Species-specific detection of three human-pathogenic microsporidial species from the genus Encephalitozoon via fluorogenic 5' nuclease PCR assays.

This study describes fluorogenic 5' nuclease PCR assays suitable for rapid, sensitive, high-throughput detection of the human-pathogenic microsporidial species Encephalitozoon hellem, E. cuniculi and E.intestinalis. The assays utilize species-specific primer sets and a genus-specific dual fluorescent-labeled probe that anneals to a region within the Encephalitozoon 16S rRNA gene. The assay design theoretically permits the probe to be used either with one set of primers for species-level determination or with a combination of all three primer sets for a genus-level screening of samples. The linear range of all three species-specific calibration curves that were developed using serial ten-fold dilutions of genomic DNA isolated from hemacytometer counted spores was determined to be between 10(4) and 10(-1) spores per PCR sample. The coefficients of variation were < or =5.2% over the entire 5-log span of each calibration curve. When DNA isolated from flow cytometric enumerated spores from each of the three Encephalitozoon species was used to evaluate the quantitative capability of the species' respective calibration curves, the results from 34 out of 36 (94%) samples were within 2 standard deviations. The species-specificity of each assay was confirmed using DNA isolated from 10(4) spores from each of the other two Encephalitozoon species as well as DNA extracted from numerous other protozoa, algae and bacteria.

Fluorescent in situ detection of Encephalitozoon hellem spores with a 6-carboxyfluorescein-labeled ribosomal RNA-targeted oligonucleotide probe.

A fluorescent in situ hybridization assay has been developed for the detection of the human-pathogenic microsporidian, Encephalitozoon hellem in water samples using epifluorescence microscopy. The assay employs a 19-nucleotide species-specific 6-carboxyfluorescein-labeled oligonucleotide probe, HEL878F, designed to be complementary to the nucleic acid sequence 878-896, a highly variable segment of the 16S ribosomal RNA of E. hellem spores. The specificity of this probe for its ribosomal RNA target site was confirmed using RNA degradation, ribosomal RNA target site competition, and nucleotide base mismatch control probe assays. Furthermore, the specificity of the HEL878F oligonucleotide probe for E. hellem spores was established when it was evaluated on spores from all three species of the genus Encephalitozoon that had been seeded in reagent water and environmental water concentrates. The specificity of the HEL878F oligonucleotide probe was further corroborated when tested on algae, bacteria, and protozoa commonly found in environmental water. The study demonstrates the applicability of a fluorescent in situ hybridization assay using a species-specific fluorescent-labeled oligonucleotide probe for the detection of E. hellem spores in water samples.

Increased endogenous ascorbyl free radical formation with singlet oxygen scavengers in reperfusion injury: an EPR and functional recovery study in rat hearts.

The objective of this study was to investigate the effect of singlet oxygen ((1)O2) scavengers on functional recovery and ascorbyl free radical (AFR) formation in isolated ischemic rat hearts. Hearts were subjected to 40 min. of global ischemia followed by 30 min. of reperfusion. Hemodynamics were measured as heart rate (HR), coronary flow (CF), left ventricular developed pressure (LVDP) and contractility (dP/dt). Electron paramagnetic resonance (EPR) spectroscopy was used to measure AFR release in coronary perfusate during the first two min. of reperfusion as a function of ROS scavengers. Relative to ischemic controls the administration of the (1)O2 scavengers 2,2,6,6-tetramethyl-4-piperidone x HCl (4-oxo-TEMP), carnosine (beta-alanyl-L-histidine) or a combination of the two significantly improved functional recovery as measured by LVDP. While no AFR signal was detected in coronary perfusate collected during preischemic perfusion with and without (1)O2 scavengers, the AFR background signal due to ischemia was significantly increased with the (1)O2 and *O2- scavengers. No such increase was observed with the hydroxyl radical (*OH) scavenger mannitol. Besides the AFR increase with the (1)O2 and *O2- scavengers the functional recovery was only significantly improved with the (1)O2 scavengers. In contrast to previous AFR studies we found with endogenous AFR that an increased AFR formation is not necessarily only reflecting increased oxidative stress but can also report improved functional recovery. Combining the hemodynamic data with increased AFR formation in the presence of several different ROS scavengers gives supportive evidence for (1)O2 also being involved in reperfusion injury.

Improved functional recovery of ischemic rat hearts due to singlet oxygen scavengers histidine and carnosine.

