Determination of salsolinol, norsalsolinol, and twenty-one biogenic amines using micellar electrokinetic capillary chromatography-electrochemical detection.

Micellar electrokinetic chromatography coupled to amperometric electrochemical detection was used to resolve and then quantify biogenic amines and metabolites within the fruit fly Drosophila melanogaster. A new separation scheme was devised to allow resolution of 24 compounds of interest. This was accomplished by precisely controlling the amount of base added to the background buffer, optimizing the resolution of the separation, and then calculating the pH. Here we focused on measurements of six of the analytes that are thought to be involved in the response to alcohol, dopamine, salsolinol, norsalsolinol, N-acetyloctopamine, octopamine, and N-acetyldopamine. These were identified and quantified within the fly head. We believe that the identification of salsolinol and norsalsolinol in the fly brain is novel.

Localization of N-methyl-norsalsolinol within rodent and human brain.

The isoquinoline derivative N-methyl-6,7-dihydroxytetrahydroisoquinoline (N-methyl-norsalsolinol) is present in normal human brain and has been identified in the cerebrospinal fluid of patients with Parkinson's disease (PD). Endogenously, N-methyl-norsalsolinol may be derived from dopamine by condensation with aldehydes or alpha-ketoacids. In vitro experiments suggest that N-methyl-norsalsolinol is neurotoxic. In this study, high-performance liquid chromatography with electrochemical detection (HPLC-EC) was used to determine N-methyl-norsalsolinol concentrations in mouse, rat, normal human, and PD brain. In addition, a monoclonal antibody was generated against N-methyl-norsalsolinol and used to determine the cellular localization of N-methyl-norsalsolinol in brain. With HPLC-EC, N-methyl-norsalsolinol was detected in all regions of rodent and human brain subjected to analysis. In rodent brains, N-methyl-norsalsolinol tissue concentrations were similar among frontal cortex, ventral midbrain, striatum, hippocampus, and cerebellum. Conversely, in normal human control brains, N-methyl-norsalsolinol was concentrated in the substantia nigra and striatum. In comparison to normal human controls, N-methyl-norsalsolinol levels were significantly lower in the substantia nigra and caudate nuclei from PD patients, a finding possibly related to the death of nigrostriatal dopaminergic neurons. N-methyl-norsalsolinol immunoreactivity colocalized with a general neuronal marker (neuron-specific enolase) and a monoaminergic marker (tyrosine hydroxylase) but not with a glial marker (glial fibrillary acidic protein). The widespread neuronal localization of N-methyl-norsalsolinol in several mammalian species suggests that, in isolation, this compound is a "weak" neurotoxin. However, endogeneously derived N-methyl-norsalsolinol could contribute to the pathobiology of PD in genetically predisposed individuals after years of accumulation in dopaminergic neurons.

Systematic regional study of dopamine, norsalsolinol, and (R/S)-salsolinol levels in human brain areas of alcoholics.

BACKGROUND: Dopamine (DA)-derived tetrahydroisoquinolines (TIQs) are discussed as neurochemical factors of addiction processes in alcoholism. In a prospective study, the regional distribution of DA, (R)-salsolinol (SAL), and (S)-SAL, as well as norsalsolinol (NorSAL) was examined systematically in a large collective of human brain samples obtained by autopsy. METHODS: The material comprises 44 brains of alcoholics and 47 controls with 6 standardized specimens in each case. The analytes were determined after solid-phase extraction and enantioselective derivatization using gas chromatography-mass spectrometry. RESULTS: Levels of DA, (R/S)-SAL, and NorSAL in alcoholics did not differ significantly from those of the control group. A relationship between alcohol consumption and SAL formation could not be proved. Topical differences and no ubiquitous occurrence were encountered. Significant amounts of (R)-SAL and (S)-SAL as well as NorSAL only were found in DA-rich areas of the basal ganglia, whereas in other regions of the brain, no TIQs were detected. Especially in the nucleus caudatus, the concentrations of DA, SAL, and NorSAL decreased significantly with rising age. CONCLUSION: These findings do not support the hypothesis that one of the SAL enantiomers or NorSAL is involved in the genesis of alcoholism. However, they suggest that the concentration of the substrate DA may determine the alkaloid level during in vivo formation. The revealed data can serve as reference for other studies in humans concerning the cause of alcoholism or other neurodegenerative diseases with the involvement of TIQs.

