Modification of histidine 56 in adrenodoxin with diethyl pyrocarbonate inhibited the interaction with cytochrome P-450scc and adrenodoxin reductase

Three histidine residues of bovine adrenodoxin, His-10, His-56, and His-62, were modified with diethyl pyrocarbonate. The order of the modification among the three histidines were monitored by measuring the proton NMR spectra. The modified adrenodoxin exhibited reduced affinity for adrenodoxin reductase as determined in cytochrome c reductase activity. In the presence of cholesterol, the modified adrenodoxin induced a high spin form of cytochrome P-450scc on complex formation in the same manner as native adrenodoxin. The spectral titration showed that adrenodoxin modified with diethyl pyrocarbonate exhibited a 5-fold higher Kd value than that of native adrenodoxin. These effects of the modification of adrenodoxin on the affinities for the redox partners were not proportional to the number of modified histidines determined by the optical absorbance change at 240 nm. Modification of adrenodoxin up to 2 histidine residues did not affect the affinity for the redox partners, but further modification on the third one resulted in an increase of apparent Km in cytochrome c reductase activity by 2-fold and of Kd for cytochrome P-450scc by 5-fold. The 1H NMR spectra of the modified adrenodoxin unequivocally demonstrated that histidine residues at His-10 and His-62 reacted more readily with diethyl pyrocarbonate than His-56 did, indicating that modification of His-56 was responsible for the reduction of binding affinities of adrenodoxin for redox partners. These results are consistent with the proposal that the residue of His-56 in adrenodoxin has an essential role in the electron transfer mechanism where adrenodoxin functions as a mobile shuttle.     

Effect of diethyl pyrocarbonate modification on spectral and steady-state kinetic properties of bovine heart cytochrome oxidase.

The histidine-specific reagent diethyl pyrocarbonate has been used to chemically modify bovine heart cytochrome oxidase. Thirty-two of sixty-seven histidine residues of cytochrome oxidase are accessible to modification by diethyl pyrocarbonate. Effects on the Soret and alpha bands of the heme spectrum indicate disturbance in the environment of one or both of the heme groups. However, diethyl pyrocarbonate modification does not alter the 830-nm absorbance band, suggesting that the environment of CuA is unchanged. Maximal modification of cytochrome oxidase by diethyl pyrocarbonate results in loss of 85-90% of the steay-state electron transfer activity, which can be reversed by hydroxylamine treatment. However, modification of the first 20 histidines does not alter either activity or the heme spectrum, but only when 32 residues have been modified are the activity and heme spectral changes complete. The steady-state kinetic profile of fully modified oxidase is monophasic; the phase corresponding to tight cytochrome c binding and low turnover is retained, whereas the high turnover phase is abolished. Proteoliposomes incorporated with modified oxidase have a 65% lower respiratory control ratio and 40% lower proton pumping stoichiometry than liposomes containing unmodified oxidase. These results are discussed in terms of a redox-linked proton pumping model for energy coupling via cytochrome oxidase.     

The role of an essential histidine residue of yeast alcohol dehydrogenase.

1. Inactivation of yeast alcohol dehydrogenase for diethyl pyrocarbonate indicates that one histidine residue per enzyme subunit is necessary for enzymic activity. The inactivated enzyme regains its activity over a period of days. 2. Enzyme modified by diethyl pyrocarbonate can form the binary enzyme - NADH complex with the same maximum NADH-binding capacity as that of native enzyme. Modified enzyme cannot form normal ternary complexes of the type enzyme - NADH - acetamide and enzyme - NAD+ - pyrazole, which are characteristic of native enzyme. 3. The rate constant for the reaction of enzyme with diethyl pyrocarbonate has been determined over the pH range 5.5--9. The histidine residue involved has approximately the same pKa as free histidine, but is 10-fold more reactive than free histidine.     

The involvement of one of the three histidine residues of cow kappa-casein in the chymosin-initiated milk clotting process.

