A four-way junction with triple-helical arms: design, characterization, and stability

The formation of the four-way junction containing four triple-helical arms has been demonstrated using chemical methods (polyacrylamide gel electrophoresis and chemical footprinting using OsO(4) as a probe) and physical methods (UV absorbance melting and DSC). The junction J(T1T3) was assembled from two 20-mer purine strands and two 44-mer pyrimidine strands. To determine the contribution of the different arms to the stability of the complete structure of J(T1T3), the junction was compared to two simplified substructures, J(T1) and J(T3), respectively. Common to these complexes is the underlying double-helical four-way junction Js. Addition of Na(+) had a profound effect on stabilizing and subsequently folding the junctions into the stacked X-structures. The following results support the structure present: (i) The native polyacrylamide electrophoresis exhibits only a single band(s) corresponding to one species present when all four single strands are mixed in equal amounts. (ii) OsO(4) modifications were investigated at pH 5.0 and in the presence of 10 mM Mg(2+) and 100 mM Na(+). There is no cleavage of thymine residues at the branch point and throughout the structure. (iii) The thermal unfolding of J(T1) and J(T3) illustrates that the triple-helical arms are more stable than the double-helical arms which are contained in these junctions and that J(T1T3) with four triple-helical arms is slightly more stable than J(T1) and J(T3). (iv) The calorimetric transition enthalpies determined for the arms of J(T1T3) are comparable to those associated with the unfolding of its corresponding arms in J(T1) and J(T3). The results also illustrate that the formation of the junctions is not restricted by the pH, [Na(+)], sequence composition of the arms, and/or the loop position.     

Thermodynamic properties of an intramolecular DNA four-way junction

We have investigated the thermodynamic properties of two homologous DNA four-way junctions, J4 and J4M, based on 46-mer linear DNA molecules. J4 and J4M have the same base sequence with the only difference that the latter contains an uncharged methylene-acetal linkage, -O3'-CH2-O5', instead of the phosphodiester linkage, -O3'-PO2-O5'-, between the residues T18 and C19. The comparison of the thermal unfolding of the J4 junction and J4M junction serves to investigate the effect of the uncharged methylene-acetal linkage on the stability of the junction. Our analysis is based on CD, UV absorbance spectroscopy, DSC, and chemical footprinting. The aim is to characterize in detail the structure and stability of the junctions. As demonstrated before by NMR, in the presence of 5 mM MgCl2 +/- 50 mM NaCl, both J4 and J4M form a complete four-way junction. This is now evidenced by protection from OsO4 cleavage (chemical footprinting). We can assume that full base pairing occurs throughout the arms even at the center of the junction. CD spectra suggest that the helices within the junctions adopt the regular B-DNA conformation. Almost identical melting temperatures and unfolding enthalpies are obtained for J4 and J4M both by UV and DSC. Furthermore, the Van't Hoff enthalpy (DeltaHVH) derived from UV melting equals the calorimetric enthalpy (DeltaHcal), which means that the melting process of the structures proceeds in a two-state manner. All results taken together support the conclusion that there are no major conformational and energetic differences between J4 and J4M. The inclusion of the uncharged methylene-acetal group into the junction has no effect on its stability.     

The melting behavior of a DNA junction structure: a calorimetric and spectroscopic study

We present an investigation of the helix–coil transition in a stable branched oligomer of DNA, known as an immobile DNA junction. This junction is composed of four 16-mer strands, which yield four double-helical arms, each containing 8 nucleotide pairs. Properties of the individual arms of this complex are modeled by four octameric duplexes. We have performed experiments using calorimetry, uv absorbance, and CD spectroscopy to characterize the melting transitions of the junction and each arm. By comparing our spectroscopic and calorimetric results on the junction and its component arms, we are able to conclude the following: (1) The calorimetric transition enthalpy for the overall junction complex is equal to the sum of the calorimetric transition enthalpies of the four constituent duplex arms. (2) The optical and the calorimetric measurements yield qualitatively similar, but not identical thermodynamic data. (3) The melting temperature of the junction is less dependent on concentration than the melting temperatures of the individual arms. We attribute this observation to the tetrameric nature of the junction. (4) The ratio of the calorimetric transition enthalpy of the junction and its corresponding van't Hoff value is close to unity. (5) The CD spectrum of the junction is equal quantitatively to the sum of the B-like CD spectra of the four constituent duplex arms.     

