Histidine-specific Reagent Research Articles

Photo-oxidation of a DNase from human small intestine

The purified small intestine DNase (SIDNase) from human intestine was inactivated by the irradiation of the enzyme in the presence of photosensitizer dyes (methylene blue and rose Bengal) which lead to a specific destruction of 10 amino acid residues: three histidine, two serine, one tryptophan and four tyrosine residues. The other photo-sensitive amino acid residues are not appreciably affected. It is reasonable to assume that one or two of histidine, two or three of tyrosine, one tryptophan and two to three serine residues were responsible for the inactivation of the enzyme and may be of essential importance in the catalytic function of the enzyme. In order to implicate these results, histidine-specific reagent (DEP), tyrosine kinase inhibitor, tryptophan hydroxylase, chymotrypsin were added separately, to the enzyme mixture with a significant decrease in the enzyme catalytic activity indicating that histidine, tyrosine, tryptophan, serine may have a role in the catalytic activity of the enzyme. These residues seem to be critically connected with the DNase activity, whether the residues could be essential for the maintenance of a catalytically efficient conformation of the protein, or be directly involved in the formation and transformation of enzyme-substrate intermediates, or in binding the coenzyme or substrate (or substrates),or both, in a mode suitable for catalysis. Key words: DNase, histidine-specific reagent (DEP), tyrosine kinase inhibitor

Role of histidine residues in EcoP15I DNA methyltransferase activity as probed by chemical modification and site-directed mutagenesis

Towards understanding the catalytic mechanism of M.EcoP15I [EcoP15I MTase (DNA methyltransferase); an adenine methyltransferase], we investigated the role of histidine residues in catalysis. M.EcoP15I, when incubated with DEPC (diethyl pyrocarbonate), a histidine-specific reagent, shows a time- and concentration-dependent inactivation of methylation of DNA containing its recognition sequence of 5'-CAGCAG-3'. The loss of enzyme activity was accompanied by an increase in absorbance at 240 nm. A difference spectrum of modified versus native enzyme shows the formation of N-carbethoxyhistidine that is diminished by hydroxylamine. This, along with other experiments, strongly suggests that the inactivation of the enzyme by DEPC was specific for histidine residues. Substrate protection experiments show that pre-incubating the methylase with DNA was able to protect the enzyme from DEPC inactivation. Site-directed mutagenesis experiments in which the 15 histidine residues in the enzyme were replaced individually with alanine corroborated the chemical modification studies and established the importance of His-335 in the methylase activity. No gross structural differences were detected between the native and H335A mutant MTases, as evident from CD spectra, native PAGE pattern or on gel filtration chromatography. Replacement of histidine with alanine residue at position 335 results in a mutant enzyme that is catalytically inactive and binds to DNA more tightly than the wild-type enzyme. Thus we have shown in the present study, through a combination of chemical modification and site-directed mutagenesis experiments, that His-335 plays an essential role in DNA methylation catalysed by M.EcoP15I.

Inhibition of Alkaline Phosphatase from Pearl Oyster Pinctada fucata by o-Phthalaldehyde: Involvement of Lysine and Histidine Residues at the Active Site

Alkaline phosphatase from Pinctada fucata was inactivated by o-phthalaldehyde (OPA). The inactivation followed pseudo first-order kinetics with a second rate constant of 0.167 (mmol/L) −1·min −1 at pH 7.5 and 25°C. A Tsou's plot analysis showed that inactivation occurred upon formation of one isoindole group. The OPA-modified enzyme lost the ability to bind with the specific affinity column and the presence of substrates or competitive inhibitors protected the enzyme from inactivation. The results revealed that the OPA-reaction site was at the enzyme substrate binding site. Prior modification of the enzyme by lysine or histidine specific reagent abolished formation of the isoindole derivatives, suggesting that lysine and histidine residues were involved in the OPA-induced inactivation. Taken together, OPA inactivated the alkaline phosphatase from Pinctada fucata by cross-linking lysine and histidine residues at the active site and formed an isoindole group at the substrate binding site of the enzyme.

