Trapping DNA-protein binding reactions with neutral osmolytes for the analysis by gel mobility shift and self-cleavage assays

We take advantage of our previous observation that neutral osmolytes can strongly slow down the rate of DNA–protein complex dissociation to develop a method that uses osmotic stress to ‘freeze’ mixtures of DNA–protein complexes and prevent further reaction enabling analysis of the products. We apply this approach to the gel mobility shift assay and use it to modify a self-cleavage assay that uses the nuclease activity of the restriction endonucleases to measure sensitively their specific binding to DNA. At sufficiently high concentrations of neutral osmolytes the cleavage reaction can be triggered at only those DNA fragments with initially bound enzyme. The self-cleavage assay allows measurement of binding equilibrium and kinetics directly in solution avoiding the intrinsic problems of gel mobility shift and filter binding assays while providing the same sensitivity level. Here we compare the self-cleavage and gel mobility shift assays applied to the DNA binding of EcoRI and BamHI restriction endonucleases. Initial results indicate that BamHI dissociation from its specific DNA sequence is strongly linked to water activity with the half-life time of the specific complex increasing ~20-fold from 0 to 1 osmolal betaine.     

Studies on the binding of lambda Int protein to attachment site DNA: identification of a tight-binding site in the P'' region.

We have used three approaches to studying the interaction of lambda Int protein with bacteriophage attachment site DNA, POP': location of binding sites by retention of DNA fragments in a filter binding assay, reconstruction of a binding site by DNA synthesis and protection of a binding site from an exonuclease. Retention of restriction fragments on nitrocellulose filters in the presence of Int protein was used to locate binding sites. A high affinity binding site lies in P' between base pairs -6 and +173 from the center of the common core sequence, and low affinity sites are found in the 200 base pair region left of position -6. Reconstruction of the high affinity binding site region from the right using primed DNA synthesis and testing for filter binding in the presence of Int protein shows that sequences sufficient for tight binding of Int protein lie to the right of position +66. When attachment site DNA is protected by bound Int protein against digestion by exonuclease III, four Int dependent protection bands are seen in positions +58, +68, +79 and +88. This can be interpreted either as showing that four Int protein monomers bind to the high affinity region in series, or as evidence for wrapping of the DNA around Int protein, leading to structural changes resembling those occurring to DNA in nucleosomes.     

Scintillation proximity assay for DNA binding by human p53

Many DNA binding proteins are known to regulate gene expression. When that binding is altered, a disease state can result. A common method for measuring DNA binding, namely electrophoretic mobility shift assay (EMSA) is often used but it is not amenable to rapid screening of many samples. As an alternative method, we have developed a DNA binding assay for the tumor suppressor protein p53 in a 96-well microtiter plate format using scintillation proximity assay (SPA) beads. We have shown this assay to be sensitive (as little as 0.5 ng p53 can be detected), quick (assay completed in as little as 15 min), and easily quantitated using a microtiter plate scintillation counter We also used the assay to analyze the kinetics of the DNA binding to p53. The specificity of this p53 DNA binding SPA was confirmed using competition by oligonucleotides either from the same gene or from mutated versions of this sequence. Thus, SPA is a good alternative to gel shift assays for DNA binding and may be useful for the analysis of multiple tumor cell samples or for high-throughput screens for compounds affecting DNA binding by proteins of interest.     

Determination of binding constants for cooperative site-specific protein-DNA interactions using the gel mobility-shift assay

We have investigated the question of whether the gel mobility-shift assay can provide data that are useful to the demonstration of cooperativity in the site-specific binding of proteins to DNA. Three common patterns of protein-DNA interaction were considered: (i) the cooperative binding of a protein to two sites (illustrated by the Escherichia coli Gal repressor); (ii) the cooperative binding of a bidentate protein to two sites (illustrated by the E. coli Lac repressor); and (iii) the cooperative binding of a protein to three sites (illustrated by the lambda cI repressor). A simple, rigorous, and easily extendable statistical mechanical approach to the derivation of the binding equations for the different patterns is presented. Both simulated and experimental data for each case are analyzed. The mobility-shift assay provides estimates of the macroscopic binding constants for each step of ligation based on its separation of liganded species by the number of ligands bound. Resolution of the binding constants depends on the precision with which the equilibrium distribution of liganded species is determined over the entire range of titration of each of the sites. However, the evaluation of cooperativity from the macroscopic binding constants is meaningful only for data that are also accurate. Some criteria that are useful in evaluating accuracy are introduced and illustrated. Resolution of cooperative effects is robust only for the simplest case, in which there are two identical protein binding sites. In this case, cooperative effects of up to 1,000-fold are precisely determined. For heterogeneous sites, cooperative effects of greater than 1,000-fold are resolvable, but weak cooperativity is masked by the heterogeneity. For three-site systems, only averaged pair-wise cooperative effects are resolvable.     

Partial purification and properties of a DNA-binding protein from nuclei of cells infected with polyoma virus.

