An acid-labile anchoring linkage for solid-phase synthesis of C-terminal peptide amides under mild conditions

A series of polymer-supported benzylamides substituted with one to three alkoxy groups in the ring positions were prepared and shown to give carboxamides upon treatment with acid. Based on the initial screening, the bis(o-methoxy)-p-alkoxybenzylamide anchoring linkage was selected for a detailed evaluation of its suitability for solid-phase synthesis of C-terminal peptide amides. The handle derivative 5-[(2' or 4')-Fmoc-aminomethyl-3',5'-dimethoxyphenoxy]valeric acid (1) was prepared in seven facile steps [purification of intermediates unnecessary; overall yield 15% for crystalline product, which is a mixture of positional isomers], and was quantitatively coupled onto amino group-containing supports by use of N,N'-dicyclohexylcarbodiimide plus 1-hydroxybenzotriazole in N,N-dimethylformamide. Stepwise elaboration of peptide chains proceeded smoothly with both N alpha-9-fluorenyl-methyloxycarbonyl (Fmoc) and N alpha-dithiasuccinoyl (Dts) amino acids, and final cleavage of tert.-butyl side-chain protecting groups and of the anchoring linkage occurred readily in trifluoroacetic acid-dichloromethane (7:3) at 25 degrees. The methodology was demonstrated by the syntheses of H-Trp-Asp-Met-Phe-NH2 (tetragastrin) and H-Tyr-Gly-Gly-Phe-Met-NH2 (methionine-enkephalinamide), both with high yields and purities.     

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.     

Side-chain anchoring strategy for solid-phase synthesis of peptide acids with C-terminal cysteine

Many naturally occurring peptide acids, e.g., somatostatins, conotoxins, and defensins, contain a cysteine residue at the C-terminus. Furthermore, installation of C-terminal cysteine onto epitopic peptide sequences as a preliminary to conjugating such structures to carrier proteins is a valuable tactic for antibody preparation. Anchoring of N(alpha)-Fmoc, S-protected C-terminal cysteine as an ester onto the support for solid-phase peptide synthesis is known to sometimes occur in low yields, has attendant risks of racemization, and may also result in conversion to a C-terminal 3-(1-piperidinyl)alanine residue as the peptide chain grows by Fmoc chemistry. These problems are documented for several current strategies, but can be circumvented by the title anchoring strategy, which features the following: (a). conversion of the eventual C-terminal cysteine residue, with Fmoc for N(alpha)-amino protection and tert-butyl for C(alpha)-carboxyl protection, to a corresponding S-xanthenyl ((2)XAL(4)) preformed handle derivative; and (b). attachment of the resultant preformed handle to amino-containing supports. This approach uses key intermediates that are similar to previously reported Fmoc-XAL handles, and builds on earlier experience with Xan and related protection for cysteine. Implementation of this strategy is documented here with syntheses of three small model peptides, as well as the tetradecapeptide somatostatin. Anchoring occurs without racemization, and the absence of 3-(1-piperidinyl)alanine formation is inferred by retention of chains on the support throughout the cycles of Fmoc chemistry. Fully deprotected peptides, including free sulfhydryl peptides, are released from the support in excellent yield by using cocktails containing a high concentration (i.e., 80-90%) of TFA plus appropriate thiols or silanes as scavengers. High-yield release of partially protected peptides is achieved by treatment with cocktails containing a low concentration (i.e., 1-5%) of TFA. In peptides with two cysteine residues, the corresponding intramolecular disulfide-bridged peptide is obtained by either (a). oxidation, in solution, of the dithiol product released by acid; (b). simultaneous acidolytic cleavage and disulfide formation, achieved by addition of the mild oxidant DMSO to the cleavage cocktail; or (c). concomitant cleavage/cooxidation (involving a downstream S-Xan protected cysteine), using reagents such as iodine or thallium tris(trifluoroacetate) in acetic acid.     