There is increasing evidence that reactive oxygen species (ROS) contribute to post-ischemic reperfusion injury, but determination of the specific ROS involved has proven elusive. In the present study electron paramagnetic resonance (EPR) spectroscopy was used in vitro to measure the relative quenching of singlet oxygen (1O2) by histidine and carnosine (beta-alanyl-L-histidine) utilizing the hindered secondary amine 2,2,6,6-tetramethyl-4-piperidone HCl (4-oxo-TEMP). The relative effect of histidine and carnosine on functional recovery of isolated perfused rat hearts was also studied. Functional recovery was measured by left ventricular developed pressure (LVDP), first derivative of left ventricular pressure (dP/dt), heart rate (HR) and coronary flow (CF). EPR measurements and Stern-Volmer plots showed that 400 microM carnosine quenched 1O2 twice as effectively as equimolar histidine in vitro. Moreover, 10 mM histidine improved functional recovery of isolated rat hearts significantly more than 1 mM histidine. Furthermore, 1 mM carnosine improved functional recovery significantly more than equimolar histidine and as effectively as 10 mM histidine. Experiments with 1 mM mannitol, a known hydroxyl radical scavenger, did not show an improvement in functional recovery relative to control hearts, thereby decreasing the likelihood that hydroxyl radicals are the major damaging species. On the other hand, the correlation between improved functional recovery of isolated rat hearts with histidine and carnosine and their relative 1O2 quenching effectiveness in vitro provides indirect evidence for 1O2 as ROS participating in reperfusion injury.

Overall and internal dynamics of DNA as monitored by five-atom-tethered spin labels.

Electron paramagnetic resonance (EPR) spectra of the two-atom-tethered six-membered ring thymidylate spin label (DUMTA) incorporated into duplexes of different sizes were found to display a helix length dependence and a local-order parameter S = 0.32 +/- 0.01 for B-DNA based on the dynamic cylinder model (Keyes, R. S., and A. M. Bobst. 1995. Detection of internal and overall dynamics of a two-atom-tethered spin-labeled DNA. Biochemistry. 34:9265-9276). This sensitivity to size, which reflects global tumbling, is now reported for the more flexible five-atom-tethered five-membered ring thymidylate spin label (DUAP) that can be readily incorporated enzymatically and sequence specifically into nucleic acids of different sizes. The DUAPs containing B-DNA systems were simulated with the same dynamic cylinder model, giving S = 0.20 +/- 0.01 for the more flexibly tethered spin label. This shows that S is dependent on tether length but not on global motion. An analysis with the same motional model of the B-Z transition in a (dG-dC)n polymer containing the five-atom-tethered six-membered ring cytidylate spin label (DCAT) (Strobel, O. K., R. S. Keyes, and A. M. Bobst. 1990b. Base dynamics of local Z-DNA conformations as detected by electron paramagnetic resonance with spin-labeled deoxycytidine analogues. Biochemistry. 29:8522-8528) revealed an increase in S from 0.15 +/- 0.01 to 0.26 +/- 0.01 in response to the B- to Z-DNA transition. This indicates that S is not only sensitive to tether length, but also to conformational changes in DNA. Both the DUAP- and the DCAT-labeled systems were also simulated with a base disk model. From the DUAP spectral series, the perpendicular component of the correlation time tau perpendicular describing the spin-labeled base diffusion was found to be sensitive to global tumbling, confirming earlier results obtained with DUMTA. The DCAT polymer results demonstrated that tau perpendicular monitors a conformational change from B- to Z-DNA, indicating that tau perpendicular is also sensitive to local base dynamics. These results confirm that the dynamics of five-atom-tethered nitroxides are coupled to the nucleic acid dynamics and, as with two-atom-tethered spin labels, can be characterized by S and tau perpendicular. The analyses of both spin-labeled systems provide good evidence for spin-labeled base motions within double-stranded DNA occurring on the nanosecond time scale, and establish that both labels can be used to monitor changes in global tumbling and local order parameter due to variations in DNA conformation and protein-DNA interactions.

Spin-labeled nucleotide mobility in the boundary of the EcoRI endonuclease binding site.

