Efficient synthesis of α-fluoromethylhistidine di-hydrochloride and demonstration of its efficacy as a glutathione S-transferase inhibitor

Histidine decarboxylase (HDC) is an enzyme that converts histidine to histamine. Inhibition of HDC has several medical applications, and HDC inhibitors are of considerable interest for the study of histidine metabolism. (S)-α-Fluoromethylhistidine di-hydrochloride (α-FMH) is a potent HDC inhibitor that is commercially available at high cost in small amounts only. Here we report a novel, inexpensive, and efficient method for synthesis of α-FMH using methyl 2-aziridinyl-3-(N-triphenylmethyl-4-imidazolyl) propionate and HF/pyridine, with experimental yield of 57%. To identify novel targets for α-FMH, we developed a three step in silico work-flow for identifying physically plausible protein targets. The work-flow resulted in 21 protein target hits, including several enzymes involved in glutathione metabolism, and notably, two isozymes of the glutathione S-transferase (GST) superfamily, which plays a central role in drug metabolism. In view of this predictive data, the efficacy of α-FMH as a GST inhibitor was investigated in vitro. α-FMH was demonstrated to be an effective inhibitor of GST at micromolar concentration, suggesting that off-target effects of α-FMH may limit physiological drug metabolism and elimination by GST-dependent mechanisms. The present study therefore provides new avenues for obtaining α-FMH and for studying its biochemical effects, with potential implications for drug development.     

Histamine formation in rat brain in vivo: effects of histidine loads

Abstract— Administration of l -histidine at the rate of 500 mg/kg induced an increase of nearly 50 per cent in the level of histamine in rat brain which lasted several hours. The augmentation of histamine level was not significant 3 h after lower doses or after d -histidine α-methyl DOPA and Ro 4-4602 neither affected the cerebral level of histamine nor its elevation induced by l -histidine. Brocresine, a known histidine decarboxylase inhibitor not only prevented the effect of histidine load but also induced a prompt fall in the amine level. These results confirm those from earlier experiments in vitro indicating that histamine synthesis in rat brain depends on a specific decarboxylase (EC 4 , 1.1.22) which is not normally saturated by the endogenous level of its substrate. When histamine levels were enhanced by histidine treatment, histidine decarboxylase activity, as evaluated on hypothalamus homogenates, was significantly reduced; intracisternal administration of cycloheximide, an inhibitor of protein synthesis, had similar effects. On the other hand, enzyme activity was not altered by the addition of histamine to hypothalamus homogenates. These results are compatible with the existence of a regulation mechanism of histidine decarboxylase involving repression by its end-product.     

Preimplantation embryo development in the mouse: Role of histidine decarboxylase

The present study determines the effect of a specific and an irreversible inhibitor of histidine decarboxylase (HDC), α-fluoromethylhistidine (α-FMH) on the mouse preimplantation embryo development in vitro. The embryo culture technique was used to assess the effect of α-FMH. Embryos recovered at 0800–0900 hr (AM) on day 3 of pregnancy were 4–8 cells, whereas those recovered at 1600–1630 hr were mostly 8-cell compacted embryos. Of the day 3-AM embryos, 81.3 ± 4.3% developed to blastocysts within 48 hr when cultured in the medium alone, but addition of α-FMH (0.19 or 0.38 mM) drastically reduced the blastocyst formation to 26.6 ± 7 or 16.8 ± 4.3%. Most of them were arrested before the compaction stage. Addition of L-histidine, the substrate for HDC, did not alter the inhibition of blastocyst formation in the presence of α-FMH (37.2 ± 10.9%). Of the day 3-PM embryos, 99.3 ± 0.7% developed to blastocyst stage when cultured in the medium alone and addition of α-FMH (0.19 or 0.38 mM) did not affect the embryo development (92.1 ± 4.3 or 81.9 ± 9.9% developed to blastocysts). The birth of healthy young following transfer of these blastocysts into pseudopregnant mice indicates normal development of the embryos under this condition. The results suggest that histamine synthesis may be required for the process of compaction and thus the formation of blastocyst.     

