Interaction of soybean beta-amylase with glucose

The interaction of soybean beta-amylase with glucose was investigated by inhibition kinetics studies and spectroscopic measurements. The inhibition type, inhibitor constant (Ki) and dissociation constant (Kd) of beta-amylase-glucose complex were dependent on pH. At pH 8.0, glucose behaved as a competitive inhibitor (Ki = 34 mM). Binding of glucose produced a characteristic difference spectrum and a change of circular dichroism (CD) at pH 8.1. By using difference absorbance at 292 nm and difference ellipticity at 290 nm, Kd values for beta-amylase-glucose complex were determined to be 45 and 46 mM, respectively. In contrast to pH 8.0, glucose behaved as a mixed-type inhibitor (Ki = 320 mM) at pH 5.4. The Kd values obtained from the difference spectrum were increased by lowering the pH from 8. The pH dependence of the Ki and Kd values suggested that one ionizable group of pK = 8.0, which is shifted to 6.9 by the binding of glucose, controls the binding affinity of glucose. The binding of glucose competed with the binding of cyclohexaamylose and maltose at pH 8.0. The modification of SH groups of the enzyme affected the binding of glucose but did not affect the binding of maltose or cyclohexaamylose at pH 8.0. It was concluded from these results that the binding site of glucose is different from that of maltose and cyclohexaamylose. Presumably, glucose may bind to the subsite 1 of soybean beta-amylase.     

Difference spectroscopic study of the interaction between soybean beta-amylase and substrate or substrate analogues

1. In order to investigate the interactions between soybean beta-amylase [EC 3.2.1.2] and ligands (maltotriose as substrate, and maltose and alpha- and beta-cyclodextrins as inhibitors for the hydrolysis of maltoheptaose), the difference spectra were measured at 25 degrees C and pH 5.4, in 0.05 M acetate buffer. Each difference spectrum produced by these ligands showed a clear peak at 292-293 nm due to a tryptophan residue. In addition to this peak, the spectra of alpha- and beta-cyclodextrins showed a specific peak at 298-299 nm, and that of maltotriose showed a shoulder at 298 nm. 2. From the concentration dependency of the difference molar extinction delta epsilon, at 292-293 nm or at 298-299 nm, the dissociation constant of the enzyme-ligand complex, Kd, was evaluated for maltotriose, and alpha- and beta-cyclodextrins. For each ligand, the Kd values obtained at these two wavelengths were in good agreement with Michaelis constant, Km, or the inhibitor constant, Ki. The Kd value for maltose obtained from the titration of delta epsilon at 292 nm was also in good agreement with Ki. 3. Maltose produced a hydrophobic change in the environment of the tryptophan residue, while the interactions of maltotriose, and alpha- and beta-cyclodextrins with this enzyme caused an electrostatic change in the vicinity of the tryptophan residue in addition to the hydrophobic change. Since the signal at 298-299 nm was not found in the difference spectrum of maltose, this signal may be due to a tryptophan residue different from that which produces the signal at 292-293 nm. If both the signals are due to the same tryptophan residue, we must conclude that some conformational change is caused in the enzyme active site by the ligand binding.     

Regulation of hamster carbamoyl-phosphate synthase II by 5-phospho-alpha-D-ribosyl 1-diphosphate and uridine 5'-triphosphate