A complex consisting of the EcoRI endonuclease site-specifically bound to spin-labeled DNA 26mers was prepared to provide a model system for studying possible conformational changes resulting from protein binding. EPR was used to monitor the mobility of the spin labels that were strategically placed in position 6, 9, or 11 with respect to the dyad axis of the 26mer. These positions are located within the flanking region on either side of the EcoRI hexamer binding site. This allows the monitoring of potential distal structural changes in the DNA helix caused by protein binding. The spectral line shapes indicate that the spin label closest to the EcoRI endonuclease binding site, i.e., in position 6, is most influenced by the binding event. The EPR data are analyzed according to a model that distinguishes between spectral effects due to a change in the hydrodynamic shape of the complex and those resulting from local variations in the spin-label mobility as characterized by a local order parameter S. S reflecting the motional restriction of the spin-labeled base is 0.20 +/- 0.01 for all three oligomers as well as for the two complexes with the label in position 9 or 11, while the position 6 labeled complex yields S = 0.25. To further evaluate the origin of the slightly larger EPR effect observed with position 6 labeled material, molecular dynamics (MD) simulations were used to explore the space accessible to the probes in positions 6, 9, and 11. MD results gave similar nitroxide trajectories for all three labeled 26mers in the absence or presence of EcoRI. Thus, the small position 6 effect is attributed to a structural distortion in the major groove of the DNA at this location possibly corresponding to a bend induced by protein binding. The observation that the spectral changes are small indicates the absence of any significant structural disruption being propagated along the helix as a result of protein binding. Also, the fact that the line shape of the 26mers did not change as expected from hydrodynamic theory in view of the significant increase in molecular volume upon protein binding suggests that there are additional relaxation processes involving the protein and nucleic acid.

Spectroscopic probe for the detection of local DNA bending at an AAA triplet.

Spectroscopic evidence of a DNA bend in solution is presented by analyzing model 15-mer duplexes spin-labeled with the five-atom-tethered nitroxide DUAP located in the major groove. Three 15-mers containing AATT with DUAP enzymatically incorporated into three different positions yielded nearly identical line shapes while a fourth 15-mer containing AAATT produced an EPR spectrum with significant additional line broadening. These results are interpreted according to the dynamic cylinder model where the DNA dynamics are decoupled into overall and internal contributions. It is shown that the AAATT sequence induces a change in the internal dynamics characterized by local ordering of DUAP. The increase in ordering evident in 15-mers containing AAATT rather than AATT suggests that the former sequence gives rise to a bend toward the major groove resulting in spatial restriction of the probe.

Rigidity of a B-Z region incorporated into a plasmid as monitored by electron paramagnetic resonance.

Electron paramagnetic resonance spectroscopy was employed to monitor the dynamics associated with a B-Z transition in both a linear (dG-dC)n and a modified pUC8 plasmid. A spin label consisting of cytidine substituted in position C5 with an 11-atom-tethered 5-membered ring nitroxide (DCAVAP) was incorporated into linear (dG-dC)n with Micrococcus luteus DNA polymerase or into a specific 34-bp Z-DNA-forming region of the 2.7-kb plasmid pRDZ8 with Thermus aquaticus DNA polymerase (Stoffel fragment). Although DCA-VAP is a modified nucleotide, it was an excellent substrate for both enzymes. The Z conformation was induced by changing the salt concentration from 0.01 to 4.5 M. The EPR line shape changed in response to the switch in DNA conformation. The degree of change was quantitatively similar for both the linear polymer and the plasmid with its Z-DNA-forming region. A motional analysis which focuses on local dynamics indicates that the order parameter S for the spin-labeled systems increases upon conversion from B-DNA to Z-DNA. This decrease in motional freedom is consistent with the observation that Z-DNA is more rigid than B-DNA.

Detection of internal and overall dynamics of a two-atom-tethered spin-labeled DNA.