Mechanism of horseradish peroxidase-catalyzed heme oxidation and polymerization (β-hematin formation)

Horseradish peroxidase (HRP) catalyzes the polymerization of free heme (beta-hematin formation) through its oxidation. Heme when added to HRP compound II (FeIV=O) causes spectral shift from 417 nm (Compound II) to 402 nm (native, FeIII) indicating that heme may be oxidized via one-electron transfer. Direct evidence for one-electron oxidation of heme by HRP intermediates is provided by the appearance of an E.s.r signal of a 5,5-dimethyl-1-pyrroline N-oxide (spin trap)-heme radical adduct (a1H=14.75 G, a2H=4.0 G) in E.s.r studies. Heme-polymerization by HRP is inhibited by spin trap indicating that one-electron oxidation product of heme ultimately leads to the formation of heme-polymer. HRP, when incubated with diethyl pyrocarbonate (DEPC), a histidine specific reagent, shows concentration dependent loss of heme-polymerization indicating the role of histidine residues in the process. We suggest that HRP catalyzes the formation of heme-polymer through one-electron oxidation of free heme.

Slowing of ERG current deactivation in NG108-15 cells by the histidine-specific reagent diethylpyrocarbonate

The aim of this study was to explore and characterize the effect of the histidine-specific reagent diethylpyrocarbonate (DEPC) on the ERG ( ether-à-go-go related gene) channels of whole-cell voltage-clamped NG108-15 neuroblastoma x glioma hybrid cells. The channels were fully activated by long depolarizing prepulses. Hyperpolarizing pulses elicited K + inward currents which deactivated after reaching a peak. DEPC (0.26–2.1 mM, externally applied for 5–12 min) irreversibly decreased τ −1, the rate constant of deactivation. At a pulse potential of −120 mV τ −1 decreased on average by 60%. The effect can be described as a −25 mV shift of the τ −1( V) curve. The activation curve and the curve relating steady-state current to pulse potential were shifted by similar amounts. The decrease of τ −1 was the same at 0.26 and at 2.1 mM, but developed faster at the higher concentration. The slowing of deactivation was only seen when the cells were held at a potential of −20 mV. At this potential it developed with a time constant of 47 s. At more negative holding potentials (−40 or −70 mV) only a slight reduction of the peak occurred. The observations suggest preferential binding of DEPC to the open and inactivated channel states. The DEPC effect can possibly be explained by the reaction of DEPC with histidine residues or other amino acids in the external loops of the channel. However, dichloro-(2,2′:6′,2″-terpyridine)-platinum (II) dihydrate (DTPD), another histidine-specific reagent, markedly decreased the peak current without affecting τ −1. Therefore, the possibility that (some of) the effects of DEPC and DTPD are unrelated to their property as histidine-specific reagents cannot be excluded.

Identification of catalytically essential amino acid residues of penicillin G acylase obtained from a mutant of Escherichia coli ATCC 11105

The chemical modification of penicillin G acylase (PGA) obtained from a mutant of Escherichia coli ATCC 11105 was studied in order to identify the catalytically essential amino acid residues of the enzyme. The modification of PGA by serine specific phenylmethylsulphonylfluoride (PMSF) and tryptophan specific N-bromosuccinimide (NBS) resulted in the complete inactivation of the enzyme. Modification by arginine specific phenylglyoxal and lysine specific ethylacetimidate caused the partial inactivation of the enzyme and partial protection of enzyme activity was observed when modifications were carried out in the presence of the strong competitive inhibitor penicillin G sulphoxide (PenGSO). Enzyme activity was not affected by the modification of cysteine specific ethylmaleiimide and histidine specific reagents tosyl- l-lysine-chloromethyl ketone (TLCK) and tosyl- l-phenylalanine-chloromethyl ketone (TPCK). The inactivation of PGA by amino acid specific modifying reagents obeyed first-order kinetics. The kinetic constants ( V m, K m and k cat values) and pH–activity profiles of native and modified PGA preparations were also investigated. The results of these investigations showed that the active site of the enzyme contained a catalytically essential serine residue. It may be argued that the modification of arginine residues induces the conformational change of the entire enzyme molecule. These residues are located at a site other than the active site of the enzyme and are not essential for catalysis. The modification of lysine residues induces conformational changes in the active site of the enzyme but these residues can contribute neither catalysis nor substrate binding.

