Detection of Cystathionine Ketimine and Lanthionine Ketimine in Human Brain

The sulfur containing imino acids cystathionine ketimine (CK) and lanthionine ketimine (LK) have been detected in the human brain by an HPLC procedure. The HPLC procedure takes advantage of the selective absorbance at 380 nm of the phenylisothiocyanate-ketimine adduct. Quantitation of cystathionine ketimine and lanthionine ketimine indicates a mean concentration (mean ± SD, n = 4) of 2.3 ± 0.8 nmol/g for CK and of 1.1 ± 0.3 nmol/g for LK in four human cerebral cortex samples of neurosurgical source. The identification of these cyclic ketimine derivatives of L-cystathionine and L-lanthionine as normal human metabolites in human nervous tissue may have interesting metabolic and physiological implications.     

Detection of Cystathionine Ketimine in Bovine Cerebellum

A new sulfur-containing cyclic imino acid, cystathionine ketimine, has been detected in bovine cerebellum by gas chromatography, gas chromatography-mass spectrometry, and high pressure liquid chromatography procedures. Gas chromatography and gas-mass analyses are based on derivatization of endogenous cystathionine ketimine with diazomethane after a simple enrichment procedure. The high pressure liquid chromatography procedure takes advantage of the selective absorbance at 380 nm of the phenyl isothiocyanate-ketimine interaction product. The concentration of this new sulfur imino acid found in a pool of four bovine cerebella is approximately 0.5 nmol/g.     

35S]Lanthionine ketimine binding to bovine brain membranes

2H-1,4-Thiazine-5,6-dihydro-3,5-dicarboxylic acid (trivial name: lanthionine ketimine) is a cyclic sulfur-containing imino acid detected in bovine brain extracts. This compound has been synthesized in a heavily labeled form starting from L-[35S]cysteine and purified by high performance liquid chromatography. We demonstrate the existence of a saturable and reversible binding of [35S]lanthionine ketimine to bovine brain membranes. A single population of binding sites with a concentration of 260 +/- 12 fmol/mg protein and a dissociation constant of 58 +/- 14 nM is present. Specific binding is competitively inhibited by other structurally similar imino acids, namely S-aminoethyl-L-cysteine ketimine and cystathionine ketimine. These results suggest a possible functional role for these ketimines in nervous system.     

Alternative functions of the brain transsulfuration pathway represent an underappreciated aspect of brain redox biochemistry with significant potential for therapeutic engagement

Scientific appreciation for the subtlety of brain sulfur chemistry has lagged, despite understanding that the brain must maintain high glutathione (GSH) to protect against oxidative stress in tissue that has both a high rate of oxidative respiration and a high content of oxidation-prone polyunsaturated fatty acids. In fact, the brain was long thought to lack a complete transsulfuration pathway (TSP) for cysteine synthesis. It is now clear that not only does the brain possess a functional TSP, but brain TSP enzymes catalyze a rich array of alternative reactions that generate novel species including the gasotransmitter hydrogen sulfide (H₂S) and the atypical amino acid lanthionine (Lan). Moreover, TSP intermediates can be converted to unusual cyclic ketimines via transamination. Cell-penetrating derivatives of one such compound, lanthionine ketimine (LK), have potent antioxidant, neuroprotective, neurotrophic, and antineuroinflammatory actions and mitigate diverse neurodegenerative conditions in preclinical rodent models. This review will explore the source and function of alternative TSP products, and lanthionine-derived metabolites in particular. The known biological origins of lanthionine and its ketimine metabolite will be described in detail and placed in context with recent discoveries of a GSH- and LK-binding brain protein called LanCL1 that is proving essential for neuronal antioxidant defense; and a related LanCL2 homolog now implicated in immune sensing and cell fate determinations. The review will explore possible endogenous functions of lanthionine metabolites and will discuss the therapeutic potential of lanthionine ketimine derivatives for mitigating diverse neurological conditions including Alzheimer׳s disease, stroke, motor neuron disease, and glioma.     

Sulfur-containing cyclic ketimines and imino acids. A novel family of endogenous products in the search for a role.

