Human Brain Phenol Sulfotransferase: Biochemical Properties and Regional Localization

Phenol sulfotransferase (PST) catalyzes the sulfate conjugation of catecholamines and phenol and catechol drugs. The human blood platelet contains a thermolabile (TL) form of PST that catalyzes the sulfate conjugation of dopamine and other monoamines and a thermostable (TS) form that catalyzes the sulfate conjugation of micromolar concentrations of phenol and p-nitrophenol. Experiments were performed to determine whether the brain contains forms of PST analogous to the TL and TS forms found in the human platelet, and to determine whether there are regional variations in human brain PST activity. We found that the human brain contains at least two forms of PST, forms that are similar to the platelet TS and TL forms of the enzyme with respect to substrate specificity, apparent Km constants, thermal stability, and sensitivity to inhibitors. Optimal conditions were determined for the measurement of these two activities in brain homogenates. The stability of PST activities in the human brain after death was determined in five samples of cerebral cortex that were obtained during clinically indicated neurosurgical procedures. An average of 76 +/- 8% and 80 +/- 9% (mean +/- SEM) of the basal TL and TS PST activities, respectively, remained in these five samples of cerebral cortex after 8 h of storage under simulated post-mortem conditions. Six human brains were then obtained less that 8 h after death from patients who had no neurological disease prior to death. The mean activities of the TL and TS forms of PST were measured in 17 different regions of the six brains. If the pituitary was excluded from consideration, TL and TS PST activities both varied approximately fivefold among these regions, and both activities were highest in cerebral cortex. However, the average TS activity in the anterior pituitary, a tissue of non-neural origin embryologically, was 6.5-fold greater than the highest average TS PST activity found in cerebral cortex.     

Phenol sulfotransferase in humans: properties, regulation, and function

Phenol sulfotransferase (PST) catalyzes the sulfate conjugation of phenolic and catechol drugs and neurotransmitters. All human tissues that have been studied in detail contain at least two forms of PST. One form is thermolabile (TL), catalyzes the sulfate conjugation of micromolar concentrations of dopamine and other phenolic monoamines, and is relatively resistant to inhibition by 2,6-dichloro-4-nitrophenol (DCNP). The other form is thermostable (TS), catalyzes the sulfate conjugation of micromolar concentrations of simple phenols such as p-nitrophenol, and is relatively sensitive to DCNP inhibition. These two forms of PST have been physically separated and partially purified from several human tissues, including an easily accessible tissue, the blood platelet. The biochemical properties of platelet PST are very similar to those of PST in human brain, liver, and small intestine. Individual differences in the basal activity of TS PST in the platelet are correlated with individual variations in the activity of this form of the enzyme in human cerebral cortex (r = .94, n = 15, P less than 0.001). In addition, both platelet TS and TL PST activities are correlated significantly with the extent of sulfate conjugation of orally administered drugs such as acetaminophen and methyldopa. These latter observations are compatible with the conclusions that platelet PST activity may reflect the activity of the enzyme at sites of drug metabolism, and that variation in PST activity is one factor responsible for individual differences in the sulfate conjugation of orally administered drugs.     

Phenol sulfotransferase inheritance

1. Phenol sulfotransferase (PST) catalyzes the sulfate conjugation of many phenolic and catechol neurotransmitters. Human tissues contain both thermostable (TS) and thermolabile (TL) forms of PST that differ in their substrate specificities, inhibitor sensitivities, physical properties, and regulation. 2. Individual variations in the levels of activity of both TS and TL PST in the human platelet are strongly influenced by inheritance. 3. Individual differences in the level of platelet TS PST activity are correlated with individual variations in the activity of this form of the enzyme in human cerebral cortex, liver, and intestinal mucosa. 4. There are also individual familial differences in the thermal stability of TS PST in the platelet. These differences are correlated with individual variations in the thermal stability of TS PST in cerebral cortex, liver, and intestinal mucosa. 5. Individual variations in the thermal stability of TS PST in hepatic tissue are associated with the presence of one or both of a pair of TS PST isozymes that can be separated by ion-exchange chromatography and that differ in their thermal stabilities. 6. This series of observations suggests that a structural gene polymorphism may be one mechanism by which inheritance controls TS PST in humans. The isozymes of TS PST in liver may represent the products of alternative alleles for this polymorphism, alleles that might control the structure of TS PST in many human tissues.     

