Oxidation of tryptophan to oxindolylalanine by dimethyl sulfoxide-hydrochloric acid. Selective modification of tryptophan containing peptides

Macrocyclic Oxindole Peptide Epoxyketones-A Comparative Study of Macrocyclic Inhibitors of the 20S Proteasome

Peptide macrocycles have recently gained attention as protease inhibitors due to their metabolic stability and specificity. However, the development of peptide macrocycles with improved binding potency has so far been challenging. Here we present macrocyclic peptides derived from the clinically applied proteasome inhibitor carfilzomib with an oxindole group that mimics the natural product TMC-95A. Fluorescence kinetic activity assays reveal a high potency of the oxindole group (IC50 = 0.19 μM) compared with agents lacking this motif. X-ray structures of the ligands with the β5-subunit of the yeast 20S proteasome illustrate that the installed macrocycle forces strong hydrogen bonding of the oxindole group with β5-Gly23NH. Thus, the binding of our designed oxindole epoxyketones is entropically and enthalpically favored in contrast to more flexible proteasome inhibitors such as carfilzomib.

Chemical modifications of tryptophan residues in peptides and proteins

Chemical protein modifications facilitate the investigation of natural posttranslational protein modifications and allow the design of proteins with new functions. Proteins can be modified at a late stage on amino acid side chains by chemical methods. The indole moiety of tryptophan residues is an emerging target of such chemical modification strategies because of its unique reactivity and low abundance. This review provides an overview of the recently developed methods of tryptophan modification at the peptide and protein levels.

Investigation of tryptophan-related yellowing in parenteral amino acid solution: Development of a stability-indicating method and assessment of degradation products in pharmaceutical formulations

Parenteral amino acid solutions containing tryptophan tend to develop a yellow colouration upon storage. Hence, the aim of the present study was to find out whether tryptophan degradation products are the reason for the yellowing. The degree of discolouration and tryptophan degradation was examined by visual examination and UV/Vis measurements with respect to oxygen presence, pH value, and duration of steam sterilization. LC-UV analyses of autoclaved tryptophan solutions indicated eight degradation products, namely R,R/R,S 2-amino-3-(oxoindolin-3-yl)propanoic acid, R,R/R,S 2-amino-3-hydroxy-2-oxoindolin-3-yl)propanoic acids, cis/trans 3a-hydroxy-1,2,3,3a,8,8a-hexahydropyrrolo[2,3-b]indole-2-carboxylic acid, N´-formylkynurenine, and kynurenine. The proposed degradation products were confirmed by spiking of synthesized degradation products and LC-UV/MS analyses. The LC-UV analysis method was optimized and validated according to the ICH guideline Q2 (R1). Tryptophan stability in commercially available parenteral amino acid formulations was evaluated over a storing period of 12 months in two common types of primary packaging after autoclave procedure.

Covalent Modification of Amino Acids and Peptides Induced by Ionizing Radiation from an Electron Beam Linear Accelerator Used in Radiotherapy

To identify modifications to amino acids that are directly induced by ionizing radiation, free amino acids and 3-residue peptides were irradiated using a linear accelerator (Linac) radiotherapy device. Mass spectrometry was performed to detail the relative sensitivity to radiation as well as identify covalent, radiation-dependent adducts. The order of reactivity of the 20 common amino acids was generally in agreement with published literature except for His (most reactive of the 20) and Cys (less reactive). Novel and previously identified modifications on the free amino acids were detected. Amino acids were far less reactive when flanked by glycine residues in a tripeptide. Order of reactivity, with GVG most and GEG least, was substantially altered, as were patterns of modification. Radiation reactivity of amino acids is clearly and strongly affected by conversion of the α-amino and α-carboxyl groups to peptide bonds, and the presence of neighboring amino acid residues.

Tryptophan-derived butyrylcholinesterase inhibitors as promising leads against Alzheimer's disease

We have identified tryptophan-based selective nanomolar butyrylcholinesterase (BChE) inhibitors. They are defined according to their chemical modularity, novel binding mode revealed by five solved crystal structures with human BChE, low cytotoxicity, and predicted permeability of the blood-brain barrier. Altogether, these factors indicate their potential as unique lead compounds for symptomatic therapy against Alzheimer's disease.

