Synthesis of a Precursor Dipeptide of Thymopentin in Organic Solvents by an Enzymatic Method

Abstract

The protease‐catalyzed, kinetically controlled synthesis of a precursor dipeptide of thymopentin(TP‐5), Z‐Arg‐Lys‐NH₂ in organic solvents was studied. Z‐Arg‐OMe was used as the acyl donor and Lys‐NH₂ was used as the nucleophile. An industrial alkaline protease alcalase and trypsin were used to catalyze the synthesis of the target dipeptide in water‐organic cosolvent systems. The conditions of the synthesis reaction were optimized by examining the effects of several factors, including organic solvents, water content, temperature, pH, and reaction time on the yield of Z‐Arg‐Lys‐NH₂. The optimum conditions using alcalase as the catalyst are pH 10.0, 35°C, in acetonitrile/DMF/Na₂CO₃‐NaHCO₃ buffer system (80∶10∶10, V/V), 6 h, with the dipeptide yield of 71.1%. Compared with alcalase, the optimum conditions for trypsin are pH 8.0, 35°C, in ethanol/Tris‐HCl buffer system (80∶20, V/V), 4 h, with the dipeptide yield of 76.1%.     

Protease-catalyzed synthesis of a precursor dipeptide, Z-Asp-Val-NH2 of thymopentin, in organic solvents

The protease-catalyzed, kinetically controlled synthesis of a precursor dipeptide, Z-Asp-Val-NH(2) of thymopentin (TP-5), in organic solvents was studied. Z-Asp-OMe and Val-NH(2) were used as the acyl donor and the nucleophile, respectively. An industrial alkaline protease alcalase was used to catalyze the synthesis of the target dipeptide in water-organic cosolvent systems. The conditions of the synthesis reaction were optimized by examining the effects of several factors, including organic solvents, water content, temperature, pH, and reaction time on the yield of Z-Asp-Val-NH(2). The optimum conditions using alcalase as the catalyst are pH 10.0, 35 degrees C, in acetonitrile/Na(2)CO(3)-NaHCO(3) buffer system (9:1, V/V), reaction time 5 h, with a yield of 63%. The dipeptide product was confirmed by LC- MS.     

Protease-Catalyzed Synthesis of a Precursor Dipeptide,Z-Asp-Val-NH2 of Thymopentin,in Organic Solvents

Abstract

The protease-catalyzed, kinetically controlled synthesis of a precursor dipeptide, Z-Asp-Val-NH₂ of thymopentin (TP-5), in organic solvents was studied. Z-Asp-OMe and Val-NH₂ were used as the acyl donor and the nucleophile, respectively. An industrial alkaline protease alcalase was used to catalyze the synthesis of the target dipeptide in water-organic cosolvent systems. The conditions of the synthesis reaction were optimized by examining the effects of several factors, including organic solvents, water content, temperature, pH, and reaction time on the yield of Z-Asp-Val-NH₂. The optimum conditions using alcalase as the catalyst are pH 10.0, 35°C, in acetonitrile/Na₂CO₃-NaHCO₃ buffer system (9:1, V/V), reaction time 5 h, with a yield of 63%. The dipeptde product was confirmed by LC- MS.     

Alcalase-catalyzed, kinetically controlled synthesis of a precursor dipeptide of RGDS in organic solvents

The protease-catalyzed, kinetically controlled synthesis of a precursor dipeptide of RGDS, Z-Asp-Ser-NH2 in organic solvents was studied. Alcalase, an industrial alkaline protease, was used to catalyze the synthesis of the target dipeptide in water-organic cosolvents systems with Z-Asp-OMe as the acyl donor and Ser-NH2 as the nucleophile. Acetonitrile was selected as the organic solvent from acetonitrile, ethanol, methanol, DMF, DMSO, ethyl acetate, 2-methyl-2-propanol, and chloroform tested under the experimental conditions. The conditions of the synthesis reaction were optimized by examining the effects of several factors, including water content, temperature, pH, and reaction time on the Z-Asp-Ser-NH2 yields. The optimum conditions are pH 10.0, 35 degrees C, in acetonitrile/Na2CO3-NaHCO3 buffer system (85:15, v/v), 6 h, with a dipeptide yield of 75.5%.     