THE SUBCELLULAR LOCALIZATION OF HISTIDINE DECARBOXYLASE IN VARIOUS REGIONS OF RAT BRAIN

Abstract— The subcellular distribution of histidine decarboxylase (assayed by two different isotopic methods) and several biochemical markers (lactate dehydrogenase, DOPA decarboxylase and protein) was determined in rat cerebral cortex. After differential centrifugation, the enzyme activity was found mainly in the crude mitochondrial and soluble fractions. Further separation of the former on discontinuous sucrose gradients showed that the particulate histidine decarboxylase (HD) was found in the synaptosomal fraction. After osmotic shock, HD activity appeared in the supernatant fraction suggesting that a major portion of the enzyme is localized in the cytoplasm of cortical nerve endings. By analogy with other brain amines, this finding, together with the presence of histamine in synaptic vesicles (K ataoka and de R obertis , 1967), can be taken as further support for the hypothesis of a role as neurotransmitter for histamine.
Various brain regions were homogenized under conditions leading to synaptosome formation. The distribution of HD between 'particulate' and soluble fractions differed from one region to the other, but did not give any clear-cut indication of regions rich in cell bodies or nerve terminals.     

Effects of α-fluoromethylhistidine (FMH), an irreversible inhibitor of histidine decarboxylase,on development of brain histamine and catecholamine systems in the neonatal rat

Daily administration of FMH to neonatal rats produced long-lasting inhibition of histidine decarboxylase in hypothalamus and cerebral cortex and led to depletion of histamine in both brain regions. The onset of depletion was more rapid in cerebral cortex, a region in which non-neurotransmitter pools of histamine predominate in early postnatal life, appearing as early as postnatal day 3; depletion in the hypothalamus, a region rich in histaminergic neuronal projections, appeared later. No effects were seen on body or brain growth, nor was development of other biogenic amine systems affected. FMH thus provides a selective probe for examining the role of histamine in brain development.     

l-Histidine Decarboxylase in the Human Brain: Properties and Localization

The properties of the histamine-forming enzyme in human brain samples were studied utilizing a radiochromatographic procedure. The influence of postmortem conditions was checked with rat brains, and the results indicated that the enzyme activity is not altered in situ for a delay not exceeding 4 h at ambient temperature. Moreover, tissue blocks or homogenates can be stored at low temperatures for up to 3 months with a good preservation of the enzyme activity. The data indicate that histamine synthesis in the human brain involves the ?specific” histidine decarboxylase (HD, EC 4.1.1.22) and not the aromatic l -amino acid decarboxylase; (1) the optimum pH is 7.4 at 10^-6m-l -histidine; (2) the apparent K_m is about 3.10^-5m ; (3) it is inhibited by α-hydrazino histidine and brocresine but not affected by α-methyl DOPA. Moreover, a major portion of the enzyme is localized in a subcellular fraction containing nerve terminals and it shows an uneven regional distribution which parallels that observed in the brain of other mammalian species. Taken together these data strongly suggest that histamine could play a neurotransmitter role in the human brain.     