A DNA-binding protein has been purified from nuclei of 3T3 cells infected with polyoma virus. The assay used to detect this activity measures the amount of double-stranded DNA retained on a nitrocellulose membrane filter in the presence of binding protein. The interaction between DNA and protein is salt dependent and occurs optimally at 0.8 M NaCl. The isolated protein can bind to both circular and linear duplex DNA. Incubation of the binding protein with PM2 or polyoma DNA results in the formation of a fast sedimenting DNA structure in neutral sucrose gradients. The isolated binding protein is also capable of producing a considerable stimulation of both Escherichia coli (Pol I) and T4 DNA polymerase activities when either single-stranded or intact, native T7 DNA is used as the template. The binding protein itself is free of detectable DNA polymerase or nuclease activity.     

Interactions of the Integrase Protein of the Conjugative Transposon Tn916 with Its Specific DNA Binding Sites

The binding of two chimeric proteins, consisting of the N-terminal or C-terminal DNA binding domain of Tn916 Int fused to maltose binding protein, to specific oligonucleotide substrates was analyzed by gel mobility shift assay. The chimeric protein with the N-terminal domain formed two complexes of different electrophoretic mobilities. The faster-moving complex, whose formation displayed no cooperativity, contained two protein monomers bound to a single DNA molecule. The slower-moving complex, whose formation involved cooperative binding (Hill coefficient > 1.0), contained four protein monomers bound to a single DNA molecule. Methylation interference experiments coupled with the analysis of protein binding to mutant oligonucleotide substrates showed that formation of the faster-moving complex containing two protein monomers required the presence of two 11-bp direct repeats (called DR2) in direct orientation. Formation of the slower-moving complex required only a single DR2 repeat. Binding of the N-terminal domains in vivo could serve to position two Int monomers on the DNA near each end of the transposon and assist in bringing together the ends of the transposon so that excision can occur. The chimeric protein with the C-terminal domain of Int also formed two complexes of different electrophoretic mobilities. The major, slower-moving complex, whose formation involved cooperative binding, contained two protein molecules bound to one DNA molecule. This finding suggested that while the C-terminal domain of Int can bind DNA as a monomer, a cooperative interaction between two monomers of the C-terminal domain may help to bring the ends of the transposon together during excision.     

Avian retrovirus pp32 DNA binding protein. Preferential binding to the promoter region of long terminal repeat DNA

The avian retrovirus pp32 protein possesses DNA endonuclease activity and unique DNA binding properties. An improved purification procedure was developed for pp32, resulting in a severalfold increase in the yield of this virion protein. By use of the nitrocellulose filter binding assay, the protein retains approximately 2-fold more supercoiled (form I) DNA molecules than equivalent linear duplex DNA molecules. Single-stranded DNA is only slightly preferred over double-stranded DNA for pp32 binding. The pp32 DNA binding sites on form I pBR322 DNA which contained an insert of avian retrovirus long terminal repeat (LTR) DNA were determined. A preformed protein-DNA complex was digested with one of several different multicut restriction enzymes and filtered through nitrocellulose filters. Fragments containing viral LTR DNA sequences and plasmid DNA containing promoter sequences for the ampicillin and tetracycline genes, sequences for the "left-end" inverted repeat of transposon 3, and sequences encompassing the carboxyl terminus of the beta-lactamase gene were preferentially retained on the filter by pp32. Partial mapping of pp32 DNA binding sites on LTR DNA was accomplished by generation of deletions in LTR DNA sequences. The pp32 protein preferentially bound viral DNA fragments which contain the viral promoter (TATTTAA) and the adjacent "R" repeat sequences. Computer analysis revealed that three of the four plasmid DNA fragments retained by pp32 contained LTR DNA promoter-like sequences (one mismatch only) which were part of statistically significant and thermodynamically stable hairpin structures.     

Purification and characterization of the RecF protein from Bacillus subtilis 168.

Genetic evidence suggests that the Bacillus subtilis recF gene product is involved in DNA repair and recombination. The RecF protein was overproduced and purified. NH2-terminal protein sequence analysis of RecF was consistent with the deduced amino acid sequence of the recF gene. The RecF protein (predicted molecular mass 42.3 kDa) bound single- and double-stranded DNA in a filter binding and in a gel retarding assay. The RecF-ssDNA or -dsDNA complex formation proceeds in the absence of nucleotide cofactors. RecF-ssDNA interaction is markedly stimulated by divalent cations. The apparent equilibrium constants of the RecF-DNA complexes are approximately 110-130 nM for both ssDNA and dsDNA. The binding reaction shows no cooperativity. The RecF protein does not physically interact with the RecR protein. Under our experimental conditions an ATPase activity was not associated with the purified RecF protein or with the RecF and RecR proteins.     

