Showing papers on "Cooperativity published in 1993"

A cooperative interaction between NF-kappa B and Sp1 is required for HIV-1 enhancer activation.

Abstract: The human immunodeficiency virus (HIV-1) long terminal repeat (LTR) contains two binding sites for NF-kappa B in close proximity to three binding sites for the constitutive transcription factor, Sp1. Previously, stimulation of the HIV enhancer in response to mitogens has been attributed to the binding of NF-kappa B to the viral enhancer. In this report, we show that the binding of NF-kappa B is not by itself sufficient to induce HIV gene expression. Instead, a protein-protein interaction must occur between NF-kappa B and Sp1 bound to an adjacent site. Cooperativity both in DNA binding and in transcriptional activation of NF-kappa B and Sp1 was confirmed by electrophoretic mobility shift gel analysis, DNase footprinting, chemical cross-linking and transfection studies in vivo. With a heterologous promoter, we find that the interaction of NF-kappa B with Sp1 is dependent on orientation and position, and is not observed with other elements, including GATA, CCAAT or octamer. An increase in the spacing between the kappa B and Sp1 elements virtually abolishes this functional interaction, which is not restored when these sites are brought back into the same helical position. Several other promoters regulated by NF-kappa B also contain kappa B in proximity to Sp1 binding sites. These findings suggest that an interaction between NF-kappa B and Sp1 is required for inducible HIV-1 gene expression and may serve as a regulatory mechanism to activate specific viral and cellular genes.

Cooperativity in protein-folding kinetics.

Abstract: How does a protein find its native state without a globally exhaustive search? We propose the "HZ" (hydrophobic zipper) hypothesis: hydrophobic contacts act as constraints that bring other contacts into spatial proximity, which then further constrain and zip up the next contacts, etc. In contrast to helix-coil cooperativity, HZ-heteropolymer collapse cooperativity is driven by nonlocal interactions, causes sheet and irregular conformations in addition to helices, leads to secondary structures concurrently with early hydrophobic core formation, is much more sequence dependent than helix-coil processes, and involves compact intermediate states that have much secondary--but little tertiary--structure. Hydrophobic contacts in the 1992 Protein Data Bank have the type of "topological localness" predicted by the hypothesis. The HZ paths for amino acid sequences that mimic crambin and bovine pancreatic trypsin inhibitor are quickly found by computer; the best configurations thus reached have single hydrophobic cores that are within about 3 kcal/mol of the global minimum. This hypothesis shows how proteins could find globally optimal states without exhaustive search.

Distinct mechanisms for regulation of the interleukin-8 gene involve synergism and cooperativity between C/EBP and NF-kappa B.

Abstract: The interleukin-8 promoter is transcriptionally activated by interleukin-1, tumor necrosis factor alpha, phorbol myristate acetate, or hepatitis B virus X protein through a sequence located between positions -91 and -71. This region contains an NF-kappa B-like and a C/EBP-like binding site. We show here that several members of the NF-kappa B family, including p65, p50, p52, and c-Rel, can bind to this region, confirming an authentic NF-kappa B binding site in the interleukin-8 promoter. Further, C/EBP binds only weakly to the interleukin-8 promoter site. Electrophoretic mobility shift assays with proteins overexpressed in COS cells and with nuclear extracts from tumor necrosis factor alpha-stimulated HeLa cells demonstrated a strong cooperative binding of C/EBP to its site when NF-kappa B is bound to its adjacent binding site. Transfection studies lead to a model that suggests a highly complex regulation of interleukin-8 gene expression at multiple levels: independent binding of C/EBP and NF-kappa B to their respective sites, cooperative binding of C/EBP and NF-kappa B to DNA, and positive synergistic activation through the C/EBP binding site and inhibition through the NF-kappa B binding site by combinations of C/EBP and NF-kappa B. Thus, the ultimate regulation of interleukin-8 gene expression depends on the ratio of cellular C/EBP and NF-kappa B.

Entropy-driven DNA denaturation.

Abstract: We present a nonlinear dynamical model for DNA denaturation which includes cooperativity effects through anharmonic nearest-neighbor stacking interactions. Transfer-integral calculations show that this one-dimensional model, without including long-range interactions, exhibits a sharp denaturation reminiscent of a first-order transition at a temperature lower than a similar model with harmonic coupling. Self-consistent phonon calculations point out the essential role of nonlinear effects in the mechanism.

