The use of azidoarylimidoesters in RNA-protein cross-linking studies with Escherichia coli ribosomes

A series of related hetero-bifunctional RNA-protein cross-linking reagents has been prepared, carrying an imidoester or N-hydroxysuccinimide ester function at one end of the molecule, and a phenylazido function at the other. These compounds have been applied to RNA-protein cross-linking studies with ribosomal subunits, and one of them, p-azido-phenylacetic imidoester, has proved to be a particularly useful reagent for this purpose. The reagent first reacts specifically with protein amino groups, and subsequent photolysis of the azide group leads to cross-linking to the RNA in yields of up to 8% of the total protein. The whole reaction takes place under very mild conditions in aqueous solution.The individual proteins concerned in the cross-links have been identified by two-dimensional gel electrophoresis, and the existence of a covalent cross-link was confirmed by the isolation by two different methods of protein-oligonucleotide complexes carrying a ³²P label. Although most of the ribosomal proteins could be cross-linked to their corresponding ribosomal RNA within the individual subunits, RNA-protein cross-links at the ribosomal subunit interface were only detectable in vanishingly small amounts.The advantages of this type of genuine hetero-bifunctional reagent in RNA-protein cross-linking studies are discussed.     

Identification of a base-specific contact between the restriction endonuclease SsoII and its recognition sequence by photocross-linking

A target sequence-specific DNA binding region of the restriction endonuclease SsoII was identified by photocross-linking with an oligodeoxynucleotide duplex which was substituted with 5-iododeoxyuridine (5-IdU) at the central position of the SsoII recognition site (CCNGG). For this purpose the SsoII–DNA complex was irradiated with a helium/cadmium laser (325 nm). The cross-linking yield obtained was ~50%. In the presence of excess unmodified oligodeoxynucleotide or with oligodeoxynucleotides substituted with 5-IdU elsewhere, no cross-linking was observed, indicating the specificity of the cross-linking reaction. The cross-linked SsoII-oligodeoxynucleotide complex was digested with chymotrypsin, a cross-linked peptide–oligodeoxynucleotide complex isolated and the site of cross-linking identified by Edman sequencing to be Trp61. In line with this identification is the finding that the W61A variant cannot be cross-linked with the IdU-substituted oligodeoxynucleotide, shows a decrease in affinity towards DNA and is inactive in cleavage. It is concluded that the region around Trp61 is involved in specific binding of SsoII to its DNA substrate.     

Reaction of tryptophanyl-tRNA synthetase from beef pancreas with periodate-oxidized ATP

Tryptophanyl-tRNA synthetase from beef pancreas reacts with periodate-oxidized ATP according to biphasic kinetics. A rapid phase involves two groups of the protein, presumably lysine side-chains. The slow phase corresponds to the reaction of a larger number of groups. The time-course of the partial losses of the ATP-PPi isotopic exchange and of the aminoacylation activities of the enzyme follow the labelling of the two fast-reacting groups. However, the ability of the enzyme to form a bis(tryptophanyladenylate)-enzyme complex is not lost after reaction of these two groups with the reagent. The affinity for ATP is also unaffected by this initial labelling of the protein, as seen from the Km values of this substrate in the ATP-PPi isotopic exchange reaction. These data suggest that, in this fast initial reaction, oxidized ATP reacts neither with specific ATP-binding groups of the enzyme nor with any major catalytic residue of the tryptophan-activation site. In contrast with this first step, the further slow labelling of lysine residues leads to a disappearance of the aminoacylation ability of the enzyme, while it does not further affect the ATP-PPi exchange activity. The behaviour of beef tryptophanyl-tRNA synthetase during derivatization with oxidized ATP is therefore at variance with that which has been described for the homologous E. coli enzyme.     

The effect of (o-phenanthroline)2-cupric sulfate on several properties associated with (N-A+ + K+)-dependent adenosine triphosphatase.

