Showing papers on "Cooperative binding published in 1996"

Cooperative DNA Binding and Sequence-Selective Recognition Conferred by the STAT Amino-Terminal Domain

Abstract: STAT proteins (signal transducers and activators of transcription) activate distinct target genes despite having similar DNA binding preferences. The transcriptional specificity of STAT proteins was investigated on natural STAT binding sites near the interferon-gamma gene. These sites are arranged in multiple copies and required cooperative interactions for STAT binding. The conserved amino-terminal domain of STAT proteins was required for cooperative DNA binding, although this domain was not essential for dimerization or binding to a single site. Cooperative binding interactions enabled the STAT proteins to recognize variations of the consensus site. These sites can be specific for the different STAT proteins and may function to direct selective transcriptional activation.

DNA binding of in vitro activated Stat1 alpha, Stat1 beta and truncated Stat1: interaction between NH2-terminal domains stabilizes binding of two dimers to tandem DNA sites

Abstract: Stat1 alpha, Stat1 beta and a proteolytically defined truncated Stat1 (132-713, Stat1tc) have been prepared from recombinant sources. All three proteins were specifically phosphorylated on Tyr701 in vitro and the phosphoprotein purified to homogeneity. This was achieved by employing a new isolation scheme that does not include DNA affinity steps and readily allows for the isolation of tens of milligrams of activated Stat protein. The purified phosphoprotein was free of traces of unphosphorylated polypeptide as detected by mass spectrometry. The phosphorylated Stat1 preparations bound to various DNA recognition sites with the same Keq of approximately 1 x 10(-9) M; distinction between 'weak' and 'strong' binding sites is determined by the very rapid dissociation (< 30 s, t1/2) from 'weak' sites compared with 'strong' sites (approximately 3 min, t1/2). Reports of 'weak' tandem binding sites in a natural gene caused us to examine binding to tandem sites leading to the finding that the Stat1 alpha or beta (38 amino acids shorter on the C terminus) bound to two tandem sites (but not two head-to-head sites) with a higher stability than to a single recognition site. The N-terminally truncated protein Stat1tc did not show this cooperative binding, thus implicating the N-terminal domain in promoting Stat1-Stat1 dimer interaction.

Differential effects of CTLA-4 substitutions on the binding of human CD80 (B7-1) and CD86 (B7-2).

Abstract: CTLA-4 expressed on activated T cells binds to CD80 (B7-1) and CD86 (B7-2) molecules present on APC with high avidity and appears to deliver a negative regulatory signal to the T cell. We have investigated the kinetics of CTLA-4 binding to CD80 and CD86, together with the effects of selected CTLA-4 mutations on binding activity. The dissociation constants (Kd) for binding of CTLA-4-Ig to CD80 and CD86 transfectants were 8.1 and 6.7 nM, respectively. Surface plasmon resonance was used to determine kinetic parameters of CTLA-4-Ig binding to CD80-Ig and CD86-Ig fusion proteins and revealed enhanced association (ka) and dissociation (kd) rate constants for CD86-Ig compared with CD80-Ig. Furthermore, CD80-Ig and CD86-Ig fusion molecules demonstrated variable abilities to cross-compete for binding to several modified forms of CTLA-4-Ig. Differential binding of CD80 and CD86 to CTLA-4 was further revealed by analysis of 10 discrete CTLA-4 mutants. Five single amino acid substitutions within the CTLA-4 MYPPPY domain exerted modest effects on CD80 binding, but each of these substitutions completely abrogated CD86 binding. In addition, substitutions just N-terminal of the MYPPPY region, and within the CDR1-like region of CTLA-4, eliminated both CD80 and CD86 binding. Hence, CD80 and CD86 bind with different association/dissociation kinetics to similar, but distinct, sites on CTLA-4.

Specificity and degeneracy in peptide binding to HLA-B7-like class I molecules.