Crystal structure of deoxygenated Limulus polyphemus subunit II hemocyanin at 2.18 A resolution: clues for a mechanism for allosteric regulation.

Abstract: The crystal structure of Limulus polyphemus subunit type II hemocyanin in the deoxygenated state has been determined to a resolution of 2.18 A. Phase information for this first structure of a cheliceratan hemocyanin was obtained by molecular replacement using the crustacean hemocyanin structure of Panulirus interruptus. The most striking observation in the Limulus structure is the unexpectedly large distance of 4.6 A between both copper ions in the oxygen-binding site. Each copper has approximate trigonal planar coordination by three histidine N epsilon atoms. No bridging ligand between the copper ions could be detected. Other important new discoveries are (1) the presence of a cis-peptide bond between Glu 309 and Ser 310, with the carbonyl oxygen of the peptide plane hydrogen bonded to the N delta atom of the copper B ligand His 324; (2) localization of a chloride-binding site in the interface between the first and second domain; (3) localization of a putative calcium-binding site in the third domain. Furthermore, comparison of Limulus versus Panulirus hemocyanin revealed considerable tertiary and quaternary rigid body movements, although the overall folds are similar. Within the subunit, the first domain is rotated by about 7.5 degrees with respect to the other two domains, whereas within the hexamer the major movement is a 3.1 degrees rotation of the trimers with respect to each other. The rigid body rotation of the first domain suggests a structural mechanism for the allosteric regulation by chloride ions and probably causes the cooperative transition of the hexamer between low and high oxygen affinity states. In this postulated mechanism, the fully conserved Phe49 is the key residue that couples conformational changes of the dinuclear copper site into movements of the first domain.

A bimetallic hydroformylation catalyst: high regioselectivity and reactivity through homobimetallic cooperativity.

Abstract: The racemic and meso diastereomers of an electron-rich binucleating tetraphosphine ligand have been used to prepare homobimetallic rhodium norbornadiene complexes. The racemic bimetallic Rh complex is an excellent hydroformylation catalyst for 1-alkenes, giving both a high rate of reaction and high regioselectivity for linear aldehydes, whereas the meso complex is considerably slower and less selective. A mechanism involving bimetallic cooperativity between the two rhodium centers in the form of an intramolecular hydride transfer is proposed. Mono- and bimetallic model complexes in which the possibility for bimetallic cooperativity has been reduced or eliminated are very poor catalysts.

Binding and hydrolysis of nucleotides in the chaperonin catalytic cycle: Implications for the mechanism of assisted protein folding

Abstract: Cpn60 was labeled with pyrene maleimide in order to follow structural rearrangements in the protein triggered by the binding of nucleotides and cpn10. The conjugate binds ATP, AMP-PNP, and ADP(P(i)) with pyrene fluorescence enhancements of 60%, 60%, and 15%, respectively. In each case, binding is cooperative with half-saturation (K1/2) occurring at 10 microM, 290 microM, and 2500 microM and Hill constants (nH) of 4, 3, and 3, respectively. Inclusion of the co-protein, cpn10, tightens the binding of ATP, AMP-PNP, and ADP(P(i)) to give K1/2 values of 6 microM, 100 microM, and < 0.07 microM, respectively, and cooperativity is increased. Titration of the cpn60/ADP (14-mer) complex with cpn10 (7-mer) gives a stoichiometry of 14:7 with respect to subunits, confirming the molecular asymmetry shown by electron microscopy. Transient kinetics demonstrate that ATP initially forms a weak collision complex with cpn60 (Kd = 4 mM) which isomerizes to the strongly binding state at a rate of 180 s-1. We suggest that the slow structural rearrangement driven by ATP binding is the same event which lowers the affinity of the chaperonin for protein substrates; a suggestion reinforced by the loss of AMP-PNP binding affinity in the presence of an unstructured polypeptide. As such, this rearrangement of cpn60 is analogous to a force-generating step in energy transduction. Measurements of ATP hydrolysis (pH 7.5, 25 degrees C) show that it is slow (0.04 s-1) compared both with the structural rearrangement and with the dissociation of products. This defines the steady-state complex as cpn60/ATP, a form of the chaperonin which binds substrate proteins weakly. The rate of hydrolysis of ATP is stimulated 20-fold upon binding unfolded lactate dehydrogenase, and the yield of folded enzyme is increased even in the absence of cpn10. Addition of this co-protein inhibits hydrolysis on only half of the sites in cpn60 and leads to a faster release of folded LDH. A mechanism for the action of chaperonins is proposed which depends upon cpn60 being cycled between states which have, alternately, low and high affinity for unfolded proteins. This cycle is driven by the binding and hydrolysis of ATP.