SYNTHESIS OF A PRECURSOR TRIPEPTIDE Z-Asp-Val-Tyr-OH OF THYMOPENTIN BY CHEMO-ENZYMATIC METHOD

The precursor tripeptide of thymopentin was synthesized by a combination of chemical and enzymatic methods. First, Val-Tyr-OH dipeptide was synthesized by a novel chemical method in two steps involving preparation of NCA-Val. Second, the linkage of the third amino acid Z-Asp-OMe to Val-Tyr-OH was completed by an enzymatic method under kinetic control. An industrial alkaline protease alcalase was used in water–organic cosolvent systems. The synthesis reaction conditions were optimized by examining the effects of several factors including organic solvents, water content, temperature, pH, and reaction time on the yield of Z-Asp-Val-Tyr-OH. The optimum condition is of pH 10.0, 35°C, acetonitrile/Na₂CO₃-NaHCO₃ buffer system (85:15, v/v), and reaction time of 2.5 hr, which achieves tripeptide yield of more than 70%.     

Trypsin-catalyzed kinetically controlled synthesis of a precursor dipeptide of thymopentin in organic solvents, using a free amino acid as nucleophile

Trypsin-catalyzed, kinetically controlled synthesis of a precursor, dipeptide of thymopentin (TP-5), Bz-Arg-Lys-OH (or-OEt) in organic solvents was studied. Bz-Arg-OEt was used as the acyl donor and Lys-OH and Lys-OEt were used as the nucleophiles. Ethanol was selected as the organic solvent from ethanol, methanol, acetonitrile, and ethyl acetate tested under the experimental conditions. As expected, Lys-OEt is not a suitable nucleophile in trypsin-catalyzed reaction, due to its competition with the protective Arg-OEt as acyl donor for the active site of trypsin, while Lys-OH does not have this problem. The optimal reaction condition for the synthesis of Bz-Arg-Lys-OH was set up as 20% Tris-HCl buffer, pH 8.0, 35 degrees C for 6 h with the yield of 52.5%, or for 18-24 h with the yield of about 60%.     

Synthesis of tripeptide RGD amide by a combination of chemical and enzymatic methods

The tripeptide Bz-Arg-Gly-Asp(NH₂)OH was synthesized by a combination of chemical and enzymatic methods in this study. Firstly, Gly-Asp-(NH₂)₂ was synthesized by a novel chemical method in three steps including chloroacetylation of l-aspartic acid, esterification of chloroacetyl l-aspartic acid and ammonolysis of chloroacetyl l-aspartic acid diethyl ester. Secondly, the linkage of the third amino acid (Bz-Arg-OEt) to Gly-Asp-(NH₂)₂ was completed by enzymatic method under kinetic control condition. An industrial alkaline protease alcalase was used in water–organic cosolvents systems. The synthesis reaction conditions were optimized by examining the effects of several factors including water content, temperature, pH and reaction time on the yield of the synthesis product Bz-Arg-Gly-Asp(NH₂)OH. The optimum conditions are pH 8.0, 35 °C, in ethanol/Tris–HCl buffer system (85:15, v/v), 8 h with the tripeptide yield of 73.6%.     

在AOT/异辛烷反相胶束体系中酶法合成RGD前体二肽

近十年来,在有机相中利用酶法合成短肽技术取得了长足的发展．但对于在有机相中合成含有亲水氨基酸的短肽,仍然是一个难题．利用反相胶束可以解决亲水氨基酸在有机相中的低溶解性问题［１］．Ａｒｇ－Ｇｌｙ－Ａｓｐ（ＲＧＤ）是近年来发现的一种具有粘合细胞作用的三肽...     

