperature. These compounds have been found endogenously in human and animal tissues and may be formed as a byproduct of secondary metabolism: their endogenous functions however, are not well understood. Indoles and tryptophan derivatives exhibit antioxidative actions by scavenging free radicals and forming resonance stabilized indolyl radicals. Harmane and related compounds exhibited concentration-dependent inhibition of lipid peroxidation (measured as thiobarbiturate reactive products) in a hepatic microsomal preparation incubated with either enzymatic dependent (Fe3+ ADP/NADPH) or non-enzymatic dependent (Fe3+ ADP/dihydroxyfumarate) oxygen radical producing systems. Alkaloids with hydroxyl substitution and a partially desaturated pyridyl ring were found to have the highest antioxidative potencies. Substitution of a hydroxyl group by a methoxyl group at the 6-position resulted in a decrease of greater than 10-fold in the antioxidative activities. Harmane showed high efficacy in an enzymatic system but low efficacy in a non-enzymatic system. The antioxidative effects of harmane in the former system may be attributed to its ability to inhibit oxidative enzymes in the microsomal system. These results suggest that beta-carbolines may also serve as endogenous antioxidants.

Topics: Animals; Antioxidants; Carbolines; Dose-Response Relationship, Drug; Free Radicals; Harmaline; Harmine; Lipid Peroxidation; Male; Microsomes, Liver; Models, Chemical; Rats; Rats, Inbred Strains; Structure-Activity Relationship; Thiobarbiturates; Tryptamines

The beta-carbolines harmane, norharmane, tetrahydronorharmane, harmine, harmaline and harmol were administered to sheep to assess their effects on upper motor neurone function. Harmane at a dose rate of 54 mg/kg induced hypomotility, head tremors, pelvic limb paresis, hypermetria and a wide based stance. A range of similar effects were observed with norharmane at the same dose rate. Tetrahydronorharmane at a dose rate of 54 mg/kg induced hypermotility followed by hypomotility, asymmetrical pelvic limb paresis, hypermetria, a wide based stance, and stereotyped eating behaviour. Harmine and harmaline at 6 mg/kg induced mild head and body tremors, and at 18 mg/kg induced hypomotility, intense head and body tremors, pelvic limb paresis, crossing over of limbs, neck extension and head swaying. Harmol was not effective at 54 mg/kg by either the subcutaneous or intraperitoneal routes, but at an intravenous dose of 27 mg/kg it induced hypermotility followed by hypomotility, body tremors, limb paresis, muscle asynergy, a wide based stance and jumping behaviour. Harmane, tetrahydronorharmane, harmaline and harmol were convulsive in some sheep at high dose rates.

Topics: Alkaloids; Animals; Carbolines; Female; Harmaline; Harmine; Locomotion; Motor Neurons; Plants, Toxic; Sheep

Rats were trained to discriminate between saline and 1.0 mg/kg of diazepam in a two-choice procedure where responding was maintained under a fixed-ratio, 5-response schedule of stimulus shock termination. beta-Carboline-3-carboxylate-methyl ester (beta CCM), beta-carboline-3-carboxylate-ethyl ester (beta CCE) and beta-carboline-3-carboxylate-t-butyl ester (beta CCtB), compounds with alkylcarboxy substitutions on the 3-position of the beta-carboline ring structure, were effective antagonists of the discriminative effects of diazepam. The 3-hydroxymethyl-substituted compound (3HMC) was relatively ineffective in antagonizing the discriminative effects of diazepam. The order of potency in antagonizing the 1.0 mg/kg training dose of diazepam was beta CCtB greater than beta CCM greater than beta CCE much greater than 3 HMC. The greater potency of beta CCtB likely reflects its resistance to metabolism in vivo. beta CCE and beta CCtB produced dose-related, parallel shifts in the dose-response curve for the discriminative effects of diazepam, but the magnitude of the shifts was limited: the two highest doses of beta CCE and beta CCtB produced shifts that were not significantly different in magnitude. These latter results suggest that these beta-carbolines antagonize only a portion of the component(s) of action of diazepam in producing discriminative stimuli. In contrast, the 7-substituted beta-carbolines harmane, harmol and harmine were ineffective in antagonizing the discriminative effects of diazepam up to doses of the beta-carbolines which disrupted the ability of the animals to respond.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Animals; Carbolines; Diazepam; Discrimination Learning; Harmine; Male; Picrotoxin; Rats; Rats, Inbred F344

The effects of betacarbolines on guinea-pig isolated sinus nodes superfused with Tyrode's solution at 35 degrees C were analyzed. All analogs depressed the automaticity. The phase 4 of transitional fibers was depressed, in the absence of any change in maximum diastolic potential. The threshold for harmaline action was 10(-7)M. Dehydrogeneration of harmaline into harmine increased the potency. Removal of the methoxy group (harmane) did not modify the potency but accelerated the recovery. Substitution of the methoxy group by a hydroxy group (harmalol and harmol) reduced markedly the potency of harmaline and harmine, respectively.

Topics: Alkaloids; Animals; Depression, Chemical; Dose-Response Relationship, Drug; Guinea Pigs; Harmaline; Harmine; Sinoatrial Node; Structure-Activity Relationship