Association Rate Constants For Binding Research Articles

Cyclic AMP- and (Rp)-cAMPS-induced Conformational Changes in a Complex of the Catalytic and Regulatory (RIα) Subunits of Cyclic AMP-dependent Protein Kinase

We took a discovery approach to explore the actions of cAMP and two of its analogs, one a cAMP mimic ((S(p))-adenosine cyclic 3':5'-monophosphorothioate ((S(p))-cAMPS)) and the other a diastereoisomeric antagonist ((R(p))-cAMPS), on a model system of the type Iα cyclic AMP-dependent protein kinase holoenzyme, RIα(91-244)·C-subunit, by using fluorescence spectroscopy and amide H/(2)H exchange mass spectrometry. Specifically, for the fluorescence experiments, fluorescein maleimide was conjugated to three cysteine single residue substitution mutants, R92C, T104C, and R239C, of RIα(91-244), and the effects of cAMP, (S(p))-cAMPS, and (R(p))-cAMPS on the kinetics of R-C binding and the time-resolved anisotropy of the reporter group at each conjugation site were measured. For the amide exchange experiments, ESI-TOF mass spectrometry with pepsin proteolytic fragmentation was used to assess the effects of (R(p))-cAMPS on amide exchange of the RIα(91-244)·C-subunit complex. We found that cAMP and its mimic perturbed at least parts of the C-subunit interaction Sites 2 and 3 but probably not Site 1 via reduced interactions of the linker region and αC of RIα(91-244). Surprisingly, (R(p))-cAMPS not only increased the affinity of RIα(91-244) toward the C-subunit by 5-fold but also produced long range effects that propagated through both the C- and R-subunits to produce limited unfolding and/or enhanced conformational flexibility. This combination of effects is consistent with (R(p))-cAMPS acting by enhancing the internal entropy of the R·C complex. Finally, the (R(p))-cAMPS-induced increase in affinity of RIα(91-244) toward the C-subunit indicates that (R(p))-cAMPS is better described as an inverse agonist because it decreases the fractional dissociation of the cyclic AMP-dependent protein kinase holoenzyme and in turn its basal activity.

Nature of the displaceable heme-axial residue in the EcDos protein, a heme-based sensor from Escherichia coli.

The EcDos protein belongs to a group of heme-based sensors that detect their ligands with a heme-binding PAS domain. Among these various heme-PAS proteins, EcDos is unique in having its heme iron coordinated at both axial positions to residues of the protein. To achieve its high affinities for ligands, one of the axial heme-iron residues in EcDos must be readily displaceable. Here we present evidence from mutagenesis, ligand-binding measurements, and magnetic circular dichroism, resonance Raman, and electron paramagnetic resonance spectroscopies about the nature of the displaceable residue in the heme-PAS domain of EcDos, i.e., EcDosH. The magnetic circular dichroism spectra in the near-infrared region establish histidine-methionine coordination in met-EcDos. To determine whether in deoxy-EcDos coordination of the sixth axial position is also to methionine, methionine 95 was substituted with isoleucine. This substitution caused the ferrous heme iron to change from an exclusively hexacoordinate low-spin form (EcDosH) to an exclusively pentacoordinate high-spin form (M95I EcDosH). This was accompanied by a modest acceleration of the dissociation rates of ligands but a dramatic increase (60-1300-fold) in the association rate constants for binding of O(2), CO, and NO. As a result, the affinity for O(2) was enhanced 10-fold in M95I EcDosH, but the partition constant M = [K(d)(O(2))/K(d)(CO)] between CO and O(2) was raised to about 30 from the extraordinarily low EcDosH value of 1. Thus a major consequence of the increased O(2) affinity of this sensor was the loss of its unusually strong ligand discrimination.

Dos, a heme-binding PAS protein from Escherichia coli, is a direct oxygen sensor.

