Efficient expression of isotopically labeled peptides for high resolution NMR studies: application to the Cdc42/Rac binding domains of virulent kinases in Candida albicans

The production of bioactive peptides and small protein fragments is commonly achieved via solid-phase chemical synthesis. However, such techniques become unviable and prohibitively expensive when the peptides are large (e.g., >30 amino acids) or when isotope labeling is required for NMR studies. Expression and purification of large quantities of unfolded peptides in E. coli have also proved to be difficult even when the desired peptides are carried by fusion proteins such as GST. We have developed a peptide expression system that utilizes a novel fusion protein (SFC120) which is highly expressed and directs the peptides to inclusion bodies, thereby minimizing in-cell proteolysis whilst maintaining high yields of peptide expression. The expressed peptides can be liberated from the carrier protein by CNBr cleavage at engineered methionine sites or through proteolysis by specific proteases for peptides containing methionine residues. In the present systems, we use CNBr, due to the absence of methionine residues in the target peptides, although other cleavage sites can be easily inserted. We report the production of six unfolded protein fragments of different composition and lengths (19 to 48 residues) derived from the virulent effector kinases, Cla4 and Ste20 of Candida albicans. All six peptides were produced with high yields of purified material (30–40 mg/l in LB, 15–20 mg/l in M9 medium), pointing to the general applicability of this expression system for peptide production. The enrichment of these peptides with ¹⁵N, ¹⁵N/¹³C and even ¹⁵N/¹³C/²H isotopes is presented allowing speedy assignment of poorly-resolved resonances of flexible peptides.     

Unexpected aspartimide formation during coupling reactions using Asp(OAl) in solid-phase peptide synthesis

Summary Succinimide ring closure is a well-documented side reaction in the synthesis of certain Asp-containing peptides. This side reaction is typically acid-or base-catalyzed, and its occurrence during coupling reactions has not been previously noted. This unforeseen manifestation of aspartimide formation was detected while exploring a new strategy for side-chain to side-chain lactam formation on a solid support to synthesizecyclo[D-Asp², Dap⁵]dynorphin A-(1-11) amide. The availability of allyl protecting groups, which provide an additional level of orthogonality in solid-phase peptide synthesis, was very appealing for use in preparing this conformationally constrained analogue. We found that the allyl ester (OAl) was not sufficient protection from this side reaction in this susceptible D-Asp²-Gly³ sequence. Remarkably, the aspartimide formation appeared to occur during the coupling reaction in the absence of base if excess coupling reagent was present.     

Conformation studies on oligoalanines, substance P, and the myoglobin sequence (66-73). Circular dichroism of polyethyleneglycol-bound peptides]

The conformation of polyethylene glycol-bound peptides, synthesized by the liquid-phase method, was investigated. This marcromolecular C-terminal protecting group is transparent in the visible and the ultraviolet range to 190 nm and solubilizes peptides in many different solvents. The CD spectra of the polymer-bound myoglobin sequence 66–73 and of the biologically active undecapeptide “substance P” were measured in each step of the synthesis. In both examples the formation of a secondary structure during the growth of the peptide chain was found. In the hydrophobic octapeptide containing the myoglobin sequence 66–73, the influence of either the blocked or the free N-terminal amino group on the conformation was observed. The blocked octapeptide in trifluoroethanol showed a higher degree of α-helix contribution than in its free state. The conformation of the polyethylene glycol-bound nona- and decaalanine in trifluoroethanol and water was determined. The peptide with a free amino end group has β-conformation in trifluoroethanol as well as in water. The corresponding N-Boc-protected derivatives show helical structure. The amino end group has a decisive influence on the formation of β-structure. The method of CD investigation of polymer-bound peptide sequences during the peptide synthesis in solution enables one to determine the influence of protecting groups and the chain end of a peptide on its conformation. It is also possible to study the relationship between the secondary structure, the chain length, and the kinetic of the coupling reaction in different solvents. Since the crystallization method for the liquid-phase peptide synthesis allows one to synthesize peptides in very short time, a new method of studying peptide conformations is opened.     

