Anion transport in red blood cells and arginine-specific reagents: The location of [14C]Phenylglyoxal binding sites in the anion transport protein in the membrane of human red cells

The reaction of phenylglyoxal, a reagent specific for arginine residues, with erythrocyte membrane at pH 7.4 results in complete inhibition of sulfate equilibrium exchange across human red cells. The inactivation was found to be concentration and time depenent. The binding sites of this reagent in the anion transport protein (band 3) under these conditions were determined by using [¹⁴C]phenylglyoxal. The rate of incorporation of the radioactivity into band 3 gave a good correlation with the rate of inactivation. Under conditions where the transport is completely inhibited about 6 mol [¹⁴C]phenylglyoxal are incorporated into 1 mol band 3. Treating the [¹⁴C]phenylglyoxalated ghosts at different degrees of inactivation with extracellular chymotrypsin showed that about two-thirds of these binding sites are located on the 60 kDa fragment.     

Kinetics of the inactivation of Escherichia coli glutamate apodecarboxylase by phenylglyoxal.

The possible interaction of the phosphate moiety of pyridoxal phosphate with a guanidinium group in glutamate apodecarboxylase was investigated. The holoenzyme is not inactivated significantly by incubation with butanedione, glyoxal, methylglyoxal, or phenylglyoxal. However, the apoenzyme is inactivated by these arginine reagents in time-dependent processes. Phenylgloxal inactivates the apoenzyme most rapidly. The inactivation follows pseudo-first-order kinetics at high phenylglyoxal to apoenzyme ratios. The rate of inactivation is proportional to phenylglyoxal concentration, increases with increasing pH, and is also dependent on the type of buffer present. The rate of inactivation of the apoenzyme by phenylglyoxal is fastest in bicarbonate — carbonate buffer and increases with increasing bicarbonate — carbonate concentration. Phosphate, which inhibits the binding of pyridoxal phosphate to the apoenzyme, protects the apodecarboxylase against inactivation by phenylglyoxal. When the apodecarboxylase is inactivated with [¹⁴C]phenylglyoxal, approximately 1.6 mol of [¹⁴C]phenylglyoxal is incorporated per mol subunit. The phenylglyoxal is thought to modify an arginyl residue at or near the pyridoxal phosphate binding site of glutamate apodecarboxylase.     

Auxin binding to corn coleoptile membranes: Kinetics and specificity

Summary Detailed examination of binding over the range 10^-7–10^-6 M suggests that membrane preparations from coleoptiles of Zea mays L., cv Kelvedon 33 contain at least two sets of high affinity binding sites for 1-naphthylacetic acid (NAA), with dissociation constants of 1.8×10^-7 M (site 1) and 14.5×10^-7 M (site 2). Similar studies with 3-indolylacetic acid (IAA) also indicate two sets of binding sites, whose concentrations are closely comparable to those deduced for NAA. A substantial proportion of the total binding activity is retained in a detergent-solubilized preparation. Using [¹⁴C]NAA the interactions of a range of analogues with each of the binding sites have been examined with the aid of double reciprocal plots. The specificity of site 2 is compatible with that expected for an auxin receptor, in that only active auxins, antiauxin transport inhibitors are able to compete with [¹⁴C]NAA for the binding sites. Site 1 on the other hand is less specific, since it appears to bind all compounds tested, including physiologically inactive analogues.Abbreviations NAA 1-naphthylacetic acid - IAA 3-indolylacetic acid - 2,4-D 2,4-dichlorophenoxyacetic acid - 2,6-D 2,6-dichlorophenoxyacetic acid - 2,4,5-T 2,4,5-trichlorophenoxyacetic acid - 2-CPIB -(2-chlorophenoxy)-isobutyric acid - 2,4-B 2,4-dichlorobenzoic acid - 2,6-B 2,6-dichlorobenzoic acid - TIBA 2,3,5-triiodobenzoic acid - NPA 1-N-naphthylphthalamic acid     

Pigeon liver malic enzyme: Involvement of an arginyl residue at the binding site for malate and its analogs

