Equilibrium dissociation and unfolding of the Arc repressor dimer

The equilibrium unfolding reaction of Arc repressor, a dimeric DNA binding protein encoded by bacteriophage P22, can be monitored by fluorescence or circular dichroism changes. The stability of Arc is concentration dependent, and the unfolding reaction is well described as a two-state transition from folded dimer to unfolded monomer. The stability of the protein is decreased at low pH and increased by high salt concentration. The salt dependence suggests that two ions bind preferentially to the folded protein. In 10 mM potassium phosphate (pH 7.3) and 100 mM KCl, the unfolding free energy reaches a maximum near room temperature. The results suggest that at the low protein concentrations where operator DNA binding is normally measured, Arc is predominantly monomeric and unfolded.     

Cooperativity and specificity in the interactions between DNA and the glucocorticoid receptor DNA-binding domain

We have employed fluorescence spectroscopy to study the chemical equilibrium between a 115 amino acid protein fragment containing the DNA-binding domain of the human glucocorticoid receptor (DBDr) and a 24-base-pair DNA oligomer containing the glucocorticoid response element (GRE) from the mouse mammary tumor virus promoter region and compared it with the binding to nonspecific DNA at various ionic conditions. We find that binding to both DNAs is cooperative but that DBDr shows a higher affinity for the GRE than for nonspecific DNA and that this difference is more pronounced at increased salt concentrations. Sequence-specific binding to the GRE sequence at 570 mM monovalent cations can be described by a two-site cooperative model, and this supports the notion that DBDr binding to the GRE is enhanced by dimer formation at the recognition site. The product between the (average) association constant for binding to a GRE half-site and the cooperativity parameter was estimated to be K omega = (1-4) x 10(7) M-1 at this salt concentration and 20 degrees C. The sequence-specific binding is not very sensitive to salt concentration in the interval 270-570 mM monovalent cations. However, at lower salt (70 mM) additional binding takes place, presumably nonspecific (cooperative) association to DNA adjacent to the GRE sequence. DBDr binding to nonspecific DNA can be described by the McGhee-von Hippel model for cooperative binding to a chain polymer and is very sensitive to ionic conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Escherichia coli cAMP receptor protein: evidence for three protein conformational states with different promoter binding affinities

Cyclic AMP receptor protein (CRP) from Escherichia coli is assumed to exist in two states, namely, those represented by the free protein and that of the ligand-protein complex. To establish a quantitative structure-function relation between cAMP binding and the cAMP-induced conformational changes in the receptor, protein conformational change was quantitated as a function of cAMP concentration up to 10 mM. The protein conformation was monitored by four different methods at pH 7.8 and 23 degrees C, namely, rate of proteolytic digestion by subtilisin, rate of chemical modification of Cys-178, tryptophan fluorescence, and fluorescence of the extrinsic fluorescence probe 8-anilino-1-naphthalenesulfonic acid (ANS). Each of these techniques reveals a biphasic dependence of protein conformation on cAMP concentration. At low cAMP concentrations ranging from 0 to 200 microM, the rates of proteolytic digestion and that of Cys-178 modification increase, whereas the fluorescence intensity of the ANS-protein complex is quenched, and there is no change in the fluorescence intensity of the tryptophan residues in the protein. At higher cAMP concentrations, the rates of proteolytic and chemical modification of the protein decrease, while the fluorescence intensity of the ANS-protein complex is further quenched but there is an increase in the intensity of tryptophan fluorescence. These results show unequivocally that there are at least three conformational states of the protein. The association constants for the formation of CRP-cAMP and CRP-(cAMP)2 complexes derived from conformational studies are in good agreement with those determined by equilibrium dialysis, nonequilibrium dialysis, and ultrafiltration. Therefore, the simplest explanation would be that the protein exhibits three conformational states, free CRP and two cAMP-dependent states, which correspond to the CRP-cAMP and CRP-(cAMP)2 complexes. The binding properties of CRP-cAMP and CRP-(cAMP)2 to the lac promoter were studied by using the gel retardation technique. At a high concentration of cAMP which favors the formation of the CRP-(cAMP)2 complex, binding of the protein to DNA is decreased. This, together with conformational data, strongly suggests that only the CRP-cAMP complex is active in specific DNA binding whereas CRP and CRP-(cAMP)2 are not.     