Simultaneous gas chromatographic-mass spectrometric determination of dopamine, norsalsolinol and salsolinol enantiomers in brain samples of a large human collective.

Using a solid-phase extraction procedure, an enantioselective derivatization and a gas chromatographic-mass spectrometric method, the levels of dopamine (DA) and of the dopamine-derived tetrahydroisoquinoline alkaloids (R)/(S)-salsolinol (SAL) and norsalsolinol (NorSAL) were determined in human brain samples. A complex pre-analytical synthesis of reference substances as well as deuterated internal standards allowed the standardized and reproducible analysis. In this study, to our best knowledge for the first time, the regional distribution of (R)-SAL and (S)-SAL, as well as NorSAL is examined systematically in a large collective of human brain samples obtained by autopsy. The material comprises 91 brains and 8 standardized specimens in each case. Anatomical concentration differences and no ubiquitous occurence were encountered. Significant amounts of (R)-SAL, (S)-SAL and NorSAL were only found in dopamine-rich areas of the basal ganglia, whereas in other regions of the brain no tetrahydroisoquinolines were detected. These findings suggest that the concentration of the substrate dopamine may determine the alkaloid level during in vivo formation. In our opinion, non-enzymatic formation of SAL via the Pictet-Spengler reaction reveals both the SAL enantiomers. An additional enzymatic synthesis of only (R)-SAL could explain the predominant occurrence of this enantiomer. Especially in the nucleus caudatus, the concentrations of DA, SAL and NorSAL decreased significantly with rising age, which may be consistent with apoptotic effects of ageing. Our data can serve as reference for other studies in humans concerning the etiology of alcoholism or other neurodegenerative diseases with the involvement of tetrahydroisoquinolines.

Determination of dopamine and dopamine-derived (R)-/(S)-salsolinol and norsalsolinol in various human brain areas using solid-phase extraction and gas chromatography/mass spectrometry.

Using a solid-phase extraction procedure and a gas chromatographic-mass spectrometric (GC/MS) method the levels of dopamine and the levels of dopamine-derived salsolinol (SAL) and norsalsolinol (NorSAL) were determined in human brain areas involved in the etiology of alcoholism, parkinsonism and other diseases. The possibility that biosynthesis of salsolinol occurs through a stereospecific enzymatic reaction was considered. Using a two-step derivatization with N-methyl-N-trimethylsilyltrifluoracetamide (MSTFA) and the chiral reagent (R)-(-)-2-phenylbutyryl chloride, baseline separated peaks of (R)- and (S)-SAL were obtained. Both enantiomers were found in human brain samples with no correlations between levels of salsolinol and dopamine. These findings do not support the hypothesis that only an enantio-selective synthesis of (R)-SAL by a putative salsolinol synthase is responsible for the in vivo formation. In our opinion, non-enzymatic formation of salsolinol via the Pictet-Spengler reaction reveals both salsolinol enantiomers and an additional enzymatic synthesis of only (R)-SAL explains the enantiomer ratio (R)-/(S)-SAL of approximately 2.

A systematic regional study of dopamine and dopamine-derived salsolinol and norsalsolinol levels in human brain areas.

Dopamine and the dopamine-derived tetrahydroisoquinoline alkaloids salsolinol and norsalsolinol were measured by high-performance liquid chromatography with electrochemical detection in 15 regions of the human brain. The regional distribution of dopamine in 32 brains was similar to previous reports with highest concentrations in the basal ganglia, especially in the striatum, followed by the substantia nigra and the hypothalamus. Significant amounts of salsolinol and norsalsolinol were only found in these dopamine-rich areas, whereas in the other regions no alkaloids were detected. These findings suggest that the concentration of the substrate dopamine may determine the alkaloid level during in vivo formation.

Fluorometric determination of 1,2,3,4-tetrahydro-6,7-dihydroxyisoquinoline in biological materials by HPLC.

