肌肽对绵羊精子无氧酵解的影响

在无氧条件下,绵羊精子通过酵解途径获得能量,代谢结果产生大量乳酸,本实验通过测定精子悬液中果糖摄取以及乳酸生成量,研究肌肽、棉酚对绵羊精子酵解途径的影响,结果表明：４ｍＭ肌肽对绵羊精子酵解有显著增强作用,并能刺激精子对果糖的摄取。１２μＭ棉酚对绵羊精子无明显抑制,棉酚能部分抑制肌肽对精子的酵解作用。     

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.     

L-carnosine reduces telomere damage and shortening rate in cultured normal fibroblasts

Telomere is the repetitive DNA sequence at the end of chromosomes, which shortens progressively with cell division and limits the replicative potential of normal human somatic cells. L-carnosine, a naturally occurring dipeptide, has been reported to delay the replicative senescence, and extend the lifespan of cultured human diploid fibroblasts. In this work, we studied the effect of carnosine on the telomeric DNA of cultured human fetal lung fibroblast cells. Cells continuously grown in 20 mM carnosine exhibited a slower telomere shortening rate and extended lifespan in population doublings. When kept in a long-term nonproliferating state, they accumulated much less damages in the telomeric DNA when cultured in the presence of carnosine. We suggest that the reduction in telomere shortening rate and damages in telomeric DNA made an important contribution to the life-extension effect of carnosine.     

The absorption of orally supplied β-alanine and its effect on muscle carnosine synthesis in human vastus lateralis

Summary. β-Alanine in blood-plasma when administered as A) histidine dipeptides (equivalent to 40 mg · kg⁻¹ bwt of β-alanine) in chicken broth, or B) 10, C) 20 and D) 40 mg · kg⁻¹ bwt β-alanine (CarnoSyn™, NAI, USA), peaked at 428 ± SE 66, 47 ± 13, 374 ± 68 and 833 ± 43 μM. Concentrations regained baseline at 2 h. Carnosine was not detected in plasma with A) although traces of this and anserine were found in urine. Loss of β-alanine in urine with B) to D) was <5%. Plasma taurine was increased by β-alanine ingestion but this did not result in any increased loss via urine. Pharmacodynamics were further investigated with 3 × B) per day given for 15 d. Dietary supplementation with I) 3.2 and II) 6.4 g · d⁻¹ β-alanine (as multiple doses of 400 or 800 mg) or III) L-carnosine (isomolar to II) for 4 w resulted in significant increases in muscle carnosine estimated at 42.1, 64.2 and 65.8%.     

Purification and identification of two carnosine-cleaving enzymes, carnosine dipeptidase I and Xaa-methyl-His dipeptidase, from Japanese eel (Anguilla japonica)

Three enzymes, carnosine dipeptidase I (EC 3.4.13.20, CNDP1), carnosine dipeptidase II (EC 3.4.13.18, CNDP2), and Xaa-methyl-His dipeptidase (or anserinase: EC 3.4.13.5, ANSN), are known to be capable of catalyzing the hydrolysis of carnosine (β-alanyl-l-histidine), in vertebrates. Here we report the purification and identification of two unidentified carnosine-cleaving enzymes from Japanese eel (Anguilla japonica). Two different dipeptidases were successfully purified to homogeneity from the skeletal muscle; one exhibited a broad substrate specificity, while the other a narrow specificity. N-terminal amino-acid sequencing, deglycosylation analysis, and genetic analysis clearly revealed that the former is a homodimer of glycosylated subunits, encoded by ANSN, and the latter is another homodimer of glycosylated subunits, encoded by CNDP1; that is, Xaa-methyl-His dipeptidase, and carnosine dipeptidase I respectively. This is the first report on the identification of carnosine dipeptidase I from a non-mammal. Database search revealed presence of a CNDP1 ortholog only from salmonid fishes, including Atlantic salmon and rainbow trout, but not from other ray-finned fish species, such as zebrafish, fugu, and medaka whose genomes have been completely sequenced. The mRNAs of CNDP1 and ANSN are strongly expressed in the liver of Japanese eel, compared with other tissues, while that of CNDP2 is widely distributed in all tissues tested.     

Reverse structure of carnosine-induced sedative and hypnotic effects in the chick under acute stress

In the central nervous system, beta-alanine is thought to act as an inhibitory neurotransmitter, but the role or precise mechanism of beta-alanine in the brain has not been clearly defined. beta-Alanine is found in high levels in the chicken brain as a component of the dipeptides carnosine (beta-alanyl-L-histidine) and anserine, or as a free amino acid. We focused on the position of beta-alanine, i.e., at the carboxyl terminus. In Experiment 1, the central effects of glycyl-beta-alanine, L-histidyl-beta-alanine and L-valyl-beta-alanine were compared with a saline control in chicks. L-Histidyl-beta-alanine significantly induced sedative and hypnotic effects. In Experiment 2, the effects of carnosine, its reverse (L-histidyl-beta-alanine), and their combination were investigated. Central carnosine-induced hyperactivity while reverse carnosine-induced hypoactivity, and the behaviors were intermediate following the combination of the two peptides. Finally, the central effect of reverse carnosine was compared with beta-alanine alone and L-seryl-beta-alanine in Experiment 3. Reverse carnosine showed similar effects to beta-alanine. In conclusion, L-histidyl-beta-alanine not only has the reverse structure of carnosine, but also reverse function. Thus, we propose to name reverse carnosine (L-histidyl-beta-alanine) rev-carnosine.     