Aminoethylcysteine, lanthionine, cystathionine and cystine are mono-deaminated either by L-amino-acid oxidase or by a transaminase exhibiting the properties described for glutamine transaminase. The deaminated products cyclize producing the respective ketimines. Authentic samples of each ketimine were prepared by reacting the appropriate aminothiol compound with bromopyruvate, except cystine ketimine which required the interaction of thiopyruvate with cystine sulfoxide. Reduction of the first three mentioned ketimines with NaBH4 yields the respective derivatives with the saturated rings of thiomorpholine and hexahydrothiazepine. The same reduction is carried out enzymically by a reductase extracted from mammalian tissues. Properties of the members of this family of compounds are described. Gas chromatography followed by mass spectrometry permits the identification of most of these products. HPLC is very useful for the determination of the ketimines by taking advantage of specific absorbance at 380 nm obtained by prior derivatization with phenylisothiocyanate. Adaptation of these and other analytical procedures to biological samples disclosed the presence of most of these compounds in bovine brain and in human urine. By using [35S]lanthionine ketimine as a representative member of the ketimine group, the specific, high-affinity, saturable and reversible binding to bovine brain membranes has been demonstrated. The binding is removed by aminoethylcysteine ketimine and by cystathionine ketimine indicating the occurrence in bovine brain of a common binding site for ketimines. The reduced ketimines are totally ineffective in competing with [35S]lanthionine ketimine. Alltogether these findings are highly indicative for the existence in mammals of a novel class of endogenous sulfur-containing cyclic products provided with a possible neurochemical function to be investigated further.     

Detection of cystathionine and lanthionine ketimines in human urine

A recently developed HPLC procedure for the determination of cystathionine ketimine (CK) and lanthionine ketimine (LK) has been applied to the detection of these compounds in human urine. The assay has taken advantage of the selective production of an absorbance at 380 nm, not seen with other amino acids, when the two ketimines are reacted with phenylisothiocyanate. Coelution with authentic phenylthiohydantoin derivatives of CK and LK and the identical absorption spectra establish the identity of the compounds found in the urine with the synthetic products. Quantitation of the two ketimines by HPLC indicates that the excretion of CK and LK is respectively 606 micrograms and 84 micrograms per g of creatinine as mean values of 10 healthy subjects of both sexes, 20-40 years old, in the early morning voided urine.     

Bovine brain ketimine reductase

We report the purification from bovine brain of an NAD(P)H-dependent reductase which actively reduces a new class of cyclic unsaturated compounds, named ketimines. Ketimines arise from the transamination of some sulphur-containing amino acids, such as L-cystathionine, S-aminoethyl-L-cysteine and L-lanthionine. The enzyme also reduces delta 1-piperidine 2-carboxylate, the carbon analog of aminoethylcysteine ketimine. Some kinetic and molecular properties of this enzyme have been determined. Subcellular localization and regional brain distribution have also been studied. The ketimine reductase activity was found to be associated with the soluble fraction, and was located prevalently in the cerebellum and cerebral cortices. Cyclothionine and 1,4-thiomorpholine-3,5-dicarboxylic acid, the enzymatic reduction products of cystathionine ketimine and lanthionine ketimine, respectively, have been detected in bovine brain, thus suggesting a role of this enzyme in their biosynthesis.     

Multiple-step,one-pot synthesis of 2-substituted-3-phosphono-1-thia-4-aza-2-cyclohexene-5-carboxylates and their corresponding ethyl esters

The multiple-step, one-pot procedure for a series of 2-substituted-3-phosphono-1-thia-4-aza-2-cyclohexene-5-carboxylates, analogues of the natural, sulfur amino acid metabolite lanthionine ketimine (LK), its 5-ethyl ester (LKE) and 2-substituted LKEs is described. Initiating the synthesis with the Michaelis-Arbuzov preparation of α-ketophosphonates allows for a wide range of functional variation at the 2-position of the products. Nine new compounds were synthesized with overall yields range from 40 to 62%. In addition, the newly prepared 2-isopropyl-LK-P, 2-n-hexyl-LKE-P and 2-ethyl-LKE were shown to stimulate autophagy in cultured cells better than that of the parent compound, LKE.     

Detection of 2H-1,4-thiazine-5,6-dihydro-3-carboxylic acid (aminoethylcysteine ketimine) in the bovine brain

2H-1,4-Thiazine-5,6-dihydro-3-carboxylic acid (trivial name: aminoethylcysteine ketimine) is a cyclic sulfur-containing imino acid detected in bovine brain extracts by means of three different procedures. Gas liquid chromatography of protein-free extracts of five bovine brains revealed the presence of this compound at concentrations ranging from 2 to 3 nmol/g wet weight of tissue. The enzymatic method based on the inhibition of D-amino acid oxidase activity by aminoethylcysteine ketimine together with an high-performance liquid chromatography procedure confirm the identification and quantitations obtained with gas liquid chromatography. The discovery of this compound structurally similar to pipecolic acid opens the question of its physiological role in the central nervous system.     

