Labelling of histone H5 and its interaction with DNA. 2. Cooperative binding of histone H5 to DNA as probed by steady-state fluorescence and diffusion-enhanced energy transfer

The interaction of histone H5 labelled with fluorescein isothiocyanate (FITC) with DNA has been studied by fluorescence titration, and diffusion-enhanced fluorescence energy transfer (DEFET) measurements with Tb(III) lanthanide chelates as donors. Analysis of the binding data by the model of Schwarz and Watanabe (J.Mol.Biol. 163, 467-484 (1983)) yielded a mean stoichiometry of 60 nucleotides per H5 molecule, independently of ionic strength, in the range of 3 to 300 mM NaCl, at very low DNA concentration (6 microM in mononucleotide). It ensues an approximate electroneutrality of the saturated complexes. Histone H5 molecules appeared to be clustered along the DNA lattice in clusters containing on average 3 to 4 H5 molecules separated by about 79 base pairs, at mid-saturation of the binding sites. The interaction process was found highly cooperative but the cooperativity parameter was also insensitive to ionic strength in the above range. DEFET experiments indicated an important decrease of accessibility of the FITC label to the TbHED3A and TbEDTA- chelates with ionic strength in the 0 to 100 mM NaCl range. In the presence of DNA, H5 appears already folded at low ionic strength so that the FITC probe is also not accessible to the donor chelate. The present study constitutes an indispensable preliminary step to further studies on the localization of histone H5 in condensed chromatin structures.     

Index to Subjects,Volume 5

Abstract

The interaction of histone H5 labelled with fluorescein isothiocyanate (FITC) with DNA has been studied by fluorescence titration, and diffusion-enhanced fluorescence energy transfer (DEFET) measurements with Tb(III) lanthanide chelates as donors.

Analysis of the binding data by the model of Schwarz and Watanabe (J. Mol. Biol. 163, 467-484 (1983)) yielded a mean stoichiometry of 60 nucleotides per H5 molecule, independently of ionic strength, in the range of 3 to 300 mM NaCl, at very low DNA concentration (6 μM in mononucleotide). It ensues an approximate electroneutrality of the saturated complexes. Histone H5 molecules appeared to be clustered along the DNA lattice in clusters containing on average 3 to 4 H5 molecules separated by about 79 base pairs, at mid-saturation of the binding sites. The interaction process was found highly cooperative but the cooperativity parameter was also insensitive to ionic strength in the above range.

DEFET experiments indicated an important decrease of accessibility of the FITC label to the TbHED3A° and TbEDTA^? chelates with ionic strength in the 0 to 100 mM NaCl range. In the presence of DNA, H5 appears already folded at low ionic strength so that the FITC probe is also not accessible to the donor chelate. The present study constitutes an indispensable preliminary step to further studies on the localization of histone H5 in condensed chromatin structures.     

Deoxyribonucleic acid polymerase III of Escherichia coli. Characterization of associated exonuclease activities.

Purified DNA polymerase III has two distinct exonuclease activities: one initiates hydrolsis at the 3 termini, and the other at the 5 termini of single-stranded DNA. Both exonucleases have the same relative mobility on polyacrylamide gels as the polymerase activity. Molecular identity of the three activities is further indicated by their comparative rates of thermal inactivation and their sensitivity to ionic strength. The 3-5 exonuclease activity hydrolyzes only single-standed DNA. The rate of hydrolysis is twice the optimal rate of polymerization. The products are 5-mononucleotides, but the 3-5 activity is unable to cleave free dinucleotides or the 5-terminal dinucleotide of a polydeoxynucleotide chain. The 3-5 activity will not degrade 3-phosphoryl-terminated oligonucleotides such as d(pTpTpTp). The 5-3 activity catalyzes the hydrolysis of single-stranded DNA at 1/15 the rate of the 3-5 exonuclease. The 5-3 exonuclease requires the presence of a 5 single-stranded terminus in order to initiate hydrolysis, but will thereafter proceed into a double-stranded region. Although the limit products found during hydrolysis of substrates designed to assay specifically the 5-3 activity are predominantly mono- and dinucleotides, these products probably arise from the subsequent hydrolysis of oligonucleotides by the 3-5 hydrolytic activity. This interpretation is supported by (a) the relatively greater activity of the 3-5 exonuclease, (b) the inability of the enzyme to degrade d(pTpTpTp), and (c) the release of the 5 terminus of a single-stranded DNA molecule as an oligonucleotide. The 5-3 exonuclease attacks ultraviolet-irradiated duplex DNA which has first been incised by the Micrococcus luteus endonuclease specific for thymine dimers in DNA.     

