Ion-exchange reactions of proteins during DNA binding

Assembly of functional ribonucleoprotein complexes by AU-rich element RNA-binding protein 1 (AUF1) requires base-dependent and -independent RNA contacts

AU-rich element RNA-binding protein 1 (AUF1) regulates the stability and/or translational efficiency of diverse mRNA targets, including many encoding products controlling the cell cycle, apoptosis, and inflammation by associating with AU-rich elements residing in their 3'-untranslated regions. Previous biochemical studies showed that optimal AUF1 binding requires 33-34 nucleotides with a strong preference for U-rich RNA despite observations that few AUF1-associated cellular mRNAs contain such extended U-rich domains. Using the smallest AUF1 isoform (p37(AUF1)) as a model, we employed fluorescence anisotropy-based approaches to define thermodynamic parameters describing AUF1 ribonucleoprotein (RNP) complex formation across a panel of RNA substrates. These data demonstrated that 15 nucleotides of AU-rich sequence were sufficient to nucleate high affinity p37(AUF1) RNP complexes within a larger RNA context. In particular, p37(AUF1) binding to short AU-rich RNA targets was significantly stabilized by interactions with a 3'-purine residue and largely base-independent but non-ionic contacts 5' of the AU-rich site. RNP stabilization by the upstream RNA domain was associated with an enhanced negative change in heat capacity consistent with conformational changes in protein and/or RNA components, and fluorescence resonance energy transfer-based assays demonstrated that these contacts were required for p37(AUF1) to remodel local RNA structure. Finally, reporter mRNAs containing minimal high affinity p37(AUF1) target sequences associated with AUF1 and were destabilized in a p37(AUF1)-dependent manner in cells. These findings provide a mechanistic explanation for the diverse population of AUF1 target mRNAs but also suggest how AUF1 binding could regulate protein and/or microRNA binding events at adjacent sites.

DNA-interactive properties of crotamine, a cell-penetrating polypeptide and a potential drug carrier

Crotamine, a 42-residue polypeptide derived from the venom of the South American rattlesnake Crotalus durissus terrificus, has been shown to be a cell-penetrating protein that targets chromosomes, carries plasmid DNA into cells, and shows specificity for actively proliferating cells. Given this potential role as a nucleic acid-delivery vector, we have studied in detail the binding of crotamine to single- and double-stranded DNAs of different lengths and base compositions over a range of ionic conditions. Agarose gel electrophoresis and ultraviolet spectrophotometry analysis indicate that complexes of crotamine with long-chain DNAs readily aggregate and precipitate at low ionic strength. This aggregation, which may be important for cellular uptake of DNA, becomes less likely with shorter chain length. 25-mer oligonucleotides do not show any evidence of such aggregation, permitting the determination of affinities and size via fluorescence quenching experiments. The polypeptide binds non-cooperatively to DNA, covering about 5 nucleotide residues when it binds to single (ss) or (ds) double stranded molecules. The affinities of the protein for ss- vs. ds-DNA are comparable, and inversely proportional to salt levels. Analysis of the dependence of affinity on [NaCl] indicates that there are a maximum of ∼3 ionic interactions between the protein and DNA, with some of the binding affinity attributable to non-ionic interactions. Inspection of the three-dimensional structure of the protein suggests that residues 31 to 35, Arg-Trp-Arg-Trp-Lys, could serve as a potential DNA-binding site. A hexapeptide containing this sequence displayed a lower DNA binding affinity and salt dependence as compared to the full-length protein, likely indicative of a more suitable 3D structure and the presence of accessory binding sites in the native crotamine. Taken together, the data presented here describing crotamine-DNA interactions may lend support to the design of more effective nucleic acid drug delivery vehicles which take advantage of crotamine as a carrier with specificity for actively proliferating cells.