Cow kappa-casein has been modified by photo-oxidation in the presence of rose bengal and by the chemical reagents diethyl pyrocarbonate, 2-hydroxy-5-nitro-benzyl bromide and iodoacetic acid. Photo-oxidation resulted in the destruction of histidine and tryptophan residues and all of the histidines could be ethoxy-formylated by treatment with diethyl pyrocarbonate. Both procedures caused a loss in the susceptibility of the Phe-Met linkage of kappa-casein to chymosin hydrolysis. Treatment of kappa-casein with 2-hydroxy-5-nitrobenzyl bromide and iodoacetic acid caused the loss of tryptophan and methionine residues respectively but, in both cases, the susceptibility of the modified protein to chymosin hydrolysis remained unaffected. Of the amino acids examined it is concluded that only the histidine residues of cow kappa-casein are important for the hydrolytic action of chymosin and, furthermore, the treatment with diethyl pyrocarbonate suggests that only one of the three histidines plays an essential role.     

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.     

Evidence for an essential histidine residue in 4S-limonene synthase and other terpene cyclases.

(4S)-Limonene synthase, isolated from glandular trichome secretory cell preparations of Mentha x piperita (peppermint) leaves, catalyzes the metal ion-dependent cyclization of geranyl pyrophosphate, via 3S-linalyl pyrophosphate, to (-)-(4S)-limonene as the principal product. Treatment of this terpene cyclase with the histidine-directed reagent diethyl pyrocarbonate at a concentration of 0.25 mM resulted in 50% loss of enzyme activity, and this activity could be completely restored by treatment of the preparation with 5 mM hydroxylamine. Inhibition with diethyl pyrocarbonate was distinguished from inhibition with thiol-directed reagents by protection studies with histidine and cysteine carried out at varying pH. Inactivation of the cyclase by dye-sensitized photooxidation in the presence of rose bengal gave further indication of the presence of a readily modified histidine residue. Protection of the enzyme against inhibition with diethyl pyrocarbonate was afforded by the substrate geranyl pyrophosphate in the presence of Mn2+, and by the sulfonium ion analog of the linalyl carbocation intermediate of the reaction in the presence of inorganic pyrophosphate plus Mn2+, suggesting that an essential histidine residue is located at or near the active site. Similar studies on the inhibition of other monoterpene and sesquiterpene cyclases with diethyl pyrocarbonate suggest that a histidine residue (or residues) may play an important role in catalysis by this class of enzymes.     

Studies of a reactive histidine of dyphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart.

Diphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart was inactivated at neutral pH by bromoacetate and diethyl pyrocarbonate and by photooxidation in the presence of methylene blue or rose bengal. Inactivation by diethyl pyrocarbonate was reversed by hydroxylamine. Loss of activity by photooxidation at pH 7.07 was accompanied by progressive destruction of histidine with time; loss of 83% of the enzyme activity was accompanied by modification of 1.1 histidyl residues per enzyme subunit. The pH-rate profiles of inactivation by photooxidation and by diethyl pyrocarbonate modification showed an inflection point around pH 6.6, in accord with the pK_a for a histidyl residue of a protein. Partial protection against inactivation by photooxidation or diethyl pyrocarbonate was obtained with substrate (manganous isocitrate or magnesium isocitrate) or ADP; the combination of substrate and ADP was more effective than the components singly. As demonstrated by differential enzyme activity assays between pH 6.4 and pH 7.5 with and without 0.67 mm ADP, modification of the reactive histidyl residue of the enzyme caused a preferential loss of the positive modulation of activity by ADP. The latter was particularly apparent when substrate partially protected the enzyme against inactivation by rose bengal-induced photooxidation.     

Identification of two essential histidine residues of ribonuclease T2 from Aspergillus oryzae

Ribonuclease (RNase) T2 from Aspergillus oryzae was modified by diethyl pyrocarbonate and iodoacetic acid. RNase T2 was rapidly inactivated by diethyl pyrocarbonate above pH 6.0 and by incorporation of a carboxymethyl group. No inactivation occurred in the presence of 3'AMP. 1H-NMR titration and photo-chemically induced dynamic nuclear polarization experiments demonstrated that two histidine residues were involved in the active site of RNase T2. Furthermore, analysis of inactive carboxymethylated RNase T2 showed that both His53 and His115 were partially modified to yield a total of one mole of N tau-carboxymethylhistidine/mole enzyme. The results indicate that the two histidine residues in the active site of RNase T2 are essential for catalysis and that modification of either His53 or His115 inactivates the enzyme.     

