Equilibrium studies on neutral red-DNA binding.

Spectrophotometric binding studies were undertaken on the interaction of neutral red with native and heat-denatured, sonicated, calf thymus DNA in a 0.2M ionic strength buffer containing Tris–sodium acetate–potassium chloride at 25°C. The pK_A of neutral red was found to be 6.81. At pH 5 the binding of protonated neutral red was complicated even at low concentration ratios of dye to DNA. In the pH range 7.5–8.5 the tight binding process could be studied and it was found that both protonated and free base species of neutral red significantly bind with DNA having association constants (in terms of polynucleotide phosphate) of 5.99 × 10³ M^?1 and 0.136 × 10³ M^?1, respectively, for native DNA and 7.48 × 10³ M^?1 and 0.938 × 10³ M^?1, respectively, for denatured DNA. The pK_A value of the neutral red–DNA complexes were 8.46 for native DNA and 7.72 for denatured DNA. These results are discussed in terms of possible binding mechanisms.     

Pathways for repair of DNA damaged by alkylating agent in Escherichia coli.

Summary A strain with both the polA12 and the alk-1 mutation is only slightly more sensitive to methyl methane sulfonate (MMS) than isogenic strains with only one of the mutations. On the other hand, alk-1 recA1 double mutant is much more sensitive to MMS than are strains carrying either one of alk or recA mutation. It was suggested that the alk and the polA gene products are involved in the same DNA repair process whereas the recA function is independent from the process. The yield of MMS-induced mutation (Arg^- (argE) to Arg⁺ reversion) in alk mutant is considerably higher than that in wild type strain. Thus, the repair process in which the alk gene product is involved is relatively accurate. When MMS-treated phages were plated on MMS-treated bacteria, there were considerable increases in survival of treated phage even in recA alk double mutant. It seems that a new repair pathway, which is specific for alkylating agent-induced damages and is not dependent on the RecA function, may be induced on exposure of bacteria to the alkylating agent.     

Transformation of virulence factor among bacterial blight ofXanthomonas campestris pv.malvacearum in plants

Transformation of an avirulent strain of bacterial blight of the cotton pathogenXanthomonas campestris pv.malvacearum (Xcm) to a virulent strain was achieved in plants by using total (i. e. chromosomal and plasmid DNA) as well as chromosomal DNA, but not the plasmid DNA, of a virulent Xcm strain, thereby indicating that virulence was located in the chromosomal replica. The process of transformation began 1 d after inoculation of the DNA preparation with the avirulent strain in plant tissues and was completed within 2 d with a recombination frequency of 10⁻²−10⁻⁴.     

Studies on nucleic acids. VIII. Changes in the stability of DNA secondary structure by interaction with divalent metal ions

The melting temperature of a natural DNA is decreased in the presence of increasing amounts of copper ions, whereas other divalent metal ions stabilize the DNA secondary structure at low ionic strength. At 1.28 × 10^?4M, Cu²⁺ produces a decrease of T_m depending on base composition. At very low Cu²⁺ concentrations (0.5 Cu²⁺/2 DNA-P) a stabilization of the DNA conformation appears due to an interaction between Cu²⁺ and phosphate groups of the DNA molecule. In this case the normal trend of GC dependence of T_m exists similar to that with Na⁺ and Mg²⁺ as counterions. If copper ions are in excess, the observed destabilization is stronger for DNAs rich in guanine plus cytosine than for those rich in adenine plus thymine. A sharp decrease of T_m occurs between 0.5–0.8 Cu²⁺/2 DNA-P and 1.5 Cu²⁺/2 DNA-P. The breadth of the transition decreases at high Cu²⁺ concentration with further addition of copper ions. Denaturation and renaturation experiments indicate that Cu²⁺ ions exceeding the phosphate equivalents interact with the bases and reduce the forces of the DNA helix conformation. Evidence is presented, that the destabilization effect produced by Cu²⁺ is possibly due to an interaction with guanine sites of the DNA molecule.     

