Essential histidine residues in lysolecithin:lysolecithin acetyltransferase from rabbit lung

Both activities of rabbit lung lysolecithin:lysolecithin acyltransferase (EC 3.1.1.5), hydrolysis and transacylation, are inactivated by diethylpyrocarbonate. The reaction follows pseudo-first-order kinetics, and second-order rate constants of 1.17 mM-1min-1 for hydrolysis and 0.56 mM-1 min-1 for transacylation were obtained at pH 6.5 and 37 degrees C. The rate of inactivation is dependent on pH, showing the involvement of a group with a pK of 6.5. The difference spectra showed an increase in absorbance at 242 nm, indicating the modification of histidine residues. The activity lost by diethylpyrocarbonate modification can be partially recovered by hydroxylamine treatment. The statistical analysis of residual fractional activity versus the number of modified histidine residues leads to the conclusion that two histidine residues are essential for the hydrolytic activity, whereas transacylation activity depends on only one essential histidine. The substrate and substrate analogs protected the enzyme against inactivation by diethylpyrocarbonate, suggesting that the essential residues are located at or near the active site of the enzyme.     

Interactions between aspartate animotransferase protomers observed during holoenzyme reconstitution..

Aspartate aminotransferase from pig heart cytosol consists of 2 identical protomers. Car?ymethylation of the easily accessible cysteines 45 and 82 of the holoenzyme produces a modified protein which however is still fully active. If the apoenzyme obtained from the car?ymethylated holoenzyme is subjected to the thiol specific reagent DTNB, another group per protomer can be titrated. There is some evidence that the group modified is the thiol 390 which is titrated in “syncatalytic” conditions, i.e. 2 mM ketoglutarate and 70 mM glutamate. The full reactivation of the car?ymethylated apoenzyme is obtained on binding of one PLP at each active site of the dimer. During the reactivation the number of thiols 390 accessible to DTNB decreases from 2 to 0 when PLP is added. The variation of the number of reactive thiol residues is not linear with coenzyme binding. Apo-holoenzyme car?ymethylated hybrid does not react with DTNB. Thus, a strong interaction between the 2 protomers is demonstrated.     

Modification of uridine phosphorylase from Escherichia coli by diethyl pyrocarbonate. Evidence for a histidine residue in the active site of the enzyme.

Uridine phosphorylase from Escherichia coli is inactivated by diethyl pyrocarbonate at pH 7.1 and 10 degrees C with a second-order rate constant of 840 M-1.min-1. The rate of inactivation increases with pH, suggesting participation of an amino acid residue with pK 6.6. Hydroxylamine added to the inactivated enzyme restores the activity. Three histidine residues per enzyme subunit are modified by diethyl pyrocarbonate. Kinetic and statistical analyses of the residual enzymic activity, as well as the number of modified histidine residues, indicate that, among the three modifiable residues, only one is essential for enzyme activity. The reactivity of this histidine residue exceeded 10-fold the reactivity of the other two residues. Uridine, though at high concentration, protects the enzyme against inactivation and the very reactive histidine residue against modification. Thus it may be concluded that uridine phosphorylase contains only one histidine residue in each of its six subunits that is essential for enzyme activity.     

Reaction of (Na-K)ATPase with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole: evidence for an essential tyrosine at the active site.

The reaction of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole [NBD-Cl] with purified eel electrophax Na+ and K+ stimulated adenosine triphosphatase [(Na-K)ATPase] has been monitored by changes in the (Na-K)ATPase activity, the K+ stimulated p-nitrophenyl phosphatase [PNPase] activity, and the protein ultraviolet absorption spectrum. The NBD-Cl reacts with two tyrosine residues per mol of enzyme (approximately 6-7 nmol/mg of protein), as judged by changes in protein absorption spectra and incorporation of [14C]NBD-Cl. The modified tyrosine groups are located on the Mr = 95 000 polypeptide chain and react at different rates. Only one tyrosine modification is necessary for complete inhibition of (Na-K)ATPase activity, although both must be modified for complete inhibition of PNPase activity. Reversal of these modifications by 2-mercaptoethanol restores 65% of both activities. Na+ increases the rate of tyrosine modification, K+ decreases the rate, and ATP affords the more reactive tyrosine group complete protection. NBD-Cl modification of approximately 6-7 nmol of tyrosine groups/mg of protein results in a large decrease in ATP affinity as judged by equilibrium binding. These results are compared with similar results obtained from NBD-Cl modification of the coupling factors of oxidative phosphorylation and photophosphorylation. A model is presented suggesting an asymmetric arrangement of two 95 000 polypeptide chains with a single tyrosine residue at the ATP site.     

