Covalent Labeling/Mass Spectrometry of Monoclonal Antibodies with Diethylpyrocarbonate: Reaction Kinetics for Ensuring Protein Structural Integrity.

Diethylpyrocarbonate (DEPC)-based covalent labeling together with mass spectrometry is a promising tool for the higher-order structural analysis of antibody therapeutics. Reliable information about antibody higher-order structure can be obtained, though, only when the protein's structural integrity is preserved during labeling. In this work, we have evaluated the applicability of DEPC reaction kinetics for ensuring the structural integrity of monoclonal antibodies (mAbs) during labeling. By monitoring the modification extent of selected proteolytic fragments as a function of DEPC concentration, we find that a common DEPC concentration can be used for different monoclonal antibodies in formulated samples without perturbing their higher-order structure. Under these labeling conditions, we find that the antibodies can accommodate up to four DEPC modifications without being structurally perturbed, indicating that multidomain proteins can withstand more than one label, which contrasts to previously studied single-domain proteins. This more extensive labeling provides a more sensitive measure of structure, making DEPC-based covalent labeling-mass spectrometry suitable for the higher-order structural analyses of mAbs.

DEPC modification of the CuA protein from Thermus thermophilus.

The CuA center is the initial electron acceptor in cytochrome c oxidase, and it consists of two copper ions bridged by two cysteines and ligated by two histidines, a methionine, and a carbonyl in the peptide backbone of a nearby glutamine. The two ligating histidines are of particular interest as they may influence the electronic and redox properties of the metal center. To test for the presence of reactive ligating histidines, a portion of cytochrome c oxidase from the bacteria Thermus thermophilus that contains the CuA site (the TtCuA protein) was treated with the chemical modifier diethyl pyrocarbonate (DEPC) and the reaction followed through UV-visible, circular dichroism, and electron paramagnetic resonance spectroscopies at pH 5.0-9.0. A mutant protein (H40A/H117A) with the non-ligating histidines removed was similarly tested. Introduction of an electron-withdrawing DEPC-modification onto the ligating histidine 157 of TtCuA increased the reduction potential by over 70 mV, as assessed by cyclic voltammetry. Results from both proteins indicate that DEPC reacts with one of the two ligating histidines, modification of a ligating histidine raises the reduction potential of the CuA site, and formation of the DEPC adduct is reversible at room temperature. The existence of the reactive ligating histidine suggests that this residue may play a role in modulating the electronic and redox properties of TtCuA through kinetically-controlled proton exchange with the solvent. Lack of reactivity by the metalloproteins Sco and azurin, both of which contain a mononuclear copper center, indicate that reactivity toward DEPC is not a characteristic of all ligating histidines.

Alkyl-substituted phenylamino derivatives of 7-nitrobenz-2-oxa-1,3-diazole as uncouplers of oxidative phosphorylation and antibacterial agents: involvement of membrane proteins in the uncoupling action.

In search for new effective uncouplers of oxidative phosphorylation, we studied 4-aryl amino derivatives of a fluorescent group 7-nitrobenz-2-oxa-1,3-diazol (NBD). In our recent work (Denisov et al., Bioelectrochemistry, 2014), NBD-conjugated alkyl amines (NBD-Cn) were shown to exhibit uncoupling activity. It was concluded that despite a pKa value being about 10, the expected hindering of the uncoupling activity could be overcome by insertion of an alkyl chain. There is evidence in the literature that the introduction of an aryl substituent in the 4-amino NBD group shifts the pKa to neutral values. Here we report the data on the properties of a number of 4-arylamino derivatives of NBD, namely, alkylphenyl-amino-NBD (Cn-phenyl-NBD) with varying alkyl chain Cn. By measuring the electrical current across planar bilayer lipid membrane, the protonophoric activity of Cn-phenyl-NBD at neutral pH grew monotonously from C1- to C6-phenyl-NBD. All of these compounds increased the respiration rate and reduced the membrane potential of isolated rat liver mitochondria. Importantly, the uncoupling action of C6- and C4-phenyl-NBD was partially reversed by glutamate, diethyl pyrocarbonate (DEPC), 6-ketocholestanol, and carboxyatractyloside, thus pointing to the involvement of membrane proteins in the uncoupling activity of Cn-phenyl-NBD in mitochondria. The pronounced recoupling effect of DEPC, an inhibitor of an aspartate-glutamate carrier (AGC), and that of its substrates for the first time highlighted AGC participation in the action of potent uncouplers on mitochondria. C6-phenyl-NBD produced strong antimicrobial effect on Bacillus subtilis, which manifested itself in cell membrane depolarization and suppression of bacterial growth at submicromolar concentrations.

