Solid-phase synthesis of bombesin by continuous flow procedure using Fmoc-amino acids

Bombesin has been synthesized by the continuous flow solid-phase procedure on the derivatized Kieselguhr-supported polydimethylacrylamide resin. Preformed Fmoc-amino acid symmetrical anhydrides (Met, Leu, and Arg) and Fmoc-amino acid active esters were used for amine acylation. The Mtr and the Pmc groups have been alternatively used for masking the side chain function of Arg-3. The progress of the synthesis was monitored by different analytical methods including quantitative solid-phase Edman degradation. Cleavage from the resin and simultaneous formation of the C-terminal amide function were achieved with a methanolic ammonia solution yielding indistinguishable crude peptides which have been purified by HPLC and fully characterized. Preliminary pharmacological experiments indicated that the activity of the synthetic peptides is similar to that previously measured for other synthetic bombesins. For comparison bombesin has also been prepared by solid-phase synthesis on 4-methyl benhydrylamine resin using the Boc chemistry. The results of the two strategies are discussed and compared.     

Synthesis of chicken galanin and its N- and C-terminal segments,and preparation of their antisera

Summary We describe the synthesis of the first avian galanin (GAL), chicken GAL, and its N-terminal and C-terminal segments by solid-phase synthesis, using Boc/Bzl amino acid protection groups and MBHA resin. The three peptides were prepared with purities of over 97%, as determined by RP-HPLC, HPCE, FAB-MS or ESI-MS and amino acid analysis. Antibodies against these synthetic peptides were raised in rabbits and used for immunohistochemical localization of GAL-immunoreactive neurons in chicken brain.     

Chemistry of alpha-hydroxymethylserine: problems and solutions

Further improvements related to the synthesis of peptides containing HmS are presented. Efficient synthetic protocols have been developed to synthesize "difficult" sequences containing a C-terminal HmS residue, MeA-HmS or consecutive HmS. Preparative methods for orthogonal N- and/or C-protected HmS(Ipr) derivatives are described. Their compatibility with standard solution or solid-phase peptide chemistry protocols allows synthetic flexibility toward HmS-containing peptides. In the synthesis of the sterically hindered dipeptides with the C-terminal HmS(Ipr) residue, HATU proves the highest efficiency, as compared with the fluoride and PyBroP/DMAP coupling methods. The HATU method also outperforms the fluoride activation in the solid-phase assembly of HmS homosequence. Specific protocols are described to overcome an undesired cyclization to diketopiperazines that occurs during the removal of Fmoc from dipeptides with the C-terminal HmS(Ipr) or HmS residues, thus precluding their C-->N elongation. The successful protocols involve: (i) the 2+1 condensation using mixed anhydride activation yielding the desired product with the highest optical integrity or (ii) use of the 2-chlorotrityl resin as a solid support sterically suppressing the undesired cleavage due to diketopiperazine formation. The latter approach allows the mild conditions of peptide cleavage from solid support, preserving the isopropylidene protection and minimizing the undesired N-->O-acyl migration that was observed under prolonged acid treatment used for cleaving the HmS peptide from the Wang resin.     

A gene fusion system for generating antibodies against short peptides

A novel method to obtain specific antibodies against short peptides is described, involving synthesis of the corresponding oligodeoxynucleotides followed by cloning into a new set of fusion vectors, pEZZ8 and pEZZ18, based on two synthetic IgG-binding domains (ZZ) of Staphylococcus aureus protein A. The soluble gene fusion product thus obtained, can be collected from the culture medium of Escherichia coli and rapidly recovered in a one-step procedure by IgG affinity chromatography. The system was used to express a fusion protein consisting of the two Z fragments and the C-terminal part [amino acids (aa) 57-70] of human insulin-like growth factor I (IGF-I). This 16-kDa protein was purified by affinity chromatography on IgG Sepharose and antibodies were raised in rabbits. The fusion protein elicited peptide-specific antibodies, as measured by solid-phase radioimmuno assay and Western blotting, reactive with both synthetic C-terminal peptide and the native human IGF-I protein. The results suggests that the gene fusion system can be used for efficient antibody production against short peptides encoded by synthetic oligodeoxynucleotides.     