In the belief that endogenous 1,2,3,4-tetrahydro-6,7-dihydroxyisoquinoline (DA-Fp) could be a potential marker involved in the etiology of various diseases such as Parkinsonism, we attempted to develop a fluorescence method for DA-Fp. It was synthesized by condensation of dopamine with formaldehyde according to an established method. Periodate was identified by screening from various oxidation reagents as a fluorescence reagent to DA-Fp. Optimal reaction conditions were obtained with 0.25 mM NaIO4 in 0.1 M phosphate buffer (pH 8.0) at 37 degrees C for 15 min. The fluorescence spectrum of the derivative showed that we had found a new reaction specific for DA-Fp. This reaction was coupled on-line to high performance liquid chromatography (HPLC), which enabled us to achieve a highly sensitive method for determining DA-Fp. A working curve was linear from 2 to 800 pmol of DA-Fp per injection. To determine DA-Fp in biological materials, the pretreatment before HPLC was optimized by hydrolysis of its conjugate and suppression of the artifact with l-phenylephrine. Urinary excretion of DA-Fp in men was measured by this new present method. The urinary excretion of endogenous DA-Fp increased in a rabbit given L-DOPA. The DA-Fp concentration was determined in rat brain. The significance of DA-Fp in these biological materials is discussed and evaluated. We conclude that the present method will be useful for studying tetrahydroisoquinolines involved in many diseases.

Assay for the (R)- and (S)-enantiomers of salsolinols in biological samples and foods with ion-pair high-performance liquid chromatography using beta-cyclodextrin as a chiral mobile phase additive.

A chromatographic procedure was devised for the quantitative determination of the enantiomers of salsolinol and N-methylsalsolinol, which are biologically important alkaloids. The enantiomers of salsolinol and N-methylsalsolinol were completely separated using beta-cyclodextrin in a reversed-phase ion-pair system. The HPLC method was sensitive enough to detect the isoquinolines at a concentration less than 0.1 pmol per injection. The presence of (R)- and (S)-salsolinol was confirmed in fermented foods and beverages, while N-methylsalsolinol was not detected. On the other hand, the (R)-enantiomers of both salsolinol and N-methylsalsolinol were found to predominate in the human brain.

N-methyl-(R)salsolinol as a dopaminergic neurotoxin: from an animal model to an early marker of Parkinson's disease.

A dopamine-derived 1(R), 2(N)-dimethyl-6,7-dihydroxy-1,2,3,4-tetrahydrosioquinoline [N-methyl-(R)salsolinol] was found to occur enantioselectively in human brain. This isoquinoline induced parkinsonism in rat after injection in the striatum, and the behavioral, biochemical and pathological changes were very similar to those in Parkinson's disease. N-Methyl-(R)salsolinol depleted dopamine neurons in the rat substantia nigra without necrotic tissue reaction, which may be due to the apoptotic death process, as proved by its induction of DNA damage in dopaminergic neuroblastoma SH-SY5Y cells. N-Methyl-(R)salsolinol was found to increase significantly in the cerebrospinal fluid of parkinsonian patients. All these results suggest that N-methyl-(R)salsolinol may be an endogenous neurotoxin to cause Parkinson's disease and the enzymes involved in its biosynthesis and catabolism may be endogenous factors in the pathogenesis of this disease.

Determination of the (R)- and (S)-enantiomers of salsolinol and N-methylsalsolinol by use of a chiral high-performance liquid chromatographic column.

A new method for the quantitative determination of the enantiomers of salsolinol and N-methylsalsolinol, biologically important alkaloids, is reported. The enantiomers were completely separated without derivatization, using a cyclodextrin-modified silica gel column with an HPLC-electrochemical detection system. The HPLC conditions were examined for the best resolution. The method was sensitive enough to detect salsolinol and N-methylsalsolinol at a concentration of less than 0.1 pmol per injection. In the product of the Pictet-Spengler reaction of acetaldehyde with dopamine or epinine, almost equimolar (R)- and (S)-enantiomers of salsolinol and N-methylsalsolinol were detected. Preliminary results indicate that the (R)-enantiomer of both isoquinoline derivatives predominate in the human brain.

A new rapid method for the analysis of catecholic tetrahydroisoquinolines from biological samples by gas chromatography/mass spectrometry.

A new method for the analysis of tetrahydroisoquinolines (TIQ) from biological materials is described. The method combines extraction and acylation of the TIQs from urine in a one-step procedure followed by analysis by gas chromatography/mass spectrometry. By this extractive derivatization method, a decrease of the extraction time, to speed up sample preparation in order to minimize oxidative side reaction, has been achieved. The detection limits for the analysis of salsolinol and salsolin in urine were 10 fmol/ml sample volume. Tetrahydropapaveroline could only be detected in spiked urine samples with a detection limit of 1 pmol/ml urine. The method is not only restricted to urine samples, but can also be applied to a variety of tissue types, including blood components.