In mammals, carbamoyl phosphate for utilization in pyrimidine biosynthesis is synthesized by a glutamine-dependent carbamoyl-phosphate synthase II which is subject to regulation by 5-phospho-alpha-D-ribosyl 1-diphosphate (PRib-PP), a positive effector, and MgUTP, a negative effector [Mori, M., Ishida, H. and Tatibana, M. (1975) Biochemistry 14, 2622-2630]. We have found that Lineweaver-Burk plots of carbamoyl phosphate synthase activity versus 1/[MgATP] are described by a velocity equation which is a ratio of quadratic polynomials, consistent with a positive homotropic interaction between two catalytic sites for the binding of MgATP (Ks = 16.6 +/- 3.1 mM, interaction factor a = 0.00538 +/- 0.00245). The activating effect of PRib-PP upon carbamoyl-phosphate synthase is consistent with PRib-PP binding at an allosteric site (Ka = 31.4 +/- 6.4 microM) and promoting the binding of a first molecule of MgATP as substrate (interaction factor l = 0.0437 +/- 0.0063). Thus MgATP and PRib-PP bind to the E X MgATP complex with respective dissociation constants of a X Ks = 0.089 mM and l X Ka = 1.4 microM while MgATP binds to the E X PRib-PP complex with a dissociation constant of l X Ks = 0.73 mM. Data for the inhibitory effect of MgUTP upon carbamoyl-phosphate synthase indicate that MgUTP competes with MgATP for binding at the catalytic site (Ki = 0.203 +/- 0.016 mM). A computer model has recently been developed which enables quantitative stimulation of the time-dependent effects of blockade of the pyrimidine pathway by a tight-binding enzyme inhibitor [Duggleby, R.G. and Christopherson, R.I. (1984) Eur. J. Biochem. 143, 221-226]. The velocity equation derived in the present paper provides a quantitative basis for predicting changes in the flux through the de novo pyrimidine pathway in growing cells.     

The determination of subsite binding energies of porcine pancreatic alpha-amylase by comparing hydrolytic activity towards substrates

The active centre of porcine pancreatic alpha-amylase contains five subsites. Their occupancy has been studied using as a substrate maltooligosaccharide of various chain lengths (maltose up to maltoheptaose), some of their p- and o-nitrophenylated derivatives, and 412-residue amylose. Quantitative analysis of the digestion products allowed the determination of the subsite occupancy for the various productive complexes, the bond cleavage frequency and respective kcati (where i is the binding mode). The catalytic efficiency (kcat/Km) increases with chain length from maltose (2 M-1 X S-1) up to amylose (1.06 X 10(7) M-1 X S-1). The kinetic parameters of p-nitrophenylmaltoside hydrolysis are quite close to those of maltose, and the ortho compound behaves as maltotriose. Determination of binding energy of glucose residue at the various subsites calculated according to the method of Hiromi et al. (Hiromi, K., Nitta, Y., Numata, C. and Ono, S. (1973) Biochim. Biophys. Acta 302, 362-375) did not give consistent results. A method is proposed based on certain properties of porcine pancreatic alpha-amylase, especially the non-interaction of the p-nitrophenyl moiety of the maltose derivative with subsites 1 and 2, and the o-nitrophenyl group which interacts in a similar way to a glucose residue at the reducing end, and on the grounds that the amylase-amylose complexes are of the productive type. In addition, binding energy differences were calculated from substrates with the same chain length. The subsite energy profile is characterized by a low value at subsite 3 which confirms this subsite as the catalytic one. Another consequence is that the hydrolysis rate constant of productive complexes (kintn) (where n is the number of glucose or glucose equivalent residues for a given substrate) varies with chain length which is in conflict with the hypothesis of Hiromi et al.     

Kinetics of the hydrolysis of di- and trisaccharides with Aspergillus niger glucoamylases I and II

Near-homogeneous forms of glucoamylases I and II, previously purified from an industrial Aspergillus niger preparation, were used to hydrolyze a number of di- and trisaccharides linked by alpha-D-glucosidic bonds. Maximum rates and Michaelis constants were obtained at various temperatures and pH values with glucoamylase I for the disaccharides beta,alpha-trehalose, kojibiose, nigerose, maltose, and isomaltose and the trisaccharides panose and iso-maltotriose, and with glucoamylase II for maltose, maltotriose, and isomaltotriose. Maximum rates were highest and energies of activation were lowest for maltose, maltotriose, and panose, the only three substrates containing alpha-D-(1, 4)-glucosidic bonds. Michaelis constants were lowest and standard heats of binding were most negative for maltose and maltotriose. The variation of maximum rates and Michaelis constants with varying pH values suggested that two carboxyl groups were involved in substrate binding.     