Abstract: The HLA-B7-like binding supertype includes several different HLA-B molecules. Herein, the primary and secondary anchor specificities of the five most common HLA-B7-like molecules (B*0702, B*3501, B51, B*5301, and B*5401) were defined by the use of molecular binding assays, analogue peptides, and large sets of peptides corresponding to naturally occurring sequences. All five B7-like molecules analyzed preferentially bound 9-mers, with a stringent requirement for proline in position 2, while a variety of hydrophobic or aromatic residues were well tolerated at the C-terminal anchor position. Although most peptides bound in an allele-specific fashion, approximately 20% of the binders identified were degenerate and bound at least three of the five B7-like molecules analyzed with affinities of 500 nM or less. It was also noted that, in general, peptides that bind with high affinity to any given one B7-like molecule were also most frequently capable of degenerate binding. Prominent roles for secondary anchors in positions 1 and 3 were observed for most B7-like molecules, and secondary anchor motifs were utilized to derive an HLA-B7-like supermotif. The validity of this B7-like supermotif was tested by a blind prediction set. Finally, the B7-like supermotif was utilized to derive a general strategy for rationally engineering peptide analogues of naturally occurring sequences with greatly increased binding affinity and degeneracy. Such engineered supermotif binding peptides may be of significant utility in the development of peptide-based vaccines against chronic viral diseases and cancer.

Zinc binding to the HIV-1 nucleocapsid protein: a thermodynamic investigation by fluorescence spectroscopy.

Abstract: The HIV-1 nucleocapsid protein, NCp7, is characterized by two CCHC zinc finger motifs which have been shown to stoichiometrically bind zinc in mature virions. Moreover, this binding of zinc proves to be critical in various NCp7 functions, especially in the encapsidation process. To further understand the central role of zinc binding to NCp7, we closely investigated the zinc binding properties of NCp7 and various deleted or substituted derivatives. To this end, the fluorescence of wither the naturally occurring Trp37 or the conservatively substituted Trp16 was used to monitor the binding of zinc to the N- and C-terminal finger motifs, respectively. At pH 7.5, the NCp7 proximal motif was found to bind zinc strongly with 2.8 x 10(14) M-1 binding constant about five times higher than the NCp7 distal motif. Moreover, the binding of zinc to one finger motif decreased the affinity of the second one, and this negative cooperativity was shown to be related to the spatial proximity of the zinc-saturated finger motifs. The binding seemed to be almost equally driven by entropy and enthalpy, and the binding information was essentially encoded by the finger motifs themselves whereas the other parts of the protein only played a marginal stabilization role. As expected, the Cys and His residues of the CCHC motifs were critical and competition between protons and zinc ions to these residues induced a steep pH-dependence of the zinc binding constants to both sites. Taken together, our data provide further evidence for the nonequivalence of the two NCp7 finger motifs.

Structure/function relationships in human phenylalanine hydroxylase. Effect of terminal deletions on the oligomerization, activation and cooperativity of substrate binding to the enzyme.

Abstract: Amino-terminal and carboxy-terminal deletion mutagenesis have been used to identify structurally and functionally critical regions of recombinant wild-type human phenylalanine hydroxylase (wt-hPAH; Ser2-Lys452). The wild-type form consisted of dimeric and tetrameric forms in equilibrium, and only the isolated tetrameric form showed positive cooperativity of substrate (L-Phe) binding (Hill coefficient h= 2.2, S0.5= 154 μM). The deletion mutants lacking the carboxy-terminal 24 amino acids hPAH(Ser2-Gln428) and hPAH(Gly103-Gln428) formed catalytically active dimers, and incubation with L-Phe did not promote the formation of tetramers, a characteristic property of dimeric wt-hPAH. The carboxy-terminus thus seems to contain a motif required for dimer-dimer interaction in wt-hPAH. The deletion mutants hPAH(Asp112-Lys452), hPAH(Ser2-Gln428) and hPAH(Glyl03-Gln428) were all activated by prior incubation with L-Phe, but did not reveal any positive cooperativity of substrate binding (h= 1.0). The activation by L-Phe was accompanied by a measurable conformational change (as probed by intrinsic fluorescence spectroscopy) only in the enzyme forms containing the amino-terminal sequence, i.e. wt-hPAH and the Ser2 - Gln428 mutant. The amino-terminal deletion mutants hPAH(Asp112–Lys452) and hPAH(Gly103-Gln428) revealed high specific activity, increased apparent affinity for L-Phe (S0.5= 60 μM) and a tryptophan fluorescence emission spectrum similar to that of the L-Phe-activated wt-hPAH. Moreover, prior incubation of the enzyme forms with lysophosphatidylcholine, a commonly used activator of the PAH, only increased the activity of those forms containing the wt-hPAH amino-terminal sequence. Our results are compatible with a model in which incubation of wt-hPAH with L-Phe induces both a conformational change (with cooperativity in the tetrameric enzyme) which relieves the inhibition imposed by the amino-terminal domain to the high-affinity binding of L-Phe, and an additional activation, as observed for the truncated forms lacking the amino-terminal.

