两种树脂对固相法合成丙型肝炎疫苗多肽的影响

本实验采用固相法合成丙型肝炎疫苗多肽,比较Wang树脂和二氯三苯甲基树脂（以下简称二氯树脂）作为载体时的连接率以及目标肽的产率和纯度。通过质谱鉴定分析所得目标多肽的分子量,用茚三酮法对两种树脂与氨基酸的连接率进行比较,用反相高效液相色谱（RP-HPLC）进行粗肽的分析和纯化。结果显示以二氯树脂作载体,第一个氨基酸的连接率,以及目标肽的纯度和产率都要明显高于Wang树脂,因此二氯树脂作载体合成丙型肝炎疫苗多肽更适合大规模工业化生产的要求。     

生物活性肽SSDI固相合成工艺的研究

目的:研究生物活性肤SSDI的固相合成工艺,并为大规模合成目标肽提供理论依据.方法:采用固相合成法,原料氨基酸以Fmoe形式保护,用Wang树脂为载体,经1-氧3-双二甲胺羰基苯骈三氮唑四氟化硼盐(TBTU)\1-羟基-苯并-三氮唑(HOBt)\二-异丙基乙胺(DIEA)混合试剂缩合,20%哌啶的DMF溶液脱保护,用三氟乙酸\茴香硫醚\巯基乙醇\苯酚\水混合作为切割试剂将多肽从Wang树脂上切割下来.结果:多肽粗品的得率高达70%,经RP-HPLC纯化,可获得纯度在98%以上的目标肽,经MALDI-MS质谱鉴定其分子量与理论值一致.结论:此合成方法操作简单,产品得率高,适合大规模合成目标肽.     

固相法合成多肽AN-M的工艺研究

目的:探讨生物活性肽AN-M的固相合成工艺,并为工业化合成目的肽提供理论依据。方法采用固相法,以Fmoc-保护基保护的α-氨基酸和Wang树脂为原料,经1—氧—3—双二甲胺羧基苯骈三氮唑四氟化硼盐(TBTU)、1—羟基苯并三氮唑(HoBt)、二异丙基乙胺(DIEA)缩合,20%哌啶的DMF溶液脱保护,用切割试剂将AN-M粗品从Wang树脂上切割下来。结果经反相高效液相色谱分析纯化,可得目的肽的得率大于67．00%,最终成品的纯度在98．78%以上,经质谱鉴定其分子量与理论值一致。结论该合成方法步骤简便、便于操作、产品得率高,可用于大规模合成目的肽。     

人脑利钠肽的Fmoc固相合成

探讨生物活性肽人脑利钠肽(BNP)的固相合成工艺,并为工业化合成提供理论依据.本文以二氯三甲基树脂(以下简称为二氯树脂)为载体,采用9-芴甲氧羰基(Fmoc)保护的氨基酸,以1-氧-3-双二甲胺羰基苯骈三氮唑四氟化硼盐(TBTU)/1-羟基苯并三氮唑(HOBT)/二异丙基乙胺(DIEA)缩合,以碘作为环化试剂,用切割试剂将BNP粗品从树脂上切割下来.通过MALDI-MS质谱仪检测,所合成环肽的分子量与理论分子量一致,使用RP-HPLC液相色谱仪对合成的环肽进行纯化,得到的BNP纯度达到97%以上.本合成工艺具有快捷、简便、高效的特点,适合于大批量的生产目的肽.     

Fmoc固相合成JFT的工艺研究

目的:研究多肽JFT的合成工艺。方法:本实验采用固相合成法(spps),以Fmoc—氨基酸为原料,TBTU\HoBt\DIEA混合试剂缩合,用三氟乙酸\苯甲硫醚\巯基乙醇\苯酚\水脱保护,将多肽从MBHA树脂上切割下来。结果:粗肽的收率为62%,经RP-HPLC纯化,即可获得纯度在98%以上的目标肽。经MALDI—MS质谱分析其分子量与理论值一致。结论:此工艺操作简单,便于推广,适合大规模生产。     

多肽固相序列分析载体的合成及应用

用合成的聚合物作载体,与模型15肽(纯品)偶联,使用Edman降解法进行多肽序列分析。比较了各种类型载体对肽的偶联效果。实验结果表明合成的大孔型四次乙基五胺类树脂载体已经达到国外同类产品水平。     

降钙素基因相关肽的合成

降钙素基因相关肽是一个包含有37个氨基酸残基的具有较强降血压生理功能的活性多肽。我们采用常规的固相合成方法,以简单的装置最后经无水氟化氢处理,将肽从树脂上切下,同时脱除所有侧链保护基。粗产物在30％乙酸溶液中用碘作为氧化剂使二个半胱氨酸氧化,形成二硫键。合成的α-人降钙素基因相关肽经反向高效液相层析分离,获得在高效液相层析为单一峰的产物。经酸水解氨基酸分析证明与理论值相符并具有全部生理活性。     

