Progress Towards a Submonomer Synthesis of Peptide Nucleic Acid

Abstract

We report recent developments in the optimization of a submonomer synthesis of peptide nucleic acid based on the Fukuyama-Mitsunobu reaction. The key steps in the submonomer synthesis are the installation of an appropriately protected 2-aminoethyl group on the α-nitrogen of an amino acid and its subsequent acylation with a protected nucleobase derivative. The aggressive alkylation conditions require a scheme of maximal protection for the nucleobases and that is proposed herein for the pyrimidines.     

Incorporation of chemoselective functionalities into peptoids via solid-phase submonomer synthesis

A simple route to the introduction of a number of chemoselective functional groups into peptoids (oligo(N-substituted glycines)) by an extension of the standard solid-phase submonomer method is reported. The following groups were introduced: aminooxyacetamide, N-(carbamoylmethyl)acetohydrazide, mercaptoacetamide, 2-pyridinesulfenylmercaptoacetamide, and aldehyde-terminated peptoids. The method uses commercially available reagents, is fully compatible with standard peptoid submonomer synthesis conditions, is easily automated, and generates the desired functionalized peptoid in high yield and purity. Peptoids with suitable pairs of chemoselective ligation groups were joined in high yield.     

Synthesis of Chiral Heteronucleotide ONA Sequences by a Fmoc/Boc-Based Submonomeric Strategy

Peptide nucleic acid (PNA) is a DNA analog able to form hybridization complexes with complementary DNA or RNA strands. Many PNAs have been described in recent years, particularly chiral PNA analogs. Chiral heteronucleotide ONA (Orn backbone PNA) is an important tool in the antisensing field, but was not been fully explored yet. In the present work, we performed studies toward the synthesis of chiral heteronucleotide ONA sequences by utilizing a Fmoc/Boc-based submonomer approach on solid support. The desired oligomers with different nucleic content and length were obtained in very good yields and high purity. Specific binding to the complimentary ssDNA oligomers was demonstrated.     

Solid-phase submonomer synthesis of peptoid polymers and their self-assembly into highly-ordered nanosheets

Peptoids are a novel class of biomimetic, non-natural, sequence-specific heteropolymers that resist proteolysis, exhibit potent biological activity, and fold into higher order nanostructures. Structurally similar to peptides, peptoids are poly N-substituted glycines, where the side chains are attached to the nitrogen rather than the alpha-carbon. Their ease of synthesis and structural diversity allows testing of basic design principles to drive de novo design and engineering of new biologically-active and nanostructured materials. Here, a simple manual peptoid synthesis protocol is presented that allows the synthesis of long chain polypeptoids (up to 50mers) in excellent yields. Only basic equipment, simple techniques (e.g. liquid transfer, filtration), and commercially available reagents are required, making peptoids an accessible addition to many researchers' toolkits. The peptoid backbone is grown one monomer at a time via the submonomer method which consists of a two-step monomer addition cycle: acylation and displacement. First, bromoacetic acid activated in situ with N,N'-diisopropylcarbodiimide acylates a resin-bound secondary amine. Second, nucleophilic displacement of the bromide by a primary amine follows to introduce the side chain. The two-step cycle is iterated until the desired chain length is reached. The coupling efficiency of this two-step cycle routinely exceeds 98% and enables the synthesis of peptoids as long as 50 residues. Highly tunable, precise and chemically diverse sequences are achievable with the submonomer method as hundreds of readily available primary amines can be directly incorporated. Peptoids are emerging as a versatile biomimetic material for nanobioscience research because of their synthetic flexibility, robustness, and ordering at the atomic level. The folding of a single-chain, amphiphilic, information-rich polypeptoid into a highly-ordered nanosheet was recently demonstrated. This peptoid is a 36-mer that consists of only three different commercially available monomers: hydrophobic, cationic and anionic. The hydrophobic phenylethyl side chains are buried in the nanosheet core whereas the ionic amine and carboxyl side chains align on the hydrophilic faces. The peptoid nanosheets serve as a potential platform for membrane mimetics, protein mimetics, device fabrication, and sensors. Methods for peptoid synthesis, sheet formation, and microscopy imaging are described and provide a simple method to enable future peptoid nanosheet designs.     

