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.     

Structural and enzymatic studies of the T4 DNA replication system. II. ATPase properties of the polymerase accessory protein complex

In this paper we report a detailed enzymatic characterization of the interaction of the polymerase accessory protein complex of the T4 DNA replication system with the various nucleic acid cofactors that activate the ATPase of the complex. We show that the ATPase activity of the T4 coded gene 44/62 protein complex is stimulated synergistically by binding of DNA and T4 gene 45 protein and that the level of ATPase activation appears to be directly correlated with the binding of nucleic acid cofactor. Binding of any partially or completely single-stranded DNA to the complete accessory protein complex increases the catalytic activity (as measured by Vmax) while decreasing the binding affinity for the ATP substrate. While single-stranded DNA is a moderately effective cofactor, we find that the optimal nucleic acid-binding site for the complex is the primer-template junction, rather than single-stranded DNA ends as previously reported in the literature. Gene 45 protein plays an essential role in directing the specificity of binding to primer-template sites, lowering the Km for primer-template sites almost 1000-fold, and increasing Vmax 100-fold, compared with the analogous values for gene 44/62 protein alone. The most effective primer-template site for binding and enzymatic activation has the physiologically relevant recessed 3'-OH configuration and an optimal size in excess of 18 base pairs of duplex DNA. We find that the chemical nature of the primer terminus (i.e. 3'-OH or 3'-H) does not affect the extent of ATPase activation and that binding of the polymerase accessory protein complex to DNA cofactors is salt concentration dependent but appreciably less so when the activating DNA is a primer-template junction. Finally, we show that the gene 32 protein (T4 coded single-stranded DNA-binding protein) can compete with the polymerase accessory protein complex for single-stranded DNA but not for the primer-template junction activation sites. The implications of these results for the structure and function of the polymerase accessory protein complex within the T4 DNA replication system are discussed.     

Modern tools for identification of nucleic acid-binding proteins

Numerous biological mechanisms depend on nucleic acid--protein interactions. The first step to the understanding of these mechanisms is to identify interacting molecules. Knowing one partner, the identification of other associated molecular species can be carried out using affinity-based purification procedures. When the nucleic acid-binding protein is known, the nucleic acid can be isolated and identified by sensitive techniques such as polymerase chain reaction followed by DNA sequencing or hybridization on chips. The reverse identification procedure is less straightforward in part because interesting nucleic acid-binding proteins are generally of low abundance and there are no methods to amplify amino acid sequences. In this article, we will review the strategies that have been developed to identify nucleic acid-binding proteins. We will focus on methods permitting the identification of these proteins without a priori knowledge of protein candidates.     

A new electron microscopic method for studying protein-nucleic acid interactions.

A new method for preparation of nucleic acid specimens for electron microscopy has been adapted to study the interaction of proteins with DNA. Both a detergent and a basic protein are added to the DNA-protein solution before spreading on a hypophase containing 0.2 m ammonium acetate. This method has been tested using T7 DNA and Escherichia coli RNA polymerase. Specifically bound enzyme molecules were clearly visible on the well extended DNA molecules; the binding sites were located at 0.59, 1.24, 1.57, and 1.86% of the total length of T7 DNA. Under carefully controlled conditions, 40–85% of the DNA molecules specifically bound at least one enzyme molecule.     

Ligase-mediated construction of branched DNA strands: a novel DNA joining activity catalyzed by T4 DNA ligase

Branched nucleic acid strands exist as intermediates in certain biological reactions, and bifurcating DNA also presents interesting opportunities in biotechnological applications. We describe here how T4 DNA ligase can be used for efficient construction of DNA molecules having one 5′ end but two distinct 3′ ends that extend from the 2′ and 3′ carbons, respectively, of an internal nucleotide. The nature of the reaction products is investigated, and optimal reaction conditions are reported for the construction of branched oligonucleotides. We discuss the utility of these branched DNA nanostructures for gene detection.     

Studies on bacteriophage T7 DNA synthesis in vitro. II. Reconstitution of the T7 replication system using purified proteins.

Summary DNA synthesis in vitro using intact duplex T7 DNA as template is dependent on a novel group of three phage T7-induced proteins: DNA-priming protein (activity which complements a cell extract lacking the T7 gene 4-protein), T7 DNA polymerase (gene 5-protein plus host factor), and T7 DNA-binding protein. The reaction requires, in addition to the four deoxyribonucleoside triphosphates, all four ribonucleoside triphosphates and is inhibited by low concentrations of actinomycin D. Evidence is presented that the priming protein serves as a novel RNA polymerase to form a priming segment which is subsequently extended by T7 DNA polymerase. T7 RNA polymerase (gene 1-protein) can only partially substitute for the DNA-priming protein. At 30°C, deoxyribonucleotide incorporation proceeds for more than 2 hours and the amount of newly synthesized DNA can exceed the amount of template DNA by 10-fold. The products of synthesis are not covalently attached to the template and sediment as short (12S) DNA chains in alkaline sucrose gradients. Sealing of these fragments into DNA of higher molecular weight requires the presence of E. coli DNA polymerase I and T7 ligase. Examination of the products in the electron microscope reveals many large, forked molecules and a few eye-shaped structures resembling the early replicative intermediates normally observed in vivo.     