Escherichia coli thioredoxin confers processivity on the DNA polymerase activity of the gene 5 protein of bacteriophage T7

Bacteriophage T7 gene 5 protein has been purified to apparent homogeneity from cells overexpressing its gene several hundred-fold. Gene 5 protein is a DNA polymerase with low processivity; it dissociates from the primer-template after catalyzing the incorporation of 1-50 nucleotides, depending on the salt concentration. Escherichia coli thioredoxin, a host protein that is tightly associated with the gene 5 protein in phage-infected cells, is not required for this activity. Thioredoxin acts as an accessory protein to bestow processivity on the polymerizing reaction; DNA synthesis catalyzed by the gene 5 protein-thioredoxin complex on a single-stranded DNA template can polymerize thousands of nucleotides without dissociation. Conditions that increase the stability of secondary structures in the template (i.e., low temperature or high ionic strength) decrease the processivity. E. coli single-stranded DNA-binding protein stimulates both the rate of elongation and the processivity of the gene 5 protein-thioredoxin complex.     

Complex of bacteriophage M13 single-stranded DNA and gene 5 protein

Lysates of bacteriophage M13-infected cells contain numerous unbranched filamentous structures approximately 1·1 μm long × 160 Å wide, that is, slightly longer and considerably wider than M13 virions. These structures are complexes of viral single-stranded DNA molecules with M13 gene 5 protein, a non-capsid protein required for single-stranded DNA production. All, or nearly all, of the single-stranded DNA from the infected cells and at least half to two-thirds of the gene 5 protein molecules are found as complex in the lysates. The complex contains about 1300 gene 5 protein molecules per DNA molecule but little if any of the two known capsid proteins. The complex is much less stable than virions in the presence of salt or ionic detergent solutions and in electron micrographs it appears to have a much looser and more open structure. If an excess of M13 single-stranded DNA is added to complex in a lysate, the gene 5 protein molecules from the complex redistribute onto all of the added as well as the original DNA, again suggesting a rather loose association of protein and DNA.By electron microscopy, the complex from infected cells appears to differ structurally from complex formed in vitro between purified single-stranded DNA and purified gene 5 protein. Because of this apparent structural difference and because previous experiments suggested the presence of complex in vivo, we presume that the complex which we have found in lysates of infected cells previously did exist as such inside the cells, but we have been unable to exclude that it formed during or after lysis. If it is assumed that complex does occur in vivo, the results of pulse-chase radioactive labeling experiments on infected cells can be interpreted as showing that with time the single-stranded DNA leaves complex, presumably to be matured into virions, while the gene 5 protein molecules are re-used to form more complex.     

Adsorption of single-stranded and double-helical polynucleotides on the mercury electrode

The adsorption of single-stranded polynucleotides and double-helical DNA on the dropping mercury electrode has been studied with the aid of Breyer's alternating current (a.c.) polarography. Our results indicate that all three constituents of polynucleotides (residues of bases, sugar, and phosphoric acid) are involved in the adsorption. At neutral pH their participation in adsorption depends on the ionic strength, the potential of the electrode, and the conformation of the polynucleotide in the solution. At an ionic strength of about 0.1, double-helical DNA is adsorbed electrostatically on a positively charged electrode surface by inadequately masked negative charges of the phosphate groups. At a higher ionic srength (about 0.5), this electrostatic adsorption is no longer detectable by using a.c. polarography; under these conditions it is probable that native DNA is adsorbed around the potential of the electrocapillary maximum with the aid of sugar residues and a few bases. Single-stranded polynucleotides, on the other hand, are primarily adsorbed by means of the bases. Desorption of double-helical DNA occurs around a potential of ?1.2 V against SCE. At this potential, the helical regions of single-stranded polynucleotides are also desorbed. Desorption of the disordered regions of single-stranded polynucleotides occurs at more negative potentials. Adsorption and desorption of a small number of bases released from double-helical DNA was evident in the a.c. polarograms only at elevated temperature, or at room temperature after degradation of DNA by sonication.     