Previous studies have shown that the large polypeptide of purified (Na⁺ + K⁺)-dependent adenosine triphosphatase (NaK ATPase) reacts to form a dimer and other higher oligomeric structures of the enzyme as a result of cross-linking with (o-phenanthroline)₂-cupric sulfate (CP). In the present communication, I show that both NaK ATPase activity and p-nitrophenylphosphatase (NPPase) activity decline rapidly and nearly in parallel when the enzyme is reacted with CP. Similarly, ATP binding is lost with kinetics close to those of ATPase activity and NPPase activity. The loss of ATPase activity, NPPase activity, and ATP binding occurs at a considerably faster rate than cross-linking of the large polypeptide, suggesting that CP may also be forming intrachain disulfide bonds. The binding of ouabain to NaK ATPase is also altered as a result of reacting the enzyme with CP. In marked contrast to ATP binding, however, ouabain binding is lost at a slower rate which closely parallels the rate of reaction of the large polypeptide to form cross-linked oligomeric structures.     

Chemical Cross-linking of Neighboring Thylakoid Membrane Polypeptides

Cross-linking between protein components of whole spinach (Spinacia oleracea var. Nobel) thylakoids and of photosystem I- and II-enriched thylakoid fractions has been produced by reaction with the bifunctional imidoester dimethyl-3,3′-dithiobispropionimidate dihydrochloride as well as by the oxidation of intrinsic sulfydryl groups with an orthophenanthrolinecupric ion complex. The mixture of membrane proteins and their cross-linked products has been analyzed by two-dimensional sodium dodecyl sulfate electrophoresis, with a reductive cleavage step of the cross-linkages before the second dimension. Cross-linked aggregates up to a molecular weight of about 130 kilodaltons (kD) were analyzed, and it was inferred that the polypeptides appearing together in the same aggregates were neighbors within the membrane.

In thylakoids as well as in isolated photosystem fractions, oligomers were formed by cross-linking polypeptides of the 60 to 90 kD range, among them the polypeptides of the chlorophyll-protein complex I. Polypeptides of 46, 19, and 12 kD were cross-linked to these complexes. Polypeptides of 25 and 22 kD, which are related to the chlorophyll-protein complex II, were cross-linked in thylakoids as well as in photosystem II fractions, suggesting that in the membrane these molecules are close together. In photosystem II fractions an oligomer having a molecular weight of about 60 kD was formed by cross-linking several polypeptides of different molecular weights: 40, 25, and 22 kD.

Our cross-linking experiments show that protein interactions in the thylakoid membrane occurred mainly among the polypeptides of the two chlorophyll-protein complexes, thus suggesting an oligomeric nature of these apoproteins.

     

Photo-cross-linking of guanine nucleotides to the nucleotide binding site of elongation factor G

Elongation factor G (EF-G) is rapidly inactivated when irradiated at 253.7 nm. The inactivation follows first-order single-hit kinetics with a quantum efficiency of 3.15 × 10^?5 μmol/μE. Inclusion of either GTP or GDP in the irradiation mixture does not alter the kinetics of inactivation, but does result in the covalent attachment of nucleotide to between 10 and 20% of the EF-G. This relatively low percentage of cross-linking is due to the rapid rate of photoinactivation as compared to the slower rate of covalent attachment. If EF-G is reacted before irradiation with N-ethylmaleimide, a modification known to block the nucleotide binding site [Rohrbach and Bodley (1976) J. Biol. Chem.251, 930], essentially no nucleotide can be photo-cross-linked to EF-G. Treatment of the photo-cross-linked GTP-EF-G with Raney nickel led to the liberation of the nucleotide moiety, indicating that the photo-cross-link to EF-G occurred through a sulfur atom. Although the formation of the EF-G nucleotide complex has been shown to be an obligatory first step in the formation of the EF-G nucleotide ribosome complex [Rohrbach and Bodley (1976) Biochemistry15, 4565], the covalent EF-G-nucleotide adduct cannot form a ternary complex with the ribosome. The presence of both nucleotide and ribosomes during irradiation drastically alters the kinetics of inactivation. The inactivation under these conditions follows multiple-hit kinetics with an initial period during which no EF-G activity is lost. Following this lag period, EF-G is inactivated at the same rate at which ribosomes lose their ability to bind EF-G. No nucleotide is cross-linked to EF-G or the ribosome under these conditions.     

