The solid-state catalytic isotope exchange of hydrogen in α-conotoxin G1 by the tritium spillover

Tritium-labeled α-conotoxin G1 with a molar radioactivity of 35 Ci/mmol and full biological activity (according to the binding to nicotinic acetylcholine receptor) was obtained by the high-temperature solid-state catalytic isotope exchange (HSCIE). The tritium distribution in the molecule of α-conotoxin G1 was revealed by³H NMR spectroscopy. Tritium was found in all amino acid residues except for the Asn4-Pro5-Ala6 fragment. The data on the comparative reactivity of C-H bonds, theab initio quantum-chemical calculation of the hydrogen exchange reaction, and the information on the spatial structures of α-conotoxin G1 in solution and in crystal state allowed us to establish that the reactivity of H atoms may be increased by their interaction with the electron donor O and N atoms at the transition state of the HSCIE reaction. A decrease in the rate of the HSCIE reaction could be caused by both a poor spatial accessibility of C-H bonds and a limited mobility of the peptide fragment containing these bonds.     

The effect of three-dimensional structure on the solid state isotope exchange of hydrogen in polypeptides with spillover hydrogen

The effect of the three-dimensional structure of polypeptides and proteins on their ability to undergo isotopic exchange under the action of spillover hydrogen (SH) in the high temperature solid state catalytic isotope exchange reaction (HSCIE) was theoretically and experimentally studied. The HSCIE reaction in the beta-galactosidase protein from Thermoanaerobacter ethanolicus (83kDa) was studied. The influence of the beta-galactosidase structure on isotopic exchange as peptide fragments with spillover tritium was studied. The most accessible peptide fragment, which does not contribute to alpha-helix and beta-strand formations (KEMQKE215-220), had the largest relative reactivity. The one located in the contact area between the subunits (YLRDSE417-422) showed the smallest relative reactivity. The relative reactivities of these peptides differ more than 150 times. Data collected during a study devoted to the HSCIE reaction of the beta-galactosidase protein indicate that the HSCIE reaction might be employed for acquiring information about their three-dimensional structure and protein-protein interactions. The results of ab initio calculations have shown that alpha-helix formation in polypeptides decreases the reactivity in HSCIE. Hydrogen exchange in the alpha-helical fragment Trp1-Leu8 of zervamycin IIB was also analyzed using theoretical methods. It was shown by ab initio quantum-chemical calculations that the high degree of substitution of C(alpha)H for tritium in Gln3 might be associated with the participation of electron donor O and N atoms in transition state stabilization in the HSCIE reaction.     

The solid-state catalytic synthesis of tritium labeled amino acids,peptides and proteins

Summary New catalytic reaction between a solid bioorganic compound and activated spillover tritium (ST), based on High-temperature Solid-state Catalytic Isotopic Exchange (HSCIE) was examined. The HSCIE mechanism and determination of the reactivity of hydrogen atoms in amino acids, peptides and proteins was investigated. Quantum mechanical calculations of the reactivity of hydrogen atoms in amino acids in the HSCIE reaction were done. The carbon atom with a greater proton affinity undergoes a greater exchange of hydrogen for tritium in HSCIE. The electrofilic nature of spillover hydrogen in the reaction of HSCIE was revealed. The isotope exchange between ST and the hydrogen of the solid organic compound proceeds with a high degree of configuration retention at the carbon atoms. The HSCIE reaction enables to synthesize tritium labeled proteins with a specific activity of 20–30 mCi/mg and kept biological activity.Presented at the 3rd International Congress on Amino Acids, Peptides and Analogues. Vienna, August, 23–27, 1993     

Solid phase isotope exchange with spillover hydrogen in amino acids,peptides, and proteins

We summarize here information on the theoretical and experimental study of high-temperature (150–200°C) solid phase catalytic isotope exchange (HSCIE) carried out with amino acids, peptides, and proteins under the action of spillover hydrogen. Main specific features of the HSCIE reaction, its mechanism, and its use for studying spatial interactions in polypeptides are discussed. A virtually complete absence of racemization makes this reaction a valuable preparative method. The main regularities of the HSCIE reaction with the participation of spillover tritium have been revealed in the case of peptides and proteins, and the dependence of reactivity of peptide fragments on the spatial organization of their molecules has been studied. An important peculiarity of this reaction is that HSCIE proceeds at 150–200°C with a high degree of chirality retention in amino acids and peptides. This is provided by its reaction mechanism, which consists in a synchronous one-center substitution at the saturated carbon atom characterized by the formation of pentacoordinated carbon and a three-center bond between the carbon and the incoming and outgoing hydrogen atoms.Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 1, 2005, pp. 3–21.Original Russian Text Copyright © 2005 by Zolotarev, Dadayan, Borisov.     