A new DNA binding mode for CAP

In the absence of cyclic AMP, the Escherichia coli cyclic AMP receptor protein (CAP) binds without detectable sequence specificity to restriction fragments containing lac and crp promoter sequences. Under standard conditions (10 mM Tris, 1 mM EDTA, pH 8.0), our estimates of the equilibrium constant and cooperativity parameter for complex formation are 114,000 +/- 1400 M-1 and 1.3 +/- 0.8, respectively. Thus, this interaction lacks the substantial cooperativity previously reported for CAP binding to genomic DNAs. Using the electrophoresis mobility shift assay, we find that complexes of increasing CAP content differ by a highly uniform mobility decrement. This result is most consistent with a binding mode in which little or no DNA bending occurs. The ability of CAP to distinguish between restriction fragments and genomic DNA, shown by the difference in binding cooperativity, suggests the existence of previously unsuspected DNA sequences or structures that modulate its binding cooperativity.     

Equilibrium studies of the cyclic AMP receptor protein-DNA interaction

The binding of the Escherichia coli cyclic AMP receptor protein (CAP) to restriction fragments containing the lac promoter-operator region has been investigated as a function of cAMP concentration, using a sensitive gel electrophoresis assay. Under standard conditions (13 mM ionic strength), the equilibrium constant for CAP binding to its primary site on a 203 base-pair lac promoter fragment is 6.3 X 10(8) M-1 at 0.2 microM-cAMP, and increases to 8.4 X 10(10) M-1 at 5.0 microM-cAMP. The latter is about 10(5) times larger than the equilibrium constant for binding to an isolated, non-specific site. The L8 mutation, which renders the lac promoter unresponsive to CAP in vivo, lowers this binding affinity by five- to tenfold. Analysis of the cAMP dependency of binding over the concentration range of 0.2 microM to 10 microM reveals that uptake of a single equivalent of cAMP is required for site-specific binding. Similarly, the transfer of CAP from a non-specific DNA site to a specific site requires the net uptake of a single molecule of cAMP. In contrast, co-operative non-specific binding to DNA was found to be independent of cAMP concentration with an equilibrium binding constant of 6 X 10(6) M-1. We conclude that the cAMP affinity of the two CAP subunits in the specific promoter complex is not equal, and that the complex structure therefore deviates significantly from twofold symmetry. A model for the regulation of the lac promoter by the intracellular cAMP concentration is proposed on the basis of the equilibrium binding results.     

Ligand-modulated binding of a gene regulatory protein to DNA. Quantitative analysis of cyclic-AMP induced binding of CRP from Escherichia coli to non-specific and specific DNA targets

This paper describes a generally applicable method for quantitative investigation of ligand-dependent binding of a regulatory protein to its target DNA at equilibrium. It is used here to analyse the coupled binding equilibria of cAMP receptor protein from Escherichia coli K12 (CRP) with DNA and the physiological effector cAMP. In principle, the DNA binding parameters of CRP dimers with either one or two ligands bound are determinable in such an approach. The change of protein fluorescence was used to measure CRP binding to its recognition sequence in the lac control region and to non-specific DNA. Furthermore, the binding of cAMP to preformed CRP-DNA complexes was independently studied by equilibrium dialysis. The data were analysed using a simple interactive model for two intrinsically identical sites and site-site interactions. The intrinsic binding constant K and the co-operativity factor alpha for binding of cAMP to free CRP depend only slightly on salt concentration between 0.01 M and 0.2 M. In contrast, the affinity of cAMP for CRP pre-bound to non-specific DNA increases with the salt concentration and the co-operativity changes from positive to negative. This results from cation rebinding to the DNA lattice upon forming the cAMP-CRP-DNA complex from cAMP and the pre-formed CRP-DNA complex. The CRP-cAMP1 complex shows almost the same affinity for specific and non-specific DNA as the CRP-cAMP2 complex, and both displace the same number of cations. It is concluded that the allosteric activation of CRP is induced upon binding of the first cAMP. These results are used to estimate the occupation of the CRP site in the lac control region in relation to the cAMP concentration in vivo. Under physiological conditions the lac promoter is activated by the CRP dimer complexed with only one cAMP. Furthermore, a model for the differential activation of various genes expressed under catabolite repression is presented and discussed.     