Effects of reduced levels of sulfite in wine production using mixtures with lysozyme and dimethyl dicarbonate on levels of volatile and biogenic amines.

Sulphur dioxide (SO2) is an important preservative for wine, but its presence in foods can cause allergies and this has given impetus to the research for alternatives. The aim of this study was to reduce levels of sulfite in wine production using mixtures with lysozyme and dimethyl dicarbonate and examine the influence on levels of volatile and biogenic amines. To do so, vinifications were carried out using lysozyme, dimethyl dicarbonate (DMDC) and mixtures of these with SO2 in different concentrations (25 and 50 mg l-1). Results were compared with a control vinification with only SO2 (50 mg l-1). Mixing low concentrations of SO2 with lysozyme and DMDC reduced the concentration of biogenic amines (histamine, tyramine, putrescine, cadaverine, phenylethylamine + spermidine and spermine). In general, the total concentration of volatile amines (dimethylamine, isopropylamine, isobutylamine, pyrrolidine, ethylamine, diethylamine, amylamine and hexylamine) was higher in the sample fermented only with SO2. The concentrations of amines with secondary amino groups (dimethylamine, diethylamine, pyrrolidine) were higher in the sample only fermented with SO2 than those fermented with DMDC and lysozyme or with a mixture of preservatives. When SO2 was the only preservative in wine, total amine concentration (biogenic and volatile amines) was higher than for the rest of the treatments. Lysozyme by itself, and lysozyme mixed with SO2, both reduced the formation of biogenic amines but given the antioxidant activity of SO2 the use of the preservative mixture seems more advisable.

Diethylpyrocarbonate modification reveals HisB5 as an important modulator of insulin amyloid formation.

More than 30 amyloid proteins are reported to be associated with amyloidosis diseases. Studies have implicated histidine may be critically involved in amyloid formation. Here, we used diethylpyrocarbonate (DEPC) modification to obtain a His(B5) mono-ethyloxyformylated insulin (DMI-B(5)). The secondary structure, amyloidogenicity, metal ion interaction, and cytotoxicity of DMI-B(5) and insulin were compared. DMI-B(5) was less prone to aggregation in acidic condition but easier to aggregate at neutral pH. DEPC modification resulted in attenuated inhibitory effect of Zn(2+) on aggregation, whereas DMI-B(5) fibrils induced more severe erythrocytes haemolysis compared to insulin fibrils. This study not only provides a fast new approach for studying the impact of imidazole ring in amyloid formation, but also reveals the critical modulating role of histidine imidazole ring on the amyloidogenicity of insulin.

The reduction rates of DEPC-modified mutant Thermus thermophilus Rieske proteins differ when there is a negative charge proximal to the cluster.

Rieske and Rieske-type proteins are electron transport proteins involved in key biological processes such as respiration, photosynthesis, and detoxification. They have a [2Fe-2S] cluster ligated by two cysteines and two histidines. A series of mutations, L135E, L135R, L135A, and Y158F, of the Rieske protein from Thermus thermophilus has been produced which probe the effects of the neighboring residues, in the second sphere, on the dynamics of cluster reduction and the reactivity of the ligating histidines. These properties were probed using titrations and modifications with diethyl pyrocarbonate (DEPC) at various pH values monitored using UV-Visible and circular dichroism spectrophotometry. These results, along with results from EPR studies, provide information on ligating histidine modification and rate of reduction of each of the mutant proteins. L135R, L135A, and Y158F react with DEPC similarly to wild type, resulting in modified protein with a reduced [2Fe-2S] cluster in <90 min, whereas L135E requires >15 h under the same conditions. Thus, the negative charge slows down the rate of reduction and provides an explanation as to why negatively charged residues are rarely, if ever, found in the equivalent position of other Rieske and Rieske-type proteins.