The Role of Active Site Arginines of Sorghum NADP-Malate Dehydrogenase in Thioredoxin-dependent Activation and Activity

The activation of sorghum NADP-malate dehydrogenase is initiated by thiol/disulfide interchanges with reduced thioredoxin followed by the release of the C-terminal autoinhibitory extension and a structural modification shaping the active site into a high efficiency and high affinity for oxaloacetate conformation. In the present study, the role of the active site arginines in the activation and catalysis was investigated by site-directed mutagenesis and arginyl-specific chemical derivatization using butanedione. Sequence and mass spectrometry analysis were used to identify the chemically modified groups. Taken together, our data reveal the involvement of Arg-134 and Arg-204 in oxaloacetate coordination, suggest an indirect role for Arg-140 in substrate binding and catalysis, and clearly confirm that Arg-87 is implicated in cofactor binding. In contrast with NAD-malate dehydrogenase, no lactate dehydrogenase activity could be promoted by the R134Q mutation. The decreased susceptibility of the activation of the R204K mutant to NADP and its increased sensitivity to the histidine-specific reagent diethylpyrocarbonate indicated that Arg-204 is involved in the locking of the active site. These results are discussed in relation with the recently published NADP-MDH three-dimensional structures and the previously established three-dimensional structures of NAD-malate dehydrogenase and lactate dehydrogenase.

Contribution of histidine residues to oligomerization of theta-toxin (perfringolysin O), a cholesterol-binding cytolysin.

Theta-toxin (perfringolysin O) modified by diethyl pyrocarbonate, a histidine-specific reagent, lost its hemolytic activity. The modified toxin retains the activities of binding to and insertion into cholesterol-containing membranes but lacks the ability to form oligomers. These results suggest that histidine residues of theta-toxin contribute their share to cytolysis, especially the oligomerization process.

The Autoinhibition of Sorghum NADP Malate Dehydrogenase Is Mediated by a C-terminal Negative Charge

The chloroplastic NADP malate dehydrogenase is completely inactive in its oxidized form and is activated by thiol/disulfide interchange with reduced thioredoxin. To elucidate the molecular mechanism underlying the absence of activity of the oxidized enzyme, we used site-directed mutagenesis to delete or substitute the two most C-terminal residues (C-terminal Val, penultimate Glu, both bearing negative charges). We also combined these mutations with the elimination of one or both of the possible regulatory N-terminal disulfides by mutating the corresponding cysteines. Proteins mutated at the C-terminal residues had no activity in the oxidized form but were partially inhibited when pretreated with the histidine-specific reagent diethyl pyrocarbonate before activation, showing that the active site was partially accessible. Proteins missing both N-terminal regulatory disulfides reached almost full activity without activation upon elimination of the negative charge of the penultimate Glu. These results strongly support a model where the C-terminal extension is docked into the active site through a negatively charged residue, acting as an internal inhibitor. They show also that the reduction of both N-terminal bridges is necessary to release the C-terminal extension from the active site. This is the first report for a thiol-activated enzyme of a regulatory mechanism resembling the well known intrasteric inhibition of protein kinases.

Chemical mechanism of the endogenous argininosuccinate lyase activity of duck lens delta2-crystallin.