Hydrolysis of adenosine 5'-triphosphate by Escherichia coli GroEL: effects of GroES and potassium ion.

Abstract: The potassium-ion activation constant (Kact) for the ATPase activity of Escherichia coli chaperonin groEL is inversely dependent upon the ATP concentration over at least 3 orders of magnitude. The ATPase activity shows positively cooperative kinetics with respect to ATP and K+. Both the K0.5 for ATP and cooperativity (as measured by the Hill coefficient) decrease as the K+ concentration increases. Equilibrium binding studies under conditions where hydrolysis does not occur indicate that MgATP binds weakly to groEL in the absence of K+. In the absence of groES, the K(+)-dependent hydrolysis of ATP by groEL continues to completion. In the presence of groES, the time course for the hydrolysis of ATP by groEL becomes more complex. Three distinct kinetic phases can be discerned. Initially, both heptameric toroids turn over once at the same rate that they do in the absence of groES. This leads to the formation of an asymmetric binary complex, groEL14-MgADP7-groES7, in which 7 mol of ADP is trapped in a form that does not readily exchange with free ADP. In the second phase, the remaining seven sites (containing readily exchangeable ADP) turn over, or have the potential to turn over, at the same rate as they do in the absence of groES, so that the overall rate of hydrolysis is maximally 50%. These remaining sites of the asymmetric binary complex do not hydrolyze all of the available ATP. Instead, the second phase of hydrolysis gives way to a third, completely inhibited state, the onset of which is dependent upon the relative affinities of the remaining sites for MgATP and MgADP.(ABSTRACT TRUNCATED AT 250 WORDS)

Binding of 4',6-diamidino-2-phenylindole (DAPI) to AT regions of DNA: evidence for an allosteric conformational change.

Abstract: The interaction of 4',6-diamidino-2-phenylindole (DAPI) with several double-helical poly- and oligonucleotides has been studied in solution using optical spectroscopic techniques: flow linear dichroism (LD), induced circular dichroism (CD), and fluorescence spectroscopy. In AT-rich sequences, where DAPI is preferentially bound, LD indicates that the molecule is edgewise inserted into the minor groove at an angle of approximately 45-degrees to the helix axis. This binding geometry is found for very low as well as quite high binding ratios. The concluded geometry is in agreement with that of the DAPI complex in a crystal with the Drew-Dickerson dodecamer, and the DAPI complex with this dodecamer in solution is verified to have an ICD spectrum similar to that of the complex with [poly(dA-dT)]2 at low binding ratios. The observation of two types of CD spectra characteristic for the binding of DAPI to DNA, and also for the interaction with [poly(dA-dT)]2, demonstrates that the first binding mode, despite its low apparent abundance (a few percent), is not due to a specific DNA site. The effect may be explained in terms of an allosteric binding such that when DAPI molecules bind contiguously to the AT sequence the conformation of the latter is changed. The new conformation, which according to LD appears to be stiffer than normal B-form DNA, is responsible for the second type of induced CD spectrum in the DAPI chromophore. Although the spectroscopic results indicate a change of DNA conformation, consistent with an allosteric binding model, they do not explicitly require any cooperativity, but accidental neighbors could also explain the data.