Human platelet phenol sulfotransferase: Familial variation in thermal stability of the TS form

Phenol sulfotransferase (PST) catalyzes the sulfate conjugation of catechol and phenolic drugs and xenobiotic compounds. Platelets and other tissues contain at least two forms of PST, forms that have been designated the "TL" and the "TS" forms. We measured the thermal stability of platelet TS PST in blood samples from 218 randomly selected unrelated subjects by heating platelet homogenates at 44 degrees C for 15 min. Thermal stability was expressed as the ratio of the enzyme activity remaining after preincubation to that in an unheated sample, a heated/control (H/C) ratio. The frequency distribution of H/C ratios for this population sample was bimodal, with a nadir at an H/C ratio of 0.33. Of the 218 subjects studied, 29 (13.3%) had thermolabile TS PST (H/C less than 0.33). Platelet samples were then obtained from subjects with thermolabile and thermostable TS platelet PST. PST activity in these platelet samples had similar apparent Km constants for substrates. IC50 values for inhibition of TS PST by 2,6-dichloro-4-nitrophenol in these samples were also nearly identical. The results of experiments in which platelet homogenates from subjects with thermolabile and thermostable TS PST were mixed and the results of experiments in which platelet homogenates were subjected to gel filtration chromatography were compatible with the conclusion that individual differences in TS PST thermal stability were properties of PST itself. Finally, there was a significant familial aggregation of the trait of thermolabile TS PST when H/C ratios were measured in platelet homogenates from 231 members of 49 randomly selected families.     

The human platelet as an independent unit for sulfate conjugation

The human platelets possess a full complement of enzymes capable of synthesizing N-acetyldopamine (NADA) 35sulfate from ATP, Mg++ and sodium 35sulfate. The pH optimum for this three-step overall sulfate conjugation (comprising of the ATP sulfurylase, APS kinase and phenolsulfotransferase reactions) is 8.6 and the reactions proceeded progressively for several hours. Both ATP and Mg++ ions, above their respective optimal concentrations of 5 and 7 mM, inhibited the sulfate conjugation of NADA. The apparent Km values for NADA as determined by the phenolsulfotransferase (PST) and overall reactions were similar in magnitude being 2.6 and 4.8 microM, respectively, while that for sodium 35sulfate was 202 microM. A comparison of these two activities in 62 platelet preparations of normal subjects showed that the rate of the PST reaction was generally higher than the overall reaction even though the PST assay was carried out at suboptimal concentration of PAPS. There was a positive correlation (r = 0.82) between the two sets of data, suggesting that the PST reaction probably has some control over the rate of overall sulfate conjugation.     

Human Phenol SulfotransferaseSTP2Gene: Molecular Cloning, Structural Characterization, and Chromosomal Localization

Sulfonation is an important pathway in the biotransformation of many drugs, xenobiotics, neurotransmitters, and steroid hormones. The thermostable (TS) form of phenol sulfotransferase (PST) preferentially catalyzes the sulfonation of “simple” planar phenols, and levels of activity of TS PST in human tissues are controlled by inheritance. Two different human liver TS PST cDNAs have been cloned that encode proteins with amino acid sequences that are 96% identical. We have determined the structure and chromosomal localization of the gene for one of these two cDNAs,STP2,as a step toward understanding molecular genetic mechanisms involved in the regulation of this enzyme activity in humans.STP2spans approximately 5.1 kb and contains nine exons that range in length from 74 to 347 bp. The locations of mostSTP2exon–intron splice junctions are identical to those of a gene for the thermolabile form of PST in humans,STM;a rat PST gene; a human estrogen ST (EST) gene,STE;and a guinea pig EST gene. The two initialSTP2exons, IA and IB, were identified by performing 5′-rapid amplification of cDNA ends with human liver cDNA as template. Exons IA and IB are noncoding and represent two different human liver TS PST cDNA 5′-untranslated region sequences. The two apparent 5′-flanking regions of theSTP2gene, regions flanking exons IA and IB, contain no canonical TATA boxes, but do contain CCAAT elements.STP2was localized to human chromosome 16 by performing the PCR with DNA from NIGMS human/rodent somatic cell hybrids as template. Structural characterization ofSTP2will make it possible to begin to study molecular genetic mechanisms involved in the regulation of TS PST activity in human tissue.     