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.     

Tandem Peptide Ligation for Synthetic and Natural Biologicals

We describe the concept and methods of peptide ligation and tandem peptide ligation for preparing synthetic and natural biologicals. Peptide ligation is a segment coupling method for free peptides or proteins through an amide bond without the use of a coupling reagent or a protecting group scheme. Because unprotected peptides or proteins prepared from either a chemical or biochemical source are being used as building blocks, the ligation removes the size limitation for peptide and protein synthesis. A key feature of the peptide ligation is that the coupling reaction is orthogonal, i.e. it is specific to a particular alpha-amino terminus (NT). This NT-amino acid-specific feature permits the development of a tandem peptide ligation method employing three unprotected peptide segments containing different NT-amino acids to form consecutively two amide bonds, an Xaa-SPro (thiaproline) and then an Xaa-Cys. This strategy was tested in peptides ranging from 28 to 70 amino acid residues, including analogues of somatostatins and two CC-chemokines MIP-1alpha and MIP-1beta. The thiaproline replacements in these peptides and proteins did not result in altered biological activity. By eliminating the protecting group scheme and coupling reagents, tandem ligation of multiple free peptide segments in aqueous solutions enhances the scope of protein synthesis and may provide a useful approach for preparing protein biologicals and synthetic vaccines.     

Some Mechanistic Aspects on Fmoc Solid Phase Peptide Synthesis

Peptides are biomolecules that may have several biological activities which makes them important to the environment in which they operate. Sometimes it is necessary for larger amounts of peptides to carry out some studies, like biological tests, NMR structural research or even interaction studies between peptides with other molecules. Expression can be an alternative for that. However, synthesis is specially useful when unnatural modifications or introduction of site specific tags are required. Synthetic peptides have been used for different studies such as cell signaling, development of epitope-specific antibodies, in cell-biology, biomarkers for diseases etc. Many different methodologies for peptide synthesis can be found in the literature. Solid phase peptide synthesis (SPPS) has been largely used and can be an excellent alternative to achieve larger quantities of these biomolecules. In this mini review, we aim to describe the SPPS and explain some of the mechanistic aspects and reagents involved in all phases of the synthesis: the use of resin, the ninhydrin test, some of the protecting groups, coupling reagents for peptide bond formation and the cleavage process.     

Nucleobase‐caged peptide nucleic acids: PNA/PNA duplex destabilization and light‐triggered PNA/PNA recognition

The 2‐(o‐nitrophenyl)‐propyl (NPP) group is used as caging group to mask the nucleobases adenine and cytosine in N‐(2‐aminoethyl)glycine peptide nucleic acids (aeg‐PNA). The adeninyl and cytosinyl nucleo amino acid building blocks Fmoc‐a^NPP‐aeg‐OH and Fmoc‐c^NPP‐aeg‐OH were synthesized and incorporated into PNA sequences by Fmoc solid phase synthesis relying on high stability of the NPP nucleobase protecting group toward Fmoc‐cleavage, coupling, capping, and resin cleavage conditions. Removal of the nucleobase caging group was achieved by UV‐LED irradiation at 365 nm. The nucleobase caging groups provided sterical crowding effecting the Watson–Crick base pairing, and thereby, the PNA double strand stabilities. Duplex formation can completely be suppressed for complementary PNA containing caging groups in both strands. PNA/PNA recognition can be completely restored by UV light‐triggered release of the photolabile protecting group. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

New method for peptide purification based on selective removal of truncation peptide impurities after SPPS with orthogonal capping