Resolution of Holliday junction analogs by T4 endonuclease VII can be directed by substrate structure

Endonuclease VII is an enzyme from bacteriophage T4 capable of resolving four-arm Holliday junction intermediates in recombination. Since natural Holliday junctions have homologous (2-fold) sequence symmetry, they can branch migrate, creating a population of substrates that have the branch point at different sites. We have explored the substrate requirements of endonuclease VII by using immobile analogs of Holliday junctions that lack this homology, thereby situating the branch point at a fixed site in the molecule. We have found that immobile junctions whose double-helical arms contain fewer than nine nucleotide pairs do not serve as substrates for resolution by endonuclease VII. Scission of substrates with 2-fold symmetrically elongated arms produces resolution products that are a function of the particular arms that are lengthened. We have confirmed that the scission products are those of resolution, rather than nicking of individual strands, by using shamrock junction molecules formed from a single oligonucleotide strand. A combination of end-labeled and internally labeled shamrock molecules has been used to demonstrate that all of the scission is due to coordinated cleavage of DNA on opposite sides of the junction, 3' to the branch point. Endonuclease VII is known to cleave the crossover strands of Holliday junctions in this fashion. The relationship of the long arms to the cleavage direction suggests that the portion of the enzyme which requires the minimum arm length interacts with the pair of arms containing the 3' portion of the crossover strands on the bound surface of the antiparallel junction.     

Ferrocene-assisted stabilization of collagen mimetic triple helices: solid-phase synthesis and structure

A series of ferrocene-containing collagen models Fc-CO-(Pro-Hyp-Gly)n-Cys (n = 4 (1), 6 (2), 7 (3), 8 (4), 9 (5)) were synthesized by solid-phase synthesis. Biophysical studies using circular dichroism (CD) show that these collagen analogues form triple-helical conformations, and the peptides showed a range of thermal stabilities ((T(m)), 38-74 degrees C). Results also indicate that the ferrocene (Fc)-labeled collagen models possesses a higher triple-helical propensity than the unlabeled collagen models as demonstrated by the higher melting temperatures and thermodynamic parameters, and we conclude that the Fc group at the N-terminal position of the peptide strands increases the stability of the triple helix.     

The folding of the hairpin ribozyme: dependence on the loops and the junction

In its natural context, the hairpin ribozyme is constructed around a four-way helical junction. This presents the two loops that interact to form the active site on adjacent arms, requiring rotation into an antiparallel structure to bring them into proximity. In the present study we have compared the folding of this form of the ribozyme and subspecies lacking either the loops or the helical junction using fluorescence resonance energy transfer. The complete ribozyme as a four-way junction folds into an antiparallel structure by the cooperative binding of magnesium ions, requiring 20-40 microM for half-maximal extent of folding ([Mg2+]1/2) and a Hill coefficient n = 2. The isolated junction (lacking the loops) also folds into a corresponding antiparallel structure, but does so noncooperatively (n = 1) at a higher magnesium ion concentration ([Mg2+]1/2 = 3 mM). Introduction of a G + 1A mutation into loop A of the ribozyme results in a species with very similar folding to the simple junction, and complete loss of ribozyme activity. Removal of the junction from the ribozyme, replacing it either with a strand break (serving as a hinge) or a GC5 bulge, results in greatly impaired folding, with [Mg2+]1/2 > 20 mM. The results indicate that the natural form of the ribozyme undergoes ion-induced folding by the cooperative formation of an antiparallel junction and loop-loop interaction to generate the active form of the ribozyme. The four-way junction thus provides a scaffold in the natural RNA that facilitates the folding of the ribozyme into the active form.     