Enthalpy and entropy changes for the intercalation of small molecules to DNA. II. Ethidium and propidium fluoride

Enthalpy changes (ΔH_B) for the binding of ethidium (a monocation) and propidium (a dication) to calf thymus DNA have been determined calorimetrically in piperazine-N, N′-bis(2-ethanesulfonic acid) buffer with the fluoride ion as the counterion. Heats of dilution for the fluoride salts of ethidium and propidium were substantially less than the corresponding values found for other halide salts of these cations. At a Na⁺ ion concentrations of 0.019, ΔH_B = ?8.3 and ?7.9 ± 0.3 kcal mol^?1 for ethidium and propidium, respectively. For these two cations, just as was observed for the naphthalene monoimide (monocation) and diimide (dication) [H. P. Hopkins, K. A. Stevenson, and W. D. Wilson, (1986) J. Sol. Chem. 15 , 563–579], ΔH_B is within the same experimental error for both cations. Apparently, charge–charge interactions in DNA–cation complexes produce only small changes in the enthalpy for the system. In the concentration range 0.019–0.207, the ΔH_B values for propidium did not depend appreciably on the Na⁺ ion concentration, and a similar pattern was shown to exist for ethidium. When these results were combined with ΔG_B values for the binding of these cations to DNA, we found the variation of ΔS_B with Na⁺ ion concentration to be remarkably close to the predictions of modern polyelectrolyte theory, i.e., propidium binding to DNA causes approximately twice as many Na⁺ ions to be released into the bulk solution as does the binding of ethidium. The much stronger binding of propidium, relative to ethidium, at low ionic strengths is thus seen to be primarily due to entropic effects.     

Prophage induction in Escherichia coli K12 cells deficient in DNA polymerase I.

Summary The induction of prophage by ultraviolet light has been measured inE. coli K12 lysogenic cells deficient in DNA polymerase I. The efficiency of the induction process was greater inpolA1 polC(dnaE) double mutants incubated at the temperature that blocks DNA replication than inpolA ⁺ polC single mutants. Similarly, thepolA1 mutation sensitizedtif-promoted lysogenic induction in apolA1 tif strain at 42°. In strains bearing thepolA12 mutation, which growth normally at 30°, induction of the prophage occured after the shift to 42°. It is concluded that dissapearance of the DNA polymerase I activity leads to changes in DNA replication that are able, per se, to trigger the prophage induction process.     

Fracture of DNA in transient extensional flow. A numerical simulation study

Using the Brownian dynamics simulation technique, we studied the fracture process of DNA chains subjected to transient extensional flow, letting the solution with DNA molecules pass through a very small orifice (radius = 0.0065 cm), thus experiencing extensional flow of the convergent (sink) type. The DNA molecules were modeled as FENE bead-spring chains with the springs obeying a modified Warner force law, as proposed by Reese and Zimm. The fracture yield was strongly dependent on flow rate and molecular weight, reaching, in our setup, a level of 100% at a flow rate of around 0.001 cm³/s for DNA with molecular weight 26 × 10⁶ (T7 DNA). There was found to exist a critical flow rate (Q_crit) below which fracture did not occur, in accordance with what was observed in studies on polystyrene in transient extensional flow. We found that for DNA, the critical flow rate depended on the molecular weight as Q_crit ∼ M⁻¹⁴ when the hydrodynamic interaction effect (HI) was not included in the simulations. When HI was accounted for, the relation was found to be Q_crit ∼ M^−1.1, close to the theoretical prediction for fracture of partly extended chains in transient extensional flow. © 1996 John Wiley & Sons, Inc.     

Dielectric relaxation of DNA in aqueous solutions.

Using a four-electrode cell and a new electronic system for direct detection of the frequency differences specturm of solution impedance, the complex dielectric constant of calf thymus DNA (M_r = 4 × 10⁶) in aqueous NaCl at 10°C is measured at frequencies ranging from 0.2 Hz to 30 kHz. The DNA concentrations are C_p = 0.01% and 0.05%, and the NaCl concentrations are varied from C_s = 10^?4 M to 10^?3 M. A single relaxation regions is found in this frequency range, the relaxation frequency being 10 Hz at C_p = 0.01% and C_s = 10^?3 M. At C_p = 0.05% it is evidenced that the DNA chains have appreciable intermolecular interactions. The dielectric relaxaton time τ_d at C_p = 0.01% agrees well with the rotational relaxation time estimated from the reduced visocisty on the assumption that the DNA is not representable as a rigid rod but a coiled chain. It is concluded that the dielectric relaxiatioinis ascribed to the rotation of the molecule. Observed values of dielectric increment and other experimental findings are reasonably explained by assuming that the dipole moment of DNA results from the slow counterion fluctuation which has a longer relaxation time than τ_d.     