Correlation between troglitazone cytotoxicity and drug metabolic enzyme activities in cryopreserved human hepatocytes

Troglitazone (TRO) was developed for the treatment of type II diabetes. It was withdrawn from use due to idiosyncratic liver damage and failure. The mechanism of toxicity is still not determined, moreover, it is still not clear whether toxicity is due to the parent compound or its metabolite(s). The cytotoxicity of TRO was evaluated in human hepatocytes using previously cryopreserved hepatocyte suspensions from 27 human donors. Cellular adenosine triphosphate content was used as a viability endpoint. To investigate the role of xenobiotic metabolism in TRO toxicity, the correlation between the drug metabolism activities of the hepatocytes from each donor to EC(50) values TRO cytotoxicity. The activities examined were cytochrome P450 (CYP) isoform activities (CYP2A6, CYP2D6, CYP2C19, CYP1A2, CYP2E1, CYP3A4 and CYP2C9) and phase 2 conjugation enzyme activities (phenol sulfotransferase (PST) and glucuronyl transferase (UGT)). Taken individually, none of the phase 1 or 2 enzyme activities correlated to the EC(50). However, when three enzyme activities ((CYP3A4 x UGT)/PST) were taken into account, a correlation was made (r(2)=0.53). Based on the correlation, we hypothesize that TRO and TRO sulfate are direct acting toxicants, whereas CYP3A4 oxidation and glucuronidation are detoxification pathways.     

Comparative electrophoretic characteristics of alkaline phosphatase isoforms in maternal blood and shaggy chorion extracts at various periods of pregnancy]

A comparative study of enzyme alkaline phosphatase (AP) of plasma and chorion placental extracts was made in various terms of pregnancy by PAAG electrophoresis. It is shown that the first three month chorion extract contained 1 thermolabile (TL) and 1 or 3 thermostable (TS) fractions of AP. In the second trimester of intrauterine development the activity of TL fraction disappeared, the number of TS forms increased. The early plasma period (6-12 weeks) was characterized by 2 TL non-placental forms, from the second half they added to 1 or 3 TS placental fractions, and before delivery TS enzyme appeared in the liver AP which had no analogue in the placenta. It is concluded that only the fastest placental TS AP forms (1 or 3) appear in maternal blood from the second trimester of gestation.     

Stereoselective sulfate conjugation of isoproterenol in humans: Comparison of hepatic,intestinal, and platelet activity

The stereochemistry of sulfate conjugation of isoproterenol (ISO) was examined with human liver, intestine, and platelets as the phenolsulfotransferase (PST) enzyme source and PAP³⁵S as the cosubstrate. With the hepatic cytosol, two distinct sulfation reactions were identified, a high affinity reaction (K_m 5 to 50 μM) and a low affinity reaction (K_m 360 to 2,900 μM). The efficiency of sulfation (V_max/K_m) for both reactions was 5-fold higher for (+)- than for (?)-ISO. When the hepatic PSTs were resolved by ionexchange chromatography, it could be shown that the high affinity reaction was catalyzed by the monoamine (M) form and the low affinity reaction by the phenol (P) form of PST. Only the high affinity (M form) sulfation was detected in the jejunal cytosol with a V_max/K_m value 6.1-fold higher for (+)- than for (?)-ISO. Finally the platelet, as a potentially useful model tissue, also demonstrated only the high affinity M form reaction with a V_max/K_m value 5.7-fold higher for (+)- than for (?)-ISO. In summary, this study has shown that sulfation of ISO by PSTs in various human tissues is stereoselective and favors the inactive (+)-enantiomer over the active (?)-enantiomer by about 5-fold, a finding which should be considered in the therapeutic use of chiral drugs cleared by sulfate conjugation. © 1993 Wiley-Liss, Inc.     