NMR studies of dynamics in RNA and DNA by 13C relaxation

RNA and DNA molecules experience motions on a wide range of time scales, ranging from rapid localized motions to much slower collective motions of entire helical domains. The many functions of RNA in biology very often require this molecule to change its conformation in response to biological signals in the form of small molecules, proteins or other nucleic acids, whereas local motions in DNA may facilitate protein recognition and allow enzymes acting on DNA to access functional groups on the bases that would otherwise be buried in Watson-Crick base pairs. Although these statements make a compelling case to study the sequence dependent dynamics in nucleic acids, there are few residue-specific studies of nucleic acid dynamics. Fortunately, NMR studies of dynamics of nucleic acids and nucleic acids-protein complexes are gaining increased attention. The aim of this review is to provide an update of the recent progress in studies of nucleic acid dynamics by NMR based on the application of solution relaxation techniques.     

A sense of closeness: protein detection by proximity ligation

Highly specific and sensitive procedures will be required to evaluate proteomes. Proximity ligation is a recently introduced mechanism for protein analysis. In this technique, the convergence of sets of protein-binding reagents on individual target molecules juxtaposes attached nucleic acid sequences. Through a ligation reaction a DNA reporter sequence is created, which can be amplified. The procedure thus encodes detected proteins as specific nucleic acid sequences in what may be viewed as a reverse translation reaction.     

The Arrangements of Nucleotide Sequences in T2 and T5 Bacteriophage DNA Molecules

The genetic map of T4 (and T2) bacteriophage is circular but the DNA molecule that is liberated by phenol extraction is a linear duplex of polynucleotide chains. If the genetic map is related to the physical structure of the DNA molecule, the problem arises as to how a linear molecule can give rise to a circular map. An explanation can be made on the basis that the bacteriophage liberate molecules which have nucleotide sequences which are circular permutations of each other. Thus, markers which are most distant on one molecules are closest together on another. To test this hypothesis, the middles of T2 and T5 DNA molecules were mechanically deleted and the absence of certain nucleotide sequences was tested by “renaturation” or “reannealing” experiments using columns containing denatured DNA immobilized in agar beads. The results indicate that when the middles are deleted from the T5 DNA molecule, some special sequences are removed; whereas, when the middles are deleted from the T2 DNA molecule, no special group of sequences is removed. This would indicate that T2 molecules begin at different points in their nucleotide sequence, while T5 molecules all begin at the same point. It is likely that this permutation of sequences of T2(T4) molecules is related to the circularity of their genetic map.     

Laser crosslinking of E. coli RNA polymerase and T7 DNA.

The first photochemical crosslinking of a protein to a nucleic acid using laser excitation is reported. A single, 120 mJ, 20 ns pulse at 248 nm crosslinks about 10% of bound E. coli RNA polymerase to T7 DNA under the conditions studied. The crosslinking yield depends on mercaptoethanol concentration, and is a linear function of laser intensity. The protein subunits crosslinked to DNA are beta, beta' and sigma.     

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.     

Assembly of bacteriophage T7. Dimensions of the bacteriophage and its capsids.

The dimensions of bacteriophage T7 and T7 capsids have been investigated by small-angle x-ray scattering. Phage T7 behaves like a sphere of uniform density with an outer radius of 301 +/- 2 A (excluding the phage tail) and a calculated volume for protein plus nucleic acid of 1.14 +/- 0.05 x 10(-16) ml. The outer radius determined for T7 phage in solution is approximately 30% greater than the radius measured from electron micrographs, which indicates that considerable shrinkage occurs during preparation for electron microscopy. Capsids that have a phagelike envelope and do not contain DNA were obtained from lysates of T7-infected Escherichia coli (capsid II) and by separating the capsid component of T7 phage from the phage DNA by means of temperature shock (capsid IV). In both cases the peak protein density is at a radius of 275 A; the outer radius is 286 +/- 4 A, approximately 5% smaller than the envelope of T7 phage. The thickness of the envelope of capsid II is 22 +/- 4 A, consistent with the thickness of protein estimated to be 23 +/- 5 A in whole T7 phage, as seen on electron micrographs in which the internal DNA is positively stained. The volume in T7 phage available to package DNA is estimated to be 9.2 +/- 0.4 x 10(-17) ml. The packaged DNA adopts a regular packing with 23.6 A interplanar spacing between, DNA strands. The angular width of the 23.6 A reflection shows that the mean DNA-DNA spacing throughout the phage head is 27.5 +/- less than 2.2 A. A T7 precursor capsid (capsid I) expands when pelleted for x-ray scattering in the ultracentrifuge to essentially the same outer dimensions as for capsids II and IV. This expansion of capsid I can be prevented by fixing with glutaraldehyde; fixed capsid I has peak density at a radius of 247 A, 10% less than capsid II or IV.     