Hydrogen bond cooperativity: a quantitative study using matrix-isolation FT-IR spectroscopy

Abstract: Matrix-isolation FT-IR spectroscopy is a suitable experimental method for evaluating hydrogen-bond cooperativities in complexes containing more than one single H bond. It is demonstrated that the cooperativity factor A,, which represents the fortification of a H bond A-H---A-H by a further A-H---B interaction in a 1:2 complex A-H---A-H---B, increases with increasing proton affinity of the base B. On the other hand, the cooperativity factor A b , representing the inverse fortification, is more or less constant for constant A-H

Engineering stability of the insulin monomer fold with application to the structure-activity relationship

Abstract: To evaluate the possible relationship between biological activity and structural stability in selected regions of the insulin molecule, we have analyzed the guanidine hydrochloride induced reversible unfolding of a series of mutant insulins using a combination of near- and far-UV circular dichroism (CD). The unfolding curves are reasonably described on the basis of a two-state denaturation scheme; however, the observation of subtle differences between near- and far-UV CD detected unfolding indicates that intermediates may be present. Three regions of the insulin molecule are analyzed in detail with respect to their contribution to folding stability, i.e., the central B-chain helix, the NH2-terminal A-chain helix, and the B25-B30 extended chain region. Considerable enhancement of folding stability is engineered by mutations at the N-cap of the central B-chain helix and at the C-cap of the NH2-terminal A-chain helix. Mutations that confer increased stability in these regions are identical to those that lead to enhanced biological activity. In contrast, for insulin species modified in the B25-B30 region of the molecule, we observe no correlation between global folding stability and bioactivity. Mutations in the three regions examined are found to affect stability in a nearly independent fashion, and stabilizing mutations are generally found to enhance the cooperativity of the unfolding transition. We conclude that highly potent insulins (i.e., HisA8, ArgA8, GluB10, and AspB10) elicit enhanced activity because these mutations stabilize structural motifs of critical importance for receptor recognition.

Mutational effects on the cooperativity of Ca2+ binding in calmodulin.

Abstract: The importance of the aspartate ligand in the +Y Ca2+ coordinating position of two EF-hands of calmodulin has been investigated. Synthetic calmodulin genes were used to produce engineered proteins with the wild-type bovine sequence as well as with aspartate 58 in Ca(2+)-binding site II and/or aspartate 95 in site III changed to asparagine. The macroscopic Ca(2+)-binding constants of the intact calmodulins and of tryptic fragments comprising the N- and C-terminal domains were determined from titrations with Ca2+ in the presence of 5,5'-Br2BAPTA. Substitution of aspartate by asparagine in Ca(2+)-binding site II led to a slight increase in the total free energy change on Ca2+ binding, and the cooperativity of Ca2+ binding to the N-terminal sites was substantially increased. The change from aspartate to asparagine in site III decreased the Ca2+ affinity and also appeared to decrease the positive cooperativity between the sites in the C-terminal domain. Thus, identical mutations in sites II and III were found to result in opposite effects. The data imply that involvement of liganding side chains in interactions other than direct calcium attraction and calcium coordination is of considerable importance for the Ca(2+)-binding process, particularly for the cooperativity.

Electric potentiation, cooperativity, and synergism of magainin peptides in protein-free liposomes.

Abstract: Magainins, positively charged peptides present in the skin of Xenopus laevis, are known to permeabilize free-energy transducing membranes. Structural studies in otherwise protein-free model systems show alpha-helical magainins parallel to the membrane water interface. However, functional studies in biological membranes suggest that magainins operate as oligomeric complexes. Here we investigate whether magainins function as oligomers in protein-free liposomes also. We report that they do exhibit strong positive heterocooperativity. The magainins, magainin 2 and PGLa, act synergistically. Both activity and cooperativity are enhanced by net negative charge of the liposomal membranes. A transmembrane electric potential, negative inside, enhanced the activity of the peptides. We propose a model in which (i) binding to the surface of the membrane, mainly guided by electrostatic interactions, occurs and (ii) the bound form is in equilibrium with an n-meric complex of magainins spanning the membrane.

