Binding and reversible denaturation of double-stranded DNA by Ff gene 5 protein

The gene 5 protein (g5p) from Ff filamentous virus is a model single-stranded DNA (ssDNA) binding protein that has an oligonucleotide/oligosaccharide binding (OB)-fold structure and binding properties in common with other ssDNA-binding proteins. In the present work, we use circular dichroism (CD) spectroscopy to analyze the effects of amino acid substitutions on the binding of g5p to double-stranded DNA (dsDNA) compared to its binding to ssDNA. CD titrations of poly[d(A). d(T)] with mutants of each of the five tyrosines of the g5p showed that the 229-nm CD band of Tyr34, a tyrosine at the interface of adjacent protein dimers, is reversed in sign upon binding to the dsDNA, poly[d(A). d(T)]. This effect is like that previously found for g5p binding to ssDNAs, suggesting there are similarities in the protein-protein interactions when g5p binds to dsDNA and ssDNA. However, there are differences, and the possible perturbation of a second tyrosine, Tyr41, in the complex with dsDNA. Three mutant proteins (Y26F, Y34F, and Y41H) reduced the melting temperature of poly[d(A). d(T)] by 67 degrees C, but the wild-type g5p only reduced it by 2 degrees C. This enhanced ability of the mutants to denature dsDNA suggests that their binding affinities to dsDNA are reduced more than are their binding affinities to ssDNA. Finally, we present evidence that when poly[d(A). d(T)] is melted in the presence of the wild-type, Y26F, or Y34F proteins, the poly[d(A)] and poly[d(T)] strands are separately sequestered such that renaturation of the duplex is facilitated in 2 mM Na(+).     

DNA microarrays with unimolecular hairpin double-stranded DNA probes: fabrication and exploration of sequence-specific DNA/protein interactions

We have fabricated double-stranded DNA (dsDNA) microarrays containing unimolecular hairpin dsDNA probes immobilized on glass slides. The unimolecular hairpin dsDNA microarrays were manufactured by four steps: Firstly, synthesizing single-stranded DNA (ssDNA) oligonucleotides with two reverse-complementary sequences at 3' hydroxyl end and an overhang sequence at 5' amino end. Secondly, microspotting ssDNA on glutaraldehyde-derived glass slide to form ssDNA microarrays. Thirdly, annealing two reverse-complementary sequences to form hairpin primer at 3' end of immobilized ssDNA and thus to create partial-dsDNA microarray. Fourthly, enzymatically extending hairpin primer to convert partial-dsDNA microarrays into complete-dsDNA microarray. The excellent efficiency and high accuracy of the enzymatic synthesis were demonstrated by incorporation of fluorescently labeled dUTPs in Klenow extension and digestion of dsDNA microarrays with restriction endonuclease. The accessibility and specificity of the DNA-binding proteins binding to dsDNA microarrays were verified by binding Cy3-labeled NF-kappaB to dsDNA microarrays. The dsDNA microarrays have great potential to provide a high-throughput platform for investigation of sequence-specific DNA/protein interactions involved in gene expression regulation, restriction and so on.     

A cold-regulated nucleic acid-binding protein of winter wheat shares a domain with bacterial cold shock proteins

The molecular mechanisms of cold acclimation are still largely unknown; however, it has been established that overwintering plants such as winter wheat increases freeze tolerance during cold treatments. In prokaryotes, cold shock proteins are induced by temperature downshifts and have been proposed to function as RNA chaperones. A wheat cDNA encoding a putative nucleic acid-binding protein, WCSP1, was isolated and found to be homologous to the predominant CspA of Escherichia coli. The putative WCSP1 protein contains a three-domain structure consisting of an N-terminal cold shock domain with two internal conserved consensus RNA binding domains and an internal glycine-rich region, which is interspersed with three C-terminal CX(2)CX(4)HX(4)C (CCHC) zinc fingers. Each domain has been described independently within several nucleotide-binding proteins. Northern and Western blot analyses showed that WCSP1 mRNA and protein levels steadily increased during cold acclimation, respectively. WCSP1 induction was cold-specific because neither abscisic acid treatment, drought, salinity, nor heat stress induced WCSP1 expression. Nucleotide binding assays determined that WCSP1 binds ssDNA, dsDNA, and RNA homopolymers. The capacity to bind dsDNA was nearly eliminated in a mutant protein lacking C-terminal zinc fingers. Structural and expression similarities to E. coli CspA suggest that WCSP1 may be involved in gene regulation during cold acclimation.     