Chemo-enzymatic synthesis of tripeptide RGD diamide in organic solvents

The tripeptide BzArgGlyAsp(NH(2))(2) was synthesized by a combination of chemical and enzymatic methods in this study. First of all, GlyAsp(NH(2))(2) was synthesized by a novel chemical method in three steps including chloroacetylation of L-aspartic acid, esterification of chloroacetyl L-aspartic acid and ammonolysis of chloroacetyl L-aspartic acid diethyl ester. Secondly, kinetically controlled synthesis of BzArgGlyAsp(NH(2))(2) catalyzed by trypsin in organic solvent was conducted. The optimum conditions are pH 8.0, 30 degrees C in ethanol/Tris-HCl buffer system (85:15, v/v) for 80 min in the maximum yield of 74.4%.     

Lipase-catalyzed synthesis of precursor dipeptides of RGD in aqueous water-miscible organic solvents

PPL-catalyzed synthesis of the precursor dipeptides of RGD as a cellular adhesion factor, Benzyl-Arg-Gly-NH2 and CBZ-Gly-Asp-NH2, was conducted in water-organic cosolvents systems. Five water-miscible organic solvents, which have some advantage over the water-immiscible organic solvent systems or the anhydrous organic solvent systems used often in protease-catalyzed synthesis of a peptide bond, were tested. The reaction condition of PPL-catalyzed synthesis of the dipeptides was optimized by examining the main factors affecting the product yield. The optimal reaction condition for the synthesis of Benzyl-Arg-Gly-NH2 was set up as pH 8.0, 15 degrees C in 40% MeOH for 10 h with the maximum yield of 73.6%. The optimum condition for the synthesis of CBZ-Gly-Asp-NH2 was pH 7.0, 15 degrees C in 50% MeOH for 10h with the maximum yield of 67.0%.     

Protease-catalyzed tripeptide (RGD) synthesis

The tripeptide Bz-Arg-Gly-Asp(-OMe)-OH was synthesized by enzymatic method. Bz-Arg-Gly-OEt was synthesized by trypsin in ethanol containing 0.1 M Tris/HCl buffer (pH 8.0), and then H-Asp(-OMe)(2) was incorporated into the Bz-Arg-Gly-OEt using chymopapain in 0.25M CHES/NaOH buffer (pH = 9.0, EDTA 10 mM). The yield of Bz-Arg-Gly-OEt and Bz-Arg-Gly-Asp(-OMe)-OH were 80% and 70% using 1M Bz-Arg-OEt and 0.5M Bz-Arg-Gly-OEt, respectively. For Bz-Arg-Gly-OEt synthesis reaction at high concentrations of the substrates, the buffer content in ethanol was a key factor to determine the optimal reaction condition. In Bz-Arg-Gly-Asp(-OMe)-OH synthesis reaction, the yield was low in organic solvent due to various side products such as Bz-Arg-OH, Bz-Arg-Gly-OH, and Bz-Arg-Gly-Asp(-OMe)-Asp(-OMe)-OH, suggesting that chymopapain has a very broad substrate specificity of the S(1) site. The Bz-Arg-Gly-Asp(-OMe)-OH synthesis rate and its yield were dramatically elevated and the side reactions were reduced using only the CHES/NaOH buffer (pH = 9.0, EDTA 10 mM) as a reaction media. The final product Bz-Arg-Gly-Asp(-OMe)-OH was identified to be formed via C-terminal hydrolysis of Bz-Arg-Gly-Asp(-OMe)(2) after the nucleophile, H-Asp(-OMe)(2), was added.     

Enzymatic peptide synthesis in organic media: a comparative study of water-miscible and water-immiscible solvent systems.