An electron microscopic method for the mapping of proteins attached to nucleic acids.

An electron microscopic method for demonstrating the presence of and mapping the positions of proteins specifically bound to nucleic acids is described. The nucleic acid-protein complex is treated with dinitrofluorobenzene under conditions such that dinitrophenyl (DNP) groups are attached to nucleophilic groups on the protein, with only a low level of random attachment to the nuclei acid. This product is treated with rabbit anti-DNP IgG. The position of the protein-(DNP)n(IgG)m complex on the nucleic acid strand can be observed by electron microscopy by protein free spreading methods and, in many cases, by cytochrome-c spreading. If necessary for visualization by the latter method, the size of the labeled region can be increased by treatment with goat anti-rabbit IgG. High efficiency of electron microscopic labeling is achieved. Examples studied are: the adenovirus-2 DNA terminal protein, a protein covalently bound to SV40 DNA, DNA polymerase I bound to DNA, E. coli RNA polymerase bound to T7 DNA, and proteins UV crosslinked to avian sarcoma virus RNA.     

Effects of the bacteriophage T4 dda protein on DNA synthesis catalyzed by purified T4 replication proteins

The T4 bacteriophage dda protein is a DNA-dependent ATPase and DNA helicase that is the product of an apparently nonessential T4 gene. We have examined its effects on in vitro DNA synthesis catalyzed by a purified, multienzyme T4 DNA replication system. When DNA synthesis is catalyzed by the T4 DNA polymerase on a single-stranded DNA template, the addition of the dda protein is without effect whether or not other replication proteins are present. In contrast, on a double-stranded DNA template, where a mixture of the DNA polymerase, its accessory proteins, and the gene 32 protein is required, the dda protein greatly stimulates DNA synthesis. The dda protein exerts this effect by speeding up the rate of replication fork movement; in this respect, it acts identically with the other DNA helicase in the T4 replication system, the T4 gene 41 protein. However, whereas a 41 protein molecule remains bound to the same replication fork for a prolonged period, the dda protein seems to be continually dissociating from the replication fork and rebinding to it as the fork moves. Some gene 32 protein is required to observe DNA synthesis on a double-stranded DNA template, even in the presence of the dda protein. However, there is a direct competition between this helix-destabilizing protein and the dda protein for binding to single-stranded DNA, causing the rate of replication fork movement to decrease at a high ratio of gene 32 protein to dda protein. As shown elsewhere, the dda protein becomes absolutely required for in vitro DNA synthesis when E. coli RNA polymerase molecules are bound to the DNA template, because these molecules otherwise stop fork movement (Bedinger, P., Hochstrasser, M., Jongeneel, C.V., and Alberts, B. M. (1983) Cell 34, 115-123).     

FRACTIONATION OF NUCLEAR,CHLOROPLAST, AND MITOCHONDRIAL DNA FROM POLYSIPHONIA BOLDII (RHODOPHYTA) USING A RAPID AND SIMPLE METHOD FOR THE SIMULTANEOUS ISOLATION OF RNA AND DNA1

Extraction of nucleic acids from red algae is complicated by the presence of phycocolloids. For this reason, methods used for nucleic acid isolation from other organisms are not always amenable to use with red algal preparations; modifications in some cases lead to protocols that are time consuming and complicated, often requiring large amounts of algal tissue for starting material. Here we describe the isolation of both RNA and DNA followed by fractionation and identification of nuclear, chloroplast, and mitochondrial DNAs from a single preparation of Polysiphonia boldii Wynne and Edwards using a simple method that yielded approximately 100 μg of total RNA and 20 μg of total DNA from 1 g of frozen powdered algae. The potent protein denaturant guanidinium thiocyanate and the detergent sarkosyl were used to gently lyse the cells and organelles and immediately inhibit nuclease activity in the extract. The nucleic acids were isolated by ultracentrifugation into a dense solution of CsCl; the RNA was recovered as a pellet and the DNA as a band within the CsCl solution. Agarose gel electrophoresis of the total RNA showed discrete ribosomal RNA bands, indicating little nonspecific degradation. The nuclear, chloroplast, and mitochondrial DNAs were fractionated by density gradient ultracentrifugation in the presence of the DNA binding dye, bisbenzimide H (Hoechst 33258), which binds preferentially to DNA with a high A + T:G + C ratio, thus altering its density to a greater degree than it does that of DNA with a lower nucleotide ratio. The three fractions were identified by Southern blot analysis using heterologous gene probes specific for the different genomes. The protocol should be applicable to different types of algae. The simple nucleic acid isolation step can be performed on multiple samples simultaneously without subsequent fractionation of DNA, allowing comparison of DNA from different individuals, populations, or species.     

