Metabolism of intracerebrally administered histidine, histamine and imidazoleacetic acid in mice and frogs

Abstract— After intracerebral administration of [¹⁴C]histidine to mice the major labelled substance found in the brain extracts was histidine itself; small amounts of labelled carnosine and homocarnosine were detected. No other labelled substances were detected on radio- autographs of two-dimensional TLC's of the extracts. In the case of the frog, radioactive histidine, N-acetylhistidine, carnosine and homocarnosine were found in the brain extracts at various times after intracerebral injection of the labelled histidine. With time, approximately 90 per cent of the radioactivity in the extracts was found in the N-acetylhistidine. In neither the mouse nor frog could we find unequivocal evidence for the formation either of histamine or imidazoleacetic acid from intracerebrally administered histidine, but our analytical procedures may have lacked sufficient sensitivity to pick up extremely low activities of histamine and imidazoleacetic acid. Experiments with [¹⁴C]histamine administered intracerebrally into mice demonstrated the major pathway of metabolism in brain to be histamine → methylhistamine → methylimidazoleacetic acid. No detectable label appeared in inlidazoleacetic acid. In the frog intracerebral administration of the labelled histamine led to the formation of methylhistamine and imidazoleacetic acid, but at most only traces of methylimidazoleacetic acid were found. The injection of [¹⁴C]imidazoleacetic acid intra- cerebrally into mice and frogs resulted in virtually no loss of the label in the form administered in the frog brain over a period of 4 h and in a slow rate of decrease in the mouse brain. No radioactive metabolites of imidazoleacetic acid were found in either species. The limitations of trying to determine natural functions of substances in brain by following the fate of exogenously administered materials is discussed.     

The effect of reserpine, chlorpromazine and neumbutal on levels of dipeptides in rat brain and muscle

Rat brain levels of histidine, carnosine, and homocarnosine were determined after intraperitoneal injection of chlorpromazine (CPZ), sodium pentobarbital (PB), or reserpine (RSP). At the same time, rat muscle levels of histidine, carnosine, and anserine were determined. RSP, CPZ, and PB significantly lowered brain homocarnosine levels and RSP raised histidine levels. RSP, CPZ, and PB significantly lowered levels of muscle carnosine and anserine. PB and CPZ also lowered levels of muscle histidine.     

Relevance of allosteric conformations and homocarnosine concentration on carnosinase activity

Activity of carnosinase (CN1), the only dipeptidase with substrate specificity for carnosine or homocarnosine, varies greatly between individuals but increases clearly and significantly with age. Surprisingly, the lower CN1 activity in children is not reflected by differences in CN1 protein concentrations. CN1 is present in different allosteric conformations in children and adults since all sera obtained from children but not from adults were positive in ELISA and addition of DTT to the latter sera increased OD450 values. There was no quantitative difference in the amount of monomeric CN1 between children and adults. Further, CN1 activity was dose dependently inhibited by homocarnosine. Addition of 80 μM homocarnosine lowered V _max for carnosine from 440 to 356 pmol/min/μg and increased K _m from 175 to 210 μM. The estimated K _i for homocarnosine was higher (240 μM). Homocarnosine inhibits carnosine degradation and high homocarnosine concentrations in cerebrospinal fluid (CSF) may explain the lower carnosine degradation in CSF compared to serum. Because CN1 is implicated in the susceptibility for diabetic nephropathy (DN), our findings may have clinical implications for the treatment of diabetic patients with a high risk to develop DN. Homocarnosine treatment can be expected to reduce CN1 activity toward carnosine, resulting in higher carnosine levels.     

Analysis of Carnosine, Homocarnosine, and Other Histidyl Derivatives in Rat Brain

Isocratic reverse-phase analytical HPLC has been used to examine naturally occurring imidazoles of rat brain. Elution of brain extracts with a phosphate buffer mobile phase from columns packed with Hypersil ODS (5 microns) resulted in good separation of the well-documented brain imidazole-containing dipeptides carnosine and homocarnosine. Measured concentrations corresponded to published values. Several further peaks observed had properties consistent with those of N-acetyl derivatives of compounds related to carnosine and homocarnosine. N-Acetyl forms not commercially available were prepared and their identities verified by nuclear magnetic resonance spectroscopy. A number of these had chromatographic properties identical to those of compounds in brain extracts. Fractions corresponding to some of the peaks were examined using staining systems specific for certain chemical features and compared with results obtained for commercial or synthetic standards. The results of these tests supported the chromatographic data. Thus, chromatographic and microchemical evidence is presented for the existence of N-acetyl forms of histidine, 1-methylhistidine, carnosine, anserine, and homocarnosine in rat brain.     