A negatively charged anchor residue promotes high affinity binding to the MHC class II molecule I-Ak.

Abstract: An allele-specific peptide-binding motif for the murine MHC class II molecule I-Ak has proven elusive. Here we demonstrate that the I-Ak molecule preferentially binds peptides that contain negatively charged amino acids at the primary anchor position (Asp or Glu at P1), and that I-Ak can also bind peptides with polar residues at P1 (Cys, Ser, Asn, Gin, or Thr), although with lower affinity. This preference for a negatively charged anchor residue is so pronounced that polyalanine peptides containing a single Asp can bind to I-Ak. Eight naturally processed peptides were found to use an Asp, as demonstrated by a drop in the I-Ak binding affinity of these peptides after Ala substitution. The chemical identity of the amino acid in the anchor position was also important in determining the ability of peptide-I-Ak complexes to resist denaturation on SDS-polyacrylamide gels. The P1 binding pockets of HLA-DR and H-2E molecules are reported to be large and hydrophobic, and these class II molecules prefer to bind peptides with large aliphatic or aromatic side chains at P1. Our results suggest that the structure of the I-Ak P1 binding pocket is different. Based on sequence comparisons, we suggest that the P1 binding pockets of H-2A molecules may prove more polymorphic than the P1 binding pockets of H-2E molecules, and that this additional polymorphism will cause H-2A molecules to display larger intra-allelic differences in peptide binding specificities.

Alternative Splicing Determines the Binding of Platelet-Derived Growth Factor (PDGF-AA) to Glycosaminoglycans†

Abstract: We have shown previously that the platelet-derived growth factor (PDGF) and a synthetic oligopeptide, corresponding to the basic carboxyl-terminal amino acid extension of the long PDGF-A isoform, bind to heparin. Here, we have expressed the long (rA125) and the short (rA109) variants of PDGF A-chains in Escherichia coli and produced the functional homodimers. Surface plasmon resonance analyses showed that while the dimeric rA125 bound with high affinity to low molecular weight heparin, the rA109, lacking the basic extension, did not. This strongly indicated that high affinity binding is due to the carboxyl-terminal extension. Investigations of kinetics and thermodynamics suggested an allosteric binding mechanism. Thus, dimeric rA125 contains two equivalent binding sites. Following low affinity binding of heparin to one binding site, the dimer undergoes a conformational change, increasing the affinity for heparin about 40 times. This positive cooperativity requires the basic amino acid extension in both monomers of the dimeric PDGF molecule. Thermodynamics of the reaction, showing an entropy-driven endothermic process, suggest the involvement of hydrophobic interactions in this rearrangement. Three amino acids in the basic carboxyl-terminal extension were essential for the interaction: the basic residues Arg111 and Lys116, and the polar Thr125. We also found that other glycosaminoglycan species, corresponding to those produced by human arterial smooth muscle cells, bound to dimeric rA125 and that heparan sulfate showed the highest affinity.

Cooperative interactions of nucleotide ligands are linked to oligomerization and DNA binding in bacteriophage T7 gene 4 helicases.

