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...     

Combined solid-phase and solution approach for the synthesis of large peptides or proteins.

In the synthesis of large peptides or proteins, highly homogeneous segments are indispensable for a convergent strategy either on a solid-phase resin or in solution. Employing Boc/Bzl chemistry to prepare fully protected segments with a free alpha-carboxyl group from the solid support, base-labile linkers are profitable for practical peptide synthesis since they require no special equipment. For this purpose, an N-[9-(hydroxymethyl)-2-fluorenyl]succinamic acid (HMFS) linker was adopted. Consequently, there must be high compatibility between the protecting groups of the segment and the anchoring group which is cleavable by treatment with morpholine or piperidine in DMF. Instead of using the 2-bromobenzyloxycarbonyl (BrZ) group for the Tyr residue and the formyl (For) group for the Trp residue, both of which are the most susceptible protecting groups under these base-catalysed conditions, the base-resistant 3-pentyl (Pen) and cyclohexyloxycarbonyl (Hoc) groups were introduced to the respective side-chain functional groups. By applying the present strategy, the authors were able to rapidly synthesize homogeneous protected segments for use in the subsequent segment coupling in solution. In the present paper, the utility of the combined solid-phase and solution approach is demonstrated by synthesizing muscarinic toxin 1 (MTX1) which binds to the muscarinic acetylcholine receptors.     

Group separation of peptides by ligand-exchange chromatography with a Sephadex containing N-(2-pyridylmethyl)glycine

The synthesis of 2-hydroxy-3[N-(2-pyridylmethyl)glycine]propyl Sephadex ether--a new chelating resin--is described. This resin has been employed in the form of its Cu2+ complex to separate peptides, as a group, from alpha-amino acids and NaCl. Ninety-seven ligands of different structures were separated chromatographically at room temperature. It was shown that two structural parameters of the ligands control the separation process, namely, the presence of ligand donor groups and the possibility for them to form chelate rings of suitable size. Separation of peptides from alpha-, gamma-, delta-amino acids, N-acetyl derivatives of amino acids (except N-Ac-Trp), and NaCl is possible if the peptides fulfill the following structural requirements: the peptide molecule must have a free terminal amino group; a carbonyl group (of the peptide linkage) must be situated in the alpha- or beta-position of the free amino group; and the peptide may not contain an imidazole residue (except Gly-Gly-His). A relationship was found between the log k' and the corresponding pKHHL, log KCuCuL, and log KCuBipyCuBipyL values. Interpretation of the different K' values was possible based on the different basicities of the terminal amino groups and on the structures of the different side chains of the peptides.     

N(3)‐Protection of Thymidine with Boc for an Easy Synthetic Access to Sugar‐Alkylated Nucleoside Analogs

The use of Boc as a nucleobase‐protecting group in the synthesis of sugar‐modified thymidine analogs is reported. Boc was easily inserted at N(3) by a simple and high‐yielding reaction and found to be stable to standard treatments for the removal of Ac and ^tBuMe₂Si (TBDMS) groups, as well as to ZnBr₂‐mediated 4,4′‐dimethoxytrityl (DMTr) deprotection. Boc Protection proved to be completely resistant to the strong basic conditions required to regioselectively achieve O‐alkylation, therefore, providing synthetic access to a variety of sugar‐alkylated nucleoside analogs. To demonstrate the feasibility of this approach, two 3′‐O‐alkylated thymidine analogs have been synthesized in high overall yields and fully characterized.     

Thia-analogues of amino acids synthesis of peptide derivatives containing 3-thia-analogues of amino acids

Summary N-Protected dipeptides containing L-3-thia-analogues of phenylalanine, p-nitro-phenylalanine, lysine and leucine respectively were prepared applying an enantioselective enzymatic reaction step. Racemic synthetic intermediates of the type acyl-NH-CH(R¹)-CO-D,L-NH-CH(S-R²)-COOBzl were selectively deprotected at the C-terminus by enzymatic hydrolysis using thermitase or trypsin.Abbreviations Ac acetyl - AcOEt ethyl acetate - AcOH acetic acid - Boc tert.-butyloxycarbonyl - Bz benzoyl - Bzl benzyl - DMF dimethyl-formamide - EtOH ethanol - THF tetrahydrofuran - Z benzyloxycarbonyl Dedicated to Prof. D. Cavallini at the occasion of his 75th birthday.     