Binding of arylazidocytochrome c to yeast cytochrome c peroxidase

Cytochrome c derivatives modified with a photoactivatable arylazido group in selected lysine residues were irradiated in the presence of cytochrome c peroxidase (EC 1.11.1.5). A derivative modified at lysine 13 was able to cross-link to the enzyme and inhibit electron transfer activity. Complete inhibition of cytochrome c peroxidase activity was obtained when 1 mol of cytochrome c was covalently bound per mol of cytochrome c peroxidase. Chemical cleavage of the covalent complex has been used for a preliminary characterization of the site of cross-linking of cytochrome c to cytochrome c peroxidase. This linkage site was localized to the NH2 terminal part of cytochrome c peroxidase including residues 1-51.     

Site-directed mutagenesis of yeast cytochrome c peroxidase shows histidine 181 is not required for oxidation of ferrocytochrome c

The long-distance electron transfer observed in the complex formed between ferrocytochrome c and compound I, the peroxide-oxidized form of cytochrome c peroxidase (CCP), has been proposed to occur through the participation of His 181 of CCP and Phe 87 of yeast iso-1 cytochrome c [Poulos, T. L., & Kraut, J. (1980) J. Biol. Chem. 255, 10322-10330]. We have examined the role of His 181 of CCP in this process through characterization of a mutant CCP in which His 181 has been replaced by glycine through site-directed mutagenesis. Data from single-crystal X-ray diffraction studies, as well as the visible spectra of the mutant CCP and its 2-equiv oxidation product, compound I, show that at pH 6.0 the protein is not dramatically altered by the His 181----Gly mutation. The rate of peroxide-dependent oxidation of ferrocytochrome c by the mutant CCP is reduced only 2-fold relative to that of the parental CCP, under steady-state conditions. Transient kinetic measurements of the intracomplex electron transfer rate from ferrous cytochrome c to compound I indicate that the rate of electron transfer within the transiently formed complex at high ionic strength (mu = 114 mM, pH = 6) is also reduced by approximately 2-fold in the mutant CCP protein. The relatively minor effect of the loss of the imidazole side chain at position 181 on the kinetics of electron transfer in the CCP-cytochrome c complex precludes an obligatory participation of His 181 in electron transfer from ferrous cytochrome c to compound I.(ABSTRACT TRUNCATED AT 250 WORDS)     

Diethyl pyrocarbonate reaction with the lactose repressor protein affects both inducer and DNA binding

Modification of the lactose repressor protein of Escherichia coli with diethyl pyrocarbonate (DPC) results in decreased inducer binding as well as operator and nonspecific DNA binding. Spectrophotometric measurements indicated a maximum of three histidines per subunit was modified, and quantitation of lysine residues with trinitrobenzenesulfonate revealed the modification of one lysine residue. The loss of DNA binding, both operator and nonspecific, was correlated with histidine modification; removal of the carbethoxy groups from the histidines by hydroxylamine was accompanied by significant recovery of DNA binding function. The presence of inducing sugars during the DPC reaction had no effect on histidine modification or the loss of DNA binding activity. In contrast, inducer binding was not recovered upon reversal of the histidine modification. However, the presence of inducer during reaction protected lysine from reaction and also prevented the decrease in inducer binding; these results indicate that reaction of the lysine residue(s) may correlate to the loss of sugar binding activity. Since no difference in incorporation of radiolabeled carbethoxy was observed following reaction with diethyl pyrocarbonate in the presence or absence of inducer, the reagent appears to function as a catalyst in the modification of the lysine. The formation of an amide bond between the affected lysine and a nearby carboxylic acid moiety provides a possible mechanism for the activity loss. Reaction of the isolated NH2-terminal domain resulted in loss of DNA binding with modification of the single histidine at position 29. Results from the modification of core domain paralleled observations with intact repressor.     