Classification and purification of proteins of heterogeneous nuclear ribonucleoprotein particles by RNA-binding specificities.

Several proteins of heterogeneous nuclear ribonucleoprotein (hnRNP) particles display very high binding affinities for different ribonucleotide homopolymers. The specificity of some of these proteins at high salt concentrations and in the presence of heparin allows for their rapid one-step purification from HeLa nucleoplasm. We show that the hnRNP C proteins are poly(U)-binding proteins and compare their specificity to that of the previously described cytoplasmic poly(A)-binding protein. These findings provide a useful tool for the classification and purification of hnRNP proteins from various tissues and organisms and indicate that different hnRNP proteins have different RNA-binding specificities.     

Kinetics and thermodynamics of salt-dependent T7 gene 2.5 protein binding to single- and double-stranded DNA

Bacteriophage T7 gene 2.5 protein (gp2.5) is a single-stranded DNA (ssDNA)-binding protein that has essential roles in DNA replication, recombination and repair. However, it differs from other ssDNA-binding proteins by its weaker binding to ssDNA and lack of cooperative ssDNA binding. By studying the rate-dependent DNA melting force in the presence of gp2.5 and its deletion mutant lacking 26 C-terminal residues, we probe the kinetics and thermodynamics of gp2.5 binding to ssDNA and double-stranded DNA (dsDNA). These force measurements allow us to determine the binding rate of both proteins to ssDNA, as well as their equilibrium association constants to dsDNA. The salt dependence of dsDNA binding parallels that of ssDNA binding. We attribute the four orders of magnitude salt-independent differences between ssDNA and dsDNA binding to nonelectrostatic interactions involved only in ssDNA binding, in contrast to T4 gene 32 protein, which achieves preferential ssDNA binding primarily through cooperative interactions. The results support a model in which dimerization interactions must be broken for DNA binding, and gp2.5 monomers search dsDNA by 1D diffusion to bind ssDNA. We also quantitatively compare the salt-dependent ssDNA- and dsDNA-binding properties of the T4 and T7 ssDNA-binding proteins for the first time.     

A rapid and sensitive method for studying the binding of ribonucleotide polymers to mammalian ribosomal subunits.

A sensitive and rapid method has been developed for studying the interactions of ribonucleotide homopolymers with isolated liver ribosomal subunits. Small amounts of ribosomal subunits are first immobilised on Millipore filters. The homopolymers are then allowed to interact with the ribosomes by slow passage through the filters. Conditions are described under which both the large and the small subunits can bind poly(A) and poly(U) as well as poly(G). The poly(A) and poly(G) binding sites can be shown to be different.     

cDNA cloning and sequencing of tobacco chloroplast ribosomal protein L12

Tobacco chloroplast ribosomal protein L12 was isolated as a ssDNA-cellulose-binding protein from a chloroplast soluble protein fraction. Based on the N-terminal amino acid sequence of chloroplast L12, a cDNA clone was isolated and characterized. The precursor protein deduced from the DNA sequence consists of a transit peptide of 53 amino acid residues and a mature L12 protein of 133 amino acid residues. The chloroplast L12 protein was synthesized with a reticulocyte lysate and subjected to nucleic acid-binding assays. L12 synthesized in vitro does not bind to ssDNA, dsDNA nor ribonucleotide homopolymers, but it binds to cellulose matrix.     

Mechanical measurement of single-molecule binding rates: kinetics of DNA helix-destabilization by T4 gene 32 protein

Bacteriophage T4 gene 32 protein (gp32) is a single-stranded DNA (ssDNA) binding protein, and is essential for DNA replication, recombination and repair. While gp32 binds preferentially and cooperatively to ssDNA, it has not been observed to lower the thermal melting temperature of natural double-stranded DNA (dsDNA). However, in single-molecule stretching experiments, gp32 significantly destabilizes lambda DNA. In this study, we develop a theory of the effect of the protein on single dsDNA stretching curves, and apply it to the measured dependence of the DNA overstretching force on pulling rate in the presence of the full-length and two truncated forms of the protein. This allows us to calculate the rate of cooperative growth of single clusters of protein along ssDNA that are formed as the dsDNA molecule is stretched, as well as determine the site size of the protein binding to ssDNA. The rate of cooperative binding (ka) of both gp32 and of its proteolytic fragment *I (which lacks 48 residues from the C terminus) varies non-linearly with protein concentration, and appears to exceed the diffusion limit. We develop a model of protein association with the ends of growing clusters of cooperatively bound protein enhanced by 1-D diffusion along dsDNA, under the condition of protein excess. Upon globally fitting ka versus protein concentration, we determine the binding site size and the non-cooperative binding constants to dsDNA for gp32 and I. Our experiment mimics the growth of clusters of gp32 that likely exist at the DNA replication fork in vivo, and explains the origin of the "kinetic block" to dsDNA melting by gene 32 protein observed in thermal melting experiments.     