Scanning cysteine accessibility of EmrE, an H+-coupled multidrug transporter from Escherichia coli, reveals a hydrophobic pathway for solutes.

EmrE is a 12-kDa Escherichia coli multidrug transporter that confers resistance to a wide variety of toxic reagents by actively removing them in exchange for hydrogen ions. The three native Cys residues in EmrE are inaccessible to N-ethylmaleimide (NEM) and a series of other sulfhydryls. In addition, each of the three residues can be replaced with Ser without significant loss of activity. A protein without all the three Cys residues (Cys-less) has been generated and shown to be functional. Using this Cys-less protein, we have now generated a series of 48 single Cys replacements throughout the protein. The majority of them (43) show transport activity as judged from the ability of the mutant proteins to confer resistance against toxic compounds and from in vitro analysis of their activity in proteoliposomes. Here we describe the use of these mutants to study the accessibility to NEM, a membrane permeant sulfhydryl reagent. The study has been done systematically so that in one transmembrane segment (TMS2) each single residue was replaced. In each of the other three transmembrane segments, at least four residues covering one turn of the helix were replaced. The results show that although the residues in putative hydrophilic loops readily react with NEM, none of the residues in putative transmembrane domains are accessible to the reagent. The results imply very tight packing of the protein without any continuous aqueous domain. Based on the findings described in this work, we conclude that in EmrE the substrates are translocated through a hydrophobic pathway.     

Modification of arginine and lysine in proteins with 2,4-pentanedione.

Primary amines react with 2,4-pentanedione at pH 6-9 to form enamines, N-alkyl-4-amino-3-penten-2-ones. The latter compounds readily regenerate the primary amine at low pH or on treatment with hydroxylamine. Guanidine and substituted guanidines react with 2,4-pentanedione to form N-substituted 2-amino-4,6-dimethylpyrimidines at a rate which is lower by at least a factor of 20 than the rate of reaction of 2,4-pentanedione with primary amines. Selective modification of lysine and arginine side chains in proteins can readily be achieved with 2,4-pentanedione. Modification of lysine is favored by reaction at pH 7 or for short reaction times at pH 9. Selective modification of arginine is achieved by reaction with 2,4-pentanedione for long times at pH 9, followed by treatment of the protein with hydroxylamine. The extent of modification of lysine and arginine side chains can readily be measured spectrophotometrically. Modification of lysozyme with 2,4-pentanedione at pH 7 results in modification of 3.8 lysine residues and less than 0.4 arginine residue in 24 hr. Modification of lysozyme with 2,4-pentanedione at pH 9 results in modification of 4 lysine residues and 4.5 arginine residues in 100 hr. Treatment of this modified protein with hydroxylamine regenerated the modified lysine residues but caused no change in the modified arginine residues. One arginine residue seems to be essential for the catalytic activity of the enzyme.     

Nonenzymatic biotinylation of a biotin carboxyl carrier protein: unusual reactivity of the physiological target lysine

Enzyme-catalyzed addition of biotin to proteins is highly specific. In any single organism one or a small number of proteins are biotinylated and only a single lysine on each of these proteins is modified. A detailed understanding of the structural basis for the selective biotinylation process has not yet been elucidated. Recently certain mutants of the Escherichia coli biotin protein ligase have been shown to mediate "promiscuous" biotinylation of proteins. It was suggested that the reaction involved diffusion of a reactive activated biotin intermediate, biotinoyl-5'-AMP, with nonspecific proteins. In this work the reactivity of this chemically synthesized intermediate toward the natural target of enzymatic biotinylation, the biotin carboxyl carrier protein, was investigated. The results indicate that the intermediate does, indeed, react with target protein, albeit at a significantly slower rate than the enzyme-catalyzed process. Surprisingly, analysis of the products of nonenzymatic biotinylation indicates that of five lysine residues in the protein only the physiological target side chain is modified. These results indicate that either the environment of this lysine residue or its intrinsic properties render it highly reactive to nonenzymatic biotinylation mediated by biotinoyl-5'-AMP. This reactivity may be important for its selective biotinylation in vivo.     