The histidine residues of phospholipase C from Bacillus cereus.

The inactivation of phospholipase C from Bacillus cereus at pH6 by diethyl pyrocarbonate parallelled the N-ethoxyformylation of a single histidine residue in the enzyme. The inactivation arose from a decrease in the maximum velocity of the enzymic reaction with no effect on the Km value. The inactivation did not apparently alter the ability of the enzyme to bind to a substrate-based affinity gel. The native enzyme contained only one reactive histidine residue. Removal of the two zinc atoms from the enzyme increased the number of reactive histidine residues to five, whereas in the totally denatured enzyme nearly eight such residues were available for reaction with diethyl pyrocarbonate. The enzyme thus appears to contain one histidine residue that is essential for catalytic activity and four that may be involved in co-ordinating the zinc atoms in the structure.     

Identification of structurally and functionally important histidine residues in cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae

Cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae is an alpha 2 dimer (alpha, Mr 63,000), each alpha containing 12 histidines. The covalent incorporation of 6-7 mol of diethyl pyrocarbonate per monomer corresponded to complete enzyme inactivation. This inactivation was reversed by hydroxylamine hydrolysis which regenerates free histidine (and tyrosine) while leaving the carbethoxy group still attached to the epsilon-amino group of lysine. Three histidines, one tyrosine, and four lysines were the main targets of the reagent. Site-directed mutagenesis was also tried to replace each of these modified residues. Given the unstability of the carbethoxy-imidazole bond, the nine histidines that were not modified by diethyl pyrocarbonate were mutated too. For these experiments, the enzyme was expressed in Escherichia coli by using a vector bearing the structural gene in which the first 13 codons were replaced by the first 14 of the CII lambda gene. This substitution had no effect on the kinetic parameters. The combined results of chemical modification and site-directed mutagenesis show that one histidine seems to be part of the active site while two others play an important structural role. On the other hand, labeled lysines and tyrosine are nonessential residues. These results are discussed in light of two recent articles establishing the existence of a second family of aminoacyl-tRNA synthetases devoid of the HIGH and KMSKS consensus sequences and containing no Rossmann's domain in their three-dimensional structures.     

Identification by proton nuclear magnetic resonance of the histidines in cytochrome b5 modified by diethyl pyrocarbonate

Diethyl pyrocarbonate (DEP) is an electrophilic reagent that is used to modify reversibly the histidine residues of proteins. Unfortunately, the lability of the acylated histidine adduct usually does not permit the isolation and identification of the modified histidine. By use of 500-MHz proton NMR spectroscopy, it has been possible to identify the C-H resonances of the nonaxial histidines of trypsin-solubilized bovine, rabbit, and porcine cytochrome b5 and therefore observe the interaction of DEP with specific histidine residues of cytochrome b5. In addition, the pKa of the peripheral histidines of bovine and rabbit cytochrome b5 have been measured in D2O. In the bovine protein it was found that the histidines are modified sequentially with increasing DEP concentration in the order His-26 greater than His-15 greater than His-80. This order is maintained in the rabbit protein with the following additions: His-26 approximately His-27 greater than His-15 greater than or equal to His-17 greater than His-80. The relative reactivity of the peripheral histidines with DEP was rationalized by considering three of their characteristics: (1) the pKa of the histidine, (2) the fraction of the side chain exposed to the solvent, and (3) the hydrogen-bond interactions of the imidazole ring.     

Metal-tetracycline/H+ antiporter of Escherichia coli encoded by a transposon Tn10. Histidine 257 plays an essential role in H+ translocation.