Factors affecting mycelial to yeast phase conversion and growth of the yeast phase ofHistoplasma capsulatum

A procedure for rapid induction of mycelial to yeast phase (M→Y) conversion ofHistoplasma capsulatum has been devised. Exposure of mycelial fragments to low oxidation-reduction (O/R) potentials (+5 to+65 mv) either aerobically (ascorbic acid treatment) or anaerobically (nitrogen atmosphere) for 18 to 24 hours at 37° C resulted in induction of the M→Y conversion process whether or not an organic sulfur source was available. However, aerobic conditions and a suitable organic sulfur source, such as cysteine, cystine or lanthionine were found essential for outgrowth and maintenance in the yeastlike phase.     

The role of glutamine transaminase K (GTK) in sulfur and alpha-keto acid metabolism in the brain, and in the possible bioactivation of neurotoxicants

Glutamine transaminase K (GTK), which is a freely reversible glutamine (methionine) aromatic amino acid aminotransferase, is present in most mammalian tissues, including brain. Quantitatively, the most important amine donor in vivo is glutamine. The product of glutamine transamination (i.e., alpha-ketoglutaramate; alphaKGM) is rapidly removed by cyclization and/or conversion to alpha-ketoglutarate. Transamination is therefore "pulled" in the direction of glutamine utilization. Major biological roles of GTK are to maintain low levels of phenylpyruvate and to close the methionine salvage pathway. GTK also catalyzes the transamination of cystathionine, lanthionine, and thialysine to the corresponding alpha-keto acids, which cyclize to ketimines. The cyclic ketimines and several metabolites derived therefrom are found in brain. It is not clear whether these compounds have a biological function or are metabolic dead-ends. However, high-affinity binding of lanthionine ketimine (LK) to brain membranes has been reported. Mammalian tissues possess several enzymes capable of catalyzing transamination of kynurenine in vitro. Two of these kynurenine aminotransferases (KATs), namely KAT I and KAT II, are present in brain and have been extensively studied. KAT I and KAT II are identical to GTK and alpha-aminoadipate aminotransferase, respectively. GTK/KAT I is largely cytosolic in kidney, but mostly mitochondrial in brain. The same gene codes for both forms, but alternative splicing dictates whether a 32-amino acid mitochondrial-targeting sequence is present in the expressed protein. The activity of KAT I is altered by a missense mutation (E61G) in the spontaneously hypertensive rat. The symptoms may be due in part to alteration of kynurenine transamination. However, owing to strong competition from other amino acid substrates, the turnover of kynurenine to kynurenate by GTK/KAT I in nervous tissue must be slow unless kynurenine and GTK are sequestered in a compartment distinct from the major amino acid pools. The possibility is discussed that the spontaneous hypertension in rats carrying the GTK/KAT I mutation may be due in part to disruption of glutamine transamination. GTK is one of several pyridoxal 5'-phosphate (PLP)-containing enzymes that can catalyze non-physiological beta-elimination reactions with cysteine S-conjugates containing a good leaving group attached at the sulfur. These elimination reactions may contribute to the bioactivation of certain electrophiles, resulting in toxicity to kidney, liver, brain, and possibly other organs. On the other hand, the beta-lyase reaction catalyzed by GTK may be useful in the conversion of some cysteine S-conjugate prodrugs to active components in vivo. The roles of GTK in (a) brain nitrogen, sulfur, and aromatic amino acid/kynurenine metabolism, (b) brain alpha-keto acid metabolism, (c) bioactivation of certain electrophiles in brain, (d) prodrug targeting, and (e) maintenance of normal blood pressure deserve further study.     

Ketimine rings: useful detectors of enzymatic activities in solution and on polyacrylamide gel. Detection of L-amino acid oxidase, glutamine transaminase, pantetheinase, and acylase I

A simple procedure has been developed for the detection of L-amino acid oxidase, glutamine transaminase, pantetheinase, and acylase I in solution and on polyacrylamide gels. The method is based on the strong absorbance at 296 nm of some ketimine rings which can be directly produced by the enzymatic reaction or formed by the reaction of the enzymatic product with 3-bromopyruvate. The procedure allows one to visualize up to about 1-10 mU of enzyme.     