DNA motions consist of several components which couple, making their investigation difficult. This study describes an approach for obtaining dynamical information by EPR when spin-labeled nucleic acids are examined. The analysis is accomplished by implementing two motional models. The first model (i.e., dynamic cylinder model) views the spin-labeled helix as a diffusing cylinder containing internal dynamics which are characterized by an order parameter. The second model (i.e., base disk model) provides correlation times describing the diffusion of the spin-labeled base. In each model, the nitroxide motion consists of both global and internal contributions. Dynamic cylinder and base disk simulations of four duplexes containing nitroxides attached to thymidine by a two-atom tether (DUMTA)-(dT)7DUMTA-(dT)7.(dA)15, [(dT)7DUMTA(dT)7]2.(dA)30, [(dT)7DUMTA(dT)7]3.(dA)45, and [(dT)7DUMTA(dT)7]m.-(dA)n--demonstrate the useful application of this approach. From dynamic cylinder simulations, the order parameter for internal motions is found to be independent of the helix length (S = 0.32 +/- 0.01). Previous base disk simulations of a DNA 26mer and polymer labeled with a five-atom-tethered nitroxide seemed to indicate that tau perpendicular was only sensitive to internal dynamics. Results from base disk simulations of DUMTA-labeled DNA indicate that the perpendicular component of the base disk correlation time (tau perpendicular = 1.4-6.2 ns) is sensitive to global dynamics. Thus, tau perpendicular is a quantitative indicator of both internal and global dynamics. Comparison of the two models reveals that tau perpendicular infinity S2 tau rb, where tau rb represents the rigid-body diffusion of the DNA helix. This relationship between S and tau perpendicular provides a framework for studying conformational changes and size-dependent phenomena in spin-labeled nucleic acids. Application of the dynamic cylinder model to a B-Z transition generates distinct values of S for each of the conformations, indicating that Z-DNA is more rigid than B-DNA.

A comparative study of Scatchard-type and linear lattice models for the analysis of EPR competition experiments with spin-labeled nucleic acids and single-strand binding proteins.

An EPR competition formalism is developed which provides relative affinities of proteins for nucleic acids. Two models for analyzing protein-nucleic acid interactions, one assuming independent binding sites (Model 1) and the other considering site overlap (Model 2), are examined with respect to their validity and limitations. The models are employed to derive affinity ratio relationships which are used to calculate the relative affinities of gene 32, gene 5, and SSB proteins for various nucleic acids. It is determined that although Model 2 must be used when determining absolute binding constants, by taking the ratio of binding constants the site overlap becomes unimportant under conditions of moderate to high cooperativity and relatively small site size. This allows Model 1 to considerably simplify binding analyses. Both models are applied to the single-strand binding proteins of bacteriophage T4 gene 32, bacteriophage fd gene 5, and the Escherichia coli ssb gene, and the results are compared.

An EPR study to determine the relative nucleic acid binding affinity of single-stranded DNA-binding protein from Escherichia coli.

A direct quantitative determination by EPR of the nucleic acid binding affinity relationship of the single-stranded DNA-binding protein (SSB) from Escherichia coli at close to physiological NaCl concentration is reported. Titrations of (DUAP, dT)n, an enzymatically spin-labeled (dT)n, with SSB in 20 mM Tris-HCl (pH 8.1), 1 mM sodium EDTA, 0.1 mM dithiothreitol, 10% (w/v) glycerol, 0.05% Triton with either low (5 mM), intermediate (125 mM) or high 200 mM) NaCl content, reveal the formation of a high nucleic acid density complex with a binding stoichiometry (s) of 60 to 75 nucleotides per SSB tetramer. Reverse titrations, achieved by adding (DUAP, dT)n to SSB-containing solutions, form a low nucleic acid density complex with an s = 25 to 35 in the buffer with low NaCl content (5 mM NaCl). The complex with an s = 25 to 35 is converted to the high nucleic acid density complex by increasing the NaCl content to 200 mM. It is, therefore, metastable and forms only under reverse titration conditions in low NaCl. The relative apparent affinity constant Kapp of SSB for various unlabeled single-stranded nucleic acids was determined by EPR competition experiments with spin-labeled nucleic acids as macromolecular probes in the presence of the high nucleic acid density complex. The Kapp of SSB exhibits the greatest affinity for (dT)n as was previously found for T4 gene 32 protein (Bobst, A.M., Langemeier, P.W., Warwick-Koochaki, P.E., Bobst, E.V. and Ireland, J.C. (1982) J. Biol. Chem. 257, 6184) and gene 5 protein (Bobst, A.M., Ireland, J.C. and Bobst, E.V. (1984) J. Biol. Chem. 259, 2130) by EPR competition assays. In contrast, however, SSB does not display several orders of magnitude greater affinity for (dT)n than for other single stranded DNAs as is the case with both gene 5 and T4 gene 32 protein. The relative Kapp values for SSB in the above buffer with 125 mM NaCl are: Kapp(dT)n = 4KappfdDNA = 40Kapp(dA)n = 200Kapp(A)n.

Preparation and characterization of spin-labeled oligonucleotides for DNA hybridization.