The transposon Tn10-encoded tetA gene product is a metal-tetracycline/proton antiporter (Yamaguchi, A., Udagawa, T., and Sawai, T. (1990) J. Biol. Chem. 265, 4809-4813). Its tetracycline transport activity was inhibited by a histidine-specific reagent, diethyl pyrocarbonate. Among five histidine residues in this antiporter, only His257 is located in the putative transmembrane helices. Thus, His257 was replaced by Glu or Asp. Inverted vesicles containing the Glu257 and Asp257 mutant proteins showed only 20 and 10% of the tetracycline uptake of wild-type vesicles, respectively. In contrast to wild-type vesicles, the mutant vesicles showed no tetracycline-dependent proton translocation, indicating that the mutant proteins had lost the tetracycline/H+ antiport activity. The significant 60Co2+ uptake without proton translocation by the mutant vesicles also confirmed that the mutant carriers act as uniporters of a metal-tetracycline complex. The metal-tetracycline uniport by the mutant proteins was not inhibited by diethyl pyrocarbonate, indicating that His257 is the only histidine residue essential for proton translocation. These mutant proteins conferred about half-level resistance to tetracycline, probably due to their catalyzing downhill efflux of a metal-tetracycline complex out of the cells.     

A proton NMR study of the non-covalent complex of horse cytochrome c and yeast cytochrome-c peroxidase and its comparison with other interacting protein complexes

Cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) forms a noncovalent 1:1 complex with horse cytochrome c in low ionic strength solution that is detectable by proton NMR spectroscopy. When the entire proton hyperfine-shifted spectrum is considered only five hyperfine resonances exhibit unambiguously detectable shifts: the heme 8-CH3 and 3-CH3 resonances, single proton resonances near 19 ppm and -4 ppm and the methionine-80 methyl group. These shifts are very similar to those observed for the covalently crosslinked complex of cytochrome-c peroxidase and horse cytochrome c, but different from those reported for cytochrome c complexes with flavodoxin and cytochrome b5. By comparison with the shifts reported for lysine-13-modified cytochrome c we conclude that the results reported here support the Poulos-Kraut proposed structure for the molecular redox complex between cytochrome-c peroxidase and cytochrome c. These results indicate that the principal site of interaction with cytochrome-c peroxidase is the exposed heme edge of horse cytochrome c, in proximity to lysine-13 and the heme pyrrole II. The noncovalent cytochrome-c peroxidase-cytochrome c complex exists in the rapid-exchange time limit even at 500 mHz proton frequency. Our data provide an improved estimate of the minimum off-rate for exchanging cytochrome c as 1133 (+/- 120) s-1 at 23 degrees C.     

Enthalpy and enzyme activity of modified histidine residues of adenosine deaminase and diethyl pyrocarbonate complexes

Kinetic and thermodynamic studies have been made on the effect of diethyl pyrocarbonate as a histidine modifier on the active site of adenosine deaminase in 50 mM sodium phosphate buffer pH 6.8, at 27 degrees C using UV spectrophotometry and isothermal titration calorimetry (ITC). Inactivation of adenosine deaminase by diethyl pyrocarbonate is correlated with modification of histidyl residues. The number of modified histidine residues complexed to active site of adenosine deaminase are equivalent to 4. The number and energy of histidine binding sets are determined by enthalpy curve, which represents triple stages. These stages are composed of 3,1 and 1 sites of histidyl modified residues at diethyl pyrocarbonate concentrations, 0.63, 1.8, 3.3 mM. The heat contents corresponding to the first, second and third sets are found to be 18000, 22000 and 21900 kJ mol(-1) respectively.     

The involvement of carboxylate groups of putidaredoxin in the reaction with putidaredoxin reductase