Identification of an RNA binding region within the N-terminal third of the influenza A virus nucleoprotein.

The influenza A virus nucleoprotein (NP) has been examined with regard to its RNA-binding characteristics. NP, purified from virions and devoid of RNA, bound synthetic RNAs in vitro and interacted with the ribonucleotide homopolymers poly(A), poly(G), poly(U), and poly(C) in a salt-dependent manner, showing higher binding affinity for polypyrimidine homopolymers. To map the NP regions involved in RNA binding, a series of deleted forms of the NP were prepared, and these truncated polypeptides were tested for their ability to bind poly(U) and poly(C) homopolymers linked to agarose beads. Proteins containing deletions at the N terminus of the NP molecule showed reduced RNA-binding activity, indicating that this part of the protein was required to bind RNA. To identify the NP region or regions which directly interact with RNA, proteins having the maltose-binding protein fused with various NP fragments were obtained and tested for binding to radioactively labeled RNAs in three different assays: (i) nitrocellulose filter binding assays, (ii) gel shift assays, and (iii) UV light-induced cross-linking experiments. A maltose-binding protein fusion containing the N-terminal 180 amino acids of NP behaved as an RNA-binding protein in the three assays, demonstrating that the N terminus of NP can directly interact with RNA. This NP region could be further subdivided into two smaller regions (amino acids 1 to 77 and 79 to 180) that also retained RNA-binding activity.     

Binding of SSB-protein from Ehrlich ascites carcinoma cells with DNA and polyribonucleotides]

Binding of SSB-protein from Ehrlich ascites tumor to ssDNA from M13 phage leads to its compactization. The structure of the complex at the protein/DNA ratios far from the saturation level looks like "beads-on the string". DNA that was fully saturated with protein forms collapsed globular structure. Binding of the protein to the dsDNA from phage lambda increases its flexibility and decreases the coil dimensions; no "beads-on the string" structure are seen. The protein possess slight destabilizing effect on hairpin helices of M13DNA. Competition studies demonstrate that the binding properties of protein with polyribonucleotide lattices and DNA's decrease in ranking as follows: poly(rG) greater than or equal to poly(rI) greater than or equal to ssDNA greater than dsDNA greater than poly(rA) congruent to approximately poly(rU). Thus SSB-protein from Ehrlich ascites tumor differs significantly from its presumed prokaryotic analogs.     

AAV-ITR单链DNA微载体在小鼠骨骼肌中的表达

AAV-ITR单链DNA微载体是一种基于腺相关病毒(AAV)倒置末端重复序列(ITR)的基因表达载体(AAV-ITR ss DNA mini vector)。前期研究已证明AAV-ITR单链DNA微载体在HEK 293T细胞中具有较高的转染、表达效率。本文中将相同拷贝数的AAV-ITR单链DNA微载体、3?-ITR末端错配的AAV-ITR单链DNA微载体(AAV-ITRmm ss DNA mutant vector)、AAV-ITR双链DNA和质粒分别用Turbo Fect转入小鼠骨骼肌中,比较检测AAV-ITR单链DNA微载体与其他基因表达载体在小鼠体内1周、1个月及3个月的表达效率。组织切片经荧光显微镜观察及荧光灰度值分析表明,相同分子摩尔数的AAV-ITR单链DNA微载体比AAV-ITR双链DNA和质粒在不同时期表达效率都要高且更稳定。提取注射3个月后的肌肉组织的DNA,用荧光定量PCR分析比较各载体的存留分子数。RT-PCR的结果显示AAV-ITR单链DNA微载体在注射3个月后的存留分子数较其他载体高。综合结果显示AAV-ITR单链DNA微载体在动物体内具有表达效率高和长久稳定的优势,有可能开发为基因治疗的一种高效、稳定的新型载体。     