A spin label study of lipid oxidation catalyzed by heme proteins

Rapid loss of the electron spin resonance signal from a variety of spin labels is observed when ferricytochrome c or metmyogloblin are combined with lipids. Evidence is presented that this loss of signal can be used as a sensitive method to study lipid oxidation catalyzed by heme proteins. Under aerobic conditions and with lipids which bind the heme protein, the kinetics of the oxidation process as observed by the spin label method are identical to the kinetics previously observed by measurements of oxygen uptake. Use of pre-oxidized lipids under anaerobic conditions indicates that cytochrome c reacts with a product of lipid oxidation. Kinetic studies of the anaerobic reaction indicate that cytochrome c reacts rapidly with lipid oxidation products in membrane areas far larger than the area occupied by cytochrome c, implying rapid transport of reactive species within the membrane interior in directions parallel to the membrane surface. Under anaerobic conditions, reaction of cytochrome c with lipid oxidation products appears to produce a relatively long lived (hours) species located in the hydrophobic portion of the membrane, which is capable of subsequent reaction with lipid-soluble spin labels.     

Characterization of the extended carbohydrate binding site of concanavalin A: Specificity for interaction with the nonreducing termini of α-(1→2)-linked disaccharides

p-Nitrophenyl 2-O-α-d-galactopyranosyl-α-d-mannopyranoside and p-nitrophenyl 2-O-α-d-glucopyranosyl-α-d-mannopyranoside were synthesized and the interactions of these disaccharides with concanavalin A (con A) were characterized. The kinetics of binding of the galactopyranosyl-containing disaccharide to con A were found to be similar to those observed with monosaccharides in that monophasic time dependencies for binding were observed. The glucopyranosyl-containing disaccharide, however, exhibited biphasic time dependencies which were similar to those previously observed for the binding of p-nitrophenyl 2-O-α-d-mannopyranosyl-α-d-mannopyranoside to con A. These results support a model wherein the α-(1→2)-linked disaccharides which exhibit biphasic binding kinetics must be able to bind to con A in two different and mutually exclusive orientations. The ability to bind to con A in two orientations is shared by α-(1→2)-linked disaccharides in which both glycosyl residues can interact separately with the primary glycosyl binding site of con A. According to the model, the initial fast phase of the biphasic reaction reflects binding of the ligand in two orientations so that two complexes are formed in amounts determined by the relative values of the rate constants for formation of each complex. The subsequent slow phase is proposed to reflect a slow equilibration of the less stable complex to the thermodynamically more stable one. In the more stable complex, the glycosyl residue at the reducing end of the disaccharide occupies the primary glycosyl binding site. The added stability of this complex is attributed to extended interactions between con A and groups on the second glycosyl residue. An axial orientation of OH-2 of the second glycopyranosyl residue appears to be the most important determinant for the extended interaction.     

The nature and reactivity of the ‘essential’ thiol in rabbit muscle creatine kinase III (EC 2.7.3.2)

Rabbit muscle creatine kinase III (EC 2.7.3.2) can be reacted with 2-chloromercuri-4-nitrophenol and this results in the incorporation of two moles of mercurial per mole of enzyme subunit in a biphasic reaction. The second-order rate constant for the slow reaction is 475 ± 42 M^?1 s^?1. S-Carboxamidomethyl-creatine kinase reacts with a single mole of mercurial per mole of subunit. The rate constant, 466 ± 57 M^?1 s^?1, is almost identical to that for the slow reaction of the native enzyme. The reaction between 3-carboxy-4-nitrophenylthio-creatine kinase and 2-chloromercuri-4-nitrophenol has a second-order rate constant of 449 ± 56 M^?1 s^?1. The results may be explained if the mercurial reacts very rapidly with that cysteine residue which reacts independently with iodoacetamide or 5,5′-dithiobis(2-nitrobenzoic acid). However, 2-chloromercuri-4-nitrophenol also reacts more slowly with a second cysteine residue. Definition of the essentiality of thiol groups in enzymes by reaction with labile ligands, here represented by organomercurials, clearly must be approached with caution.     