Peptide synthesis was carried out in a variety of organic solvents with low contents of water. The enzyme was deposited on the support material, celite, from an aqueous buffer solution. After evaporation of the water the biocatalyst was suspended in the reaction mixtures. The chymotrypsin-catalyzed reaction between Z-Phe-OMe and Leu-NH2 was used as a model reaction. Under the conditions used ([Z-Phe-OMe]0 less than or equal to 40 mM, [Leu-NH2]0/([Z-Phe-OMe]0 = 1.5) the reaction was first order with respect to Z-Phe-OMe. Tris buffer, pH 7.8, was the best buffer to use in the preparation of the biocatalyst. In water-miscible solvents the reaction rate increased with increasing water content, but the final yield of peptide decreased due to the competing hydrolysis of Z-Phe-OMe. Among the water-miscible solvents, acetonitrile was the most suitable, giving 91% yield with 4% (by vol.) water. In water-immiscible solvents the reaction rate and the product distribution were little affected by water additions in the range between 0% and 2% (vol. %) in excess of water saturation. The reaction rates correlated well with the log P values of the solvent. The highest yield (93%) was obtained in ethyl acetate; in this solvent the reaction was also fast. Under most reaction conditions used the reaction product was stable; secondary hydrolysis of the peptide formed was normally negligible. The method presented is a combination of kinetically controlled peptide synthesis (giving high reaction rates) and thermodynamically controlled peptide synthesis (giving stable reaction products).     

Stability and catalytic properties of chemically modified pig trypsin

Pig trypsin was chemically modified with the bifunctional compound ethylene glycol-bis(succinic acid N-hydroxysuccinimide ester) to yield EG-trypsin. EG-trypsin showed greater thermal stability (100% active beyond 100 min at 55°C; native only 53% active at 100 min) together with slightly increased tolerance toward some organic solvents. Arg/Lys hydrolysis ratio changed little. Esterase/amidase activity ratio of EG-trypsin in buffer was 11-fold greater than that of native pig trypsin, but 5-fold less in 30% v/v acetonitrile. In buffer, EG-trypsin synthesized the dipeptide benzoyl-Arg-Leu-NH₂ at a 3-fold higher rate than native trypsin, but native trypsin outperformed EG-trypsin in 30% v/v acetonitrile.     

Enantioselective synthesis of (S)‐naproxen using immobilized lipase on chitosan beads

S‐naproxen by enantioselective hydrolysis of racemic naproxen methyl ester was produced using immobilized lipase. The lipase enzyme was immobilized on chitosan beads, activated chitosan beads by glutaraldehyde, and Amberlite XAD7. In order to find an appropriate support for the hydrolysis reaction of racemic naproxen methyl ester, the conversion and enantioselectivity for all carriers were compared. In addition, effects of the volumetric ratio of two phases in different organic solvents, addition of cosolvent and surfactant, optimum pH and temperature, reusability, and inhibitory effect of methanol were investigated. The optimum volumetric ratio of two phases was defined as 3:2 of aqueous phase to organic phase. Various water miscible and water immiscible solvents were examined. Finally, isooctane was chosen as an organic solvent, while 2‐ethoxyethanol was added as a cosolvent in the organic phase of the reaction mixture. The optimum reaction conditions were determined to be 35 °C, pH 7, and 24 h. Addition of Tween‐80 in the organic phase increased the accessibility of immobilized enzyme to the reactant. The optimum organic phase compositions using a volumetric ratio of 2‐ethoxyethanol, isooctane and Tween‐80 were 3:7 and 0.1% (v /v/v), respectively. The best conversion and enantioselectivity of immobilized enzyme using chitosan beads activated by glutaraldehyde were 0.45 and 185, respectively.     