Quantification of Escherichia coli genomic DNA contamination in recombinant protein preparations by polymerase chain reaction and affinity-based collection

This study describes the development of a novel assay for the quantification of Escherichia coli genomic DNA contamination in recombinant protein samples. The technique is based on PCR amplification and digoxygenin labeling of the genes encoding 5S ribosomal RNA followed by affinity-based collection and detection. Samples containing 1 pg x mL(-1) of extracted E. coli genomic DNA (gDNA) could be measured using this method. Using extracted E. coli gDNA as standards, a 35-cycle PCR reaction exhibited a linear response versus template concentration between 1 pg x mL(-1) and1 ng x mL(-1) genomic DNA even when diluted in a variety of buffering conditions. Comparison of the novel assay with a traditional filter binding and hybridization technique using recombinant protein samples confirmed that the procedure was accurate and sensitive. The assay described in this report is a safer and less expensive alternative to radioactive techniques employed for DNA quantification, utilizing readily available reagents and apparatus.     

Specific interaction of a protein(s) at or near the termini of adenovirus 2 DNA

When human adenovirus type 2 DNA was extracted from the virions, and the sedimentation profile of the DNA-protein complex in a linear sucrose gradient was analyzed by the nitrocellulose filter binding assay, it was found that 90–95% of adenovirus 2 DNA molecules was tightly associated with the protein(s). The analyses of the binding site of the protein(s) on the DNA by using the restriction endonucleases suggested that the protein(s) interact with the DNA at or near the termini of the viral genome. The stability of the linkage between the DNA and the protein(s) was tested in the presence of various reagents. From the available data, it is suggestive that the protein(s) is linked to the DNA covalently.     

Green fluorescent protein as a signal for protein-protein interactions.

Green fluorescent protein (GFP) is autofluorescent. This property has made GFP useful in monitoring in vivo activities such as gene expression and protein localization. We find that GFP can be used in vitro to reveal and characterize protein-protein interactions. The interaction between the S-peptide and S-protein fragments of ribonuclease A was chosen as a model system. GFP-tagged S-peptide was produced, and the interaction of this fusion protein with S-protein was analyzed by two distinct methods: fluorescence gel retardation and fluorescence polarization. The fluorescence gel retardation assay is a rapid method to demonstrate the existence of a protein-protein interaction and to estimate the dissociation constant (Kd) of the resulting complex. The fluorescence polarization assay is an accurate method to evaluate Kd in a specified homogeneous solution and can be adapted for the high-throughput screening of protein or peptide libraries. These two methods are powerful new tools to probe protein-protein interactions.     

Integration of cell-free protein coexpression with an enzyme-linked immunosorbent assay enables rapid analysis of protein-protein interactions directly from DNA

Assays that integrate detection of binding with cell-free protein expression directly from DNA can dramatically increase the pace at which protein-protein interactions (PPIs) can be analyzed by mutagenesis. In this study, we present a method that combines in vitro protein production with an enzyme-linked immunosorbent assay (ELISA) to measure PPIs. This method uses readily available commodity instrumentation and generic antibody-affinity tag interactions. It is straightforward and rapid to execute, enabling many interactions to be assessed in parallel. In traditional ELISAs, reporter complexes are assembled stepwise with one layer at a time. In the method presented here, all the members of the reporter complex are present and assembled together. The signal strength is dependent on all the intercomponent interaction affinities and concentrations. Although this assay is straightforward to execute, establishing proper conditions and analysis of the results require a thorough understanding of the processes that determine the signal strength. The formation of the fully assembled reporter sandwich can be modeled as a competition between Langmuir adsorption isotherms for the immobilized components and binding equilibria of the solution components. We have shown that modeling this process provides semiquantitative understanding of the effects of affinity and concentration and can guide strategies for the development of experimental protocols. We tested the method experimentally using the interaction between a synthetic ankyrin repeat protein (Off7) and maltose-binding protein. Measurements obtained for a collection of alanine mutations in the interface between these two proteins demonstrate that a range of affinities can be analyzed.     

A geminivirus replication protein is a sequence-specific DNA binding protein.

The genome of the geminivirus tomato golden mosaic virus (TGMV) consists of two circular DNA molecules designated as components A and B. The A component encodes the only viral protein, AL1, that is required for viral replication. We showed that AL1 interacts specifically with TGMV A and B DNA by using an immunoprecipitation assay for AL1:DNA complex formation. In this assay, a monoclonal antibody against AL1 precipitated AL1:TGMV DNA complexes, whereas an unrelated antibody failed to precipitate the complexes. Competition assays with homologous and heterologous DNAs established the specificity of AL1:DNA binding. AL1 produced by transgenic tobacco plants and by baculovirus-infected insect cells exhibited similar DNA binding activity. The AL1 binding site maps to 52 bp on the left side of the common region, a 235-bp region that is highly conserved between the two TGMV genome components. The AL1:DNA binding site does not include the putative hairpin structure that is conserved in the common regions or the equivalent 5' intergenic regions of all geminiviruses. These studies demonstrate that a geminivirus replication protein is a sequence-specific DNA binding protein, and the studies have important implications for the role of this protein in virus replication.