Synthesis and site-directed fluorescence labeling of azido proteins using eukaryotic cell-free orthogonal translation systems

Eukaryotic cell-free systems based on wheat germ and Spodoptera frugiperda insect cells were equipped with an orthogonal amber suppressor tRNA–synthetase pair to synthesize proteins with a site-specifically incorporated p-azido-l-phenylalanine residue in order to provide their chemoselective fluorescence labeling with azide-reactive dyes by Staudinger ligation. The specificity of incorporation and bioorthogonality of labeling within complex reaction mixtures was shown by means of translation and fluorescence detection of two model proteins: β-glucuronidase and erythropoietin. The latter contained the azido amino acid in proximity to a signal peptide for membrane translocation into endogenous microsomal vesicles of the insect cell-based system. The results indicate a stoichiometric incorporation of the azido amino acid at the desired position within the proteins. Moreover, the compatibility of cotranslational protein translocation, including glycosylation and amber suppression-based incorporation of p-azido-l-phenylalanine within a cell-free system, is demonstrated. The presented approach should be particularly useful for providing eukaryotic and membrane-associated proteins for investigation by fluorescence-based techniques.     

Kinetic analysis of site-specific photoaptamer-protein cross-linking

ssDNA oligonucleotides containing bromodeoxyuridine, BrdU-photoaptamers, are rapidly emerging as specific protein capture reagents in protein microarray technologies. A mathematical model for the kinetic analysis of photoaptamer-protein photocross-linking reactions is presented. The model is based on specific aptamer/protein binding followed by laser excitation that can lead to either covalent cross-linking of the photoaptamer and protein in the complex or irreversible photodamage to the aptamer. Two distinct kinetic regimes, (1) frozen and (2) rapid equilibrium, are developed analytically to model binding kinetics between laser pulses. The models are used to characterize the photocross-linking between three photoaptamers and their cognate protein targets; photoaptamers 0650 and 0615 cross-link human basic fibroblast growth factor and 0518 cross-links HIV MN envelope glycoprotein. Data for cross-linking reaction yields as a function of both laser energy dose and target protein concentration are analyzed for affinity constants and cross-link reaction rates. The binding dissociation constants derived from the cross-linking data are in good accord with independent measurements; the rapid equilibrium model appears to produce results more consistent with the experimental observations, although there is significant overlap between the two models for most conditions explored here. The rate of photodamage for 0615 and 0518 is 3.5 and 2.5 times that of the specific cross-link, giving low maximum reaction yields of approximately 20% and approximately 30%, whereas 0650 cross-links with a rate over five times higher than its photodamage rate and has a maximum reaction yield exceeding 80%. Quantum yields for the three systems are estimated from the data; photoaptamer 0650 has a reasonably high quantum yield of approximately 0.2 for protein cross-linking, while 0518 and 0615 have quantum yields of 0.07 and 0.02. The work presented here provides a useful set of metrics that allow for refinement of photoaptamer properties.     

Conformational change in the Bacillus subtilis RNase P holoenzyme–pre-tRNA complex enhances substrate affinity and limits cleavage rate

Ribonuclease P (RNase P) is a ribonucleoprotein complex that catalyzes the 5′ maturation of precursor tRNAs. To investigate the mechanism of substrate recognition in this enzyme, we characterize the thermodynamics and kinetics of Bacillus subtilis pre-tRNA^Asp binding to B. subtilis RNase P holoenzyme using fluorescence techniques. Time courses for fluorescein-labeled pre-tRNA binding to RNase P are biphasic in the presence of both Ca(II) and Mg(II), requiring a minimal two-step association mechanism. In the first step, the apparent bimolecular rate constant for pre-tRNA associating with RNase P has a value that is near the diffusion limit and is independent of the length of the pre-tRNA leader. Following formation of the initial enzyme–substrate complex, a unimolecular step enhances the overall affinity of pre-tRNA by eight- to 300-fold as the length of the leader sequence increases from 2 to 5 nucleotides. This increase in affinity is due to a decrease in the reverse rate constant for the conformational change that correlates with the formation of an optimal leader–protein interaction in the RNase P holoenzyme–pre-tRNA complex. Furthermore, the forward rate constant for the conformational change becomes rate limiting for cleavage under single-turnover conditions at high pH, explaining the origin of the observed apparent pK_a in the RNase P-catalyzed cleavage reaction. These data suggest that a conformational change in the RNase P•pre-tRNA complex is coupled to the interactions between the 5′ leader and P protein and aligns essential functional groups at the cleavage active site to enhance efficient cleavage of pre-tRNA.     