Investigations on DNA intercalation and surface binding by SYBR Green I, its structure determination and methodological implications

The detection of double-stranded (ds) DNA by SYBR Green I (SG) is important in many molecular biology methods including gel electrophoresis, dsDNA quantification in solution and real-time PCR. Biophysical studies at defined dye/base pair ratios (dbprs) were used to determine the structure–property relationships that affect methods applying SG. These studies revealed the occurrence of intercalation, followed by surface binding at dbprs above ~0.15. Only the latter led to a significant increase in fluorescence. Studies with poly(dA) · poly(dT) and poly(dG) · poly(dC) homopolymers showed sequence-specific binding of SG. Also, salts had a marked impact on SG fluorescence. We also noted binding of SG to single-stranded (ss) DNA, although SG/ssDNA fluorescence was at least ~11-fold lower than with dsDNA. To perform these studies, we determined the structure of SG by mass spectrometry and NMR analysis to be [2-[N-(3-dimethylaminopropyl)-N-propylamino]-4-[2,3-dihydro-3-methyl-(benzo-1,3-thiazol-2-yl)-methylidene]-1-phenyl-quinolinium]. For comparison, the structure of PicoGreen (PG) was also determined and is [2-[N-bis-(3-dimethylaminopropyl)-amino]-4-[2,3-dihydro-3-methyl-(benzo-1,3-thiazol-2-yl)-methylidene]-1-phenyl-quinolinium]⁺. These structure–property relationships help in the design of methods that use SG, in particular dsDNA quantification in solution and real-time PCR.     

The uvsX protein of bacteriophage T4 arranges single-stranded and double-stranded DNA into similar helical nucleoprotein filaments

The bacteriophage T4 uvsX gene codes for a DNA-binding protein that is important for genetic recombination in T4-infected cells. This protein is a DNA-dependent ATPase that resembles the Escherichia coli recA protein in many of its properties. We have examined the binding of purified uvsX protein to single-stranded DNA (ssDNA) and to double-stranded DNA (dsDNA) using electron microscopy to visualize the complexes that are formed and double label analysis to measure their protein content. We find that the uvsX protein binds cooperatively to dsDNA, forming filaments 14 nm in diameter with an apparently helical axial repeat of 12 nm. Each repeat contains about 42 base pairs and 9-12 uvsX protein monomers. In solutions containing Mg2+, the uvsX protein also binds cooperatively to ssDNA. The filaments that result are 14 nm in diameter, show a 12-nm axial repeat, and they are nearly identical in appearance to the filaments that contain dsDNA. In the filaments formed along ssDNA, each axial repeat contains about 49 DNA bases and 9-12 uvsX monomers. Both the filaments formed on the ssDNA and dsDNA show a strong tendency to align side-by-side. T4 gene 32 protein also binds cooperatively to ssDNA and interacts both physically and functionally with uvsX protein. However, when gene 32 and uvsX proteins were added to ssDNA together, no interaction between the two proteins was detected.     

The location of binding sites on C1q for DNA

Previous studies have suggested that C1q reacts with DNA via both the globular region of C1q (GR) and the collagen-like region of C1q (CLR). In this study, the binding of dsDNA and ssDNA to GR and CLR was quantitated by a solid-phase assay. Both dsDNA and ssDNA bound to the GR and CLR of C1q in an ionic strength-dependent manner. Under physiologic salt concentrations, however, dsDNA and ssDNA bound preferentially to CLR and not to GR. The binding of dsDNA to C1q was not affected by heat inactivation of C1q or its exposure to pH 4.45, which abolished the binding of heat-aggregated human IgG (AHG) with C1q. The preincubation of the solid-phase C1q with AHG did not decrease the binding of dsDNA or ssDNA to the solid-phase C1q. These results indicate that the major sites for binding DNA to C1q are located in the CLR of C1q and are not overlapping with those for AHG or immune complexes.     

Characterization of thermostable RecA protein and analysis of its interaction with single-stranded DNA.