Chemical modification of sheep-liver 6-phosphogluconate dehydrogenase by diethylpyrocarbonate. Evidence for an essential histidine residue

Sheep liver 6-phosphogluconate dehydrogenase is shown to be inactivated by diethylpyrocarbonate in a biphasic manner at pH 6.0, 25 degrees C. After allowing for the hydrolysis of the reagent, rate constants of 56 M-1 s-1 and 11.0 M-1 s-1 were estimated for the two processes. The complete reactivation of partially inactivated enzyme by neutral hydroxylamine, the elimination of the possibility that modification of cysteine or tyrosine residues are responsible for inactivation, and the magnitudes of the rate constants for inactivation relative to the experimentally determined value for the reaction of diethylpyrocarbonate with N alpha-acetylhistidine (2.2 M-1 s-1), all suggested that enzyme inactivation occurs solely by modification of histidine residues. Comparison of the experimental plot of residual fractional activity versus the number of modified histidine residues per subunit with simulated plots for three hypothetical models, each predicting biphasic kinetics, indicated that inactivation results from the modification of at most one essential histidine residue per subunit, although it appears that other (non-essential) histidines react independently. This histidine is thought to be His-242 and is present in the active site. Evidence in support of its role in catalysis is briefly discussed. Both 6-phosphogluconate and organic phosphate protect against inactivation, and a kinetic analysis of the protection indicated a dissociation constant of 2.1 X 10(-6) M for the enzyme--6-phosphogluconate complex. NADP+ also protected, but this might be due, at least in part, to a reduction in the effective concentration of diethylpyrocarbonate.     

A histidine residue at the active site of avian liver phosphoenolpyruvate carboxykinase

The histidine-selective reagents diethylpyrocarbonate (DEPC) and dimethylpyrocarbonate were used to study active site residues of phosphoenolpyruvate carboxykinase. Both reagents show pseudo first-order inhibition of enzyme activity at 22 +/- 1 degree C with calculated second-order rate constants of 2.8 and 4.6 M-1 s-1, respectively. The inhibition appears partially reversible. Substrates affect the rate of inhibition: KHCO3 enhances the rate, Mn2+ has little effect, and phosphoenolpyruvate decreases the rate. The best protection is obtained by IDP or IDP and Mn2+. The kinetic studies show that modification of histidine is specific and leads to loss of enzymatic activity. Two histidines per enzyme are modified by DEPC, as measured by an absorption change at 240 nm, in the absence of substrate, leading to loss in activity. One histidine per molecule is modified in the presence of KHCO3, giving inactivation. Cysteine and lysine residues are not affected. A study of the inhibition rate constant as a function of pH gives a pKa of 6.7. Enzyme modified by DEPC in the absence of substrate (1% remaining activity) shows no binding of ITP or of phosphoenolpyruvate to the enzyme.Mn2+ complex as studied by proton relaxation rates. When enzyme is modified in the presence of KHCO3 (44% remaining activity), ITP and KHCO3 bind to the enzyme.Mn2+ complex similarly to the binding to native enzyme. Phosphoenolpyruvate binding to modified enzyme.Mn results in an enhancement of proton relaxation rates rather than the decrease observed with native enzyme.Mn. The CD spectra of histidine-modified enzyme show a decrease in alpha-helical and random structure with an increase in anti-parallel beta-sheet structure compared to native enzyme. These results show that avian phosphoenolpyruvate carboxykinase has 2 histidine residues which are reactive with DEPC and dimethylpyrocarbonate, and one of the 15 histidine residues in the protein is at or near the phosphoenolpyruvate binding site and is involved in catalysis.     

