Specific labeling of the thyroxine binding site in thyroxine-binding globulin: determination of the amino acid composition of a labeled peptide fragment isolated from a proteolytic digest of the derivatized protein

[125I] Thyroxine has been covalently bound to the thyroxine binding site in thyroxine-binding globulin by reaction with the bifunctional reagent, 1,5-difluoro-2,4-dinitrobenzene. An average of 0.47 mol of [125I] thyroxine was incorporated per mol protein; nonspecific binding amounted to 8%. A labeled peptide fragment was isolated from a proteolytic digest of the derivatized protein by HPLC and its amino acid composition was determined. Comparison with the amino acid sequence of thyroxine-binding globulin indicated partial correspondence of the labeled peptide with two possible regions in the protein. These regions also coincide with part of the barrel structure present in the closely homologous protein, alpha 1-antitrypsin.     

Analysis of the antigen binding site of anti-deoxycholate monoclonal antibody using a novel affinity labeling reagent, acyl adenylate

Large-scale analysis of protein-protein interaction sites is especially needed in the postgenomic era. The combination of affinity labeling with mass spectrometry is a potentially useful high-throughput screening method for this purpose. However, reagents in current use are not ideal as some cause damage to the target molecule and others have poor solubility in physiologic aqueous buffers. In this paper, we describe a novel affinity labeling reagent, acyl adenylate, which is highly soluble in aqueous solutions and reacts in a pH-dependent manner. The adenylate of deoxycholic acid reacts with amino groups on the side chain of a lysine residue and at the N-terminus of proteins/peptides. The reactivity and stability of this reagent were investigated, and it was confirmed that, after formation of a reversible ligand-protein complex under weakly acidic conditions, derivatization with acyl adenylate occurred at the target site under weakly alkaline condition. We further demonstrated the utility of this reagent for affinity labeling using a monoclonal antibody with high affinity for deoxycholic acid. Competitive ELISA indicated that deoxycholic acid was labeled around the antibody ligand binding site, thus enabling the structural elucidation of the ligand-protein interaction. In addition, LC/ESI-MS/MS analysis of the labeled peptide obtained by enzymatic digestion and affinity extraction allowed the identification of the structure surrounding the antigen binding site.     

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.     

Novel cyclization chemistry especially suited for biologically derived, unprotected peptides.

A novel method is described for the cyclization of peptides--or segments of polypeptides--which requires a free N-terminal alpha-amino group and a distal amino acid residue containing a nucleophilic side chain. The reaction is conducted in two steps, both in the aqueous phase. The first step involves acylation of the N-terminal alpha-amino group with iodoacetic anhydride at pH 6. This acylation reaction has greater than 90% specificity for peptide alpha-amino groups and gives no alkylation of Arg, His, Lys or Met by the iodoacetate side product (R. Wetzel et al., Bioconjugate Chem., 1, 114-122, 1990). In the second step, the acylation reaction mixture or the isolated iodoacetyl-peptide is incubated at room temperature to give the cyclic peptide formed by reaction of the nucleophilic side chain with the iodoacetyl moiety. The pH dependence of the cyclization reaction by Met, Lys, Arg or His is consistent with the pKa of the nucleophilic side chain. Thus, peptides containing Met plus other nucleophilic amino acids should preferentially cyclize via Met at low pH. In this paper, preparation of cyclic peptides containing 3-6 amino acids is described; the full range of ring sizes and sequences which can undergo this cyclization has not been further explored. Preliminary results suggest that this method is also fairly general with respect to the amino acid sequence being cyclized. The reaction appears to be particularly suited for cyclization via Lys and Met side chains. All of the cyclized products are sufficiently stable for many biological applications.(ABSTRACT TRUNCATED AT 250 WORDS)     

1,4-diazepine-2,5-dione ring formation during solid phase synthesis of peptides containing aspartic acid beta-benzyl ester.

The Fmoc-based SPPS of H-Xaa-Asp(OBzl)-Yaa-Gly-NH(2) sequences results in side reactions yielding not only aspartimide peptides and piperidide derivatives, but also 1,4-diazepine-2,5-dione-peptides. Evidence is presented to show that the 1,4-diazepine-2,5-dione derivative is formed from the aspartimide peptide. The rate of this ring transformation depends primarily on the tendency to aspartimide and piperidide formation, which is influenced by the nature of the amino acid following the aspartic acid beta-benzyl ester (Xaa). However the bulkiness of the amino acid side chain preceeding the aspartic acid beta-benzyl ester (Yaa) is also important. Under certain conditions the 1,4-diazepine-2,5-dione peptide derivative may even be formed dominantly, which is a highly undesirable side reaction in peptide synthesis, but which provides a new way for the synthesis of diazepine peptide derivatives with targeted biological or pharmacological activity.     