Novel base-labile protecting groups for 5'-hydroxy function in solid-phase oligonucleotide synthesis

The 6-(levulinyloxymethyl)-3-methoxy-2-nitrobenzoyl (LMMoNBz) and 2-(levulinyloxymethyl)-5-methoxy-4-nitrobenzoyl (LMMpNBz) groups were developed as novel base-labile protection for the 5'-hydroxy function in solid-phase oligonucleotide synthesis. A comparative study of the LMMoNBz, LMMpNBz and 2-(levulinyloxymethyl)-5-nitrobenzoyl (LMNBz) protecting groups for oligonucleotide synthesis proved strong feasibility for the LMMoNBz group.     

Application of arylsulphonyl side-chain protected arginines in solid-phase peptide synthesis based on 9-fluorenylmethoxycarbonyl amino protecting strategy.

One of the main problems still hampering solid-phase peptide synthesis using orthogonal protection strategies based on the 9-fluorenylmethoxycarbonyl amino protecting group is the difficult removal of currently used arginine arylsulphonyl guanidino protecting groups. Poor acid liability of 4-methoxy-2,3,6-trimethylbenzenesulphonyl-protected arginine has led to the popularity of the newer 2,2,5,7,8- pentamethylchroman-6-sulphonyl guanidino protecting group. This group was initially believed to have liability to trifluoroacetic acid, the reagent commonly used to simultaneously deprotect peptides and detach them from the synthesis resin, comparable to tert.-butyl and trityl type protecting groups used for the protection of other peptide side-chain functionalities. In a comparison of three established cleavage/deprotection mixtures we have shown that this is not always the case, particularly in multiple arginine peptides. We have found that only hard-acid deprotection with trimethylsilyl bromide reliably removed both arylsulphonyl guanidino protecting groups from a variety of arginine-containing peptides.     

Methionine anchoring applied to the solid-phase synthesis of lysine-containing 'head-to-tail' cyclic peptides

Lysine-containing 'head-to-tail' cyclic peptides can be prepared via a side-chain anchoring solid-phase synthesis strategy. A handle is prepared using a methionine residue, the C -carboxylof which forms an amide with the N -amine of lysine. Subsequently, the linear peptide sequence is assembled, appropriatedeblocking steps are carried out, and on-resin head-to-tail cyclizationfollows. Optionally, acid-labile protecting groups may be removed while the peptide remains resin-bound. The final cleavage step uses CNBr, and releases the free or protected cyclic peptide into solution.     

Methionine anchoring applied to the solid-phase synthesis of lysine-containing 'head-to-tail' cyclic peptides

Summary Lysine-containing ‘head-to-tail’ cyclic peptides can be prepared via a side-chain anchoring solid-phase synthesis strategy. A handle is prepared using a methionine residue, theC ^α-carboxyl of which forms an, amide with theN ^ε-amine of lysine. Subsequently, the linear peptide sequence is assembled, appropriate deblocking steps are carried out, and on-resin head-to-tail cyclization follows. Optionally, acid-labile protecting groups may be removed while the peptide remains resin-bound. The final cleavage step uses CNBr, and releases the free or protected cyclic peptide into solution. Taken in part from the Ph.D. Thesis of J. C. Kappel, University of Minnesota, November 2003. Portions of this work were reported in preliminary form at the Eighteenth American Peptide Symposium, Boston, MA, U.S.A., 19–23 July 2003, and at the Eighth International Symposium on Solid Phase Synthesis and Combinatorial Chemical Libraries, London, England, U.K., 2–5 September 2003.     

New hydrogenation catalyst: An advantageous method for the removal of hydrogenolysable protecting groups in peptide synthesis

Removal of some commonly used protecting groups in peptide synthesis by catalytic transfer hydrogenation employing ammonium formate and magnesium is described. This method is equally competitive with other methods in deblocking most of the commonly used protecting groups in peptide synthesis. tert-Butyl derived and base labile protecting groups were completely stable under these conditions. The use of ammonium formate and magnesium makes this a rapid, low-cost alternative to palladium and reduces the work-up to a simple filtration and extraction operation.     