Stability and structure-forming properties of the two disulfide bonds of alpha-conotoxin GI

alpha-Conotoxin GI is a 13 residue snail toxin peptide cross-linked by Cys2-Cys7 and Cys3-Cys13 disulfide bridges. The formation of the two disulfide bonds by thiol/disulfide exchange with oxidized glutathione (GSSG) has been characterized. To characterize formation of the first disulfide bond in each of the two pathways by which the two disulfide bonds can form, two model peptides were synthesized in which Cys3 and Cys13 (Cono-1) or Cys2 and Cys7 (Cono-2) were replaced by alanines. Equilibrium constants were determined for formation of the single disulfide bonds of Cono-1 and Cono-2, and an overall equilibrium constant was measured for formation of the two disulfide bonds of alpha-conotoxin GI in pH 7.00 buffer and in pH 7. 00 buffer plus 8 M urea using concentrations obtained by HPLC analysis of equilibrium thiol/disulfide exchange reaction mixtures. The results indicate a modest amount of cooperativity in the formation of the second disulfide bond in both of the two-step pathways by which alpha-conotoxin GI folds into its native structure at pH 7.00. However, when considered in terms of the reactive thiolate species, the results indicate substantial cooperativity in formation of the second disulfide bond. The solution conformational and structural properties of Cono-1, Cono-2, and alpha-conotoxin GI were studied by 1H NMR to identify structural features which might facilitate formation of the disulfide bonds or are induced by formation of the disulfide bonds. The NMR data indicate that both Cono-1 and Cono-2 have some secondary structure in solution, including some of the same secondary structure as alpha-conotoxin GI, which facilitates formation of the second disulfide bond by thiol/disulfide exchange. However, both Cono-1 and Cono-2 are considerably less structured than alpha-conotoxin GI, which indicates that formation of the second disulfide bond to give the Cys2-Cys7, Cys3-Cys13 pairing induces considerable structure into the backbone of the peptide.     

Solid phase catalytic hydrogen isotope exchange in dalargin

A [3H]Dalargin preparation with a molar radioactivity of 52 Ci/mmol was obtained by the high temperature solid-state catalytic isotope exchange (HSCIE) of tritium for hydrogen at 150 degrees C. This tritium-labeled peptide was shown to completely retain its biological activity in the test of binding to opioid receptors from rat brain. The dissociation constant of the Dalargin-opioid receptor complex was found to be 4.3 nM. The dependencies of the chemical yield and the molar radioactivity on the reaction time and temperature of HSCIE were determined. The activation energy of the HSCIE reaction for the peptide was calculated to be 32 kcal/mol. The amino acid analysis showed that tritium is distributed between all the amino acid residues of [3H]Dalargin at the HSCIE reaction, with the temperature growth significantly increasing the total tritium incorporation and, especially, enhancing the radioactivity incorporation into aromatic residues.     

The solid-state catalytic isotope exchange of hydrogen in dalargin

A [³H]Dalargin preparation with a molar radioactivity of 52 Ci/mmol was obtained by the high temperature solid-state catalytic isotope exchange (HSCIE) of tritium for hydrogen at 150°C. This tritium-labeled peptide was shown to completely retain its biological activity in the test of binding to opioid receptors from rat brain. The dissociation constant of the Dalargin-opioid receptor complex was found to be 4.3 nM. The dependences of the chemical yield and the molar radioactivity on the reaction time and temperature of HSCIE were determined. The activation energy of the HSCIE reaction for the peptide was calculated to be 32 kcal/mol. The amino acid analysis showed that tritium is distributed between all the amino acid residues of [³H]Dalargin at the HSCIE reaction, with the temperature growth significantly increasing the total tritium incorporation and, especially, enhancing the radioactivity incorporation into aromatic residues.     