Polypeptide synthesis using an expressed peptide as a building block for condensation with a peptide thioester: application to the synthesis of phosphorylated p21Max protein(1-101).

An expressed peptide proved to be useful as a building block for the synthesis of a polypeptide via the thioester method. A partially protected peptide segment, for use as a C-terminal building block, could be prepared from a recombinant protein; its N-terminal amino acid residue was transaminated to an alpha-oxoacyl group, the side-chain amino groups were then protected with t-butoxycarbonyl (Boc) groups, and. finally, the alpha-oxoacyl group was removed. On the other hand, an O-phosphoserine-containing peptide thioester was synthesized via a solid-phase method using Boc chemistry. These building blocks were then condensed in the presence of silver ions and an active ester component. During the condensation, epimerization at the condensation site could be suppressed by the use of N,N-dimthylformamide (DMF) as a solvent. Using this strategy, a phosphorylated partial peptide of the p21Max protein, [Ser(PO3H2)2.11]-p21Max(1-101), was successfully synthesized.     

Removal of acid-labile protecting or anchoring groups in the presence of polyfluorinated alcohol: Application to solid-phase peptide synthesis

We describe herein a new method for cleaving from resin and removing acid-labile protecting groups in solid-phase peptide synthesis in the presence of a polyfluorinated alcohol (either trifluoroethanol, TFE, or hexafluoroisopropanol, HFIP). It was shown that 0.1 M HCl in hexafluoroisopropanol or trifluoroethanol removes the acid-labile protecting groups commonly used in Fmoc SPPS for the protection of amino acid side-chains, such as t-butyl ester and ether, Boc, trityl, and Pbf groups including the most acid-resistant p-hydroxymethylphenoxyacetyl group (HMPA), p-benzyloxy benzyl ester (Wang resin), Rink amide, and peptide amide linker (PAL). The addition of 5–10% of a hydrogen-bonding solvent was shown to considerably retard or even fully inhibit the reaction. However, nonhydrogen-bonding solvents, such as dichloromethane, do not slow down the reaction.     

Characteristics of chymotrypsin modified with water-soluble acylating reagents and its peptide synthesis ability in aqueous organic media.

Several kinds of modified chymotrypsin were prepared with water-soluble acylating reagents, and their characteristics after hydrolyzing with unmodified chymotrypsin in aqueous-N,N'-dimethylformamide (DMF) media were compared. It was found that chymotrypsin (Csin), of which a 20% amino group was modified with a benzyloxycarbonyl group (Z(20)Csin), had more favorable characteristics than unmodified chymotrypsin with regard to hydrolytic activity in an aqueous DMF media. We also investigated the Z(20)Csin-catalyzed peptide synthesis in two different solution systems. In the one-layer system containing water and DMF, Z(20)Csin catalyzed the peptide bond formation in a higher yield than that by unmodifide chymotrypsin and enabled a synthetic reaction in even an 80% (v/v) DMF media, in which the hydrolytic reaction could not be carried out. Z(20)Csin catalyzed the condensation between some N-acyl amino acids or peptide derivatives and amino acids in 90% ethylacetate, 90% hexane or 50% benzene. This latter method employs a two-layer system, and the modified enzyme may be able to reduce the number of synthetic steps when preparing acyl peptides.     

Structures of Gibberellins A33 and A34 from Immature Seeds of Calonyction aculeatum

Several kinds of modified chymotrypsin were prepared with water-soluble acylating reagents, and their characteristics after hydrolyzing with unmodified chymotrypsin in aqueous-N,N’ -dimethylformamide (DMF) media were compared. It was found that chymotrypsin (Csin), of which a 20% amino group was modified with a benzyloxycarbonyl group (Z(20)Csin), had more favorable characteristics than unmodified chymotrypsin with regard to hydrolytic activity in an aqueous DMF media. We also investigated the Z(20)Csin-catalyzed peptide synthesis in two different solution systems. In the one-layer system containing water and DMF, Z(20)Csin catalyzed the peptide bond formation in a higher yield than that by unmodifide chymotrypsin and enabled a synthetic reaction in even an 80% (v/v) DMF media, in which the hydrolytic reaction could not be carried out. Z(20)Csin catalyzed the condensation between some N-acyl amino acids or peptide derivatives and amino acids in 90% ethylacetate, 90% hexane or 50% benzene. This latter method employs a two-layer system, and the modified enzyme may be able to reduce the number of synthetic steps when preparing acyl peptides.     