Does PAPS generation determine the overall sulfate conjugation in human platelets?

The formation of 3'-phospho-adenosine-5'phosphosulfate (PAPS) depends on essentially two enzymic reactions catalysed by ATP-sulfurylase and APS-kinase (adenosine 5'-phosphosulfate-kinase). In this paper, PAPS generation by human platelets was determined by the transfer of 35sulfate from PAP35S formed in vitro to N-acetyldopamine (NADA), using the phenolsulfotransferase extracted from rat liver. A pre-requisite of this quantitative procedure was the prior inhibition of the sulfate-activating system in the latter enzyme preparation. This was accomplished by the addition of 10 mM EDTA and 14 mM pyrophosphate. The PAPS-generating system of human platelets exhibited two pH peaks with higher activity at pH 8 than pH 6. Optimal concentrations of ATP and Mg++ at 7 mM were required for the two reactions. PAPS generation so measured showed a highly significant correlation with the overall sulfate conjugation of NADA: a correlation coefficient of 0.96 was established from data obtained from 60 platelet preparations of normal subjects.     

Evolutionary analysis of a novel zinc ribbon in the N-terminal region of threonine synthase

Threonine synthase (TS) catalyzes the terminal reaction in the biosynthetic pathway of threonine and requires pyridoxal phosphate as a cofactor. TSs share a common catalytic domain with other fold type II PALP dependent enzymes. TSs are broadly grouped into two classes based on their sequence, quaternary structure, and enzyme regulation. We report the presence of a novel zinc ribbon domain in the N-terminal region preceding the catalytic core in TS. The zinc ribbon domain is present in TSs belonging to both classes. Our sequence analysis reveals that archaeal TSs possess all zinc chelating residues to bind a metal ion that are lacking in the structurally characterized homologs. Phylogenetic analysis suggests that TSs with an N-terminal zinc ribbon likely represents the ancestral state of the enzyme while TSs without a zinc ribbon must have diverged later in specific lineages. The zinc ribbon and its N- and C-terminal extensions are important for enzyme stability, activity and regulation. It is likely that the zinc ribbon domain is involved in higher order oligomerization or mediating interactions with other biomolecules leading to formation of larger metabolic complexes.     

Immunohistochemical Detection of Phenol Sulfotransferase-Containing Neurons in Human Brain

Using antibodies raised against human platelet phenol sulfotransferase (PST), immunohistochemical studies were performed to determine the cellular localization of PST in several areas of human brain. In the hippocampus PST immunoreactivity was localized in both the pyramidal and nonpyramidal neurons and was in greatest abundance in the CA2 and CA3 areas. In the striatum the immunoreactivity was most predominant in the large neurons of the globus pallidus and in the medulla the staining was scattered throughout the neurons of the raphe nucleus and the reticular formation. The selective presence of PST in the neurons of the CNS raises the issue as to the role of this enzyme in sulfating neurotransmitters because PST has been shown to be capable of conjugating a variety of neurotransmitters including the catecholamines as well as the tyrosine moiety of a number of small peptides such as enkephalin and cholecystokinin.     

Human erythrocyte catechol-O-methyltransferase: correlation with lung and kidney activity

Catechol-O-methyltransferase (COMT) activity measured in homogenates of human lung or renal cortical tissue was approximately an order of magnitude greater than the enzyme activity in human erythrocytes. Lung and blood enzyme activities varied from individual to individual over a 5–7 fold range. There was a highly significant correlation between the COMT activity in erythrocytes and the enzyme activity in lung (r = 0.59, P < .001, N = 29) and kidney (r = 0.81, P < .005, N = 12) of the same subjects. These results suggest that the relative COMT activity in lung and kidney might be predicted by the measurement of the enzyme activity in blood and raise the possibility that individual variation in the metabolism of endogenous catecholamines and catechol drugs in man may result in part from variations in COMT activity.     