Peptide purification by high-performance liquid chromatography (HPLC) is associated with high solvent consumption, relatively large effort and lack of efficient parallelization. As an alternative, many catch-and-release (c&r) purification methods have been developed over the last decades to enable the efficient parallel purification of peptides originating from solid-phase peptide synthesis (SPPS). However, with one exception, none of the c&r systems has been widely established in industry and academia until today. Herein, we present an entirely new chromatography-free purification concept for peptides synthesized on a solid support, termed reactive capping purification (RCP). The RCP method relies on the capping of truncation peptides arising from incomplete coupling of amino acids during SPPS with a reactive tag. The reactive tag contains a masked functionality that, upon liberation during cleavage from the resin, enables straightforward purification of the peptide by incubation with a resin-bound reactive moiety. In this work, two different reactive tags based on masked thiols were developed. Capping with these reactive tags during SPPS led to effective modification of truncated sequences and subsequent removal of the latter by chemoselective reaction with a maleimide-functionalized solid support. By introducing a suitable protecting group strategy, the thiol-based RCP method described here could also be successfully applied to a thiol-containing peptide. Finally, the purification of a 15-meric peptide by the RCP method was demonstrated. The developed method has low solvent consumption, has the potential for efficient parallelization, uses readily available reagents, and is experimentally simple to perform.     

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.     

The Use of Crown Ethers in Peptide Chemistry – V. Solid-phase Synthesis of Peptides by the Fragment Condensation Approach using Crown Ethers as Non-covalent Protecting Groups

We have previously described the conditions by which peptide synthesis by the solid-phase fragment condensation approach can be carried out using crown ethers as non-covalent protection for the N^α -amino group. Here we demonstrate that the procedure can be extended to large, partially protected peptide fragments possessing free Lys and/or Arg residues. The first step was to ensure that complex formation on the side chain of amino acids was not detrimental to the methodology and exhibited the same solubility and coupling properties as N^α -complexed peptides. Thus, a model hexapeptide was synthesized using Fmoc chemistry containing Lys and Arg residues, which, when complexed with 18-Crown-6, was readily soluble in DCM and coupled quantitatively to a resin-bound tetrapeptide. Two tripeptides were then prepared, one containing a free Ser residue, the other free Tyr, to examine the possible occurrence of side reactions. After coupling using standard conditions only the former tripeptide exhibited the formation of the O-acylation by-product (5%). Another model hexapeptide containing Lys, Tyr, Ser and Asp protected with a TFA-stable adamantyl group was complexed with 18-Crown-6 and coupled to the resin-bound tetrapeptide with near quantative yield. Extending the length of the peptide to 21 and 40 residues, which represent sequences Gly⁵² to Leu⁷² (21-mer) and Pro³³ to Leu⁷² (40-mer) from Rattus norvegicus chaperonin 10 protein, respectively, resulted in partially protected fragments that were readily soluble in water, thus enabling purification by RP-HPLC. Complexation with 18-Crown-6 gave two highly soluble products that coupled to resin-board tetramer with 68% and 50% coupling efficiencies for the 21-mer and 40-mer, respectively. Treatment with 1% DIEA solutions followed by acidolytic cleavage and purification of the major product confirmed that the correct product had been formed, when analysed by amino acid analysis and ESI-MS. These results served to extend the methodology of non-covalent protection of large partially protected peptide fragments for the stepwise fragment condensation of polypeptides.     

Chemical synthesis of kurtoxin, a T-type calcium channel blocker

Kurtoxin isolated from the venom of scorpion, Parabuthus transvaalicus, is a 63-residue peptide with four intramolecular disulfide bonds which inhibits low-threshold T-type Ca²⁺channels. Kurtoxin was synthesized by native chemical ligation involving the coupling of (1--26)-thioester peptide and Cys²⁷-(28--63)-peptide. The former was synthesized by standard solid-phase peptide synthesis (SPPS) with Boc chemistry, while the latter was sequentially assembled from three protected segments onto a resin-bound C-terminal segment in a chloroform--phenol mixed solvent followed by deprotection reaction using HF. Each protected segment used for the coupling on a solid support was prepared on an N-[9-(hydroxymethyl)-2-fluorenyl] succinamic acid (HMFS) resin and detached from the resin by treatment with 20% Et ₃N in DMF to produce it in the form of an α-carboxylic acid. Synthetic kurtoxin obtained after the oxidative folding reaction was found to be identical with the natural product by means of several analytical procedures, and its disulfide structure was determined for the first time to be Cys¹²-Cys⁶¹, Cys¹⁶-Cys³⁷, Cys²³-Cys⁴⁴ and Cys²⁷-Cys⁴⁶ by peptide mapping, sequence analysis and mass measurements.     

