Detection, characterisation, and quantification of carnosine and other histidyl derivatives in cardiac and skeletal muscle

Isocratic reverse phase analytical high performance liquid chromatography (HPLC) has been used to examine naturally occurring imidazoles of cardiac and skeletal muscles. Elution of muscle extracts with a phosphate buffer mobile phase from columns packed with hypersil ODS (5 micron) resulted in good separation of the skeletal muscle imidazole-containing dipeptides carnosine and anserine. Measured concentrations corresponded to published values. N-Acetyl forms that were not commercially available were prepared from their parent compounds and their identities verified by NMR-spectroscopy. Examination of frog cardiac muscle confirmed the presence of N-acetylhistidine and also indicated the presence of its 1-methyl derivative. Extracts of mammalian cardiac muscle were examined by HPLC which indicated the presence of low concentrations of carnosine but substantial amounts of N-acetyl forms of histidine, 1-methylhistidine, carnosine and anserine. Fractions corresponding to the numerous peaks were examined using staining systems specific for certain chemical features and compared to results obtained for commercial or synthetic standards. Results of these tests supported the chromatographic data. The total concentrations in cardiac muscle of these imidazole-containing substances (approx. 10 mM) is sufficient to alter significantly the sensitivity of their contractile apparatus to calcium ions.     

Separation and characterization of two carnosine-splitting cytosolic dipeptidases from hog kidney (carnosinase and non-specific dipeptidase)

High performance anion-exchange chromatography was used to separate two carnosine-hydrolysing dipeptidases from hog kidney. Both enzymes (peaks I and II) were cytosolic and were activated and stabilized by Mn2+ and dithiothreitol. Peak I had a narrow specificity when assayed without added metal ions, but a broad specificity in the presence of Mn2+ or Co2+. Peak II was inactive unless both Mn2+ and dithiothreitol were present. Bestatin and leucine inhibited peak II, but not peak I. Peak I had a Km of 0.4 mM carnosine, a pI of 5.5 and a Mr of 57,000. Peak II had a Km of 5 mM carnosine, a pI of 5.0 and a Mr of 70,000. Hog and rat brain and liver carnosinase activity was completely inhibited by bestatin, indicating that these organs contained peak II, with little or no peak I enzyme. Hog kidney peak I contained the classical carnosinase of Hanson and Smith, who first described this enzyme. It also contained activity against homocarnosine ("homocarnosinase") and showed "manganese-independent carnosinase" activity. These three activities could not be separated using 8 different chromatographic procedures; it was concluded that they are attributable to one enzyme. It is recommended that the name carnosinase be retained for this enzyme and the names "homocarnosinase" and "manganese-independent carnosinase" be withdrawn. The properties of hog kidney peak II closely resembled those of human tissue carnosinase (also known as prolinase, a non-specific dipeptidase), mouse "manganese-dependent carnosinase" and a rat brain enzyme termed "beta-Ala-Arg hydrolase". Since these terms appear to represent closely related enzymes with broad specificity, the recommended name for each is "non-specific cytosolic dipeptidase".     

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.     

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.     

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.     

Incorporation of [14C]histidine into homocarnosine and carnosine of frog brain in vivo and in vitro

1. Homocarnosine, carnosine and histidine were determined in brain from several species and the results compared with values in the literature. 2. [(14)C]Homocarnosine and [(14)C]carnosine were isolated from frog brain after intracerebral injection of [(14)C]histidine in vivo. 3. Whole frog brain, incubated in vitro with l-[(14)C]histidine, formed labelled homocarnosine and carnosine. 4. A frog brain homogenate or supernatant fraction catalysed the incorporation of l-[(14)C]histidine into homocarnosine and carnosine. 5. The results indicate that brain tissue can synthesize homocarnosine and carnosine.     

Sequence identification and characterization of human carnosinase and a closely related non-specific dipeptidase

Carnosine (beta-alanyl-L-histidine) and homocarnosine (gamma-aminobutyric acid-L-histidine) are two naturally occurring dipeptides with potential neuroprotective and neurotransmitter functions in the brain. Peptidase activities degrading both carnosine and homocarnosine have been described previously, but the genes linked to these activities were unknown. Here we present the identification of two novel cDNAs named CN1 and CN2 coding for two proteins of 56.8 and 52.7 kDa and their classification as members of the M20 metalloprotease family. Whereas human CN1 mRNA and protein are brain-specific, CN2 codes for a ubiquitous protein. In contrast, expression of the mouse and rat CN1 orthologues was detectable only in kidney. The recombinant CN1 and CN2 proteins were expressed in Chinese hamster ovary cells and purified to homogeneity. CN1 was identified as a homodimeric dipeptidase with a narrow substrate specificity for Xaa-His dipeptides including those with Xaa = beta Ala (carnosine, K(m) 1.2 mM), N-methyl beta Ala, Ala, Gly, and gamma-aminobutyric acid (homocarnosine, K(m) 200 microM), an isoelectric point of pH 4.5, and maximal activity at pH 8.5. CN2 protein is a dipeptidase not limited to Xaa-His dipeptides, requires Mn(2+) for full activity, and is sensitive to inhibition by bestatin (IC(50) 7 nM). This enzyme does not degrade homocarnosine and hydrolyzes carnosine only at alkaline pH with an optimum at pH 9.5. Based on their substrate specificity and biophysical and biochemical properties CN1 was identified as human carnosinase (EC ), whereas CN2 corresponds to the cytosolic nonspecific dipeptidase (EC ).     