Solid phase reaction of hemoglobin with spillover hydrogen

The reaction of high-temperature solid-state catalytic isotope exchange (HSCIE) between bovine hemoglobin and spillover hydrogen (SH) was studied. It was shown that, in the field of subunit contact, there is a significant decrease in ability for hydrogen exchange by SH. A comparison of the distribution of the isotope label in the hemoglobin α-subunit was carried out for the HSCIE reaction with the hemoglobin complex and with the free α-subunit. To this end, enzymatic hydrolysis of protein under the action of trypsin was carried out. The separation of tritium-labeled tryptic peptides was achieved by HPLC. Changes in availability of polypeptide chain fragments caused by complex formation were calculated using a molecular model. The formation of the protein complex was shown to lead to a decrease in the ability of fragments of α-subunits MFLSFPTTK (A_32?40) and VDPVNFK (A_93?99) for hydrogen replacement by tritium by almost an order of magnitude; hence, their availability to water (1.4 Å) twice decreased on the average. The decrease in ability to an exchange of hydrogen by spillover tritium on the formation of hemoglobin complex was shown to be connected with a reduction in availability of polypeptide chain fragments participating in spatial interactions of subunits with each other. Thus, the HSCIE reaction can be used not only for the preparative obtaining of tritium-labeled compounds, but also for determining the contact area in the formation of protein complexes.     

Identification of the sites of hydroxyl radical reaction with peptides by hydrogen/deuterium exchange: prevalence of reactions with the side chains

Hydroxyl radical-effected protium/deuterium ((1)H/(2)H) exchange into the C-H bonds present in peptides has been used to identify the site of hydrogen atom abstraction by hydroxyl radical. Radiolysis of anaerobic, N(2)O-saturated D(2)O solutions containing peptide and dithiothreitol generates a hydroxyl radical that mediates (1)H/(2)H exchange into the side chains of peptides of up to 66 atom % excess (2)H. The (1)H/(2)H exchange is determined by measuring the isotope ratio, [M + H + 1](+)/[M + H](+), of the peptide using electrospray ionization-mass spectrometry. The (1)H/(2)H exchange within each residue of the peptide was determined by measuring the isotope ratio of each isolated dansyl amino acid following hydrolysis and derivatization. Generation of 0.40 mM hydroxyl radical effected (1)H/(2)H exchange into each of the five different residues of (Ala(2))-leucine enkephalin (YAGFL). The propensity of the residues to undergo exchange was L > Y > A congruent with F > G, independent of whether they were radiolyzed separately or as the peptide. The minimal exchange into glycine suggests that reaction of hydroxyl radical with the side chain hydrogens predominates over reaction with the polypeptide alpha-hydrogens. The ability of radiolysis to effect (1)H/(2)H exchange into a larger peptide, SNEQKACKVLGI, was also demonstrated.     

C-H...O hydrogen bonds in the nuclear receptor RARgamma--a potential tool for drug selectivity

Hydrogen bonds between polarized atoms play a crucial role in protein interactions and are often used in drug design, which usually neglects the potential of C-H...O hydrogen bonds. The 1.4 A resolution crystal structure of the ligand binding domain of the retinoic acid receptor RARgamma complexed with the retinoid SR11254 reveals several types of C-H...O hydrogen bonds. A striking example is the hydroxyl group of the ligand that acts as an H bond donor and acceptor, leading to a synergy between classical and C-H...O hydrogen bonds. This interaction introduces both specificity and affinity within the hydrophobic ligand pocket. The similarity of intraprotein and protein-ligand C-H...O interactions suggests that such bonds should be considered in rational drug design approaches.     

