Linkage of protein assembly to protein-DNA binding

Coupling of binding and differential subdomain folding of the intrinsically disordered transcription factor CREB

The cyclic AMP response element binding protein (CREB) contains a basic leucine zipper motif (bZIP) that forms a coiled coil structure upon dimerization and specific DNA binding. Although this state is well characterized, key features of CREB bZIP binding and folding are not well understood. We used single-molecule Förster resonance energy transfer (smFRET) to probe conformations of CREB bZIP subdomains. We found differential folding of the basic region and leucine zipper in response to different binding partners; a strong and previously unreported DNA-independent dimerization affinity; folding upon binding to nonspecific DNA; and evidence of long-range interdomain interactions in full-length CREB that modulate DNA binding. These studies provide new insights into DNA binding and dimerization and have implications for CREB function.

Allosteric modulation of nucleoporin assemblies by intrinsically disordered regions

Intrinsically disordered regions (IDRs) of proteins are implicated in key macromolecular interactions. However, the molecular forces underlying IDR function within multicomponent assemblies remain elusive. By combining thermodynamic and structural data, we have discovered an allostery-based mechanism regulating the soluble core region of the nuclear pore complex (NPC) composed of nucleoporins Nup53, Nic96, and Nup157. We have identified distinct IDRs in Nup53 that are functionally coupled when binding to partner nucleoporins and karyopherins (Kaps) involved in NPC assembly and nucleocytoplasmic transport. We show that the Nup53·Kap121 complex forms an ensemble of structures that destabilize Nup53 hub interactions. Our study provides a molecular framework for understanding how disordered and folded domains communicate within macromolecular complexes.

Inhibition of amyloid beta fibril formation by monomeric human transthyretin

Transthyretin (TTR) is a homotetrameric protein that is found in the plasma and cerebrospinal fluid. Dissociation of TTR tetramers sets off a downhill cascade of amyloid formation through polymerization of monomeric TTR. Interestingly, TTR has an additional, biologically relevant activity, which pertains to its ability to slow the progression of amyloid beta (Aβ) associated pathology in transgenic mice. In vitro, both TTR and a kinetically stable variant of monomeric TTR (M-TTR) inhibit the fibril formation of Aβ1-40/42 molecules. Published evidence suggests that tetrameric TTR binds preferentially to Aβ monomers, thus destabilizing fibril formation by depleting the pool of Aβ monomers from aggregating mixtures. Here, we investigate the effects of M-TTR on the in vitro aggregation of Aβ1-42 . Our data confirm previous observations that fibril formation of Aβ is suppressed in the presence of sub-stoichiometric amounts of M-TTR. Despite this, we find that sub-stoichiometric levels of M-TTR are not bona fide inhibitors of aggregation. Instead, they co-aggregate with Aβ to promote the formation of large, micron-scale insoluble, non-fibrillar amorphous deposits. Based on fluorescence correlation spectroscopy measurements, we find that M-TTR does not interact with monomeric Aβ. Two-color coincidence analysis of the fluorescence bursts of Aβ and M-TTR labeled with different fluorophores shows that M-TTR co-assembles with soluble Aβ aggregates and this appears to drive the co-aggregation into amorphous precipitates. Our results suggest that mimicking the co-aggregation activity with protein-based therapeutics might be a worthwhile strategy for rerouting amyloid beta peptides into inert, insoluble, and amorphous deposits.

Analysis of Linked Equilibria

The ATPases associated with diverse cellular activities (AAA+) is a large superfamily of proteins involved in a broad array of biological processes. Many members of this family require nucleotide binding to assemble into their final active hexameric form. We have been studying two example members, Escherichia coli ClpA and ClpB. These two enzymes are active as hexameric rings that both require nucleotide binding for assembly. Our studies have shown that they both reside in a monomer, dimer, tetramer, and hexamer equilibrium, and this equilibrium is thermodynamically linked to nucleotide binding. Moreover, we are finding that the kinetics of the assembly reaction are very different for the two enzymes. Here, we present our strategy for determining the self-association constants in the absence of nucleotide to set the stage for the analysis of nucleotide binding from other experimental approaches including analytical ultracentrifugation.

Monomeric nature of dengue virus NS3 helicase and thermodynamic analysis of the interaction with single-stranded RNA

Dengue virus nonstructural protein 3 (NS3) is a multifunctional protein formed by a superfamily-2 RNA helicase linked to a protease domain. In this work, we report results from in vitro experiments designed to determine the oligomeric state of dengue virus NS3 helicase (NS3h) and to characterize fundamental properties of the interaction with single-stranded (ss)RNA. Pulsed field gradient-NMR spectroscopy was used to determine the effective hydrodynamic radius of NS3h, which was constant over a wide range of protein concentrations in the absence and presence of ssRNA. Size exclusion chromatography-static light scattering experiments showed that NS3h eluted as a monomeric molecule even in the presence of ssRNA. Binding of NS3h to ssRNA was studied by quantitative fluorescence titrations using fluorescein-labeled and unlabeled ssRNA oligonucleotides of different lengths, and the effect of the fluorescein label on the interaction parameters was also analyzed. Experimental results were well described by a statistical thermodynamic model based on the theory of non-specific interactions of large ligands to a one-dimensional lattice. We found that binding of NS3h to ssRNA oligonucleotides and to poly(A) is characterized by minimum and occluded binding site sizes both of 10 nucleotides and by a weak positive cooperativity between adjacent proteins.