Metabolite Proofreading in Carnosine and Homocarnosine Synthesis: MOLECULAR IDENTIFICATION OF PM20D2 AS β-ALANYL-LYSINE DIPEPTIDASE*

Carnosine synthase is the ATP-dependent ligase responsible for carnosine (β-alanyl-histidine) and homocarnosine (γ-aminobutyryl-histidine) synthesis in skeletal muscle and brain, respectively. This enzyme uses, also at substantial rates, lysine, ornithine, and arginine instead of histidine, yet the resulting dipeptides are virtually absent from muscle or brain, suggesting that they are removed by a “metabolite repair” enzyme. Using a radiolabeled substrate, we found that rat skeletal muscle, heart, and brain contained a cytosolic β-alanyl-lysine dipeptidase activity. This enzyme, which has the characteristics of a metalloenzyme, was purified ≈200-fold from rat skeletal muscle. Mass spectrometry analysis of the fractions obtained at different purification stages indicated parallel enrichment of PM20D2, a peptidase of unknown function belonging to the metallopeptidase 20 family. Western blotting showed coelution of PM20D2 with β-alanyl-lysine dipeptidase activity. Recombinant mouse PM20D2 hydrolyzed β-alanyl-lysine, β-alanyl-ornithine, γ-aminobutyryl-lysine, and γ-aminobutyryl-ornithine as its best substrates. It also acted at lower rates on β-alanyl-arginine and γ-aminobutyryl-arginine but virtually not on carnosine or homocarnosine. Although acting preferentially on basic dipeptides derived from β-alanine or γ-aminobutyrate, PM20D2 also acted at lower rates on some “classic dipeptides” like α-alanyl-lysine and α-lysyl-lysine. The same activity profile was observed with human PM20D2, yet this enzyme was ∼100–200-fold less active on all substrates tested than the mouse enzyme. Cotransfection in HEK293T cells of mouse or human PM20D2 together with carnosine synthase prevented the accumulation of abnormal dipeptides (β-alanyl-lysine, β-alanyl-ornithine, γ-aminobutyryl-lysine), thus favoring the synthesis of carnosine and homocarnosine and confirming the metabolite repair role of PM20D2.     

肌肽对离体培养的鸡肝细胞的影响

研究了肌肽对离体培养的鸡肝细胞的影响。实验采用胶原酶原位二步灌流法获得鸡肝细胞,再用不同浓度的肌肽(①2 μmol L、②2 0 μmol L、③2 0 0 μmol L ,④2 0mmol L)分别进行处理。结果表明,1 )在各个时期,含2 0 μmol L肌肽的实验组肝细胞生长均好于对照组(0 μmol L肌肽) ,而且在48和72h时二者差异显著(P <0 0 5 ) ;2 ) 2 0mmol L肌肽能显著提高肝细胞的分泌白蛋白的功能(P <0 0 5 ) ;3 )添加肌肽的各实验组上清液中丙二醛(MDA)含量在2 4和48h时均低于对照组;4)添加2 0mmol L肌肽的实验组与对照组相比,能维持无血清培养肝细胞的形态达8d。表明了肌肽对鸡肝细胞增殖和分泌白蛋白有促进作用,同时可以保护肝细胞对抗过氧化,保护细胞形态。     

New glycoside derivatives of carnosine and analogs resistant to carnosinase hydrolysis: synthesis and characterization of their copper(II) complexes

Carnosine (β-alanyl-L-histidine) is an endogenous dipeptide widely and abundantly distributed in muscle and nervous tissues of several animal species. Many functions have been proposed for this compound, such as antioxidant and metal ion-chelator properties. However, the main limitation on therapeutic use of carnosine on pathologies related to increased oxidative stress and/or metal ion dishomeostasis is associated with the hydrolysis by the specific dipeptidase carnosinase. Several attempts have been made to overcome this limitation. On this basis, we functionalized carnosine and its amide derivative with small sugars such as glucose and lactose. The resistance of these derivatives to the carnosinase hydrolysis was tested and compared with that of carnosine. We found that the glycoconjugation protects the dipeptide moiety from carnosinase hydrolysis, thus potentially improving the availability of carnosine. The copper(II) binding properties of all the new synthesized compounds were investigated by spectroscopic (UV-Visible and circular dichroism) and ESI-MS studies. Particularly, the new family of amide derivatives that are not significantly hydrolyzed by carnosinase is a very promising class of carnosine derivatives. The sugar moiety can act as a recognition element. These new derivatives are potentially able to act as chelating agents in the development of clinical approaches for the regulation of metal homeostasis in the field of medicinal inorganic chemistry.     

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.