Force spectroscopy of single DNA and RNA molecules

Experiments in which single molecules of RNA and DNA are stretched, and the resulting force as a function of extension is measured have yielded new information about the physical, chemical and biological properties of these important molecules. The behavior of both single-stranded and double-stranded nucleic acids under changing solution conditions, such as ionic strength, pH and temperature, has been studied in detail. There has also been progress in using these techniques to study both the kinetics and equilibrium thermodynamics of DNA-protein interactions. These studies generate unique insights into the functions of these proteins in the cell.     

Single molecule DNA sequencing in submicrometer channels: state of the art and future prospects

We demonstrate a new method for single molecule DNA sequencing which is based upon detection and identification of single fluorescently labeled mononucleotide molecules degraded from DNA-strands in a cone shaped microcapillary with an inner diameter of 0.5 microm. The DNA was attached at an optical fiber via streptavidin/biotin binding and placed approximately 50 microm in front of the detection area inside of the microcapillary. The 5'-biotinylated 218-mer model DNA sequence used in the experiments contained 6 fluorescently labeled cytosine and uridine residues, respectively, at well defined positions. The negatively charged mononucleotide molecules were released by addition of exonuclease I and moved towards the detection area by electrokinetic forces. Adsorption of mononucleotide molecules onto the capillary walls as well as the electroosmotic (EOF) flow was prevented by the use of a 3% polyvinyl pyrrolidone (PVP) matrix containing 0.1% Tween 20. For efficient excitation of the labeled mononucleotide molecules a short-pulse diode laser emitting at 638 nm with a repetition rate of 57 MHz was applied. We report on experiments where single-stranded model DNA molecules each containing 6 fluorescently labeled dCTP and dUTP residues were attached at the tip of a fiber, transferred into the microcapillary and degraded by addition of exonuclease I solution. In one experiment, the exonucleolytic cleavage of 5-6 model DNA molecules was observed. 86 photon bursts were detected (43 Cy5-dCMP and 43 MR121-dUMP) during 400 s and identified due to the characteristic fluorescence decay time of the labels of 1.43+/-0.19 ns (Cy5-dCMP), and 2.35+/-0.29 ns (MR121-dUMP). The cleavage rate of exonuclease I on single-stranded labeled DNA molecules was determined to 3-24 Hz under the applied experimental conditions. In addition, the observed burst count rate (signals/s) indicates nonprocessive behavior of exonuclease I on single-stranded labeled DNA.     

Thermodynamic analysis of monoclonal antibody binding to duplex DNA.

A technique based on fluorescence polarization (anisotropy) was used to measure the binding of antibodies to DNA under a variety of conditions. Fluorescein-labeled duplexes of 20 bp in length were employed as the standard because they are stable even at low ionic strength yet sufficiently short so that both arms of an IgG cannot bind to the same duplex. IgG Jel 274 binds duplexes in preference to single-stranded DNA; in 80 mM NaCl Kobs for (dG)20.(dC)20 is 4.1x10(7) M-1 compared with 6.4x10(5) M-1 for d(A5C10A5). There is little sequence specificity, but the interaction is very dependent on ionic strength. From plots of log Kobs against log[Na+] it was deduced that five or six ion pairs are involved in complex formation. At low ionic strength,Kobs is independent of temperature and complex formation is entropy driven with DeltaH degrees obs and DeltaC degrees p,obs both zero. In contrast, in 80 mM NaCl DeltaC degrees p,obs is -630 and -580 cal mol-1K-1 for [d(TG)]10.[d(CA)]10 and (dG)20.(dC)20 respectively. IgG Jel 241 also binds more tightly to duplexes than single-stranded DNA, but sequence preferences were apparent. The values for Kobs to [d(AT)]20 and [d(GC)]20 are 2.7x10(8) and 1.3x10(8) M-1 respectively compared with 5.7x10(6) M-1 for both (dA)20. (dT)20 and (dG)20.(dC)20. As with Jel 274, the binding of Jel 241 is very dependent on ionic strength and four or five ionic bonds are involved in complex formation with all the duplex DNAs which were tested. DeltaC degrees p,obs for Jel 241 binding to [d(AT)]20 was negative (-87 cal mol-1K-1) in 80 mM NaCl but was zero at high ionic strength (130 mM NaCl). Therefore, for duplex-specific DNA binding antibodies DeltaC degrees p,obs is dependent on [Na+] and a large negative value does not correlate with sequence-specific interactions.     