Quantitative analysis of affinity enhancement by noncovalently oligomeric ligands

Designed ligands that self-assemble noncovalently via an independent oligomerization domain have demonstrated enhancement in affinity for a variety of chemical and biological targets. To better understand the thermodynamic linkage between enhanced receptor binding and self-assembly, we have developed linkage models for the three commonly encountered types of noncovalently oligomeric ligands: homofunctional oligomeric ligands, heterodimeric ligands that target a single receptor, and bispecific ligands that crosslink noninteracting receptors. Expressions and numerical approaches for exact analysis as a function of total ligand concentrations are provided. We apply the linkage models to the binding data for two published noncovalently oligomeric ligands: one targeting a small molecule (phosphocholine) and the other targeting a soluble protein (tumor necrosis factor α). The linkage models provide a quantitative measure of the potential and realized enhancement in affinity that could inform and guide design optimization efforts, and they reveal physical insight that would elude model-free analysis. Incorporation of the linkage models, therefore, is expected to be valuable in the rational engineering of noncovalently oligomeric ligands.

Negative co-operativity in the EGF receptor

Scatchard analyses of the binding of EGF (epidermal growth factor) to its receptor (EGFR) yield concave up Scatchard plots, indicative of some type of heterogenity in ligand-binding affinity. This was typically interpreted as being due to the presence of two independent binding sites: one of high affinity representing ≤10% of the receptor population, and one of low affinity making up the bulk of the receptors. However, the concept of two independent binding sites is difficult to reconcile with the X-ray structures of the dimerized EGFR that show symmetrical binding of the two ligands. A new approach to the analysis of 125I-EGF-binding data combined with the structure of the singly-occupied Drosophila EGFR have now shown that this heterogeneity is due to the presence of negative co-operativity in the EGFR. Concerns that negative co-operativity precludes ligand-induced dimerization of the EGFR confuse the concepts of linkage and co-operativity. Linkage refers to the effect of ligand on the assembly of dimers, whereas co-operativity refers to the effect of ligand binding to one subunit on ligand binding to the other subunit within a preassembled dimer. Binding of EGF to its receptor is positively linked with dimer assembly, but shows negative co-operativity within the dimer.

The membrane-proximal intracellular domain of the epidermal growth factor receptor underlies negative cooperativity in ligand binding

The binding of EGF induces dimerization of its receptor, leading to the stimulation of its intracellular tyrosine kinase activity. Kinase activation occurs within the context of an asymmetric dimer in which one kinase domain serves as the activator for the other kinase domain but is not itself activated. How ligand binding is related to the formation and dynamics of this asymmetric dimer is not known. The binding of EGF to its receptor is negatively cooperative--that is, EGF binds with lower affinity to the second site on the dimer than to the first site on the dimer. In this study, we analyzed the binding of (125)I-EGF to a series of EGF receptor mutants in the intracellular juxtamembrane domain and demonstrate that the most membrane-proximal portion of this region plays a significant role in the genesis of negative cooperativity in the EGF receptor. The data are consistent with a model in which the binding of EGF to the first site on the dimer induces the formation of one asymmetric kinase dimer. The binding of EGF to the second site is required to disrupt the initial asymmetric dimer and allow the formation of the reciprocal asymmetric dimer. Thus, some of the energy of binding to the second site is used to reorient the first asymmetric dimer, leading to a lower binding affinity and the observed negative cooperativity.

Thermodynamic linkage of large-scale ligand aggregation with receptor binding

There are many examples in the literature that deal explicitly with the coupling of ligand oligomerization with receptor binding. For example, many transcription factors dimerize and this plays a fundamental role in sequence specific DNA recognition. However, many biological macromolecules undergo reversible, large scale aggregation processes, some of which are indefinite. The thermodynamic coupling of these aggregation processes to other processes, such as protein-protein and protein-DNA interactions, has not been explored in depth. Here we consider the thermodynamic consequences of large scale ligand aggregation on the determination of fundamental thermodynamic parameters, such as equilibrium binding constants and ligand-receptor stoichiometries. We find that a fundamental consequence of an aggregating ligand is that the free ligand concentration (ligand that is not found in aggregates) is buffered over a wide total ligand concentration range. In general, the larger the size of the aggregates, the wider the range over which the free ligand concentration is buffered. An additional consequence of this observation is that an upper limit is set on the fractional occupancy of the ligand's receptor, such that even if the ligand is over-expressed to very high levels in the cell, this will not necessarily ensure that 100% of the ligand's receptors will be occupied. The implications of these results for sequence specific DNA binding proteins will be discussed.