Kinetic analysis of the role of lipoic acid residues in the pyruvate dehydrogenase multienzyme complex of Escherichia coli

The catalytic roles of the two reductively acetylatable lipoic acid residues on each lipoate acetyltransferase chain of the pyruvate dehydrogenase complex of Escherichia coli were investigated. Both lipoyl groups are reductively acetylated from pyruvate at the same apparent rate and both can transfer their acetyl groups to CoASH, part-reactions of the overall complex reaction. The complex was treated with N-ethylmaleimide in the presence of pyruvate and the absence of CoASH, conditions that lead to the modification and inactivation of the S-acetyldihydrolipoic acid residues. Modification was found to proceed appreciably faster than the accompanying loss of enzymic activity. The kinetics of the modification were fitted best by supposing that the two lipoyl groups react with the maleimide at different rates, one being modified at approximately 3.5 times the rate of the other. The loss of complex activity took place at a rate approximately equal to that calculated for the modification of the more slowly reacting lipoic acid residue. The simplest interpretation of this result is that only this residue is essential in the overall catalytic mechanism, but an alternative explanation in which one lipoic acid residue can take over the function of another was not ruled out. The kinetics of inactivation could not be reconciled with an obligatory serial interaction between the two lipoic acid residues. Similar experiments with the fluorescent N-[p-(benzimidazol-2-yl)phenyl]maleimide supported these conclusions, although the modification was found to be less specific than with N-ethylmaleimide. The more rapidly modified lipoic acid residue may be involved in the system of intramolecular transacetylation reactions that couple active sites in the lipoate acetyltransferase component.     

Chemical modification of proteins: plotting of the remaining activity against the number of residues modified

In the study of chemical modification of proteins, it has been a common practice to plot the fractional remaining activity against the number of residues modified per protein molecule. Extrapolation of the initial, nearly linear portion of the curve to the axis giving numbers of residues has often been presumed to specify the actual number of critical groups modified, i.e., the stoichiometry of the modification and the inactivation reactions. However, this extrapolation method is not generally applicable (Horiike, K. & McCormick, D.B. (1979) J. Theor. Biol. 79, 403-414). This paper describes further examination of the underlying theoretical framework of the extrapolation method. The properties and features of the extrapolated values are considered and presented with numerical and graphical examples. And the theoretical conditions with which the extrapolated value gives the number of essential residues are derived.     

Structural and functional characteristics of activated human factor IX after chemical modification of gamma-carboxyglutamic acid residues

Activated human factor IX (factor IXa) was treated under mildly acidic conditions with a mixture of formaldehyde and morpholine. This reagent has been shown to react preferentially with gamma-carboxyglutamyl (Gla) residues and to convert these residues to gamma-methyleneglutamyl residues (Wright, S.F., Bourne, C.D., Hoke, R.A., Koehler, K.A., and Hiskey, R.G. (1984) Anal. Biochem. 139, 82-90). The modified enzyme was evaluated for coagulant activity and calcium-dependent fluorescence quenching. [14C]Formaldehyde was employed to allow quantitation of the modification and to facilitate localization of the modified residues in the primary structure of factor IXa. In the presence of the [14C]formaldehyde/morpholine reagent, factor IXa rapidly lost coagulant activity, which corresponded to incorporation of radiolabel. Examination of the relationship between protein modification (radiolabel incorporation) and the loss of coagulant activity suggested that modification of 1 mol of Gla/mol of factor IXa results in complete loss of factor IXa coagulant activity. Primary structure analysis of the radioactivity labeled factor IXa suggested that modification of any one of 11 Gla residues was responsible for the loss of coagulant activity. In the presence of calcium, modified factor IXa exhibited a smaller Gla-dependent decrease in protein fluorescence than native factor IXa, but the Gla-independent fluorescence change was the same for both proteins. It therefore appears that the Gla domain of factor IXa must be completely intact for the enzyme to undergo a functionally important calcium-dependent conformational change necessary for coagulant activity.     

Topographic labelling of pore-forming proteins from the outer membrane of Escherichia coli.