Treatment of malic enzyme with arginine-specific reagents phenylglyoxal or 2,3-butanedione results in pseudo-first-order loss of oxidative decarboxylase activity. Inactivation by phenylglyoxal is completely prevented by saturating concentrations of NADP⁺, Mn²⁺, and substrate analog hydroxymalonate. Double log plots of pseudo-first-order rate constant versus concentration yield straight lines with identical slopes of unity for both reagents, suggesting that reaction of one molecule of reagent per active site is associated with activity loss. In parallel experiments, complete inactivation is accompanied by the incorporation of four [¹⁴C]phenylglyoxal molecules, and the loss of two arginyl residues per enzyme subunit, as determined by the colorimetric method of Yamasaki et al (R. B. Yamasaki, D. A. Shimer, and R. E. Feeney (1981) Anal. Biochem., 14, 220–226). These results confirm a 2:1 ratio for the reaction between phenylglyoxal and arginine (K. Takahashi (1968) J. Biol. Chem., 243, 6171–6179) and yield a stoichiometry of two arginine residues reacted per subunit for complete inactivation, of which one is essential for enzyme activity as determined by the statistical method of Tsou (C. L. Tsou (1962) Acta Biochim. Biophys. Sinica, 2, 203–211) and the Ray and Koshland analysis (W. J. Ray and D. E. Koshland (1961) J. Biol. Chem., 236, 1973–1979). Amino acid analysis of butanedione-modified enzyme also shows loss of arginyl residues, without significant decrease in other amino acids. Modification by phenylglyoxal does not significantly affect the affinity of this enzyme for NADPH. Binding of l-malate and its dicarboxylic acid analogs oxalate and tartronate is abolished upon modification, as is binding of the monocarboxylic acid α-hydroxybutyrate. The latter result indicates binding of the C-1 carboxyl group of the substrate to an arginyl residue on the enzyme.     

Demonstration of auxin binding to strawberry fruit membranes

Presence of specific auxin-binding sites in strawberry fruit (Fragaria ananassa Duch. cv. Ozark Beauty) membranes has been demonstrated. These 1-naphthaleneacetic acid (NAA)-binding sites in the 80,000g to 120,000g fraction of the strawberry fruit membrane were pronase sensitive with an estimated equilibrium dissociation constant for NAA of 1.1 × 10⁻⁶ molar. The minimum concentration of NAA required to stimulate strawberry fruit growth was at least one order of magnitude higher than the minimum concentration of NAA required to stimulate corn coleoptile elongation. This was consistent with the higher equilibrium dissociation constant (lower affinity) for auxin binding to strawberry fruit membranes than to corn coleoptiles. Twelve auxin analogs, ranging from very strong to weak auxins, were tested for abilities to stimulate in situ strawberry fruit growth and to bind (displace or compete with NAA) to strawberry fruit membranes. The observed positive correlation (r = 0.74) between the in vitro binding to the 80,000 to 120,000 membrane fraction and the in situ biological activity of these analogs indicated that the NAA-binding sites in strawberry fruit membranes may represent physiologically relevant auxin receptors.     

Auxin binding activities in monocotyledonous and dicotyledonous tissue

A screening study was carried out in order to investigate the binding of NAA to subcellular fractions from various dark grown monocotyledonous and dicotyledonous tissues known to be physiologically responsive to NAA. Napthalene-1-acetic acid (NAA) binding results revealed differences between the monocots and dicots. Maize coleoptile tissue gave the highest concentration of saturable binding sites with a K_d-value of 1.56 μM and another in maize mesocotyl with a K_d-value of 0.83 M indicating a single class of binding site for NAA for both tissues. However, an inability to demonstrate saturable auxin binding in dicotyledonous tissues and maize root tissues was found. It is concluded that the results of this investigation do not negate the hypothesis that the high affinity saturable binding sites found in maize shoot tissues may function as auxin receptors.     

Anion transport in red blood cells and arginine-specific reagents. Interaction between the substrate-binding site and the binding site of arginine-specific reagents

Phenylglyoxal is found to be a potent inhibitor of sulfate equilibrium exchange across the red blood cell membrane at both pH 7.4 and 8.0. The inactivation exhibits pseudo-first-order kinetics with a reaction order close to one at both pH 7.4 and 8. The rate constant of inactivation at 37 degrees C was found to be 0.12 min-1 at pH 7.4 and 0.19 min-1 at pH 8.0. Saturation kinetics are observed if the pseudo-first order rate constant of inhibition is measured as a function of phenylglyoxal concentration. Sulfate ions as well as chloride ions markedly decrease the rate of inactivation by phenylglyoxal at pH 7.4, suggesting that the modification occurs at or near to the binding site for chloride and sulfate. The decrease of the rate of inactivation produced at pH 8.0 by chloride ions is much higher than that produced by sulfate ions. Kinetic analysis of the protection experiments showed that the loaded transport site is unable to react with phenylglyoxal. From the data it is concluded that the modified amino acid(s) residues, presumably arginine, is (are) important for the binding of the substrate anion.     