Solvent selection and optimization of α‐chymotrypsin‐catalyzed synthesis of N‐Ac‐Phe‐Tyr‐NH2 using mixture design and response surface methodology

A peptide, N‐Ac‐Phe‐Tyr‐NH₂, with angiotensin I‐converting enzyme (ACE) inhibitor activity was synthesized by an α‐chymotrypsin‐catalyzed condensation reaction of N‐acetyl phenylalanine ethyl ester (N‐Ac‐Phe‐OEt) and tyrosinamide (Tyr‐NH₂). Three kinds of solvents: a Tris–HCl buffer (80 mM, pH 9.0), dimethylsulfoxide (DMSO), and acetonitrile were employed in this study. The optimum reaction solvent component was determined by simplex centroid mixture design. The synthesis efficiency was enhanced in an organic‐aqueous solvent (Tris‐HCl buffer: DMSO: acetonitrile = 2:1:1) in which 73.55% of the yield of N‐Ac‐Phe‐Tyr‐NH₂ could be achieved. Furthermore, the effect of reaction parameters on the yield was evaluated by response surface methodology (RSM) using a central composite rotatable design (CCRD). Based on a ridge max analysis, the optimum condition for this peptide synthesis included a reaction time of 7.4 min, a reaction temperature of 28.1°C, an enzyme activity of 98.9 U, and a substrate molar ratio (Phe:Tyr) of 1:2.8. The predicted and the actual (experimental) yields were 87.6 and 85.5%, respectively. The experimental design and RSM performed well in the optimization of synthesis of N‐Ac‐Phe‐Tyr‐NH₂, so it is expected to be an effective method for obtaining a good yield of enzymatic peptide. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2012     

Peptide synthesis of aspartame precursor using organic-solvent-stable PST-01 protease in monophasic aqueous-organic solvent systems

The PST-01 protease is a metalloprotease that has zinc ion at the active center and is very stable in the presence of water-soluble organic solvents. The reaction rates and the equilibrium yields of the aspartame precursor N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester (Cbz-Asp-Phe-OMe) synthesis from N-carbobenzoxy-L-aspartic acid (Cbz-Asp) and L-phenylalanine methyl ester (Phe-OMe) in the presence of water-soluble organic solvents were investigated under various conditions. Higher reaction rate and yield of Cbz-Asp-Phe-OMe were attained by the PST-01 protease when 30 mM Cbz-Asp and 500 mM Phe-OMe were used. The maximum reaction rate was obtained pH 8.0 and 37 degrees C. In the presence of dimethylsulfoxide (DMSO), glycerol, methanol, and ethylene glycol, higher reaction rates were obtained. The equilibrium yield was the highest in the presence of DMSO. The equilibrium yield of Cbz-Asp-Phe-OMe using the PST-01 protease attained 83% in the presence of 50% (v/v) DMSO.     

A two-step, one-pot enzymatic synthesis of ampicillin from penicillin G potassium salt

A two-step, one-pot synthesis of ampicillin from penicillin G potassium salt (PGK) in aqueous buffer/organic co-solvent has been achieved. Ethylene glycol (EG) was chosen as the organic co-solvent. Factors including co-solvent content, enzyme loading, reaction temperature and substrate concentration were investigated. The optimum conditions were as follow: pH 8.0 phosphate buffer solution, 50% EG (v/v), 25 °C, 100 mM PGK and 300 mM d-phenylglycine methyl ester (D-PGM), 43.2 IU/ml IPA-750. The maximum yield was 57.3% after a reaction time of 17 h. It is the first report about the synthesis of ampicillin from penicillin G potassium salt in one-pot combining the enzymatic hydrolysis and the subsequent enzymatic condensation, and the novel methodology will have important application in the β-lactam antibiotics industry.     

Enzymatic semisynthesis of [LeuB30] insulin

Experimental conditions for the preparation of [LeuB30] insulin by coupling of des-AlaB30 insulin with Leu-OBu(t) were determined using Achromobacter protease I and trypsin as catalysts. Successful coupling required a large excess of the amine component (0.8 M), a high concentration of organic cosolvent (35-50%) and neutral pH of the reaction mixture. The coupling yield of Achromobacter protease I after 24 h at 37 degrees C was almost the same or a little higher than that at 25 degrees C. With trypsin, the coupling yield at 37 degrees C after 24 h was considerably lower than at 25 degrees C. This was partly ascribed to the difference in concentration of organic cosolvent at 37 degrees C and 25 degrees C; 35% and 50%, respectively, or possibly of enzyme stability at these temperatures. The maximum product yield was about 90% with both enzymes under optimal conditions. A preparative scale experiment was performed with Achromobacter protease I; the yield of [LeuB30] insulin was 51% using porcine insulin as the starting material. This semisynthetic insulin was identified by HPLC and amino acid analysis. No difference was observed in CD spectra between [LeuB30] insulin and human insulin.     