The topography of three pore-forming proteins from the outer membrane of Escherichia coli has been explored by using two labelling techniques. Firstly, the distribution of nucleophilic residues has been investigated by selective chemical modification using arylglyoxals (for arginine residues), isothiocyanates (for lysine residues), carbodi-imides (for carboxy residues) and diazonium salts. Secondly, the membrane-embedded domains have been investigated by labelling with photoactivatable phospholipid analogues and a reagent that partitions into the membrane. Few nucleophilic groups are found to be freely accessible to pore-impermeant probes reacting in the aqueous medium. More groups are accessible to small, pore-permeant probes, suggesting that several groups of each sort are contained within the pore. In addition, there appear to be a number of arginine, lysine, carboxyl and many tyrosine residues that are rather inaccessible and that react only with small, hydrophobic probes, if at all. Amongst these more deeply buried residues there are four arginine residues and an as-yet-undetermined number of carboxy residues that appear to be essential to the structural integrity of the oligomeric molecule.     

The reaction of the histidine residues of luteinizing hormone with ethoxyformyl anhydride.

Bovine and porcine luteinizing hormones (B-LH, P-LH) and their subunits were treated by ethoxyformyl anhydride. The acylation of the histidine residues was followed by examination of the absorbance spectrum. All the histidine residues of the luteinizing hormone molecule can be modified at pH5. However 2 His in B-LH and 1 in P-LH appear to be much less reactive at pH 5 than the others and their acylated imidazols more labile at the same pH. At neutral pH, 2 histidines in B-LH (and 1 in P-LH) become unreactive. In the case of the subunits, 1 histidine becomes unreactive in each subunit at neutral pH. These unreactive histidine residues at neutral pH are probably those which appear to be poorly reactive at pH 5. Comparison of the results obtained with B-LH and P-LH suggests that of the 2 histidine residues present in B-LH and absent in P-LH (beta 60, beta 112), only one exhibits a low reactivity. Acylation of 4 His in B-LH do not cause dissociation into subunits of the molecule but supress 95 per cent of the biological activity.     

Arginine-specific modification of rabbit muscle phosphoglucose isomerase: Differences in the inactivation by phenylglyoxal and butanedione and in the protection by substrate analogs

Rabbit muscle phosphoglucose isomerase was modified with phenylglyoxal or 2,3-butanedione, the reaction with either reagent resulting in loss of enzymatic activity in a biphasic mode. At slightly alkaline pH butanedione was found to be approximately six times as effective as phenylglyoxal. The inactivation process could not be significantly reversed by removal of the modifier. Competitive inhibitors of the enzyme protected partially against loss of enzyme activity by either modification. The only kind of amino acid residue affected was arginine. However, more than one arginine residue per enzyme subunit was found to be susceptible to modification by the dicarbonyl reagents. From protection experiments it was concluded (i) that both modifiers react specifically with an arginine in the phosphoglucose isomerase active site and nonspecifically with one or more arginine residues elsewhere in the enzyme molecule, (ii) that modification at either loci causes loss of catalytic activity, and (iii) that butanedione has a higher preference for active site arginine than for arginine residues outside of the catalytic center whereas the opposite is true for phenylglyoxal.     

Investigation of the relation of the pH-dependent dissociation of malate dehydrogenase to modification of the enzyme by N-ethylmaleimide.

The pH-dependent dissociation of porcine heart mitochondrial malate dehydrogenase (L-malate:NAD+ oxidoreductase, EC 1.1.1.37) has been further characterized using the technique of sedimentation velocity ultracentrifugation. The increased rate and specificity of the inactivation of mitochondrial malate dehydrogenase by the sulfhydryl reagent N-ethylmaleimide has been correlated with the pH-dependent dissociation of the enzyme. Data obtained using NAD+ and its component parts to reassociate the enzyme and also to protect the enzyme from inactivation by N-ethylmaleimide suggest that the sulfhydryl residues being modified by N-ethylmaleimide are inaccessible when the enzyme is in its dimeric form. A dissociation curve for the pH-dependent dissociation suggests that a limited number of residues are being protonated concomitant with dissociation of the enzyme. An apparent pKa of 5.3 has been determined for this phenomenon. Studies using enzyme modified by the sulfhydryl reagent N-ethylmaleimide indicate that selective modification of essential sulfhydryl residues alters the proper binding of NADH.     