Use of N-chlorosuccinimide/urea for the selective cleavage of tryptophanyl peptide bonds in proteins. Cytochrome c.

The conditions and utility of the N-chlorosuccinimide/urea (NCS/urea) reagent for the selective cleavage of tryptophanyl peptide bonds in proteins is demonstrated with cytochrome c. At low concentrations of NCS/urea the oxidation of thioether side chains in cytochrome c is the predominant reaction. Methionyl residues are oxidized to sulfoxide and the heme-thioether bridge is partially cleaved. At 10-fold excess of NCS/urea reagent, cleavage of the tryptophanyl peptide bond is optimal at approximately 50% yield in several species of cytochrome c studied. Analytical data on isolated horse cytochrome c peptide fragments demonstrate lack of modification and cleavage at tyrosyl and histidyl residues. However, at high concentrations of NCS/urea reagent (30-fold) unexpected conversions of methionine to sulfone and cysteine to cysteic acid in intact proteins are observed. This is in contradistinction to the absence of sulfone in NCS/urea-reacted amino acid mixtures. The mechanisms of halogenation and cleavage by N-bromosuccinimide, N-iodosuccinimide, and N-chlorosuccinimide are discussed. It is porposed that the selectivity with respect to halogenation by N-chlorosuccinimide is due to the insignificant participation of molecular chlorine in the NCS/urea reaction. A mechanism of halogenation and cleavage by NCS at tryptophan is also offered.     

Solid-phase synthesis of an Htc-containingdimer analog of the autophosphorylationsite of pp60src PTK: Effective acylationconditions for Htc residues

Summary The difficulty during SPPS in acylating the secondary amino group of Htc, a locally constrained tyrosine, can be correlated with the steric hindrance of the amino acid or with the conformation of the growing peptide chain. Our experimental data indicate that the availability of the Htc amino group is associated with its steric hindrance rather than a conformational effect of the peptide chain. An optimized solid phase automated protocol for Htc is reported. Under optimal conditions, Fmoc-amino acids with hindered side chains were incorporated in approximately 99% yield using HATU as coupling reagent. Unhindered side chain amino acid acylated the secondary amino group of Htc in good yield under classical HBTU/HOBt coupling conditions. Abbreviations: Abbreviations used for amino acids and the designation of peptides follow the rules of the IUPAC-IUB Commission of Biochemical Nomenclature [J. Biol. Chem., 247 (1972) 977–983]. Amino acid symbols denote thel-configuration where applicable, unless indicated otherwise. The following additional, abbreviations are used     

A switchable stapled peptide

The O‐N acyl transfer reaction has gained significant popularity in peptide and medicinal chemistry. This reaction has been successfully applied to the synthesis of difficult sequence‐containing peptides, cyclic peptides, epimerization‐free fragment coupling and more recently, to switchable peptide polymers. Herein, we describe a related strategy to facilitate the synthesis and purification of a hydrophobic stapled peptide. The staple consists of a serine linked through an amide bond formed from its carboxylic acid function and the side chain amino group of diaminopropionic acid and through an ester bond formed from its amino group and the side chain carboxylic acid function of aspartic acid. The α‐amino group of serine was protonated during purification. Interestingly, when the peptide was placed at physiological pH, the free amino group initiated the O‐N shift reducing the staple length by one atom, leading to a more hydrophobic stapled peptide. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

Identification of the fatty acid binding site on glutathione S-transferase P.

Glutathione S-transferase P (GST-P) bound a series of endogenous fatty acids (C12-C18). To clarify the function and the binding site of the fatty acids, interaction between fatty acids and GST-P was investigated by using 12-(9-anthroyloxy) stearic acid conjugated with Woodward's reagent K. The fluorescence-conjugated fatty acid noncompetitively inhibited GST activity. After GST-P was covalently labeled with the fatty acid, the enzyme was digested with Lysyl Endopeptidase. From the peptide mapping, a single fluorescence-labeled peptide was obtained. By the sequence analysis, the peptide binding fatty acid was determined as the residues of 141-188 from the amino terminus.     