3-Thiopropionic acid as a highly versatile multidetachable thioester resin linker

This paper describes a practical new use of3-mercaptopropionic acid as a highly versatilemultidetachable linker for solid-phase synthesis. Ourapproach is based on the stability of thealkylthioester functionality to optimized Boc-SPPSprotocols and HF treatment, as well as on the mildactivation of the thioester functionality towardnucleophilic or reductive displacement. This allowsseveral C-terminal modifications to be introduced intoa synthetic molecule during the cleavage step. We haveshown that unprotected peptides can be efficientlycleaved from a propyl thioester-polyethyleneglycol-poly-(N,N-dimethylacrylamide) copolymerresin using a great variety of nucleophiles to givethe corresponding C-terminally modified peptides(esters, thioesters, carboxylic acids, thioacids,amides, hydroxamic acids, hydrazides, alcohols). Thenucleophilic cleavage reaction is both rapid andexceptionally clean in all the cases tested.     

Diabetogenic action of human growth hormone. Synthesis and activity of C-terminal fragments.

Three peptides corresponding to the C-terminal region of human growth hormone have been synthesized by the solid-phase method: HGH-(177--191), HGH-(178--191) and HGH-(179--191). The diabetogenic activities of these synthetic peptides are reported. The data indicate that extension of HGH-(179--191) at its NH2-terminus is required for in vivo activity. The reduced and S-carbamidomethylated form of HGH-(177--191) was also active, indicating that the disulphide bond is possibly not a prerequisite for biological activity.     

Synthetic hFSH peptide constructs in the evaluation of previous studies on the hFSH receptor interaction

The human follicle-stimulating hormone (hFSH) belongs to a family of glycoprotein hormones which contains two non-identical subunits. This paper describes the design and synthesis of a series of synthetic hFSH constructs as putative ligands for the receptor. The design of these constructs is based on the crystal structure of hCG and molecular modelling using the program package Insight II/Discover. The designed constructs contain peptides ranging from 7 to 48 amino acid residues, disulphide bridges and glycan residues. All the synthetic peptides were synthesized by the stepwise solid-phase method using Fmoc chemistry. Two of the synthetic peptides contain the glycosylated amino acid, Asn(GlcNAc-GlcNAc) and both were prepared using fully protected glycosylated building blocks in the solid-phase peptide synthesis. The disulphide bridges were formed from acetamidomethyl-protected glycopeptides and peptides by a direct deprotection/oxidation method using thallium(III) trifluoroacetate. Mass spectroscopy and amino acid analysis were used for characterization of the synthetic hFSH glycopeptides and peptides. The synthetic hFSH constructs were tested for binding activity on FSH receptor assays but none showed improved binding properties compared with the naturally occurring hormone. It was finally demonstrated that non-related peptides showed non-specific binding at the same level as reported for specific peptides. © 1997 European Peptide Society and John Wiley & Sons, Ltd.     

Localization of two antigenic determinants in histone H4

Four overlapping synthetic peptides corresponding to the carboxy-terminal region 80-102 of histone H4 were prepared by solid-phase peptide synthesis. Their antigenic activity was analysed by inhibition of the H4-anti-H4 reaction in complement fixation and enzyme-linked immunosorbent assay. One antigenic determinant was localized in residues 88-96 of the H4 molecule. No antigenic activity was found in peptides 80-89 and 97-102. Antibodies induced by peptide 85-102 were found to bind to free H4 in solution but not to chromatin subunits, suggesting a lack of accessibility of the C-terminal region of H4 in nucleosomes. A second epitope was found to be situated in the N-terminal region 1-53 of histone H4.     

Synthetic peptides in biochemical research

Synthetic peptides play an important role in many areas of biological research. Advances in synthetic chemistry and automation over the past few years have resulted in increasingly reliable and rapid syntheses. As a result, peptides are now frequently employed in immunological studies, structural studies, as enzyme substrates, in ligand/receptor studies, and as probes for a range of molecular interactions. This review describes solid-phase peptide synthesis and the applications of synthetic peptides in molecular biology and biochemistry.     

Solid-phase peptide synthesis (SPPS), C-terminal vs. side-chain anchoring: a reality or a myth

Here we review the strategies for the solid-phase synthesis of peptides starting from the side chain of the C-terminal amino acid. Furthermore, we provide experimental data to support that C-terminal and side-chain syntheses give similar results in terms of purity. However, the stability of the two bonds that anchor the peptide to the polymer may determine the overall yield and this should be considered for the large-scale production of peptides. In addition, resins/linkers which do not subject to side reactions can be preferred for some peptides.     

Synthesis of of beta-amyloid precursor peptide and presenilin segments.