The intracellular juxtamembrane domain of the epidermal growth factor (EGF) receptor is responsible for the allosteric regulation of EGF binding

We have previously shown that the binding of epidermal growth factor (EGF) to its receptor can best be described by a model that involves negative cooperativity in an aggregating system (Macdonald, J. L., and Pike, L. J. (2008) Proc. Natl. Acad. Sci. U. S. A. 105, 112-117). However, despite the fact that biochemical analyses indicate that EGF induces dimerization of its receptor, the binding data provided no evidence for positive linkage between EGF binding and dimer assembly. By analyzing the binding of EGF to a number of receptor mutants, we now report that in naive, unphosphorylated EGF receptors, ligand binding is positively linked to receptor dimerization but the linkage is abolished upon autophosphorylation of the receptor. Both phosphorylated and unphosphorylated EGF receptors exhibit negative cooperativity, indicating that mechanistically, cooperativity is distinct from the phenomenon of linkage. Nonetheless, both the positive linkage and the negative cooperativity observed in EGF binding require the presence of the intracellular juxtamembrane domain. This indicates the existence of inside-out signaling in the EGF receptor system. The intracellular juxtamembrane domain has previously been shown to be required for the activation of the EGF receptor tyrosine kinase (Thiel, K. W., and Carpenter, G. (2007) Proc. Natl. Acad. Sci. U. S. A. 104, 19238-19243). Our experiments expand the role of this domain to include the allosteric control of ligand binding by the extracellular domain.

Heterogeneity in EGF-binding affinities arises from negative cooperativity in an aggregating system

Scatchard analysis of the binding of EGF to its receptor yields concave up plots that indicate the presence of two classes of binding sites. However, how two independent classes of sites arise from the expression of a single EGF receptor protein has never been adequately explained. Using a new analytical approach involving the simultaneous fitting of binding isotherms from cells expressing increasing levels of EGF receptors, we show that (125)I-EGF-binding data can be completely explained by a model involving negative cooperativity in an aggregating system. This approach provides an experimentally determined value for the monomer-dimer equilibrium constant, which, for wild-type EGF receptors, corresponds to approximately 50,000 receptors per cell. Therefore, changes in receptor expression within the physiological range can modulate the outcome of a signaling stimulus. Analysis of the L680N-EGF receptor mutant, in which the formation of asymmetric kinase domain dimers is blocked, indicates that the kinase dimers make a substantial energetic contribution to the ligand-independent association of EGF receptor monomers, but are not necessary for negative cooperativity. The model accurately predicts the behavior of receptor mutants, such as the dimerization-defective Y246D-EGF receptor, which exhibit a single class of binding sites and provides a framework for understanding secondary dimer formation and lateral signaling in the EGF receptor family.

Assembly and molecular activities of the MutS tetramer

Analytical equilibrium ultracentrifugation indicates that Escherichia coli MutS exists as an equilibrating mixture of dimers and tetramers. The association constant for the dimer-to-tetramer transition is 2.1 x 10(7) M-1, indicating that the protein would consist of both dimers and tetramers at physiological concentrations. The carboxyl terminus of MutS is required for tetramer assembly because a previously described 53-amino acid carboxyl-terminal truncation (MutS800) forms a limiting species of a dimer (Obmolova, G., Ban, C., Hsieh, P., and Yang, W. (2000) Nature 407, 703-710; Lamers, M. H., Perrakis, A., Enzlin, J. H., Winterwerp, H. H., de Wind, N., and Sixma, T. K. (2000) Nature 407, 711-717). MutS800 binds a 20-base pair heteroduplex an order of magnitude more weakly than full-length MutS, and at saturating protein concentrations, the heteroduplex-bound mass observed with MutS800 is only half that observed with the full length protein, indicating that the subunit copy number of heteroduplex-bound MutS is twice that of MutS800. Analytical equilibrium ultracentrifugation using a fluorescein-tagged 20-base pair heteroduplex demonstrated that native MutS forms a tetramer on this single site-sized heteroduplex DNA. Equilibrium fluorescence experiments indicated that dimer-to-tetramer assembly promotes mismatch binding by MutS and that the tetramer can bind only a single heteroduplex molecule, implying nonequivalence of the two dimers within the tetramer. Compared with native MutS, the ability of MutS800 to promote MutL-dependent activation of MutH is substantially reduced.

A dimeric mechanism for contextual target recognition by MutY glycosylase

MutY, an adenine glycosylase, initiates the critical repair of an adenine:8-oxo-guanine base pair in DNA arising from polymerase error at the oxidatively damaged guanine. Here we demonstrate for the first time, using presteady-state active site titrations, that MutY assembles into a dimer upon binding substrate DNA and that the dimer is the functionally active form of the enzyme. Additionally, we observed allosteric inhibition of glycosylase activity in the dimer by the concurrent binding of two lesion mispairs. Active site titration results were independently verified by gel mobility shift assays and quantitative DNA footprint titrations. A model is proposed for the potential functional role of the observed polysteric and allosteric regulation in recruiting and coordinating interactions with the methyl-directed mismatch repair system.

Concerted binding and bending of DNA by Escherichia coli integration host factor

Integration host factor (IHF) is a heterodimeric Escherichia coli protein that plays essential roles in a variety of cellular processes including site-specific recombination, transcription, and DNA replication. The IHF-DNA interface extends over three helical turns and includes sequential minor groove contacts that present strong, sequence specific protection patterns against hydroxyl radical cleavage. Synchrotron X-ray footprinting has been used to follow the kinetics of formation of DNA-protein contacts in the IHF-DNA complex with single base-pair spatial, and millisecond time, resolution. The three sites of IHF protection on the DNA develop with similar time-dependence, indicating that sequence specific binding and bending occur concertedly. Two distinct phases are observed in the association process. The first "burst" phase is characterized by a rate that is greater than diffusion limited (>10(10) s(-1) M(-1)) and the second phase is on the order of diffusion controlled (approximately 10(8) M(-1) s(-1)). The overall kinetics of association become faster with increasing IHF concentration showing that complex formation is second-order with protein. The rate of association is maximal between 100 and 200 mM KCl decreasing at higher and lower concentrations. The rate of IHF dissociation from site-specifically bound DNA increases monotonically as KCl concentration is increased. The dissociation progress curves are biphasic with the amplitude of the first phase dependent upon competitor DNA concentration. These results are the first analysis by synchrotron footprinting of the fast kinetics of a protein-DNA interaction and suggest that IHF binds its specific site through a multiple-step mechanism in which the first step is facilitated diffusion along the length of the duplex followed by subsequent binding and bending of the DNA in a concerted manner.

