Characterisation of an in vivo system for nicking at the origin of conjugal DNA transfer of the sex factor F

Transfer of the F plasmid between conjugating Escherichia coli cells has been assumed to require endonucleolytic cleavage at a specific site (oriT) on a specific strand of the F molecule. Using a lambda transducing phage which contains oriT we have detected this nicking process in vivo. Nicking of DNA occurred in the strand that included the “transferred” F strand and at a location within the transducing segment consistent with all previous genetic and restriction enzyme cleavage data on the position of oriT in F. Genetic study of the nicking process using Flac tra^? point and deletion mutants, and also λtra phages which carried various parts of the transfer region, indicated that the products of two transfer operon genes, traY and the previously unidentified gene traZ, were directly involved in nicking at oriT. The product of traJ was also required for nicking, but the possibility that this was solely due to the regulatory function of the traJ product could not be excluded. The plasmid specificities of oriT, traY and traZ between F and the related F-like plasmids R1-19 and R100-1 were investigated using the λoriT nicking system, and shown to be consistent with those determined in genetic complementation tests. The differences in specificity observed imply that the oriT sequence of F differs from those of R1-19 and R100-1.The products of the traM and traI genes are known to be required for the initiation of DNA transfer; their possible roles in modulating the activity of the traY Z endonuclease are discussed.     

Processes at the nick region link conjugation, T-DNA transfer and rolling circle replication

Data from prokaryotic replicative and conjugative systems, which interrelate DNA processing events initiated by a site-specific nick, are reviewed. While the replicative systems have been established in accordance with the rolling circle replication model, the mechanism of conjugative replication has not been elucidated experimentally. We summarize data involving random point mutagenesis of the RK2 transfer origin (oriT), which yielded relaxation-deficient and transfer-deficient derivatives having mutations exclusively in a 10bp region defined as the nick region. Features of the RK2 (IncP) nick region, including the DNA sequence, nick site position, and 5′ covalent attachment of the nicking protein, have striking parallels in other systems involving nicking and mobilization of single-stranded DNA from a supercoiled substrate. These other systems include T-DNA transfer occurring in Agrobacterium tumefaciens Ti plasmid-mediated tumorigenesis in plants, and the rolling circle replication of plasmids of Gram-positive bacteria and of φX174-like bacteriophage. The structural and functional similarities suggest that IncP conjugative replication, originating at the oriT, and T-DNA transfer replication, originating at the T-DNA border, produce continuous strands via a rolling circle-type replication.     

Initiation and termination of DNA transfer at F plasmid oriT

DNA sequences within the F plasmid transfer origin (oriT) were tested for their ability to initiate or terminate conjugal transfer. Mutant and wild-type oriT elements were cloned as direct repetitions flanking the rpsL gene on a pBR322-based plasmid, and the frequency of deletion of this segment during matings sponsored by F’lac (F42) with streptomycin-resistant recipients was measured. Shortened oriT elements that lacked adjacent TraM-binding sites allowed efficient initiation and termination. Some truncated orir segments lacking the TraM-binding sites and the TraY-binding site, sbyA, initiated transfer inefficiently, but nevertheless promoted efficient termination. Removal of TraM-, TraY-, and IHF-binding sites severely reduced both nicking and termination. Point mutations that previously had been reported to prevent nicking caused reduced levels of both initiation and termination. These results indicate that regions of oriT supporting initiation are more extensive than those needed for termination, although some regions are required for both. Moreover, termination can be effective for some mutant loci that do not support efficient nicking.     

Role of DNA minor groove interactions in substrate recognition by the M.SinI and M.EcoRII DNA (cytosine-5) methyltransferases

The SinI and EcoRII DNA methyltransferases recognize sequences (GG^A/_TCC and CC^A/_TGG, respectively), which are characterized by an ^A/_T ambiguity. Recognition of the A·T and T·A base pair was studied by in vitro methyltransferase assays using oligonucleotide substrates containing a hypoxanthine·C base pair in the central position of the recognition sequence. Both enzymes methylated the substituted oligonucleotide with an efficiency that was comparable to methylation of the canonical substrate. These observations indicate that M.SinI and M.EcoRII discriminate between their canonical recognition site and the site containing a G·C or a C·G base pair in the center of the recognition sequence (GG^G/_CCC and CC^G/_CGG, respectively) by interaction(s) in the DNA minor groove. M.SinI mutants displaying a decreased capacity to discriminate between the GG^A/_TCC and GG^G/_CCC sequences were isolated by random mutagenesis and selection for the relaxed specificity phenotype. These mutations led to amino acid substitutions outside the variable region, previously thought to be the sole determinant of sequence specificity. These observations indicate that ^A/_T versus ^G/_C discrimination is mediated by interactions between the large domain of the methyltransferase and the minor groove surface of the DNA.     