Application of acetamidomethyl and 9-fluorenylmethyl groups for efficient side protection of penicillamine in solid-phase peptide synthesis

Synthesis of S-acetamidomethyl and S-fluorenylmethyl derivatives of penicillamine is described. Both groups are completely stable to all the usual reagents in solid-phase peptide synthesis, including the HF cleavage step, and show an excellent degree of orthogonality to each other. Treatment of the protected peptides Ac-L-Pen(X)-L-Pro-D-Val-L-Cys(X)-NH2 with thallium (III) trifluoroacetate or iodine for X = Acm or piperidine/DMF (1:1) for X = Fm induced with good yield the formation of the intramolecular disulfide bridge. This cyclic peptide appears to assume a type II beta-turn conformation in d6-DMSO as evidenced by 1H-NMR spectra.     

New hydrogenation catalyst: An advantageous method for the removal of hydrogenolysable protecting groups in peptide synthesis

Summary Removal of some commonly used protecting groups in peptide synthesis by catalytic transfer hydrogenation employing ammonium formate and magnesium is described. This method is equally competitive with other methods in deblocking most of the commonly used protecting groups in peptide synthesis.tert-Butyl derived and base labile protecting groups were completely stable under these conditions. The use of ammonium formate and magnesium makes this a rapid, low-cost alternative to palladium and reduces the work-up to a simple filtration and extraction operation.     

Practical approach to solid-phase synthesis of C-terminal peptide amides under mild conditions based on a photolysable anchoring linkage

Several 3-nitro-4-(N-protected aminomethyl)benzoic acids; with protection provided by tert.-butyloxycarbonyl (Boc), 9-fluorenylmethyloxycarbonyl (Fmoc), trifluoroacetyl (Tfa), dithiasuccinoyl (Dts), or phthaloyl (Phth), have been prepared by reproducible routes. Synthesis of Dts-handle 6 illustrates some particularly novel and efficient chemistry, and is preferred over more intricate routes to Boc-handle 3 and Fmoc-handle 4. The five handles were each evaluated for their application to the synthesis of peptide amides. Coupling onto amino-functionalized supports provided a general starting point for peptide chain assembly. The handle amino function was deblocked (Boc, Fmoc, Dts), the C-terminal residue was coupled as its N alpha-protected free acid, and ultimately the ortho-nitrobenzylamide anchorage linkage was cleaved photolytically to give the corresponding amide. Starting with handles 3, 4, and 6, several free and protected peptide amides were synthesized.     

Improved approach for anchoring N alpha-9-fluorenylmethyloxycarbonylamino acids as p-alkoxybenzyl esters in solid-phase peptide synthesis

Several Fmoc-amino acids have been esterified by use of N,N-dimethylformamide dineopentyl acetal to 2,4,5-trichlorophenyl 3'-(4'-hydroxymethyl-phenoxy)propionate, and the resultant handle derivatives were purified and then quantitatively coupled onto aminomethyl supports. Compared to literature methodology, the present procedure is preferred because: (i) extra steps to selectively protect and liberate the carboxyl of the handle are circumvented; and (ii) the additional methylene group spacer reflecting substitution of a propionyl group for an acetyl group in the handle changes the electronic parameters of the resultant p-alkoxybenzyl ester sufficiently so that the rates of acidolytic cleavage of the anchoring linkage are 2- to 3-fold increased and useful improvements in yields can be achieved.     

Application of a partially automated solid-phase peptide synthesis apparatus to the synthesis of a protected peptide fragment of cytochrome c.

In solid-phase peptide synthesis, more than 80% of the discrete steps involve washing the resin with various solvents to remove unreacted reagents and byproducts. A simple, inexpensive apparatus has been designed to perform automatically up to three successive washing cycles, each consisting of the addition of a measured volume of solvent, stirring for a fixed time interval, and then draining off the solvent. The apparatus is a very useful labor-saving device because the time period between operator interventions (about 10 min) is long enough to permit other work to be done, whereas the manual peptide shaker approach requires virtually constant attendance by the operator. This peptide synthesizer proved to be both reliable and convenient during synthesis of a protected pentadecapeptide corresponding to amino acid residues 66 to 80 of horse heart cytochrome c.     