Comparison of cAMP receptor protein (CRP) and a cAMP-independent form of CRP by Raman spectroscopy and DNA binding.

The secondary structures of the cAMP receptor protein (CRP), a complex of CRP and cAMP, and a cAMP-independent receptor protein mutant (CRP*141 gln) were examined by using Raman spectroscopy. Spectra were obtained from CRP and CRP*141 gln dissolved in 0.3 M NaCl and 30 mM sodium phosphate at protein concentrations of 30-40 mg/mL. CRP and CRP.cAMP1 were compared at lower protein concentrations (10-12 mg/mL) in a solvent of 0.35 M NaCl and 20 mM sodium phosphate. Raman analysis indicates that CRP structural changes induced by one bound cAMP or by the Gly to Gln mutation at residue 141 are small. Spectra of the three CRP samples are essentially identical from 400 to 1900 cm-1. This result differs from the Raman spectroscopy study of CRP and CRP.cAMP2 cocrystals [DeGrazia et al. (1990) Biochemistry 29, 3557]. The latter work showed spectral differences between CRP and CRP.cAMP2 consistent with alterations in the protein conformation. These studies indicate that CRP and CRP.cAMP1 in solution are similar in structure and differ from CRP.cAMP2 cocrystals. Protease digestion and a DNA binding assay were also employed to characterize the wild-type and mutant proteins. CRP*141 gln exhibited the same conformational characteristics of previously reported cAMP-independent mutant proteins. It was sensitive to proteolytic attack in the absence of cAMP, or upon addition of cGMP. In the absence of cAMP, both wild-type and mutant CRPs bound noncooperatively to a 62 bp lac promoter DNA. The equilibrium constants were approximately 10(6) M-1 in 0.1 M Na+. CRP*141 gln had a 2-4-fold higher affinity for the 62 bp DNA than CRP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structures during binding of cAMP receptor to promoter DNA: promoter search slowed by non-specific sites

The kinetics of cAMP receptor (CAP) binding to promoter DNA has been studied by stopped-flow electric-dichroism at a reduced salt concentration, where the coupling of non-specific and specific binding can be observed directly. Amplitudes, rise and decay times of dichroism transients provide detailed information about the reaction and the structure of intermediates over more than six orders of magnitude on the time scale. CAP binding during the first milliseconds after mixing is indicated by an increase of both rise- and decay-time constants. A particularly large increase of rise times reflects initial formation of non-symmetric complexes by protein binding to non-specific sites at DNA ends. The increase of the hydrodynamic dimensions continues up to ~1 s, before a decrease of time constants reflects transition to compact states with bent DNA up to the time range of ~10³ s. The slow approach to CAP-induced DNA bending is due to non-specific complexes, which are formed initially and are converted slowly to the specific complex. At the salt concentration of 13.5 mM, conversion to specific complexes with bent DNA is completed after ~40 s at pH 8 compared to >10³ s at pH 7, resulting from a higher affinity of CAP to non-specific sites at pH 7 than 8 by a factor of ~100. Thus, under the given conditions non-specific sites delay rather than facilitate formation of the specific complex with bent DNA. Experimental data obtained for a non-specific DNA clearly indicate the impact of pseudo-sites. The different electro-optical parameters have been combined in global fits.     

The change of DNA structure by specific binding of the cAMP receptor protein from rotation diffusion and dichroism measurements.