Nonhistone chromosomal protein HMG 1 interactions with DNA. Fluorescence and thermal denaturation studies

The interaction of high mobility group protein 1 (HMG 1) isolated from chicken erythrocytes with DNA has been characterized using the intrinsic tryptophan fluorescence of the protein as a probe. It was found that the fluorescence is quenched approximately 30% upon binding to either single- or double-stranded DNA. Fluorescent titrations indicate that the physical site size for HMG 1 binding on native DNA is approximately 14 base pairs (or 14 bases for binding to single-stranded DNA). Binding to single-stranded poly(dA) is only slightly dependent on ionic strength, although the affinity for double-stranded DNA is strongly ionic strength-dependent and has an optimum at approximately 100-120 mM Na+. Above this range, binding to native DNA is virtually all electrostatic in nature. Although the affinity of HMG 1 for single-stranded DNA is higher than that for double-stranded DNA at the extremes of the ionic range studied, no clear evidence for a helix-destabilizing activity was obtained. At low ionic strength, the protein actually stabilized DNA against thermal denaturation, while at high ionic strength, HMG 1 appears to undergo denaturation below the Tm of the DNA. Studies of the environment of the tryptophan fluorophores using collisional quenchers iodide, cesium, and acrylamide suggest that the predominant fluorophore is relatively exposed but constrained in a rigid, positively charged environment.     

Absorption and fluorescence studies of the binding of the recA gene product from E. coli to single-stranded and double-stranded DNA. Ionic strength dependence

The binding of the recA gene product from E. coli to double-stranded and single-stranded nucleic acids has been investigated by following the change in melting temperature of duplex DNA and the fluorescence of single-stranded DNA or poly(dA) modified by reaction with chloroacetaldehyde. At low ionic strength, in the absence of Mg2+ ions, RecA protein binds preferentially to duplex DNA or poly(dA-dT). This leads to an increase of the DNA melting temperature. Stabilization of duplex DNA decreases when ionic strength or pH increases. In the presence of Mg2+ ions, preferential binding to single-stranded polynucleotides is observed. Precipitation occurs when duplex DNA begins to melt in the presence of RecA protein. From competition experiments, different single-stranded and double-stranded polydeoxynucleotides can be ranked according to their ability to bind RecA protein. Structural changes induced in nucleic acids upon RecA binding are discussed together with conformational changes induced in RecA protein upon magnesium binding.     

DNA Strands Attached Inside Single Conical Nanopores: Ionic Pore Characteristics and Insight into DNA Biophysics

Single nanopores attract a great deal of scientific interest as a basis for biosensors and as a system to study the interactions and behavior of molecules in a confined volume. Tuning the geometry and surface chemistry of nanopores helps create devices that control transport of ions and molecules in solution. Here, we present single conically shaped nanopores whose narrow opening of 8 or 12 nm is modified with single-stranded DNA molecules. We find that the DNA occludes the narrow opening of nanopores and that the blockade extent decreases with the ionic strength of the background electrolyte. The results are explained by the ionic strength dependence of the persistence length of DNA. At low KCl concentrations (10 mM) the molecules assume an extended and rigid conformation, thereby blocking the pore lumen and reducing the flow of ionic current to a greater extent than compacted DNA at high salt concentrations. Attaching flexible polymers to the pore walls hence creates a system with tunable opening diameters in order to regulate transport of both neutral and charged species.     