Discovery of new PPARγ agonists based on arylopeptoids

In this study we present the design, synthesis and biological evaluation of a small, first-generation library of small molecule aromatic amides based on the arylopeptoid skeleton. The compounds were efficiently synthesized using a highly convenient submonomer solid-phase methodology which potentially allows for access to great product diversity. The synthesized compounds were tested for their ability to activate peroxisome proliferator-activated receptors (PPARs) and they all acted as PPARγ agonists in the μM range spanning from 2.5- to 14.7-fold activation of the receptor. This is the first discovery of bioactive molecules based on the arylopeptoid architecture.     

Exploration of the use of an acylsulfonamide safety-catch linker for the polymer-supported synthesis of hyaluronic acid oligosaccharides

The synthesis of hyaluronic acid oligosaccharides on polyethylene glycol (PEG) using an acylsulfonamide linker has been explored. Hyaluronic acid is a challenging synthetic target that usually involves the condensation of highly disarmed glucuronic acid building blocks. Amine-ended PEG monomethyl ether was efficiently functionalized with a hydroxyl-terminated acylsulfonamide linker. Suitably protected d-glucosamine (GlcN) and d-glucuronic acid (GlcA) monosaccharide building blocks were coupled to the polymer acceptor using the trichloroacetimidate glycosylation method. The sulfonamide safety-catch linker enables simultaneous cleavage of the monosaccharide from the polymer and orthogonal functionalization for further (bio)-conjugation of the sugar sample. Subsequent glycosylation of PEG-bound glycosyl acceptor to generate hyaluronic acid oligosaccharide chain failed. Model glycosylation experiments in solution and on soluble support using the same unreactive acceptors and donors allows for the synthesis of an orthogonally protected hyaluronic acid disaccharide and suggest that the encountered difficulties could be attributed to the presence of the N-acylsulfonamide.     

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.     

An imidazoline pseudodipeptide suitable for solid phase peptide synthesis.

This paper describes the synthesis of two diastereoisomers of an imidazoline dipeptide mimetic (a 4,5 dihydroimidazole-4-carboxylic acid), suitably protected for incorporation into solid phase peptide synthesis (SPPS) using the Fmoc protocol, from a phenylalanine-derived thioimidate and an alpha,beta-diaminopropanoic acid ester, followed by protecting group manipulation.     

Convenient synthesis of thioamidated peptides and proteins

The unique physicochemical properties of a thioamide bond, which is an ideal isostere of an amide bond, have not been fully exploited because of the tedious synthesis of thionated amino acid building blocks. Here, we report a purification‐free and highly efficient synthesis of thiobenzotriazolides of Fmoc‐protected and orthogonally protected 20 naturally occurring amino acids including asparagine, glutamine, and histidine. The near‐quantitative conversion to the respective thioamidated peptides on solid support demonstrates the robustness of the synthetic route. Furthermore, the unaltered incorporation efficiency of thiobenzotriazolides from their stock solution till 48 h suggests their compatibility toward automated peptide synthesis. Finally, utilizing an optimized cocktail of 2% DBU + 5% piperazine for fast Fmoc‐deprotection, we report the synthesis of a thioamidated Pin1 WW domain and thioamidated GB1 directly on solid support.     

Facile synthesis of orthogonally protected amino acid building blocks for combinatorial N-backbone cyclic peptide chemistry.

Protected Nalpha-(aminoallyloxycarbonyl) and Nalpha-(carboxyallyl) derivatives of all natural amino acids (except proline), and their chiral inverters, were synthesized using facile and efficient methods and were then used in the synthesis of Nalpha-backbone cyclic peptides. Synthetic pathways for the preparation of the amino acid building units included alkylation, reductive amination and Michael addition using alkylhalides, aldehydes and alpha,beta-unsaturated carbonyl compounds, and the corresponding amino acids. The resulting amino acid prounits were then subjected to Fmoc protection affording optically pure amino acid building units. The appropriate synthetic pathway for each amino acid was chosen according to the nature of the side-chain, resulting in fully orthogonal trifunctional building units for the solid-phase peptide synthesis of small cyclic analogs of peptide loops (SCAPELs). Nalpha-amino groups of building units were protected by Fmoc, functional side-chains were protected by t-Bu/Boc/Trt and N-alkylamino or N-alkylcarboxyl were protected by Alloc or Allyl, respectively. This facile method allows easy production of a large variety of amino acid building units in a short time, and is successfully employed in combinatorial chemistry as well as in large-scale solid-phase peptide synthesis. These building units have significant advantage in the synthesis of peptido-related drugs.     