Some properties of a homocarnosine-carnosine synthetase isolated from rat brain

—An enzyme from rat brain catalysing the synthesis of the histidine-containing dipeptides carnosine and homocarnosine (l .-histidine: β-alanine ligase (AMP) [EC 6.3.2.11]) was purified about 30-40-fold from a 100,000 g supernatant. Assays were conducted by measuring the incorporation of L-[14C]histidine into carnosine and homocarnosine isolated by paper electrophoresis from the incubation mixture. The ratios of specific activities for the formation of carnosine and homocarnosine were not significantly different for the various purification steps. This was taken as evidence of one enzyme synthesizing both dipeptides. In studying the properties of this enzyme, a pH optimum of 7.4 was shown for carnosine synthesis. The concentrations of amino acid substrates giving maximal synthesis of both dipeptides were in the physiological range found for rat brain. An apparent requirement for ATP, Mg²⁺, and DPN was seen for dipeptide synthesis. A substrate dependent, enzymecatalysed ³²PPi-ATP exchange reaction was observed, suggesting the formation of an aminoacyl-AMP intermediate. Certain other nucleoside triphosphates could substitute for the ATP; this effect showed a specificity toward the dipeptide being synthesized. The apparent requirement for DPN was quite specific, with a number of related compounds having no effect. The stoichiometry of enzyme-catalysed carnosine synthesis was studied. A one to one relationship between carnosine formed and ATP hydrolysed was demonstrated. However, the ratio between carnosine synthesized and DPN hydrolysed was about 6 to 1, indicating a catalytic role for the DPN. The breakdown of DPN did not occur with enzyme alone but was dependent on the presence of substrate.     

Transport and distribution of homocarnosine after intracerebroventricular and intravenous injection in the rat

Rats were injected intracerebroventricularly (i.c.v.) or i.v. with [¹⁴C]homocarnosine (250 nmol). Distribution of the dipeptide in brain structures, transport from the brain to the blood, distribution in peripheral organs, and excretion in the urine were studied by measuring radioactivity in tissue, plasma, and urine samples by liquid scintillation counting 15–120 min after injection. After i.c.v. injection, [¹⁴C]homocarnosine was taken up into all parts of the brain investigated (highest uptake in structures close to the site of injection), it was transported to the blood, and radioactive substances were found in low concentration in muscle, spleen, and liver, in high concentration in the kidneys, and very high concentration in the urine. Investigations using high pressure liquid chromatography (HPLC) showed that no degradation took place in the brain, all radioactivity was found in the homocarnosine fraction. In the plasma 86% of the radioactivity was found in the GABA fraction presumed to be formed by cleavage of the peptide, while in the kidneys 35% and in the urine 40% was found in the GABA fraction. After i.v. injection of [¹⁴C]homocarnosine, no radioactivity was measured in hippocampus, striatum, cerebellum and cerebral cortex 15 min after injection, however, 60 min after injection a very low activity was detected in these structures (estimated intravascular radioactivity subtracted). A low activity was also measured in the spinal cord both 15 and 60 min after injection. When homocarnosine and GABA were separated on HPLC, all radioactivity in brain tissue was found in the GABA fraction, indicating either that [¹⁴C]homocarnosine did not cross the blood-brain barrier in amounts that could be measured with the method used, or that peptide entering the brain was rapidly transported back to the blood. [¹⁴C]Homocarnosine was not taken up either into crude synaptosomal preparations from hippocampus, striatum, cerebellum, cortex and spinal cord, or into slices prepared from the hippocampus and striatum. Transport from the brain to the kidneys and excretion in the urine seems to be a major route for disposal of this peptide in the rat.     

N-Acetylhistidine, Glutamate, and β-Alanine Are Concentrated in a Receptor Cell Layer of the Trout Inner Ear

An epithelial sheet isolated from the trout saccular macula, highly enriched in acousticolateralis receptor cells (hair cells), has been analyzed for primary amine-containing compounds. The hair cell preparation, compared to the saccular nerve, was found to contain elevated levels of the presumptive receptoneural transmitter, glutamate, as well as beta-alanine, and components eluting in the positions of the standards phosphoserine and phosphoethanolamine on cation-exchange HPLC. Saccular nerve contained a different spectrum of primary amines and was elevated specifically in carnosine/homocarnosine. Acid hydrolysis of perchlorate extracts of both hair cell and nerve fractions yielded large amounts of histidine. For the saccular nerve fraction, production of histidine by acid hydrolysis was matched by production of beta-alanine and gamma-aminobutyric acid (GABA) and disappearance of carnosine/homocarnosine. The dipeptides carnosine and homocarnosine have been chromatographically resolved by expanded HPLC and found to be present in saccular nerve in a ratio of approximately 10:1, respectively. Production of histidine in the hair cell extract was not coupled with production of beta-alanine and GABA. The hair cell histidine-containing unknown, present in millimolar concentration, has been identified as N-acetylhistidine by the hydrolysis and rechromatography of fractions from cation-exchange HPLC. The large and specific presence of N-acetylhistidine in the hair cell preparation, together with electrophysiological evidence for its facilitatory action on afferent fibers in the frog semicircular canal, is suggestive of a role for this molecule as well as glutamate in acousticolateralis receptoneural transmission.     