Structural and enzymological characterization of a deoxyribonucleic acid dependent adenosine triphosphatase from KB cell nuclei

We have purified to near homogeneity the single DNA-dependent ATPase activity that we have identified in extracts of KB cell nuclei. The protein structure of the enzyme was defined by sodium dodecyl sulfate gel electrophoresis, which revealed a single protein band of 75000 daltons that was coincident with the profile of ATPase activity resolved by the final step of agarose-ATP chromatography or by isoelectric focusing. The enzyme has a pI of 8.5, a Stokes' radius by gel filtration of 3.8 nm, and a sedimentation coefficient in high salt of 5.3 S. At low ionic strength the enzyme activity sediments at 7.0 S, suggesting that it may dimerize under these conditions. The purified enzyme has a specific activity of 5.9 X 10(5) nmol of ATP hydrolyzed per h per mg of protein and is devoid of endonuclease, exonuclease, RNA or DNA polymerase, nicking-closing, and gyrase activities at exclusion limits of 10(-6)-10(-8) of the ATPase activity. The enzyme can hydrolyze only ATP or dATP, to generate ADP or dADP plus Pi, but the other NTPs and dNTPs are competitive inhibitors of the enzyme with respect to ATP. A divalent cation (Mg2+ greater than Mn2+ greater than Ca2+) as well as a nucleic acid cofactor is required for activity. Single-stranded DNA or deoxyhomopolymers are most effective, but blunt-ended linear and nicked circular duplex DNA molecules are also used at Vmax values approximately 20% of that obtained with single-stranded DNA. Intact duplex DNA and polyribonucleotides are unable to support ATP hydrolysis. Velocity gradient sedimentation studies corroborate the interpretations of the kinetic analyses and demonstrate enzyme binding to single-stranded DNA and nicked duplex DNA but not to intact duplex DNA. Although we have not succeeded directly in demonstrating DNA unwinding by this protein, preliminary results suggest that in the presence of ATP, the ATPase can stimulate the reactivity of homogeneous human DNA polymerases alpha and beta on nicked duplex DNA substrates.     

Electrostatic interactions of redox cations with surface-immobilized and solution DNA.

Association constants for ruthenium(III) hexaamine and cobalt(III) tris(2,2'-bipyridine) with solution and surface-immobilized DNA were determined. The interaction of the cationic redox molecules with calf thymus DNA was monitored via normal pulse voltammetry with analysis of the mass-transfer limited current assuming a discrete binding-site model. Single-stranded DNA was immobilized on gold via self-assembly of a 5' hexanethiol linker. Double-stranded surface-immobilized DNA was produced by hybridization of a complementary target to surface-immobilized single strands. The interaction between the metal complexes and surface-immobilized DNA was determined using chronocoulometry to construct adsorption isotherms. The measured binding constants for the cationic redox molecules with solution, surface-immobilized single-stranded, and double-stranded DNA are well-correlated, even as a function of ionic strength. The agreement between the determined association constants for the surface-immobilized and solution DNA indicates the potential utility of DNA-derivatized electrodes for examination of small molecule interactions with nucleic acids.     

Thermal stability of nucleosomes studied in situ by flow cytometry: effect of ionic strength and n-butyrate

Heating of cells permeabilized with ethanol and resuspended in aqueous media increases accessibility of DNA to intercalating dyes such as acridine orange (AO). The curves, representing increase in binding of AO as a function of rise in temperature, indicate that the transitions are cooperative. The transitions are sensitive to ionic strength and occur at lower temperatures when cells are suspended in media of increasing ionic strength. Extraction of histones raises accessibility of DNA to intercalators at room temperature, and heating has little effect on additional binding. The results are interpreted as indicating thermal destruction of nucleosomal structure in nuclear chromatin; dissociation of DNA from core histones results in its increasing ability to intercalate AO, most likely due to increased topological freedom to undergo unwinding and elongation following binding of the intercalator. Preincubation of cells with n-butyrate, known to induce histone hyperacetylation, lowers the heat stability of nucleosomes by about 5 degrees C. On the other hand, no differences are observed between chromatin of mitotic vs interphase cells tested over a wide range of ionic strengths (0.1-0.7 N NaCl). The method appears to be useful as a probe of chromatin structure at the nucleosomal level.     