Brain α-Ketoglutarate Dehydrotenase Complex Activity in Alzheimer's Disease

We measured the activity of the a-ketoglutarate dehydrogenase complex (α-KGDHC), a rate-limiting Krebs cycle enzyme, in postmortem brain samples from 38 controls and 30 neuropathologically confirmed Alzheimer's disease (AD) cases, in both the presence and absence of thiamine pyrophosphate (TPP), the enzyme's cofactor. Statistically significant correlations between brain pH and lactate levels and α-KGDHC activity in the controls were observed, suggesting an influence of agonal status on the activity of α-KGDHC. As compared with the controls, mean α-KGDHC activity, with added TPP, was significantly (p < 0.005) reduced in AD brain in frontal (-56%), temporal (-60%), and parietal (-68%) cortices, with the reductions (-25 to -53%) in the occipital cortex, hippocampus, amygdala, and caudate failing to reach statistical significance. In the absence of exogenously administered TPP, mean a-KGDHC activity was reduced to a slightly greater extent in all seven AD brain areas (-39 to -83%), with the reductions now reaching statistical significance in the four cerebral cortical areas and hippocampus. A statistically significant negative correlation was observed between α-KGDHC activity and neurofibrillary tangle count in AD parietal cortex, the brain area exhibiting the most marked reduction in enzyme activity; this suggests that the enzyme activity reduction in AD brain may be related to the disease process and severity. In each brain area examined, TPP produced a greater stimulatory effect on α-KGDHC activity in the AD group (23–280% mean stimulation) as compared with the controls (-4 to ±50%); this TPP effect could be explained by reduced endogenous TPP levels in AD brain. Reduced brain α-KGDHC activity could be consequent to loss of neurons preferentially enriched in α-KGDHC, a premortem reduction in TPP levels (which may have affected enzyme stability), elevated brain levels of the α-KGDHC inhibitor ammonia, or an actual failure in the expression of the gene encoding the enzyme. We suggest that a defect in this key Krebs cycle enzyme could contribute to an impairment of cerebral energy metabolism and the brain dysfunction in AD.     

Postnatal ontogeny of uridine kinase in the cerebellum,hypothalamus, and cerebral cortex of the rat

Postnatal developmental patterns of uridine kinase were determined in crude subcellular fractions of the rat cerebellum, hypothalamus and cerebral cortex at ages 3 through 60 days. The highest specific activity and predominant distribution of enzyme was in the 105,000g supernatant of the 3 brain regions. Enzyme activity in hypothalamus and cerebral cortex was maximum at 3 days and decreased with age; in cerebellum it increased through 13 days and decreased thereafter. Thus, the pattern of activity in hypothalamus and cerebral cortex paralleled changes in DNA and RNA synthesis through age 60 days; in cerebellum, it more closely approximated changes in DNA synthesis during early development. Changes inK _m with aging suggest that the brain regions contain more than one form of enzyme. The highest particulate activity was in the microsomal fraction of the cerebellum and hypothalamus at all ages and in the cortex at 35 and 60 days. Relative specific activity for microsomal fractions of the brain regions at 60 days indicate a concentration of the enzyme which may be relevant in the maintenance of RNA activity in adult brain.     

Partial characterization of histidine decarboxylase in hamster and rat brain employing a new method

Histidine decarboxylase activity in hamster and rat brains were studied using a newly developed sensitive, direct radioenzymatic microassay. For our assay conditions, we determined aK _m forl-histidine of 320 M and aV _max for histidine decarboxylase of 110 pmol histamine/hr/mg protein in rat hypothalamus. The regional distributions of both histidine decarboxylase and histamine levels were similar in the hamster and rat with the most activity in hypothalamus. Most of the histidine decarboxylase activity in rat hypothalamus was in the cytosol fraction. The developmental pattern of histidine decarboxylase in the fetal rat did not reveal a prenatal spike in activity. Histidine decarboxylase activity in rat brain reached adult levels by four weeks. Alpha-fluoromethylhistidine inhibited histidine decarboxylase activity almost totally in vitro at 10 M and about 80% in vivo after six days of infusion (100mg/kg/day) in all brain regions except the cerebellum. Likewise, histamine levels were depleted about 75% in all brain regions except the cerebellum.     

PROPERTIES AND REGIONAL DISTRIBUTION OF HISTIDINE DECARBOXYLASE IN RAT BRAIN

—Properties of the histamine-forming enzyme in rat brain were studied, utilizing a sensitive fluorometric assay. The optimum pH was related to substrate concentration and found to be6·4 at 10^?2m -histidine; the apparent Km was about 4·10^?4m ; enzyme activity was inhibited by α-hydrazino -histidine and brocresine but was not affected by α-methyl DOPA or benzene. These different data suggest that the 'specific’histidine decarboxylase (EC 4.1.1.22)—and not the aromatic l -aminoacid decarboxylase—is involved. Determination of enzyme activity and histamine level in different areas of the rat brain revealed important regional differences, the two values being roughly parallel.     