Azido auxins: quantitative binding data in maize

The binding constants of three auxin analogs, 4-, 5-, and 6-azidoindole-3-acetic acid (4-, 5-, and 6-N₃IAA), and of the photoproducts of 5-N₃IAA to the naphthalene-1-acetic acid (NAA) binding sites of Zea mays L. WF9 × BR38 were determined to evaluate the potential of these analogs as photoaffinity labeling agents. We have found that 4- and 5-N₃IAA bind to these sites with affinities similar to that of IAA, while 6-N₃IAA and the photoproducts of 5-N₃IAA bind less tightly. This binding is fully reversible in the dark. Binding of 5-N₃IAA becomes covalent and irreversible upon UV irradiation, as evidenced by a 30% loss in NAA binding at sites pretreated with 5-N₃IAA and UV irradiation, then washed extensively. IAA or NAA, included with this 5-N₃IAA pretreatment, can protect the sites from blockage, whereas benzoic acid and tryptophan are unable to protect the site, indicating that 5-N₃IAA specifically labels the auxin sites.     

Reaction of neutral endopeptidase 24.11 (enkephalinase) with arginine reagents

The effect of the arginine-specific reagents phenylglyoxal and butanedione on the activity of neutral endopeptidase 24.11 ("enkephalinase") was determined. Inactivation of the enzyme by butanedione is completely protected by methionine-enkephalin, but only partially protected by methionine-enkephalinamide. In contrast, phenylglyoxal inactivation of the enzyme exhibits saturation kinetics with a Kd of 20 mM. The enzyme is only partially protected against phenylglyoxal inactivation by both methionine-enkephalin and its amide, indicating that phenylglyoxal reacts at two sites. Reaction of the enzyme with phenylglyoxal in the presence of saturating methionine-enkephalin involves the direct reaction of the reagent with the enzyme-substrate complex. Enzyme treated with butanedione or with phenylglyoxal (at site 1) exhibits a 3-5 decrease in substrate binding with little change in kcat. In contrast, reaction with phenylglyoxal in the presence of saturating methionine-enkephalin shows little change in substrate binding but a 4-fold decrease in kcat. Enzyme inactivation involves the incorporation of approximately 1 mol of phenylglyoxal/enzyme subunit in the absence of methionine-enkephalin and approximately 2.5 mol of phenylglyoxal/enzyme subunit in the presence of saturating methionine-enkephalin. These results suggest that an arginine residue on the enzyme is involved in substrate binding.     

In-vitro riboflavin binding and endogenous flavins in Phycomyces blakesleeanus

Several types of membrane-localized flavin binding sites were investigated in sporangiophores (spph) and mycelia of Phycomyces blakesleeanus. In-vitro binding of riboflavin, riboflavin-5′-phosphate, and flavin-adenine-dinucleotide was demonstrated with unfractionated membrane preparations by means of competition of [¹⁴C]riboflavin binding. Saturation of binding was only obtained with the highly water-soluble riboflavin-5′-phosphate, but by extrapolation it was shown that riboflavin showed the highest affinity towards the binding sites (K_D about 4·10^-6M). The number of binding sites was estimated to be 0.7 nmol g^-1 fresh-weight equivalent. Analysis of endogenous soluble flavin revealed that only riboflavin, riboflavin-5′-phosphate, and flavin-adenine-dinucleotide occurred in Phycomyces, and at a concentration of at least 1 nmol g^-1 fresh-weight equivalent in entire spph. Thus, the measured binding sites could reach saturation in-vivo. In the apical part of spph to which blue-light sensitivity is restricted, the amount of soluble flavin was three-fold higher. Exclusively in this zone, heat-labile riboflavin proteins were measured at a concentration of about 3 nmol g^-1 fresh-weight equivalent. The amount of covalently bound flavin was higher in spph tips than in intact spph (8 nmol and 3 nmol g^-1 fresh-weight equivalent, respectively). In either case, the concentrations of the flavin-membrane complexes were higher than the theoretical calculated concentration of (anisotropic) blue-light photoreceptor in Phycomyces (Bergman et al. 1969), and their involvement in blue-light photoreception is considered.     