Biomarkers of therapeutic responses in chronic Chagas disease: state of the art and future perspectives

The definition of a biomarker provided by the World Health Organization is any substance, structure, or process that can be measured in the body, or its products and influence, or predict the incidence or outcome of disease. Currently, the lack of prognosis and progression markers for chronic Chagas disease has posed limitations for testing new drugs to treat this neglected disease. Several molecules and techniques to detect biomarkers in Trypanosoma cruzi-infected patients have been proposed to assess whether specific treatment with benznidazole or nifurtimox is effective. Isolated proteins or protein groups from different T. cruzi stages and parasite-derived glycoproteins and synthetic neoglycoconjugates have been demonstrated to be useful for this purpose, as have nucleic acid amplification techniques. The amplification of T. cruzi DNA using the real-time polymerase chain reaction method is the leading test for assessing responses to treatment in a short period of time. Biochemical biomarkers have been tested early after specific treatment. Cytokines and surface markers represent promising molecules for the characterisation of host cellular responses, but need to be further assessed.     

Residues located in the primase domain of the bacteriophage T7 primase-helicase are essential for loading the hexameric complex onto DNA

The T7 primase-helicase plays a pivotal role in the replication of T7 DNA. Using affinity isolation of peptide–nucleic acid crosslinks and mass spectrometry, we identify protein regions in the primase-helicase and T7 DNA polymerase that form contacts with the RNA primer and DNA template. The contacts between nucleic acids and the primase domain of the primase-helicase are centered in the RNA polymerase subdomain of the primase domain, in a cleft between the N-terminal subdomain and the topoisomerase-primase fold. We demonstrate that residues along a beta sheet in the N-terminal subdomain that contacts the RNA primer are essential for phage growth and primase activity in vitro. Surprisingly, we found mutations in the primase domain that had a dramatic effect on the helicase. Substitution of a residue conserved in other DnaG-like enzymes, R84A, abrogates both primase and helicase enzymatic activities of the T7 primase-helicase. Alterations in this residue also decrease binding of the primase-helicase to ssDNA. However, mass photometry measurements show that these mutations do not interfere with the ability of the protein to form the active hexamer.     

Recognition of damaged regions in DNA by oligopeptides and proteins

The binding of various damaged DNAs to the single-strand binding protein coded for by gene 32 from bacteriophage T4, on the one hand, and of oligopeptides containing tryptophan and lysine residues, on the other hand, is described. These molecules exhibit a higher affinity for modified DNA than for native DNA in so far as modification results in a local destabilization of the double-stranded structure of the nucleic acid. Stacking interactions between aromatic amino acids and nucleic acid bases appear to play a crucial role in the recognition of destabilized regions induced by chemical agents (carcinogens and antitumor drugs). These interactions confer to the peptide lysyl-tryptophyl-lysine an endonucleolytic activity specific for apurinic sites. From results obtained with such oligopeptides a model for the active sites of Ap-endonucleases is proposed which could account for the strategy used by the denV endonuclease from phage T4 during the first step of excision repair of pyrimidine dimers in DNA. The effect of the overall conformation of modified DNA on repair efficiency is discussed.     

Detection of single DNA molecules by multicolor quantum-dot end-labeling

Observation of DNA–protein interactions by single molecule fluorescence microscopy is usually performed by using fluorescent DNA binding agents. However, such dyes have been shown to induce cleavage of the DNA molecule and perturb its interactions with proteins. A new method for the detection of surface-attached DNA molecules by fluorescence microscopy is introduced in this paper. Biotin- and/or digoxigenin-modified DNA fragments are covalently linked at both extremities of a DNA molecule via sequence-specific hybridization and ligation. After the modified DNA molecules have been stretched on a glass surface, their ends are visualized by multicolor fluorescence microscopy using conjugated quantum dots (QD). We demonstrate that under carefully selected conditions, the position and orientation of individual DNA molecules can be inferred with good efficiency from the QD fluorescence signals alone. This is achieved by selecting QD pairs that have the distance and direction expected for the combed DNA molecules. Direct observation of single DNA molecules in the absence of DNA staining agent opens new possibilities in the fundamental study of DNA–protein interactions. This work also documents new possibilities regarding the use of QD for nucleic acid detection and analysis.