Sequence-specific spin-labeled oligodeoxynucleotides with conformation-sensitive electron paramagnetic resonance (EPR) signals are synthesized and examined as solution-phase nucleic acid hybridization probes. Either a proxyl or tempo ring linked to the C(5) position of deoxyuridine (dU) by a nonrigid two-atom methylamino tether is incorporated within 15-mers by phosphotriester chemistry yielding stable spin-labeled probes with distinctive EPR specific activity (AEPR) values. The AEPR is greater for a proxyl-labeled than for a tempo-labeled probe and is consistent with EPR data of enzymatically labeled 26-mers [Bobst, A. M., Pauly, G. T., Keyes, R. S., and Bobst, E. V. (1988) FEBS Lett. 228, 33-36], after normalizing for percent labeling. The spectral characteristics of the free probes and the probe/target complexes are similar to those of enzymatically spin-labeled nucleic acids containing a different nonrigid two-atom-tethered spin label [Bobst, A. M., Kao, S.-C., Toppin, R. C., Ireland, J. C., and Thomas, I. E. (1984) J. Mol. Biol. 173, 63-70]. The presence of target DNA is detected in solution by EPR spectroscopy and the assay is based on the characteristic line-shape change associated with hybridization. The EPR spectra of free and bound probe reflect little interference from changes in global dynamics of the probe, and the line-shape change upon complexation results primarily from a change in local base dynamics. The presence or absence of hybridization can be detected in a loop-gap resonator with about 1 pmol of spin-labeled 15-mer within minutes.

Base dynamics of local Z-DNA conformations as detected by electron paramagnetic resonance with spin-labeled deoxycytidine analogues.

Conformation detection and base dynamics of spin-labeled Z-DNA have been investigated by electron paramagnetic resonance (EPR) spectroscopy. The two synthesized and characterized probes used in this study were C(5)-nitroxide-labeled 2'-deoxycytidine 5'-triphosphates, pppDCAT and pppDCAVAT, which serve as suitable substrates for Micrococcus luteus DNA polymerase. Enzymatic incorporation of these probes into (dG-dC)n yields the EPR-active alternating copolymers (dG-dC,DCAT)n and (dG-dC,-DCAVAT)n. These polymers assume typical B- and Z-DNA conformations under respective low (0.1 M NaCl) and high (4.5 M NaCl) salt conditions, as evidenced by their UV-circular dichroism spectra. The EPR line shape of (dG-dC,DCAT)n in Z-form is unique and significantly different from the B-form EPR spectrum. A similar observation is made for (dG-dC,DCAVAT)n. Thus, the EPR line shapes of these spin-labeled DNAs are indicative of their local conformations. The EPR spectra, analyzed with a previously published motional model [Kao, S.-C., Polnaszek, C.F., Toppin, C.R., & Bobst, A.M. (1983) Biochemistry 22, 5563-5568], indicate tau perpendicular values of 4 and 7 ns for the B- and Z-forms, respectively. Therefore, the base dynamics of Z-DNA are about two times slower than in B-DNA.

Gene 5 protein-DNA complex: modeling binding interactions.

A helical (not toroidal) complex consisting of eight gene 5 protein dimers per turn is proposed for the extension of DNA from dimer to dimer using known bond length constraints, postulated protein-nucleic acid interactions (determined from NMR and chemical modification studies), other physical properties of the complex, and data from electron micrographs. The binding channel has been dictated by these known parameters and the relative ease of geometrically fitting these constituents. This channel is different from that previously reported by other modelers. The channel lies underneath the long arm "claw-like" extension of the monomer, so that it rests inside the outer surface of the protein complex. An explanation is proposed for the two binding modes, n = 4 (the predominate mode) and n = 3, based on the weak binding interaction of Tyrosine 34. Also, the site of the less mobile nucleic acid base as reported from ESR studies (S.-C. Kao, E.V. Bobst, G.T. Pauly and A.M. Bobst, J. Biom. Struc. Dyn. 3,261 (1985)) is postulated as involving the fourth nucleotide, and this particular base is stacked between Tyrosine 34 and Phenylalanine 73'.

An electron paramagnetic resonance probe to detect local Z-DNA conformations.

We present spectroscopic evidence for an electron paramagnetic resonance (EPR) probe to detect local Z-DNA conformations in synthetic DNA. A spin labeled deoxycytidine-5'-triphosphate (pppDCAT) was co-polymerized with Micrococcus luteus DNA polymerase to yield the spin active alternating co-polymer (dG-dC,DCAT)n. The EPR spectrum of (dG-dC,DCAT)n in the Z-DNA conformation indicates a decrease in the local base dynamics by about a factor of two as compared to that computed for B-DNA. A control experiment conducted with (dA-dT, DUAT)n under similar salt conditions rules out the possibility of observing salt induced artifacts.