The effects of adrenalectomy and thermal stress on glutamic acid decarboxylase activity in different regions of the rat brain

Glutamic acid decarboxylase (GAD) enzyme activity was measured in synaptosomes prepared from the hypothalamus, the hippocampus, the striatum and the cerebral cortex of control, adrenalectomized and rat exposed to a thermal stress. Adrenalectomy caused a statistically significant decrease in the enzyme activity in the striatum, while it had no effect in the other three brain areas. On the other hand, exposure to the thermal stress resulted in a dramatic increase of GAD specific activity in all brain areas examined. This thermal stress-induced increase in enzyme activity was observed in both non-operated and adrenalectomized animals, which implies that it is not mediated by glucocorticoids.Abbreviations used GAD glutamic acid decarboxylase - GABA -aminobutyric acid - AET 2-aminoethylisourethonium bromide - ADX adrenalectomized - rpm revolutions per minute     

The influence of alpha-fluoromethylhistidine on the regional brain histamine and plasma corticosterone levels in aging

alpha-Fluoromethylhistidine, a histidine decarboxylase inhibitor, induced a significant depletion in the hypothalamic, midbrain, and cortical brain histamine amounts in 12- and 3-month-old rats. In all three brain regions the most evident depletion occurred 2 h after treatment. In both groups of rats midbrain histamine levels returned to control values 6 h after treatment; however, hypothalamic histamine depletion was still significant and more evident in the old than in the young animals. Cortical brain histamine also remained significantly depleted in old rats, but returned to control values in young animals 6 h after alpha-fluoromethylhistidine treatment. These results suggest that old rats show a slower rate of new histamine synthesis in the cortex and hypothalamus. Regional brain histamine depletion was associated with a very significant decrease in plasma corticosterone levels, which indicates that brain histamine-corticosterone interactions do occur.     

Blood brain barrier breakdown in brain edema following cold injury is mediated by microvascular polyamines

A focal freeze injury to rat cerebral cortex induces an early (less than 5 min) increase in brain ornithine decarboxylase activity and an accumulation of polyamines involving cerebral microvessels. This polyamine synthesis correlates with the abnormal increase in microvascular permeability, monitored by uptake of Evans Blue and sod. fluorescein. The ornithine decarboxylase inhibitor alpha-difluoromethylornithine suppressed the injury-induced increment in spermidine and spermine and microvascular permeability. Putrescine nullified alpha-difluoromethylornithine inhibition and restored microvessel spermidine and spermine and the pathological increase in microvascular permeability. These results indicate that polyamine synthesis is obligatory for blood-brain barrier breakdown. alpha-Difluoromethylornithine may be useful in the treatment of vasogenic brain edema.     

Short-term effect of stress on tyrosine hydroxylase activity

The short-term influences of stress on the activities of tyrosine hydroxylase in vivo and in vitro were examined in mice. The in vivo tyrosine hydroxylase activity was estimated by the rate of dopa accumulation which was measured at 30 min after the injection of NSD-1015 (100 mg kg), an aromatic l-amino acid decarboxylase inhibitor, intraperitoneally and was compared with tyrosine hydroxylase activity measured in vitro. For the in vivo assay, both the accumulation of dopa (tyrosine hydroxylase activity) and that of 5-hydroxytryptophan (tryptophan hydroxylase activity) and the levels of monoamines and the metabolites (noradrenalin, adrenalin, dopamine, normetanephrine, 3-methoxytyramine and serotonin) and those of precursor amino acids, tyrosine and tryptophan, were investigated in ten different brain regions and in adrenals. The amount of dopa accumulation in the brain as a consequence of decarboxylase inhibition, in vivo tyrosine hydroxylase activity, was significantly increased by stress, in nerve terminals (striatum, limbic brain, hypothalamus, cerebral cortex and cerebellum) and also in adrenals. The effect of stress on tyrosine hydroxylase activity in vitro at a subsaturating concentration of 6-methyltetrahydropterin cofactor was also observed in nerve terminals (striatum, limbic brain, hypothalamus, and cerebral cortex). The amount of 5-hydroxytryptophan accumulation, the in vivo tryptophan hydroxylase activity, was also significantly increased in bulbus olfactorius, limbic brain, cerebral cortex, septum and lower brain stem. The influence of stress was also observed on the levels of precursor amino acids, tyrosine and tryptophan and monoamines in specific brain parts. These results suggest that the stress influences both catecholaminergic neurons and serotonergic neurons in nerve terminals in the brain. This effect was also observed on tyrosine hydroxylase activity in vitro in nerve terminals. However, in adrenals, the influence by stress was not observed on the in vitro activity, although dopa accumulation was increased.     

