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.     

Computer assisted signal co-localization for simultaneous detection of antigen by immunohistochemistry and DNA by non-isotopic in situ hybridization

A method has been developed to co-localize signals for antigen and DNA using a desktop microcomputer system (computer assisted signal co-localization). Antigens were detected by standard immunohistochemical methods and DNA was detected by non-isotopic in situ hybridization (NISH). Using this method, NISH signals can be precisely located in cells with well-preserved morphology captured by computer. The removal of the first immunohistochemical reaction products and reagents eliminates possible interference with hybridization and non-specific binding to the probe; therefore the sensitivity of the original NISH method remains. The captured NISH signals can be converted to any other colour which contrasts with the immunostaining. We have used detection of Epstein-Barr virus (EBV) and keratins as a model system. This method is straightforward, and with necessary modifications, will be applicable to any type of combined immunohistochemistry and in situ hybridization technique for simultaneous detection of antigen and nucleic acids or two types of nucleic acids in the same cells.     

Nucleic binding affinity of bacteriophage T4 gene 32 protein in the cooperative binding mode

This study reports on various parameters which affect the binding stoichiometry for complexes of bacteriophage T4 gene 32 protein (P32) and single stranded polynucleotides (determined by UV absorbance and fluorescence quenching) and presents results of a quantitative electron spin resonance assay to determine physiologically effective binding affinity differences of nucleic acid binding proteins. The assay employs macromolecular spin probes (spin-labeled nucleic acids) which are used to determine the fraction of saturation in competition experiments with unlabeled nucleic acids. It was found that the fraction of complexed spin-labeled polynucleotides can be directly monitored by ESR with a two-component analysis approach when ligands such as poly(L-lysine), gene 5 protein (P5) of filamentous bacteriophage fd, and gene 32 protein (P32) of bacteriophage T4 are used. The ESR data unequivocally show that: 1) the binding stoichiometry for poly(L-lysine), P5 and P32 is nucleotide/lysine, 4 nucleotides/P5 monomer, and 10 nucleotides/P32 monomer, respectively; and 2) under physiologically relevant buffer conditions the relative affinity of P32 in the cooperative binding mode for polythymidylic acid is about 4 times greater than for polydeoxyinosinic acid and about 12 times greater than for polyinosinic acid, and the relative affinity of P32 for polydeoxyinosinic acid is about 3 times greater than for polyinosinic acid.     

Laser cross-linking of nucleic acids to proteins. Methodology and first applications to the phage T4 DNA replication system

Single-pulse (approximately 8 ns) ultraviolet laser excitation of protein-nucleic acid complexes can result in efficient and rapid covalent cross-linking of proteins to nucleic acids. The reaction produces no nucleic acid-nucleic acid or protein-protein cross-links, and no nucleic acid degradation. The efficiency of cross-linking is dependent on the wavelength of the exciting radiation, on the nucleotide composition of the nucleic acid, and on the total photon flux. The yield of cross-links/laser pulse is largest between 245 and 280 nm; cross-links are obtained with far UV photons (200-240 nm) as well, but in this range appreciable protein degradation is also observed. The method has been calibrated using the phage T4-coded gene 32 (single-stranded DNA-binding) protein interaction with oligonucleotides, for which binding constants have been measured previously by standard physical chemical methods (Kowalczykowski, S. C., Lonberg, N., Newport, J. W., and von Hippel, P. H. (1981) J. Mol. Biol. 145, 75-104). Photoactivation occurs primarily through the nucleotide residues of DNA and RNA at excitation wavelengths greater than 245 nm, with reaction through thymidine being greatly favored. The nucleotide residues may be ranked in order of decreasing photoreactivity as: dT much greater than dC greater than rU greater than rC, dA, dG. Cross-linking appears to be a single-photon process and occurs through single nucleotide (dT) residues; pyrimidine dimer formation is not involved. Preliminary studies of the individual proteins of the five-protein T4 DNA replication complex show that gene 43 protein (polymerase), gene 32 protein, and gene 44 and 45 (polymerase accessory) proteins all make contact with DNA, and can be cross-linked to it, whereas gene 62 (polymerase accessory) protein cannot. A survey of other nucleic acid-binding proteins has shown that E. coli RNA polymerase, DNA polymerase I, and rho protein can all be cross-linked to various nucleic acids by the laser technique. The potential uses of this procedure in probing protein-nucleic acid interactions are discussed.     