Pre-steady-state uptake of D-glucose by the human erythrocyte is inconsistent with a circulating carrier mechanism

Simulation shows that the four-state mobile carrier model for sugar transport in which the asymmetry arises from unequal rate constants of inward and outward translation of the free-carrier and carrier-sugar complex, does not fit with the observed data for pre-steady-state uptake recently obtained by A.G. Lowe and A.R. Walmsley [1987) Biochim. Biophys. Acta 903, 547-550). The main reason for this discrepancy is that pre-steady-state fluxes are determined mainly by the dissociation constants Ks of glucose and maltose for the external sites, rather than the Km (zero-transoi) of glucose and the Ki of maltose. The data are also inconsistent with other forms of asymmetric carrier but are fairly consistent with a symmetrical carrier with high-affinity sites for D-glucose or with a fixed site carrier model.     

High-affinity maltose/trehalose transport system in the hyperthermophilic archaeon Thermococcus litoralis.

The hyperthermophilic marine archaeon Thermococcus litoralis exhibits high-affinity transport activity for maltose and trehalose at 85 degrees C. The K(m) for maltose transport was 22 nM, and that for trehalose was 17 nM. In cells that had been grown on peptone plus yeast extract, the Vmax for maltose uptake ranged from 3.2 to 7.5 nmol/min/mg of protein in different cell cultures. Cells grown in peptone without yeast extract did not show significant maltose or trehalose uptake. We found that the compound in yeast extract responsible for the induction of the maltose and trehalose transport system was trehalose. [14C]maltose uptake at 100 nM was not significantly inhibited by glucose, sucrose, or maltotriose at a 100 microM concentration but was completely inhibited by trehalose and maltose. The inhibitor constant, Ki, of trehalose for inhibiting maltose uptake was 21 nM. In contrast, the ability of maltose to inhibit the uptake of trehalose was not equally strong. With 20 nM [14C]trehalose as the substrate, a 10-fold excess of maltose was necessary to inhibit uptake to 50%. However, full inhibition was observed at 2 microM maltose. The detergent-solubilized membranes of trehalose-induced cells contained a high-affinity binding protein for maltose and trehalose, with an M(r) of 48,000, that exhibited the same substrate specificity as the transport system found in whole cells. We conclude that maltose and trehalose are transported by the same high-affinity membrane-associated system. This represents the first report on sugar transport in any hyperthermophilic archaeon.     

Kinetic studies with myo-inositol monophosphatase from bovine brain

The kinetic properties of myo-inositol monophosphatase with different substrates were examined with respect to inhibition by fluoride, activation or inhibition by metal ions, pH profiles, and solvent isotope effects. F- is a competitive inhibitor versus 2'-AMP and glycerol 2-phosphate, but noncompetitive (Kis = Kii) versus DL-inositol 1-phosphate, all with Ki values of approximately 45 microM. Activation by Mg2+ follows sigmoid kinetics with Hill constants around 1.9, and random binding of substrate and metal ion. At high concentrations, Mg2+ acts as an uncompetitive inhibitor (Ki = 4.0 mM with DL-inositol 1-phosphate at pH 8.0 and 37 degrees C). Activation and inhibition constants, and consequently the optimal concentration of Mg2+, vary considerably with substrate structure and pH. Uncompetitive inhibition by Li+ and Mg2+ is mutually exclusive, suggesting a common binding site. Lithium binding decreases at low pH with a pK value of 6.4, and at high pH with a pK of 8.9, whereas magnesium inhibition depends on deprotonation with a pK of 8.3. The pH dependence of V suggests that two groups with pK values around 6.5 have to be deprotonated for catalysis. Solvent isotope effects on V and V/Km are greater than 2 and 1, respectively, regardless of the substrate, and proton inventories are linear. These results are consistent with a model where low concentrations of Mg2+ activate the enzyme by stabilizing the pentacoordinate phosphate intermediate. Li+ as well as Mg2+ at inhibiting concentrations bind to an additional site in the enzyme-substrate complex. Hydrolysis of the phosphate ester is rate limiting and facilitated by acid-base catalysis.     