Demonstration of highly specific and sensitive antibodies to a naturally occurring tetrahydroisoquinoline alkaloid, salsolidine.

1. We report for the first time on the production and characterization of antibodies against a naturally occurring tetrahydroisoquinoline, namely salsolidine (6,7-dimethoxy-1-methyl-1,2,3,4-tetrahydroisoquinoline). 2. Immunogen synthesis was carried out by coupling the hapten salsolidine to bovine serum albumin (BSA) as carrier protein on the basis of reductive amination. 3. By immunization of rabbits with salsolidine-BSA conjugate antisalsolidine antibodies were produced. 4. At a final dilution of 1:1700 the highest-titre antiserum bound 35% of 0.21 pmol [3H]salsolidine. This antiserum was used to develop a radioimmunoassay for salsolidine. 5. Cross-reactivity studies revealed a high specificity of the antiserum to the hapten. 6. The antibodies had a high affinity to salsolidine (Ka = 1.5 x 10(9) M-1). 7. Standard curves covered a measuring range of 0.5-70 pmol/tube and the detection limit was found to be 0.27 pmol/tube.

Identification and quantification of 1-carboxysalsolinol and salsolinol in biological samples by gas chromatography--mass spectrometry.

1-Carboxysalsolinol was found to be present in rat striatum, human urine and caudate nucleus of post mortem human brain, according to capillary column gas chromatographic retention times and selected ion monitoring of the hexafluoropropionyl ester pentafluoropropyl derivative. Simultaneous quantification of 1-carboxysalsolinol and salsolinol was performed in biological samples using deuterium labelled internal standards. In human urine, the precision of the method was +/- 7.1% (coefficient of variation, n = 25) for 1-carboxysalsolinol at 15 pmol/ml and +/- 8.5% for salsolinol at 10 pmol/ml. According to enzymatic hydrolysis, 68% of 1-carboxysalsolinol was found as conjugates in urine, and the corresponding figure for salsolinol was 92%. In human caudate nucleus, the amounts of 1-carboxysalsolinol were found to be significantly greater in brains from alcoholics, who at autopsy had ethanol present in the blood, whereas alcoholics without blood ethanol levels at autopsy had significantly lower concentrations of salsolinol.

Analysis of salsolinol and salsoline in biological samples using deuterium-labelled internal standards and gas chromatography--mass spectrometry.

Salsolinol and salsoline were labelled with deuterium using an acidic exchange reaction in 2HCl--2H2O. Two deuterium atoms were incorporated in both compounds. The deuterium-labelled salsolinol and salsoline were used as internal standards to determine picomol amounts of the corresponding unlabelled compound in the urine, cerebrospinal fluid, brain and liver. The salsolinol was purified on alumina and salsoline collected in the effluent. The compounds were analysed as their pentafluoropropionyl derivatives by gas chromatography on a 1% OV-17 column and were selectively detected with electron-impact mass spectrometry at the molecular ions M+ and M+--15. With human urine the precision of the methods were +/- 4.9% (coefficient of variation, n = 10) for salsolinol and +/- 2.2% for salsoline at a level of 0.100 nmol/ml. Administration of salsolinol to rats intraperitoneally (0.4 mmol/kg) resulted in levels of 1--2 nmol/g in striatum and limbic forebrain after 2 h, whereas the corresponding liver values were about 550 nmol/g. Control animals showed salsolinol values in liver of about 2 nmol/g and in striatum and limbic forebrain 1 nmol/g tissue.

Estimation of the in vivo concentration of salsolinol and tetrahydropapaveroline in rat brain after the administration of ethanol.

Tetrahydroisoquinolines (TIQs) are not only pharmacologically active, but their intraventricular infusion evokes alcohol drinking in rats. It is not known if salsolinol or tetrahydropapaveroline (THP), the two most commonly studied TIQs, spontaneously form in vivo in brain during chronic or acute consumption of ethanol. A theoretical calculation based on a steady-state assumption was made in order to estimate what could be the upper limit of these compounds in rat brain. The model used was that the rate of formation was equal to the rate of disappearance. The latter term is the rate constant for metabolism times the TIQ concentration. The former was estimated for salsolinol from data obtained from human urine while for THP it was simply the second order rate equation. The values obtained for both concentrations were ca 1 ng/g-brain tissue.