Single-stranded DNA binding protein facilitates specific enrichment of circular DNA molecules using rolling circle amplification

Many techniques in molecular biology require the use of pure nucleic acids in general and circular DNA (plasmid or mitochondrial) in particular. We have developed a method to separate these circular molecules from a mixture containing different species of nucleic acids using rolling circle amplification (RCA). RCA of plasmid or genomic DNA using random hexamers and bacteriophage Phi29 DNA polymerase has become increasingly popular for the amplification of template DNA in DNA sequencing protocols. Recently, we reported that the mutant single-stranded DNA binding protein (SSB) from Thermus thermophilus (TthSSB) HB8 eliminates nonspecific DNA products in RCA reactions. We developed this method for separating circular nucleic acids from a mixture having different species of nucleic acids. Use of the mutant TthSSB resulted in an enhancement of plasmid or mitochondrial DNA content in the amplified product by approximately 500×. The use of mutant TthSSB not only promoted the amplification of circular target DNA over the background but also could be used to enhance the amplification of circular targets over linear targets.     

Interaction of resveratrol and genistein with nucleic acids

Resveratrol (RES) and genistein (GEN) are the dietary natural products known to possess chemopreventive property and also the ability to repair DNA damage induced by mutagens/carcinogens. It is believed that the therapeutic activity of these compounds could be primarily due to their interaction with nucleic acids but detailed reports are not available. We here explore the interaction of these drugs with nucleic acids considering DNA and RNA as a potential therapeutic target. The interaction of RES and GEN has been analysed in buffered solution with DNA [saline sodium citrate (SSC)] and RNA [tris ethylene diammine tetra acetic acid (TE)] using UV-absorption and Fourier transform infrared (FTIR) spectroscopy. The UV analysis revealed lesser binding affinity with nucleic acids at lower concentration of RES (P/D = 5.00 and 10.00), while at higher drug concentration (P/D = 0.75, 1.00 and 2.50) hyperchromic effect with shift in the lambda(max) is noted for DNA and RNA. A major RES-nucleic acids complexes was observed through base pairs and phosphate backbone groups with K = 35.782 M(-1) and K = 34.25 M(-1) for DNARES and RNA-RES complexes respectively. At various concentrations of GEN (P/D = 0.25, 0.50, 0.75, 1.00 and 2.50) hyperchromicity with shift in the lambda(max) from 260-->263 nm and 260--> 270 nm is observed for DNA-GEN and RNA-GEN complexes respectively. The binding constant (from UV analysis) for GEN-nucleic acids complexes could not be obtained due to GEN absorbance overlap with that of nucleic acids at 260 nm. Nevertheless a detailed analysis with regard to the interaction of these drugs (RES/GEN) with DNA and RNA could feasibly be understood by FTIR.     

Phosphorylation and nucleic acid binding properties of m1 Moloney murine sarcoma virus-specific pP60gag.