Mechanism of posttranslational regulation of phenol sulfotransferase: expression of two enzyme forms through redox modification and nucleotide binding

Sulfotransferase catalyzes sulfuryl group transfer between a nucleotide and a variety of nucleophiles that may be sugar, protein, xenobiotics, and other small molecules. Nucleotides may serve as cosubstrate, cofactor, inhibitor, or regulator in an enzyme catalyzed sulfuryl group transfer reaction. We are trying to understand how nucleotide regulates the activity of phenol sulfotransferase (PST) through the expression of two enzyme forms. The homogeneous rat recombinant PST was obtained from Escherichia coli, and the nucleotide copurified was examined. The nucleotide was completely removed from inactive PST in high salt and oxidative condition. Total enzyme activity was recovered following incubation in reductive environment. Many nucleotides are known to tightly bind to PST but only one nucleotide, 3'-phosphoadenosine 5'-phosphate (PAP), was identified to combine with PST by ion-pair RP-HPLC, UV-visible spectra, (31)P NMR, and ESI-MS and MS-MS spectrometry. In addition to the presence or absence of PAP, oxidation following reduction of PST was required to completely interconvert the two forms of PST. According to the experimental results, a mechanism for the formation of the two enzyme forms was proposed.     

Damaging effects of Clostridium perfringens delta toxin on blood platelets and their relevance to ganglioside GM2

The lytic effect of Clostridium perfringens delta toxin was investigated on goat, human, rabbit, and guinea pig platelets. In contrast to erythrocytes from the latter three species, which are insensitive to the toxin, the platelets were equally lysed by the same amount of toxin. These results suggest the presence of GM2 or GM2-like ganglioside(s) as a specific recognition site of the toxin on platelet plasmic membrane as previously established for sensitive erythrocytes. Plasmic membrane damage of human platelets was evidenced by the release of entrapped alpha-[14C]aminoisobutyric acid used as a cytoplasmic marker. The specific binding of hemolytically active 125I-delta toxin by human and rabbit platelets was practically identical, dose dependent, and inhibitable by GM2. Labeled toxin was also bound by various subcellular organelles separated from rabbit platelets except the 5-hydroxytryptamine (5-HT)-containing dense bodies, suggesting the absence or inaccessibility of GM2 on the surface of the latter organelles. This result correlates with the low amounts of 5-[3H]HT liberated after platelet challenge with delta toxin whereas this mediator was massively liberated upon lysis by the sulfhydryl-activated toxin alveolysin. The levels of M and P forms of phenol sulfotransferase (PST), involved in 5-HT catabolism, were determined in human platelet lysates after challenge with delta toxin, alveolysin, and other disruptive treatments. The low PST-M activities detected after lysis by delta toxin suggest that this isoenzyme is very likely associated to dense bodies in contrast to PST-P which is cytoplasmic. Platelet lysis by the toxin allows easy separation of these organelles.     

Platelet oxygen consumption as a peripheral blood marker of brain energetics in a mouse model of severe neurotoxicity

Interactions of chemicals with cerebral cellular systems are often accompanied by similar changes involving components in non-neural tissues. On this basis, indirect strategies have been developed to investigate neural cell function parameters by methods using accessible cells, including platelets and/or peripheral blood lymphocytes. Therefore, here it was investigated whether peripheral blood markers may be useful for assessing the central toxic effects of methylmercury (MeHg). For this purpose, we investigated platelet mitochondrial physiology in a well-established mouse model of MeHg-induced neurotoxicity, and correlated this peripheral activity with behavioural and central biochemical parameters. In order to characterize the cortical toxicity induced by MeHg (20 and 40 mg/L in drinking water, 21 days), the behavioral parameter namely, short-term object recognition, and the central mitochondrial impairment assessed by measuring respiratory complexes I-IV enzyme activities were determined in MeHg-poisoned animals. Neurotoxicity induced by MeHg exposure provoked compromised cortical activity (memory impairment) and reduced NADH dehydrogenase, complex II and II-III activities in the cerebral cortex. These alterations correlated with impaired systemic platelet oxygen consumption of intoxicated mice, which was characterized by reduced electron transfer activity and uncoupled mitochondria. The data brought here demonstrated that impaired systemic platelet oxygen consumption is a sensitive and non-invasive marker of the brain energy deficits induced by MeHg poisoning. Finally, brain and platelets biochemical alterations significantly correlated with cognitive behavior in poisoned mice. Therefore, it could be proposed the use of platelet oxygen consumption as a peripheral blood marker of brain function in a mouse model MeHg-induced neurotoxicity.     