Purification, characterization, and subsite affinities of Thermoactinomyces vulgaris R-47 maltooligosaccharide-metabolizing enzyme homologous to glucoamylases

A maltooligosaccharide-metabolizing enzyme from Thermoactinomyces vulgaris R-47 (TGA) homologous to glucoamylases does not degrade starch efficiently unlike most glucoamylases such as fungal glucoamylases (Uotsu-Tomita et al., Appl. Microbiol. Biotechnol., 56, 465-473 (2001)). In this study, we purified and characterized TGA, and determined the subsite affinities of the enzyme. The optimal pH and temperature of the enzyme are 6.8 and 60 degrees C, respectively. Activity assays with 0.4% substrate showed that TGA was most active against maltotriose, but did not prefer soluble starch. Kinetic analysis using maltooligosaccharides ranging from maltose to maltoheptaose revealed that TGA has high catalytic efficiency for maltotriose and maltose. Based on the kinetics, subsite affinities were determined. The A1+A2 value of this enzyme was highly positive whereas A4-A6 values were negative and little affinity was detected at subsites 3 and 7. Thus, the subsite structure of TGA is different from that of any other GA. The results indicate that TGA is a metabolizing enzyme specific for small maltooligosaccharides.     

Inhibition of substrate binding to the adrenal cytochrome P450C-21 by acrylamide and its implications for solvent accessibility of the binding site in the microsomes

The present study offers evidence indicating that acrylamide, a highly polar molecule and an efficient quencher of tryptophanyl fluorescence, inhibits substrate binding to P450C-21 in bovine adrenocortical microsomes, in a competitive manner similar to that in the purified enzyme. Resolution of the fluorescence-quenching data revealed an acrylamide quenching constant (K2 = 9.9 M, that is, the association constant for the quencher-fluorophore complex) that was similar to the reciprocal of its inhibition constant (1/Ki = Ka = 8.3 +/- 0.9 M) for substrate binding. The substrate inhibited the fluorescence quenching by acrylamide as indicated by its concentration-dependent decrease in K2. The inhibition was in accordance with partial competition. These results are essentially similar to those previously observed in the purified lipid-free enzyme. In addition, the substrate dissociation, acrylamide inhibition, and fluorescence-quenching constants and the tryptophanyl fluorescence maximum (340-342 nm) were essentially the same in the microsomes and the lipid-free purified enzyme. These results indicate that the substrate-binding site of P450C-21 and the concerned tryptophan are accessible to the highly polar molecule in the microsomal membranes, similar to that in the lipid-free purified enzyme. This implies that the substrate-binding site is not shielded by lipids in such a way that only the substrate in the lipid phase can gain access to the binding site. This conclusion is consistent with the currently favored model, for membrane topology of mammalian P450 enzymes, in which P450 is anchored to the membrane through a short N-terminal sequence while the remaining portion of the molecule is exposed to polar environment.     

The interaction and inhibition of muscle lactate dehydrogenase by the alkaloid caffeine

Kinetic analysis showed that the alkaloid caffeine is a competitive inhibitor of the enzyme lactate dehydrogenase with respect to substrate pyruvate, and a non-competitive inhibitor with respect to the coenzyme NADH. The inhibitor constant Ki is 0,54 mM. Scatchard analysis determined the dissociation constant for a single independent binding site of the ternary lactate dehydrogenase - NADH - caffeine complex (KE-NADH-CAFFEINE) and the number of binding sites to be 0,14 mM and 3,83 respectively. Caffeine binds to a hydrophobic domain in the substrate binding site. Alternate nucleophilic - electrophilic functionalities within the inhibitor molecule are proposed to be the fundamental reason for the inhibition.     