Biophysical characterization of DNA and RNA aptamer interactions with hen egg lysozyme

This work characterized the binding of an RNA aptamer recognizing hen egg white lysozyme, as well as a literature-reported single-stranded DNA analog of sequence identical to the original RNA aptamer, using fluorescence anisotropy, isothermal titration calorimetry (ITC) and analytical ultracentrifugation. The polyanionic DNA aptamer analog is selective for lysozyme even over cationic cytochrome c and has been reported to be successfully used in biosensing applications. The association however, is predominantly of electrostatic character, strongly salt-sensitive and entropically-driven, in contrast to previously described enthalpically-driven antibody-lysozyme and DNA aptamer-VEGF interactions. With a moderate selectivity for their target, high salt-sensitivity along with fast association and dissociation behavior, these molecules might serve as pseudo-affinity ligands for biomolecular separations.

Electrostatic hot spot on DNA-binding domains mediates phosphate desolvation and the pre-organization of specificity determinant side chains

A major obstacle towards elucidating the molecular basis of transcriptional regulation is the lack of a detailed understanding of the interplay between non-specific and specific protein–DNA interactions. Based on molecular dynamics simulations of C₂H₂ zinc fingers (ZFs) and engrailed homeodomain transcription factors (TFs), we show that each of the studied DNA-binding domains has a set of highly constrained side chains in preset configurations ready to form hydrogen bonds with the DNA backbone. Interestingly, those domains that bury their recognition helix into the major groove are found to have an electrostatic hot spot for Cl⁻ ions located on the same binding cavity as the most buried DNA phosphate. The spot is characterized by three protein hydrogen bond donors, often including two basic side chains. If bound, Cl⁻ ions, likely mimicking phosphates, steer side chains that end up forming specific contacts with bases into bound-like conformations. These findings are consistent with a multi-step DNA-binding mechanism in which a pre-organized set of TF side chains assist in the desolvation of phosphates into well defined sites, prompting the re-organization of specificity determining side chains into conformations suitable for the recognition of their cognate sequence.

Thermodynamic profiling of HIV RREIIB RNA-zinc finger interactions

The interactions between the HIV Rev-responsive element (RRE) RNA and the HIV regulatory protein Rev, are crucial for the HIV life-cycle. Earlier, we showed that single C(2)H(2) zinc fingers (znfs) have the same binding site as the Rev peptide and exhibit nanomolar affinity. In this study, the specific role of amino acid side chains and molecular processes involved with complex formation were investigated by perturbation of the binding energetics via changes in temperature, pH, buffers, and salt concentrations, as well as znf and RNA mutations, by isothermal titration calorimetry. Interestingly, despite the large cationic charge on the znfs, the number of interactions with the RNA phosphate backbone was lower than intuitively expected. The presence of binding induced protonation was established by ITC and localized by NMR to a histidine on the znf beta-sheet. The DeltaC(p) of znf-RNA binding was observed to be substantially negative and could not be accounted for by conventional solvent-accessible surface area models. An alternative model, based on the extent of hydrogen bond changes as a result of differences in ligand-induced water displacement at the binding site, provided reasonable explanation of the trends in DeltaC(p), as well as DeltaH and DeltaS. Our studies show that incorporation of favorable interactions at the solvent-excluded binding interface can be used to alleviate the unfavorable enthalpic penalties of displacing water molecules from the hydrated RNA surface.

The salt dependence of the interferon regulatory factor 1 DNA binding domain binding to DNA reveals ions are localized around protein and DNA

The equilibrium dissociation constant of the DNA binding domain of interferon regulatory factor 1 (IRF1 DBD) for its DNA binding site depends strongly on salt concentration and salt type. These dependencies are consistent with IRF1 DBD binding to DNA, resulting in the release of cations from the DNA and both release of anions from the protein and uptake of a cation by the protein. We demonstrated this by utilizing the fact that the release of fluoride from protein upon complex formation does not contribute to the salt concentration dependence of binding and by studying mutants in which charged residues in IRF1 DBD that form salt bridges with DNA phosphates are changed to alanine. The salt concentration dependencies of the dissociation constants of wild-type IRF1 DBD and the mutants R64A, D73A, K75A, and D73A/K75A were measured in buffer containing NaF, NaCl, or NaBr. The salt concentration and type dependencies of the mutants relative to wild-type IRF1 DBD provide evidence of charge neutralization by solution ions for R64 and by a salt bridge between D73 and K75 in buffer containing chloride or bromide salts. These data also allowed us to determine the number, type, and localization of condensed ions around both IRF1 DBD and its DNA binding site.