Conformation and reactivity of DNA. IV. Base binding ability of transition metal ions to native DNA and effect on helix conformation with special reference to DNA-Zn(II) complex

The effects of metal ions of the first-row transition and of alkaline earth metals on the DNA helix conformation have been studied by uv difference spectra, circular dichroism, and sedimentation measurements. At low ionic strength (10^?3 M NaClO₄) DNA shows a maximum in the difference absorption spectra in the presence of Zn²⁺, Mn²⁺, Co²⁺, Cd²⁺, and Ni²⁺ but not with Mg²⁺ or Ca²⁺. The amplitude of this maximum is dependent on GC content as revealed by detailed studies of the DNA-Zn²⁺ complex of eight different DNA's. Pronounced changes also occur in the CD spectra of DNA transition metal complexes. A transition appears up to a total ratio of approximately 1 Zn²⁺ per DNA phosphate at 10^?3 M NaClO₄; then no further change was observed up to high concentrations. The characteristic CD changes are strongly dependent on the double-helical structure of DNA and on the GC content of DNA. Differences were also observed in hydrodynamic properties of DNA metal complexes as revealed by the greater increase of the sedimentation coefficient of native DNA in the presence of transition metal ions. Spectrophotometric acid titration experiments and CD measurements at acidic pH clearly indicate the suppression of protonation of GC base-pair regions on the addition of transition metal ions to DNA. Similar effects were not observed with DNA complexes with alkaline earth metal ions such as Mg²⁺ or Ca²⁺. The data are interpreted in terms of a preferential interaction of Zn²⁺ and of other transition metal ions with GC sites by chelation to the N-7 of guanine and to the phosphate residue. The binding of Zn²⁺ to DNA disappears between 0.5 M and 1 M NaClO₄, but complex formation with DNA is observable again in the presence of highly concentrated solutions of NaClO₄ (3?7.2 M NaClO₄) or at 0.5 to 2 M Mn²⁺. At relatively high cation concentration Mg²⁺ is also effective in changing the DNA comformation. These structural alterations probably result from both the shielding of negatively charged phosphate groups and the breakdown of the water structure along the DNA helix. Differential effects in CD are also observed between Mn²⁺, Zn²⁺ on one hand and Mg²⁺ on the other hand under these conditions. The greater sensitivity of the double-helical conformation of DNA to the action of transition metal ions is due to the affinity of the latter to electron donating sites of the bases resulting from the d electronic configuration of the metal ions. An order of the relative phosphate binding ability to base-site binding ability in native DNA is obtained as follows: Mg²⁺, Ba²⁺, < Ca²⁺ < Fe²⁺, Ni²⁺, Co²⁺ < Mn²⁺, Zn²⁺ < Cd²⁺ < Cu²⁺. The metal-ion induced conformational changes of the DNA are explained by alternation of the winding angle between base pairs as occurs in the transition from B to C conformation. These findings are used for a tentative molecular interpretation of some effects of Zn²⁺ and Mn²⁺ in DNA synthesis reported in the literature.     

Restriction and modification in B. subtilis

Summary The effects of restriction in vivo by competent B. subtilis R cells and in vitro by purified endonuclease BsuR on transformation and transfection with native and denatured DNA were investigated.The results show that transformation by either native, or denatured DNA is not affected by restriction, whereas transfection both with native and denatured SPP1 DNA is severely restricted.In contrast to the results obtained in vivo, the biological activity of native and denatured transforming DNA is destroyed by BsuR in vitro, as is the transfecting activity of native and denatured SPP1 DNA. The sensitivity of denatured DNA, either with mixtures of the complementary strands or with separated single strands¹ alone, is significantly lower than that of native DNA.The results are discussed in the context of possible mechanisms underlying the different responses of transforming and transfecting DNA to in vivo restriction by B. subtilis R cells.Abbreviations EGTA ethyleneglycolbis-(aminoethylether)tetraacetic acid - m⁺ modified - m^- non-modified - moi multiplicity of infection - r⁺ m⁺ restricting and modifying - r^- m^- mon-restricting and non-modifying - SSC 0.15M NaCl+0.015 M trisodium citrate - SDS sodium dodecyl sulphate     

The molecular structure of the transducing particles of Salmonella phage P22. II. Density gradient analysis of DNA

Summary CsCl density gradient analysis showed that the DNA of plaque forming particles ofSalmonella phageP22 is lighter than the host DNA. The DNA of transducing phages exhibits an intermediate density, but close to host DNA. BU labelling of DNA synthesized in the cells after phage infection resulted in a density increase of transducing DNA of about 0.004 gxcm^-3, whereas infectious DNA increased by about 0.045 gxcm^-3. Shearing of isolated DNA molecules from unlabelledP22 lysates demonstrated that transducing DNA consists of two pieces of DNA of different density: 90% stem from the bacterial host whereas 10% are phage DNA and therefore responsible for the BU lable in transducing phages.     