The pP60gag polyprotein of the feline leukemia virus pseudotype of m1 Moloney murine sarcoma virus [m1MSV(FeLV)] was previously shown to be MSV specific and to contain murine p30 and smaller structural polypeptides. This protein was detected in m1MSV-transformed cells, and in pulse-chase studies it was found to be stable. In this study virion P60 was shown to contain murine pp12, to be phosphorylated, and to bind to nucleic acids. 32P-labeled m1MSV[FeLV) was fractionated by guanidine agarose chromatography and analyzed by gel electrophoresis. Both P60 and pp12 were found to be the major phosphoproteins, phosphorylated in both serine and threonine residues. Virion P60 bound preferentially to single-stranded DNA and RNA in a competition filter binding assay, using 125I-labeled single-stranded calf thymus DNA and various unlabeled nucleic acids. Similar phosphorylation and DNA binding properties were demonstrated for cellular P60. Thus, immunoprecipitation of cellular extracts showed that P60 was phosphorylated in both producer and nonproducer transformed cells, indicating that phosphorylation occurs independently of virus assembly. Moreover, P60 from cytoplasmic extracts was retained on single-stranded DNA-Sepharose columns, demonstrating that cellular P60 binds to DNA.     

A rapid assay for affinity and kinetics of molecular interactions with nucleic acids

The Differential Radial Capillary Action of Ligand Assay (DRaCALA) allows detection of protein interactions with low-molecular weight ligands based on separation of the protein-ligand complex by differential capillary action. Here, we present an application of DRaCALA to the study of nucleic acid-protein interactions using the Escherichia coli cyclic AMP receptor protein (CRP). CRP bound in DRaCALA specifically to (32)P-labeled oligonucleotides containing the consensus CRP binding site, but not to oligonucleotides with point mutations known to abrogate binding. Affinity and kinetic studies using DRaCALA yielded a dissociation constant and dissociation rate similar to previously reported values. Because DRaCALA is not subject to ligand size restrictions, whole plasmids with a single CRP-binding site were used as probes, yielding similar results. DNA can also function as an easily labeled carrier molecule for a conjugated ligand. Sequestration of biotinylated nucleic acids by streptavidin allowed nucleic acids to take the place of the protein as the immobile binding partner. Therefore, any molecular interactions involving nucleic acids can be tested. We demonstrate this principle utilizing a bacterial riboswitch that binds cyclic-di-guanosine monophosphate. DRaCALA is a flexible and complementary approach to other biochemical methods for rapid and accurate measurements of affinity and kinetics at near-equilibrium conditions.     

Recognition of chemically damaged DNA by the gene 32 protein from bacteriophage T4

We have used fluorescence spectroscopy to investigate the binding of gene 32 protein from bacteriophage T4 to DNA which has been chemically modified with carcinogens or antitumor drugs. This protein exhibits a high specificity for single-stranded nucleic acids and binds more efficiently to DNA modified either with cis-diaminodichloroplatinum(II) or with aminofluorene derivatives than to native DNA. This increased affinity is related to the formation of locally unpaired regions which are strong binding sites for the single-strand binding protein. In contrast, gene 32 protein has the same affinity for native DNA, DNA containing methylated purines and DNA that has reacted with trans-diaminodichloroplatinum(II) or with chlorodiethylenetriaminoplatinum(II) chloride. These types of damage do not induce a sufficient structural change to allow gene 32 protein binding. Depurination of DNA does not create binding sites for the T4 gene 32 protein but nicked apurinic sites are strong ligands for the protein. This T4 single-strand binding protein does not exhibit a significantly increased affinity for nicked DNA as compared with native DNA. These results are discussed with respect to the recognition of DNA damage by proteins involved in DNA repair and to the possible role of single-strand binding proteins in DNA repair mechanisms.     

Preparation of GDP-D-mannose specifically labeled with tritium in the D-mannosyl moiety

A method, called “bidirectional transfer”, has been described for the transfer of DNA and RNA from agarose or polyacrylamide gels onto diazobenzyloxymethyl (DBM)-paper or nitrocellulose filters. The gels were sandwiched between either two nitrocellulose filters or two diazobenzyloxymethyl-papers. Next, the nucleic acids were allowed to diffuse out of the gels onto the filters. In this way, duplicate blots were obtained from a single gel. The bidirectional transfer of DNA or RNA from 0.5 to 1% agarose gels was complete and nearly quantitative after 1 h of transfer. DNA fragments from 5% polyacrylamide gels were efficiently blotted after 36 h onto nitrocellulose filters using bidirectional transfer. The fragments were transferred with good resolution and were shown to be efficient substrates for homologous [³²P]DNA probes.     