Electrophoretic mobility shift assay (EMSA) for detecting protein-nucleic acid interactions

The gel electrophoresis mobility shift assay (EMSA) is used to detect protein complexes with nucleic acids. It is the core technology underlying a wide range of qualitative and quantitative analyses for the characterization of interacting systems. In the classical assay, solutions of protein and nucleic acid are combined and the resulting mixtures are subjected to electrophoresis under native conditions through polyacrylamide or agarose gel. After electrophoresis, the distribution of species containing nucleic acid is determined, usually by autoradiography of 32P-labeled nucleic acid. In general, protein-nucleic acid complexes migrate more slowly than the corresponding free nucleic acid. In this protocol, we identify the most important factors that determine the stabilities and electrophoretic mobilities of complexes under assay conditions. A representative protocol is provided and commonly used variants are discussed. Expected outcomes are briefly described. References to extensions of the method and a troubleshooting guide are provided.

Cation binding linked to a sequence-specific CAP-DNA interaction

The equilibrium association constant observed for many DNA-protein interactions in vitro (K(obs)) is strongly dependent on the salt concentration of the reaction buffer ([MX]). This dependence is often used to estimate the number of ionic contacts between protein and DNA by assuming that release of cations from the DNA is the dominant involvement of ions in the binding reaction. With this assumption, the graph of logK(obs) versus log[MX] is predicted to have a constant slope proportional to the number of ions released from the DNA upon protein binding. However, experimental data often deviate from log-linearity at low salt concentrations. Here we show that for the sequence-specific interaction of CAP with its primary site in the lactose promoter, ionic stoichiometries depend strongly on cation identity and weakly on anion identity. This outcome is consistent with a simple linkage model in which cation binding by the protein accompanies its association with DNA. The order of ion affinities deduced from analysis of DNA binding is the same as that inferred from urea-denaturation experiments performed in the absence of DNA, suggesting that ion binding to free CAP contributes significantly to the ionic stoichiometry of DNA binding. In living cells, the coupling of ion-uptake and DNA binding mechanisms could reduce the sensitivity of gene-regulatory interactions to changes in environmental salt concentration.

Theory of electrostatically regulated binding of T4 gene 32 protein to single- and double-stranded DNA

Bacteriophage T4 gene 32 protein (gp32) is a single-stranded DNA binding protein, which is essential for DNA replication, recombination, and repair. In a recent article, we described a new method using single DNA molecule stretching measurements to determine the noncooperative association constants K(ds) to double-stranded DNA for gp32 and *I, a truncated form of gp32. In addition, we developed a single molecule method for measuring K(ss), the association constant of these proteins to single-stranded DNA. We found that in low salt both K(ds) and K(ss) have a very weak salt dependence for gp32, whereas for *I the salt dependence remains strong. In this article we propose a model that explains the salt dependence of gp32 and *I binding to single-stranded nucleic acids. The main feature of this model is the strongly salt-dependent removal of the C-terminal domain of gp32 from its nucleic acid binding site that is in pre-equilibrium to protein binding to both double-stranded and single-stranded nucleic acid. We hypothesize that unbinding of the C-terminal domain is associated with counterion condensation of sodium ions onto this part of gp32, which compensates for sodium ion release from the nucleic acid upon its binding to the protein. This results in the salt-independence of gp32 binding to DNA in low salt. The predictions of our model quantitatively describe the large body of thermodynamic and kinetic data from bulk and single molecule experiments on gp32 and *I binding to single-stranded nucleic acids.