1,2-Cyclohexanedione modification of arginine residues in egg-white riboflavin-binding protein

1. Reaction of 1,2-cyclohexanedione with arginine residues of egg white riboflavin-binding protein results in a loss of the binding activity. 2. In borate buffer pH 8.0, with 0.15 M cyclohexanedione, the inactivation proceeds with a pseudo-first-order rate constant 0.084 hr.-1. 3. At least 65% of lost riboflavin binding capacity can be recovered on 12 hr incubation in 0.5 M hydroxylamine pH 7.0. 4. All 5 arginine residues are modified, 2-3 of them seem to react much easier than others. 5. The correlation between modification of arginines and protein inactivation, as analyzed by kinetic and statistical methods, suggests that one of low-reactivity residues is "essential" for riboflavin binding. 6. In the holoprotein, one arginine residue is almost completely protected from 1,2-cyclohexanedione modification. 7. Riboflavin does not dissociate from holoprotein, even on prolongated incubation with the reagent. 8. The protected arginine residue seems to be located in the riboflavin binding pocket of protein macromolecule.     

Chemical modification of arginine residues of porcine muscle acylphosphatase

Acylphosphatase (acylphosphate phosphohydrolase, EC 3.6.1.7) from porcine skeletal muscle is inactivated by phenylglyoxal following pseudo-first-order kinetics. The dependence of the apparent first-order rate constant for inactivation on the phenylglyoxal concentration shows that the inactivation is also first order with respect to the reagent concentration. Among the competitive inhibitors for the enzyme examined, inorganic phosphate and ATP almost completely, and Cl- partially, protect the enzyme against the inactivation. The dissociation constants for inorganic phosphate and ATP determined from protection experiments by these inhibitors agree well with those from inhibition experiments by them. These results support the idea that the modification occurs at the phosphate-binding site. The amino-acid analysis reveals the lack of reaction at residues other than arginine. Circular dichroism spectra of the modified enzymes show that the inactivation seems not to be due to denaturation of the enzyme resulting from the modification of the non-essential arginine residues. The relationship between the loss of the enzyme activity and the number of arginine residues modified in the presence and absence of ATP shows that one arginine residue is possibly responsible for the inactivation of acylphosphatase.     

Photoinactivation and carbethoxylation of leucine aminopeptidase.

In the present paper the reactivity of histidyl residues of leucine aminopeptidase from bovine eye lens was studied by dye-sensitized photooxidation and by carbethoxylation of the enzyme protein using diethylpyrocarbonate. Of all the different amino acids modified by photooxidation only histidine is connected with the enzymic acticity, whereas tyrosine seems to be involved in structure stabilization. By changing the pH and varying the effectors (Mg2+ and/or dodecylsulfate) of the reaction mixture a different number of histidyl residues of the enzyme protein is caused to react with diethylpyrocarbonate. No secondary reactions with tyrosyl or tryptophyl residues could be observed by spectrophotometric investigations. The enzyme modified by one of the above-mentioned methods shows changes in the capacity of Mn2+ binding measured by autoradiography as well as in the degree of enhancement of enzymic activity by Mn2+ or Mg2+ ions. Of the 48 histidyl residues of the enzyme (Mr = 326000) up to 2 histidyl residues per subunit (Mr = 54000) may be involved in Mn2+ or Mg2+ binding and up to 4 histidyl residues have a strong influence on Zn2+ binding.     

STUDIES ON THE ATTACHMENT OF DNA TO SILICA-COATED NANOPARTICLES THROUGH A DIELS-ALDER REACTION

A new method has been investigated for the functionalization of gold nanoparticles with DNA. Silica-coated nanoparticles functionalized with a maleimide have been prepared. These particles are designed to react with modified DNA containing a diene functionality at one end of the molecule. The result would be the formation of a more stable attachment of the DNA to the particle through a Diels-Alder reaction. This covalent attachment would not be susceptible to ligand exchanges, which are known to occur in the conventional DNA functionalization of gold nanoparticles.