Activity of homocarnosine and other compounds against staphylococcal infections in mice

Homocarnosine and carnosine have been identified in bovine brain extracts which are effective in protecting mice against infections by Staphylococcus aureus. These peptides, as well as l-1-methylhistidine, beta-alanine, gamma-aminobutyric acid, delta-aminovaleric acid, epsilon-aminocaproic acid, 1-aminomethylcyclohexane-4-carboxylic acid, and anserine, were tested as prophylactic agents against S. aureus infections in C3H and Swiss mice. Histidine and methylhistidine were ineffective in preventing mortality in both mouse strains. Carnosine, anserine, and epsilon-aminocaproic acid were effective in C3H but not in Swiss mice. beta-Alanine and gamma-aminobutyric acid were weakly effective (C3H) or ineffective (Swiss). delta-Aminovaleric and 1-aminomethylcyclohexane-4-carboxylic acid (tested only in Swiss) were somewhat effective in early stages of the infection. Homocarnosine was the best compound and was highly effective in protecting both mouse strains against S. aureus infections by the testing procedure employed.     

Protective effects of histidine dipeptides on the modification of neurofilament-L by the cytochrome c/hydrogen peroxide system

Neurofilament-L (NF-L) is a major element of the neuronal cytoskeleton and is essential for neuronal survival. Moreover, abnormalities in NF-L result in neurodegenerative disorders. Carnosine and the related endogeneous histidine dipeptides prevent protein modifications such as oxidation and glycation. In the present study, we investigated whether histidine dipeptides, carnosine, homocarnosine, or anserine protect NF-L against oxidative modification during reaction between cytochrome c and H(2)O(2). Carnosine, homocarnosine and anserine all prevented cytochrome c/H(2)O(2)-mediated NF-L aggregation. In addition, these compounds also effectively inhibited the formation of dityrosine, and this inhibition was found to be associated with the reduced formations of oxidatively modified proteins. Our results suggest that carnosine and histidine dipeptides have antioxidant effects on brain proteins under pathophysiological conditions leading to degenerative damage, such as, those caused by neurodegenerative disorders.     

Protective effects of carnosine and homocarnosine on ferritin and hydrogen peroxide-mediated DNA damage

Previous studies have shown that one of the primary causes of increased iron content in the brain may be the release of excess iron from intracellular iron storage molecules such as ferritin. Free iron generates ROS that cause oxidative cell damage. Carnosine and related compounds such as endogenous histidine dipetides have antioxidant activities. We have investigated the protective effects of carnosine and homocarnosine against oxidative damage of DNA induced by reaction of ferritin with H(2)O(2). The results show that carnosine and homocarnosine prevented ferritin/H(2)O(2)-mediated DNA strand breakage. These compounds effectively inhibited ferritin/H(2)O(2)-mediated hydroxyl radical generation and decreased the mutagenicity of DNA induced by the ferritin÷H(2)O(2) reaction. Our results suggest that carnosine and related compounds might have antioxidant effects on DNA under pathophysiological conditions leading to degenerative damage such as neurodegenerative disorders.     

Intensity of label incorporation from [1,4-14C]putrescine into homocarnosine in the brain of rats of various ages

Intensity of 14C incorporation from the [1.4-14C]-putrescine to the homocarnosine and homocarnosine content in the brain of 1-, 7-, 14-, 21-day and adult rat were investigated. It is shown that dynamics of 14C incorporation from 1.4-14C-putrescine to the homocarnosine in the brain of rats of different age does not correlate with dynamics of homocarnosine content increase. The most significant activity of label incorporation from 14C-putrescine to the homocarnosine takes place in the brain of 1-, 21-day animals and adult rats.     