Analytic binding isotherms describing competitive interactions of a protein ligand with specific and nonspecific sites on the same DNA oligomer

Many studies of specific protein-nucleic acid binding use short oligonucleotides or restriction fragments, in part to minimize the potential for nonspecific binding of the protein. However, when the specificity ratio is low, multiple nonspecifically bound proteins may occupy the region of DNA corresponding to one specific site; this situation was encountered in our recent calorimetric study of binding of integration host factor (IHF) protein to its specific 34-bp H' DNA site. Here, beginning from the analytical McGhee and von Hippel infinite-lattice nonspecific binding isotherm, we derive a novel analytic isotherm for nonspecific binding of a ligand to a finite lattice. This isotherm is an excellent approximation to the exact factorial-based Epstein finite lattice isotherm even for short lattices and therefore is of great practical significance for analysis of experimental data and for analytic theory. Using this isotherm, we develop an analytic treatment of the competition between specific and nonspecific binding of a large ligand to the same finite lattice (i.e., DNA oligomer) containing one specific and multiple overlapping nonspecific binding sites. Analysis of calorimetric data for IHF-H' DNA binding using this treatment yields enthalpies and binding constants for both specific and nonspecific binding and the nonspecific site size. This novel analysis demonstrates the potential contribution of nonspecific binding to the observed thermodynamics of specific binding, even with very short DNA oligomers, and the need for reverse (constant protein) titrations or titrations with nonspecific DNA to resolve specific and nonspecific contributions. The competition treatment is useful in analyzing low-specificity systems, including those where specificity is weakened by mutations or the absence of specificity factors.

Requirements for osmosensing and osmotic activation of transporter ProP from Escherichia coli

Transporter ProP of Escherichia coli, a solute-H+ symporter, can sense and respond to osmotic upshifts imposed on cells, on membrane vesicles, or on proteoliposomes that incorporate purified ProP-(His)6. In this study, proline uptake catalyzed by ProP was used as a measure of its osmotic activation, and the requirements for osmosensing were defined using the proteoliposome system. The initial rate of proline uptake increased with decreasing external pH and increasing DeltaPsi, lumen negative. Osmotic upshifts increased DeltaPsi by concentrating lumenal K+, but osmotic activation of ProP could be distinguished from this effect. Osmotic activation of ProP resulted from changes in Vmax, though osmotic shifts also increased the KM for proline. Osmotic activation could be described as a reversible, osmotic upshift-dependent transition linking (at least) two transporter protein conformations. No correlation was observed between ProP activation and the position of the anions of activating sodium salts within the Hofmeister series of solutes. Both the magnitude of the osmotic upshift required to activate ProP and the ProP activity attained were similar for membrane-impermeant osmolytes, including NaCl, glucose, and PEG 600. The membrane-permeant osmolytes glycerol, urea, PEG 62, and PEG 106 failed to activate ProP. Two poly(ethylene glycol)s, PEG 150 and PEG 200, were membrane-permeant and did not cause liposome shrinkage, but they did partially activate ProP-(His)6.

Site-specific cation binding mediates TATA binding protein-DNA interaction from a hyperthermophilic archaeon

Pyrococcus woesei (Pw) is a hyperthermophilic archaeal organism that exists under conditions of high salt and elevated temperature. In a previous study [O'Brien, R., DeDecker, B., Fleming, K., Sigler, P. B., and Ladbury, J. E., (1998) J. Mol. Biol. 279, 117-125], we showed that, despite the similarity of primary and secondary structure, the TATA box binding protein (TBP) from Pw binds thermodynamically in a fundamentally different way to its mesophilic counterparts. The affinity of the interaction increases as the salt concentration is increased. The formation of the protein-DNA complex involves the release of water and the uptake of ions, which were hypothesized to be cations. Here we test this hypothesis by selecting potential cation binding sites at negatively charged, acidic residues in the complex interface. These were substituted using site-directed mutagenesis of specific residues. Changes in the thermodynamic parameters on formation of the mutant protein-DNA complex were determined using isothermal titration calorimetry and compared to the wild type interaction. Removal of a glutamate residue from the binding site resulted in the uptake of one less cation on formation of the complex. This glutamate (E12) is directly involved in the binding of cations in the complex interface. Substitution of another acidic residue proximal to the DNA binding site (D101) had no effect on cation uptake, suggesting that the location of the amino acid on the protein surface is important in dictating the potential to coordinate cations. Removal of the cation binding site provided a more favorable entropy of binding; however, this effect is significantly reduced at higher salt concentrations. The removal of the cation binding site led to an increase in affinity with respect to the wild-type TBP at low salt concentrations.