It seems likely that the beta-amyloid precursor protein (APP) and the presenilins (PS-1/2) play important roles in the development of Alzheimer's disease (AD). Attempts to mimic the biochemical actions of these proteins are often made by the application of fragments of these proteins. However, the synthesis of these segments by conventional methods of peptide synthesis is problematic. We have synthesized several C-terminal fragments of APP and PS-1/2 by solid-phase synthesis through combination of automatic and manual methods of synthesis. This permits solution of the 'difficult sequences' in the solid-phase synthesis of these peptides. Some details of the syntheses of nine segments are presented in this paper.     

Liquid-phase peptide synthesis on polyethylene glycol (PEG) supports using strategies based on the 9-fluorenylmethoxycarbonyl amino protecting group: application of PEGylated peptides in biochemical assays.

Stepwise synthetic assembly of polypeptide chains reversibly linked to polyethylene glycol represents a hybrid between traditional solution and solid-phase chemistries and combines the inherent advantages of both approaches. The technical simplicity and scalability of the liquid-phase peptide synthesis method renders it particularly attractive for multiple parallel syntheses, combinatorial approaches and the large-scale preparation of peptides. The versatile protection strategy based on the N alpha-fluorenylmethoxycarbonyl group commonly used in solid-phase peptide synthesis was adapted to the liquid-phase approach. Fluoride ions were used rather than the conventional organic base piperidine for the repetitive amino-deprotection step. Using a range of acid- and base-labile linkers between the polymer and the peptide, it was shown that free and fully side-chain protected peptides can be obtained using our version of the liquid-phase peptide synthesis method. Protocols for simultaneous multiple syntheses requiring a minimum of equipment are presented and the use of polyethylene glycol-bound peptides in biochemical binding and functional assay systems is demonstrated.     

A general procedure for evaluation of immunological relevance of synthetic peptides: peptides synthesized on paper in enzyme-linked immunosorbent assay.

Multiple continuous-flow solid-phase peptide synthesis has been adapted for synthesis of peptides on a cellulose carrier (Whatman 3MM paper). Paper-bound synthetic peptides that represent antigenic determinants of particular proteins detected antibodies against the respective proteins in an enzyme-linked immunosorbent assay. The method is applied to the synthesis, and use in site-directed serology, of four peptides derived from the gp41 glycoprotein of HIV, the Epstein-Barr virus-determined nuclear antigen-1 and VCA proteins of the Epstein-Barr virus, and the early region of human papillomavirus type 11.     

Orthogonal protecting groups for N(alpha)-amino and C-terminal carboxyl functions in solid-phase peptide synthesis

For the controlled synthesis of even the simplest dipeptide, the N(alpha)-amino group of one of the amino acids and the C-terminal carboxyl group of the other should both be blocked with suitable protecting groups. Formation of the desired amide bond can now occur upon activation of the free carboxyl group. After coupling, peptide synthesis can be continued by removal of either of the two protecting groups and coupling with the free C-terminus or N(alpha)-amino group of another protected amino acid. When three functional amino acids are present in the sequence, the side chain of these residues also has to be protected. It is important that there is a high degree of compatibility between the different types of protecting groups such that one type may be removed selectively in the presence of the others. At the end of the synthesis, the protecting groups must be removed to give the desired peptide. Thus, it is clear that the protection scheme adopted is of the utmost importance and makes the difference between success and failure in a given synthesis. Since R. B. Merrifield introduced the solid-phase strategy for the synthesis of peptides, this prerequisite has been readily accepted. This strategy is usually carried out using two main protection schemes: the tert-butoxycarbonyl/benzyl and the 9-flourenylmethoxycarbonyl/tert-butyl methods. However, for the solid-phase preparation of complex or fragile peptides, as well as for the construction of libraries of peptides or small molecules using a combinatorial approach, a range of other protecting groups is also needed. This review summarizes other protecting groups for both the N(alpha)-amino and C-terminal carboxyl functions.     

Developments in peptide and amide synthesis

The solid-phase methodology is key for an effective synthesis of peptides, from a milligram scale for research to a multi-kilo scale for drug production. Indeed, small peptides containing up to 20-30 amino acids are most readily synthesized by a solid-phase strategy. Larger peptides (up to 60 amino acids) should be synthesized by a convergent approach (i.e. synthesis of protected constituent peptides in solid-phase and combination of these units in solution). Larger peptides and proteins are prepared by chemical ligation, where unprotected segments have been prepared in solid-phase.     

Synthesis of modified peptides with C-terminal alpha-amino aldehydes]

Various synthetic approaches to modified peptides with the C-terminal aldehyde group, capable of inhibiting a number of proteolytic enzymes belonging to the classes of thiol, serine, and aspartyl proteases, are considered. Both chemical methods, including solid phase peptide synthesis now widely used, and biocatalytic synthetic methods for obtaining these substances are discussed in detail.     