Construction of a DNA four-way junction: Design and NMR spectroscopy

In 1964 Holliday postulated the formation of cruciform structures (four-way junctions) in duplex DNA as intermediate in genetic recombination. Since then, many biochemical and biophysical investigations were directed at solving questions concerning structural details of stable four-way junctions. Thus far, NMR spectroscopy played a minor part in these investigations on account of the minimum size of the molecule (expressed as the number of nucleotide residues) that was thought necessary to produce a stable cruciform structure. Indeed, the smallest four-way junction studied thus far by NMR methods was built from four separate DNA strands, each containing 16 nucleotides, a total of 64. Obviously, with such a large structure one runs into assignment problems. We considered the possibility of constructing a stable four-way junction from a single strand of DNA. The underlying idea was to make use of our detailed knowledge of the building principles of stable minihairpin loops. These loops, containing only two nucleotides to bridge the gap between antiparallel strands, are maximally stable in DNA sequences like 5-d(-C-TT-G-), where C and G form a normal Watson-Crick base pair and the two T residues cross the minor groove to form the minihairpin loop. Three of such miniloops could in principle cap three arms of the cruciform. The fourth arm would have an open end. The problem to be solved is to find the minimum length that is required to insure stability of the three closed arms and of the fourth open arm. We were successful with a structure that has three short stems (four base pairs each) and an open-end stem consisting of eight base pairs, a total of 46 residues. NMR experiments, carried out on this molecule in the presence of Mg²⁺, showed details of folding which have never been observed before.     

Studies of DNA dumbbells. II. Construction and characterization of DNA dumbbells with a 16 base-pair duplex stem and Tn end loops (n = 2, 3, 4, 6, 8, 10, 14).

The preparation and characterization of DNA dumbbells that contain the 16 base-pair duplex sequences 5'G-C-A-T-A-G-A-T-G-A-G-A-A-T-G-C3' (set 1) and 5'G-C-A-T-C-A-T-C-G-A-T-G-A-T-G-C3' (set 2) are reported. The dumbbells of set 1 have the duplex stem nucleated on both ends by Tn (n = 2, 3, 4, 6, 8, 10, and 14) loops. The dumbbells of set 2 have Tn (n = 2, 4, 8, 10) end loops. For the molecules of set 1, effects of end loop size on the electrophoretic mobility, CD and UV absorbance spectra, and cleavage by restriction enzymes, were investigated. Effects of loop size on the CD spectra and restriction enzyme cleavage of the molecules of set 2 were also examined. Optical melting curves of the molecules of set 1 were collected as a function of sodium ion concentration from 30 to 120 mM. These investigations revealed that as loop size decreases, the electrophoretic mobilities, rates of enzyme cleavage, and optical melting temperatures increase. For end loops with at least three T's the observed increases are inversely proportional to loop size. The behavior of the dumbbell with T2 end loops departs from this linear dependence and is anomalous in every experimental context. For molecules with end loops comprised of at least four T's CD spectra were virtually indistinguishable. However, these spectra differed considerably from the CD spectrum of the T2-looped molecule. The CD spectrum of the dumbbell with T3 end loops displayed features common to the dumbbells with larger loops and T2 end loops. Thermodynamic evidence that the terminal G.C base pairs (bps) nucleating the T2 end loops were intact was obtained from a comparison of the melting temperature of this molecule with that of a DNA dumbbell containing the 14 central bps of the set 1 duplex sequence linked instead by end loops comprised of the four base sequence, C-T-T-C. The tm of this latter molecule was determined to be 9 degrees C less than that of the former dumbbell assumed to contain a 16-bp stem and T2 end loops.(ABSTRACT TRUNCATED AT 400 WORDS)     

The solution structure of the four-way DNA junction at low-salt conditions: a fluorescence resonance energy transfer analysis.