Modification of the cysteine residues of cytochrome P-450cam with 2-bromoacetamido-4-nitrophenol

The Pseudomonas putida cytochrome P-450 was alkylated with the SH-reagent, 2-bromoacetamido-4-nitrophenol. One out of eight cysteine residues present in the enzyme reacted rapidly while another 3 ～ 4 cysteine residues were gradually alkylated at longer reaction times. The derivative in which the most reactive cysteine residue was labeled with this reagent was hydrolyzed with trypsin and a tryptic peptide isolated. From the amino acid composition and end group analysis of the peptide, the rapidly reacting cysteine residue was shown to be Cys 355. This cysteine residue is probably exposed on the surface and is involved in the dimerization of the enzyme. The amino acid sequence about cysteine 355 shows sequence homology with residues 429–445 of the rat liver cytochrome P-450-LM-2.     

Development of a Maleimide Amino Acid for Use as a Tool for Peptide Conjugation and Modification

An amino acid possessing a maleimide side chain was developed and synthesized in good yield. With a propensity to undergo the Michael addition reaction, the creation of a maleimide amino acid derivative was targeted for use as a highly functional tool for enabling peptide conjugation and structural modifications. After addressing the inherent potential side reactions of maleimides during solid phase peptide synthesis, the ability to incorporate the maleimide amino acid in an RGDS peptide sequence was demonstrated. ¹H NMR and mass spectroscopic techniques enabled thorough characterization of the peptide sequence, confirming the presence of the maleimide functionality. Once characterized, the ability to use the maleimide moiety as a peptide modification tool was investigated. Specifically, it was shown that the maleimide functional group could be exploited, given the proper reaction conditions, to anchor a peptide to a surface and create a cyclic conformation from a linear sequence. Furthermore, bioactivity of the peptide containing maleimide amino acid was evaluated by studying cellular interactions with surfaces functionalized with an integrin binding sequence.     

The initiation of fetal hemoglobin biosynthesis.

Biosynthesis of the alpha and beta chains of rabbit and human adult hemoglobin is initiated with a methionyl residue, which is removed during elongation of the peptide chain. To study the initiation of biosynthesis of the delta chain of human fetal hemoglobin, fresh placental blood was used for labeling experiments with radioactive amino acids. Labeled nascent peptide chains were purified from the polysomal fraction of placental blood reticulocytes. The number of amino acid residues in nascent gamma chain at the time of removal of its N-terminal methionine was estimated to be 40--60 from the relative yields of labeled tryptic peptides.     

The aspartimide problem persists: Fluorenylmethyloxycarbonyl‐solid‐phase peptide synthesis (Fmoc‐SPPS) chain termination due to formation of N‐terminal piperazine‐2,5‐diones

Aspartimide (Asi) formation is a notorious side reaction in peptide synthesis that is well characterized and described in literature. In this context, we observed significant amounts of chain termination in Fmoc‐SPPS while synthesizing the N‐terminal Xaa‐Asp‐Yaa motif. This termination was caused by the formation of piperazine‐2,5‐diones. We investigated this side reaction using a linear model peptide and independently synthesizing its piperazine‐2,5‐dione derivative. Nuclear magnetic resonance (NMR) data of the side product present in the crude linear peptide proves that exclusively the six‐membered ring is formed whereas the theoretically conceivable seven‐membered 1,4‐diazepine‐2,5‐dione is not found. We propose a mechanism where nucleophilic attack of the N‐terminal amino function takes place at the α‐carbon of the carbonyl group of the corresponding Asi intermediate. In addition, we systematically investigated the impact of (a) different adjacent amino acid residues, (b) backbone protection, and (c) side chain protection of flanking amino acids. The side reaction is directly related to the Asi intermediate. Hence, hindering or avoiding Asi formation reduces or completely suppresses this side reaction.     

Calmodulin is labeled at lysine 148 by a chemically reactive phenothiazine

10-(3-Propionyloxysuccinimide)-2-(trifluoromethyl)phenothiazine (POS-TP) is a chemically reactive calmodulin antagonist: 2 mol are incorporated per mol of calmodulin when excess reagent is used, and only lysyl side chains are modified. Tryptic peptide mapping demonstrated that a single unique site on calmodulin reacts at low molar ratios of POS-TP. Labeled peptides were isolated and analyzed by amino acid composition and sequence analysis. The unique site was identified as Lys148 of calmodulin, the carboxyl-terminal residue. At higher molar ratios of the reagent Lys21, Lys75, and Lys77 are labeled as are several minor peptides that were not characterized.     