The multifunctional bacteriophage P2 cox protein requires oligomerization for biological activity

The Cox protein of bacteriophage P2 is a multifunctional protein of 91 amino acids. It is directly involved in the site-specific recombination event leading to excision of P2 DNA out of the host chromosome. In this context, it functions as an architectural protein in the formation of the excisome. Cox is also a transcriptional repressor of the P2 Pc promoter, thereby ensuring lytic growth. Finally it promotes derepression of prophage P4, a nonrelated defective satellite phage, by activating the P4 P(LL) promoter that controls P4 DNA replication. In this case it binds upstream of the P(LL) promoter, which normally is activated by the P4 Delta protein. In this work we have analyzed the native form of the Cox protein in vivo, using a bacteriophage lambda cI-based oligomerization assay system, and in vitro, using gel filtration, cross-linking agents, and gel retardation assays. We found that P2 Cox has a strong oligomerization function in vivo as well as in vitro. The in vitro analysis indicates that its native form is a tetramer that can self-associate to octamers. Furthermore we show that oligomerization is necessary for the biological activity by characterizing different cox mutants and that oligomerization is mediated by the C-terminal region.

The N-terminal region of the human progesterone A-receptor. Structural analysis and the influence of the DNA binding domain

The role of the N-terminal region in nuclear receptor function was addressed by a biochemical and biophysical analysis of the progesterone receptor A-isoform lacking only the hormone binding domain (NT-A). Sedimentation studies demonstrate that NT-A is quantitatively monomeric, with a highly asymmetric shape. Contrary to dogma, the N-terminal region is structured as demonstrated by limited proteolysis. However, N-terminal structure is strongly stabilized by the DNA binding domain, possibly explaining the lack of structure seen in isolated activation domains. Upon DNA binding, NT-A undergoes N-terminal mediated assembly, suggestive of DNA-induced allostery, and consistent with changes in protease accessibility of sites outside the DNA binding domain. Microsequencing reveals that protease-accessible regions are limited to previously identified phosphorylation motifs and to functional domain boundaries.

Wrapping of flanking non-operator DNA in lac repressor-operator complexes: implications for DNA looping

In our studies of lac repressor tetramer (T)-lac operator (O) interactions, we observed that the presence of extended regions of non-operator DNA flanking a single lac operator sequence embedded in plasmid DNA produced large and unusual cooperative and anticooperative effects on binding constants (Kobs) and their salt concentration dependences for the formation of 1:1 (TO) and especially 1:2 (TO2) complexes. To explore the origin of this striking behavior we report and analyze binding data on 1:1 (TO) and 1:2 (TO2) complexes between repressor and a single O(sym) operator embedded in 40 bp, 101 bp, and 2514 bp DNA, over very wide ranges of [salt]. We find large interrelated effects of flanking DNA length and [salt] on binding constants (K(TO)obs, K(TO2)obs) and on their [salt]-derivatives, and quantify these effects in terms of the free energy contributions of two wrapping modes, designated local and global. Both local and global wrapping of flanking DNA occur to an increasing extent as [salt] decreases. Global wrapping of plasmid-length DNA is extraordinarily dependent on [salt]. We propose that global wrapping is driven at low salt concentration by the polyelectrolyte effect, and involves a very large number (>/similar 20) of coulombic interactions between DNA phosphates and positively charged groups on lac repressor. Coulombic interactions in the global wrap must involve both the core and the second DNA-binding domain of lac repressor, and result in a complex which is looped by DNA wrapping. The non-coulombic contribution to the free energy of global wrapping is highly unfavorable ( approximately +30-50 kcal mol(-1)), which presumably results from a significant extent of DNA distortion and/or entropic constraints. We propose a structural model for global wrapping, and consider its implications for looping of intervening non-operator DNA in forming a complex between a tetrameric repressor (LacI) and one multi-operator DNA molecule in vivo and in vitro. The existence of DNA wrapping in LacI-DNA interactions motivates the proposal that most if not all DNA binding proteins may have evolved the capability to wrap and thereby organize flanking regions of DNA.

Yeast Rad54 promotes Rad51-dependent homologous DNA pairing via ATP hydrolysis-driven change in DNA double helix conformation

Saccharomyces cerevisiae RAD54 gene functions in the formation of heteroduplex DNA, a key intermediate in recombination processes. Rad54 is monomeric in solution, but forms a dimer/oligomer on DNA. Rad54 dimer/oligomer alters the conformation of the DNA double helix in an ATP-dependent manner, as revealed by a change in the DNA linking number in a topoisomerase I-linked reaction. DNA conformational alteration does not occur in the presence of non-hydrolyzable ATP analogues, nor when mutant rad54 proteins defective in ATP hydrolysis replace Rad54. Accordingly, the Rad54 ATPase activity is shown to be required for biological function in vivo and for promoting Rad51-mediated homologous DNA pairing in vitro. Taken together, the results are consistent with a model in which a Rad54 dimer/oligomer promotes nascent heteroduplex joint formation via a specific interaction with Rad51 protein and an ability to transiently unwind duplex DNA.