The endogenous argininosuccinate lyase activity of duck delta2-crystallin was specifically inactivated by the histidine-specific reagent, diethyl pyrocarbonate. The protein was protected by l-citrulline or l-arginine from the diethyl pyrocarbonate inactivation. To characterize further the chemical mechanism of the delta2-crystallin-catalysed reaction, deuterium-labelled argininosuccinate was enzymically synthesized from fumarate and l-arginine with delta2-crystallin in 2H2O. The argininosuccinate synthesized contained about 19% of the anhydride form; however, the deuterium was clearly demonstrated to be incorporated enantioselectively. Only the pro-HR atom at C-9 of the succinate moiety was labelled in the [2H]argininosuccinate-9-d synthesized, which indicates an anti-elimination mechanism for the endogenous argininosuccinate lyase activity of delta2-crystallin. The enzymic activity of duck lens delta2-crystallin in the pH range 5.5-8.5 was investigated using both protium- and deuterium-labelled argininosuccinate as the substrate. From the logkcat versus pH plot, two molecular pKa values of 6.18+/-0.02 and 8.75+/-0.03 were detected in the delta2-crystallin-argininosuccinate binary complex. The former must be dehydronated and the latter hydronated to achieve an optimum reaction rate. The logkcat/Km versus pH plot suggested two molecular pKa values of 5.96+/-0.09 and 8.29+/-0.10 for the free delta2-crystallin to be involved in the substrate binding. Small kinetic isotope effects of 1.17+/-0.02 and 1.05+/-0.09 were found for kcat and kcat/Km respectively. Combining results from labelling and kinetic analysis indicates that the endogenous argininosuccinate lyase activity of duck delta2-crystallin is compatible with a stepwise E1cB mechanism, the rate-limiting step probably at the C-N bond-cleavage step.

Functional residues at the active site of bovine brain adenosine deaminase.

Brain adenosine deaminase was investigated in order to identify amino acid residues essential for its catalytic activity. The pH dependence of log Vmax shows that the enzyme activity depends on two ionizing groups with pK values of 5.4, that must be unprotonated, and 8.4, that must be protonated, for the catalysis. These same groups are observed in the Vmax/Km profiles. The plausible role of histidine residues at the active site of brain adenosine deaminase was proved by chemical modification with (DEP). The histidine specific reagent inactivated the enzyme following a pseudo first-order kinetics with a second-order rate constant of 8.9 10(-3) (+/- 1.8 10(-3)) M-1 min-1. The inhibition of the enzyme with PCMBS was studied monitoring the enzyme activity after incubation with the inhibitor. Brain adenosine deaminase exhibited a characteristic intrinsic tryptophan fluorescence with an emission peak centered at 335 nm. Stern-Volmer quenching parameters in the presence of acrylamide and iodide indicated that tryptophan residues are buried in the native molecule. Tryptophan residues also showed a high heterogeneity that was increased after binding of ground- and transition-state analogs to the enzyme.

Evidence for the essential histidine residues in geranylgeranyl transferase type I from bovine testis.

Geranylgeranyl transferase was purified 30,000-fold by sequential use of 30-50% ammonium sulfate fractionation, Q-Sepharose anion exchange chromatography, Phenyl Superose hydrophobic interaction chromatography, Sephacryl S-300 gel filtration chromatography, and peptide (YREKKFFCAIL) affinity chromatography. Geranylgeranyl transferase, when incubated with diethyl pyrocarbonate (DEPC), a histidine-specific reagent, shows time-dependent inactivation, and the activity is restored by the addition of neutral hydroxylamine. The inactivation follows pseudo-first order kinetics with a second order rate constant of 0.319 M-1min-1. The overall results thus provide evidence that a histidine residue in the active site is involved in the catalytic mechanism of the geranylgeranyl transferase reaction.