High-performance liquid chromatographic determination of indoleamines, dopamine, and norepinephrine in rat brain with fluorometric detection

A high-performance liquid chromatography-fluorescence procedure for the determination of 5-hydroxytryptamine, 5-hydroxyindoleacetic acid, tryptophan, dopamine, and norepinephrine has been developed. The method uses an ion-pairing system on an Ultrasphere ODS (5-microns) column with detector wavelength settings of excitation at 290 nm and emission at 330 nm. The procedure has been used to quantitate these indoleamines and catecholamines in rat brain tissue after homogenization in a perchloric acid solution; an aliquot of this solution is injected directly onto the HPLC column. Column sensitivities range from 6.1 pmol for tryptophan to 1.1 pmol for 5-hydroxytryptamine.     

Quantitation of hydroxyproline isomers in acid hydrolysates by high-performance liquid chromatography

A method has been developed to rapidly separate and quantitate levels of hydroxy-L-proline isomers in tissue hydrolysates. The procedure incorporates derivatization of the imino acids with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole chloride followed by separation by high-performance liquid chromatography employing two C18 reverse-phase columns connected in series. Conditions for the derivatization procedure have been optimized for the selective reactivity of imino acids. The derivatized imino acid fractions are then quantitated spectrophotometrically at 495 nm. Using this technique, quantities above 40 pmol are readily detected for trans-4-hydroxyl-L-proline, trans-3-hydroxyl-L-proline, proline, and other imino acid analogs. The method is applicable to a wide range of clinical and experimental tissues.     

A fluorometric procedure for measuring the neuraminidase activity: its application to the determination of this activity in influenza and parainfluenza viruses

A fluorometric procedure for quantitating the amount of N-acetylneuraminic acid enzymatically released by the neuraminidase activity from N-acetylneuraminyl-lactose (sialyl-lactose) has been developed. The liberated lactose is hydrolyzed with beta-galactosidase, and the released galactose is oxidized with galactose dehydrogenase and NAD+; finally, the NADH produced is measured by fluorometry (excitation at 340 nm and analysis of emitted light at 465 nm). The fluorometric assay is about 10-fold more sensitive than the spectrophotometric procedure that measures NADH at 340 nm. It readily measures amounts as little as 2 nmol of sialic acid, and does not require the use of radioactive isotopes. Interferences due to sucrose or other substances, which cause errors in some cases with the use of the periodate-thiobarbiturate method for neuraminidase activity determination, are avoided. The procedure reported here provides a sensitive, rapid, and relatively simple method (feasible with commercialized reagents) for measuring the neuraminidase activity not only in purified samples from different sources but also directly in biological materials such as viruses. The technique has been tested with some viruses recently isolated belonging to Orthomyxoviridae or Paramyxoviridae families, known to be rich in neuraminidase. Reciprocally, this method can also be employed for determining the sialic acid concentration in acylneuraminyl-lactose-containing compounds when using purified neuraminidase for hydrolysis.     

Measurement of kynurenic acid in mammalian brain extracts and cerebrospinal fluid by high-performance liquid chromatography with fluorometric and coulometric electrode array detection

Kynurenic acid is a broad-spectrum excitatory amino acid (EAA) receptor antagonist which is present in the mammalian central nervous system. We describe a method for the measurement of kynurenic acid using isocratic reverse-phase high-performance liquid chromatography (HPLC) with fluorometric detection enhanced by Zn2+ as a postcolumn reagent. The method requires no prior sample preparation procedures other than extraction with 0.1 M HClO4. The reliability of the primary fluorometric method was verified by comparing measurements of tissue concentrations of kynurenic acid in human cerebral cortex and putamen using three different methods of separation with fluorometric detection, as well as four methods utilizing HPLC with coulometric electrode array system (CEAS) detection. All seven methods produced comparable results. The concentration of kynurenic acid in human cerebral cortex was 2.07 +/- 0.61 pmol/mg protein, and in human putamen, 3.38 +/- 0.81 pmol/mg protein. Kynurenic acid was also found to be present in human cerebrospinal fluid (CSF) at a concentration of 5.09 +/- 1.04 nM. The regional distribution of kynurenic acid in the rat brain was examined. Kynurenic acid concentrations were highest in brainstem (149.6 fmol/mg protein) and olfactory bulb (103.9 fmol/mg protein) and lowest in thalamus (26.0 fmol/mg protein). There were no significant postmortem changes in kynurenic acid concentrations in cerebral cortex, hippocampus, and striatum at intervals ranging from 0 to 24 h. Perfusion of the cerebral vasculature with normal saline prior to sacrifice did not significantly alter kynurenic acid content in rat hippocampus, cerebral cortex, or striatum. The analytical methods described are the most sensitive (10-30 fmol injection-1) and specific (utilizing both excitation and emissions properties and electrochemical reaction potentials, respectively) methods for determining kynurenic acid in brain tissue extracts and CSF. These methods should prove useful in examining whether kynurenic acid modulates EAA-mediated neurotransmission under physiologic conditions, as well as in determining the role of kynurenic acid in excitotoxic neuronal death.     