Peptide synthesis with a proteinase from the extremely thermophilic organism Thermus Rt41A

A proteinase isolated from Thermus RT41a was immobilized to controlled pore glass beads and was used in the free and immobilized forms for peptide synthesis. The observed maximum yield was the same in both cases. a number of dipeptides were produced from amino acid esters and amides. The best acyl components, from those tested, were found to be Ac-Phe-OEt and Bz-Ala-OMe. Tur-NH(2), Trp-NH(2), Leu-pNA, and Val-pNA were all reactive nucleophiles.The kinetically controlled synthesis of Bz-ala-Tyr-NH(2) was optimized by studying the effect of pH, temperature, solvent concentration, ionic strength, and nucleophile and acyl donor concentration, ionic strength, and nucleophile and acyl donor concentration on the maximum yield. The initial conditions used were 25 mM Bz-ala-OMe, 25 mM Tyr-NH(2), 70 degrees C, pH 8.0, and 10% v/v dimethylformamide (DMF). The optimum conditions were 90% v/v DMF using 80 mM bz-Ala-OMe and 615 mM Tyr-NH(2) at 40 degrees C and pH 10. These conditions increased the maximum conversion from 0.75% to 26% (of the original ester concentration). In a number of other cosolvents, the best peptide yields were observed with acetonitrile and ethyl acetate. In 90% acetonitrile similar yields were observed to those in 90% DMF under optimized conditions except that the acyl donor and nucleophile concentrations could be reduced to 25 mM and 100mM, respectively. The effect of the blocking group on the nucleophile was also investigated; -betaNA and -pNA as blocking groups improved the yields markedly. The blocking and leaving groups of the acyldonor had no effect on the dipeptide yield. (c) 1994 John Wiley & Sons, Inc.     

Effects of subzero temperatures on the kinetics of protease catalyzed dipeptide synthesis in organic media

A depeptide synthesis was drastically influenced by the reaction temperature, in the range from -30 degrees to 25 degrees C. This article shows the kinetic reasons of this effect. alpha-Chymotrypsin was immobilized on celite and used in four different water-miscible solvents containing small amounts of water-miscible solvents containing small amounts of water. The reaction studied was the aminolysis of N-acetyl-L-phenylalanine ethyl ester (Ac-PheOEt) with L-alaninamide (Ala-NH(2)) and water for the acylenzyme complex, the nucleophile was favoured by low reaction temperatures. This effect (quantified as p-values) was observed in all four solvents, and it was greatest in acetonitrile and tetrahydrofuran. The esterase and amidase activities of the enzyme were studies using AcPheOEt and N-acetyl-L-phenylalanyl-L-ananinamide (AcPheAla-NH(2)) as substrates. The Michaelis-Menten parameters, K(m,app) and V(max), were determined for ester hydrolysis and dipeptide hydrolysis. Both K(m,app) and V(max) tended to increase with increasing temperature. Secondary hydrolysis was reduced at subzero temperatures because ester hydrolysis was favoured in relation to depeptide hydrolysis. Depeptide synthesis was thus favored by low temperatures in two ways: first, in the competition between the nucleophile and water for the acyl enzyme; and, second, in the competition between the ester substrate and the peptide substrate for the free enzyme. As a result, in acetonitrile containing 10% water, the maximal yield was 99% at -20%C compared with 84% at 25 degrees C. (c) 1995 John Wiley & Sons, Inc.