Abstract: The equilibrium nucleotide binding and oligomerization of bacteriophage T7 gene 4 helicases have been investigated using thymidine 5‘-triphosphate (dTTP), deoxythymidine 5‘-(β,γ-methylenetriphosphate) (dTMP-PCP), thymidine 5‘-diphosphate (dTDP), adenosine 5‘-triphosphate (ATP), and adenosine 5‘-O-(3-thiotriphosphate) (ATPγS). In the presence of nucleotide ligands, T7 helicases self-assemble into hexamers with six potential nucleotide binding sites that are nonequivalent both in the absence and in the presence of single-stranded DNA. All nucleotides tested bind with high affinity to three sites (Kd = 5 × 10-6 M, dTTP; 6 × 10-7 M, dTMP-PCP; 4 × 10-6 M, dTDP; 3 × 10-5 M, ATP; 2 × 10-6 M, ATPγS), while binding to the remaining sites is undetectable. Interestingly, nucleotide binding to the high-affinity sites exhibits positive cooperativity which is sensitive to protein concentration. This effect is a result of ligand binding-linked oligomerization wherein helicase oligomer equilibrium changes as a function o...

A critical arginine residue mediates cooperativity in the contact interface between transcription factors NFAT and AP-1

Abstract: The heterologous transcription factors NFAT and AP-1 coordinately regulate cytokine gene expression through cooperative binding to precisely juxtaposed DNA recognition elements. The molecular origins of cooperativity in the binding of NFAT and AP-1 to DNA are poorly understood. Herein we have used yeast one-hybrid screening and alanine-scanning mutagenesis to identify residues in AP-1 that affect cooperative interactions with NFAT on DNA. Mutation of a single conserved Arg residue to Ala in the cJun spacer region (R285A) led to a virtually complete abolition of cooperative interactions with NFAT. The DNA-binding activity of AP-1 alone was unaffected by the cJun R285A mutation, thus indicating that this residue influences cooperative binding only. Ala-scanning mutations elsewhere in AP-1, including the cFos subunit, revealed no other strongly interacting single positions. We thus conclude that NFAT contacts AP-1 in the spacer region of the cJun subunit, making an especially important contact to R285, and that these interactions drive formation of the cooperative NFAT/AP-1/DNA complex. These results provide a general strategy for selectively ablating cooperativity between transcription factors without affecting their ability to act alone and yield insights into the structural basis for coordinate regulation of gene expression.

A kinetic study on the influence of nucleoside triphosphate effectors on subunit interaction in mouse ribonucleotide reductase.

Abstract: For enzymatic activity, mouse ribonucleotide reductase must form a heterodimeric complex composed of homodimeric R1 and R2 proteins Both substrate specificity and overall activity are regulated by the allosteric effectors ATP, dATP, dTTP, and dGTP, which bind to two different sites found on R1, the activity site and the substrate specificity site We have used biosensor technique to directly observe the effects of these nucleotides on R1/R2 interactions In the absence of effectors, positive cooperativity was observed with a Hill coefficient of 18 and a KD of 05 microM In the presence of dTTP or dGTP, there was no cooperativity and subunit interaction was observed at a much lower R1 concentration The highest R1/R2 affinity was in the presence of dATP or ATP with KDs of 005-01 microM In all experiments, the molar stoichiometry between the subunits was close to 1:1 Our data support a model whereby binding of any of the effectors to the substrate specificity site promotes formation of the R1 dimer, which we believe is prerequisite for binding to the R2 dimer Additional binding of either ATP (a positive effector) or dATP (a negative effector) to the activity site further increases R1/R2 association We propose that binding of ATP or dATP to the activity site controls enzyme activity, not by changing the aggregation state of the R1/R2 proteins as proposed earlier, but rather by locally influencing the long range electron transport between the catalytic site of R1 and the tyrosyl free radical of R2

Unusual binding stoichiometries and cooperativity are observed during binary and ternary complex formation in the single active pore of R67 dihydrofolate reductase, a D2 symmetric protein.

Abstract: R67 dihydrofolate reductase (DHFR) is an R-plasmid-encoded enzyme that confers resistance to the antibacterial drug, trimethoprim. This DHFR variant is not homologous in either sequence or structure to chromosomal DHFRs. A recent crystal structure of the active tetrameric species describes a single active site pore that traverses the length of the protein (Narayana et al., 1995). Related sites (due to a 222 symmetry element at the center of the active site pore) are used for binding of ligands, i.e., each half-pore can accommodate either the substrate, dihydrofolate, or the cofactor, NADPH, although dihydrofolate and NADPH are bound differently. Ligand binding in R67 DHFR was evaluated using time-resolved fluorescence anisotropy and isothermal titration calorimetry techniques. Under binary complex conditions, two molecules of either NADPH, folate, dihydrofolate, or N10 propargyl-5,8-dideazafolate (CB3717) can be bound. Binding of NADPH displays negative cooperativity, binding of either folate or dihydrofolate shows positive cooperativity, and binding of CB3717 shows two identical sites. Any asymmetry introduced by binding of one ligand is proposed to induce the cooperativity associated with binding of the second ligand. Evaluation of ternary complex formation demonstrates that one molecule of folate binds to a 1:1 mixture of R67 DHFR+NADPH. These binding results indicate a maximum of two ligands bind in the pore. A mechanism describing catalysis is proposed that is consistent with the binding results.