Peptide arrays on cellulose support: SPOT synthesis, a time and cost efficient method for synthesis of large numbers of peptides in a parallel and addressable fashion

Peptide synthesis on cellulose using SPOT technology allows the parallel synthesis of large numbers of addressable peptides in small amounts. In addition, the cost per peptide is less than 1% of peptides synthesized conventionally on resin. The SPOT method follows standard fluorenyl-methoxy-carbonyl chemistry on conventional cellulose sheets, and can utilize more than 600 different building blocks. The procedure involves three phases: preparation of the cellulose membrane, stepwise coupling of the amino acids and cleavage of the side-chain protection groups. If necessary, peptides can be cleaved from the membrane for assays performed using soluble peptides. These features make this method an excellent tool for screening large numbers of peptides for many different purposes. Potential applications range from simple binding assays, to more sophisticated enzyme assays and studies with living microbes or cells. The time required to complete the protocol depends on the number and length of the peptides. For example, 400 9-mer peptides can be synthesized within 6 days.     

Efficient solid-phase synthesis of a large peptide by a single coupling protocol with a single HPLC purification step

Summary Peptide chain assembly is now routinely performed by the use of automated synthesizers, although purification and characterization of large peptides still requires knowledge and experience. Structural biology has recently become closely involved in molecular recognition studies that often require the analysis of relatively large peptides using high-resolution NMR spectroscopy, for which synthesis of high-quality peptides in 5–10 mg amounts is of prime importance. The present study describes a solid-phase synthesis of a 7 kDa peptide related to the recently characterized ethylene-responsive element binding protein of tobacco, which is the conserved sequence among these proteins. The rapid and efficient preparation was carried out through a single coupling in combination with a single HPLC separation step. Assembly was performed in 63 h. Different coupling chemistries were employed and compared, involving benzotriazol-1-yloxy-tris(pyrrolidino)phosphonium hexafluorophosphate, 1-hydroxy-7-azabenzotriazole and/or the recently introduced reagent,N-[(dimethylamino)-1H-1,2,3-triazolo[4,5-b]pyridin-1-ylmethylene]-N-methylmethanaminium hexafluorophosphateN-oxide. After each synthesis, purified material was characterized by mass spectrometry, sequencing and enzymatic mapping and shown to contain a high proportion of the desired peptide.     

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.     

1H-nmr studies of polyoxyethylene-bound homo-oligo-L-methionines

The use of ¹H-nmr spectroscopy is demonstrated to be a useful analytical method to characterize the structure of synthetic peptides attached to soluble, macromolecular polyoxyethylene (POE) supports in the liquid-phase method (LPM) of peptide synthesis. We report an extensive 360-MHz ¹H-nmr study of POE-bound homo-oligo-L -methionine peptides. A combination of high field and selective saturation or Redfield pulse methods allows resolution of individual backbone NH and α-CH resonances of dilute peptides in the presence of strong resonances from macromolecular POE and/or protonated solvents. The nmr spectra for the POE-bound peptides in CDCl₃ are qualitatively similar to those of the low-molecular-weight Boc-L -Met_n-OMe peptide esters. This corroborates other observations that POE has little effect on peptide stucture. The backbone α-CH region of peptides is overlapped by signals from the terminal oxyethylene group of POE, but the peptide side-chain and low-field backbone NH resonances are well resolved. In trifluoroethanol the Boc-(L -Met)_n-NH-POE heptamer and octamer adopt the right-handed α-helical structure, and the present nmr studies provide evidence for two strong intramolecular hydrogen bonds to stabilize the helices. In water, the N-deblocked derivatives, (L -Met)_n-NH-POE oligomers adopt β-sheet structure and manifest well-resolved nonequivalent NH resonances with 6–7 Hz ³J_NH-CH coupling constants.     