Synthesis of phosphotyrosyl-containing phosphopeptides by solid-phase peptide synthesis.

The synthesis of phosphotyrosine-containing phosphopeptides using solid-phase peptide synthesis (SPPS) techniques is described. We present the synthesis of a Boc-phosphotyrosine derivative, which when used with modifications of the conventional SPPS protocol permits the incorporation of phosphotyrosine into synthetic peptides. The resulting phosphopeptides were authenticated by fast atom bombardment mass spectrometry, amino acid analysis, and phosphate assay. Alkaline phosphatase was found to dephosphorylate synthetic phosphopeptides at different rates, supporting the potential use of these synthetic substrates for studies of phosphoprotein phosphatases. Synthesis of a phosphopeptide using the described protocol has several advantages over the preparation of phosphopeptides via enzymatic phosphorylation.     

Solid-phase synthesis of peptides with C-terminal asparagine or glutamine. An effective, mild procedure based on N alpha-fluorenylmethyloxycarbonyl (Fmoc) protection and side-chain anchoring to a tris(alkoxy)benzylamide (PAL) handle

Attempts to anchor Fmoc-asparagine or glutamine as p-alkoxybenzyl esters for solid-phase peptide synthesis are fraught with difficulties. A convenient and effective method to prepare peptides with C-terminal asparagine or glutamine involves quantitative attachment of N alpha-Fmoc-C alpha-tert.-butyl aspartate or glutamate via the free omega-carboxyl groups to a tris(alkoxy)benzylamino (PAL) support. Chain elongation proceeds normally by standard Fmoc chemistry, and treatment with acid, e.g., CF3COOH--CH2Cl2, 90 min at 25 degrees, releases the desired peptides in greater than 95% yields without side reactions at the C-terminus. Feasibility of the approach has been demonstrated by the syntheses of the C-terminal octapeptide from human proinsulin, H-Leu-Ala-Leu-Glu-Gly-Ser-Leu-Gln-OH, and the serum thymic factor pGlu-Ala-Lys-Ser-Gln-Gly-Gly-Ser-Asn-OH.     

Fmoc-based chemical synthesis and selective binding to supercoiled DNA of the p53 C-terminal segment and its phosphorylated and acetylated derivatives.

The C-terminal domain of p53 comprises a linker, the tetramerization domain and the regulatory domain, and contains at least seven sites of potential post-translational modification. An improved strategy was developed for the synthesis of large peptides that contain phosphorylated amino acids and p53(303-393), a 91-amino acid peptide, and three post-translationally modified derivatives were synthesized through the sequential condensation of three partially protected segments. Peptide thiolesters were prepared using the sulfonamide-based 'safety-catch' resin approach and employing Fmoc-based solid-phase peptide synthesis. At the N-terminus of the middle building block, a photolabile protecting group, 3,4-dimethoxy-6-nitrobenzyloxycarbonyl, was incorporated to differentiate the N-terminal amino group from the side-chain amino groups. Two sequential couplings were accomplished following this protection strategy. The synthetic products, p53(303-393) and its phosphorylated or acetylated derivatives, exhibited the ability to bind specifically to supercoiled DNA, which is one of the characteristics of this domain.     

Dehydroalanine-containing peptides: preparation from phenylselenocysteine and utility in convergent ligation strategies

This protocol describes the methodology for the synthesis of dehydroalanine (Dha)-containing peptides and illustrates their use in convergent ligation strategies for the preparation of peptide conjugates. A nonproteinogenic amino acid, Fmoc-Se-phenylselenocysteine (SecPh), can be prepared in high yield over four synthetic steps and be conveniently incorporated into peptides by standard solid-phase peptide synthesis techniques. Globally deprotected peptides containing phenylselenocysteine can be converted to dehydrated peptides following a chemoselective, mild oxidation with hydrogen peroxide or sodium periodate (i.e., the phenylselenocysteine side chain is converted to that of Dha). Dha residues are electrophilic handles for the preparation of glycopeptides, lipopeptides or other peptide conjugates; one such transformation will be outlined here. The preparation of Dha-containing peptides, including the synthesis of SecPh, peptide elongation and oxidative treatment of phenylselenocysteine-containing peptides can be completed by one person in approximately 3-5 weeks. However, once SecPh is in hand, the time required for the preparation of peptides is significantly shorter and comparable to that for any peptide synthesis.