tra cistrons and proteins encoded by the Escherichia coli antibiotic resistance plasmid R6-5

Summary Hybrid plasmids obtained by cloning individual EcoRI and HindIII fragments of the conjugative plasmid, R6-5, were analyzed for their ability to complement transfer-deficient point mutations of Flac. As a result, the locations of 10 tra cistrons were defined on the physical map of R6-5. Two cistrons, traE and traG, are interrupted by EcoRI restriction sites and one cistron, traC, probably contains a HindIII restriction site. The origin of DNA transfer, oriT, was also localized. Surprisingly the hybrid plasmid carrying oriT is mobilized by the F factor as well as by R6-5. The surface exclusion cistrons, traS and traT, were mapped and their biological expression analyzed. A total of 18 proteins encoded by cistrons within the tra region were detected by SDS polyacrylamide gel electrophoresis of proteins synthesized in minicells; they represent about 53% of the coding capacity of the cloned DNA. R6-5 DNA fragments containing the cistrons traC, traE, and traT directed the synthesis of proteins which comigrated during SDS gel electrophoresis with the F-coded proteins previously characterized as TraCp, TraEp, and TraTp. A further two proteins encoded by R6-5 comigrated with F-encoded (but genetically unidentified) proteins whose cistrons map in the corresponding part of the tra region. In contrast, no R6-5 proteins corresponding to F proteins TraAp, TraDp, TraJp, TraMp, 6a or 6c were detected. These results are discussed in relation to known DNA sequence homologies between the F and R6-5 plasmids. A preliminary physical map of the tra region of R6-5 is presented and compared with that of F.     

The origin of greater-than-unit-length plasmids generated during bacterial conjugation

In Gram-negative bacteria, the general mechanism of conjugal plasmid transfer, which is probably similar for many different groups of plasmids, involves the transfer of a single plasmid DNA strand with 5′ to 3′ polarity. Transfer is initiated by nicking of the duplex DNA at a particular site, i.e. the origin of transfer (oriT). We constructed plasmids containing two directly repeated copies of oriT, derived from the broad-host-range plasmid R1162 and flanking the lac operator. The number of lacO copies in the plasmid after transfer could be determined from the colour of transconjugant colonies on medium containing X-Gal. When the oriTs were mutated to prevent initiation and termination of transfer at the same oriTs, almost all of the transconjugant cells contained greater-than-unit-length plasmids with two copies of lacO and three copies of oriT. We show that these molecules were generated by an intramolecular, conjugation dependent mechanism unlikely to depend solely on a pre-existing population of circular or linear multimers in donor cells. We propose that the greater-than-unit-length molecules were instead generated by a rolling-circle mechanism of DNA replication.     

Evidence for long-range interactions in DNA. Analysis of melting curves of block polymers d(C15A15)·d(T15G15), d(C20A15)·d(T15G20), and d(C20A10)·d(T10G20)

The influence of one DNA region on the stability of an adjoining region (telestability) was examined. Melting curves of three block DNA's, d(C₁₅A₁₅)·d(T₁₅G₁₅), d(C₂₀A₁₅)·d(T₁₅G₂₀), and d(C₂₀A₁₀)·d(T₁₀G₂₀) were analyzed in terms of the nearest neighbor Ising model. Comparisons of predicted and experimental curves were made in 0.01 M and 0.1 M sodium ion solutions. The nearest neighbor formalism was also employed to analyze block DNA transition in the presence of actinomycin, a G·C specific molecule. The results show that nearest neighbor base-pair interaction cannot predict the melting curves of the block DNA's. Adjustments in theoretical parameters to account for phosphate repulsion assuming a B conformation throughout the DNA's do not alter this conclusion. Changes in the theoretical parameters, which provide good overall agreement, are consistent with a substantial stabilization of the A·T region nearest the G·C block. The melting temperature T A·T for the average A·T pari in d(C₂₀A₁₀)·d(T₁₀G₂₀), with 10 A·T pairs, appears to be 4°C greater than T_A·T for d(C₁₅A₁₅)·d(T₁₅G₁₅) and d(C₂₀A₁₅)·d(T₁₅G₂₀), both with 15 A·T pairs. Actinomycin bound to the G·C end effectively stabilizes the A·T end by 9°C. These results indicate a long-range contribution to the interactions governing DNA stability. A possible mechanism for these interactions will be discussed.     