A direct sensor of O(2), the Dos protein, has been found in Escherichia coli. Previously, the only biological sensors known to respond to O(2) by direct and reversible binding were the FixL proteins of Rhizobia. A heme-binding region in Dos is 60% homologous to the O(2)-sensing PAS domain of the FixL protein, but the remainder of Dos does not resemble FixL. Specifically, the C-terminal domain of Dos, presumed to be a regulatory partner that couples to its heme-binding domain, is not a histidine kinase but more closely resembles a phosphodiesterase. The absorption spectra of Dos indicate that both axial positions of the heme iron are coordinated to side chains of the protein. Nevertheless, O(2) and CO bind to Dos with K(d) values of 13 and 10 microM, respectively, indicating a strong discrimination against CO binding. Association rate constants for binding of O(2) (3 mM(-)(1) s(-)(1)), CO (1 mM(-)(1) s(-)(1)) and even NO (2 mM(-)(1) s(-)(1)) are extraordinarily low and very similar. Displacement of an endogenous ligand, probably Met 95, from the heme iron in Dos triggers a conformational change that alters the activity of the enzymatic domain. This sensing mechanism differs from that of FixL but resembles that of the CO sensor CooA of Rhodospirillum rubrum. Overall the results provide evidence for a heme-binding subgroup of PAS-domain proteins whose working range, signaling mechanisms, and regulatory partners can vary considerably.

Binding and Hydrolysis of TNP-ATP by Escherichia coli F1-ATPase

It had previously been suggested that Vmax hydrolysis rate of 2', 3'-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate (TNP-ATP) by F1-ATPase required filling of only two catalytic sites on the enzyme (Grubmeyer, C., and Penefsky, H. S. (1981) J. Biol. Chem. 256, 3718-3727), whereas recently it was shown that Vmax rate of ATP hydrolysis requires that all three catalytic sites are filled (Weber, J., Wilke-Mounts, S., Lee, R. S. F., Grell, E., and Senior, A. E. (1993) J. Biol. Chem. 268, 20126-20133). To resolve this apparent discrepancy, we measured equilibrium binding and hydrolysis of MgTNP-ATP under identical conditions, using betaY331W mutant Escherichia coli F1-ATPase, in which the genetically engineered tryptophan provides a direct fluorescent probe of catalytic site occupancy. We found that MgTNP-ATP hydrolysis at Vmax rate did require filling of all three catalytic sites, but in contrast to the situation with MgATP, "bisite hydrolysis" of MgTNP-ATP amounted to a substantial fraction (approximately 40%) of Vmax. Binding of MgTNP-ATP to the three catalytic sites showed strong binding cooperativity (Kd1 < 1 nm, Kd2 = 23 nm, Kd3 = 1.4 microM). Free TNP-ATP (i.e. in presence of EDTA) bound to all three catalytic sites with lower affinity but was not hydrolyzed. These data emphasize that the presence of Mg2+ is critical for cooperativity of substrate binding, formation of the very high affinity first catalytic site, and hydrolytic activity in F1-ATPases and that these three properties are strongly correlated.

Differential changes in the association and dissociation rate constants for binding of cystatins to target proteinases occurring on N-terminal truncation of the inhibitors indicate that the interaction mechanism varies with different enzymes

The importance of the N-terminal region of human cystatin C or chicken cystatin for the kinetics of interactions of the inhibitors with four cysteine proteinases was characterized. The association rate constants for the binding of recombinant human cystatin C to papain, ficin, actinidin and recombinant rat cathepsin B were 1.1 x 10(7), 7.0 x 10(6), 2.4 x 10(6) and 1.4 x 10(6) M-1.s-1, whereas the corresponding dissociation rate constants were 1.3 x 10(-7), 9.2 x 10(-6), 4.6 x 10(-2) and 3.5 x 10(-4) s-1. N-Terminal truncation of the first ten residues of the inhibitor negligibly affected the association rate constant with papain or ficin, but increased the dissociation rate constant approx. 3 x 10(4)- to 2 x 10(6)-fold. In contrast, such truncation decreased the association rate constant with cathepsin B approx. 60-fold, while minimally affecting the dissociation rate constant. With actinidin, the truncated cystatin C had both an approx. 15-fold lower association rate constant and an approx. 15-fold higher dissociation rate constant than the intact inhibitor. Similar results were obtained for intact and N-terminally truncated chicken cystatin. The decreased affinity of human cystatin C or chicken cystatin for cysteine proteinases after removal of the N-terminal region is thus due to either a decreased association rate constant or an increased dissociation rate constant, or both, depending on the enzyme. This behaviour indicates that the contribution of the N-terminal segment of the two inhibitors to the interaction mechanism varies with the target proteinase as a result of structural differences in the active-site region of the enzyme.