Isomerization of d-glucose with sodium aluminate: Mechanism of the reaction

A mechanism for the isomerization of d-glucose to d-fructose by sodium aluminate is proposed, involving transformation of a β-d-glucopyranose-1,3-aluminate complex into an α-d-fructofuranose-1,3,6-aluminate complex through an enolaluminate complex that inhibits the formation of a d-mannose-aluminate complex. The α-d-fructofuranose-1,3,6-aluminate further reacts to form a d-psicose-aluminate complex in substantial yield. Constant degradation of the 6-carbon sugars occurred during the reaction because of the high pH of the solution. The C₆ sugars were analyzed chromatographically but the degradation products were not identified.     

The kinetics and mechanism of oxidation of reduced spinach ferredoxin by molecular oxygen and its reduced products

Reduced spinach ferredoxin reacts with molecular oxygen in an autocatalytic reaction characterized by a hyperbolic dependence on oxygen concentration. The kinetics of the reaction indicate formation of a reduced ferredoxin-oxygen intermediate complex and production of superoxide anion which may also react with reduced ferredoxin. Hydrogen peroxide, which is formed from superoxide, in turn reoxidizes reduced ferredoxin at a rate nearly 10-times faster than that of the comparable reaction with oxygen. The kinetics of reaction of hydrogen peroxide with reduced ferredoxin are biphasic. The substrate dependence of the first phase of the reaction is consistent with a simple one-step equilibrium reaction. The second phase of the reaction could be eliminated by addition of the radical trapper, sodium formate.     

Studies of the primary oxygen intermediate in the reaction of fully reduced cytochrome oxidase.

The formation and disappearance of a photosensitive species during the reaction of reduced cytochrome c oxidase (putatively a3II.O2), EC 1.9.3.1, has been followed by (a) mixing a3II.CO with O2 in a stopped flow apparatus; (b) initiating the oxygen-oxidase reaction by removing CO with a laser flash; (c) probing the reaction mixture for photosensitivity with a second laser flash. Photosensitivity appears in the reaction mixture after the first laser flash, reaches a maximum after 50-60 microseconds ([O2] greater than 100 microM), and disappears in a further 50-100 microseconds. The kinetics can be represented by the scheme [formula: see text]. In species B, O2 is associated with the protein, possibly CuB, but not with the heme. Species C is the photosensitive a3II.O2 complex, and in D, a3 iron has been oxidized. The formation of species C is responsible for the rapid phase of absorbance change in the oxidase-oxygen reaction. The rate of reaction with oxygen approaches the limit of 35,000 s-1 at high oxygen. Nitric oxide, however, reacts with FeII oxidase with a rate of 1 x 10(8) M-1 s-1, which is accurately maintained up to an observed rate of 10(5) s-1. In flash photolysis experiments, approximately half of the photodissociated nitric oxidase recombines in a biphasic geminate reaction with rates of 1 x 10(8) s-1 and 1 x 10(7) s-1.     

The chronoamperometric determination of homogeneous small molecule-redox protein reaction rates.

An essentially new application of chronoamperometry is presented for the determination of homogeneous second-order rate constants for the reactions between small molecule reductants and redox proteins. The first part of the work is a comparison between stopped-flow kinetics and chronoamperometric kinetics for the reaction of ferrous-EDTA with horse cytochrome c. The reaction was demonstrated to be first order in both ferrous-EDTA and cytochrome c and the effect of ionic strength was also studied. All of the chronoamperometric results compared well with the stopped-flow work which had been done previously. Chronoamperometry was then used to study several other reactions which have not been previously examined, including the reaction of ferrous-diethylenetriamine pentaacetic acid with cytochrome c. The reaction was slower than the ferrous-EDTA reaction but was more sensitive to ionic strength because of the greater charge (?3) on the complex. The second study was the reaction of ferrous-EDTA with Rhodospirillum rubrum cytochrome c₂ as a function of ionic strength. This novel application of chronoamperometry to small molecule-redox protein reactions represent a new and relatively easy alternative to anaerobic stopped-flow kinetics.     