Nick translation of lambda phage DNA with a deoxycytidine analog spin labeled in the 5 position.

The synthesis and properties of a novel C(5)-spin-labeled 2'-deoxycytidine 5'-triphosphate which serves as a suitable substrate for the template-directed enzyme Escherichia coli DNA polymerase I are reported. The spin label is readily incorporated into lambda phage DNA by nick translation where it reports the characteristic local base motion for double- and single-stranded DNA as determined by electron spin resonance. The high-frequency deoxycytidine motion is similar to the previously reported thymidine motion in double-stranded lambda phage DNA.

Interaction of a folded chromosome-associated protein with single-stranded DNA-binding protein of Escherichia coli, identified by affinity chromatography.

A single-stranded DNA-binding protein (SSB) affinity column was prepared by optimizing the coupling of Escherichia coli single-stranded DNA-binding protein to Affi-Gel 10. The bound SSB retained its ability to specifically bind single-stranded DNA. When nuclease-treated cell extracts were incubated with the SSB beads overnight at 4 degrees C, a major protein of Mr = 25,000 was bound. At shorter incubation times, two additional proteins of Mr = 32,000 and 36,000 were also detected. In the absence of nuclease treatment, eight additional proteins ranging from Mr = 14,000 to 160,000 also bound to the affinity column. The major Mr = 25,000 protein has been shown to be a folded chromosome-associated protein. Its binding to SSB is strongly enhanced by the addition of DNA polymerase III or DNA polymerase III holoenzyme.

Enzymatic sequence-specific spin labeling of a DNA fragment containing the recognition sequence of EcoRI endonuclease.

Deoxyuridine analogs spin labeled in position 5 have been enzymatically incorporated sequence specifically into an oligodeoxyribonucleotide to form a spin-labeled 26-mer. The 26-mer contains the EcoRI-binding site and two labels which are located symmetrically close to the binding site. The labels are separated from one another far beyond the Heisenberg spin-exchange distance. The local base motion as determined by ESR spectroscopy is of the order of 4 ns in the oligonucleotide duplex. This is the same value as reported earlier for local T motions in polynucleotide duplexes, thereby providing direct experimental evidence that the ESR line shape of spin levels covalently attached to nucleic acids depends primarily on the local dynamics of the nucleic acid building blocks.

Base dynamics of nitroxide-labeled thymidine analogues incorporated into (dA-dT)n by DNA polymerase I from Escherichia coli.

Nitroxide-labeled thymidine substrates (dL) for Escherichia coli DNA polymerase I (pol I) were used to synthesize spin-labeled alternating double-stranded copolymers with (dA-dT)n as a template. All dL substrates use an alkane or alkene tether substituted into the 5-position of the pyrimidine ring to link a five- or six-membered ring nitroxide to the pyrimidine base. The kinetics of dL incorporation show some tether dependence with respect to tether length and tether geometry. The electron spin resonance (ESR) spectra of (dA-dT,dL)n duplexes directly formed by polymerization with pol I are compared with the ESR spectra of (dA)n(dT,dL)n duplexes, which are obtained after annealing of nitroxide-labeled single strands with complementary unlabeled single strands. The ESR spectra indicate that nitroxide-labeled analogues with tethers short enough to let the nitroxide ring reside in the major groove are excellent reporter groups for monitoring hybridization. A small difference between the ESR line shapes of the alternating duplexes (dA-dT,dL)n and the homopolymer duplexes (dA)n(dT,dL)n containing the same dL is detectable, suggesting the presence of subtle differences in the base dynamics between both systems. Computer simulation of the ESR spectra of the (dA-dT,dL)n duplexes was successful with the same motional model reported earlier [Kao, S.-C., & Bobst, A.M. (1985) Biochemistry 24, 5465-5469]. The thymidine motion arising from tilting and torsion of base pairs and base twisting in (dA-dT)n is similar to that in (dA)n(dT)n and is of the order of 4 ns.

The relative rate of synthesis and levels of single-stranded DNA binding protein during induction of SOS repair in Escherichia coli.

Induction of the SOS response in Escherichia coli results in an increase in the relative rate of synthesis of single-stranded DNA binding protein (SSB). In contrast to RecA protein, this increase is slow and does not lead to higher SSB levels. The significance of ssb induction to SOS repair is discussed.