Inhibitions of sugar transport produced by ligands binding at opposite sides of the membrane. Evidence for simultaneous occupation of the carrier by maltose and cytochalasin B

This study examines inhibitions of human erythrocyte D-glucose uptake at ice temperature produced by maltose and cytochalasin B. Maltose inhibits sugar uptake by binding at or close to the sugar influx site. Maltose is thus a competitive inhibitor of sugar uptake. Cytochalasin B inhibits sugar transport by binding at or close to the sugar efflux site and thus acts as a noncompetitive inhibitor of sugar uptake. When maltose is present in the uptake medium, Ki(app) for cytochalasin B inhibition of sugar uptake increases in a hyperbolic manner with increasing maltose. When cytochalasin B is present in the uptake medium, Ki(app) for maltose inhibition of sugar uptake increases in a hyperbolic manner with increasing cytochalasin B. High concentrations of cytochalasin B do not reverse the competitive inhibition of D-glucose uptake by maltose. These data demonstrate that maltose and cytochalasin B binding sites coexist within the glucose transporter. These results are inconsistent with the simple, alternating conformer carrier model in which maltose and cytochalasin B binding sites correspond to sugar influx and sugar efflux sites, respectively. The data are also incompatible with a modified alternating conformer carrier model in which the cytochalasin B binding site overlaps with but does not correspond to the sugar efflux site. We show that a glucose transport mechanism in which sugar influx and sugar efflux sites exist simultaneously is consistent with these observations.     

Crystal structures of beta-amylase from Bacillus cereus var mycoides in complexes with substrate analogs and affinity-labeling reagents

The crystal structures of beta-amylase from Bacillus cereus var. mycoides in complexes with five inhibitors were solved. The inhibitors used were three substrate analogs, i.e. glucose, maltose (product), and a synthesized compound, O-alpha-D-glucopyranosyl-(1-->4)-O-alpha-D-glucopyranosyl-(1-->4)-D-xylopyranose (GGX), and two affinity-labeling reagents with an epoxy alkyl group at the reducing end of glucose. For all inhibitors, one molecule was bound at the active site cleft and the non-reducing end glucose of the four inhibitors except GGX was located at subsite 1, accompanied by a large conformational change of the flexible loop (residues 93-97), which covered the bound inhibitor. In addition, another molecule of maltose or GGX was bound about 30 A away from the active site. A large movement of residues 330 and 331 around subsite 3 was also observed upon the binding of GGX at subsites 3 to 5. Two affinity-labeling reagents, alpha-EPG and alpha-EBG, were covalently bound to a catalytic residue (Glu-172). A substrate recognition mechanism for the beta-amylase was discussed based on the modes of binding of these inhibitors in the active site cleft.     

Kinetic studies on the interaction of eglin c with human leukocyte elastase and cathepsin G

We have investigated the inhibition of human leukocyte elastase and cathepsin G by recombinant Eglin c under near physiological conditions. The association rate constants k on of Eglin c for elastase and cathepsin G were 1.3 X 10(7) M-1 s-1 and 2 X 10(6) M-1 s-1, respectively. Under identical conditions, the k on for the association of human plasma alpha 1-proteinase inhibitor with the two leukocproteinases were 2.4 X 10(7) M-1 s-1 and 10(6) M-1 s-1, respectively. The consistency of these data could be verified using a set of competition experiments. The elastase-Eglin c interaction was studied in greater detail. The dissociation rate constant k off was determined by trapping of free elastase from an equilibrium mixture of elastase and Eglin c with alpha 1-proteinase inhibitor or alpha 2-macroglobulin. The rate of dissociation was very low (k off = 3.5 X 10(-5) s-1). The calculated equilibrium dissociation constant of the complex, Ki(calc) = k off/k on, was found to be 2.7 X 10(-12) M. Ki was also measured by adding elastase to mixtures of Eglin c and substrate and determining the steady-state rates of substrate hydrolysis. The Ki determined from these experiments (7.5 X 10(-11) M) was significantly higher than Ki(calc). This discrepancy might be explained by assuming that the interaction of Eglin c with elastase involves two steps: a fast binding reaction followed by a slow isomerization step. From the above kinetic constants it may be inferred that at a therapeutic concentration of 5 X 10(-7) M, Eglin c will inhibit leukocyte elastase in one second and will bind this enzyme in a "pseudo-irreversible" manner.     