SELEX selection of high-affinity oligonucleotides for bacteriophage Ff gene 5 protein

The Ff gene 5 protein (g5p) is a cooperative ssDNA-binding protein. SELEX was used to identify DNA sequences favorable for g5p binding at physiological ionic strength (200 mM NaCl) and 37 degrees C. Sequences were selected from a library of 58-mers that contained a central variable segment of 26 nucleotides. DNA sequences selected after eight rounds of SELEX were mostly G-rich, with multiple copies of CPuGGPy, TPuGGGPy, and/or PyPuPuGGGPy motifs. This was unexpected, since g5p has higher binding affinities for polypyrimidine than for polypurine sequences. The most recurrent G-rich sequence, named I-3, was found to have g5p-binding properties that were correlated with a structural transition. At 10 mM NaCl, I-3 existed in a single-stranded form that was saturated by g5p in an all-or-none fashion. At 200 mM NaCl, I-3 existed in a structured form that showed CD spectral features of G-quadruplexes. The g5p binding affinity for this structured form of I-3 was >100-fold higher than for the single-stranded form. Moreover, the structured I-3 was saturated by g5p in two steps, the first of which was the formation of an apparent initiation complex consisting of one I-3 strand and about three g5p dimers. Nuclease S1 footprinting and other experiments showed that g5p molecules in the initiation complex at 200 mM NaCl were bound directly to the G-rich variable segment and that the structure of I-3 was retained after saturation by g5p. Thus, G-rich motifs may form structures favorable for initiation of g5p binding and also provide the actual g5p-binding sites.     

Single-molecule analysis reveals the kinetics and physiological relevance of MutL-ssDNA binding

DNA binding by MutL homologs (MLH/PMS) during mismatch repair (MMR) has been considered based on biochemical and genetic studies. Bulk studies with MutL and its yeast homologs Mlh1-Pms1 have suggested an integral role for a single-stranded DNA (ssDNA) binding activity during MMR. We have developed single-molecule Förster resonance energy transfer (smFRET) and a single-molecule DNA flow-extension assays to examine MutL interaction with ssDNA in real time. The smFRET assay allowed us to observe MutL-ssDNA association and dissociation. We determined that MutL-ssDNA binding required ATP and was the greatest at ionic strength below 25 mM (K_D = 29 nM) while it dramatically decreases above 100 mM (K_D>2 µM). Single-molecule DNA flow-extension analysis suggests that multiple MutL proteins may bind ssDNA at low ionic strength but this activity does not enhance stability at elevated ionic strengths. These studies are consistent with the conclusion that a stable MutL-ssDNA interaction is unlikely to occur at physiological salt eliminating a number of MMR models. However, the activity may infer some related dynamic DNA transaction process during MMR.     

Isolation and characterization of DNA-DNA and DNA-RNA.

A simple method for the isolation and characterization of DNA-DNA and DNA-RNA hybrid molecules formed in solution was developed. It was based on the fact that, in appropriate salt concentration, such as 5% Na2HPO4, DNA in either double-stranded (DNA-DNA or DNA-RNA) or single-stranded forms, but not free nucleotides, can bind to diethylaminoethylcellulose disc filters (DE81). Thus tested samples were treated with the single-strand-specific nuclease S1 and then applied to DE81 filters. The free nucleotides, resulting from degrading the single-stranded molecules, were removed by intensive washing with 5% Na2HPO4, leaving only the hybrid molecules on the filters. The usefulness of this method was illustrated in dissociation and reassociation studies of viral (SV40) or cellular (NIH/3T3) DNAs and DNA-RNA hybrid molecules. Using this technique the reassociation of denatured SV40 DNA was found to be a very rapid process. Dissociation studies revealed that the melting curves of tested DNAs were dependent on salt concentration. Thus the melting temperatures (tm) obtained for SV40 DNA were 76 degrees C at 1 X SSC (0.15 M NaCl-0.015 M sodium citrate) and 65 degrees C at 0.1 X SSC, and for NIH/3T3 DNA 82 degrees C at 1 X SSC and 68 degrees C at 0.1 X SSC. MuLV DNA-RNA hybrid molecules were formed by annealing in vitro synthesized MuLV DNA with 70S MuLV RNA at 68 degrees C. The melting temperature of this hybrid in the annealing solution was 87 degrees C. Another important feature of this procedure was that, after being selectively bound to the filters, the hybrid molecules could efficiently be recovered by heating the filters for 5 min at 60 degrees C in 1.5-1.7 M KCl. The recovered molecules were intact hybrids as they were found to be completely resistant to S1 nuclease.     