Fluorometric quantification of RNA and DNA in solutions containing both nucleic acids

A fluorescence-based method for quantitative determination of RNA and DNA in probes containing both nucleic acids has been developed. The total concentration of nucleic acids is determined using SYBR Green II dye under conditions providing independent binding of the fluorophore with DNA and RNA. The concentration of DNA is specifically measured using the Hoechst 33258 dye and the RNA concentration is calculated from these data. The procedure allows for accurate determination of DNA concentration in the range 10-1000 ng/ml in the presence of 200-fold excess of RNA and determination of RNA concentrations in the range 10-1000 ng/ml in the presence of large excess of DNA. An absence of the treatment of mixed samples with RNase-free DNase I provides rapid, reproducible, and accurate RNA quantification.     

Using FAM labeled DNA oligos to do RNA electrophoretic mobility shift assay

The electrophoretic mobility shift assay is a useful tool to identify proteins and nucleic acids interactions. Traditionally, the nucleic acids fragments are end-labeled with ³²P. We present here the use of fluorescent methodologies for studies of RNA in place of radioactivity. The method is highly sensitive and quantitative with the use of an infrared fluorescence imaging system. Fluorescently labeled primers can be used to monitor protein–RNA interactions by fluorescent mobility shift assays. The simplicity and validity of this approach may have more advantages than that of previous methods that traditionally used hazardous radioisotopes. This method was successfully tested in the study of the interactions between MS2 Coat Protein and its RNA target.     

The P30 movement protein of tobacco mosaic virus is a single-strand nucleic acid binding protein

The P30 protein of tobacco mosaic virus (TMV) is required for cell to cell movement of viral RNA, which presumably occurs through plant intercellular connections, the plasmodesmata. The mechanism by which P30 mediates transfer of TMV RNA molecules through plasmodesmata channels is unknown. We have identified P30 as an RNA and single-stranded (ss) DNA binding protein. Binding of purified P30 to ss nucleic acids is strong, highly cooperative, and sequence nonspecific with a minimal binding site of 4-7 nucleotides per P30 monomer. In-frame deletions across P30 were used to localize the ss nucleic acid binding domain to within amino acid residues 65-86 of the protein. We propose that binding of P30 to TMV RNA creates an unfolded protein-RNA complex that functions as an intermediate in virus cell to cell movement through plasmodesmata.     

A spin probe approach for measuring the nucleic acid affinity of gene 32 protein.

A novel and fast procedure for determining by electron spin resonance the affinity of proteins for nucleic acids is described. The assay makes use of nitroxide radicals which are covalently bound to various polynuleotides to the extent of one probe per 75 to 100 nucleotides. As a test example gene 32 protein was used, a protein known to interact with single stranded nucleic acids. Competition experiments with unlabeled nucleic acids made it feasible to directly monitor the gene 32 protein affinity for different nucleic acids. It was observed that DNA single strands are not necessarily favored by this protein for preferential binding. The experimental data also suggest that the difference in the binding constants for most of the complexes is remarkably large; for instance, (dT)_n binds at least 3 to 4 orders of magnitude better to gene 32 protein than (dA)_n.     