Dielectric relaxation of DNA solutions. III. Effects of DNA concentration, protein contamination, and mixed solvents

As a continuation of previous papers [Biopolymers (1976) 15 , 879; (1978) 17 , 1508], the low-frequency dielectric relaxation of DNA solutions was studied with a four-electrode cell and the simultaneous two-frequency measurement. Below a critical concentration, the dielectric relaxation time agrees with the rotational relaxation time estimated from the reduced viscosity and is almost independent of DNA concentration C_p, and the dielectric increment is proportional to C_p. The critical concentration is approximately 0.02% of DNA for molecular weight M_r 2 × 10⁶ and 0.2% for M_r 4.5 × 10⁵ in 1 mM NaCl. Dielectric relaxations are compared for samples before and after deproteinization, and the protein contamination is found to have a minor effect on the dipole moment of DNA. The effect of a mixed solvent of water and ethanol on the dielectric relaxation of DNA is well interpreted in terms of changes in viscosity and the dielectric constant of the solvent, assuming that the relaxation arises from rotation of the molecule with a quasi-permanent dipole due to counterion fluctuation.     

Extranuclear DNA accumulates in aged cells and contributes to senescence and inflammation

Systemic inflammation is central to aging‐related conditions. However, the intrinsic factors that induce inflammation are not well understood. We previously identified a cell‐autonomous pathway through which damaged nuclear DNA is trafficked to the cytosol where it activates innate cytosolic DNA sensors that trigger inflammation. These results led us to hypothesize that DNA released after cumulative damage contributes to persistent inflammation in aging cells through a similar mechanism. Consistent with this notion, we found that older cells harbored higher levels of extranuclear DNA compared to younger cells. Extranuclear DNA was exported by a leptomycin B‐sensitive process, degraded through the autophagosome–lysosomal pathway and triggered innate immune responses through the DNA‐sensing cGAS‐STING pathway. Patient cells from the aging diseases ataxia and progeria also displayed extranuclear DNA accumulation, increased pIRF3 and pTBK1, and STING‐dependent p16 expression. Removing extranuclear DNA in old cells using DNASE2A reduced innate immune responses and senescence‐associated (SA) β‐gal enzyme activity. Cells and tissues of Dnase2a^?/? mice with defective DNA degradation exhibited slower growth, higher activity of β‐gal, or increased expression of HP‐1β and p16 proteins, while Dnase2a^?/?;Sting^?/? cells and tissues were rescued from these phenotypes, supporting a role for extranuclear DNA in senescence. We hypothesize a direct role for excess DNA in aging‐related inflammation and in replicative senescence, and propose DNA degradation as a therapeutic approach to remove intrinsic DNA and revert inflammation associated with aging.     

Linear dichroism studies of nucleic acids. II. Calculation of reduced dichroism curves of A-and B-form DNA

We have calculated the uv linear dichroism for the A- and B-forms of DNA using π-π* transition moments and band components determined from the free DNA bases. The reduced dichroism (LD^R) as a function of wavelength is estimated is in the 220–300-nm region, for both the oriented-gas model and a simple exciton model. For B-form DNA, LD^R is obtained to ?1.48S (S being the orientation factor) over the whole wavelenth region by both models. For A-form DNA, LD^R is not constant, but changes monotonically from about ?1.15S at 220 nm to about ?1.35S to ?1.45S at 300 nm, depending on base combination and degree of interaction (?1.35S for the oriented gas). It is emphasized that a common assumption of a single “effective” transition moment of the principal band at 260 nm may not generally be made because of the extensive overlap of differently polarized bands. The possibility of using the reduced dichroism curve for characterizing the secondary structure of DNA is discussed.     

A new DNA-cloning vector forHaemophilus influenzae Rd.

A new, high-efficiency, DNA-cloning vector pJ1-8 was derived in two steps from the chimeric plasmid pD7 consisting of RSF 0885(amp ^r) andHaemophilus influenzae chromosomal DNA. pJl-8 has only oneEcoRI site and a molecular weight of only 2.5 × 10⁶. No detectableamp ^r transformation was obtained with pJl-8 DNA. However,amp ^r transformation increases markedly ifHaemophilus influenzae chromosomal DNA segments are spliced into it, providing a very facile assay for detecting inserts.     