虎纹捕鸟蛛毒素-Ⅰ的化学合成及其结构与生理活性分析

应用芴甲氧羰基(Fmoc)固相方法化学合成了虎纹捕鸟蛛毒素-I,合成采用Fmoc氨基酸五氟苯酯,各侧链保护措施如下:羧基和酚羟基用叔丁基(tBu)保护,赖氨酸和组氨酸侧链用叔丁氧羰基(Boc)保护,精氨酸胍基用4-甲氧-2,3,6-三甲基苯磺酰基(Mtr)保护,半胱氨酸巯基用三苯甲基(Trt)保护.固相载体为需活化的乙二胺-聚乙二醇-聚苯乙烯(EDA-PEG-PS)树脂.合成产物(肽树脂)用苯甲硫醚-乙二硫醇-苯甲醚-三氟乙酸系统一步裂解以及去除侧链保护基,然后用二硫苏糖醇(DTT)还原,再通过氧化型和还原型谷胱甘肽系统促使其形成正确的二硫键配对.对HPLC分离纯化得到的合成产物,进行了氨基酸组成、肽谱、氨基酸顺序以及一维核磁共振谱分析.分析结果表明合成毒素具有与天然毒素相同的化学结构和空间构象.生理实验结果表明,其生物学活性与天然Huwentoxin-I也相同.     

镇痛多肽——内吗啡肽-1的人工合成及活性研究

 用液相合成方法合成了具有镇痛作用的μ阿片受体的内源性配体——内吗啡肽 - 1(endomorphin- 1 ) ,该四肽为 Tyr- Pro- Trp- Phe NH2 .液相合成法是在氨基酸的 N端用 Boc(叔丁氧羰酰基 )作保护基 ,C端用 HOSu(N-羟基琥珀酰亚胺 )活化 ,与未加保护基的氨基酸在碱性条件下接肽 .先分别合成 C端二肽和 N端二肽 ,再缩合为四肽 ,产物的保护基用盐酸脱帽去除 .中间产物用薄层层析和熔点鉴定其纯度 ,最终得到了高纯度的四肽 .小白鼠脑室注射 (i.c.v)测定表明 ,8.2 5nmol剂量给药 ,其镇痛活性为 87% ,明显高于吗啡 (morphine) .     

杂环肽FIK的Fmoc固相合成法研究

为研究二硫键成环的杂环肽FIK的合成工艺, 以Fmoc氨基酸为原料, 采用固相合成法, 经TBTU/HOBT/DIEA复合缩合剂催化合成直链肽, 再经I2氧化肽链上两个半胱氨酸的巯基生成分子内二硫键而得到目标环肽, 将其用切割试剂切割脱离树脂得到粗产品, MALDI-MS和RP-HPLC进行鉴定, 分析和纯化。产率可以达到18%, 纯化后纯度达97%以上, 经MALDI-MS和Ellman试剂检测确定为目标肽。该合成法高效, 简便, 快速, 目标肽收到较理想产率, 适合大批量生产。     

Improving the performance of an acid-labile 4-hydroxymethyl phenoxyacetic acid (HMP) linker on resin and SynPhase grafted solid-supports.

A replacement of the acetic acid moiety by valeric acid within the 4-hydroxymethylphenoxyacetic acid (HMP) linker (Sheppard RC, Williams BJ. Acid-labile resin linkage agents for use in solid phase peptide synthesis. Int. J. Peptide Protein Res. 1982; 20: 451-454) significantly improved its performance in terms of loading capacity, yield and purity of the final products. The results indicated the spacer-linker combination and type of solid supports are important factors for solid-phase synthesis.     

Comparison of the solid-phase fragment condensation and phase-change approaches in the synthesis of salmon I calcitonin.

Salmon I calcitonin was synthesized using both phase-change and conventional solid-phase fragment condensation (SPFC) approaches, utilizing the Rink amide linker (Fmoc-amido-2,4-dimethoxybenzyl-4-phenoxyacetic acid) combined with 2-chlorotrityl resin and the Fmoc/tBu(Trt)-based protection scheme. Phase-change synthesis, performed by the selective detachment of the fully protected C-terminal 22-mer peptide-linker from the resin and subsequent condensation in solution with the N-terminal 1-10 fragment, gave a product of slightly less purity (85 vs. 92%) than the corresponding synthesis on the solid-phase. In both cases salmon I calcitonin was easily obtained in high purity.     

Novel heterobifunctionalized polystyrene-polyethylene glycol resin for simultaneous preparation of free and immobilized peptides and biological activity detected by confocal microscopy

Summary Fast and convenient binding assays using synthetic peptides are of utmost and increasing importance, especially in the search for lead structures or in the field of diagnostics. A polymeric support suitable for solid-phase peptide synthesis was functionalized with two different anchor groups. The interior part of the aminomethylated polystyrene-1%-divinylbenzene resin beads, comprising about 98% of the total loading capacity, was modified by the acid-labile ADPV anchor whereas the 2% outer surface of the polymer was covalently coated with a PEG 10 000 derivative which renders the resin surface hydrophilic and biocompatible. The novel resin was characterized by introducing marker amino acids and by infrared spectroscopy. Employing this bifunctionalized resin for peptide synthesis, free as well as polymer-bound peptides were obtained which were tested for recognition by antibody. The resin-bound peptides proved to be suitable for ELISA and fluorescence assays, as shown by confocal laser microscopic investigations. Peptides from the interior part were obtained in high yield and purity as analyzed by HPLC, electrospray mass spectrometry and Edman degradation.     