N(3)-protection of thymidine with Boc for an easy synthetic access to sugar-alkylated nucleoside analogs

The use of Boc as a nucleobase-protecting group in the synthesis of sugar-modified thymidine analogs is reported. Boc was easily inserted at N(3) by a simple and high-yielding reaction and found to be stable to standard treatments for the removal of Ac and (t) BuMe(2) Si (TBDMS) groups, as well as to ZnBr(2) -mediated 4,4'-dimethoxytrityl (DMTr) deprotection. Boc Protection proved to be completely resistant to the strong basic conditions required to regioselectively achieve O-alkylation, therefore, providing synthetic access to a variety of sugar-alkylated nucleoside analogs. To demonstrate the feasibility of this approach, two 3'-O-alkylated thymidine analogs have been synthesized in high overall yields and fully characterized.     

Synthesis of beta- and gamma-fluorenylmethyl esters of respectively N alpha-Boc-L-aspartic acid and N alpha-Boc-L-glutamic acid

The orthogonal synthesis of N alpha-Boc-L-aspartic acid-gamma-fluorenylmethyl ester and N alpha-Boc-L-glutamic acid-delta-fluorenylmethyl ester is reported. This is a four-step synthesis that relies on the selective esterification of the side-chain carboxyl groups on N alpha-CBZ-L-aspartic acid and N alpha-CBZ-L-glutamic acid. Such selectivity is accomplished by initially protecting the alpha-carboxyl group through the formation of the corresponding 5-oxo-4-oxazolidinone ring. Following side-chain esterification, the alpha-carboxyl and alpha-amino groups are deprotected with acidolysis. Finally, the alpha-amino group is reprotected with the t-butyl-oxycarbonyl (Boc) group. Thus aspartic acid and glutamic acid have their side-chain carboxyl groups protected with the base-labile fluorenylmethyl ester (OFm) and their alpha-amino groups protected with the acid-labile Boc group. These residues, when used in conjunction with N alpha-Boc-N epsilon-Fmoc-L-lysine, are important in the formation of side-chain to side-chain cyclizations, via an amide bridge, during solid-phase peptide synthesis.     

Convenient synthesis of a sialylglycopeptide-thioester having an intact and homogeneous complex-type disialyl-oligosaccharide

Access to glycopeptides with C-terminal thioester functionality is essential for the synthesis of large glycopeptides and glycoproteins through the use of native chemical ligation. Toward that end, we have developed a concise method for the synthesis of a glycopeptide thioester having an intact complex-type dibranched disialyl-oligosaccharide. The synthesis employed a coupling reaction between benzylthiol and a free carboxylic acid at the C-terminus of a glycopeptide in which the peptide side chains are protected. After construction of glycopeptide on the HMPB-PEGA resin through the Fmoc-strategy, the protected glycopeptide was released upon treatment with acetic acid/trifluoroethanol and then the C-terminal carboxylic acid was coupled with benzylthiol at -20 degrees C in DMF. For this coupling, PyBOP/DIPEA was found to be the best for the formation of the thioester, while avoiding racemization. Finally, the protecting groups were removed in good yield with 95% TFA, thus affording a glycopeptide-thioester having an intact and homogeneous complex-type disialyl-oligosaccharide.     

Convenient solid phase synthesis method for the preparation of cysteine C-terminally derivatized peptides

Summary This paper describes a novel solid phase peptide synthesis method for the systematic C-terminal modification of cysteine-containing peptides. In this method, cysteine is linked to chloromethylated polystyrene resin by its thiol functionality, followed by protection of the N-terminus and derivatization of the carboxylic acid to esters or amides. We report here on examples of the methodology and its application to the synthesis of Ac-Asp-cyclo(Cys-Gly-Pro-Cys)-NHBzl, a cyclic peptide amide. The method has been applied to the synthesis of complex esters as well as amides.Abbreviations Ac acetyl - AcN acetonitrile - Ac₂O acetic anhydride - AcOH acetic acid - Boc t-butyloxycarbonyl - BOP benzotriazol-1-yl-oxy-tris-(dimethylamino)-phosphonium hexafluorophosphate - Bzl benzyl - cHex cyclohexyl - DBU 1,8-diazabicyclo[5.4.0]-undec-7-ene - DCC N,N-dicyclohexylcarbodiimide - DCM dichloromethane - DIEA diisopropylethylamine - DMF dimethylformamide - DMS dimethylsulfide - HOB 1-hydroxybenzotriazole - MBzl 4-methyl benzyl - MeOH methanol - TEA triethylamine - TEAP triethylammonium phosphate - TFA trifluoroacetic acid     

p‐Methoxyphenol: A potent and effective scavenger for solid‐phase peptide synthesis