Optimum Conditions for Electric Pulse-mediated Gene Transfer to Bacillus subtilis Cells

It was found that plasmid DNA (pUB 110) can be introduced into not only protoplasts but also intact cells of Bacillus subtilis by electric field pulses. The transformation of, B. subtilis using protoplasts results in an efficiency of 2.5 × 10⁴ transformants per μg of DNA, with a single pulse of 50 jisec with an initial electric field strength of 7kV/cm. Even transformation of intact B. subtilis cells results in a maximum efficiency of 1.5 × 10³ transformants per μg DNA, with a single pulse of 400 μsec with an initial electric field strength of 16kV/cm. The cell survival of protoplasts and intact cells was approximately 100% and 30%, respectively, under the conditions found to be optimal for the transformation process. Plasmid DNA isolated from pUB 110 containing transformants was indistinguishable from authentic preparations of pBU 110 on gel electrophoretic analysis.     

Cloning of an EcoRI fragment carrying E. coli tufA gene.

Summary EcoRI fragments of the transducing phage fus3 DNA have been linked to the ColEl derivative plasmid RSF2124 (ColEl-Ap^r) DNA using bacteriophage T4 ligase. Among the plasmids formed, one designated pTUAl was found to contain the E. coli tufA gene. The proof for the presence of tufA gene in pTUAl is based on the following observations: (1) ability of pTUAl DNA and its EcoRI fragments to direct synthesis of EF-Tu in a cell-free protein synthesizing system; and (2) RNA·DNA hybridization of RNA transcribed from phage rif ^d18 carrying tufB with DNA from pTUAl.     

Induction of protein X in Escherichia coli.

Summary Certain treatments that damage DNA and/or inhibit replication in E. coli have been reported to induce synthesis of a new protein, termed protein X, in recA ⁺ lexA ⁺ strains. We have examined some of the treatments that might induce protein X and we have, in particular, tested the hypothesis of Gudas and Pardee (1975) that DNA degradation products play an essential role in the induction process.We confirmed that UV irradiation, nalidixic acid treatment, or thymine starvation result in protein X synthesis in wild type strains. However, we found that UV irradiation, unlike nalidixic acid, also induced protein X in recB strains, in which little DNA degradation occurs. Furthermore, we found that the presence of DNA fragments resulting from host-controlled restriction of phage DNA did not affect protein X synthesis. We conclude that no causal relationship exists between the production of DNA fragments and induction of protein X.The presence of the plasmid R46, which confers enhanced mutagenesis and UV resistance on its host, did not affect protein X synthesis. Growth in the presence of 5-bromouracil, which does not result in production of degradation fragments, resulted eventually in a low rate of protein X synthesis. In dnaA mutants, deficient in the initiation of new rounds of replication, UV irradiation induced protein X, again unlike nalidixic acid. Thus, the inhibition of active replication forks is not an essential requirement for protein X induction.     

Yeast as a model system for understanding the control of DNA replication in eukaryotes

In the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, the initiation of DNA replication is controlled at a point called START. At this point, the cellular environment is assessed; only if conditions are appropriate do cells traverse START, thus becoming committed to initiate DNA replication and complete the remainder of the cell cycle. The cdc2⁺ / CDC28⁺ gene, encoding the protein kinase p34, is a key element in this complex control. The identification of structural and functional homologues of p34 suggests that it has a role in the control of DNA replication in all eukaryotes. The WHI1⁺, CLN1⁺ and CLN2⁺ gene products, identified in S. cerevisiae, are positive regulators that function at START and may interact with p34. Determining how passing the START control point leads to the initiation of DNA replication is a major outstanding challenge in cell cycle studies.     

Isolation and characterization of plasmid from the Bacillus brevis var. G.-B. cells

Summary The plasmid designated pAD1 was isolated from the cells of four variants of Bacillus brevis var. G.-B. The plasmid DNA has a molecular weight of about 47.1×10⁶ daltons and contains 43.4 mole % G+C. The bulk of pAD1 DNA (96–98%) is associated with the fraction of chromosome DNA and membranes.Restriction endonucleases SmaI, SalI and BamHI cleaved the plasmid DNA into two, two and six fragments, respectively. The cleavage map of the pAD1 genome has been constructed for these three endonucleases. Restriction enzymes EcoRI, HindIII, KpnI and PstI hydrolized the plasmid DNA into 16, 21, 10 and 9 fragments, respectively. The presence of repeated sequences in the plasmid genome was shown based on pAD1 DNA cleavage by these endonucleases.