Construction of Spirooxindole Skeleton Through Intramolecular Dieckmann Cyclization

A highly efficient and direct approach was developed to construct the structurally diverse spirooxindole skeleton, which is an important basic motif in natural products. Both the 3,3'-pyrrolidonyl spirooxindoles and spiroindolin-2-one δ-lactones were smoothly obtained by the intramolecular Dieckmann cyclization of oxindoles in excellent yield under mild conditions.

Synthesis and disaggregation of asparagine repeat-containing peptides

Of all amino acid repeats in eukaryotes, polyglutamine (polyQ) is the most frequent, followed by polyasparagine (polyN). Glutamine repeats are expanded in proteins associated with several neurodegenerative disorders. The expanded polyQ domain is known to induce aggregation, and it is hypothesized that aggregation is directly causative of pathology. Despite the widespread presence of asparagine repeats in invertebrate eukaryotes, polyN is curiously quite rare in vertebrates. Several investigators have characterized the conformational and aggregation properties of polyQ-containing peptides and proteins, and to a lesser extent, peptides containing mixed glutamine and asparagine, but to our knowledge, there is no detailed characterization of polyN-containing peptides. Such a comparison could elucidate reasons for the paucity of asparagine repeats in humans. In this study, we synthesized a peptide containing a 24-asparagine repeat (N24). For aggregation studies, it is critical to start with monomeric unaggregated peptide. A protocol involving dissolution in mixed trifluoroacetic acid and hexafluoroisopropanol (TFA + HFIP) solvents is widely used for disaggregation of polyQ peptides. We used the same protocol for N24 but discovered that there was both oxidative damage and insufficient disaggregation. Oxidation of tryptophan, used as a flanking residue, was common. Moreover, we found evidence of Förster resonance energy transfer between Trp and its oxidation product N-formylkynurenine, even in chemical denaturants. This suggested that N24 was insufficiently disaggregated, a conclusion that was further supported by gel electrophoresis analysis. Oxidation was reduced, but not eliminated, by addition of methionine to the buffer. Formic acid proved to be a better disaggregator and caused no oxidative damage. The glutamine repeat peptide Q24 also underwent some oxidation after extended incubation in TFA + HFIP, but there was no evidence of Förster resonance energy transfer, and samples appeared monomeric by gel electrophoresis. This result indicates that polyN-containing peptides self-associate more strongly than polyQ-containing peptides. Circular dichroism spectra reveal a greater propensity for β-turn formation in polyN than polyQ, providing an explanation for the increased stability of polyN aggregates relative to polyQ.

Instabilities of proteins: theoretical aspects, degradation products and methods for their detection

Recombinant DNA technology has led to a significant increase in the number of peptide and protein based pharmaceuticals, giving a new approach to combat poorly controlled diseases. This particular development has been reached in the last two decades. However, proteins are highly susceptible of physical and chemical degradation resulting in a decrease or complete loss of biological activities. Reasons for their physical and chemical instabilities and the methods for their examination, become a challenge for the pharmaceutical scientists for successful development of stabile protein - based pharmaceuticals. The stability of protein - based pharmaceuticals is significant in terms of their pharmaceutical quality and biological activity. In addition, a right choice of suitable analytical methods is needed in order to detect an early formation of degradation products or modified forms.

Catalytic mechanism of the tryptophan synthase alpha(2)beta(2) complex. Effects of pH, isotopic substitution, and allosteric ligands

The mechanism of the tryptophan synthase alpha(2)beta(2) complex from Salmonella typhimurium is explored by determining the effects of pH, of temperature, and of isotopic substitution on the pyridoxal phosphate-dependent reaction of L-serine with indole to form L-tryptophan. The pH dependence of the kinetic parameters indicates that three ionizing groups are involved in substrate binding and catalysis with pK(a)1 = 6.5, pK(a)2 = 7.3, and pK(a)3 = 8.2-9. A significant primary isotope effect (approximately 3.5) on V and V/K is observed at low pH (pH 7), but not at high pH (pH 9), indicating that the base that accepts the alpha-proton (betaLys-87) is protonated at low pH, slowing the abstraction of the alpha-proton and making this step at least partially rate-limiting. pK(a)2 is assigned to betaLys-87 on the basis of the kinetic isotope effect results and of the observation that the competitive inhibitors glycine and oxindolyl-L-alanine display single pK(i) values of 7.3. The residue with this pK(a) (betaLys-87) must be unprotonated for binding glycine or oxindolyl-L-alanine, and, by inference, L-serine. Investigations of the temperature dependence of the pK(a) values support the assignment of pK(a)2 to betaLys-87 and suggest that the ionizing residue with pK(a)1 could be a carboxylate, possibly betaAsp-305, and that the residue associated with a conformational change at pK(a)3 may be betaLys-167. The occurrence of a closed to open conformational conversion at high pH is supported by investigations of the effects of pH on reaction specificity and on the equilibrium distribution of enzyme-substrate intermediates.

