Immunoregulative effects of carnosine and beta-alanine

Physiological factors involved in immunity and tissue repair with regulate homeostasis, a physiological function of the connective tissue, are as yet unidentified. We earlier detected the granulation-promoting action of carnosine, and reported on the acceleration of tissue repair in experimental as well as clinical studies. In that study, immunoregulatory effects of carnosine and beta-alanine were examined by the plaque-forming cell (PFC) count and delayed hypersensitivity reaction (DHR). The PFC value increased in mice pretreated with these agents. In these mice, PFC reaction to 2 X 10(7) SRBC was enhanced but that to 1 X 10(9) SRBC was suppressed. The agents also suppressed excess immunoreaction in immature mice but increased weakened immunoreaction in aged animals. Furthermore, the agents had the optimal doses for the enhancement of both PFC reaction to 1 X 10(8) SRBC and DHR to 1% picryl chloride. They also induced recovery of immunofunction suppressed by the administration of MMC. Carnosine and beta-alanine exerts immunoregulatory effects by activating both T and B cells. Our observations indicated that the agents not only promote tissue repair but also help maintain homeostasis and accelerate spontaneous healing.     

Discovery of carnosine and anserine. Some of their properties]

The history of discovery of carnosine and anserine is reviewed with special reference to the structure and distribution of the dipeptides in various tissues during ontogenesis. The state of the dipeptides in muscle cells, their metabolism and role in muscle activity are considered. The properties of carnosine and anserine phosphoric esters are described, and their putative role in mitochondrial oxidative phosphorylation is discussed. The membranotropic activity of carnosine and anserine is demonstrated.     

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.     

Effects of carnosine and anserine on muscle and non-muscle phosphorylases

Rabbit muscle phosphorylases a and b are activated by carnosine, whereas potato and yeast phosphorylases are inhibited at the same concentration of dipeptide. Rabbit muscle phosphorylase a is activated by anserine whereas the b form enzyme and the potato and yeast enzymes are inhibited by the dipeptide. The dipeptides affect the Vmax values for the enzymes rather than the substrate Km values. Kinetic analysis suggested that, for rabbit muscle phosphorylase, both dipeptides compete for occupancy of the same binding site(s) on the enzyme.     

Spectrophotometric determination of carnosine,anserine, and taurine in skeletal muscle

The determination of carnosine using the diazonium salt of p-bromoaniline and the determination of taurine and of taurine, carnosine, and anserine together using 2,4-dinitro-1-fluorobenzene to give yellow-colored derivatives is the basis for the spectrophotometric assay of these compounds in skeletal muscle. The procedure can be applied directly to aqueous extracts of muscle and is well suited for routine assays of many samples.     

Effect of beta-alanine supplementation on muscle carnosine concentrations and exercise performance

High-intensity exercise results in reduced substrate levels and accumulation of metabolites in the skeletal muscle. The accumulation of these metabolites (e.g. ADP, Pi and H⁺) can have deleterious effects on skeletal muscle function and force generation, thus contributing to fatigue. Clearly this is a challenge to sport and exercise performance and, as such, any intervention capable of reducing the negative impact of these metabolites would be of use. Carnosine (β-alanyl-l-histidine) is a cytoplasmic dipeptide found in high concentrations in the skeletal muscle of both vertebrates and non-vertebrates and is formed by bonding histidine and β-alanine in a reaction catalysed by carnosine synthase. Due to the pKa of its imidazole ring (6.83) and its location within skeletal muscle, carnosine has a key role to play in intracellular pH buffering over the physiological pH range, although other physiological roles for carnosine have also been suggested. The concentration of histidine in muscle and plasma is high relative to its K _m with muscle carnosine synthase, whereas β-alanine exists in low concentration in muscle and has a higher K _m with muscle carnosine synthase, which indicates that it is the availability of β-alanine that is limiting to the synthesis of carnosine in skeletal muscle. Thus, the elevation of muscle carnosine concentrations through the dietary intake of carnosine, or chemically related dipeptides that release β-alanine on absorption, or supplementation with β-alanine directly could provide a method of increasing intracellular buffering capacity during exercise, which could provide a means of increasing high-intensity exercise capacity and performance. This paper reviews the available evidence relating to the effects of β-alanine supplementation on muscle carnosine synthesis and the subsequent effects on exercise performance. In addition, the effects of training, with or without β-alanine supplementation, on muscle carnosine concentrations are also reviewed.     

Selective effects of actinomycin D on myosin biosynthesis and myoblast fusion during myogenesis in culture

The regulation of myosin biosynthesis in primary culture from embryonic chick muscle has been studied by measuring the residual myosin synthesis and the rate of fusion after actinomycin treatment. It is shown that while the rate of fusion is completely unaffected by an 8-h treatment with the inhibitor, throughout culture, the myosin biosynthesis shows different levels of inhibition during culture. In fact at onset of fusion (53 h) myosin synthesis is strongly inhibited, while at a later period following fusion (100 h) it is scarcely affected by the treatment.     

Gender-related differences in carnosine,anserine and lysine content of murine skeletal muscle

Summary. The aminoacyl-imidazole dipeptides carnosine (-alanyl-L-histidine) and anserine (-alanyl-1-methyl-histidine) are present in relatively high concentrations in excitable tissues, such as muscle and nervous tissue. In the present study we describe the existence of a marked sexual dimorphism of carnosine and anserine in skeletal muscles of CD1 mice. In adult animals the concentrations of anserine were higher than those of carnosine in all skeletal muscles studied, and the content of aminoacyl-imidazole dipeptides was remarkably higher in males than in females. Postnatal ontogenic studies and hormonal manipulations indicated that carnosine synthesis was up-regulated by testosterone whereas anserine synthesis increased with age. Regional variations in the concentrations of the dipeptides were observed in both sexes, skeletal muscles from hind legs having higher amounts of carnosine and anserine than those present in fore legs or in the pectoral region. The concentration of L-lysine in skeletal muscles also showed regional variations and a sexual dimorphic pattern with females having higher levels than males in all muscles studied. The results suggest that these differences may be related with the anabolic action of androgens on skeletal muscle.     

Cytogenetical effects of sonication in mice and their modulations by actinomycin D and a homeopathic drug,Arnica 30

Experiments were designed to examine if Actinomycin D, an antibiotic, and Amica 30, a homeopathic drug used against shock and injury, can ameliorate cytogenetic damage induced by single or multiple exposures to ultrasonication. Separate sets of healthy mice were directly exposed to sonication for two minutes either once or they received multiple exposures at an interval of 20 days. The mice were then assessed at different intervals, against suitable controls, using parameters like chromosome aberrations (CA), mitotic index (MI), sperm head anomaly (SHA) and micronucleated erythrocytes (MNE). Separate groups of sonicated mice were either orally administered with Arnica 30 (alcohol 30 in control) or injected intramuscularly with Actinomycin-D (AMD). Elevated frequencies of CA, MI, MNE and SHA were noted in sonicated series. AMD had genotoxic effects of its own and also had additive effects on sonication induced genotoxicity. Sonicated mice fed with Arnica 30 showed appreciably reduced genotoxicity as against alcohol 30 and distilled water fed controls, thereby showing ameliorating effect which may have human application.