Negative cooperativity in the binding of nucleotides to Escherichia coli replicative helicase DnaB protein. Interactions with fluorescent nucleotide analogs

Abstract: The interactions of nucleotides with Escherichia coli replicative helicase DnaB protein have been systematically studied using fluorescent nucleotide analogs, 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate (TNP-ATP), 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-diphosphate (TNP-ADP), 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-monophosphate (TNP-AMP), 3'-O-(N-methylantraniloyl) 5'-diphosphate (MANT-ADP), and 1,N6-ethenoadenosine diphosphate (epsilon ADP). The binding of the analogs is accompanied by strong quenching of the protein fluorescence; 0.76 +/- 0.05, 0.76 +/- 0.05, 0.58 +/- 0.05, and 0.53 +/- 0.5 for TNP-ATP, TNP-ADP, MANT-ADP, and epsilon ADP, respectively. A thermodynamically rigorous method has been applied to obtain all binding parameters from fluorescence titration curves independent of the assumption of strict proportionality between the observed quenching of the protein fluorescence and the degree of nucleotide binding. An exact representation of the observed fluorescence quenching, as a function of the nucleotide binding, is introduced through an empirical function which enables analysis of single binding isotherms without the necessity of determining all quenching constants for different binding sites. Using this method, we determined that, at saturation, the DnaB hexamer binds six molecules of TNP-ATP, TNP-ADP, MANT-ADP, and epsilon ADP, and that there is strong heterogeneity among nucleotide binding sites. The binding isotherms are biphasic. Three molecules of nucleotide are bound in the first high-affinity binding phase, and the subsequent three molecules are bound in the second low-affinity binding phase. The separation of the two binding steps is even more pronounced at higher temperatures. The change of the monitored fluorescence is sequential. The binding of the first nucleotide causes the largest quenching of the protein fluorescence with subsequent nucleotide binding inducing progressively less quenching. The simplest explanation of this behavior is that there is a negative cooperativity among nucleotide binding sites on a DnaB hexamer. The negative cooperativity is an intrinsic property of the DnaB helicase, since it is observed in the binding of nucleotide analogs which are different in type and location of the modifying group. A statistical thermodynamic model is proposed, the hexagon, which provides an excellent description of the binding process using only two interaction parameters, intrinsic binding constant K and cooperativity parameter sigma. The data suggest an important role of the phosphate groups in binding and in recognition of nucleotides by the DnaB helicase.

In vitro functional characterization of bacterially expressed human fibroblast tropomyosin isoforms and their chimeric mutants.

Abstract: At least eight tropomyosin isoforms (hTM1, hTM2, hTM3, hTM4, hTM5, hTM5a, hTM5b, and hTMsm alpha) are expressed from four distinct genes in human fibroblasts. In order to elucidate isoform properties, we have subcloned hTM3 and hTM5 full-length cDNAs, as well as their chimeric cDNAs into the bacterial expression pET8C system. Bacterially expressed tropomyosin isoforms (called PEThTM3, PEThTM5, PEThTM5/3, and PEThTM3/5) were purified and characterized. Under optimal binding conditions, the binding of PEThTM5 isoform to F-actin was stronger than the PEThTM3 isoform. However, analysis of actin-binding by the McGhee and von Hippel equation revealed that PEThTM3 exhibits higher cooperativity in binding than PEThTM5 does. Furthermore, the chimera PEThTM5/3 which possessed the N-terminal fragment of hTM5 fused to the C-terminal fragment of hTM3 had even stronger actin binding ability. The reverse chimera PEThTM3/5 which possessed the N-terminal fragment of hTM3 fused to the C-terminal fragment of hTM5 demonstrated greatly reduced affinity to actin filaments. In addition, both chimeras had different KCl requirements for optimal binding to F-actin than their parental tropomyosins. A bacterially made C-terminal fragment of human fibroblast caldesmon (PETCaD39) and native chicken gizzard caldesmon were both able to enhance the actin-binding of these bacterially expressed tropomyosins. However, PETCaD39's enhancement of binding to F-actin was greater for PEThTM5 than PEThTM3. Under 30 mM KCl and 4 mM MgCl2, the low M(r) isoform PEThTM4 appeared to be able to amplify the actin-activated HMM ATPase activity by 4.7 fold, while the high M(r) isoform PEThTM3 stimulated the activity only 1.5 fold. The higher enhancement of ATPase activity by PEThTM5 than by PEThTM3 suggested that the low M(r) isoform hTM5 may be more involved in modulating nonmuscle cell motility than hTM3. These results further suggested that different isoforms of tropomyosin might have finite differences in their specific functions (e.g., cytoskeletal vs. motile) inside the cell.

Cooperative binding of an Ultrabithorax homeodomain protein to nearby and distant DNA sites.