Ionic strength dependence of protein-polyelectrolyte interactions

The effect of univalent electrolyte concentration on protein-polyelectrolyte complex formation has been measured by frontal analysis continuous capillary electrophoresis (FACCE) and turbidimetry for the interaction of bovine serum albumin (BSA) with a synthetic hydrophobically modified polyacid, for BSA with (porcine mucosal) heparin (Hp), a highly charged polyanion, and for Hp and insulin. All three highly diverse systems display maxima or plateaus in complex formation in the range of ionic strength 5 < I < 30 mM, confirmed in the case of BSA-Hp by multiple techniques. Similar maxima are reported in the literature, but with little discussion, for BSA-poly(dimethyldiallylammonium chloride), lysozyme-hyaluronic acid, and lysozyme-chondroitin sulfate, always in the I range 5-30 mM. While inversion of salt effect has been discussed specifically for the interaction of gelatin and sodium polystyrenesulfonate with gelatin(28) and with beta-lactoglobulin,(10) the general nature of this phenomenon, regardless of polyelectrolyte origin, molecular weight, and charge sign has not been recognized. The position of the maxima and their occurrence when protein and polyelectrolyte have the same net charge imply that they arise when Debye lengths extend, at low I, beyond half the protein diameter so that addition of salt screens repulsions, as well as attractions. This appears to be a general effect caused by electrostatic repulsions that can coexist simultaneously with hydrophobic interactions. Modeling of protein electrostatics via Delphi is used to visualize this effect for BSA, lysozyme, insulin, and beta-lactoglobulin.

Role of hydration in the binding of lac repressor to DNA

The osmotic stress technique was used to measure changes in macromolecular hydration that accompany binding of wild-type Escherichia coli lactose (lac) repressor to its regulatory site (operator O1) in the lac promoter and its transfer from site O1 to nonspecific DNA. Binding at O1 is accompanied by the net release of 260 +/- 32 water molecules. If all are released from macromolecular surfaces, this result is consistent with a net reduction of solvent-accessible surface area of 2370 +/- 550 A. This area is only slightly smaller than the macromolecular interface calculated for a crystalline repressor dimer-O1 complex but is significantly smaller than that for the corresponding complex with the symmetrical optimized O(sym) operator. The transfer of repressor from site O1 to nonspecific DNA is accompanied by the net uptake of 93 +/- 10 water molecules. Together these results imply that formation of a nonspecific complex is accompanied by the net release of 165 +/- 43 water molecules. The enhanced stabilities of repressor-DNA complexes with increasing osmolality may contribute to the ability of Escherichia coli cells to tolerate dehydration and/or high external salt concentrations.

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 cAMP receptor protein CRP can function as an osmoregulator of transcription in Escherichia coli

Transcription of the P1 promoter of the Escherichia coli proP gene, which encodes a transporter of osmoprotectants, is strongly induced by a shift to hyperosmotic media. Unlike most other osmotically regulated promoters, the induction occurs for a brief period of time, corresponding to the replacement of intracellular K(+) glutamate with osmoprotecting compounds. This burst of proP transcription is correlated with the osmolarity-dependent binding of the cAMP receptor protein CRP to a site within the proP P1 promoter. We show that CRP-cAMP functions as an osmotically sensitive repressor of proP P1 transcription in vitro. Binding of CRP to the proP promoter in vivo is transiently destabilized after a hyperosmotic shift with kinetics that correspond to the derepression of transcription, whereas Fis and Lac repressor binding is not osmotically sensitive. Similar osmotic regulation of proP P1 transcription by the CRP* mutant implies that binding of cAMP is not responsible for the unusual osmotic sensitivity of CRP activity. Osmotic regulation of CRP activity is not limited to proP. Activation of the lac promoter by CRP is also transiently inhibited after an osmotic upshift, as is the binding of CRP to the galdelta4P1 promoter. These findings suggest that CRP functions in certain contexts to regulate gene expression in response to osmotic changes, in addition to its role in catabolite control.