Selective Preference of Parallel DNA Triplexes Is Due to the Disruption of Hoogsteen Hydrogen Bonds Caused by the Severe Nonisostericity between the G*GC and T*AT Triplets

Implications of DNA, RNA and RNA.DNA hybrid triplexes in diverse biological functions, diseases and therapeutic applications call for a thorough understanding of their structure-function relationships. Despite exhaustive studies mechanistic rationale for the discriminatory preference of parallel DNA triplexes with G_*GC & T_*AT triplets still remains elusive. Here, we show that the highest nonisostericity between the G_*GC & T_*AT triplets imposes extensive stereochemical rearrangements contributing to context dependent triplex destabilisation through selective disruption of Hoogsteen scheme of hydrogen bonds. MD simulations of nineteen DNA triplexes with an assortment of sequence milieu reveal for the first time fresh insights into the nature and extent of destabilization from a single (non-overlapping), double (overlapping) and multiple pairs of nonisosteric base triplets (NIBTs). It is found that a solitary pair of NIBTs, feasible either at a G_*GC/T_*AT or T_*AT/G_*GC triplex junction, does not impinge significantly on triplex stability. But two overlapping pairs of NIBTs resulting from either a T_*AT or a G_*GC interruption disrupt Hoogsteen pair to a noncanonical mismatch destabilizing the triplex by ~10 to 14 kcal/mol, implying that their frequent incidence in multiples, especially, in short sequences could even hinder triplex formation. The results provide (i) an unambiguous and generalised mechanistic rationale for the discriminatory trait of parallel triplexes, including those studied experimentally (ii) clarity for the prevalence of antiparallel triplexes and (iii) comprehensive perspectives on the sequence dependent influence of nonisosteric base triplets useful in the rational design of TFO’s against potential triplex target sites.     

The MobM relaxase domain of plasmid pMV158: thermal stability and activity upon Mn2+ and specific DNA binding

Protein MobM, the relaxase involved in conjugative transfer of the streptococcal plasmid pMV158, is the prototype of the MOB_V superfamily of relaxases. To characterize the DNA-binding and nicking domain of MobM, a truncated version of the protein (MobMN199) encompassing its N-terminal region was designed and the protein was purified. MobMN199 was monomeric in contrast to the dimeric form of the full-length protein, but it kept its nicking activity on pMV158 DNA. The optimal relaxase activity was dependent on Mn²⁺ or Mg²⁺ cations in a dosage-dependent manner. However, whereas Mn²⁺ strongly stabilized MobMN199 against thermal denaturation, no protective effect was observed for Mg²⁺. Furthermore, MobMN199 exhibited a high affinity binding for Mn²⁺ but not for Mg²⁺. We also examined the binding-specificity and affinity of MobMN199 for several substrates of single-stranded DNA encompassing the pMV158 origin of transfer (oriT). The minimal oriT was delimited to a stretch of 26 nt which included an inverted repeat located eight bases upstream of the nick site. The structure of MobMN199 was strongly stabilized by binding to the defined target DNA, indicating the formation of a tight protein–DNA complex. We demonstrate that the oriT recognition by MobMN199 was highly specific and suggest that this protein most probably employs Mn²⁺ during pMV158 transfer.     