De novo synthesis of differentially protected l-iduronic acid glycosylating agents

A divergent de novo synthesis of six differentially protected l-iduronic acid thioglycosides from a common advanced precursor is described. The key step of this synthetic sequence is the stereoselective elongation of dithioacetal protected C5-dialdehyde 11 via a highly diastereoselective MgBr₂·OEt₂-mediated cyanation. Orthogonally protected l-iduronic acid building blocks obtained by this synthesis are expected to facilitate access to differentially sulfated heparins for microarray-based structure-activity relationship studies.     

Solution‐phase submonomer diversification of aza‐dipeptide building blocks and their application in aza‐peptide and aza‐DKP synthesis

Aza‐peptides have been used as tools for studying SARs in programs aimed at drug discovery and chemical biology. Protected aza‐dipeptides were synthesized by a solution‐phase submonomer approach featuring alkylation of N‐terminal benzophenone semicarbazone aza‐Gly‐Xaa dipeptides using different alkyl halides in the presence of potassium tert‐butoxide as base. Benzophenone protected aza‐dipeptide tert‐butyl ester 31c was selectively deprotected at the C‐terminal ester or N‐terminal hydrazone to afford, respectively, aza‐dipeptide acid and amine building blocks 36c and 40c, which were introduced into longer aza‐peptides. Alternatively, removal of the benzophenone semicarbazone protection from aza‐dipeptide methyl esters 29a–c led to intramolecular cyclization to produce aza‐DKPs 39a–c. In light of the importance of aza‐peptides and DKPs as therapeutic agents and probes of biological processes, this diversity‐oriented solution‐phase approach may provide useful tools for studying peptide science. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Preparation of protected peptide amides using the Fmoc chemical protocol. Comparison of resins for solid phase synthesis.

Different resins were examined for their potential use in the solid phase synthesis of protected peptide amides using the 9-fluorenylmethoxycarbonyl (Fmoc) chemical protocol. The model protected peptide amide BocTyr-Gly-Gly-Phe-Leu-Arg(Pmc)NH2 (1) was synthesized on both the acid-labile 4-(2',4'-dimethoxyphenyl-Fmoc-aminomethyl)phenoxy resin (Rink amide resin) (2) and on resins containing the base-labile linker 4-hydroxymethylbenzoic acid. Of the resins examined only the methylbenzhydrylamine resin containing the 4-hydroxymethylbenzoic acid linkage, which was cleaved by ammonolysis in isopropanol, gave the model peptide 1 in good overall yield (53% including functionalization). Thus the synthesis of protected peptide amides by solid phase synthesis using Fmoc-protected amino acids with t-butyl-type side chain protecting groups is feasible. The choice of peptide-resin linkage and its cleavage conditions, however, are critical to the success of such syntheses. The potential application of this synthetic strategy to the preparation of novel peptide amides is discussed.     

A Dde resin based strategy for inverse solid-phase synthesis of amino terminated peptides, peptide mimetics and protected peptide intermediates.

This report describes a Dde resin based attachment strategy for inverse solid-phase peptide synthesis (ISPPS). This attachment strategy can be used for the synthesis of amino terminated peptides with side chains and the carboxyl terminus either protected or deprotected. Amino acid t-butyl esters were attached through their free amino group to the Dde resin. The t-butyl carboxyl protecting group was removed by 50% TFA, and inverse peptide synthesis cycles performed using an HATU/TMP based coupling method. Protected peptides were cleaved from the resin with dilute hydrazine. Side chain protecting groups could then be removed by treatment with TFMSA/TFA. The potential of this approach was demonstrated by the synthesis of several short protected and unprotected peptides in good yield and with low epimerization. Its potential for peptide mimetic synthesis was demonstrated by the synthesis of two peptide trifluoromethylketones.     

PNA synthesis using a novel Boc/acyl protecting group strategy.