Detection of platypus-type L/D-peptide isomerase activity in aqueous extracts of papaya fruit.

Peptide isomerase catalyses the post-translational isomerisation of the L: - to the D: -form of an amino acid residue around the N/C-termini of substrate peptides. To date, some peptide isomerases have been found in a limited number of animal secretions and cells. We show here that papaya extracts have weak peptide isomerase activity. The activity was detected in each 30-100 kDa fraction of the flesh and the seed extracts of unripe and ripe papaya fruit. The definitive activity was confirmed in the ripe papaya extracts, but even then it was much less active than that of the other peptide isomerases previously reported. The activity was markedly inhibited by methanol, and partly so by amastatin and diethyl pyrocarbonate. This is the first report of peptide isomerase activity in a plant and suggests that perhaps every living organism may have some peptide isomerase activity.

Studies of histidine residues in soybean (Glycine max) urease.

Soybean urease has been investigated extensively to reveal the presence of histidine residue (s) in the active site and their potential role in the catalysis. The spectrophotometric studies using diethylpyrocarbonate (DEP) showed the modification of 11.76 ± 0.1 histidine residues per mole of native urease. Therefore, the results are indicative of the presence of twelve histidine residues per urease molecule. It is presumed that the soybean urease, being a hexameric protein possess two histidine residues per subunit. Correlation plot showed that the complete inactivation of soybean urease corresponds to the modification of 1.97 histidine residues per subunit. Further, double logarithmic plot of kapp versus DEP concentration has resulted in a linear correlation and thereby demonstrating that only one of the two histidine residues per subunit is catalytically essential. Significant protection has been observed against inactivation when urea or acetohydroxamate (AHA) is incubated with DEP treated urease. The studies have demonstrated the presence of one histidine residue at the active site of soybean urease and its significance in catalysis.

Enzymatic synthesis of fatty acid ethyl esters by utilizing camellia oil soapstocks and diethyl carbonate.

This study was reported on a novel process for fatty acid ethyl esters preparation by transesterification and esterification from renewable low-cost feedstock camellia oil soapstocks and friendly acyl acceptor diethyl carbonate. The main components of product were 83.9% ethyl oleate, 8.9% ethyl palmitate, 4.7% ethyl linoleate and 2.1% ethyl stearate, which could be used as eco-friendly renewable resources or additives of industrial solvent and fossil fuel. The effects of molar ratio of diethyl carbonate to soapstocks oil, lipases, organic solvent, reaction temperature and time were investigated, and process conditions were optimized. The yield was up to 98.4% in solvent-free system with molar ratio of diethyl carbonate to soapstocks oil 3:1 and 5% Novozym 435 (based on the weight of soapstocks oil) at 50 °C and 180 rpm for 24 h. Moreover, there was no obvious loss in the yield after lipases were reused for 10 batches without treatment under optimized conditions.

[Identification of catalytically active groups of pea (Pisum sativum L.) beta-glucosidase].

Functional groups ofcytoplasmic pea beta-glucosidase pretreated to an electrophoretically homogeneous state were identified. Data on the pH dependence of the enzyme activity, calculated heat of ionization, photoinactivation of the enzyme in the presence of methylene blue, and inactivation of the enzyme with diethyl pyrocarbonate suggest that the catalytic site of beta-glucosidase contains the carboxyl group of glutamic or aspartic acids and the imidazole group of histidine.

Working with RNA.

Working with RNA is not a special discipline in molecular biology. However, RNA is chemically and structurally different from DNA and a few simple work rules have to be implemented to maintain the integrity of the RNA. Alkaline pH, high temperatures, and heavy metal ions should be avoided when possible and ribonucleases kept in check. The chapter outlines the specific precautions recommended for work with RNA and describes some of the modifications to standard protocols in molecular biology that are relevant to RNA work. The methods are applicable to all types of RNA and require a minimum of specialized equipment.

Inhibition of electron acceptance from ascorbate by the specific N-carbethoxylations of maize cytochrome b561: a common mechanism for the transmembrane electron transfer in cytochrome b561 protein family.