Identification of the C-1-phosphate-binding arginine residue of rabbit-muscle aldolase. Isolation of 1,2-cyclohexanedione-labeled peptide by chemisorption chromatography.

The arginine-specific reagent 1,2-cyclohexanedione reacts selectively with the arginine residue of the C-1-phosphate-binding site of aldolase and inactivates the enzyme. The labeled peptide isolated from tryptic digests of inactivated aldolase was found to correspond to the sequence Leu-43 to Arg-56, the residue modified by cyclohexanedione being Arg-55. This peptide was absent form digests of aldolase treated in the same way but protected from inactivation by the presence of substrate, thus correlating modification of Arg-55 with loss of activity. Selective isolation ofthe peptide containing the modified arginine residue was effected by chemisorption chromatography on boric acid gel, a procedure exploiting the specific interaction of matrix-bound boric acid groups with vicinal cis-hxdroxyl groups of cyclohexanedione-modified arginine side chains.     

The arginines of cytochrome c. The reduction-binding site for 2,3-butanedione and ascorbate

The reactions of both ferric and ferrous horse heart cytochrome c with 2,3-butanedione, pH 7.5, 0.05 M bicarbonate buffer, under a variety of solution conditions, have been examined using amino acid integrity as the primary criterion. The only observable structural alteration was the modification of both the arginyl side chains. The reaction profiles were found to be dependent upon the presence or absence of borate and ascorbate. The single-phased modification of the arginyl side chains in ferrocytochrome c in the absence of borate is rendered biphasic in the presence of borate (borate/reagent ratio of 0.04) through substantial lowering of the rate of reaction of one of the two arginyl side chains. The addition of ascorbate inhibits the reaction in a competitive manner, particularly of the arginyl side chain undergoing rapid modification in its absence. The reactivity of both arginyl side chains to reagent for the ferricytochrome was appreciably larger than for ferrocytochrome c. The addition of reagent to ferricytochrome c also reduces heme iron, which is discerned from the development of a native-like spectrum in the region 500 to 600 nm. The differences in the reactivities of the arginyl side chains to 2,3-butanedione in the two valence states of heme iron are the reflection of small, but definite, conformational differences at the two sites in the two valence states of the protein. The concurrent reduction of heme iron and the modification of the arginyl side chains localizes the reduction and the reaction site for 2,3-butanedione. The inhibition by ascorbate of the reaction of one of the two arginines also identifies the binding domain. Of the two arginines, Arg-38 is suggested to be the ascorbate-binding site.     

Theoretical study to gain fundamental insight into reaction mechanism of N–S acyl transfer of N-sulfanylethylanilide-based protein labeling reagent on protein surface

Elucidation of protein function is one of the central issues in the field of life sciences. To study the function of proteins not in isolation, but in a cell or its lysate, thus, it is necessary to selectively label the target protein in a mixture. Affinity labeling is one of several widely used methods for selective labeling; however, this method has the disadvantage that the labeling reagent is always activated, albeit weakly. Therefore, fine-tuning of the reactivity and/or reaction conditions is generally required for successful target-selective labeling. We previously developed a new affinity labeling reagent with N-sulfanylethylanilide (SEAlide) as a key reactive unit. It was designed based on the following hypotheses. SEAlide is less reactive and does not label in the absence of a target protein. Upon target binding, amino acid side-chain functional groups on the target surface convert SEAlide into a thioester form via N–S acyl transfer, allowing the target to be labeled. However, no evidence has been obtained so far to directly prove the hypothesis. In this study, we examine whether amino acid side-chain functional groups can activate SEAlide from the viewpoint of theoretical chemistry. The theoretical studies show that the activation free energy and enthalpy of the acyl transfer of SEAlide are reduced in the presence of methylammonium, which is a model for the protonated side chain of Lys, and acetate, which is a model for the deprotonated side chain of Asp/Glu. It suggests that Lys and Asp/Glu side chains could potentially stabilize the activation transition states to accelerate the thioester formation. Furthermore, the significant decrease in the activation enthalpy indicates that the contribution of entropy to the transition state is large. This result supports the original hypothesis that the SEAlide-based labeling reagent is efficiently activated by binding to the target protein.     