The nature of stacking interations in polynucleotides. Molecular states in Oligo- and polyribocytidylic acids by relaxation analysis.

The dynamics of the helix-coil transition of single-stranded poly(C) (polyribocytidylate) and CpC (cytidyly(3'-5')cytosine) was investigated by an improved cable temperature-jump technique. The single-strand relaxation was characterized by following the ultraviolet (uv) absorbance changes at 248 and 280 nm. Poly(C) and CpC showed single relaxation processes with amplitudes corresponding to those expected from equilibrium melting curves. The relaxation time contants in the range of 25-100 ns were independent of the nucleotide concentration, but strongly dependent upon temperature. Using thermodynanic parameters obtained from circular dichroism (CD) and uv absorbance melting curves, the following rate constants k (at 20 degrees C, 1.05 M ionic strength, pH 7) and activation enthalpies EA were calculated for poly (C): helix formation kR = 1.11 X 10(-7) s-1 (EAR = 2.6 kcal); helix dissociation kD = 2.1 X 10(6) s-1 (EAD = 11.9 kcal). The rate constants obtained for CpC were higher by a factor of about 2 in kR and 12 in kD, whereas the activation enthalpies closely corresponded to those found for the polymer. In addition to the single-stranded helix-coil relaxation, poly(C) and CpC exhibit a relaxation process with a time constant below 25 ns and maximum amplitudes at wavelengths lambda greater than or equal to 285 nm. The same process is found in cytidine and is attributed to hydration equilibria. The hydration reaction can be considered to be in equilibrium during the entire time range of the helix-coil transition and thus the data obtained for the helix-coil transition can be described by a simple two-state model. The rate parameters indicate the existence of relatively high energy barriers in the helix-coil transition and provide strong evidence evidence against an oscillating dimer model. If there is an ensemble of substates for one of the states (as may be expected for the coil form), the energy difference between the populated substates is small compared with the energy difference between the major conformational states.     

Knotted single-stranded DNA rings: A novel topological isomer of circular single-stranded DNA formed by treatment with Escherichia coli ω protein

Treatment of single-stranded circular phage fd DNA with Escherichia coli ω protein yields a new species which sediments 1.2 to 1.5 times faster than the untreated DNA in an alkaline medium. The infectivity of this species in spheroplast assays, after purification of the DNA by zone sedimentation in an alkaline sucrose gradient, is only slightly lower than that of untreated fd DNA. The formation of this species requires Mg(II) and is strongly dependent on salt concentration and temperature. At 37 °C, over 85% of the input DNA can be converted to this form when incubation is carried out in media containing 0.15 to 0.25 m-salt. The yield decreases with increasing temperature or decreasing salt concentration. The increase in sedimentation coefficient of fd DNA in an alkaline medium following treatment with ω is not due to protein binding, as no change was observed upon treatment of the product with phenol or Pronase. Furthermore, neither the buoyant density of this new species in neutral CsCl nor its sedimentation coefficient in a neutral medium is significantly different from the corresponding properties of untreated fd DNA. Examination by electron microscopy shows that the new form has the appearance of a knotted ring of about the same contour length as an untreated monomeric single-stranded fd DNA. The new form can be converted to full-length linear fd DNA by treatment with pancreatic DNAase I. The rate of conversion is approximately the same as that of untreated circular fd DNA to the linear form. These results show that the new form of fd DNA is a novel topological isomer: a knotted single-stranded DNA ring. It is also found that further treatment of the knotted DNA rings with ω at low ionic strength can reverse the reaction, i.e. the knotted DNA rings can be converted back to simple DNA rings indistinguishable from fd DNA from the phage. At intermediate ionic strength the two forms are interconvertible and form an equilibrium mixture. Results similar to those obtained for fd DNA have also been observed for single-stranded circular φX174 DNA. A mechanism based on the known activity of ω protein on double-stranded DNA, the secondary structure of a single-stranded circular DNA, and the experimental results described here is proposed.