Covalent association of the traI gene product of plasmid RP4 with the 5'-terminal nucleotide at the relaxation nick site

Formation of relaxosomes is the first step in the initiation of transfer DNA replication during bacterial conjugation. This nucleoprotein complex contains all components capable of introducing a site- and strand-specific nick at a cognate transfer origin (oriT) on supercoiled plasmid DNA, thus providing the substrate for generation of the strand to be transferred. Characterization of the terminal nucleotides at the oriT nick site revealed that relaxation occurs by hydrolysis of a single phosphodiester bond between a 2'-deoxyguanosyl and a 2'-deoxycytidyl residue. The relaxation nick site and a 19-base pair invert repeat sequence that is recognized by asymmetric binding of the RP4 TraJ protein are interspaced by 8 base pairs. The nicking reaction results in covalent attachment of the RP4 TraI protein to the 5'-terminal 2'-deoxycytidyl residue of the cleaved strand. The arrangement of the TraJ binding site and the relaxation nick site on the same side of the DNA double helix suggests that protein-protein interactions between TraJ and TraI are a prerequisite for oriT specific nicking. In accordance with the current model of transfer DNA replication, the 3' end remains accessible for primer extension by DNA polymerase I, enabling replacement strand synthesis in the donor cell by a rolling circle-type mechanism.     

Determination of stability of the DNA double helix in an aqueous medium

The possibility of determining the free energy of stabilization ΔG₀ of native DNA structure with the help of calorimetric data on heats ΔH of transition from the native to denaturated state is considered. Results of microcalorimetric measurements of heats of denaturation of T₂ phage DNA at, different values of pH and ionic strength of solution are given. Values of free energy of stabilization of the DNA native structure ΔG₀ under various conditions have been obtained. It is shown that under conditions close to physiological ΔG₀ approaches 1200 cal/mole per base pair.     

Defining cosQ, the site required for termination of bacteriophage lambda DNA packaging

Bacteriophage lambda is a double-stranded DNA virus that processes concatemeric DNA into virion chromosomes by cutting at specific recognition sites termed cos. A cos is composed of three subsites: cosN, the nicking site; cosB, required for packaging initiation; and cosQ, required for termination of chromosome packaging. During packaging termination, nicking of the bottom strand of cosN depends on cosQ, suggesting that cosQ is needed to deliver terminase to the bottom strand of cosN to carry out nicking. In the present work, saturation mutagenesis showed that a 7-bp segment comprises cosQ. A proposal that cosQ function requires an optimal sequence match between cosQ and cosNR, the right cosN half-site, was tested by constructing double cosQ mutants; the behavior of the double mutants was inconsistent with the proposal. Substitutions in the 17-bp region between cosQ and cosN resulted in no major defects in chromosome packaging. Insertional mutagenesis indicated that proper spacing between cosQ and cosN is required. The lethality of integral helical insertions eliminated a model in which DNA looping enables cosQ to deliver a gpA protomer for nicking at cosN. The 7 bp of cosQ coincide exactly with the recognition sequence for the Escherichia coli restriction endonuclease, EcoO109I.     

Correlation between percentage guanine-cytosine content and melting temperature of deoxyribonucleic acid

An explicit relation between the percentage (G + C)-content X_GC, and the melting temperature (T_m) of a natural DNA, is derived froma a statistical mechanics calculation with due consideration given to the base pair bonding and stacking interactions. The well-known Marmur-Doty empirical formula, linearly relating these two quantities, can now be understood in terms of the fundamental processes. We also propose a simpler experimental procedure for the determination of X_GC. It is similar to the melting temperature method, but we take only one reading at a prescribed temperature of any natural DNA in addition to the two normalization readings. It should be more sensitive for DNAs having X_GC ranging from 35 to 65%.     

Evolution of I-SceI homing endonucleases with increased DNA recognition site specificity

Elucidating how homing endonucleases undergo changes in recognition site specificity will facilitate efforts to engineer proteins for gene therapy applications. I-SceI is a monomeric homing endonuclease that recognizes and cleaves within an 18-bp target. It tolerates limited degeneracy in its target sequence, including substitution of a C:G₊₄ base pair for the wild-type A:T₊₄ base pair. Libraries encoding randomized amino acids at I-SceI residue positions that contact or are proximal to A:T₊₄ were used in conjunction with a bacterial one-hybrid system to select I-SceI derivatives that bind to recognition sites containing either the A:T₊₄ or the C:G₊₄ base pairs. As expected, isolates encoding wild-type residues at the randomized positions were selected using either target sequence. All I-SceI proteins isolated using the C:G₊₄ recognition site included small side-chain substitutions at G100 and either contained (K86R/G100T, K86R/G100S and K86R/G100C) or lacked (G100A, G100T) a K86R substitution. Interestingly, the binding affinities of the selected variants for the wild-type A:T₊₄ target are 4- to 11-fold lower than that of wild-type I-SceI, whereas those for the C:G₊₄ target are similar. The increased specificity of the mutant proteins is also evident in binding experiments in vivo. These differences in binding affinities account for the observed ∼36-fold difference in target preference between the K86R/G100T and wild-type proteins in DNA cleavage assays. An X-ray crystal structure of the K86R/G100T mutant protein bound to a DNA duplex containing the C:G₊₄ substitution suggests how sequence specificity of a homing enzyme can increase. This biochemical and structural analysis defines one pathway by which site specificity is augmented for a homing endonuclease.     