Complexes formed by complementary RNA stem-loops: Their formations, structures and interaction with ColE1 Rom protein

Regulation of replication of plasmid ColEl involves interaction of two plasmid-specified RNA transcripts. One of these RNAs (RNA II) serves as a primer for DNA synthesis, and the other (RNA I) is complementary to part of RNA II. The complementary regions of RNA I and RNA II form several stem-loop structures. Binding of these RNAs that regulates DNA replication begins by interaction at the loop regions. Plasmid-coded Rom protein stabilizes the product of the interaction. In this paper, the mechanism of the loop-to-loop interaction between pairs of RNA stem-loops having various nucleotide sequences is studied. Binding of two stem-loops containing six to eight nucleotides in their loops requires that the loop sequences be complementary, whereas the stem sequences need not be. The association rate constants for binding of complementary pairs with various sequences are relatively similar, around 1 × 10 6 M −1 S −1. On the other hand, the rates of dissociation of the complexes vary greatly depending on the loop sequence, even for complexes having the same base composition, suggesting a strong effect of base-stacking. All the complementary bases in the seven-nucleotide loops participate in complex formation, and the resulting complex is bent a little at the interacting region. Rom binds and stabilizes any complex formed by pairs containing fully complementary loop sequences. Structures are proposed for the RNA complexes with and without Rom.

The role of Val68(E11) in ligand binding to sperm whale myoglobin. Site-directed mutagenesis of a synthetic gene.

Site-directed mutants of sperm whale myoglobin were prepared to probe the functional role of the highly conserved distal pocket valine residue, Val68(E11). This amino acid was replaced with Ala, Ile, and Phe to examine the effects of the side chain volume at position 68 on ligand binding. Three double mutants were also constructed in which the distal His64(E7) was replaced with Gly and Val68 was replaced with Ala, Ile, and Phe to determine the effects of size at position 68 in the absence of the distal histidine. Association and dissociation rate constants for O2, CO, and alkyl isocyanide binding were measured by stopped-flow rapid mixing, conventional flash, and laser photolysis techniques at pH 7, 20 degrees C. The association rate constants for the binding of all eight ligands to the single mutants decreased in the order Ala68 greater than Val68 (native) greater than Ile68 myoglobin, indicating that the 68(E11) residue is part of the overall kinetic barrier. A similar pattern was observed for the association constants of the double mutants: Gly64/Ala68 greater than Gly64/Val68 greater than Gly64/Ile68. Thus, increasing size of the E11 side chain inhibits the rate of ligand binding even in the absence of histidine at position 64. Substitution of Ala for Val68 had little effect on O2 affinity but did increase the affinities for CO and isocyanide binding. The affinities for all of the ligands were decreased for the Ile68 mutant. The ligand binding affinities for the Gly64/Ala68, Gly64/Val68, and Gly64/Ile68 myoglobins displayed an analogous trend to that of the single mutants, indicating that the equilibrium interactions between the position 64 and 68 side chains and the bound ligand are roughly additive. Both the association rate constants and dissociation rate constants for O2 and isocyanide binding were decreased for the Phe68 mutant myoglobin. These kinetic parameters result in little change in O2 affinity and an increase in isocyanide affinity, relative to the native protein. Thus, the large benzyl side chain of phenylalanine at position 68 inhibits the rate of ligand movement up to and away from the iron atom but not the final bound state.