Tyrosine mutant helps define overlapping CD bands from fd gene 5 protein · nucleic acid complexes

We used a mutant gene 5 protein (g5p) to assign and interpret overlapping CD bands of protein · nucleic acid complexes. The analysis of overlapping protein and nucleic acid CD bands is a common challenge for CD spectroscopists, since both components of the complex may change upon binding. We have now been able to more confidently resolve the bands of nucleic acids complexed with the fd gene 5 protein by exploiting a mutant gene 5 protein that has an insignificant change in tyrosine optical activity at 229 nm upon binding to nucleic acids. We have studied the interactions of the mutant Y34F g5p (Tyr-34 substituted with phenylalanine) with poly[r(A)], poly[d(A)], and fd single-stranded DNA (ssDNA). Our results showed the following: (1) The 205–300 nm spectrum of poly[r(A)] saturated with the Y34F mutant (P/N = 0.25) was essentially the sum of the spectra of poly[r(A)] at a high temperature plus the spectrum of the free protein, except for a minor negative band at 257 nm. (2) The spectra of poly[d(A)] and fd ssDNA saturated with the mutant protein at a P/N = 0.25, minus the spectra of the free nucleic acids at a high temperature, also essentially equaled the spectrum of the free protein in the 205–245 nm region. (3) While the overall secondary structure of the Y34F protein did not change upon binding to any of these nucleic acids, there could be changes in the environment of individual aromatic residues. (4) Nucleic acids complexed with the g5p are unstacked (as if heated) and (in the cases of the DNAs) perturbed as if part of a dehydrated double-stranded DNA. (5) Difference spectra revealed regions of the spectrum specific for the particular nucleic acid, the protein, and whether g5p was bound to DNA or RNA. © 1997 John Wiley and Sons, Inc. Biopoly 42: 337–348, 1997     

Improved chemiluminescent DNA sequencing

A new chemiluminescent 1,2-dioxetane substrate, CSPD, shows improved performance over AMPPD when used in our nonisotopic method for DNA sequencing. CSPD differs from AMPPD by the addition of a chlorine atom to the adamantyl group that limits the amount of aggregation of the dioxetane and its dephosphorylated anion. This results in a shorter time elapsing before reaching steady state light emission when detecting nucleic acids on nylon membrane. An additional advantage of CSPD over AMPPD is that the resolution of imaged DNA bands does not degrade over time. These features of CSPD permit rapid acquisition of high-quality DNA sequence data.     

Characterization of the nucleic acid-binding activities of the isolated amino-terminal head domain of the intermediate filament protein vimentin reveals its close relationship to the DNA-binding regions of some prokaryotic single-stranded DNA-binding proteins.

In order to demonstrate that the nucleic acid-binding activities of vimentin are dictated by its Arg-rich N-terminal head domain, this was cut off at position Lys96 with lysine-specific endoproteinase and analysed for its capacity to associate with a variety of synthetic and naturally occurring nucleic acids. The isolated polypeptide (vim NT) showed a preference for single-stranded (ss) polynucleotides, particularly for ssDNAs of high G-content. A comparison of the sequence and predicted secondary structure of vim NT with that of two prokaryotic ssDNA-binding proteins, G5P and G32P of bacteriophages fd and T4, respectively, revealed that the nucleic acid-binding region of all three polypeptides is almost entirely in the beta-conformation and characterized by a very similar distribution of aromatic amino acid residues. A partial sequence of vim NT can be folded into the same beta-loop structure as the DNA-binding wing of G5P of bacteriophage fd and related viruses. As in the case of G5P, nitration of the Tyr residues with tetranitromethane was blocked by single-stranded nucleic acids. This and spectroscopic data indicate intercalation of the Tyr aromatic ring systems between the bases of the nucleic acids and thus the contribution of a stacking component to the binding reaction. The binding was accompanied by significant changes in the ultraviolet absorption spectra of both vim NT and single-stranded nucleic acids. Upon mixing of vim NT with nucleic acids, massive precipitation of the reactants occurred, followed by the quick rearrangement of the aggregates with the formation of specific and soluble association products. Even at very high ionic strengths, at which no electrostatic reaction should be expected, a distinct fraction of vim NT incorporated naturally occurring ssRNAs and ssDNAs into fast sedimenting complexes, suggesting co-operative interaction of the polypeptide with the nucleic acids. In electron microscopy, the complexes obtained from 28 S rRNA appeared as networks of extended nucleic acid strands densely covered with vim NT, in contrast to the compact random coils of uncomplexed RNA. The networks produced from fd DNA were heterogeneous in appearance and their nucleoprotein strands in rare cases were very similar to the rod-like structures of G5P-fd DNA complexes.     