The cluster-arranged cooperative model: a model that accounts for the kinetics of binding to A1 adenosine receptors.

Abstract: To explain the equilibrium binding and binding kinetics of ligands to membrane receptors, a number of models have been proposed, none of which is able to adequately describe the experimental findings, in particular the apparent negative cooperativity of ligand binding. In this paper, a new model, the cluster-arranged cooperative model, is presented whose main characteristic is that it explains the existence of negative cooperativity in the binding of ligands to the receptor molecule. The model is based on our findings of agonist binding to A1 adenosine receptors and of ligand-induced clustering of these receptors on the cell surface. The model assumes the existence of two conformational forms of the receptor in an equilibrium which depends on the concentration of the ligand. In this way, negative cooperativity is explained by the transmission of the information between receptor molecules through the structure of the membrane. The model is able to predict the thermodynamic binding and binding kinetics of [3H]-(R)-(phenylisopropyl)adenosine to A1 adenosine receptors in the presence and absence of guanylyl imidodiphosphate. In the presence of the guanine nucleotide analogue, the linear Scatchard plots obtained for [3H]-(R)-(phenylisopropyl)adenosine binding are explained by the disappearance of cooperativity, thus suggesting that G proteins are important for the existence of negative cooperativity in ligand binding. Among other predictions, the model justifies early events in homologous desensitization since high ligand concentrations would lead to the saturation of the receptor in a low-affinity conformation that does not signal. Our model can likely explain the behavior of a number of heptaspanning and tyrosine-kinase receptors exhibiting complex binding kinetics.

Interaction of the 33 kDa extrinsic protein with photosystem II: rebinding of the 33 kDa extrinsic protein to photosystem II membranes which contain four, two, or zero manganese per photosystem II reaction center.

Abstract: The 33 kDa extrinsic protein of photosystem II acts to enhance oxygen evolution and to stabilize the manganese cluster at low chloride concentrations. Due to controversies concerning the stoichiometry of this protein [Miyao, M., & Murata, N. (1989) Biochim. Biophys. Acta 977, 315-321, versus Xu, Q., & Bricker, T. M. (1992) J. Biol. Chem. 267. 25816-25821] we have examined the rebinding of this protein to PS II membrane preparations which contain four, two, or zero manganese per photosystem II reaction center. After rebinding, immunoquantification of the 33 kDa extrinsic protein demonstrated that each of these photosystem II membrane preparations strongly bound two copies of the 33 kDa extrinsic protein per photosystem II reaction center. The first and second stoichiometric binding constants (Ka1 and Ka2) for the binding of the 33 kDa protein to PS II centers containing four manganese were 0.42 and 0.67 nM(-1), respectively. Disruption of the manganese cluster either by removal of the chloride-sensitive manganese or extraction of the manganese cluster by alkaline Tris led to a 5-6-fold decrease in Ka1 and about a 3-fold decrease in Ka2. In all cases the binding of the two copies of the 33 kDa extrinsic protein exhibited positive cooperativity with Hill coefficients ranging from 1.6 to 2.2. These findings demonstrate that damage to the manganese cluster alters the binding affinity of the 33 kDa extrinsic protein to photosystem II but does not alter the molecularity of the binding reaction.

Spectroscopic characterization of a high-affinity calmodulin-target peptide hybrid molecule.