Preferential binding of tumor suppressor p53 to positively or negatively supercoiled DNA involves the C-terminal domain

The C-terminal domain of the tumor suppressor protein p53 is the site of non-specific DNA binding. Purified p53 produced from baculovirus-infected insect cells binds preferentially to supercoiled DNA, forming bands with lower electrophoretic mobility. This non-covalent binding does not change the linking number of the DNA. An anti-p53 antibody targeting the C-terminal domain partially competes with supercoiled DNA in binding to p53, while antibodies targeted to the N terminus of p53 supershift the complex bands. A synthetic peptide corresponding to amino acid residues 319-393 of human p53 also displays preferential binding to supercoiled DNA, while a mutant peptide, which is unable to form tetramers, is inactive. The center of the equilibrium distribution of topoisomers formed by relaxation with topoisomerase I is not shifted in the presence of p53 although the distribution is broadened. The preferential binding of p53 is exhibited toward both positively and negatively supercoiled DNA. These observations are consistent with a model in which p53 binds to right-handed or left-handed strand crossings.

Binding of proteins to copolymers of varying hydrophobicity

Hydrophobic interactions between proteins and amphiphilic polyelectrolytes were studied by frontal analysis continuous capillary electrophoresis (Gao et al., Analytical Chemistry, 1997, Vol. 69, pp. 2945-2951). Binding isotherms were obtained for beta-lactoglobulin and for bovine serum albumin interacting with a series of alternating copolymers of maleic acid and alkyl-vinyl ethers of varying hydrophobicity. Although binding between proteins and copolymers increases with increasing alkyl chain length, a minimum alkyl chain length of 3-4 methylenes is required for significant hydrophobic interactions to occur. These copolymers, like other polyamphiphiles, can form intrapolymer micelles, and the extent of such micellization decreases with increasing degree of carboxylate ionization. Binding results obtained at different pHs suggest that competition exists between intrapolymer micelle formation and protein-polymer hydrophobic interactions.

The TATA-binding protein from Saccharomyces cerevisiae oligomerizes in solution at micromolar concentrations to form tetramers and octamers

Equilibrium analytical ultracentrifugation has been used to determine the stoichiometry and energetics of the self-assembly of the TATA-binding protein of Saccharomyces cerevisiae at 30 degreesC, in buffers ranging in salt concentration from 60 mM KCl to 1 M KCl. The data are consistent with a sequential association model in which monomers are in equilibrium with tetramers and octamers at protein concentrations above 2.6 microM. Association is highly cooperative, with octamer formation favored by approximately 7 kcal/mol over tetramers. At high [KCl], the concentration of tetramers becomes negligible and the data are best described by a monomer-octamer reaction mechanism. The equilibrium association constants for both monomer <--> tetramer and tetramer <--> octamer reactions change with [KCl] in a biphasic manner, decreasing with increasing [KCl] from 60 mM to 300 mM, and increasing with increasing [KCl] from 300 mM to 1 M. At low [KCl], approximately 3 mole equivalents of ions are released at each association step, while at high [KCl], approximately 3 mole equivalents of ions are taken up at each association step. These results suggest that there is a salt concentration-dependent change in the assembly mechanism, and that the mechanistic switch takes place near 300 mM KCl. The possibility that this self-association reaction may play a role in the activity of the TATA-binding protein in vivo is discussed.

Interaction of the effector domain of MARCKS and MARCKS-related protein with lipid membranes revealed by electric potential measurements

We have investigated the binding of the effector domains of myristoylated alanine-rich C kinase substrate (MARCKS) and of MARCKS-related protein (MRP) to lipid model membranes. For membrane systems we used lipid monolayers on a Langmuir trough and black lipid membranes (BLM). The binding of the peptides was detected by monitoring changes in the boundary potential of the lipid membranes. The vibrating plate technique (VPT) and the method of inner field compensation (IFC) were used for the monolayer and for the BLM, respectively. We could show that the effector domain of MARCKS binds to acidic lipid membranes mainly via electrostatic interactions and to zwitterionic lipid membranes via hydrophobic interactions. Isobaric measurements on lipid monolayers revealed that binding of both effector domains is accompanied by partial insertion of the peptides into the membrane. Adsorption and insertion of the peptides could be followed simultaneously by the VPT and by recording the increase in area of the lipid monolayer, respectively. No temporal delay could be observed between adsorption and insertion of the peptides, demonstrating that adsorption is the rate-limiting step and that insertion is faster than the time resolution of the experiments, i.e., a few seconds. Both the IFC and the VPT did not show any significant difference between the behaviors of the effector domains of MARCKS and MRP. With the IFC we show that calcium can regulate the translocation of the MARCKS effector peptide between the membrane and calmodulin (CaM) in the bulk. Our results indicate, that the IFC and VPT are suitable qualitatively, and to a certain extent quantitatively, as membrane binding assays.

The DNA binding characteristics of the trimeric EcoKI methyltransferase and its partially assembled dimeric form determined by fluorescence polarisation and DNA footprinting

The type I DNA restriction and modification systems of enteric bacteria display several enzymatic activities due to their oligomeric structure. Partially assembled forms of the EcoKI enzyme from E. coli K12 can display specific DNA binding properties and modification methyltransferase activity. The heterodimer of one specificity (S) subunit and one modification (M) subunit can only bind DNA whereas the addition of a second modification subunit to form M2S1 also confers methyltransferase activity. We have examined the DNA binding specificity of M1S1 and M2S1 using the change in fluorescence anisotropy which occurs on binding of a DNA probe labelled with a hexachlorofluorescein fluorophore. The dimer has much weaker affinity for the EcoKI target sequence than the trimer and slightly less ability to discriminate against other DNA sequences. Binding of both proteins is strongly dependent on salt concentration. The fluorescence results compare favourably with those obtained with the gel retardation method. DNA footprinting using exonucleaseIII and DNaseI, and methylation interference show no asymmetry, with both DNA strands being protected by the dimer and the trimer. This indicates that the dimer is a mixture of the two possible forms, M1S1 and S1M1. The dimer has a footprint on the DNA substrate of the same length as the trimer implying that the modification subunits are located on either side of the DNA helical axis rather than lying along the helical axis.