High-throughput single-nucleotide structural mapping by capillary automated footprinting analysis

The use of capillary electrophoresis with fluorescently labeled nucleic acids revolutionized DNA sequencing, effectively fueling the genomic revolution. We present an application of this technology for the high-throughput structural analysis of nucleic acids by chemical and enzymatic mapping ('footprinting'). We achieve the throughput and data quality necessary for genomic-scale structural analysis by combining fluorophore labeling of nucleic acids with novel quantitation algorithms. We implemented these algorithms in the CAFA (capillary automated footprinting analysis) open-source software that is downloadable gratis from https://simtk.org/home/cafa. The accuracy, throughput and reproducibility of CAFA analysis are demonstrated using hydroxyl radical footprinting of RNA. The versatility of CAFA is illustrated by dimethyl sulfate mapping of RNA secondary structure and DNase I mapping of a protein binding to a specific sequence of DNA. Our experimental and computational approach facilitates the acquisition of high-throughput chemical probing data for solution structural analysis of nucleic acids.     

A streptavidin paramagnetic-particle based competition assay for the evaluation of the optical selectivity of quadruplex nucleic acid fluorescent probes

Although quadruplex nucleic acids are thought to be involved in many biological processes, they are massively overwhelmed by duplex DNA in the cell. Small molecules, able to probe quadruplex nucleic acids with high optical selectivity, could possibly achieve the visualization of these processes. The aim of the method described herein is to evaluate quickly the optical selectivity of quadruplex nucleic acid probes, in isothermal conditions, using widely available materials, small quantities of oligonucleotides and virtually any kind and quantity of biological competitor. The assay relies on the use of streptavidin-coated paramagnetic particles and biotinylated quadruplex forming oligonucleotides, allowing a quick and easy separation of the quadruplex target from the competitor. In the present study, two quadruplex nucleic acids (the DNA and RNA human telomeric repeats) have been used as targets while a duplex DNA oligonucleotide, total DNA, total RNA, another quadruplex nucleic acid and a protein have been used as competitors. The optical selectivity of various probes, displaying different photophysical properties and binding selectivities, has been successfully examined, allowing the identification of a best candidate for further cell microscopy experiments. This assay allows a quick and reliable assessment of the labeling properties of a quadruplex binder in cellular environment conditions. It is an interesting alternative to gel electrophoresis experiments since it is performed in solution, has a well-resolved separation system and allows easy quantifications.     

Interactions of pyronin Y(G) with nucleic acids

Spectral properties of pyronin Y(PY) alone or in complexes with natural and synthetic nucleic acids of various base compositions have been studied in aqueous solution containing 10 or 150 mM NaCl and 5 mM Hepes at pH 7.0. The dimerization constant (KD = 6.27 X 10(3), M-1) and the absorption spectra of the dye in monomeric and dimeric form were established. The complexes of PY with single-stranded (ss) nucleic acids show a hypsochromic shift in absorption, and their fluorescence is quenched by over 90% compared to free dye. In contrast, complexes with double-stranded (ds) RNA or DNA (binding by intercalation) exhibit a bathochromic shift in their absorption (excitation) spectrum, and their fluorescence is correlated with the base composition of the binding site. Namely, guanine quenches fluorescence of PY by up to 90%, whereas A, C, I, T, and U bases exert a rather minor effect on the fluorescence quantum yield of the dye. The intrinsic association constant of the dye to ds RNA (Ki = 6.96 X 10(4), M-1) and to ds DNA (Ki = 1.74 X 10(4), M-1) was measured in 150 mM NaCl; the binding site size was 2-3 base pair for both polymers. Implications of these findings for qualitative and quantitative cytochemistry of nucleic acids are discussed.