Kinetic characterization of linear diffusion of the restriction endonuclease EcoRV on DNA

We have examined the kinetic parameters of linear diffusion of EcoRV on DNA. The data were analyzed by Monte Carlo simulations in which the efficiency of recognition of EcoRV sites during linear diffusion, the efficiency of linear diffusion, and the behavior of enzymes at the ends of linear DNA is explicitly treated. The analysis of the dependence of linear diffusion on the concentrations of NaCl and MgCl2 shows that linear diffusion is maximal at 50 mM NaCl under all concentrations of MgCl2 tested and increases with increasing concentrations of Mg2+ up to 10 mM, the highest concentration used in the test. Under these conditions, EcoRV scans 2 x 10(6) bp during one binding event with a velocity of about 1.7 x 10(6) bp s-1. The enzyme tends to overlook cleavage sites at 1 mM but not at 10 mM MgCl2. This result confirms the thermodynamic finding that EcoRV does not bind very specifically to DNA in the absence of Mg2+. It demonstrates that there is a Mg2+-dependent continuous transition between a nonspecific and a specific binding mode of EcoRV to DNA. By comparing cleavage rates of linear DNA whose ends are free or blocked, we have shown that EcoRV has a very low probability to fall off at the ends of linear DNA. The enzyme rather is "reflected" and continues linear diffusion. EcoRV does not cleave oligonucleotides containing two EcoRV sites processively. Consequently, dissociation of the enzyme from the cleavage products is not preceded by a transfer to nonspecific DNA, and linear diffusion is not involved in product dissociation in EcoRV.

Role of macromolecular hydration in the binding of the Escherichia coli cyclic AMP receptor to DNA

The osmotic stress technique was used to measure the changes in macromolecular hydration that accompany binding of the Escherichia coli CAP protein to its transcription-regulatory site (C1) in the lactose promoter and that accompany the transfer of CAP from site C1 to nonspecific genomic DNA. Formation of the C1 complex is accompanied by the net release of 79 +/- 11 water molecules. If all water molecules were released from macromolecular surfaces, this result would be consistent with a net reduction of solvent-accessible surface area of 711 +/- 189 A2. This area is only slightly smaller than the solvent-inaccessible macromolecular interface in crystalline CAP-DNA complexes. The transfer of CAP from site C1 to nonspecific sites is accompanied by the net uptake of 56 +/- 10 water molecules. Taken with the water stoichiometry of sequence-specific binding, this value implies that formation of a nonspecific complex is accompanied by the net release of 2-44 water molecules. The enhanced stabilities of CAP-DNA complexes with increased osmolality (decreased water activity) may contribute to the ability of E.coli cells to tolerate dehydration and/or high external salt concentrations.

Specific binding by EcoRV endonuclease to its DNA recognition site GATATC

Restriction endonuclease EcoRV has been reported to be unable to distinguish its specific DNA site, GATATC, from non-specific DNA sites in the absence of the catalytic cofactor Mg2+, and thus to exercise sequence specificity solely in the catalytic step. In contrast, we show here that under appropriate conditions of pH and salt concentration, specific complexes with oligonucleotides containing the GATATC site can be detected by either filter-binding or gel-retardation. Equilibrium binding constants (K(A)) are easily measured by both direct equilibrium and equilibrium-competition methods. The preference for "specific" over "non-specific" binding at pH 7 in the absence of divalent cations is about 1000-fold (per mole of oligonucleotide) or 12,000-fold (per mole of binding sites). Ethylation-interference footprinting shows that the "specific" complex includes strong contacts to the phosphate groups GpApTpApTC. Specific DNA binding is strongly pH-dependent, decreasing about 15-fold for each increase of one pH unit above pH 6, but non-specific binding is not; thus, binding specificity decreases with increasing pH. Gel retardation and filter-binding at pH < or = 7 yield essentially identical values of K(A) for specific-site binding, but at pH > 7 gel retardation significantly underestimates K(A). Specific-site binding is stimulated about 700-fold by Ca2+ (not a cofactor for cleavage), but with non-cleavable 3'-phosphorothiolate and 4'-thiodeoxyribose derivatives whose response to Ca2+ is similar to that of the parent oligonucleotide, Mg2+ stimulates binding only fourfold and twofold, respectively. Thus, binding specificity is not dramatically enhanced by Mg2+. Taking into account discrimination in binding and in the first-order rate constant for phosphodiester bond scission, the overall discrimination exercised against the incorrect site GTTATC is about 10(7)-fold. EcoRV endonuclease is thus not a "new paradigm" for site-specific interaction without binding specificity, but like other type II restriction endonucleases achieves sequence specificity by discriminating both in DNA binding and in catalysis.