Cytochromes b(561) constitute a novel class of proteins in eukaryotic cells with a number of highly relevant common features including six transmembrane alpha-helices and two haem groups. Of particular interest is the presence of a large number of plant homologues having putative ascorbate- and monodehydroascorbate radical-binding sites. We conducted a diethylpyrocarbonate-modification study employing Zea mays cytochrome b(561) heterologously expressed in Pichia pastoris cells. Pre-treatment of cytochrome b(561) with diethylpyrocarbonate in oxidized form caused N-carbethoxylation of His(86), His(159) and Lys(83), leading to a drastic inhibition of the electron transfer from ascorbate. The activity was protected by the inclusion of ascorbate during the treatment. However, midpoint potentials of two haem centres did show only slight decreases upon the treatment, suggesting that changes in the midpoint potentials were not the major cause of the inhibition. Present results indicated that Zea mays cytochrome b(561) conducted an ascorbate-specific transmembrane electron transfer by utilizing a concerted H(+)/e(-) transfer mechanism and that the specific N-carbethoxylation of haem axial His(86) that would inhibit the removal of a proton from the bound ascorbate was a major cause of the inhibition. On the other hand, Lys(83) might be important for an initial step(s) of the fast electron acceptance from ascorbate.

The role of the histidine-35 residue in the cytocidal action of HM-1 killer toxin.

Diethylpyrocarbonate modification and site-directed mutagenesis studies of histidine-35 in HM-1 killer toxin (HM-1) have shown that a specific feature, the imidazole side chain of histidine-35, is essential for the expression of the killing activity. In subcellular localization experiments, wild-type HM-1 was in the membrane fraction of Saccharomyces cerevisiae BJ1824, but not the HM-1 analogue in which histidine-35 was replaced by alanine (H35A HM-1). Neither wild-type nor H35A HM-1 was detected in cellular fractions of HM-1-resistant yeast S. cerevisiae BJ1824 rhk1Delta : : URA3 and HM-1-insensitive yeast Candida albicans even after 1 h incubation. H35A HM-1 inhibited the activity of partially purified 1,3-beta-glucan synthase from S. cerevisiae A451, and its extent was almost the same as wild-type HM-1. Co-immunoprecipitation experiments showed that wild-type and H35A HM-1 directly interact with the 1,3-beta-glucan synthase complex. These results strongly suggest that histidine-35 has an important role in the cytocidal action of HM-1 that participates in the binding process to the HM-1 receptor protein on the cell membrane, but it is not essential for the interaction with, and inhibition of, 1,3-beta-glucan synthase.

Functional contribution of a conserved, mobile loop histidine of phosphoribulokinase.

In the Rhodobacter sphaeroides phosphoribulokinase (PRK) structure, there are several disordered regions, including a loop containing invariant residues Y98 and H100. The functional importance of these residues has been unclear. PRK is inactivated by diethyl pyrocarbonate (DEPC) and protected by the substrates ATP and Ru5P, as well as by the competitive inhibitor, 6-phosphogluconate, suggesting active site histidine residue(s). PRK contains only three invariant histidines: H45, H100, and H134. Previous mutagenesis studies discount significant function for H134, but implicate H45 in Ru5P binding. PRK mutant H45N is inactivated by DEPC, implicating a second active site histidine. To evaluate the function of H100, as well as another invariant loop residue Y98, PRK mutants Y98L, H100A, H100N, and H100Q were characterized. Mutant PRK binding stoichiometries for the fluorescent alternative substrate, trinitrophenyl-ATP, as well as the allosteric activator, NADH, are comparable to wild-type PRK values, suggesting intact effector and substrate binding sites. The K(mRu5P) for the H100 mutants shows modest eight- to 14-fold inflation effects, whereas Y98L exhibits a 40-fold inflation for K(mRu5P). However, Y98L's K(i) for the competitive inhibitor 6-phosphogluconate is close to that of wild-type PRK. These observations suggest that Y98 and H100 are not essential Ru5P binding determinants. The Vm of Y98L is diminished 27-fold compared with wild-type PRK. In contrast, H100A, H100N, and H100Q exhibit significant decreases in Vm of 2600-, 2300-, and 735-fold, respectively. Results suggest that the mobile region containing Y98 and H100 must contribute to PRK's active site. Moreover, H100's imidazole significantly influences catalytic efficiency.