The halide complexes of myeloperoxidase and the mechanism of the halogenation reactions

The spectral changes caused by the addition of halides to myeloperoxidase (donor:hydrogen-peroxide oxidoreductase, EC 1.11.1.7) have been investigated and the dissociation constants of the enzyme-halide complexes have been determined. The pH dependence of the dissociation constants suggests that halide binding is associated with a protonation step in myeloperoxidase. Myeloperoxidase catalyzes the peroxidative chlorination and bromination of monochlorodimedone. It is shown that at low pH, chloride acts as a competitive inhibitor with respect to H2O2, whereas at higher pH, H2O2 inhibits the chlorination reaction. The dissociation constant (Kd) of the spectroscopically detectable complex and the Km for chloride are considerably smaller than the inhibition constant (Ki) for chloride. These halogenation reactions are strongly pH dependent, the logarithm of the Km for chloride varies linearly with pH. The position of the pH optimum of the chlorination and bromination reaction is a linear function of the logarithm of the [halide]/[H2O2] ratio. A mechanism of the chlorination and bromination reaction is suggested with substrate inhibition for both hydrogen peroxide and the halide.     

Purification and substrate specificity of honeybee, Apis mellifera L., alpha-glucosidase III

Alpha-glucosidase III, which was different in substrate specificity from honeybee alpha-glucosidases I and II, was purified as an electrophoretically homogeneous protein from honeybees, by salting-out chromatography, DEAE-cellulose, DEAE-Sepharose CL-6B, Bio-Gel P-150, and CM-Toyopearl 650M column chromatographies. The enzyme preparation was confirmed to be a monomeric protein and a glycoprotein containing about 7.4% of carbohydrate. The molecular weight was estimated to approximately 68,000, and the optimum pH was 5.5. The substrate specificity of alpha-glucosidase III was kinetically investigated. The enzyme did not show unusual kinetics, such as the allosteric behaviors observed in alpha-glucosidases I and II, which are monomeric proteins. The enzyme was characterized by the ability to rapidly hydrolyze sucrose, phenyl alpha-glucoside, maltose, and maltotriose, and by extremely high Km for substrates, compared with those of alpha-glucosidases I and II. Especially, maltotriose was hydrolyzed over 3 times as rapidly as maltose. However, maltooligosaccharides of four or more in the degree of polymerization were slowly degraded. The relative rates of the k0 values for maltose, sucrose, p-nitrophenyl alpha-glucoside and maltotriose were estimated to be 100, 527, 281 and 364, and the Km values for these substrates, 11, 30, 13, and 10 mM, respectively. The subsite affinities (Ai's) in the active site were tentatively evaluated from the rate parameters for maltooligosaccharides. In this enzyme, it was peculiar that the Ai value at subsite 3 was larger than that of subsite 1.     

Protein ligand interactions:isoquinoline alkaloids as inhibitors for lactate and malate dehydrogenase

Kinetic analysis has shown that isoquinoline, papaverine and berberine act as reversible competitive inhibitors to muscle lactate dehydrogenase and mitochondrial malate dehydrogenase with respect to the coenzyme NADH. The inhibitor constants Ki vary from 7.5 microM and 12.6 microM berberine interaction with malate dehydrogenase and lactate dehydrogenase respectively to 91.4 microM and 196.4 microM with papaverine action on these two enzymes. Isoquinoline was a poor inhibitor with Ki values of 200 microM (MDH) to 425 microM (LDH). No inhibition was observed for both enzymes in terms of their respective second substrate (oxaloacetic acid - malate dehydrogenase; pyruvate - lactate dehydrogenase). A fluorimetric analysis of the binding of the three alkaloids show that the dissociation constants (Kd) for malate dehydrogenase are 2.8 microM (berberine), 46 microM (papaverine) and 86 microM (isoquinoline); the corresponding values for lactate dehydrogenase are 3.1 microM, 52 microM and 114 microM. In all cases the number of binding sites averaged at 2 (MDH) and 4 (LDH). The binding of the alkaloids takes place at sites close to the coenzyme binding site. No conformational non equivalence of subunits is evident.     