Cyclic AMP receptor protein functions as a repressor of the osmotically inducible promoter proP P1 in Escherichia coli

Transcription of the proP gene, encoding a transporter of the osmoprotectants proline and glycine betaine, is controlled from two promoters, P1 and P2, that respond primarily to osmotic and stationary-phase signals, respectively. The P1 promoter is normally expressed at a very low level under low or normal medium osmolarity. We demonstrate that the binding of the cyclic AMP (cAMP) receptor protein (CRP) to a site centered at -34.5 within the promoter is responsible for the low promoter activity under these conditions. A brief period of reduced CRP binding in early log phase corresponds to a transient burst of P1 transcription upon resumption of growth in Luria-Bertani broth. A CRP binding-site mutation or the absence of a functional crp gene leads to high constitutive expression of P1. We show that the binding of CRP-cAMP inhibits transcription by purified RNA polymerase in vitro at P1, but this repression is relieved at moderately high potassium glutamate concentrations. Likewise, open-complex formation at P1 in vivo is inhibited by the presence of CRP under low-osmolarity conditions. Because P1 expression can be further induced by osmotic upshifts in a delta crp strain or in the presence of the CRP binding-site mutation, additional controls exist to osmotically regulate P1 expression.

Characterization of a cooperativity domain mutant Lys3 --> Ala (K3A) T4 gene 32 protein

The N-terminal "B" domain of T4 gene 32 protein contains a Lys3-Arg4-Lys5 sequence that has been postulated to provide a major determinant for cooperative binding. In this report, the equilibrium binding properties of a Lys3 --> Ala substitution mutant of gp32 (K3A gp32) and described and compared to a set of substitution mutants of Arg4 previously described (Villemain, J. L., and Giedroc, D. P. (1993) Biochemistry 32, 11235-11246) and further characterized here. K3A gp32 exhibits binding behavior which mirrors that of R4Q gp32. Despite an 6-8-fold decrease in overall binding affinity (Kapp = Kint x omega) at pH 8.1, 0.20 M NaCl, 20 degrees C, the magnitude of the cooperativity parameter is at most 2-3-fold smaller than that of the wild-type protein. The magnitude of omega is independent of salt concentration and type over the range in [NaCl] from 0.125 to 0. 225 M and [NaF] between 0.20 and 0.32 M (log omega = 2.86 +/- 0.19). For comparison, log omega for wild-type gp32 is 2.91 (+/- 0.21) resolved at 0.275 M NaCl and 3.39 +/- 0.11 in [NaF] between 0.40 and 0.45 M. In contrast to omega, the [NaCl] dependence of Kapp is large and markedly nonlinear for both wild-type and K3A gp32s over a [NaCl] range extending from 0.05 M to 0.40 M NaCl. Modeling of the complete salt dependence of Kapp for wild-type, K3A, and R4T gp32s in NaCl and NaF with a simple ion-exchange model suggests that substitutions within the basic Lys3-Arg4-Lys5 sequence do not strongly modulate the net displacement of cations and anions upon poly(A) complex formation by gp32.