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.     

Protection by carnosine-related dipeptides against hydrogen peroxide-mediated ceruloplasmin modification

Carnosine, homocarnosine, and anserine are present in high concentrations in the muscle and brain of many animals and humans. Previous studies showed that these compounds have an antioxidant function. We investigated the protective effects of carnosine and related compounds on the modification of human ceruloplasmin that is induced by H2O2. Carnosine, homocarnosine, and anserine significantly inhibited the fragmentation and inactivation of ceruloplasmin that is induced by H2O2. All three compounds also inhibited the release of copper ion from protein, and the formation of hydroxyl radicals in the ceruloplasmin/H2O2 system. These compounds inhibited the fragmentation of human serum albumin that is induced by the copper-catalyzed oxidation system, as well as by the iron-catalyzed oxidation system. These results suggest that carnosine, homocarnosine, and anserine might protect ceruloplasmin against H2O2-mediated oxidative damage through a combination of copper chelation and free radical scavenging.     

Effect of carnosine and related compounds on the inactivation of human Cu,Zn-superoxide dismutase by modification of fructose and glycolaldehyde

Glycolaldehyde, an intermediate of the Maillard reaction, and fructose, which is mainly derived from the polyol pathway, rapidly inactivate human Cu,Zn-superoxide dismutase (SOD) at the physiological concentration. We employed this inactivation with these carbonyl compounds as a model glycation reaction to investigate whether carnosine and its related compounds could protect the enzyme from inactivation. Of eight derivatives examined, histidine, Gly-His, carnosine and Ala-His inhibited the inactivation of the enzyme by fructose (p<0.001), and Gly-His, Ala-His, anserine, carnosine, and homocarnosine exhibited a marked protective effect against the inactivation by glycolaldehyde (p<0.001). The carnosine-related compounds that showed this highly protective effect against the inactivation by glycolaldehyde had high reactivity with glycolaldehyde and high scavenging activity toward the hydroxyl radical as common properties. On the other hand, the carnosine-related compounds that had a protective effect against the inactivation by fructose showed significant hydroxyl radical-scavenging ability. These results indicate that carnosine and such related compounds as Gly-His and Ala-His are effective anti-glycating agents for human Cu,Zn-SOD and that the effectiveness is based not only on high reactivity with carbonyl compounds but also on hydroxyl radical scavenging activity.     

Protective effects of carnosine, homocarnosine and anserine against peroxyl radical-mediated Cu,Zn-superoxide dismutase modification

Carnosine (beta-alanyl-L-histidine), homocarnosine (gamma-amino-butyryl-L-histidine) and anserine (beta-alanyl-1-methyl-L-histidine) have been proposed to act as anti-oxidants in vivo. The protective effects of carnosine and related compounds against the oxidative damage of human Cu,Zn-superoxide dismutase (SOD) by peroxyl radicals generated from 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH) were studied. The oxidative damage to Cu,Zn-SOD by AAPH-derived radicals led to protein fragmentation, which is associated with the inactivation of enzyme. Carnosine, homocarnosine and anserine significantly inhibited the fragmentation and inactivation of Cu,Zn-SOD by AAPH. All three compounds also inhibited the release of copper ions from the enzyme and the formation of carbonyl compounds in AAPH-treated Cu,Zn-SOD. These compounds inhibited the fragmentation of other protein without copper ion. The results suggest that carnosine and related compounds act as the copper chelator and peroxyl radical scavenger to protect the protein fragmentation. Oxidation of amino acid residues in Cu,Zn-SOD induced by AAPH were significantly inhibited by carnosine and related compounds. It is proposed that carnosine and related dipeptides might be explored as potential therapeutic agents for pathologies that involve Cu,Zn-SOD modification mediated by peroxyl radicals.     

The Sod Like Activity of Copper: Arnosine,Copper: Anserine and Copper: Homocarnosine Complexes

Carnosine, anserine and homocarnosine are natural compounds which are present in high concentrations (2–20 mM) in skeletal muscles and brain of many vertebrates. We have demonstrated in a previous work that these compounds can act as antioxidants, a result of their ability to scavenge peroxyl radicals, singlet oxygen and hydroxyl radicals. Carnosine and its analogues have been shown to be efficient chelating agents for copper and other transition metals. Since human skeletal muscle contains one-third of the total copper in the body (20–47 mmol/kg) and the concentration of carnosine in this tissue is relatively high, the complex of carnosine:copper may be of biological importance. We have studied the ability of the coppenarnosine (and other carnosine derivatives) complexes to act as superoxide dismutasc. The results indicate that the complex of copper:carnosine can dismute superoxide radicals released by neutrophils treated with PMA in an analogous mechanism to other amino acids and copper complexes. Copper:anserine failed to dismute superoxide radicals and coppwhomocarnosine complex was efficient when the cells were treated with PMA or with histone-opsonized streptococci and cytochalasine B. The possible role of these compounds to act as physiological antioxidants that possess superoxide dismutase activity is discussed.     