Kinetic comparison of procaspase-3 and caspase-3.

Caspases, the key enzymes in apoptosis, are synthesized as proenzymes and converted into active form by proteolytic cleavage. The residues on active site reorganize during the activation process as shown in the comparative studies of crystallographic structures of procaspase-7 and its mature form. On the other hand, the proenzyme itself has some activity. Aiming to characterize the activation process, the comparative kinetic study for the pro- and mature caspase-3 was performed. In 1/K(M) versus pH study, a residue with pKa of 6.89+/-0.13 was detected only in caspase-3. While Vmax versus pH kinetic results were consistent with the existence of a residue with pKa of 6.21+/-0.06 in procaspase-3 mutant (D9A/D28A/D175A) but not in caspase-3. In the inactivation assays with diethylpyrocarbonate, a residue (pKa, 6.61+/-0.05) could be determined only for caspase-3 whereas with iodoacetamide a residue with pKa value (6.01+/-0.05) could be assigned only for procaspase-3. Considering that those residues could be protected by caspase-3-specific inhibitor from the inactivation, the modifiers are histidine- and cysteine-specific, respectively, and the involvement of these residues in the characteristic catalytic dyad of caspases, the results indicate that the pKa values of the catalytic histidine and cysteine residues are changed during the activation process.

Histidine-834 of human erythrocyte band 3 has an essential role in the conformational changes that occur during the band 3-mediated anion exchange.

We have shown that diethyl pyrocarbonate (DEPC) inhibits band 3-mediated anion exchange and that the inhibition occurs only when histidine residue(s) is (are) modified with DEPC from the cytosolic surface of resealed ghosts [Izuhara et al. (1989) Biochemistry 28, 4725-4728]. In the present study, we have identified the DEPC-modified histidine residue as His834 using liquid chromatography with electrospray ionization mass spectrometry (LC/ESI-MS). This mild, rapid, sensitive, and quantitative method was successfully applied to analysis of the unstable DEPC-histidine adduct. The DEPC modification of His834 was pH dependent and 4,4'-dinitrostilbene-2,2'-disulfonic acid (DNDS) sensitive as previously shown. After DEPC modification, band 3-mediated anion exchange is inhibited. Consistent with previous results, we confirmed that His834 was located on the cytosolic side of the membrane and the DEPC modification of His834 had allosteric effects on the extracellular DNDS-binding site of band 3. Therefore, we conclude that His834 is located at the cytosolic surface of band 3 and is an essential residue for band 3-mediated anion exchange. We will discuss important roles of the region from TM12 to TM14 in the conformational changes that occur during the band 3-mediated anion exchange.

Diethylpyrocarbonate inhibition of vacuolar H+-pyrophosphatase possibly involves a histidine residue.

Vacuolar proton pumping pyrophosphatase (H+-PPase; EC 3.6.1.1) plays a pivotal role in electrogenic translocation of protons from cytosol to the vacuolar lumen at the expense of PPi hydrolysis. A histidine-specific modifier, diethylpyrocarbonate (DEPC), could substantially inhibit enzymic activity and H+-translocation of vacuolar H+-PPase in a concentration-dependent manner. Absorbance of vacuolar H+-PPase at 240 nm was increased upon incubation with DEPC, demonstrating that an N-carbethoxyhistidine moiety was probably formed. On the other hand, hydroxylamine, a reagent that can deacylate N-carbethoxyhistidine, could reverse the absorption change at 240 nm and partially restore PPi hydrolysis activity as well. The pKa of modified residues of the enzyme was determined to be 6.4, a value close to that of histidine. Thus, we speculate that inhibition of vacuolar H+-PPase by DEPC possibly could be attributed to the modification of histidyl residues on the enzyme. Furthermore, inhibition of vacuolar H+-PPase by DEPC follows pseudo-first-order rate kinetics. A reaction order of 0.85 was calculated from a double logarithmic plot of the apparent reaction constant against DEPC concentration, suggesting that the modification of one single histidine residue on the enzyme suffices to inhibit vacuolar H+-PPase. Inhibition of vacuolar H+-PPase by DEPC changes Vmax but not Km values. Moreover, DEPC inhibition of vacuolar H+-PPase could be substantially protected against by its physiological substrate, Mg2+-PPi. These results indicated that DEPC specifically competes with the substrate at the active site and the DEPC-labeled histidine residue might locate in or near the catalytic domain of the enzyme. Besides, pretreatment of the enzyme with N-ethylmaleimide decreased the degree of subsequent labeling of H+-PPase by DEPC. Taken together, we suggest that vacuolar H+-PPase likely contains a substrate-protectable histidine residue contributing to the inhibition of its activity by DEPC, and this histidine residue may located in a domain sensitive to the modification of Cys-629 by NEM.