Influence of diet on cystathionine ketimine and lanthionine ketimine content in human urine

A simple HPLC procedure for the routine analyses of Cystathionine ketimine (CK) and Lanthionine ketimine (LK) content in human urine has been developed. The values obtained in morning urine of fifteen healthy subjects (both sexes, 25-45 years old) on a common mixed diet are 330-2480 micrograms/g creatinine (mean 1110) of CK and 100-420 micrograms/g creatinine (mean 200) of LK. Quantitation of the two ketimines in urine of subjects on strictly vegetarian diet indicate that while the excretion of LK is independent of the diet, the excretion of CK is significantly decreased in conditions of vegetarian diet.     

The oxidation of sulfur containing cyclic ketimines The sulfoxide is the main product of S-aminoethyl-cysteine ketimine autoxidation

Summary The products of autoxidation of S-aminoethyl-L-cysteine ketimine (AECK) have been analysed with the amino acid analyzer, with thin layer chromatography and with high performance liquid chromatography. Under the conditions of the assay (pH 8.5, 38°C, O₂ bubbling) AECK is almost totally oxidized in 1.5 hours. Among the final products a component running fast in HPLC, named Cx1, has been isolated, reduced with NaBH₄ and analysed. Reduced Cx1 resulted to show the same properties of synthetic thiomorpholine-3-carboxylic acid-S-oxide, known in the past literature with the name of chondrine. On the basis of these results and by specific chromatographic tests, Cx1 has been identified as the sulfoxide of AECK. Among the other autoxidation products, thiomorpholine-3-one has been identified. The detection, after HCl hydrolysis, of glyoxylic acid and mesoxalic semialdehyde together with cysteamine indicates that compounds provided with easily cleavable S-C bonds, possibly thiohemiacetals or (and) thioesters, are the likely intermediates for other products. AECK sulfoxide and thiomorpholine-3-one are relatively stable and cannot be taken as the main intermediates for the remaining oxidation products.Abbreviations AAA amino acid analyzer - TLC thin layer chromatography - HPLC high performance liquid chromatography - AECK S-aminoethyl-L-cysteine ketimine - AECK-SO aminoethylcysteine ketimine sulfoxide - TMA thiomorpholine-3-carboxylic acid - TMA-SO thiomorpholine-3-carboxylic acid-S-oxide - CMCA S-carboxymethylcysteamine - DNPH 2,4-dinitrophenylhydrazine     

Reversible cyclization ofS-(2-oxo-2-carboxyethyl)-L-homocysteine to cystathionine ketimine

Summary S-(2-oxo-2-carboxyethyl)homocysteine (OCEHC), produced by the enzymatic monodeamination of cystathionine, is known to cyclize producing the seven membered ring of cystathionine ketimine (CK) which has been recognized as a cystathionine metabolite in mammals. Studies have been undertaken in order to find the best conditions of cyclization of synthetic OCEHC to CK and for the preparation of solid CK salt product. It has been found that ring closure takes place at alkaline pH and is highly accelerated in 0.5 M phosphate buffer. The sodium salt of CK has been prepared by controlled additions of NaOH to water-ethanol solution of OCEHC under N₂ atmosphere. A solid product is obtained which, dissolved in water, shows the spectral features of CK. Solutions of the sodium salt of CK show the presence of a pH depending reversible equilibrium with the open OCEHC form. Plot of the absorbance at 296 nm in function of pH indicates that at pH 9 the compound is completely cyclized while at pH 6 is totally in the open OCEHC form. At intermediate pHs variable ratios between the two forms occur. According to the results obtained by the spectral analysis, HPLC assays of the sodium salt of CK show different patterns depending on the pH of the elution buffer.Abbreviations CK cystathionine ketimine - OCEHC S-(2-oxo-2-carboxyethyl) homocysteine - HPLC high performance liquid chromatography     

Simultaneous determination of tryptophan and its metabolites in mouse brain by high-performance liquid chromatography with fluorometric detection

A new method for the determination of tryptophan and its metabolites in a single mouse brain using high-performance liquid chromatography (HPLC) with fluorometric detection is described. Tryptophan, serotonin, 5-hydroxyindoleacetic acid, indoleacetic acid, and tryptophol were clearly separated by a C8 reverse-phase column. Tissue preparation is performed only to centrifuge homogenates of brain prior to the injection to HPLC. The sensitivity is in the range from 10 to 15 pg.