Peptides Derived from α-hydroxymethylserine: Aspects of solid-phase synthesis

Summary The solid-phase synthesis of peptides derived from the sterically hindered α-hydroxymethylserine (HmS) was investigated. The acid-sensitive,O,O-isopropylidene (Ipr) protection of HmS is compatible with the Fmoc chemistry, represented here by the Fmoc-HmS(Ipr)-OH and Fmoc-HmS(Ipr)-F derivatives. Three analogs of the opioid pentapeptide DADLE with a single or two consecutive HmS residue(s) were synthesized using Wang resin as the solid support. The HATU method has been shown to effectively accomplish ‘difficult’ couplings with the HmS(Ipr) residue. Wang resin is not suitable, for the synthesis of sequences with a C-terminal HmS because of the easy formation of the diketopiperazine resulting from the cyclization of the susceptible dipeptide sequence AA-HmS(Ipr) bound to the resin. A further drawback of the Wang resin methodology is the increased danger of the undersired N→O-acyl shift, when long-lasting acidic cleavage is applied. These side reactions are totally suppressed when the 2-chlorotrityl polystyrene is used as a solid support. The mild conditions (AcOH/TFE/DCM) applied for the peptide detachment from this resin do not affect the Ipr protection, affording highly pure fragments with HmS(Ipr) residues suitable for post-cleavage condensation, cyclization or controlled side-chain deprotection. This approach is documented by the efficient synthesis of linear and cyclic analogs of the opioid hexapeptide DTLET containing two residues of HmS or HmS(Ipr) in positions 2 and 6.     

Solid phase synthesis of peptide hydroxamic acids on poly(ethylene glycol)‐based support

A novel resin designed for solid‐phase synthesis of peptide hydroxamic acids (PHA) combining the trityl linker with poly(ethylene glycol)‐based support, ChemMatrix® type, is described. The synthesis of PHA can be performed according to a standard protocol, providing products in excellent purity and reasonable yields. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

A simple oxazolidine linker for solid-phase synthesis of peptide aldehydes

A very simple and cheap linker has been used for solid-phase synthesis of peptide aldehydes. Protected amino acid aldehydes are immobilized on 2-Cl(trt) resin as oxazolidine formation via diethanolamine. After classical Fmoc SPPS, treatment of the resin with AcOH/DCM/H(2)O (8:1:1) affords peptide aldehydes in high yield and purity.     

Synthesis of cyclic penta- and hexapeptides: A general synthetic strategy on DAS resin

The active part or receptor-binding sequence of peptide hormones can usually be defined by a span of 4–8 amino acids. Cyclic penta- and hexapeptides are excellent model systems for performing conformational and structure-function studies on this class of bioactive molecules. A synthetic scheme has been devised comprising solid-phase Fmoc chemistry followed by resin cleavage, cyclization in solution, and, finally, side-chain deprotection. A new resin, DAS, cleaved under weak acid conditions, is an excellent solid-phase synthesis support, and HBTU or PyBOP are the activation reagents of choice, not only during synthesis, but also for the cyclization reaction. Three cyclic peptides were synthesized using this method, one requiring extensive side-chain protection, and this method has general applicability for any cyclic pentapeptide or hexapeptide, giving good yields and high purity.     

Syntheses of four peptides from the immunodominant region of hepatitis C viral pathogens using PS-TTEGDA support for the investigation of HCV infection in human blood.

Four peptides were designed and synthesized on a highly solvating copolymer of tetraethyleneglycol diacrylate cross-linked polystyrene (PS-TTEGDA) support with very high purity and yield. The polymer was synthesized in various cross-linking densities (1, 2, 3, 4, 5 and 10%) using radical aqueous suspension polymerization. Four per cent PS-TTEGDA resin showed rigidity and mechanical characteristics comparable with those of divinylbenzene cross-linked polystyrene (PS-DVB) support. Swelling and solvation characteristics of PS-TTEGDA were much higher than PS-DVB support in all solvents used in solid-phase peptide synthesis. Forty-eight hour treatment of the support with neat trifluoroacetic acid did not show any change in its infrared spectra. PS-TTEGDA could be functionalized with chloromethyl, aminomethyl and hydroxymethyl functional groups under various controlled conditions. Synthetic utility of the support was demonstrated by the synthesis of four peptides selected from the envelope and nonstructural protein region of the prototype hepatitis C virus (HCV). These peptides were later used successfully to develop a peptide-based immunoassay (PBEIA) for the detection of HCV immunity. Peptides designed from the NS1 and NS4 protein regions were found to be very promising for the development of a new diagnostic kit to detect HCV infection in human blood. Peptide purity was tested by RP-FPLC and the peptide identity was confirmed by amino acid analysis.