The role of valine in the biosynthesis of penicillin N and cephalosporin C by a Cephalosporium sp

1. The production of penicillin N, but not that of cephalosporin C, was inhibited by the addition of d-valine to suspensions in water of washed mycelium of Cephalosporium sp. 8650. The production of cephalosporin C was selectively inhibited by gamma-hydroxyvaline. 2. l-[(14)C]Valine was taken up rapidly and virtually completely by suspensions of washed mycelium but d-[(14)C]valine and alpha-oxo[(14)C]-isovalerate were taken up relatively slowly. 3. Part of the l-valine was rapidly degraded in the mycelium and part was incorporated into protein. Turnover of the valine in the amino acid pool was estimated to occur in 10-17min. 4. No detectable amount of l-[(14)C]valine was converted into the d-isomer in the mycelium. alpha-Oxo[(14)C]isovalerate was rapidly converted into l-[(14)C]valine in mycelium and mycelial extracts. 5. d-[(14)C]Valine was partially converted into the l-isomer in the mycelium and (14)C from d-valine was incorporated into protein. 6. The labelling of penicillin N and cephalosporin C by (14)C from l-[(14)C]valine was consistent with the view that l-valine is a direct precursor of C(5) fragments of both antibiotics and that any intermediates involved are present in relatively small pools in rapid turnover. 7. Labelling of the antibiotics with (14)C from d-[1-(14)C]valine appeared to occur after the latter had been converted into the l-isomer. Unlabelled d-valine did not decrease the efficiency of incorporation of (14)C from l-[1-(14)C]valine. 8. Intracellular peptide material which contained, among others, residues of alpha-aminoadipic acid, cysteine and valine, was rapidly labelled by (14)C from l-[1-(14)C]valine in a manner consistent with it being an intermediate in the biosynthesis of one or both of the antibiotics. 9. Labelling of penicillin N from l-[1-(14)C]valine occurred more rapidly than that of cephalosporin C. However, the effects of d-valine and gamma-hydroxyvaline on antibiotic production and the course of labelling of the antibiotics from l-[(14)C]valine could not readily be explained on the assumption that penicillin N was a precursor of cephalosporin C.     

Homocarnosine in human cerebrospinal fluid: an age-dependent phenomenon

—Homocarnosine, rather than carnosine, is the major imidazole dipeptide present in human CSF. This compound can be readily detected in the CSF of normal infants and young children, while it is either not detectable or is present only in very small concentrations in the CSF of normal adult subjects. Slightly greater amounts of homocarnosine can be found in the CSF of some adults with neurological disorders.     

Metabolism of l-Threonic Acid in Rumex x acutus L. and Pelargonium crispum (L.) L'Hér

l-Threonic acid is a natural constituent in leaves of Pelargonium crispum (L.) L'Hér (lemon geranium) and Rumex x acutus L. (sorrel). In both species, l-[(14)C]threonate is formed after feeding l-[U-(14)C]ascorbic acid to detached leaves. R. acutus leaves labeled with l-[4-(3)H]- or l-[6-(3)H]ascorbic acid produce l-[(3)H]threonate, in the first case internally labeled and in the second case confined to the hydroxymethyl group. These results are consistent with the formation of l-threonate from carbons three through six of l-ascorbic acid. Detached leaves of P. crispum oxidize l-[U-(14)C] threonate to l-[(14)C]tartrate whereas leaves of R. acutus produce negligible tartrate and the bulk of the (14)C appears in (14)CO(2), [(14)C]sucrose, and other products of carbohydrate metabolism. R. acutus leaves that are labeled with l-[U-(14)C]threonate release (14)CO(2) at linear rate until a limiting value of 25% of the total [U-(14)C]threonate is metabolized. A small quantity of [(14)C]glycerate is also produced which suggests a process involving decarboxylation of l-[U-(14)C]threonate.     

Quantification of carnosine-related peptides by microchip electrophoresis with chemiluminescence detection

A microchip electrophoresis (MCE) method with chemiluminescence (CL) detection was developed for the determination of carnosine-related peptides, including carnosine, homocarnosine, and anserine, in biological samples. A simple integrated MCE-CL system was built to perform the assays. The highly sensitive CL detection was achieved by means of the CL reaction between hydrogen peroxide and N-(4-aminobutyl)-N-ethylisoluminol-tagged peptides in the presence of adenine as a CL enhancer and Co²⁺ as a catalyst. Experimental conditions for analyte labeling, MCE separation, and CL detection were studied. MCE separation of the above-mentioned three peptides took less than 120 s. Detection limits (signal/noise ratio [S/N] = 3) of 3.0 × 10⁻⁸, 2.8 × 10⁻⁸, and 3.4 × 10⁻⁸ M were obtained for carnosine, anserine, and homocarnosine, respectively. The current MCE-CL method was applied for the determination of carnosine, anserine, and homocarnosine in human cerebrospinal fluid (CSF) and canine plasma. Homocarnosine was detected at the micromolar (μM) level in the CSF samples analyzed, whereas the levels of carnosine and anserine in these samples were below the detection limit of the assay. Interestingly, both carnosine and anserine were detected in the canine plasma samples, whereas homocarnosine was not.     