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.     

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.     

High-performance liquid chromatographic determination of imidazole dipeptides,histidine, 1-methylhistidine and 3-methylhistidine in equine and camel muscle and individual muscle fibres

The combined solid-phase extraction (Isolute PRS columns) and reversed-phase gradient HPLC method presented provides a sensitive, reproducible and selective quantification of carnosine, anserine, balenine, homocarnosine, histidine, 1-methylhistidine and 3-methylhistidine in equine and camel muscle and individual muscle fibres. Recoveries were 91–115%. Lower limits of detection were 0.005–0.010 mmol kg⁻ dry muscle. The compounds were isolated from other physiological amino acids and small peptides and resolved within a single chromatographic run of 55 min. Concentrations of these compounds in equine myocardium, diaphragm, skeletal muscle, camel muscle and individual muscle fibres of both species are presented for the first time.     

Hydrogen peroxide-mediated Cu,Zn-superoxide dismutase fragmentation: protection by carnosine, homocarnosine and anserine

The fragmentation of human Cu,Zn-superoxide dismutase (SOD) was observed during incubation with H(2)O(2). Hydroxyl radical scavengers such as sodium azide, formate and mannitol protected the fragmentation of Cu,Zn-SOD. These results suggested that *OH was implicated in the hydrogen peroxide-mediated Cu,Zn-SOD fragmentation. Carnosine, homocarnosine and anserine have been proposed to act as anti-oxidants in vivo. We investigated whether three compounds could protect the fragmentation of Cu,Zn-SOD induced by H(2)O(2). The results showed that carnosine, homocarnosine and anserine significantly protected the fragmentation of Cu,Zn-SOD. All three compounds also protected the loss of enzyme activity induced by H(2)O(2). Carnosine, homocarnosine and anserine effectively inhibited the formation of *OH by the Cu,Zn-SOD/H(2)O(2) system. These results suggest that carnosine and related compounds can protect the hydrogen peroxide-mediated Cu,Zn-SOD fragmentation through the scavenging of *OH.     

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.     

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.     

Carnosine and related dipeptides protect human ceruloplasmin against peroxyl radical-mediated modification

Ceruloplasmin (CP) is the major plasma antioxidant and copper transport protein. In a previous study, we showed that the aggregation of human ceruloplasmin was induced by peroxyl radicals. We investigated the effects of antioxidant dipeptides carnosine, homocarnosine and anserine on peroxyl radical-mediated ceruloplasmin modification. Carnosine, homocarnosine and anserine significantly inhibited the aggregation of CP induced by peroxyl radicals. When CP was incubated with peroxyl radicals in the presence of three compounds, ferroxidase activity, as measured by the activity staining method, was protected. All three compounds also inhibited the formation of dityrosine in peroxyl radicals-treated CP. The results suggest that carnosine and related compounds act as peroxyl radical scavenger to protect the protein modification. It is proposed that carnosine and related peptides might be explored as potential therapeutic agents for pathologies that involve CP modification mediated by peroxyl radicals generated in the lipid peroxidation.     

Molecular Identification of Carnosine Synthase as ATP-grasp Domain-containing Protein 1 (ATPGD1)

Carnosine (β-alanyl-l-histidine) and homocarnosine (γ-aminobutyryl-l-histidine) are abundant dipeptides in skeletal muscle and brain of most vertebrates and some invertebrates. The formation of both compounds is catalyzed by carnosine synthase, which is thought to convert ATP to AMP and inorganic pyrophosphate, and whose molecular identity is unknown. In the present work, we have purified carnosine synthase from chicken pectoral muscle about 1500-fold until only two major polypeptides of 100 and 90 kDa were present in the preparation. Mass spectrometry analysis of these polypeptides did not yield any meaningful candidate. Carnosine formation catalyzed by the purified enzyme was accompanied by a stoichiometric formation, not of AMP, but of ADP, suggesting that carnosine synthase belongs to the “ATP-grasp family” of ligases. A data base mining approach identified ATPGD1 as a likely candidate. As this protein was absent from chicken protein data bases, we reconstituted its sequence from a PCR-amplified cDNA and found it to fit with the 100-kDa polypeptide of the chicken carnosine synthase preparation. Mouse and human ATPGD1 were expressed in HEK293T cells, purified to homogeneity, and shown to catalyze the formation of carnosine, as confirmed by mass spectrometry, and of homocarnosine. Specificity studies carried out on all three enzymes were in agreement with published data. In particular, they acted with 15–25-fold higher catalytic efficiencies on β-alanine than on γ-aminobutyrate. The identification of the gene encoding carnosine synthase will help for a better understanding of the biological functions of carnosine and related dipeptides, which still remain largely unknown.