Abstract: We describe the properties of a hybrid protein comprising the full length of the Xenopus laevis calmodulin sequence, followed by a pentapeptide linker (GGGGS), and residues 3-26 of M13, the calmodulin binding region of skeletal muscle myosin light chain kinase. The properties of the hybrid protein are compared with those of the complex formed between Drosophila calmodulin and a peptide corresponding to residues 1-18 of the M13 sequence. The addition of calcium to the hybrid protein produces pronounced changes in the near- and far-UV CD spectra, in the fluorescence emission spectrum of the single tryptophan residue at position 4 in the M13 sequence, and in the accessibility of this tryptophan residue to acrylamide quenching. These changes are consistent with the tryptophan residue being immobilized in a hydrophobic environment and with the hybrid protein adopting a more alpha-helical structure when calcium is bound. The increased alpha-helicity derives from changes in both the calmodulin and peptide regions of the hybrid protein. Changes in the circular dichroism and fluorescence properties of the hybrid protein as a function of the calcium to hybrid protein ratio are consistent with the fact that these changes parallel the cooperative binding of all four calcium ions. The hybrid protein shows greatly increased affinity (>250-fold) for calcium compared with calmodulin itself. Macroscopic calcium binding constants (K(1)-K(4)) were determined from calcium titrations performed in the presence of the calcium chelator Quin 2. Values for log(K(1)K(2)) and log(K(3)K(4)) were determined to be 15.4 +/- 0.2 and 15.59 +/- 0.22 (20 degrees C). The corresponding values for Drosophila calmodulin alone are 11.65 +/- 0.15 and 9.66 +/- 0.25. Consistent with this increased affinity for calcium stopped-flow kinetic studies suggest that the dissociation rate for the N-terminal calcium ions is reduced to at least 0.77 s(-1), compared with approximately 700 s(-1) for Drosophila calmodulin in the absence of peptide. This hybrid protein illustrates the principle whereby the binding of a peptide sequence covalently attached to calmodulin can enhance the average calcium affinity by more than 2 orders of magnitude. Conversely, the target sequence in the hybrid protein undergoes a calcium-induced conformational change to bind to the calmodulin in a conformation very similar to that of the corresponding dissociable target sequence binding to calmodulin, but with a greatly enhanced affinity due to its physical proximity to the binding site. This avoidance of the energetic penalty of dissociation may be a key contributory factor in determining the high affinity and specificity of the complex multiple interactions involved in recognition of biological targets by calmodulin.

Proteins C1 and C2 of Heterogeneous Nuclear Ribonucleoprotein Complexes Bind RNA in a Highly Cooperative Fashion: Support for Their Contiguous Deposition on Pre-mRNA during Transcription†

Abstract: Proteins C1 and C2 together comprise about one-third the protein mass of mammalian core 40S heterogeneous nuclear ribonucleoprotein particles (40S hnRNP) and exist as heterotetramers of (C1)3C2. On the basis of nonequilibrium binding studies, it has been suggested that the C proteins specifically bind oligo(U)- and poly(U)-rich sequences, and preferentially associate with uridine-rich regions near the 3' termini of many introns. We describe here a more quantitative characterization of the equilibrium binding properties of native and recombinant C protein to homoribopolymers using fluorescence spectroscopy. Like C protein from HeLa cells, the recombinant proteins spontaneously oligomerize to form tetramers with the same hydrodynamic properties as native protein. Near-stoichiometric binding titrations of the fluorescent homoribopolymer polyethenoadenosine (poly[r(epsilon A)]) with recombinant (C1)4 and (C2)4 homotetramers along with competition binding assays with poly(A) and poly(C) indicate that the binding site size (n) is between 150 and 230 nucleotides. This site size range is in close agreement with that previously determined for native C protein through hydrodynamic and ultrastructural studies (approximately 230 nucleotides). (C1)4 and (C2)4 bind poly(G) with intrinsic affinities (Ki) of 10(9) M-1, which are a hundredfold higher than their affinities for poly(U). In opposition to reports that C protein does not bind poly(A) and poly(C), we find that the C proteins bind these substrates with moderate Ki, but with high cooperativity (omega). The overall affinity (K omega) for the binding of both proteins to poly(A) and poly(C) is 10-fold higher (> 10(8) but < 10(9) M-1) than their affinities for poly(U). The highly cooperative binding of C protein to these substrates provides a mechanistic basis for the distribution of C protein along the length of nucleic acid substrates.