Carnosine,homocarnosine and anserine in vertebrate retinas

The dipeptides carnosine, homocarnosine and anserine are differentially distributed among the retinas of several vertebrate species. Retinas of birds are rich in anserine while those of frogs have primarily carnosine. Several mammalian species contain only very low levels of homocarnosine. The biological function of these dipeptides is unknown but their presence and synthesis in retina may confound studies of uptake, metabolism and cellular localization of their component amino acids β-alanine, gamma-aminobutyric acid and histidine.     

Biosynthesis of carcinine (beta-alanyl-histamine) in vivo

Carcinine was biosynthesized by Carcinus maenas from [14C]beta-alanine, [14C] histidine and [14C] histamine. Since carnosine (beta-alanyl-histidine) could not be detected in crab tissues, biosynthesis of carcinine could only be effected by direct coupling of beta-alanine and histamine resulting from histidine decarboxylation. Biosynthesis of carcinine was weak when [14C]beta-alanine and [14C] histidine were used as precursors. On the contrary when [14C] histamine was used, synthesis was important. Thus carcinine appears to be a product of histamine catabolism. After injecting [14C] histamine, radioactive carcinine was concentrated mainly in the heart and nervous system; nonmetabolized [14C] histamine was recovered mainly in the latter. The nervous system might therefore be the seat of carcinine biosynthesis and thus the site of action of histamine.     

Metabolism of [14C]citrulline in the perfused sheep and goat udder

1. A lactating-sheep mammary gland was perfused for 12h in the presence of l-[2-(14)C]-citrulline and received adequate quantities of glucose, acetate and amino acids. Two lactating-goat udders were similarly perfused in the presence of either l-[carbamoyl-(14)C,-2-(14)C]citrulline or l-[carbamoyl-(14)C,1-(14)C]citrulline and l-[4-(3)H]arginine. 2. In these experiments, [(14)C]citrulline was substantially oxidized to CO(2) and converted into arginine and proline of casein. 3. The specific radioactivities of arginine, ornithine and proline of the plasma increased after passage through the udders, demonstrating that [(14)C]citrulline is metabolized by the mammary gland. 4. The presence of two unknown radioactive metabolites of [(14)C]citrulline was detected in the perfusate. These substances were not found after incubation in vitro of oxygenated blood in the presence of the radioactive precursor. 5. From these experiments, it is concluded that citrulline is metabolized in mammary tissue by way of arginine to urea, ornithine and proline.     

Biochemical and Physiological Evidence that Carnosine Is an Endogenous Neuroprotector Against Free Radicals

1. Carnosine, anserine, and homocarnosine are endogenous dipeptides concentrated in brain and muscle whose biological functions remain in doubt.2. We have tested the hypothesis that these compounds function as endogenous protective substances against molecular and cellular damage from free radicals, using two isolated enzyme systems and two models of ischemic brain injury. Carnosine and homocarnosine are both effective in activating brain Na, K-ATPase measured under optimal conditions and in reducing the loss of its activity caused by incubation with hydrogen peroxide.3. In contrast, all three endogenous dipeptides cause a reduction in the activity of brain tyrosine hydroxylase, an enzyme activated by free radicals. In hippocampal brain slices subjected to ischemia, carnosine increased the time to loss of excitability.4. In in vivo experiments on rats under experimental hypobaric hypoxia, carnosine increased the time to loss of ability to stand and breath and decreased the time to recovery.5. These actions are explicable by effects of carnosine and related compounds which neutralize free radicals, particularly hydroxyl radicals. In all experiments the effective concentration of carnosine was comparable to or lower than those found in brain. These observations provide further support for the conclusion that protection against free radical damage is a major role of carnosine, anserine, and homocarnosine.     

A sensitive specific enzymatic-fluorometric assay for homocarnosine

We have developed a sensitive and specific assay for homocarnosine in tissues. Homocarnosine is separated from GABA by ion exchange chromatography. After hydrolysis of homocarnosine with swine kidney carnosinase, the evolved GABA is measured by an enzymatic-fluorometric procedure. As little as 0.1 nmol of tissue homocarnosine can be detected by this procedure. Homoanserine, which would be detected by this assay, can be separated from homocarnosine by thin layer chromatography. No homoanserine could be detected in any tissues examined. There are marked regional variations in levels of homocarnosine in guinea-pig brain that do not correspond to regional differences in GABA levels.