Inhibition of brain glutamate decarboxylase by 2-keto-4-pentenoic acid, a metabolite of allylglycine.

Abstract— 2-Keto-4-pentenoic acid, a potent inhibitor of brain glutamate decarboxylase (Orlowski et al., 1977) was prepared by oxidative deamination of l -allylglycine with snake venom l -amino acid oxidase. In the presence of glutamate the keto acid is a competitive inhibitor of the enzyme with respect to glutamate; its K_i is 2.4 ± 10^?6m . After preincubation of brain glutamate decarboxylase with 2-keto-4-pentenoic acid in the absence of glutamate, a slow and incomplete reactivation is obtained by prolonged dialysis, Sephadex gel-filtration, and dilution, suggesting the formation of a slowly dissociating enzyme-inhibitor complex and partial inactivation of the enzyme. In vivo inhibition of brain glutamate decarboxylase after administration of allylglycine is maximal after 2-8 h with activity returning to normal after 16 h. The inhibition of the enzyme after administration of d -allylglycine was greatest in the cerebellum and the medulla-pons area, the sites of the highest activity of d -amino acid oxidase. These results are interpreted as strongly supporting the postulate that allylglycine-induced inhibition of brain glutamate decarboxylase is due to the in vivo formation of 2-keto-4-pentenoic acid.     

OCCURRENCE AND DISTRIBUTION OF AROMATIC l-AMINO ACID (l-DOPA) DECARBOXYLASE IN THE HUMAN BRAIN

—The enzymatic decarboxylation of l -DOPA was measured in isotonic dextrose homogenates of different regions of the human brain by estimating ¹⁴CO₂ evolved from tracer amounts of d l -DOPA[carboxy1-¹⁴C]. Enzyme activity was linear with respect to tissue concentration and time of incubation. The reaction exhibited a pH maximum at 7·0, was completely dependent upon the presence of high concentrations of pyridoxal phosphate, proceeded at the same rate in an atmosphere of air and nitrogen, and produced dopamine in addition to CO₂ as a reaction product. The enzyme preparation behaved like an aromatic l -amino acid decarboxylase: it also decarboxylated o-tyrosine and when incubated with 5-hydroxytryptophan, serotonin was isolated as the reaction product; but it was devoid of activity towards d -DOPA[carboxy1-¹⁴C]. Within the human brain, l -DOPA decarboxylase was most active in the putamen and caudate nucleus; the pineal gland, hypothalamus, and the reticular formation and dorsal raphe areas of the mesencephalon exhibited considerable activity. Areas of cerebral cortex exhibited very low enzymatic activity and in regions composed predominantly of white matter, l -DOPA decarboxylase activity was not significantly above blank values. The activity of l -DOPA decarboxylase in the human putamen and caudate nucleus tended to decrease with the age of the patients; in comparatively young subjects (46 yr old) the enzyme activity compared favourably with that found, by means of the same assay technique, in the caudate nucleus of the cat.     