Abstract: Cooperativity in binding of regulatory proteins to multiple DNA sites can heighten the sensitivity and specificity of the transcriptional response. We report here the cooperative DNA-binding properties of a developmentally active regulatory protein encoded by the Drosophila homeotic gene Ultrabithorax (Ubx). We show that naturally occurring binding sites for the Ubx-encoded protein contain clusters of multiple individual binding site sequences. Such sites can form complexes containing a dozen or more Ubx-encoded protein molecules, with simultaneous cooperative interactions between adjacent and distant DNA sites. The distant mode of interaction involves a DNA looping mechanism; both modes appear to enhance transcriptional activation in a simple yeast assay system. We found that cooperative binding is dependent on sequences outside the homeodomain, and we have identified regions predicted to form coiled coils carboxy terminal to the homeodomains of the Ubx-encoded protein and several other homeotic proteins. On the basis of our findings, we propose a multisite integrative model of homeotic protein action in which functional regulatory elements can be built from a few high-affinity sites, from many lower-affinity sites, or from sites of some intermediate number and affinity. An important corollary of this model is that even small differences in binding of homeotic proteins to individual sites could be summed to yield large overall differences in binding to multiple sites. This model is consistent with reports that homeodomain protein targets contain multiple individual binding site sequences distributed throughout sizable DNA regions. Also consistent is a recent report that sequences carboxy terminal to the Ubx homeodomain can contribute to segmental specificity.

The primary self-assembly reaction of bacteriophage .lambda. cI repressor dimers is to octamer

Abstract: Cooperative binding of the bacteriophage lambda cI repressor dimer to specific sites of the phage operators OR and OL controls the developmental state of the phage. It has long been believed that cooperativity is mediated by self-assembly of repressor dimers to form tetramers which can then bind simultaneously to adjacent operator sites. As a first step in defining the individual energy contributions to binding cooperativity, sedimentation equilibrium and steady-state fluorescence anisotropy methods have been used to study the higher order assembly reactions of the free repressor in solution. Wild-type repressor with 5-hydroxytryptophan (5-OHTrp) substituted for the native tryptophan [Ross et al. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 12023-12027] and two mutant repressor proteins that bind cooperatively to OR but have altered dimerization properties were also studied. We report here that the primary assembly mode of all four proteins is dimer to octamer. It is not dimer to tetramer as previously assumed. While tetramer does form as an assembly intermediate, dimer-octamer assembly is a concerted process so that tetramer is never a predominant species in solution. Sedimentation velocity experiments suggest that the octamer is highly asymmetric, consistent with an elongated shape. This conformation could allow octamers to bind simultaneously to all three operator sites at either OR or OL. Examination of tetramer and octamer concentrations suggests that both species could be involved in cooperative repressor-operator interactions. Our previous work used the unique spectral properties of 5-OHTrp to demonstrate that octamer binds single-operator DNA and is not dissociated to tetramer [Laue et al. (1993) Biochemistry 32, 2469-2472]. Taken together with the results presented here, octamers as well as tetramers must be considered in developing models to explain the cooperativity of lambda cI repressor binding to operator DNA.

Cooperative DNA binding of the human HoxB5 (Hox-2.1) protein is under redox regulation in vitro

Abstract: The human HoxB5 (Hox-2.1) gene product is a sequence-specific DNA binding protein. Cooperative interactions stabilize in vitro DNA binding of the HoxB5 protein to tandem binding sites by at least 100-fold relative to binding to a single site. The HoxB5 homeodomain is sufficient for sequence-specific DNA binding but not for cooperative DNA binding. Here we report that the additional protein sequence required for cooperativity is a small domain adjacent to the homeodomain on the amino-terminal side. We further show that cooperative DNA binding is under redox regulation. The HoxB5 protein binds to DNA in vitro both when oxidized or reduced but binds cooperatively only when oxidized. Mutational analysis has revealed that the cysteine residue in the turn between homeodomain helices 2 and 3 is necessary for cooperative binding and redox regulation. The enhanced DNA binding of oxidized HoxB5 protein is the opposite of the redox regulation reported for other mammalian transcription factors such as Fos, Jun, USF, NF-kappa B, c-Myb, and v-Rel, in which oxidation of cysteine residues inhibits DNA binding. Thus, specific oxidation of nuclear proteins is a potential regulatory mechanism that can act to either decrease or increase their DNA binding activity.