The effects of E7 and E11 mutations on the kinetics of ligand binding to R state human hemoglobin

Association and dissociation rate constants for O2, CO, and methyl isocyanide binding to native and distal pocket mutants of R state human hemoglobin were measured using ligand displacement and partial photolysis techniques. Individual rate constants for the alpha and beta subunits were resolved by comparisons between the kinetic behavior of the native and mutant proteins. His-E7 was replaced with Gly and Gln in both alpha and beta subunits and with Phe in beta subunits alone. In separate experiments Val-E11 was replaced with Ala, Leu, and Ile in each globin chain. The parameters describing ligand binding to R state alpha subunits are sensitive to the size and polarity of the amino acids at positions E7 and E11. The distal histidine in this subunit inhibits the bimolecular rate of binding of both O2 and CO, sterically hinders bound CO and methyl isocyanide, and stabilizes bound O2 by hydrogen bonding. The Val-E11 side chain in alpha chains also appears to be part of the kinetic barrier to O2 and CO binding since substitution with Ala causes approximately 10-fold increases in the association rate constants for the binding of these diatomic ligands. However, substitution of Val-E11 by Ile produces only small decreases in the rates of ligand binding to alpha subunits. For R state beta subunits, the bimolecular rates of O2 and CO binding are intrinsically large, approximately 2-5-fold greater than those for alpha subunits, and with the exception of Val-E11----Ile mutation, little affected by substitutions at either the E7 or E11 positions. For the beta Val-E11----Ile mutant the association rate and equilibrium constants for all three ligands decreased 10-50-fold. All of these results agree with Shaanan's conclusions that the distal pocket in liganded beta subunits is more open whereas in alpha subunits bound ligands are more sterically hindered by adjacent distal residues (Shaanan, B. (1983) J. Mol. Biol. 171, 31-59). In the case of O2 binding to alpha subunits, the unfavorable steric effects are compensated by the formation of a hydrogen bond between the nitrogen atom of His-E7 and bound dioxygen.

Molecular forms of the acetylcholine receptor from vertebrate muscles and Torpedo electric organ. Interactions with specific ligands.

Multiple forms of the acetylcholine receptor solubilised from cat denervated muscle were separated by velocity sedimentation centrifugation. The kinetic properties of the two main forms (with sedimentation coefficients of 9 S and 4 S) were investigated using a pure preparation of a suitable probe, [3H]propionyl-alpha-bungaro-toxin. The binding of this toxin to each of these forms of the muscle receptor was consistent with a simple bimolecular reaction with a homogeneous class of binding sites. Negligible dissociation of the receptor-toxin complex was observed. This behaviour was also found for the different forms of the acetylcholine receptor of chick embryo muscle and of Torpedo marmorata electric organ. Association rate constants for binding of the 3H-labelled alpha-toxin to receptor from chick embryo muscle and the 9-S and 4-S forms from cat denervated muscle were 0.54 X 10(5), 1.76 X 10(5) and 2.69 X 10(5) M--1 S--1 respectively, at 25 degrees C. The values obtained for the 9-S and 13-S forms of receptor from T. marmorata were 4.51 X 10(5) and 9.93 X 10(5) M--1 S--1 respectively. The reaction of the 3H-labelled alpha-toxin with the receptor was second-order and linear in the presence of an antagonist, as in its absence, for the 4-S and 9-S forms of the cat denervated muscle receptor. This reaction of the receptor was inhibited by cholinergic ligands, with Ki values for two antagonists tested being greater with the 4-S form than with the 9-S form. Apparent negative interaction is observed for antagonists with this receptor, with Hill coefficients of about 0.78 and 0.64 for the 4-S and 9-S forms respectively. A ligand-induced affinity increase, produced by the agonists but not by the antagonists, was observed in this reaction for both forms of the muscle receptor. Two agonists tested showed no difference between these forms in their high-affinity states in either their binding affinities or Hill coefficients.