Observation of internucleotide NH...N hydrogen bonds in the absence of directly detectable protons

Several structural motifs found in nucleic acids involve N-H...N hydrogen bonds in which the donor hydrogens are broadened to extinction due to chemical or conformational exchange. In such situations, it is impossible to use the well-established HNN-COSY or soft HNN-COSY experiments, which report the presence of the hydrogen bond directly on the donor proton(s). We present a pulse sequence, H(CN)N(H), for alleviating this problem in hydrogen bonds of the type NdH...Na-CH, in which the donor Nd nitrogen is correlated with the corresponding non-exchangeable C-H proton associated with the acceptor Na nitrogen. In this way, missing NdH...Na correlations in an HNN-COSY spectrum may be recovered from CH-Nd correlations in the H(CN)N(H) spectrum. By correlating a different set of nuclei relative to the HNN-COSY class of experiments, the H(CN)N(H) experiment also serves to remove ambiguities associated with degeneracies in HNN-COSY spectra. The technique is demonstrated on d(GGAGGAG)4,a quadruplex containing a novel A. (G.G.G.G). A hexad and on d(GGGCAGGT)4, containing a G.G.G.C tetrad, in which missing NH2...N7 correlations are retrieved via H8-(N2,N6) correlations in the H(CN)N(H) spectrum.     

Silacyclobutenes - Synthesis and reactivity

Silacyclobutenes can be prepared using different synthetic approaches such as: nucleophilic substitution reactions of organometallic reagents with silahalides; reaction of intermediary silenes or silylenes generated under FVP-conditions or by complex reagents, subsequently the silenes reacting in inter- or intramolecular [2+2] cycloaddition with CC or CC bonds and the silylenes commonly via intramolecular insertion reaction into C-H bonds to give silacyclobutenes; use of transition metal complexes as catalysts or reagents. The reactivity of silacyclobutenes is depending on the substituents at the silicon center and at the carbon ring atoms with their reactions leading to a wide range of materials.     

Study of the intermolecular association of poly(G).poly(c) and poly(dG).poly(dC) in solutions by methods of 1H to 3H exchange and electron microscopy

The kinetic of 1H leads to 3H exchange between water and C(8)H-groups of the guanylic residues in poly(G) . poly(C) and poly(dG) . poly(dC) was investigated within the temperature range from 30 to 90 degrees in 0.5 M NaCl (pH 7.2). It was shown that the exchange in freshly dissolved preparations at temperatures lower than 50 degrees proceeds faster than that in the case of GMP. According to the ylide mechanism of the exchange reaction the observed acceleration of the exchange is considered as a consequence of associates formation in poly(G) . poly(c) and poly(dG) . poly(dC) solutions at temperatures lower than 50 degrees. Associates are stabilized by intermolecular hydrogen bonds in which N(7) atoms of guanylic residues take part. The increase of the temperature is accompanied by gradual disappearance of the exchange acceleration. The retardation of exchange, which is characteristic of most non-associated double-stranded polynucleotides and nucleic acids is observed at the temperatures above 60 degrees. The retardation points to thermal destruction of the associates at temperatures higher than 50 degrees. The associates which are characterized by ordered structure including several "side by side" arranged double-stranded molecules were observed by electron microscopy. The addition of EDTA to solutions as well as the increase of temperature leads to destruction of the associates whereas the addition of Mg2+ makes the associates more stable.     

Pulse sequences for detection of NH2···N hydrogen bonds in sheared G⋅A mismatches via remote, non-exchangeable protons

The non-detectability of NH...N hydrogen bonds in nucleic acids due to exchange broadened imino/amino protons has recently been addressed via the use of non-exchangeable protons for detecting internucleotide 2hJ(NN) couplings. In these applications, the appropriate non-exchangeable proton is separated by two bonds from the NH...N bond. In this paper, we extend the scope of this approach to protons which are separated by four bonds from the NH...N moiety. Specifically, we consider the case of the commonly occurring sheared G x A mismatch alignment, in which we use the adenine H2 proton to report on the (A)N6H6(1.2)...N3(G) hydrogen bond, in the presence of undetectable, exchange broadened N6H6(1.2) protons. Two sequences, the 'straight-through' (H6)N6N3H2 and 'out-and-back' H2N6N3 experiments, are presented for observing these correlations in H2O and D2O solution, respectively. The sequences are demonstrated on two uniformly 15N,13C labelled DNA samples: d(G1G2G3T4T5C6A7G8G9)2, containing a G3 x (C6-A7) triad involving a sheared G3 x A7 mismatch, and d(G1G2G3C4A5G6G7T8)4, containing an A5 x (G3 x G6 x G3 x G6) x A5 hexad involving a sheared G3 x A5 mismatch.     