During the final step of t‐Boc/Bzl, solid‐phase peptide synthesis (SPPS)‐protecting groups from amino acids (aa) side chains must be removed from the target peptides during cleavage from the solid support . These reaction steps involve hydrolysis with hydrogen fluoride (HF) in the presence of a nucleophile (scavenger), whose function is to trap the carbocations produced during S_N1‐type reactions. Five peptide sequences were synthesised for evaluating p‐methoxyphenol effectiveness as a potent scavenger. After the synthesis, the resin–peptide was then separated into two equal parts to be cleaved using two scavengers: conventional reactive p‐cresol (reported in the literature as an effective acyl ion eliminator) and p‐methoxyphenol (hypothesised as fulfilling the same functions as the routinely used scavenger). Detailed analysis of the electrostatic potential map (EPM) revealed similarities between these two nucleophiles, regarding net atomic charge, electron density distribution, and similar pKa values. Good scavenger efficacy was observed by chromatography and mass spectrometry results for the synthesised molecules, which revealed that p‐methoxyphenol can be used as a potent scavenger during SPPS by t‐Boc/Bzl strategy, as similar results were obtained using the conventional scavenger.     

Use of the excluded protecting group (EPG) method for peptide synthesis.

The excluded protecting group (EPG) method has been used for the solution synthesis of several peptides including Merrifield's Model Tetrapeptide, linear antamanide and an analogue of magainin-1, [Ala(19), Asn(22)]magainin-1. In the approach reported, the C-terminal amino acid is esterified to the 2-position of cholestane as the [2s,3s]iodohydrin ester and the penultimate amino acid added to the aminoacyl-steroid as the Fmoc-pentafluorophenyl-ester. The Fmoc group is removed with Et(2)NH/DMF ( approximately 15% v/v) and, after evaporation to approximately 10 mL, the solution chromatographed on Sephadex LH-20 in DMF. The dipeptidyl-steroid elutes as the free amine well separated from other reaction mixture components. Fractions containing the dipeptide, as determined by counting and TLC, are pooled and reacted with the next Fmoc-amino acid-pentafluorophenyl ester in the sequence. Repetition of the deprotection/purification/reaction cycle yields the fully protected peptide.On completion of the synthesis, the cholestane iodohydrin ester is selectively removed by treatment with Zn degrees /AcOH to yield the peptide with intact alpha-amino and side chain protecting groups. Global deprotection is achieved with HF. All intermediates from the syntheses reported were characterized. The magainin analogue was shown to have full biologic activity. The Fmoc iodohydrin esters of 16 of the 20 proteogenic amino acids have been prepared and characterized for use as the C-terminal amino acids in other EPG syntheses.     

Synthesis of labelled PNA oligomers by a post-synthetic modification approach

The preparation of t-butoxycarbonyl (Boc)-protected O(4)-(o-nitrophenyl) thymine peptide nucleic acid (PNA) monomer is described. This PNA monomer was incorporated into PNA oligomer sequences. The post-synthetic modification of the oligomers to yield fluorescently-labelled PNA oligomers was studied before and after the removal of the protecting groups. In both cases, the desired fluorescently-labelled PNA oligomer was obtained in good yields.     

A side reaction in solid phase synthesis. Insertion of glycine residues into peptide chains via Nim----N alpha transfer

In solid-phase peptide synthesis using N alpha-Boc-Nim-tosyl-histidine (Boc-His(Tos)), byproducts having extra Gly residues in the peptide chain were observed at a high rate. When a Boc-amino acid such as Asn was incorporated after assembly of Boc-His(Tos), the Nim-tosyl group was partially or fully cleaved by an activating agent, 1-hydroxybenzotriazole. In the successive coupling reactions, Boc-Gly was incorporated into the free Nim ring as well as the alpha-amino function, and the Nim-Gly was then transferred to the alpha-amino group of Gly of the peptide chain after removal of these Boc groups to give extra Gly residues at the position of Gly. This was observed in only the coupling reaction with Boc-Gly and could be circumvented using a more stable Nim protecting group for His, such as a dinitrophenyl group.     