The synthesis of novel Boc/acyl protected monomers for the synthesis of peptide nucleic acid (PNA) is described. The oligomerization protocol using these new monomers has been optimized with regard to coupling reagents. The use of base-labile acyl protecting groups at the exocyclic amines of the heterocyclic bases (isobutyryl for guanine and benzoyl for adenine and cytosine) and a PAM-linked solid support offers an attractive alternative to the present procedures used in PNA synthesis. This strategy has been applied for the synthesis of a test 17mer PNA on both control pore glass (CPG) and a polystyrene MBHA support and was used in the preparation of PNA-DNA chimeras.     

Chemoselectively addressable HCan building blocks in peptide synthesis: L-homocanaline derivatives

(S-2-amino-5-(aminooxy)pentanoic acid (L -homocanaline, HCan), a structural analogue of lysine, contains a reactive alkyloxyamine side chain and is therefore considered to react chemoselectively with carbonyl compounds by forming a kinetically stable oxime bond. The chemical synthesis of L -homocanaline starting from protected glutamic acid derivatives is described. Two orthogonally protected homocanaline derivatives were synthesized and their use in standard SPPS procedures was exemplified for the synthesis of a chemoselectively addressable cyclic peptide for use in TASP design. Moreover, the wide range of applications of this unique building block was demonstrated for the chemoselective ligation of an unprotected disaccharide to a HCan containing model peptide resulting in a chimeric glycopeptide structure. © 1998 European Peptide Society and John Wiley & Sons, Ltd.     

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.     

Ritter-based glycoconjugation of amino acids and peptides--access to novel glycoconjugates displaying a beta-amide linkage between amino acid and sugar moiety

Beta-peptidic-D-gluco-, D-galacto-, and L-fuco-configured glycosyl amino acids can be prepared from the corresponding 2-deoxy-oct-3-ulopyranosonic acids via a one-pot intramolecular Ritter reaction. Initially, a ketopyranoside-based acid condenses under Lewis acid promoted conditions with nitriles (PhCN, MeCN) and a partially protected diamino ester (Boc-DAB-O-t-Bu, Boc-Orn-O-t-Bu) to form a beta-peptidic glycosyl amino t-butylesters. The glycosyl amino t-butylesters can be converted into Fmoc-protected glycosyl amino acids that are suitably protected for solid-phase glycopeptide synthesis. Furthermore, replacement of the protected diamino ester by immobilized peptide amines permits post-synthetic N-terminal- and N(epsilon)-glycoconjugation of peptides on the solid phase.     

Design and synthesis of an optimized positional scanning library of peptoids: identification of novel multidrug resistance reversal agents

Herein is reported the optimized solid-phase synthesis of a library of 5,120 trimeric N-alkylglycines (peptoids) using the positional scanning format and the submonomer strategy. Diversity at the N-terminal position was generated from 20 commercially available primary amines, whereas 16 primary amines were employed for the middle and C-terminal positions of the trimers. Formation of undesirable side-products observed in a previous library synthesis (Humet, M. et al. J. Comb. Chem. 2003, 5, 597-605) was averted by restricting the use of primary amines functionalized with tertiary amino groups to the third amination step. Screening of the new library for the identification of chemosensitizers yielded two peptoids, compounds 1 and 2, with potent in vitro activity as multidrug resistance (MDR) reversal agents. The structures of the lead peptoids are consistent with a pharmacophore model generated from the interaction of various known inhibitors with the MDR-implicated transmembrane glycoprotein P-gp.     

Asymmetrically Substituted myo-Inositols. XXXIX. The Synthesis of Conjugate of 2',3'-Didehydro-3'-deoxythymidine with Phosphatidylinositol: A New Nucleoside Phospholipid with Potential Anti-HIV Activity

A partially protected phosphatidylinositol with a free hydroxyl group in the cyclitol moiety was synthesized by phosphorylation of a tetrasubstituted myo-inositol using the H-phosphonate and phosphoamidite methods. The H-phosphonate method was advantageous for the synthesis of selectively protected monophosphoinositide due to a lesser number of stages. Two schemes for the conjugation of 2',3'-didehydro-3'-de oxythymidine with phosphatidylinositol using succinic acid as a linker were tested in the synthesis of the target nucleoside phospholipid.