Synthetic active site analogues of heme-thiolate proteins. Characterization and identification of intermediates of the catalytic cycles of cytochrome P450cam and chloroperoxidase

In view of recent results from different sources, the reaction mechanisms of two heme-thiolate proteins, cytochrome P450cam and chloroperoxidase (CPO), are discussed. In this context a mechanism of CPO is proposed which includes H2O2 cleavage, subsequent formation of compound I and the identification of two elusive intermediates. The HOCl adduct of the iron(III)porpyhrin is the catalytically competent Cl+ donor chlorinating activated C-H bonds of substrates bound to the enzyme. Pulse-EPR characterization of an enzyme model of the resting state of P450cam suggests a role of the electric field of the protein for stabilizing the low-spin state of the cofactor of the enzyme. It is further suggested that the same effect of the protein may trigger the reactivity of compound I such that both concerted and two-step reactions are feasible within the concept of a Two-State-Reactivity. This review emphasizes the value of synthetic enzyme models complementing investigations of the native proteins.     

Crystal structure of an Fab fragment in complex with a meningococcal serosubtype antigen and a protein G domain.

Many pathogens present highly variable surface proteins to their host as a means of evading immune responses. The structure of a peptide antigen corresponding to the subtype P1.7 variant of the porin PorA from the human pathogen Neisseria meningitidis was determined by solution of the X-ray crystal structure of the ternary complex of the peptide (ANGGASGQVK) in complex with a Fab fragment and a domain from streptococcal protein G to 1.95 A resolution. The peptide adopted a beta-hairpin structure with a type I beta-turn between residues Gly4P and Gly7P, the conformation of the peptide being further stabilised by a pair of hydrogen bonds from the side-chain of Asn2P to main-chain atoms in Val9P. The antigen binding site within the Fab formed a distinct crevice lined by a high proportion of apolar amino acids. Recognition was supplemented by hydrogen bonds from heavy chain residues Thr50H, Asp95H, Leu97H and Tyr100H to main-chain and side-chain atoms in the peptide. Complementarity-determining region (CDR) 3 of the heavy chain was responsible for approximately 50 % of the buried surface area formed by peptide-Fab binding, with the remainder made up from CDRs 1 and 3 of the light chain and CDRs 1 and 2 of the heavy chain. Knowledge of the structures of variable surface antigens such as PorA is an essential prerequisite to a molecular understanding of antigenic variation and its implications for vaccine design.     

Theoretical study on rate constants for the reactions of CF3CH2NH2 (TFEA) with the hydroxyl radical at 298 K and atmospheric pressure

Theoretical investigations are carried out on reaction mechanism of the reactions of CF₃CH₂NH₂ (TFEA) with the OH radical by means of ab initio and DFT methods. The electronic structure information on the potential energy surface for each reaction is obtained at MPWB1K/6-31+G(d,p) level and energetic information is further refined by calculating the energy of the species with a Gaussian-2 method, G2(MP2). The existence of transition states on the corresponding potential energy surface is ascertained by performing intrinsic reaction coordinate (IRC) calculation. Our calculation indicates that the H abstraction from –NH₂ group is the dominant reaction channel because of lower energy barrier. The rate constants of the reaction calculated using canonical transition state theory (CTST) utilizing the ab initio data. The agreement between the theoretical and experimental rate constants is good at the measured temperature. From the comparison with CH₃CH₂NH₂, it is shown that the fluorine substution decreases the reactivity of the C-H bond.     

Measurement of protein turnover rates by heavy water labeling of nonessential amino acids

In vivo measurements of protein synthesis using isotope-labeled amino acids (AAs) are hampered by the heterogeneity of AA pools and, for slow turnover proteins, the difficulty and expense of long-term labeling. Continuous oral heavy water (2H2O) labeling can safely maintain stable body water 2H enrichments for weeks or months. 2H is metabolically incorporated into C-H bonds of nonessential AAs (NEAAs) and hence into proteins. No posttranslational label exchange occurs, so 2H incorporation into protein NEAAs, in principle, reports on protein synthesis. Here, we show by mass isotopomer distribution analysis (MIDA) of 2H2O-labeled rodent tissue proteins that metabolic 2H flux into C-H bonds of Ala, Gly, or Gln used for protein synthesis is nearly complete. By 2H2O labeling of rodents, turnover of bone and muscle mixed proteins was quantified and stimulation of liver collagen synthesis by CCl4 was detected. Kinetics of several human serum proteins were also measured, reproducing published t1/2 estimates. Plateau enrichments in Ala varied among different proteins. Moderate amounts of protein, isolated chromatographically or electrophoretically, sufficed for kinetic analyses. In conclusion, 2H2O labeling permits sensitive, quantitative, operationally simple measurements of protein turnover in vivo by the rise-to-plateau approach, especially for proteins with slow constitutive turnover.     