The structure of complexes formed between cAMP receptor protein (CRP) and various restriction fragments from the promoter region of the lactose operon has been analysed by measurements of electrodichroism. Binding of CRP to a 62-bp fragment containing the major site leads to an increase of the rotation time constant from 0.33 to 0.43 microseconds; addition of cAMP to the complex induces a decrease to 0.25 microseconds. Similar data are obtained for a 80-bp fragment containing the operator site; however, in this case the decrease of the rotation time for the specific complex is only observed when the salt concentration is increased from 3 to 13 mM. A 203-bp fragment containing both sites showed a corresponding change after pre-incubation at 50 mM salt. The salt dependence of the rotation time for the specific complex formed with the 203-bp fragment also indicates that a compact structure is formed at 13 mM salt, whereas the structure is not as compact at 3 mM salt. A 98-bp fragment without specific CRP sites did not reveal changes corresponding to those observed for the specific fragments. The rotation time constants together with the dichroism amplitudes indicate that binding of CRP to specific sites in the presence of cAMP leads to the formation of compact structures, which are consistent with bending of DNA helices. The observed strong salt dependence of the structure is apparently due to electrostatic repulsion between adjoining helix segments.     

Regulation of the Escherichia coli L-arabinose operon studied by gel electrophoresis DNA binding assay

DNA binding properties of the proteins required for induction of the Escherichia coli L-arabinose operon were measured using a polyacrylamide gel electrophoresis assay. The mechanisms of induction and repression were studied by observing the multiple interactions of RNA polymerase, cyclic AMP receptor protein and araC protein with short DNA fragments containing either the araC or araBAD promoter regions. These studies show that binding of araC protein to the operator site, araO1, directly blocks RNA polymerase binding at the araC promoter, pC. We find that cyclic AMP receptor protein and araC protein do not bind co-operatively at their respective sites to linear DNA fragments containing the pBAD promoter. Nevertheless, both these positive effectors must be present on the DNA to stimulate binding of RNA polymerase. Additionally, binding of the proteins to the DNA is not sufficient; araC protein must also be in the inducing state, for RNA polymerase to bind. Equilibrium binding constraints and kinetics were determined for araC protein binding to the araI and the araO1 sites. In the presence of inducer, L-arabinose, araC protein binds with equal affinity to DNA fragments containing either of these sites. In the presence of anti-inducer, D-fucose, the affinity for both sites is reduced 40-fold. The apparent equilibrium binding constants for both states of the protein vary in parallel with the buffer salt concentration. This result suggests that the inducing and repressing forms of araC protein displace a similar number of cations upon binding DNA.     

In vitro interaction of the Escherichia coli cyclic AMP receptor protein with the lactose repressor

Sedimentation equilibrium studies show that the Escherichia coli cyclic AMP receptor protein (CAP) and lactose repressor associate to form a 2:1 complex in vitro. This is, to our knowledge, the first demonstration of a direct interaction of these proteins in the absence of DNA. No 1:1 complex was detected over a wide range of CAP concentrations, suggesting that binding is highly cooperative. Complex formation is stimulated by cAMP, with a net uptake of 1 equivalent of cAMP per molecule of CAP bound. Substitution of the dimeric lacI-18 mutant repressor for tetrameric wild-type repressor completely eliminates detectable binding. We therefore propose that CAP binds the cleft between dimeric units in the repressor tetramer. CAP-lac repressor interactions may play important roles in regulatory events that take place at overlapping CAP and repressor binding sites in the lactose promoter.     

Characterization of the self association of Avian sarcoma virus integrase by analytical ultracentrifugation.