Histidine Modification of Human Serum Butyrylcholinesterase

The effects of histidine-modifying reagents on human serum butyrylcholinesterase (BChE) were investigated. The commercially available enzyme was further purified by chromatography on a Sepharose CI-6B column prior to use. In the modification studies, we found that the histidine-specific reagents tosylphenylalanine chloromethyl ketone (TPCK) and tosyllysine chloromethyl ketone (TLCK) did not modify the enzyme; however, they inhibited the enzyme reversibly. The kinetic parameters of enzyme inhibition calculated were α = 10.8, β = 0.26, andKi= 0.016 mmfor TPCK. TLCK inhibition gave similar kinetic behavior, with α = 41.6, β = 0.065, andKi= 0.039 mm. Tosyllysine, an analog of TLCK, did not inhibit the enzyme. Removal of TPCK and TLCK by dialysis resulted in significant reactivation of the enzyme. From kinetic studies, it was found that the inhibitions were hyperbolic mixed-type inhibitions. We concluded that the reagents competed with substrate for hydrophobic binding sites and inhibited the enzyme reversibly. On the other hand, in the modification studies with diethyl pyrocarbonate (DPC), it was observed that inactivation of the enzyme was irreversible and time-dependent. In the protection studies, the activity of the enzyme was partially protected from inactivation by DPC even at a 50 mmconcentration of butyrylthiocholine. The results indicate that DPC modifies some essential histidine side chains in BChE, including the functional histidyl residue found at the active site.

Affinity purification and characterization of protein gene product 9.5 (PGP9.5) from retina.

Protein gene product 9.5 (PGP9.5) is a cytosolic protein that is highly expressed in vertebrate neurons, which is now included in the ubiquitin C-terminal hydrolase subclass (UCH) on the basis of primary-structure homology and hydrolytic activity on the synthetic substrate ubiquitin ethyl ester (UbOEt). Some UCHs show affinity for immobilized ubiquitin, a property exploited to purify them. In this study we show that this property can also be applied to PGP9.5, since a protein has been purified to homogeneity from bovine retina by affinity chromatography on a ubiquitin-Sepharose column that can be identified with: (a) PGP9.5 with respect to molecular mass, primary structure and immunological reactivity; (b) the known UCHs with respect to some catalytic properties, such as hydrolytic activity on UbOEt, (which also characterizes PGP9.5), Km value and reactivity with cysteine and histidine-specific reagents. However, it differs with respect to other properties, e.g. inhibition by UbOEt and a wider pH range of activity.

Assembly of virus-like particles in insect cells infected with a baculovirus containing a modified coat protein gene of potato leafroll luteovirus.

DNA encoding the coat protein (P3) of a Scottish isolate of potato leafroll virus (PLRV) was inserted into the genome of Autographa californica nucleopolyhedrovirus (AcNPV) such that the coat protein was expressed either in an unmodified form or with the addition of the amino acid sequence MHHHHHHGDDDDKDAMG at the N terminus (P3-6H). Insect cells infected with these recombinant baculoviruses accumulated substantial amounts of P3 and P3-6H. P3 could not be recovered from cell extracts unless it was denatured in SDS but a proportion of the P3-6H was recoverable in a soluble form in non-denaturing conditions. Immunogold labelling of sections of infected cells showed that P3 accumulated in nuclei in large amorphous bodies. In contrast, although much of the P3-6H also accumulated in nuclei, it formed virus-like particles (VLP) which were often grouped in close-packed, almost cystalline arrays. When electron microscope grids coated with antibodies to PLRV were floated on cell extracts containing P3-6H, VLP were trapped which were indistinguishable from PLRV particles trapped from extracts of PLRV-infected plants. The VLP co- sedimented in sucrose gradients with PLRV particles which suggests that the VLP contained RNA. VLP collected from sucrose density gradient fractions contained protein which reacted with nickel chelated to nitrilotriacetic acid, a histidine-specific reagent. Cells infected with either recombinant baculovirus also synthesized a protein, with an Mr of about 17000, which was shown to be the translation product of the P4 gene which is in the +1 reading frame within the coat protein gene. This protein was also found in the nuclear fraction of infected cells but was more readily soluble than was P3.