Single-chain lambda Cro repressors confirm high intrinsic dimer-DNA affinity

The overall affinity of the bacteriophage lambda Cro repressor for its operator DNA site is limited by dimer dissociation at submicromolar concentrations. Since Cro dimer-operator complexes form at nanomolar concentrations of Cro subunits where free dimers are rare, these dimers must bind with compensating high affinities. Previous studies of the covalent dimer Cro V55C suggest little change in DNA binding affinity even though the dimeric species is quantitatively populated; this is an apparent contradiction to the expectation of high intrinsic dimer-DNA affinity. In contrast to the disulfide linkage at the center of the dimer interface in Cro V55C, polypeptide linkers that join the two subunits allow single-chain Cro repressors to bind operator DNA with picomolar affinities. A series of five single-chain Cro repressors have been expressed from fused tandem cro genes. Each contains a peptide linker of 8-16 hydrophilic residues that connects the C-terminus of one subunit to the N-terminus of the next. All bind to operator DNA with at least 100-fold higher affinity than Cro V55C. Proteins containing the longest and shortest linkers have been purified and characterized in detail. Both exhibit similar CD spectra to wild-type Cro and enhanced thermal stability. Sedimentation equilibrium experiments show that single-chain Cro repressors do not associate at concentrations up to 30 microM. The rate of dissociation of Cro-DNA complexes is almost unchanged by covalent linkage. Biophysical characterization of Cro variants such as these, where DNA binding is uncoupled from subunit assembly, is necessary for a quantitative understanding of the structural and energetic determinants of DNA recognition in this simple model system.

A folded monomeric intermediate in the formation of lambda Cro dimer-DNA complexes

The folding, dimerization and DNA binding equilibria of the bacteriophage lambda Cro repressor have been characterized. Comparison with four engineered variants shows that a folded monomeric species is substantially populated under conditions used for the formation of dimer-DNA complexes. Although Cro dimers are the only DNA-bound species observed in electrophoretic mobility shift assays, cooperativity in Cro-DNA binding isotherms shows that the predominant free protein species is monomeric at nanomolar concentrations. Micromolar dissociation constants for Cro dimers have been measured in the absence of DNA by sedimentation equilibrium and gel filtration chromatography. Denaturation of Cro dimers in the 10 to 100 micromolar concentration range by guanidine hydrochloride (GdnHCl) is well modeled as a two-state process, with folded dimers and unfolded monomers as the only significantly populated species. However, linear extrapolation of this composite unfolding and dimer dissociation free energy predicts a nanomolar dissociation constant in the absence of denaturant. This extrapolation is clearly inconsistent with the DNA binding and hydrodynamic measurements. Our interpretation of these results is that the monomeric species detected in DNA binding and hydrodynamic experiments is predominantly folded. The stability of the folded monomeric species can be calculated as the difference between the dimerization free energy determined from hydrodynamic measurements and the folding free energy extrapolated from GdnHCl denaturation. The calculated stability of the Cro F58W monomer is greater than that of the wild-type Cro monomer. Thus, residue 58, which makes critical intermolecular contacts across the dimer interface, is also involved in intramolecular stabilization of the monomeric intermediate.

Activation of RNase L by 2',5'-oligoadenylates. Biophysical characterization

Ribonuclease L (RNase L) is an endoribonuclease that is activated upon binding of adenosine oligomers linked 2' to 5' to cleave viral and cellular RNAs. We recently proposed a model for activation in which activator A binds to monomer, E, to form EA, which subsequently dimerizes to the active form, E2A2 (Cole, J. L., Carroll, S. S., and Kuo, L. C. (1996) J. Biol. Chem. 271, 3978-3981). Here, we have employed this model to define the equilibrium constants for activator binding (Ka) and dimerization of EA to E2A2 (Kd) by equilibrium analytical ultracentrifugation and fluorescence measurements. Multi-wavelength sedimentation data were globally fit to the model above, yielding values of Ka = 1.69 microM and Kd = 17. 8 nM for 2',5'-linked adenosine trimer. Fluorescent conjugates of 2',5'-linked adenosine trimer with 7-hydroxycoumarin have been prepared. The coumarin emission anisotropy shows a large increases upon binding to RNase L. Analysis of anisotropy titrations yields values of Ka and Kd close to those obtained by sedimentation. The sedimentation parameters for unmodified 2',5'-linked adenosine trimer also agree with those obtained by enzyme kinetic methods (Carroll, S. S., Cole, J. L., Viscount, T., Geib, J., Gehman, J., and Kuo, L. C. (1997) J. Biol. Chem. 272, 19193-19198). Thus, the data presented here clearly define the energetics of RNase L activation and support the minimal activation model.