Analysis of a calcium ion binding system composed of two different sites

Using murexide (Mx), a metallochromic indicator, and a dual wavelength spectrophotometer with a high signal-to-noise ratio, the Ca⁺⁺ binding in a system containing two classes of binding sites was studied. Solutions with solute containing one or two classes of Ca⁺⁺ binding sites and without such solute were titrated with Ca⁺⁺ using Mx as an indicator of free Ca⁺⁺ concentration. Since curvilinear Scatchard plots are obtained from titration curves of solutes containing two classes of binding sites, a computer program was developed to resolve such plots into two linear partial plots, each corresponding to a single class of binding site. The validity of the procedure was examined with solutions of ethylene glycol bis(β-aminoethyl)-N-N′-tetraacetic acid, adenosine triphosphate (EGTA, ATP), or a mixture thereof. The method was also applied to biological material and it was found that a protein fraction isolated from rat skeletal muscle sarcotubular membranes, termed Fraction-2 (Fr-2), has two classes of binding sites for Ca⁺⁺; the association constants of the high affinity site and low affinity site are 4.3 × 10⁵ M^-1 and 9 × 10³ M^-1, respectively. The advantages and limitations of this methodology are discussed.     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. II. Co-operativity and specificity of binding site II.

The following properties characterize the interaction of nucleic acid binding site II of Escherichia coli ribosomal protein S1 with oligo- and polyribonucleotides; all have been determined with site I complexed with oligo- or polydeoxyribonucleotides. (1) The intrinsic binding constant (K) of site II to single-stranded polyribonucleotides is fairly independent of base composition, though cytidinecontaining polymers bind with approximately threefold higher intrinsic affinities than do the comparable adenine-containing species. (2) Poly(rC) is bound to site II co-operatively; the co-operativity parameter (ω) ? 31. Poly(rA) shows no binding co-operativity. The site size (n) for both polyribonucleotides binding at site II is about ten nucleotide residues. (3) The K value for site II is ? 4 × 10⁵m^?1 for poly(rA), and ? 1 × 10⁶m^?1 for poly(rC), in 0.12 m-Na⁺. Unlike site I, the binding affinity of site II increases somewhat with increasing salt concentration, suggesting that phosphate—basic protein residue contacts are not involved. (4) Varying Mg^{2 +} concentration has no effect on K, and changes in the concentration of either Mg²⁺ or Na⁺ do not affect the magnitude of site II co-operativity. (5) Reaction of the exocyclic amino groups of poly (rC) with formaldehyde drastically reduces the affinity of site II for this polynucleotide, while the affinity of poly (rC) for site I is not altered by this treatment. (6) No major sequence specificity of K for site II is found with either homogeneous polynucleotides or the 3′ terminal dodecanucleotide of 16 S ribosomal RNA; we conclude that selectivity of S1 binding via site II depends largely on the presence or absence of base compositiondependent binding co-operativity.The binding properties of site II probably account for the ability of S1 to inhibit translation at high S1 to ribosome ratios (“factor i” activity). Possible mechanisms for the role of S1 protein as a part of the phage Qβ replicase complex and in protein synthesis are discussed in relation to the binding properties of site I and site II.     

An adenosine 3':5'-monophosphate-adenosine binding protein from mouse liver. Factors affecting the activation of the binding protein by adenosine 5'-triphosphate.

A cyclic AMP-adenosine binding protein, whose binding sites are activated by preincubation in the presence of Mg⁺-ATP, has been purified to apparent homogeneity from mouse liver (P.M. Ueland and S.O. Døskeland, 1977, J. Biol. Chem.,252, 677–686). The degree of activation of both the cyclic AMP binding site and a high-affinity site for adenosine depends on the concentration of ATP during the preincubation. The velocity and the degree of activation are dependent on the temperature and the presence of Mg²⁺ and K⁺. The NH₄⁺ ion can be substituted for K⁺, whereas Na⁺ is inefficient. Low pH promotes the conversion from the inactive to the active form. The apparent affinity for adenosine to the high-affinity site for this adenine derivative and the affinity for cyclic AMP to the site specific for this nucleotide are independent of the degree of activation as judged from the slope of Scatchard plots. The activation of the cyclic AMP binding site by ATP (6 mm) was determined at pH 7 in the presence of 10 μm cyclic AMP, AMP, ADP, or adenosine. Adenosine specifically inhibits the activation and does not promote the inactivation of the binding protein. The possibility that the apparent inhibition of activation was effected by interference with cyclic AMP binding by adenosine was ruled out.     