Linear dichroism studies of tryptophanase and its quasisubstrate complexes oriented in polyacrylamide gel

Tryptophanase from Escherichia coli was oriented in a compressed slab of polyacrylamide gel and its linear dichroism (LD) and absorption spectra have been measured. The free enzyme displays four LD bands at 305, 340, 425 and 490 nm. Two bands at 340 and 425 nm belong to the internal coenzyme-lysine aldimine. The 305-nm band apparently belongs to an aromatic amino acid residue. The 490-nm band disappears after treatment with NaBH4 or after incubation with L-alanine and subsequent dialysis. It is suggested that the 490-nm band belongs to a quinonoid enzyme subform. The reaction of tryptophanase with threo-3-phenyl-DL-serine, L-threonine and D-alanine leads to formation of an external aldimine with an intense absorption band at 420-425 nm. The values of reduced LD (delta A/A) in this band strongly differ from that in the 420-nm band of the free enzyme. The LD value of the complex with D-alanine is intermediate between those of the free enzyme and the complex with 3-phenylserine. In the presence of indole the complex with D-alanine displays the same LD as that observed with 3-phenylserine. The reaction of tryptophanase with L-alanine or oxindolyl-L-alanine leads to formation of a quinonoid intermediate with an absorption band near 500 nm. The LD value in this band is close to that of an external aldimine with L-threonine. It is concluded that reorientations of the coenzyme occur in the course of the tryptophanase reaction.

Binding of placental ribonuclease inhibitor to the active site of angiogenin

The importance of specific residues in angiogenin for binding to placental ribonuclease inhibitor (PRI) has been assessed by examining the interaction of angiogenin derivatives with PRI. PRI binds native angiogenin with a Ki value of 7.1 X 10(-16) M [Lee, F. S., Shapiro, R., & Vallee, B. L. (1989) Biochemistry 28, 225-230]. Substitution of a Gln for Lys-40 in angiogenin by site-specific mutagenesis decreases the association rate constant 3-fold and increases the dissociation rate constant 440-fold, resulting in a 1300-fold weaker Ki value. The half-life of the mutant.PRI complex is 3.4 h compared to approximately 60 days for the native angiogenin.PRI complex. The magnitude of the change in Ki value suggests that in the complex, Lys-40 forms a salt bridge or hydrogen bond with an anionic moiety in PRI. Carboxymethylation of His-13 or His-114 with bromoacetate increases the Ki value 15-fold, and oxidation of Trp-89 by means of dimethyl sulfoxide and hydrochloric acid increases it 2.4-fold, suggesting that these residues also form part of the contact region with PRI. The changes in Ki value reflect an increase in the dissociation rate constant. On the other hand, dinitrophenylation of either Lys-50 or Lys-60 with 1-fluoro-2,4-dinitrobenzene does not significantly alter the Ki value, suggesting that these residues are not part of the contact region. These results indicate that PRI inhibition minimally involves the three residues critical for the activity of angiogenin--Lys-40, His-13, and His-114--and to a lesser extent its single tryptophan, Trp-89.

Conformational changes in the active site of tryptophanase revealed by the circular dichroism method