Mapping Cu(II) binding sites in prion proteins by diethyl pyrocarbonate modification and matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass spectrometric footprinting.

Although Cu(II) ions bind to the prion protein (PrP), there have been conflicting findings concerning the number and location of binding sites. We have combined diethyl pyrocarbonate (DEPC)-mediated carbethoxylation, protease digestion, and mass spectrometric analysis of apo-PrP and copper-coordinated mouse PrP23-231 to "footprint" histidine-dependent Cu(II) coordination sites within this molecule. At pH 7.4 Cu(II) protected five histidine residues from DEPC modification. No protection was afforded by Ca(II), Mn(II), or Mg(II) ions, and only one or two residues were protected by Zn(II) or Ni(II) ions. Post-source decay mapping of DEPC-modified histidines pinpointed residues 60, 68, 76, and 84 within the four PHGGG/SWGQ octarepeat units and residue 95 within the related sequence GGGTHNQ. Besides defining a copper site within the protease-resistant core of PrP, our findings suggest application of DEPC footprinting methodologies to probe copper occupancy and pathogenesis-associated conformational changes in PrP purified from tissue samples.

An essential histidine residue in GTP binding domain of bovine brain glutamate dehydrogenase isoproteins.

Greater than 90% of the original activity of the enzymes remained after modification of histidine residues of glutamate dehydrogenase (GDH) isoproteins from bovine brains with diethyl pyrocarbonate (DEPC). This suggests that the DEPC modified histidine residues are not critically involved in the catalysis of the GDH isoproteins. The influence of DEPC modified histidine residue(s) on binding of GTP to GDH isoproteins was investigated by protection studies. These studies showed that inhibition of GDH isoproteins by GTP was protected by preincubation of GDH isoproteins with DEPC. The amount of protection was dependent on the concentration of DEPC. The GTP inhibition was fully protected by preincubation of GDH isoproteins with DEPC at saturating concentrations. These results indicate that the histidine residues may play an important role in the GTP binding on GDH isoproteins. Spectrophotometric studies showed that three histidine residues per enzyme subunit were able to react with DEPC in the absence of GTP, whereas two histidine residues per enzyme subunit interacted with DEPC when the enzymes were preincubated with GTP. These results indicate that one of the histidine residues is involved in the GTP binding domain of GDH isoproteins. The quantitative affinity chromatographic studies showed that the influence of GTP on the binding of GDH isoproteins to DEPC-Sepharose was significantly distinct for the two GDH isoproteins. GDH I was more sensitively affected by GTP than GDH II in the binding affinity for DEPC-Sepharose. ADP, another well-known allosteric regulator, showed no significant changes in the interaction of DEPC with GDH isoproteins.

Functional residues on the enzyme active site of glyoxalase I from bovine brain.

Bovine brain glyoxalase I was investigated in order to identify amino acid residues essential for its catalytic activity. This enzyme is a 44-kDa dimeric protein which exhibits a characteristic intrinsic fluorescence, with an emission peak centered at 342 nm. The total of eight tryptophan residues/molecule was estimated by using a fluorescence titration method. Low values of Stern Volmer quenching constants for the quenchers used indicated that the tryptophan residues are relatively buried in the native molecule. Similar results were obtained for glyoxalase I, purified from yeast and human erythrocytes. The activity of bovine brain glyoxalase I was found to be particularly sensitive to 2,3-butanedione and diethylpyrocarbonate, selective reagents for arginine and histidine residues, respectively. A minor effect was observed by treatment of the enzyme with other amino acid-specific reagents. A protective effect of the competitive inhibitor S-hexylglutathione was observed for all reagents used, indicating the presence of modified amino acids in or near the enzyme active site.