P-17-5 - Regional cerebral perfusion by Tc-99m HMPAO SPECT before and after tacrine in alzheimer's disease

Microvillus membrane vesicles isolated from renal cortex have subsequently served as a useful model system for characterizing the kinetic and biochemical features of a Na+–H+ exchanger whose properties are largely representative of plasma membrane Na+–H+ exchangers in general. This chapter reviews studies on the molecular properties of the renal microvillus membrane Na+–H+ exchanger. Additional transport systems for the transfer of acids or bases exist in parallel with the Na+–H+ exchanger on the luminal membrane of proximal tubule cells. The chapter describes the kinetics of the renal Na+–H+ exchanger. As the imidazolium ring of histidine is the principal ionic group in proteins that is titratable at near-neutral pH values, in the study described in the chapter, this helped to evaluate the effect of histidine-specific reagents on the activity of the renal microvillus membrane Na+–H+ exchanger. The carboxyl-activating reagent N-ethoxycarbonyl-2-ethoxy- 1,2-dihydroquinoline (EEDQ) inhibits Na+–H + exchange in renal microvillus vesicles. Also, The observations that N,N'-dicyclohexyl-carbodiimide (DCCD) inactivates the renal Na+–H+ exchanger irreversibly and that amiloride protects against this inactivation suggested a strategy for covalently labeling the transport protein or one of its subunits. The renal Na+–H+ exchanger helps in facilitating anion transport by HCO−3 reabsorption, organic anion reabsorption, Cl− reabsorption, and anion transport and maintaining intracellular pH.

A Single Histidine Is Required for Activity of Cytochrome c Peroxidase from Paracoccus denitrificans

The diheme cytochrome c peroxidase from Paracoccus denitrificans was modified with the histidine-specific reagent diethyl pyrocarbonate. At low excess of reagent, 1 mol of histidine was modified in the oxidized enzyme, and modification was associated with loss of the ability to form the active state. With time, the modification reversed, and the ability to form the active state was recovered. The agreement between the spectrophotometric measurement of histidine modification and radioactive incorporation using a radiolabeled reagent indicated little modification of other amino acids. However, the reversal of histidine modification observed spectrophotometrically was not matched by loss of radioactivity, and we propose a slow transfer of the ethoxyformyl group to an unidentified amino acid. The presence of CN- bound to the active peroxidatic site of the enzyme led to complete protection of the essential histidine from modification. Limited subtilisin treatment of the native enzyme followed by tryptic digest of the C-terminal fragment (residues 251-338) showed that radioactivity was located in a peptide containing a single histidine at position 275. We propose that this conserved residue, in a highly conserved region, is central to the function of the active mixed-valence state.

Properties and chemical modification of D -amino acid oxidase from Trigonopsis variabilis

The basic properties of purified d-amino acid oxidase from the yeast Trigonopsis variabilis were investigated. The pH optimum of activity was between pH 8.5 and 9.0, and the native molecular masses of holo- and apo-enzyme were determined to be 170 kDa; higher aggregates corresponded to molecular masses of 320 and 570 kDa. The apparent Vmax and Km values for different substrates varied between 3.7 to 185 U/mg and 0.2 to 17.3 mM, respectively. The reaction of d-amino acid oxidase with sulfite was followed by the typical spectral modifications of the FAD resembling the reduced enzyme; a Kd of 30 μM was calculated for the N(5)-adduct. The red anionic flavin radical of the enzyme was stable; benzoate had no influence on the spectral properties. A complete loss of enzyme activity was observed after chemical modification by the histidine-specific reagent diethyl pyrocarbonate. The inactivation showed pseudo-first-order kinetics, with a second-order rate constant of 13.6 M–1 min–1 at pH 6.0 and 20°C. The addition of a substrate under anoxic conditions led to a substantial protection from inactivation, which indicates a localization of the modified residues close to the active site. The pKa of the reacting group was determined to be 7.7, and the rate of inactivation reached a limiting value of 0.031 min–1.