Thermostable RecA protein (ttRecA) from Thermus thermophilus HB8 showed strand exchange activity at 65 degrees C but not at 37 degrees C, although nucleoprotein complex was observed at both temperatures. ttRecA showed single-stranded DNA (ssDNA)-dependent ATPase activity, and its activity was maximal at 65 degrees C. The kinetic parameters, K(m) and kcat, for adenosine triphosphate (ATP) hydrolysis with poly(dT) were 1.4 mM and 0.60 s-1 at 65 degrees C, and 0.34 mM and 0.28 s-1 at 37 degrees C, respectively. Substrate cooperativity was observed at both temperatures, and the Hill coefficient was about 2. At 65 degrees C, all tested ssDNAs were able to stimulate the ATPase activity. The order of ATPase stimulation was: poly(dC) > poly(dT) > M13 ssDNA > poly(dA). Double-stranded DNAs (dsDNA), poly(dT).poly(dA) and M13 dsDNA, were unable to activate the enzyme at 65 degrees C. At 37 degrees C, however, not only dsDNAs but also poly(dA) and M13 ssDNA showed poor stimulating ability. At 25 degrees C, poly(dA) and M13 ssDNA gave circular dichroism (CD) peaks at around 192 nm, which reflect a particular structure of DNA. The conformation was changed by an upshift of temperature or binding to Escherichia coli RecA protein (ecRecA), but not to ttRecA. The dissociation constant between ecRecA and poly(dA) was estimated to be 44 microM at 25 degrees C by the change in the CD. These observations suggest that the capability to modify the conformation of ssDNA may be different between ttRecA and ecRecA. The specific structure of ssDNA was altered by heat or binding of ecRecA. After this alteration, ttRecA and ecRecA can express their activities at each physiological temperature.     

A Phage Single-Stranded DNA (ssDNA) Binding Protein Complements ssDNA Accumulation of a Geminivirus and Interferes with Viral Movement

Geminiviruses are plant viruses with circular single-stranded DNA (ssDNA) genomes encapsidated in double icosahedral particles. Tomato leaf curl geminivirus (ToLCV) requires coat protein (CP) for the accumulation of ssDNA in protoplasts and in plants but not for systemic infection and symptom development in plants. In the absence of CP, infected protoplasts accumulate reduced levels of ssDNA and increased amounts of double-stranded DNA (dsDNA), compared to accumulation in the presence of wild-type virus. To determine whether the gene 5 protein (g5p), a ssDNA binding protein from Escherichia coli phage M13, could restore the accumulation of ssDNA, ToLCV that lacked the CP gene was modified to express g5p or g5p fused to the N-terminal 66 amino acids of CP (CP66:6G:g5). The modified viruses led to the accumulation of wild-type levels of ssDNA and high levels of dsDNA. The accumulation of ssDNA was apparently due to stable binding of g5p to viral ssDNA. The high levels of dsDNA accumulation during infections with the modified viruses suggested a direct role for CP in viral DNA replication. ToLCV that produced the CP66:6G:g5 protein did not spread efficiently in Nicotiana benthamiana plants, and inoculated plants developed only very mild symptoms. In infected protoplasts, the CP66:6G:g5 protein was immunolocalized to nuclei. We propose that the fusion protein interferes with the function of the BV1 movement protein and thereby prevents spread of the infection.     

Replication protein A interactions with DNA. 2. Characterization of double-stranded DNA-binding/helix-destabilization activities and the role of the zinc-finger domain in DNA interactions

Human replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein that is composed of subunits of 70, 32, and 14 kDa. RPA is required for multiple processes in cellular DNA metabolism. RPA has been reported to (1) bind with high affinity to single-stranded DNA (ssDNA), (2) bind specifically to certain double-stranded DNA (dsDNA) sequences, and (3) have DNA helix-destabilizing ("unwinding") activity. We have characterized both dsDNA binding and helix destabilization. The affinity of RPA for dsDNA was lower than that of ssDNA and precisely correlated with the melting temperature of the DNA fragment. The rates of helix destabilization and dsDNA binding were similar, and both were slow relative to the rate of binding ssDNA. We have previously mapped the regions required for ssDNA binding [Walther et al. (1999) Biochemistry 38, 3963-3973]. Here, we show that both helix-destabilization and dsDNA-binding activities map to the central DNA-binding domain of the 70-kDa subunit and that other domains of RPA are needed for optimal activity. We conclude that all types of RPA binding are manifestations of RPA ssDNA-binding activity and that dsDNA binding occurs when RPA destabilizes a region of dsDNA and binds to the resulting ssDNA. The 70-kDa subunit of all RPA homologues contains a highly conserved putative (C-X2-C-X13-C-X2-C) zinc finger. This motif directly interacts with DNA and contributes to dsDNA-binding/unwinding activity. Evidence is presented that a metal ion is required for the function of the zinc-finger motif.