Thermodynamics of sequence-specific protein-DNA interactions

The molecular recognition processes in sequence-specific protein-DNA interactions are complex. The only feature common to all sequence-specific protein-DNA structures is a large interaction interface, which displays a high degree of complementarity in terms of shape, polarity and electrostatics. Many molecular mechanisms act in concert to form the specific interface. These include conformational changes in DNA and protein, dehydration of surfaces, reorganization of ion atmospheres, and changes in dynamics. Here we review the current understanding of how different mechanisms contribute to the thermodynamics of the binding equilibrium and the stabilizing effect of the different types of noncovalent interactions found in protein-DNA complexes. The relation to the thermodynamics of small molecule-DNA binding and protein folding is also briefly discussed.

Salt effects on nucleic acids

Salt-dependent electrostatic effects are a major factor in determining the stability, structure, reactivity, and binding behavior of nucleic acids. Increasingly detailed theoretical methods, especially those based on Monte Carlo and Poisson-Boltzmann methodologies, combined with powerful computational algorithms are being used to examine how the shape, charge distribution and dielectric properties of the molecules affect the ion distribution in the surrounding aqueous solution, and how they play a role in ligand binding, structural transitions and other biologically important reactions. These studies indicate that inclusion of detailed structural information about the nucleic acid and its ligands is crucial for improving models of nucleic acid electrostatics, and that better treatment of the ion atmosphere and dielectric effects is also of major importance.

Analysis of the thermodynamic linkage of DNA binding and ion binding for dimeric and tetrameric forms of the lac repressor

The salt concentration dependences of the observed association constants (Kobs) for the binding of wild-type lac repressor tetramer and the dimeric lacI-18 mutant repressor to lactose operator DNA were compared. For both proteins, the data are consistent with a class of linkage models in which ion binding by the protein is driven by differences in the ionic concentrations in bulk solution and in the volume near the DNA surface. The models that best agree with the data are those in which ion-binding reactions are cooperative. In spite of close agreement between these models and the data, the determination of ion stoichiometries and apparent ion-binding affinities requires additional mechanistic or structural information. The simplest ion-binding mechanism consistent with the data is compatible with a current structural model of the repressor-operator complex. At salt concentrations in excess of 50 mM, at which cation displacement from the DNA and anion displacement from the protein are expected to dominate, similar ion stoichiometries are found for the DNA binding of dimeric and tetrameric repressors. This supports the notion that the DNA contacts of these proteins are homologous. At lower salt concentrations, in which cation binding by the proteins is expected to be significant, the net ion stoichiometry of wild-type repressor binding is slightly greater than that of the lacI-18 mutant. This difference may reflect the availability of ion-binding sites in the distal subunits of tetramer that are not present in the dimer, or may be a consequence of the involvement of ion binding in the dimer/monomer equilibrium.

Molecular sequestration stabilizes CAP-DNA complexes during polyacrylamide gel electrophoresis

The gel electrophoresis mobility shift assay is widely used for qualitative and quantitative characterization of protein complexes with nucleic acids. Often it is found that complexes that are short-lived in free solution (t1/2 of the order of minutes) persist for hours under the conditions of gel electrophoresis. We have investigated the influence of polyacrylamide gels on the pseudo first-order dissociation kinetics of complexes containing the E.coli cyclic AMP receptor protein (CAP) and lactose promoter DNA. Within the gel matrix, kdiss decreased with increasing [polyacrylamide] and the order of the reaction was changed. In free solution, kdiss was proportional to [DNA]2, while in 5% gels, kdiss was proportional to [DNA]0.3. In gels of [polyacrylamide] > or = 10%, kdiss was nearly independent of [DNA] until fragment concentrations exceeded 0.1 microM. Even in the absence of competing DNA, kdiss(gel) < kdiss(solution). These results suggest that the lifetime of CAP-DNA complexes in free solution is limited by their encounter frequency with molecules of DNA or with protein-DNA complexes; some or all of the stabilization observed in gels may be due to a reduction in this frequency.