Brain Histaminergic System in Mast Cell-Deficient (Ws/Ws) Rats: Histamine Content, Histidine Decarboxylase Activity, and Effects of (S)α-Fluoromethylhistidine

Abstract: The mast cell-deficient [ Ws/Ws ( W hite spotting in the skin)] rat was investigated with regard to the origin of histamine in the brain. No mast cells were detected in the pia mater and the perivascular region of the thalamus of Ws/Ws rats by Alcian Blue staining. The histamine contents and histidine decarboxylase (HDC) activities of various brain regions of Ws/Ws rats were similar to those of +/+ rats except the histamine contents of the cerebral cortex and cerebellum. As the cerebral cortex and cerebellum have meninges that are difficult to remove completely, the histamine contents of these two regions may be different between Ws/Ws and +/+ rats. We assume that the histamine content of whole brain with meninges in Ws/Ws rats is <60% of that in +/+ rats. So we conclude that approximately half of the histamine content of rat brain is derived from mast cells. Next, the effects of ( S )α-fluoromethylhistidine (FMH), a specific inhibitor of HDC, on the histamine contents and HDC activities of various regions of the brain were examined in Ws/Ws rats. In the whole brain of Ws/Ws rats, 51 and 37% of the histamine content of the control group remained 2 and 6 h, respectively, after FMH administration (100 mg/kg of body weight). Therefore, we suggest that there might be other histamine pools including histaminergic neurons in rat brain.     

Developmental changes in choline acetyltransferase and glutamate decarboxylase activity in various regions of the brain of the male,female, and neonatally androgenized female rat

In an attempt to discern effects of sex hormones on the development of neurotransmitter systems in the rat brain, choline acetyltransferase (ChAT) and glutamate decarboxylase (GAD) have been measured at postnatal days 8, 12, 25, and 60 in five regions (amygdala, anterior hypothalamus, hippocampus, olfactory bulbs, and cerebral cortex) of the brains of normal male, normal female, and neonatally androgen-treated female rats. Essentially no associations between sex or of neonatal androgenization on either enzyme were found. The data, however, provide new information on the relative rates of development of ChAT and GAD in five regions of the rat brain which supplement the limited information already available in the literature. ChAT activity was highest in amygdala and hypothalamus, but developed most rapidly in hippocampus and cerebral cortex. The relative activities and patterns of development of GAD activity were similar to those of ChAT.     

Biosynthesis of brain 2-phenylethylamine: influence of decarboxylase inhibitors and D-amphetamine

2-Phenylethylamine (PEA) is an endogenous brain amine which probably modulates affective behavior. Using a gas-liquid chromatographic method for the quantification of PEA (as its dinitrophenyl-sulfonic acid derivative), we found in rabbits 340.9 ± 45.8 ng of PEA/g of wet brain. Brain PEA levels were markedly decreased by the ip administration of 200 mg/Kg, 4 hrs before sacrifice, of the L-aromatic amino acid decarboxylase inhibitors α-methyldopa (28.2 ± 5.1 ng/g), L-α-methyldopa hydrazine (MK-486 [66.9 ± 13.0 ng/g]) or a combination of both (30.0 ± 3.3 ng/g). Since MK-486 inhibits only peripheral decarboxylase, brain PEA must be in part of peripheral origin. Another decarboxylase inhibitor, RO 4-4602 mg/Kg, 4 hrs before sacrifice) failed to affect brain PEA content. D-amphetamine (10 mg/Kg) induced a small depletion of PEA after 30 min in untreated animals; when given in combination with RO 4-4602, brain PEA content was markedly decreased. This supports the view that amphetamine releases PEA and stimulates its synthesis.     

Modulation in Acetylcholinesterase of Rat Brain by Pyrethroids In Vivo and an In Vitro Kinetic Study

Abstract: The modulation in acetylcholinesterase (AChE) of rat brain by two pyrethroids—permethrin (PM) and cypermethrin (CPM)—was studied both in vivo and in vitro. PM inhibited AChE activity in all regions of the rat brain (cerebral cortex, cerebellum, corpora striata, brainstem, hippocampus, and hypothalamus) at 4, 8, and 12 h after gastric intubation, whereas CPM elevated the enzyme activity in vivo. Substrate-dependent enzyme kinetic studies have shown that PM and CPM behave as mixed-type inhibitors, as evidenced by alterations in both Michaelis-Menten constant ( K _m) and maximal velocity ( V _max) values. This indicates that both PM and CPM and substrate acetylcholine interact at hydrophobic subsites and may be able to bind simultaneously to the enzyme.