Evidence for (PNA)2/DNA triplex structure upon binding of PNA to dsDNA by strand displacement

The binding of PNA (peptide nucleic acid) T₂CT₂CT₄-LysNH₂ to the double-stranded DNA target 5′ -A₂GA₂GA₄ was studied by KMnO₄ and dimethylsulfate (DMS) probing. It is found that upon sequence-specific strand displacement binding of the PNA to the dsDNA target concomitant protection of the N-7 of guanines within the target takes place. It is furthermore shown that the binding of this PNA is more efficient at pH 5.5 that at pH 6.5 and very inefficient at pH 7.5. These results clearly indicate that C⁺G Hoogsteen base pairing is present and important for binding and that the strand displacement complex therefore involves a PNA·DNA-PNA triplex.     

Stable secondary structure near the nicking site for adeno-associated virus type 2 Rep proteins on human chromosome 19

Adeno-associated virus serotype 2 (AAV-2) can preferentially integrate its DNA into a 4-kb region of human chromosome 19, designated AAVS1. The nicking activity of AAV-2's Rep68 or Rep78 proteins is essential for preferential integration. These proteins nick at the viral origin of DNA replication and at a similar site within AAVS1. The current nicking model suggests that the strand containing the nicking site is separated from its complementary strand prior to nicking. In AAV serotypes 1 through 6, the nicking site is flanked by a sequence that is predicted to form a stem-loop with standard Watson-Crick base pairing. The region flanking the nicking site in AAVS1 (5'-GGCGGCGGT/TGGGGCTCG-3' [the slash indicates the nicking site]) lacks extensive potential for Watson-Crick base pairing. We therefore performed an empirical search for a stable secondary structure. By comparing the migration of radiolabeled oligonucleotides containing wild-type or mutated sequences from the AAVS1 nicking site to appropriate standards, on native and denaturing polyacrylamide gels, we have found evidence that this region forms a stable secondary structure. Further confirmation was provided by circular dichroism analyses. We identified six bases that appear to be important in forming this putative secondary structure. Mutation of five of these bases, within the context of a double-stranded nicking substrate, reduces the ability of the substrate to be nicked by Rep78 in vitro. Four of these five bases are outside the previously recognized GTTGG nicking site motif and include parts of the CTC motif that has been demonstrated to be important for integration targeting.     

Melting studies of short DNA hairpins: Influence of loop sequence and adjoining base pair identity on hairpin thermodynamic stability

Spectroscopic and calorimetric melting studies of 28 DNA hairpins were performed. These hairpins form by intramolecular folding of 16 base self‐complementary DNA oligomer sequences. Sequence design dictated that the hairpin structures have a six base pair duplex linked by a four base loop and that the first five base pairs in the stem are the same in every molecule. Only loop sequence and identity of the duplex base pair closing the loop vary for the set of hairpins. For these DNA samples, melting studies were carried out to investigate effects of the variables on hairpin stability. Stability of the 28 oligomers was ascertained from their temperature‐induced melting transitions in buffered 115 mM Na⁺ solvent, monitored by ultraviolet absorbance and differential scanning calorimetry (DSC). Experiments revealed the melting temperatures of these molecules range from 32.4 to 60.5°C and are concentration independent over strand concentrations of 0.5 to 260 μM; thus, as expected for hairpins, the melting transitions are apparently unimolecular. Model independent thermodynamic transition parameters, ΔH_cal, ΔS_cal, and ΔG_cal, were determined from DSC measurements. Model dependent transition parameters, ΔH_vH, ΔS_vH, and ΔG_vH were estimated from a van't Hoff (two‐state) analysis of optical melting transitions. Results of these studies reveal a significant sequence dependence to DNA hairpin stability. Thermodynamic parameters evaluated by either procedure reveal the transition enthalpy, ΔH_cal (ΔH_vH) can differ by as much as 20 kcal/mol depending on sequence. Similarly, values of the transition entropy ΔS_cal (ΔS_vH) can differ by as much as 60 cal/Kmol (eu) for different molecules. Differences in free energies ΔG_cal (ΔG_vH) are as large as 4 kcal/mol for hairpins with different sequences. Comparisons between the model independent calorimetric values and the thermodynamic parameters evaluated assuming a two‐state model reveal that 10 of the 28 hairpins display non‐two‐state melting behavior. The database of sequence‐dependent melting free energies obtained for the hairpins was employed to extract a set of n‐n (nearest‐neighbor) sequence dependent loop parameters that were able to reproduce the input data within error (with only two exceptions). Surprisingly, this suggests that the thermodynamic stability of the DNA hairpins can in large part be reasonably represented in terms of sums of appropriate nearest‐neighbor loop sequence parameters. © 1999 John Wiley & Sons, Inc. Biopoly 50: 425–442, 1999     