Retroviral integration protein (IN) has been shown to be both necessary and sufficient for the integration of reverse-transcribed retroviral DNA into the host cell DNA. It has been demonstrated that self-assembly of IN is essential for proper function. Analytical ultracentrifugation was used to determine the stoichiometry and free energy of self-association of a full-length IN in various solvents at 23.3 degrees C. Below 8% glycerol, an association stoichiometry of monomer-dimer-tetramer is observed. At salt concentrations above 500 mM, dimer is the dominant species over a wide range of protein concentrations. However, as physiological salt concentrations are approached, tetramer formation is favored. The addition of glycerol to 500 mM NaCl, 20 mM Tris (pH 8.4), 2 mM beta-mercaptoethanol significantly enhances dimer formation with little effect on tetramer formation. Furthermore, as electrostatic shielding is increased by increasing the ionic strength or decreasing the cation size, dimer formation is strengthened while tetramer formation is weakened. Taken together, the data support a model in which dimer formation includes favorable buried surface interactions which are opposed by charge-charge repulsion, while favorable electrostatic interactions contribute significantly to tetramer formation.     

CAP and RNA polymerase interactions with the lac promoter: binding stoichiometry and long range effects.

The binding stoichiometries of the complexes formed when the E. coli cyclic AMP receptor protein (CAP) binds to 203 bp lac promoter-operator restriction fragments have been determined. Under quantitative binding conditions, a single dimer of CAP occupies each of two sites in the promoter. Different electrophoretic mobilities are observed for 1:1 complexes formed with L8-UV5 mutant, L305 mutant, and wild type promoter fragments, indicating sequence-specific structural differences between the complexes. The differences in gel mobility between L8-UV5 and wild type complexes disappear when the promoter fragments are cleaved with Hpa II restriction endonuclease. Models in which CAP alters DNA conformation or in which CAP forms a transient intramolecular bridge between two domains of a DNA molecule could account for these observations. The selective binding of RNA polymerase to CAP-promoter complexes is demonstrated: the binding of a single CAP dimer to the promoter is sufficient to stimulate subsequent polymerase binding. Functional CAP molecules are not released from the promoter on polymerase binding.     

High resolution experimental and theoretical thermal denaturation studies on small overlapping restriction fragments containing the Escherichia coli lactose genetic control region

The distribution of thermal stability in the Escherichia coli lac control region is evaluated from the melting behavior of 5 short (80-219 base pairs (bp)) sequenced DNA restriction fragments containing various parts of this sequence. The thermal denaturation of these fragments was measured at 3 salt concentrations. The previous notion that the melting curves for small fragments are sharp and asymmetric in 0.01 M Na+ and broadened and less asymmetric at 0.105 and 0.505 M Na+ is confirmed and the possible explanations are discussed. The existence of two thermodynamic boundaries in this region is also confirmed. The exact location of the boundary upstream of the cyclic AMP receptor protein (CAP) binding site is accurately determined from melting experiments at 260 and 282 nm. The secondary boundary located between the promoter and operator sequence is apparent at the two higher salt concentrations and begins to disappear at the lower salt concentration. The physical interpretation of the melting experiments is compared to the results of theoretical predictions derived from the known sequence of the fragments.     

Energetics of subunit dimerization in bacteriophage lambda cI repressor: linkage to protons, temperature, and KCl.

A common feature of gene regulatory systems is the linkage between reversible protein oligomerization and DNA binding. Experimental dissection using temperature dependence of the subunit-subunit energetics and their linkage to processes such as ion binding and release is necessary for characterization of the chemical forces that contribute to cooperativity and site specificity. We have therefore studied the effects of temperature, proton activity, and monovalent salt on monomer-dimer assembly of the lambda cI repressor using a recently developed gel chromatographic procedure. This technique has made possible studies in the previously inaccessible picomolar concentration ranges where the assembly reactions occur. Upon formation of the dimer interface in the range pH 5-9, we find an overall absorption of protons which is temperature-dependent. The dimerization reaction displays a large negative enthalpy of association at all conditions studied (pH 5, 7, and 9). The reaction is also dependent on monovalent salt concentration: subunit association is weaker at low-salt conditions. The results suggest that a repulsive interaction between negatively charged side chains (i.e., aspartates and glutamates) on each monomer surface is attenuated by increasing concentrations of KCl. Formation of the dimer interface may be mediated by absorption of cations which stabilize the complex.