Characterization of an antibody-urokinase conjugate. A plasminogen activator targeted to fibrin

The plasminogen activator urokinase was linked covalently to a monoclonal antibody specific for the amino terminus of the beta chain of human fibrin by means of the unidirectional cross-linking reagent N-succinimidyl-3-(2-pyridyldithio)propionate. N-Succinimidyl-3-(2-pyridyldithio)propionate allowed the amino groups on urokinase to be coupled to the sulfhydryl groups on iminothiolane (which had been introduced into the antibody before the coupling reaction). The inter-heavy chain sulfhydryl of the Fab' of this antibody was also linked to N-succinimidyl-3-(2-pyridyldithio)propionate-substituted urokinase. The antibody- or Fab'-urokinase complexes were purified by two affinity chromatography steps. In the first, benzamidine was used as ligand for urokinase, in the second, a heptapeptide consisting of the 7 amino-terminal residues of the beta chain of fibrin (beta peptide) was used as ligand for the antibody. The activity of the purified conjugates was compared with that of urokinase alone in an assay measuring lysis of 125I-fibrin monomer covalently linked to Sepharose CL-4B. For any concentration of either urokinase alone or urokinase-antifibrin antibody conjugate, an equivalent amount of lysis (release of labeled peptide from fibrin monomer-Sepharose) was obtained with 1/250 the concentration (with respect to urokinase content) of antifibrin antibody-urokinase conjugate. The antifibrin Fab'-urokinase conjugate exhibited a similar enhancement of activity in comparison with urokinase. Enhanced fibrinolysis was fully inhibited by beta peptide. These results suggest that antibody targeting enhances the concentration of urokinase in the vicinity of immobilized fibrin monomer, thereby also increasing the local conversion of plasminogen to plasmin, which in turn degrades its substrate, fibrin. Univalent antigen-antibody binding is sufficient for optimal efficiency.     

Lysine 480 is an essential residue in the putative ATP site of lamb kidney (Na,K)-ATPase. Identification of the pyridoxal 5'-diphospho-5'-adenosine and pyridoxal phosphate reactive residue

Pyridoxal 5'-diphospho-5'-adenosine (AP2PL) inhibits lamb kidney (Na,K)-ATPase and that inhibition and covalent modification is blocked by the presence of ATP. After trypsin digestion of the labeled, purified alpha subunit and subsequent peptide mapping of the fluorescently labeled peptides by means of high performance liquid chromatography, the main labeled peptide was further purified and analyzed by amino acid composition analysis and peptide sequencing. The obtained peptide had the sequence Ile470-Val-Glu-Ile-Pro-Phe-Asn-Ser-Thr-Asn-Lys480-Tyr-Gln-Le u-Ser-Ile-His- Lys487. Lysine 480 is the residue modified by AP2PL in the absence, but not in the presence of ATP. The beta subunit is not differentially labeled by AP2PL in the presence or absence of ATP. Interestingly, the same results were obtained using pyridoxal phosphate as the labeling and inactivation reagent, indicating that the specificity of labeling by these reagents is not due to the presence of the adenosine moiety, but instead that the initial recognition of nucleotides by the ATP-binding site of (Na,K)-ATPase may be due to recognition of the phosphate moiety. The amino acid sequence surrounding this lysine residue labeled by both reagents is highly conserved in (Na,K)-ATPase and the related (H,K)-ATPase sequences thus far obtained, which may signify a functional importance for this region of the putative ATP-binding site in these transport proteins.     

Stepwise synthesis of oligopeptides with N-carboxy α-amino acid anhydrides. II. Oligopeptides with some polar side chains

The reaction of NCA's with some amino acids having a nucleophilic functional group on the side chain was studied in a heterogeneous reaction medium (acetonitrile-water). Glutamic acid and aspartic acid, having a free carboxyl group on the side chain, were successfully used to synthesize oligopeptides without interactions of the γ- and β-carboxyl group with NCA's. Two products were obtained by the reaction of NCA with L -lysine, which contains a free amino group on the side chain. ε-Protected lysine was used to prepare α-peptides as a nucleophile in the reaction. No racemization was observed in the synthesis of peptides by the NCA method in the heterogeneous solvent system. Oligopeptides with some polar side chains were synthesized by the NCA method.