Identification of acceptor substrate binding subsites +2 and +3 in the amylomaltase from Thermus thermophilus HB8

Glycoside hydrolase family 77 (GH77) belongs to the alpha-amylase superfamily (Clan H) together with GH13 and GH70. GH77 enzymes are amylomaltases or 4-alpha-glucanotransferases, involved in maltose metabolism in microorganisms and in starch biosynthesis in plants. Here we characterized the amylomaltase from the hyperthermophilic bacterium Thermus thermophilus HB8 (Tt AMase). Site-directed mutagenesis of the active site residues (Asp293, nucleophile; Glu340, general acid/base catalyst; Asp395, transition state stabilizer) shows that GH77 Tt AMase and GH13 enzymes share the same catalytic machinery. Quantification of the enzyme's transglycosylation and hydrolytic activities revealed that Tt AMase is among the most efficient 4-alpha-glucanotransferases in the alpha-amylase superfamily. The active site contains at least seven substrate binding sites, subsites -2 and +3 favoring substrate binding and subsites -3 and +2 not, in contrast to several GH13 enzymes in which subsite +2 contributes to oligosaccharide binding. A model of a maltoheptaose (G7) substrate bound to the enzyme was used to probe the details of the interactions of the substrate with the protein at acceptor subsites +2 and +3 by site-directed mutagenesis. Substitution of the fully conserved Asp249 with a Ser in subsite +2 reduced the activity 23-fold (for G7 as a substrate) to 385-fold (for maltotriose). Similar mutations reduced the activity of alpha-amylases only up to 10-fold. Thus, the characteristics of acceptor subsite +2 represent a main difference between GH13 amylases and GH77 amylomaltases.     

Tight-binding inhibition of angiogenin and ribonuclease A by placental ribonuclease inhibitor

The dissociation rate constant of the angiogenin-placental ribonuclease inhibitor complex was determined by measuring the release of free angiogenin from the complex in the presence of scavenger for free placental ribonuclease inhibitor (PRI). In 0.1 M NaCl, pH 6, 25 degrees C, this value is 1.3 X 10(-7) s-1 (t1/2 congruent to 60 days). The Ki value for the binding of PRI to angiogenin, calculated from the association and dissociation rate constants, is 7.1 X 10(-16) M. The corresponding values for the interaction of RNase A with PRI, determined by similar means, are both considerably higher: the dissociation rate constant is 1.5 X 10(-5) s-1 (t1/2 = 13 h), and the Ki value is 4.4 X 10(-14) M. Thus, PRI binds about 60 times more tightly to angiogenin than to RNase A. The effect of increasing sodium chloride concentration on the binding of PRI to RNase A was explored by Henderson plots. The Ki value increases to 39 pM in 0.5 M NaCl and to 950 pM in 1 M NaCl, suggesting the importance of ionic interactions. The mode of inhibition of RNase A by PRI was determined by examining the effect of a competitive inhibitor of RNase A, cytidine 2'-phosphate, on the association rate of PRI with RNase A. Increasing concentrations of cytidine 2'-phosphate decrease the association rate in a manner consistent with a competitive mode of inhibition.     

Rigorous determination of the Hill coefficient of non-Michaelian substrate-inhibited enzymes

The Hill coefficient (n), the max. velocity (VM) and the dissociation constants of the competent enzyme-substrate complex (Ks) and of the inhibitory bindings of substrate to both pure enzyme (Kse) and to ES (Kses) can be determined using a particular property of the representative equation. Choosing successive pairs of substrate concns (Si, Sj) in such a way as Si.Sj = 1, and plotting Sj-1 versus Si-1 gives a family of straight lines whose slopes are: b = Ks.kses, i.e.b = Sm2n, independent of Si, Sj. Then: n = Lnb/2 LnSm, where Sm corresponds to vm, maximum value of v on the curve. All of the other parameters can be calculated from the value of n.