His257 is a uniquely important histidine residue for tetracycline/H+ antiport function but not mandatory for full activity of the transposon Tn10-encoded metal-tetracycline/H+ antiporter.

His257 is the only histidine residue located in the putative transmembrane region of the Tn10-encoded metal-tetracycline/H+ antiporter (TetA) and contributes to the substrate/H+ coupling [Yamaguchi, A.. Adachi, K., Akasaka. T., Ono. N., & Sawai, T. (1991) J. Biol. Chem. 266, 6045-6051]. Tn10-TetA contains five histidine residues, including His257. When these histidine residues were replaced by alanine one by one, only the His257Ala mutant showed almost complete loss of the tetracycline transport activity, whereas the other four His --> Ala mutants, H42A, H158A, H329A, and H359A, retained transport activity comparable to that of the wild type. The mutant which contains only one histidine, His257, retained about 80% of the wild-type activity, whereas the histidine-less mutant, in which all five histidine residues were replaced by Ala, exhibited little activity. These results clearly indicated that His257 is a unique histidine residue in TetA responsible for the transport activity. The His257Tyr mutant, irrespective of the presence or absence of the other four histidine residues, retained about 30% of the wild-type tetracycline transport activity and showed corresponding tetracycline-coupled H+ translocation, indicating that an imidazole group is not necessary at position 257 for the substrate/H+ coupling. A histidine-specific reagent, diethyl pyrocarbonate (DEPC), equally inactivated the wild-type and one-histidine mutant TetA, whereas the H257Y mutant was hardly inactivated by DEPC irrespective of the presence or absence of the other four histidine residues, indicating that the inactivation by DEPC is due to the modification of His257.

Inhibition of Mouse Erythroid Band 3-Mediated Chloride Transport by Site-Directed Mutagenesis of Histidine Residues and Its Reversal by Second Site Mutation of Lys 558, the Locus of Covalent H2DIDS Binding

Substitution by site-directed mutagenesis of any one of the histidine residues H721, H837, and H852 by glutamine, or of H752 by serine, inhibits Cl- flux mediated by band 3 expressed in Xenopus oocytes. Mutation of Lys 558 (K558N), the site of covalent binding of H2DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonate) in the outer membrane surface, in combination with any one of the His/Gln mutations leads to partial (H721Q; H837Q) or complete (H852Q) restoration of Cl- flux. In contrast, inhibition of Cl- flux by mutation of proline or lysine residues in the vicinity of His 837 at the inner membrane surface cannot be reversed by the second-site mutation K558N, indicating specificity of interaction between Lys 558 and His 837. The histidine-specific reagent diethyl pyrocarbonate (DEPC) is known to inhibit band 3-mediated anion exchange in red blood cells [Izuhara, K., Okubo, K., & Hamasaki, N. (1989) Biochemistry 28, 4725-4728]. It was also found to inhibit transport after expression in the oocyte of wild-type band 3, of the double mutants of the histidines listed above, and of the single mutant H752S. The effects on the wild type and the double mutants were indistinguishable, while the mutant H752S exhibited a considerably reduced sensitivity to inhibition, suggesting that His 752 is the most prominent site of action of DEPC. According to a hydrophobicity plot of band 3 and further independent evidence, Lys 558, the mutated histidines, and Glu 699, the mutation of which was also found to inhibit Cl- flux [Müller-Berger, S., Karbach, D., Kang, D., Aranibar, N., Wood, P. G., Rüterjans, H., & Passow, H. (1995) Biochemistry 34, 9325-9332], are most likely located in five different transmembrane helices. The interactions between Lys 558 and the various histidines suggest that these helices reside in close proximity. Together with the helix carrying Glu 699, they could form an access channel lined with an array of alternating histidine and glutamate residues. Together with a chloride ion bridging the gap between His 852 and His 837, they could have the potential to form, at low pH, a transmembrane chain of hydrogen bonds. The possible functional significance of such channel is discussed.