Identification of recombinant AtPYL2, an abscisic acid receptor,in E. coli using a substrate-derived bioactive small molecule,a biotin linker with alkyne and amino groups,and a protein cross-linker

Target protein identification of bioactive small molecules is one of the most important research in forward chemical genetics. The affinity chromatography technique to use a resin bound with a small molecule is often used for identification of a target protein of a bioactive small molecule. Here we report a new method to isolate a protein targeted with a bioactive small molecule using a biotin linker with alkyne and amino groups, protein cross-linker containing disulfide bond, and a bioactive small molecule with an azido group (azido probe). After an azido probe is associated with a target protein, the complex of a target protein and azido probe is covalently bound through the biotin linker by azide-alkyne Huisgen cycloaddition and protein cross-linker containing disulfide bond. This ternary complex is immobilized on an affinity matrix with streptavidin, and then the target protein is selectively eluted with a buffer containing a reducing agent for cleavage of disulfide bonds. This method uses a probe having an azido group, which a small functional group, and has the possibility to be a solution strategy to overcome the hindrance of a functional group introduced into the probe that reduces association a target protein. The effectiveness of the method in this study was shown using linker 1, 3′-azidoabscisic acid 3, and protein cross-linker containing a disulfide bond (DTSSP 5).     

On site heterogeneity in sturgeon muscle GPDH: a kinetic approach

The kinetics and stoichiometry of the reaction of sturgeon muscle glyceraldchyde-3-PO₄-dehydrogenase (GPDH) with the disulfide interchange reagent bis(2,2' dithio-bis(5-nitrobenzoate) (DTNB) has been studied in detail. The native enzyme, a tetramer of covalently identical subunits, reacts relatively rapidly with precisely four equivalents of reagent, although there are three cysteine residues per subunit (12 per tetratner). Reaction of these four cystcines leads to total catalytic inactivation; the extent of inactivation is proportional to the fractional reaction. The rate of reaction is dependent on the extent of bound NAD: reactivity being very much greater at unliganded sites. The reaction with apo-enzyme is fastest, bimolecular and monophasic. Over a wide range of NAD concentration, however, the reaction of enzyme with a large molar excess of reagent is precisely biphasic, and each individual kinetic experiment can be analytically described by two pseudo first-order (NAD concentration-dependent) rate constants and two unequal NAD concentration-insensitive amplitudes. The biphasicity in rate is quantitatively explainable on the basis of a C₂ symmetry for the tetrameric subunits with a tighter binding of NAD at two of the four sites, if high reactivity is exclusively dependent on the absence of bound NAD. The inequality in the two amplitudes, however, requires either a more complex or a more dynamic model. Arguments are presented for the appropriateness of a C₂ symmetry model in which intramolecular transconformational isomerization of tight and loose NAD binding sites is possible. The equilibrium constant for the isomerization is estimable from the macroscopic specific rates and amplitudes. This “flip-over” C₂ symmetry model is apropos to all situations of negative cooperativity in ligand binding to tetramers, as is discussed.     

Evidence for the Existence of Two Essential and Proximal Cysteinyl Residues in NADP-Malic Enzyme from Maize Leaves

Incubation of maize (Zea mays) leaf NADP-malic enzyme with monofunctional and bifunctional N-substituted maleimides results in an irreversible inactivation of the enzyme. Inactivation by the monofunctional reagents, N-ethylmaleimide (NEM) and N-phenylmaleimide, followed pseudo-first-order kinetics. The maximum inactivation rate constant for phenylmaleimide was 10-fold higher than that for NEM, suggesting a possible hydrophobic microenvironment of the residue(s) involved in the modification of the enzyme. In contrast, the inactivation kinetics with the bifunctional maleimides, ortho-, meta-, and para-phenylenebismaleimide, were biphasic, probably due to different reactivities of the groups reacting with the two heads of these bifunctional reagents, with a possible cross-linking of two sulfhydryl groups. The inactivation by mono and bifunctional maleimides was partially prevented by Mg²⁺ and l-malate, and NADP prevented the inactivation almost totally. Determination of the number of reactive sulfhydryl groups of the native enzyme with [³H]NEM in the absence or presence of NADP showed that inactivation occurred concomitantly with the modification of two cysteinyl residues per enzyme monomer. The presence of these two essential residues was confirmed by titration of sulfhydryl groups with [³H]NEM in the enzyme previously modified by o-phenylenebismaleimide in the absence or presence of NADP.     

Kinetics of reduction of the cytochrome C3 from Desulvovibrio vulgaris.

The reduction of cytochrome c₃ from Desulfovibrio vulgaris by dithionite or carboxyl radicals follows biphasic kinetics. The data are consistent with lack of heme to heme electron exchange within a single protein molecule. The kinetics of reduction with hydrated electrons are also reported.