The energetics and cooperativity of protein folding: a simple experimental analysis based upon the solvation of internal residues.

Abstract: The reversible unfolding of two dissimilar proteins, phosphoglycerate kinase from Bacillus stearothermophilus (PGK) and Staphylococcus aureus nuclease (SAN), was induced with two denaturants, urea and guanidinium chloride (GuHCl). For each protein, structural transitions were monitored by intrinsic fluorescence intensity changes arising from a unique tryptophan residue. In the case of SAN the single, native tryptophan residue was used, whereas for PGK two versions, one with a tryptophan at position 315 and one at 379, were constructed genetically. The resultant folding curves were analyzed by considering the change in the solvation free energy of internal amino acid residues as the denaturant concentration was varied. We derive the following simple relationship: -RT ln K = delta Gw + n delta Gs,m[D]/Kden. + [D]) where K is the equilibrium constant describing the distribution of folded and unfolded forms at a given denaturant concentration [D], delta Gw is the free energy change for the transition in the absence of denaturant, and n is the number of internal side chains becoming exposed. delta Gs,m and Kden. are constants derived empirically from the solvation energies of model compounds and represent the behavior of an average internal side chain between 0 and 6 M GuHCl and 0 and 8 M urea. For proteins of known structure these values can easily be derived, and for others, average values in guanidinium chloride (delta Gs,m = 0.775 kcal/mol and Kden. = 5.4 M) or urea (delta Gs,m = 1.198 kcal/mol and Kden. = 25.25 M) can be used in the analysis. Results show that the parameters n and delta Gw are independent of the denaturant used for all 12 transitions studied. This supports the hypothesis that the unfolding activity of urea and GuHCl can be accounted for by their effect on the solvation energy of amino acid side chains which are buried in the folded but exposed in the unfolded protein. This simple analytical treatment allows the "cooperativity" of protein folding to be interpreted in terms of the number of side chains becoming exposed to the solvent in a given step and allows accurate estimation of the free energy irrespective of the denaturant concentration needed to induce the transition.

Cooperative effects on filament stability in actin modified at the C‐terminus by substitution or truncation

Abstract: We have studied the contribution of the C-terminus of actin to filament stability by chemical modification and limited proteolysis. Formation of mixed disulfides of the penultimate C-terminal cysteine residue 374 with various low-molecular-mass thiols resulted in filament destabilization, as reflected by an increase in critical concentration and steady-state ATPase activity. These effects were fully reversed by the addition of phalloidin. Both the destabilization by glutathionylation and the reversal of it by phalloidin exhibited a high degree of cooperativity; half-maximal destabilization required the modification of four out of five actin subunits, and half-maximal restabilization by phalloidin was already reached when only one out of 20 actin subunits was complexed. C-terminal truncation by limited trypsinolysis of filamentous actin resulted in a similar destabilization of the polymer, as shown by a 2–3-fold increase in the steady-state ATPase activity. This effect was likewise cooperative and could be reversed by phalloidin. Since truncation of the C-terminus of actin has an effect on stability similar to that of chemical modification with bulky substituents, the possibility can be excluded that, in the latter case, destabilization was caused by steric hindrance. Rather, it seems that the highly conserved C-terminal part of actin plays an active role in establishing a tight contact between neighbouring subunits.

A single-stranded DNA binding protein from Drosophila melanogaster: characterization of the heterotrimeric protein and its interaction with single-stranded DNA.

Abstract: We describe the purification to near homogeneity of a single-stranded DNA binding protein from 0-18-h embryos of Drosophila melanogaster. Drosophila SSB (D-SSB) is a heterotrimer with subunits of molecular weight of 70,000, 30,000, and 8000. It has a Stokes radius of 48.6 +/- 2 A and s20,w = 5.0 +/- 0.2 S. The interaction of D-SSB with ssDNA was examined by the quenching of intrinsic protein fluorescence. The binding site size was determined to be n = 22 +/- 4 nucleotides with a maximum quenching Qm = 35 +/- 3%. Equilibrium titrations indicate that D-SSB binds with low cooperativity, omega = 10-300, and high apparent affinity, K omega = (0.7-5) x 10(7) M-1, at 225 mM NaCl. Sedimentation of D-SSB bound to small oligonucleotides demonstrates that D-SSB does not require protein association for binding. D-SSB stimulates the extent and processivity of DNA synthesis of its cognate DNA polymerase alpha. On the basis of these properties, we conclude that D-SSB is the Drosophila cognate of the human and yeast SSB/RP-A proteins.