Affinity labels for auxin binding sites in corn coleoptile membranes

Two auxin analogues have been tested as affinity labels for auxin binding sites in coleoptile membranes of Zea mays L. Reacting the membranes at pH 8–9 with the diazonium salt of CAPA (2-chloro-4-aminophenoxyacetic acid) reduces their subsequent ability to bind NAA(1-naphthylacetic acid). Diazo-Chloramben (2,5-dichloro-3-aminobenzoic acid) is also effective in inhibiting NAA binding capacity and this inhibition is largely independent of reaction pH over the range pH 6–9. Similar experiments with sulphydryl reagents have shown that reaction of the membranes with p-mercuribenzoate (PMB) strongly inhibits subsequent auxin binding activity. Prior addition of NAA protects the binding sites against the action of diazo-Chloramben or PMB when the reactions are carried out at pH 6. From these results and from other considerations, several of the amino acid residues in the binding site environment have been tentatively assigned.Abbreviations CAPA 2-chloro-4-aminophenoxyacetic acid - DTNB 5,5-dithiobis (2-nitrobenzoic acid) - DTT dithiothreitol - GSH reduced from of glutathione - NAA 1-naphthylacetic acid - PMB p-mercurbenzoate     

Bisulfite interacts with binding sites of the auxin-transport inhibitor N-1-naphthylphthalamic acid

The affinity of the auxin-transport inhibitor N-1-naphthylphthalamic acid (NPA) for membrane particles as well as for solubilized binding sites from Cucurbita pepo L. hypocotyls was reduced by low concentrations of bisulfite (half-maximal inhibition at 2·10^-3–3·10^-3 M). Two membrane fractions obtained by sedimentation aided with polyethylene glycol showed differential sensitivity to bisulfite. Other oxidizing or reducing substances tested at 1 mM had no effect, except for N-ethylmaleimide (80% inhibition) and iodine (complete inhibition), both of which reduced the number of binding sites but not their affinity. Addition of bisulfite to either the isoalloxane ring of flavoproteins or to pyridoxal phosphate or quinones is proposed as a possible mechanism of action. Sulfur dioxide, at concentrations measured in polluted air, can lead to bisulfite concentrations in plant tissue sufficient to interfere with NPA-binding sites and hence with auxin transport.Abbreviations DTE dithioerythritol - DTT dithiothreitol - IC₅₀ concentration of half-maximal inhibition - NAA 1-naphthylacetic acid - NEM N-ethylmaleimide - NPA N-1-naphthylphthalamic acid - PEG polyethylene glycol, 6000 molecular weight     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. I. Structure and interactions of binding site I.

Escherichia coli ribosomal protein S1 plays a central role in initiation of protein synthesis, perhaps via participation in the binding of messenger RNA to the ribosome. S1 protein has two nucleic acid binding sites with very different properties: site I binds either single-stranded DNA or RNA, while site II binds single-stranded RNA only (Draper et al., 1977). The nucleic acid binding properties of these sites have been explored using the quenching of intrinsic protein fluorescence which results from binding of oligo- and polynucleotides, and are reported in this and the accompanying paper (Draper &; von Hippel, 1978).Site I has been studied primarily using DNA oligomers and polymers, and has been found to have the following properties. (1) The intrinsic binding constant (K) of site I for poly(dA) and poly(dC) is ~3 × 10⁶m^?1 at 0.12 m-Na⁺, and the site size (n, the number of nucleotide residues covered per S1 bound) is 5.1 ± 1.0 residues. (2) Binding of site I to polynucleotides is non-co-operative. (3) The K value for binding of S1 to single-stranded polynucleotides is ~10³ larger than K for binding to double-stranded polynucleotides, meaning that S1 (via site I) is a potential “melting” or “double-helix destabilizing” protein. (4) The dependence of log K on log [Na⁺] is linear, and analysis of the data according to Record et al. (1976) shows that two basic residues in site I form charge-charge interactions with two DNA phosphates. In addition, a major part of the binding free energy of site I with the nucleic acid chain appears to involve non-electrostatic interactions. (5) Oligonucleotides bound in site II somewhat weaken the binding affinity of site I. (6) Binding affin is virtually independent of base and sugar composition of the nucleic acid ligand; in fact, the total absence of the base appears to have little effect on the binding, since the association constant for 2′-deoxyribose 5′-phosphate is approximately the same as that for dAMP or dCMP. (7) Two molecules of d(ApA) can bind to site I, suggesting the presence of two “subsites” within site I. (8) Iodide quenching experiments with S1-oligonucleotide complexes show differential exposure of tryptophans in and near the subsites of site I, depending upon whether neither, one, or both subsites are complexed with an oligonucleotide.     