The Bacteroides fragilis BtgA Mobilization Protein Binds to the oriT Region of pBFTM10

The Bacteroides fragilis conjugal plasmid pBFTM10 contains two genes, btgA and btgB, and a putative oriT region necessary for transfer in Bacteroides fragilis and Escherichia coli. The BtgA protein was predicted to contain a helix-turn-helix motif, indicating possible DNA binding activity. DNA sequence analysis of the region immediately upstream of btgA revealed three sets of inverted repeats, potentially locating the oriT region. A 304-bp DNA fragment comprising this putative oriT region was cloned and confirmed to be the functional pBFTM10 oriT by bacterial conjugation experiments using E. coli and B. fragilis. btgA was cloned and overexpressed in E. coli, and the purified protein was used in electrophoretic mobility shift assays, demonstrating specific binding of BtgA protein to its cognate oriT. DNase I footprint analysis demonstrated that BtgA binds apparently in a single-stranded fashion to the oriT-containing fragment, overlapping inverted repeats I, II, and III and the putative nick site.     

Thermodynamics and kinetics of the helix-coil transition of oligomers containing GC base pairs

Absorbance-temperature profiles have been determined for the following self-complementary oligonucleotides or equimolar paris of complementary oligonucleotides containing GC base pairs: A₂GCU₂, A₃GCU₃, A₄GCU₄, A₆CG + CGU₆, A₈CG + CGU₈, A₄G₂ + C₂U₄, A₅G₂ + C₂U₅, A₄G₃ + C₃U₄, and A₅G₃ + C₃U₅. In all cases cooperative melting transitions indicate double-helix formation. As was found previously, the stability of GC containing oligomer helices is much higher than that of AU helices of corresponding length. Moreover, helices with the same length and base composition but different sequences also have quite different stabilites. The melting curves were andlyzed using a zipper model and the thermodynamic parameters for the AU pairs determined previously. The effect of single-strand stacking was considered separately. According to this model, the formation of a GC pair from unstacked single strands is associated with an ethalpy change of ?15 kcal/mole. Due to the high degree of single-strand stacking at room temperature the enthalpy change for the formation of GC pairs from unstacked single strands is only ?5 to ?6 kcal/mole. (The corresponding parameters for AU pairs are ?10.7 kcal/mole and ?5 to ?6 kcal/mole.) The sequence dependence of helix stability seems to be primarily entropic since no differences in ΔH were seen among the sequence isomers. The kinetics of helix formation was investigated for the same molecules using the temperature jump technique. Recombination of strands is second order with rate constants in the range of 10⁵ to 10⁷M^?1 sec^?1 depending on the chain length and the nucleotide sequence. Within a series of oligomers of a given type, the rates of recombination decrease with increasing chain length. Oligomers with the sequence A_nGCU_n recombine six to eight times slower than the other oligomers of corresponding chain length. The experimental enthalpies of activation of 6 to 9 kcal/mole suggest a nucleation length of one or two GC base pairs. The helix dissociation process has rate constants between 0.5 and 500 sec^?1 and enthalpies of activation of 25 to 50 kcal/mole. An increase of chain length within a given nucleotide series leads to decreased rates of dissociation and increased enthalpies of activation. An investigation of the effect of ionic strength on A_nGCU_n helix formation showed that the rates of recombination increase considerably with increased ionic strength.