Tryptophanase from E. coli displays positive CD in the coenzyme absorption bands at 337 and 420 nm. Breaking of the internal coenzyme-lysine imine bond upon reaction with hydroxylamine or amino-oxyacetate is accompanied by a strong diminution of the positive CD. Interaction of tryptophanase with L-threonine and beta-phenyl-DL-serine(threo form) leads to a decrease in absorbance at 337 nm and to an increase at 425 nm. This is associated with inversion of the CD sign, i.e. with disappearance of the positive CD in the 420-nm band and its replacement by a negative CD. L-Phenylalanine, alpha-methyl-DL-serine and D-alanine cause an increase in absorbance at 425-430 nm and a diminution of the positive CD in this band. In the presence of D-alanine and indole a negative CD appears in the 400-450 nm region. It is inferred that an external coenzyme-quasisubstrate aldimine is formed on interaction of the above amino acids with the enzyme. L-Alanine and oxindolyl-L-alanine evoke an intense narrow absorption band at 500 nm ascribed to a quinonoid intermediate; a positive CD is observed in this band. The dissymmetry factor delta A/A in the 500-nm band is much smaller than that in the absorption bands of the unliganded enzyme. Inversion of the CD sign on formation of the external aldimine and diminution of the dissymmetry factor in the quinonoid band indicate that reorientations of the coenzyme occur in the course of the catalytic action of tryptophanase.

Mechanistic deductions from multiple kinetic and solvent deuterium isotope effects and pH studies of pyridoxal phosphate dependent carbon-carbon lyases: Escherichia coli tryptophan indole-lyase

Analysis of the pH dependence of the kinetic parameters and competitive inhibitor Ki values for tryptophan indole-lyase suggests two enzymic groups must be unprotonated in order to facilitate binding and catalysis of tryptophan. The V/K for tryptophan and the pKi for oxindolyl-L-alanine, a putative transition state analogue and competitive inhibitor, decrease below two pK values of 7.6 and 6.0, while the Ki for L-alanine, also a competitive inhibitor, is 3300-fold larger (20 mM) than that for oxindolyl-L-alanine and increases below a single pK of 7.6. A single pK of 7.6 is also observed in the V/K profile for the alternate substrate, S-methyl-L-cysteine. Therefore, the enzymic group with a pK of 7.6 is responsible for proton abstraction at the 2-position of tryptophan, while the enzymic group with a pK of 6.0 interacts with the indole portion of tryptophan and probably catalyzes formation of the indolenine tautomer of tryptophan (in concert with proton transfer to C-3 of indole from the group with pK 7.6) to facilitate carbon-carbon bond cleavage and elimination of indole. The pH variation of the primary deuterium isotope effects for proton abstraction at the 2-position of tryptophan (DV = 2.5 and D(V/Ktrp) = 2.8) are pH independent, while the Vmax for tryptophan or S-methyl-L-cysteine is the same and also pH independent. Thus, substrates bind only to the correctly protonated form of the enzyme. Further, tryptophan is not sticky, and the pK values observed in both V/K profiles are the correct ones.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of peptides containing oxidized methionine and/or tryptophan by fast atom bombardment mass spectrometry

Treatment of peptides containing methionine and/or tryptophan with dimethylsulfoxide/hydrochloric acid/acetic acid resulted in oxidation of these amino acids respectively to methionine sulfoxide and oxyindolalanine. This reaction was monitored by fast atom bombardment mass spectrometry using a dithiothreitol/dithioerythritol liquid matrix. Under these conditions, only methionine and tryptophan were oxidized. Comparison of mass spectra of a sample before and after oxidation should provide a rapid screening procedure for determination of these residues in peptides.

Additional observations on cholecystokinin and the vasoactive intestinal polypeptide

During the isolation of cholecystokinin from natural sources, as well as during its bioassay, inactivation by oxidation can cause problems. We have attempted to reactivate oxidized CCK by reduction at room temperature with N-methylmercaptoacetamide, recently stated to be the reducing agent of choice for the reduction of methionine sulfoxide to methionine [22]. We have not yet been unequivocally successful in these attempts, but the results seem promising. In the case of oxidized VIP and of oxidized tetragastrin, reduction with N-methylmercaptoacetamide does seem to result in reconversion of the peptides to their preoxidation states, as evidenced by thin layer chromatography on silica gel. We have, together with A. Holmgren and A. Ehrnberg, made observations suggesting the presence in rate liver cytosol of an enzyme which catalyzes the reductive reactivation of oxidized CCK with reduced thioredoxin as the immediate hydrogen donor. In collaboration with A. Light, Purdue University, we have found that enterokinase cleaves 39-CCK and 33-CCk with release of 8-CCK and the tetrapeptide immediately preceding it in the peptide chain. The conversion of 39-CCK to 33-CCK by the action of dipeptidyl amino-peptidase I has been confirmed.