A single functional arginyl residue involved in the catalysis promoted by Lactobacillus casei thymidylate synthetase

The inactivation of Lactobacillus casei thymidylate synthetase by phenylglyoxal occurs by a pseudo-first-order, pH-dependent process which is 100-fold faster at pH 8.4 than at pH 7.4. The second-order rate constant for inactivation at pH 7.4 is 32 m^?1 min^?1. Although four or more arginyl residues of the 24 arginines per enzyme dimer can be modified, as determined by amino acid analysis or [2-¹⁴C]phenylglyoxal incorporation, only one arginine appears to be essential for activity. The association of this arginine with the catalytic process is supported by the finding that 2′-deoxyuridylate not only protects it from modification by phenylglyoxal, but in so doing prevents the enzyme from losing activity. Additional support is derived from the fact that the product of the reaction, 2′-deoxythymidylate, a competitive inhibitor of 2′-deoxyuridylate, also protects the enzyme, but 2′-deoxycytidylate and uridylate do not. Neither the enzyme's second substrate, 5,10-CH₂H₄folate nor the folylpolyglutamates protect the enzyme from inactivation by phenyglyoxal. These findings contrast with those recently reported by Cipollo and Dunlap (Biochemistry18, 5537, 1979), which indicate that the inactivation is associated with the modification of 4 arginines per mole of enzyme, 2 of which are protected by 2′-deoxyuridylate. The requirement for a single arginine in the catalytic process is consistent with the involvement of one essential cysteine (Noonan et al., Arch. Biochem. Biophys.184, 336, 1977, both amino acids apparently participating in the binding of 1 mol of 2′-deoxyuridylate per enzyme dimer. These findings suggest that the synthetase's two identical subunits function asymmetrically and that 2′-deoxyuridylate binds as a dianion.     

In vitro auxin binding to cellular membranes of cucumber fruits

Specific binding of 1-naphthaleneacetic acid (NAA) to crude membrane preparations from cucumber (Cucumis sativus L.) was demonstrated. This in vitro binding had a pH optimum of 3.75 and an equilibrium dissociation constant of 10 to 20 micromolar with 1250 picomoles binding sites per gram fresh weight. The NAA-binding sites were pronase sensitive. The supernatant from the fruit partially inhibited the in vitro NAA binding to fruit membranes. NAA, 2-naphthoxyacetic acid, 3-indoleacetic acid, 2-4-dichlorophenoxyacetic acid, and 2,3,5-triiodobenzoic acid, which are reported to be very good inducers of parthenocarpy in cucumber, showed a high degree of specific binding to cucumber fruit membranes. In comparison, 2-naphthaleneacetic acid and indolepropionic acid, which are reported to be very weak auxins in corn coleoptile, pea stem, and strawberry fruit growth bioassays, did not bind efficiently to cucumber fruit membranes. In vitro binding studies with fruit membranes suggest that auxin stimulated fruit growth may be mediated by membrane-associated, auxin-binding protein(s).     

Involvement of arginine residues in the allosteric activation and inhibition ofSynechocystis PCC 6803 ADPglucose pyrophosphorylase

ADPglucose pyrophosphorylase (EC 2.7.7.27) from the cyanobacteriumSynechocystis PCC 6803 was desensitized to the effects of allosteric ligands by treatment with the arginine reagent, phenylglyoxal. Enzyme modification by phenylglyoxal resulted in inactivation when the enzyme was assayed under 3P-glycerate-activated conditions. There was little loss of the catalytic activity assayed in the absence of activator. Pi, 3P-glycerate, and pyridoxal-P were able to protect the enzyme from inactivation, whereas substrates gave minimal protection. The protective effect exhibited by Pi and 3P-glycerate was dependent on effector concentration. MgCl₂ enhanced the protection afforded by 3P-glycerate. The enzyme partially modified by phenylglyoxal was more resistant to 3P-glycerate activation and Pi inhibition than the unmodified form.V _max at saturating 3P-glycerate concentrations and the apparent affinity of the enzyme toward Pi were decreased upon phenylglyoxal modification. Incorporation of labeled phenylglyoxal into the enzyme was proportional to the loss of activity. Pi and 3P-glycerate nearly completely prevented incorporation of the reagent to the protein. Results suggest that one arginine residue per mol of enzyme subunit is involved in the binding of allosteric effector in the cyanobacterial ADPglucose pyrophosphorylase.