Microwave-assisted solid-phase peptide synthesis of the 60–110 domain of human pleiotrophin on 2-chlorotrityl resin

A fast and efficient microwave-assisted solid phase peptide synthesis (MW-SPPS) of a 51mer peptide, the main heparin-binding site (60–110) of human pleiotrophin (hPTN), using 2-chlorotrityl chloride resin (CLTR-Cl) following the 9-fluorenylmethyloxycarbonyl/tert-butyl (Fmoc/tBu) methodology and with the standard N,N′-diisopropylcarbodiimide/1-hydroxybenzotriazole (DIC/HOBt) coupling reagents, is described. An MW-SPPS protocol was for the first time successfully applied to the acid labile CLTR-Cl for the faster synthesis of long peptides (51mer peptide) and with an enhanced purity in comparison to conventional SPPS protocols. The synthesis of such long peptides is not trivial and it is generally achieved by recombinant techniques. The desired linear peptide was obtained in only 30 h of total processing time and in 51% crude yield, in which 60% was the purified product obtained with 99.4% purity. The synthesized peptide was purified by reversed phase high performance liquid chromatography (RP-HPLC) and identified by electrospray ionization mass spectrometry (ESI-MS). Then, the regioselective formation of the two disulfide bridges of hPTN 60–110 was successfully achieved by a two-step procedure, involving an oxidative folding step in dimethylsulfoxide (DMSO) to form the Cys⁷⁷–Cys¹⁰⁹ bond, followed by iodine oxidation to form the Cys⁶⁷–Cys⁹⁹ bond.     

Methods and protocols of modern solid phase peptide synthesis

The purpose of this article is to delineate strategic considerations and provide practical procedures to enable non-experts to synthesize peptides with a reasonable chance of success. This article is not encyclopedic but rather devoted to the Fmoc/tBu approach of solid phase peptide synthesis (SPPS), which is now the most commonly used methodology for the production of peptides. The principles of SPPS with a review of linkers and supports currently employed are presented. Basic concepts for the different steps of SPPS such as anchoring, deprotection, coupling reaction and cleavage are all discussed along with the possible problem of aggregation and side-reactions. Essential protocols for the synthesis of fully deprotected peptides are presented including resin handling, coupling, capping, Fmoc-deprotection, final cleavage and disulfide bridge formation.     

A general strategy for the bacterial expression of amyloidogenic peptides using BCL‐XL‐1/2 fusions

Biophysical studies on amyloidogenic and aggregation‐prone peptides often require large quantities of material. However, solid‐phase synthesis, handling, and purification of peptides often present challenges on these scales. Recombinant expression is an attractive alternative because of its low cost, the ability to isotopically label the peptides, and access to sequences exceeding ～50 residues. However, expression systems that seek to solubilize amyloidogenic peptides suffer from low yields, difficult optimizations, and isolation challenges. We present a general strategy for expressing and isolating amyloidogenic peptides in Escherichia coli by fusion to a polypeptide that drives the expression of attached peptides into bacterial inclusion bodies. This scheme minimizes toxicity during bacterial growth and enables the processing and handling of the peptides in denaturing solutions. Immobilized metal affinity chromatography, reverse phase HPLC, and cyanogen bromide cleavage are used to isolate the peptide, followed by further reverse phase HPLC, which yields milligram quantities of the purified peptide. We demonstrate that driving the peptides into inclusion bodies using fusion to BCL‐XL‐1/2 is a general strategy for their expression and isolation, as exemplified by the production of 11 peptides species.     

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.     

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.