Relationship between lipophilicity and antitumor activity of molecule library of Mannich ketones determined by high-performance liquid chromatography, clogP calculation and cytotoxicity test

A series of Mannich ketones were synthesized in order to study the relative importance of structure and specific substitutions in relation to their lipophilicity and antitumor activity. Substitutions were carried out with morpholinyl, pirrolidinyl, piperidyl and tetrahydro-isoquinolyl groups in various positions on three different skeletons. Lipophilicity of Mannich ketones was characterised by chromatography data (log k') and by software calculated parameters (clogP). Compounds were tested on their ability to inhibit the proliferation of the A431 human adenocarcinoma cell line evaluated by MTT and apoptosis assays. The results suggest that the higher the lipophilicity values (log k' and clogP), the higher the antitumor and apoptotic activity of Mannich ketones. Determination of lipophilicity by measuring the log k' or by calculating the clogP values of the compounds may help to predict their biological activities.     

A general method for preparation of peptides biotinylated at the carboxy terminus.

A method for the preparation of a biotinylated resin that can be elongated by standard methods of solid-phase peptide synthesis to give peptides biotinylated at the carboxy terminus is described. This methodology is particularly important for the preparation of biotinylated peptides in which a free amino terminus is required. Coupling of N epsilon-9-fluorenylmethoxycarbonyl-(Fmoc)-N alpha-tert-butyloxycarbonyl(Boc)-L- lysine to p-methylbenzhydrylamine resin, followed by removal of the Fmoc protecting group and reaction with (+)-biotin-4-nitrophenyl ester yielded N alpha-Boc-biocytin-p-methyl-benzhydrylamine resin. The utility of this resin was tested by the synthesis of a biotinylated peptide, Gly-Asn-Ala-Ala-Ala-Ala-Arg-Arg-biocytin-NH2, for use as an in vitro substrate for myristoyl-CoA:protein N-myristoyltransferase (NMT), the enzyme that catalyzes protein N-myristoylation. Analysis of the peptide derivative by HPLC and mass spectrometry revealed a single major product of the expected mass, indicating that the biotin group survived cleavage and deprotection with HF. The biotinylated peptide served as a substrate for NMT, and the resulting myristoylated peptide could be quantitatively recovered by adsorption to immobilized avidin.     

Inactivation of animal viruses during sewage sludge treatment

Using a previously developed filter adsorption technique, the inactivation of a human rotavirus, a coxsackievirus B5, and a bovine parvovirus was monitored during sludge treatment processes. During conventional anaerobic mesophilic digestion at 35 to 36 degrees C, only minor inactivation of all three viruses occurred. The k' values measured were 0.314 log10 unit/day for rotavirus, 0.475 log10 unit/day for coxsackievirus B5, and 0.944 log10 unit/day for parvovirus. However, anaerobic thermophilic digestion at 54 to 56 degrees C led to rapid inactivation of rotavirus (k' greater than 8.5 log10 units/h) and of coxsackievirus B5 (k' greater than 0.93 log10 unit/min). Similarly, aerobic thermophilic fermentation at 60 to 61 degrees C rapidly inactivated rotavirus (k' = 0.75 log10 unit/min) and coxsackievirus B5 (k' greater than 1.67 log10 units/min). Infectivity of parvovirus, however, was only reduced by 0.213 log10 unit/h during anaerobic thermophilic digestion and by 0.353 log10 unit/h during aerobic thermophilic fermentation. Furthermore, pasteurization at 70 degrees C for 30 min inactivated the parvovirus by 0.72 log10 unit/30 min. In all experiments the contribution of temperature to the total inactivation was determined separately and was found to be predominant at process temperatures above 54 degrees C. In conclusion, the most favorable treatment to render sludge hygienically safe from the virological point of view would be a thermal treatment (60 degrees C) to inactivate thermolabile viruses, followed by an anaerobic mesophilic digestion to eliminate thermostable viruses that are more sensitive to chemical and microbial inactivations.