Ligands of glutamate and dopamine receptors evenly labeled with hydrogen isotopes

Abstact  A reaction of high-temperature solid-phase catalytic isotope exchange (HSCIE) was studied for the preparation of tritium- and deuterium-labeled ligands of glutamate and dopamine receptors. Tritium-labeled (5S,10R)-(+)-5-methyl-10,11-dihydro-⁵H-dibenzo[a,d]cyclopenten-5,1-imine ([G-³H]MK-801) and R(+)-7-hydroxy-N,N-di-n-propyl-2-aminotetraline ([G-³H]-7-OH-DPAT) were obtained with a specific activity of 210 and 120 Ci/mol, respectively. The isotopomeric distribution of deuterium-labeled ligands was studied using time-of-flight mass-spectrometer MX 5310 (ESI-o-TOF) with electrospray and orthogonal ion injection. Mean deuterium incorporation per ligand molecule was 11.09 and 3.21 atoms for [G-³H]MK-801 and [G-³H]-7-OH-DPAT, respectively. The isotope label was shown to be distributed all over the ligand molecule. The radioreceptor binding of tritium-labeled ligands [G-³H]MK-801 and [G-³H]-7-OH-DPAT was analyzed using the brain structure of Vistar rats. It was demonstrated that [G-³H]MK-801 specifically binds to hippocampus membranes with K _d 8.3 ± 1.4 nM, B _max being 3345 ± 300 fmol/mg protein. The [G-³H]-7-OH-DPAT ligand specifically binds to rat striatum membranes with K _d 10.01 ± 0.91 nM and B _max 125 ± 4.5 fmol/mg protein. It was concluded that the HSCIE reaction can be used for the preparation of highly tritium-labeled (+)-MK-801 and 7-OH-DPAT with retention of their physiological activities. Original Russian Text ? Yu.A. Zolotarev, Yu.Yu. Firsova, A. Abaimov, A.K. Dadayan, V.S. Kosik, A. V. Novikov, N.V. Krasnov, B. V. Vaskovskii, I.V. Nazimov, G.I. Kovalev, N.F. Myasoedov, 2009, published in Bioorganicheskaya Khimiya, 2009, Vol. 35, No. 3, pp. 323–333.     

Proof of a disulfide bridge accessible to disulfide exchange between the heavy chains of IgG

The paper deals with the direct experimental proof that human immunoglobulin G1 (IgG1) contains a reactive disulfide bond that can be opened by 3,3'-dithiobis(6-nitrobenzoate) (DTNB) within 24 h by a SH-catalysed disulfide exchange reaction. These results were obtained with the purified IgG1 myeloma protein and confirm earlier indirect evidence based on correlation analysis of DTNB reactivity and quantitative IgG1 determination. The reactive disulfide bond is most likely the one between Cys235 of the heavy chains in the "hinge"-region, activated for the disulfide exchange by the protonated amino groups of Lys231 as turned out by analysis of IgG1. As with the whole molecule, one mol of reactive disulfide was found per mol of the Fc-fragment. 0.8 mol of labile S-S bonds was detected per mol of F(ab)2. After separation of the excess of reagent, the sedimentation pattern still corresponded with the dimer. The unaltered antigenic properties as well as the crystallizability speak against any severe conformational changes. Therefrom it was concluded that in approximately 80% of the F(ab)2 molecules one of the two inter heavy chain-bridges was opened. With the isolated F(ab)-fragment a reaction with DTNB was ascertained to an extent of 20%, which is probably due to an altered stability of the heavy-light chain-SS-bridge. However, no influence on the sedimentation pattern was observed. The intrachainar disulfide bonds of neither the heavy nor the light chain reacted with DTNB to a measurable extent.