Kinetic analysis of NAD(+)-isocitrate dehydrogenase with altered isocitrate binding sites: contribution of IDH1 and IDH2 subunits to regulation and catalysis.

Abstract: NAD(+)-dependent isocitrate dehydrogenase from Saccharomyces cerevisiae is an allosterically regulated enzyme that exists as an octamer composed of two nonidentical subunits, designated IDH1 and IDH2. To determine the contribution of each subunit to regulation and catalysis, a conserved serine residue at the proposed active site of each subunit was mutated to alanine. This mutation in IDH1 resulted in a 6-fold decrease in Vmax and a decrease in cooperativity, but little change in S0.5 for isocitrate. The mutant IDH2, in contrast, exhibited a 60-fold decrease in maximal velocity and a 2-fold reduction in S0.5 for isocitrate, but the cooperativity was unaffected. Responses to the allosteric modifier AMP also differed for the two mutant enzymes. The IDH1 mutant enzyme was not activated by AMP, whereas the IDH2 mutant enzyme exhibited an increase in isocitrate affinity in the presence of AMP similar to that observed with the wild-type enzyme. On the basis of these kinetic results, a model is presented which proposes that IDH1 functions as a regulatory subunit while IDH2 functions in catalysis. To determine if IDH1 or IDH2 alone is catalytically active, we also expressed the individual subunits in yeast strains in which the gene encoding the other subunit had been disrupted. Mitochondrial extracts from strains overexpressing solely IDH1 or IDH2 contained no detectable activity in the presence or absence of AMP. Gel filtration of these extracts showed that both IDH1 and IDH2 behaved as monomers, suggesting that the major subunit interactions within the octamer are between IDH1 and IDH2.

Cooperativity during multiple phosphorylations catalyzed by rhodopsin kinase: supporting evidence using synthetic phosphopeptides.

Abstract: Rhodopsin kinase is a key component in the shutdown of visual transduction. The phosphorylation of rhodopsin's C-terminus was evaluated using synthetic peptides derived from the last 12 amino acids (337-348) as substrates and their phosphorylated counterparts as inhibitors. It was found that synthetic peptides were phosphorylated at the serine residue corresponding to Ser-343 in the primary sequence of bovine rhodopsin. The phosphopeptides were prepared by incorporating into the peptide chain a trityl-protected serine derivative at the site destined to contain the phosphoryl group. The trityl group was selectively released with 20% (v/v) dichloroacetic acid; the free hydroxyl group was then phosphitylated with di-tert-butyl N,N-diethylphosphoramidite, and the resulting phosphite derivative was oxidized with m-chloroperoxybenzoic acid. The phosphopeptides were found to have a greater affinity for the kinase compared with their nonphosphorylated counterparts; for the peptides corresponding to residues 337-348 of rhodopsin the affinity increased in the order VSKTETSQVAPA < VSKTETS[PO3H2]QVAPA < VS[PO3H2]KTETS[PO3H2]QVAPA. The results are interpreted to support the cooperativity hypotheses proposed previously [Wilden, U., & Kuhn, H. (1982) Biochemistry 21, 3014-3022; Aton, B. R., Litman, B. J., & Jackson, M. L. (1984) Biochemistry 23, 1737-1741].

The cooperativity length in models for the glass transition

Abstract: Kinetic Ising and lattice-gas models with kinetic constraints may serve as models of cooperative dynamics in undercooled liquids near the glass transition. For a class of these models the cooperativity length of a spin/particle is defined and its distribution calculated. It is found that, contrary to an assumption of Adam and Gibbs (1964), there is no simple relation between the cooperativity length and the entropy of these models. For the autocorrelation functions, which exhibit a stretched-exponential time dependence, an approximate sum formula is proposed which contains a relaxation rate depending on cooperativity length. The sum formula is tested for a particular case and found to give good overall agreement with Monte Carlo data.