Application of N,N-dimethylformamide dineopentyl acetal for efficient anchoring of N alpha-9-fluorenylmethyloxycarbonylamino acids as p-alkoxybenzyl esters in solid-phase peptide synthesis

The attachment of Fmoc-amino acids onto p- alkoxybenzyl alcohol resins via DCC-DMAP coupling suffers from two different problems: formation of dimers and racemization. The use of N,N-dimethylformamide dineopentyl acetal for the preparation of Fmoc- aminoacyloxybenzyl handles is the basis of a safe and efficient anchoring method that avoids both problems.     

Studies in solid-phase peptide synthesis: a personal perspective

By the early 1970s it had became apparent that the solid-phase synthesis of ribonuclease A could not be generalized. Consequently, virtually every aspect of solid-phase peptide synthesis (SPPS) was reexamined and improved during the decade of the 1970s. The sensitive detection and elimination of possible side reactions (amino acid insertion, N(alpha)-trifluoroacetylation, N(alphaepsilon)-alkylation) were examined. The quantitation of coupling efficiency in SPPS as a function of chain length was studied. A new and improved support for SPPS, the "PAM-resin," was prepared and evaluated. These and many other studies from the Merrifield laboratory and elsewhere increased the general acceptance of SPPS leading to the 1984 Nobel Prize in Chemistry for Bruce Merrifield.     

Application of Mitsunobu reaction to solid-phase peptide nucleic acid (PNA) monomer synthesis

PNA type I monomer backbone with a reduced peptide bond was synthesized on a Merrifield resin in Mitsunobu reaction of Boc-aminoethanol with resin-bound o-nitrobenzenesulfonylglycine. The pseudodipeptide secondary amine group was deprotected by thiolysis and acylated with thymin-1-ylacetic acid. The monomer was released as a methyl ester. The procedure seems to be of general applicability and allows various modifications of PNA structure by using diverse alcohols and amino acid esters.     

Microwave‐assisted cleavage of Alloc and Allyl Ester protecting groups in solid phase peptide synthesis

Orthogonal protection of amino acid side chains in solid phase peptide synthesis allows for selective deprotection of side chains and the formation of cyclic peptides on resin. Cyclizations are useful as they may improve the activity of the peptide or improve the metabolic stability of peptides in vivo. One cyclization method often used is the formation of a lactam bridge between an amine and a carboxylic acid. It is desirable to perform the cyclization on resin as opposed to in solution to avoid unwanted side reactions; therefore, a common strategy is to use –Alloc and –OAllyl protecting groups as they are compatible with Fmoc solid phase peptide synthesis conditions. Alloc and –OAllyl may be removed using Pd(PPh₃)₄ and phenylsilane in DMF. This method can be problematic as the reaction is most often performed at room temperature under argon gas. It is not usually done at higher temperatures because of the fear of poisoning the palladium catalyst. As a result, the reaction is long and reagent–intensive. Herein, we report the development of a method in which the –Alloc/–OAllyl groups are removed using a microwave synthesizer under atmospheric conditions. The reaction is much faster, allowing for the removal of the protecting groups before the catalyst is oxidized, as well as being less reagent–intensive. This method of deprotection was tested using a variety of amino acid sequences and side chain protecting groups, and it was found that after two 5‐min deprotections at 38°C, all –Alloc and –OAllyl groups were removed with >98% purity. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

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.     

Application of new catalytic phosphate protecting groups for the highly efficient phosphotriester oligonucleotide synthesis.

An effective procedure for the synthesis of oligonucleotides by the phosphotriester method has been developed. The procedure is based on the use of phosphate protecting groups enabling O-nucleophilic intramolecular catalysis in the reaction of internucleotide bond formation under the action of arylsulfonyl chlorides and their derivatives. Using this new procedure, the time needed to perform one elongation step on polymer support is 7-8 min. The effectiveness of the methodology has been demonstrated in the synthesis of many oligodeoxyribonucleotides of different length with high yields.