Modification of carboxyl groups on putidaredoxin with 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide (EDC) resulted in loss of putidaredoxin reductase activity. The modification did not affect the visible absorption spectrum of putidaredoxin, indicating that the iron-sulfur center was not perturbed. In order to identify the carboxyl groups labeled by EDC, native and EDC-treated putidaredoxin were digested with a combination of trypsin and Staphylococcus aureus protease, and the resulting peptides were separated by high pressure liquid chromatography. The most heavily modified carboxyl groups were found to be those at residues 58, 65, 67, 72, and 77. These carboxyl groups are located in the same general region of the protein as those on adrenodoxin that have been shown to be involved in binding to both adrenodoxin reductase and cytochrome P-450scc. Chemical modification was also used to compare the role of lysine, arginine, and histidine residues on putidaredoxin and adrenodoxin. Modification of lysine and arginine residues had no effect on the reductase activity of either protein. The reductase activity of adrenodoxin was unaffected by labeling with 1 eq of diethyl pyrocarbonate/histidine residue, but labeling with a second equivalent completely abolished both activity and the iron-sulfur center spectrum. In contrast, modification of the 2 histidines in putidaredoxin with 1 eq each resulted in nearly complete loss of reductase activity. There was no significant activity for adrenodoxin in the putidaredoxin reductase assay or for putidaredoxin in the adrenodoxin reductase assay, demonstrating that, in spite of the structural similarity between the two proteins, they are not interchangeable functionally.     

Evaluation of cooperative interactions between substructures of iso-1-cytochrome c using double mutant cycles

A double mutant cycle has been used to evaluate interaction energies between the global stabilizer mutation asparagine 52 --> isoleucine (N52I) in iso-1-cytochrome c and mutations producing single surface histidines at positions 26, 33, 39, 54, 73, 89, and 100. These histidine mutation sites are distributed through the four cooperative folding units of cytochrome c. The double mutant cycle starts with the iso-1-cytochrome c variant AcTM, a variant with no surface histidines and with asparagine at position 52. Isoleucine is added singly at position 52, AcTMI52 variant, as are the surface histidines, AcHX variants, where X indicates the histidine sequence position. The double mutant variants, AcHXI52, provide the remaining corner of the double mutant cycle. The stabilities of all variants were determined by guanidine hydrochloride denaturation and interaction energies were calculated between position 52 and each histidine site. Six of the seven double mutants show additive (AcH33I52, AcH39I52, AcH54I52, AcH89I52, and AcH100I52) stability effects or weak interaction energies (AcH73I52) of the histidine mutations and the N52I mutation, consistent with cooperative effects on protein folding and stability being sparsely distributed through the protein structure. The AcH26I52 variant shows a strong favorable interaction energy, 2.0 +/- 0.5 kcal/mol, between the N52I mutation in one substructure and the addition of His 26 to an adjacent substructure. The data are consistent with an entropic stabilization of the intersubstructure hydrogen bond between His 26 and Glu 44 by the Ile 52 mutation.     

Comparison of aspartate transcarbamoylases from wheat germ and Escherichia coli: functionally identical histidines in nonhomologous local sequences

Aspartate transcarbamoylase (ATCase) from wheat germ and the catalytic subunit of the enzyme from Escherichia coli are trimers of similar size. The former is a regulatory enzyme in its trimeric state, while the latter is a component of a complex regulatory dodecamer. In a comparison of the two enzymes, reaction with diethyl pyrocarbonate revealed a highly active, essential histidine residue in each case. The two histidines (i.e., one in each enzyme) behaved nearly identically with respect to the following functional properties: kinetics of acylation (ethoxyformylation) and concomitant inactivation; kinetics of deacylation by hydroxylamine and concomitant reactivation; hyperbolic dependence of the apparent first-order rate constant (kapp) on diethyl pyrocarbonate concentration; pH dependence of kapp; failure of active-center ligands to protect the residue against diethyl pyrocarbonate, producing instead near-identical increases in the inactivation rate. These similarities point to an essential, highly conserved histidine in each enzyme, in a functional microenvironment that has changed relatively little since the divergence of plants and bacteria. Ethoxyformylated peptides were isolated from tryptic digests of the two inactivated enzymes. Sequencing of the major labeled peptide in each case showed the wheat and E. coli histidines embedded in nonhomologous primary segments, suggesting that, contrary to expectation, these segments are not part of the conserved microenvironment. In the case of the E. coli enzyme, the essential residue was identified as His-134 in the known sequence, which has a potential catalytic role on crystallographic evidence [Krause, K. L., Volz, K. W., & Lipscomb, W. N. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 1643-1647]. A second, much less reactive histidine was identified as His-64.(ABSTRACT TRUNCATED AT 250 WORDS)