Activation of RNase L by 2',5'-oligoadenylates. Kinetic characterization

Ribonuclease L (RNase L), the 2',5'-oligoadenylate-dependent ribonuclease, is one of the cellular antiviral systems with enhanced activity in the presence of interferon. A reaction scheme has been developed to model the sequence of steps necessary for the activation of RNase L (Cole, J. L., Carroll, S. S., Blue, E. S., Viscount, T., and Kuo, L. C. (1997) J. Biol. Chem. 272, 19187-19192). The model comprises three sequential binding steps: the binding of activator to enzyme monomer, the subsequent dimerization of the activated monomer to form the active enzyme dimer, followed by the binding of substrate prior to catalysis. The model is used to evaluate the activation of RNase L by several synthetic analogs of the native activator. The 5'-phosphate of the activator has been determined to be an important structural determinant for the efficient activation of RNase L, and its loss caused a loss of activator affinity of 2-3 orders of magnitude. The length of activator is not an important determinant of activator potency for the activator analogs examined. The specific activity of the enzyme under conditions of saturation of activator binding and complete dimerization of the activated monomers varies only by about a factor of 3 for the activators examined, indicating that once dimerized in the presence of any of these activators, the enzyme exhibits a similar catalytic activity.

Differences in water release with DNA binding by ultrabithorax and deformed homeodomains

The amino acid sequences of the homeodomains (HD) within the Ultrabithorax (Ubx) and Deformed (Dfd) proteins from Drosophila melanogaster are highly conserved despite distinct genetic regulatory functions for these proteins in embryonic development. We reported recently that Ubx-HD binding to a single target site displayed significantly increased affinity and greater salt concentration dependence at lower pH; in contrast, Dfd-HD did not show pH dependence in its DNA binding properties [Li, L., et al. (1996) Biochemistry 35, 9832-9839]. We demonstrate in this study that water activity differentially affects Ubx-HD and Dfd-HD DNA binding affinity. The sensitivity of the protein-DNA binding constant to osmotic pressures generated by neutral solutes was measured, and the formation of the Ubx-HD-DNA complex is associated with significantly greater water release than that of the Dfd-HD-DNA complex. No influence of pH on water release was detected for either HD. Experiments with chimeric Ubx-Dfd homeodomains demonstrated that the C-terminal region of the Ubx-HD is the primary determinant for the greater water release associated with DNA binding for this protein. DNA sequences do not exert a significant effect on the magnitude of water release associated with protein-DNA binding for Ubx-HD and the chimeric HD, UDU.

Single-chain repressors containing engineered DNA-binding domains of the phage 434 repressor recognize symmetric or asymmetric DNA operators

Single-chain (sc) DNA-binding proteins containing covalently dimerized N-terminal domains of the bacteriophage 434 repressor cI have been constructed. The DNA-binding domains (amino acid residues 1 to 69) were connected in a head-to-tail arrangement with a part of the natural linker sequence that connects the N and C-terminal domains of the intact repressor. Compared to the isolated N-terminal DNA-binding domain, the sc molecule showed at least 100-fold higher binding affinity in vitro and a slightly stronger repression in vivo. The recognition of the symmetric O(R)1 operator sequence by this sc homodimer was indistinguishable from that of the naturally dimerized repressor in terms of binding affinity, DNase I protection pattern and in vivo repressor function. Using the new, sc framework, mutant proteins with altered DNA-binding specificity have also been constructed. Substitution of the DNA-contacting amino acid residues of the recognition helix in one of the domains with the corresponding residues of the Salmonella phage P22 repressor c2 resulted in a sc heterodimer of altered specificity. This new heterodimeric molecule recognized an asymmetric, artificial 434-P22 chimeric operator with high affinity. Similar substitutions in both 434 domains have led to a new sc homodimer which showed high affinity binding to a natural, symmetric P22 operator. These findings, supported by both in vitro and in vivo experiments, show that the sc architecture allows for the introduction of independent changes in the binding domains and suggest that this new protein framework could be used to generate new specificities in protein-DNA interaction.

Preferential interactions of the Escherichia coli LexA repressor with anions and protons are coupled to binding the recA operator

The binding of Escherichia coli LexA repressor to the recA operator was examined as a function of the concentration of NaCl, KCl, NaF, and MgCl2 at pH 7.5, 21 degrees C. The effects of pH at 100 mM NaCl were also examined. Changes both in the qualitative appearance of the binding isotherms and in the magnitude of the apparent binding affinity with changes in solution conditions suggest that binding of anions and protons by LexA repressor is linked to oligomerization and/or operator binding. Binding of LexA repressor to the recA operator in the presence of NaCl ranging from 25 to 400 mM at picomolar DNA concentration showed a broad, apparently noncooperative, binding isotherm. Binding of LexA repressor in NaF at the same [DNA] yielded binding isotherms with a narrow transition, reflecting an apparently cooperative binding process. Also, the apparent binding affinity was weaker in NaF than in NaCl. Furthermore, the binding affinity and also the apparent binding mode, cooperative vs noncooperative, were pH dependent. The binding affinity of LexA repressor for operator was greatest near neutral pH. The apparent binding mode was noncooperative at pH 7-9 but was cooperative at pH 6 or 9.3. These observations suggest that the specific cation and anion composition and concentrations must be considered in understanding the details of regulation of the SOS system.