Multiple forms of monoamine oxidase in rabbit platelets.

Rabbit platelets were found to contain both types A and B MAO activities. The specific enzymatic activity of rabbit platelet MAO was higher for the substrate serotonin than for phenylethylamine. The K_m's for rabbit platelet MAO indicated that the MAO-B enzyme was similar to human platelet MAO and that both MAO-A and MAO-B enzymes in the rabbit platelet are similar to the corresponding forms in the rabbit brain. The drugs clorgyline and deprenyl confirmed the existence of types A and B MAO in the platelet and furthermore indicated that the type A form accounted for approximately 90% of the total enzymatic activity. Amitriptyline at low (micromolar) concentrations selectively inhibited MAO-B activity in both rabbit platelets and brain.     

Human Platelet Phenol Sulfotransferase: Partial Purification and Detection of Two Forms of the Enzyme

To begin to study the usefulness of platelet phenol sulfotransferase (PST) as a possible measure of the enzyme activity in other organs such as the brain, we purified human platelet PST 36-120-fold. Activity toward 3-methoxy-4-hydroxyphenylglycol (MHPG), dopamine, 5-hydroxytryptamine (5-HT), and phenol eluted in the same Sephadex G-100 and Affi-Gel Blue column fractions. Specific activities of the enzyme with MHPG, dopamine, 5-HT, and phenol as substrates were 1198, 1068, 401, and 408 units/mg protein, respectively. Optimal assay conditions were established for each substrate. Apparent Km values were 598 microM, 21 microM, 19 microM, and 500 microM for MHPG, dopamine, phenol, and 5-HT, respectively. Apparent Km values for 3'-phosphoadenosine-5'-phosphosulfate (PAPS) with the same four substrates ranged from 0.11 to 0.25 microM. The pH optima were 6.3 for phenol, 6.8 for dopamine, and 7.0 for MHPG and 5-HT. An additional pH optimum at 8.6 was present for 5-HT. A thermolabile form of the enzyme measured with dopamine and 5-HT, as well as a thermostable form measured with phenol, were present. Dichloronitrophenol (10(-5) M) noncompetitively inhibited the thermostable enzyme activity by 96% but decreased the thermolabile activity by only 36%. These studies provide the basis for a more accurate comparison of human platelet PST with the enzyme in the human brain and in other tissues.     

Purification and kinetic characterization of a phenol-sulfating form of phenol sulfotransferase from human brain

The identification of three forms of phenol sulfotransferase (PST) in human brain and the subsequent purification and kinetic characterization of a phenol-sulfating form of the enzyme are described. Two forms of PST which were capable of conjugating phenol and a third form which sulfated dopamine were resolved from one another using DEAE-cellulose chromatography. One of the phenol-sulfating forms (P1-PST) was subsequently purified on Affi-Gel blue and Sephacryl S-200, giving a final purification of almost 390-fold, with an overall yield of approximately 5%. The purified enzyme was sensitive to NaCl and showed an optimum for phenol conjugation at pH 8.5. Kinetic analysis demonstrated that sulfation by P1-PST proceeds via a sequential ordered, bi-substrate reaction mechanism, where 3'-phosphoadenosine-5'-phosphosulfate (PAPS) is the leading substrate. The true Km and Kia values for PAPS were both 0.35 microM, while the true Km value for phenol was 2.8 microM.