The four-way DNA (Holliday) junction is an important postulated intermediate in the process of genetic recombination. Earlier studies have suggested that the junction exists in two alternative conformations, depending upon the salt concentration present. At high salt concentrations the junction folds into a stacked X structure, while at low salt concentrations the data indicate an extended unstacked conformation. The stereochemical conformation of the four-way DNA junction at low salt (low alkali ion concentration and no alkaline earth ions) was established by comparing the efficiency of fluorescence resonance energy transfer (FRET) between donor and acceptor molecules attached pairwise in three permutations to the 5' termini of the duplex arms. A new variation of FRET was implemented based upon a systematic variation of the fraction of donor labeled single strands. The FRET results indicate that the structure of the four-way DNA junction at low salt exists as an unstacked, extended, square arrangement of the four duplex arms. The donor titration measurements made in the presence of magnesium ions clearly show the folding of the junction into the X stacked structure. In addition, the FRET efficiency can be measured. The fluorescence anisotropy of the acceptor in the presence of Mg2+ during donor titrations was also measured; the FRET efficiency can be calculated from the anisotropy data and the results are consistent with the folded, stacked X structure.     

Relative stabilities of DNA three-way, four-way and five-way junctions (multi-helix junction loops): unpaired nucleotides can be stabilizing or destabilizing.

Competition binding and UV melting studies of a DNA model system consisting of three, four or five mutually complementary oligonucleotides demonstrate that unpaired bases at the branch point stabilize three- and five-way junction loops but destabilize four-way junctions. The inclusion of unpaired nucleotides permits the assembly of five-way DNA junction complexes (5WJ) having as few as seven basepairs per arm from five mutually complementary oligonucleotides. Previous work showed that 5WJ, having eight basepairs per arm but lacking unpaired bases, could not be assembled [Wang, Y.L., Mueller, J.E., Kemper, B. and Seeman, N.C. (1991) Biochemistry, 30, 5667-5674]. Competition binding experiments demonstrate that four-way junctions (4WJ) are more stable than three-way junctions (3WJ), when no unpaired bases are included at the branch point, but less stable when unpaired bases are present at the junction. 5WJ complexes are in all cases less stable than 4WJ or 3WJ complexes. UV melting curves confirm the relative stabilities of these junctions. These results provide qualitative guidelines for improving the way in which multi-helix junction loops are handled in secondary structure prediction programs, especially for single-stranded nucleic acids having primary sequences that can form alternative structures comprising different types of junctions.     

The construction of a trefoil knot from a DNA branched junction motif

A DNA trefoil (3₁) knot has been constructed from a 104-nucleotide molecule whose strands form a 3-arm branched junction motif. This construction tests the notion that a node in a DNA knot can be equated with a half-turn of double-helical DNA, and is consistent with that concept. Of five 104-mer sequences tested, only one produces high yields of the target knot. The other molecules produce larger quantities of circular material and of a knot containing more nodes. The key features that differentiate the successful design from the others are (1) the ligation takes place in the linker region between helical domains and (2) only six nucleotide pairs are used for each of the double-helical arms of the junction. The successful design separates the double-helical regions from each other by a spacer containing two deoxythymidine nucleotides at the site of the branched junction. © 1994 John Wiley & Sons, Inc.     

Fluorescence resonance energy transfer analysis of the structure of the four-way DNA junction.

We have carried out fluorescence resonance energy transfer (FRET) measurements on four-way DNA junctions in order to analyze the global structure and its dependence on the concentration of several types of ions. A knowledge of the structure and its sensitivity to the solution environment is important for a full understanding of recombination events in DNA. The stereochemical arrangement of the four DNA helices that make up the four-way junction was established by a global comparison of the efficiency of FRET between donor and acceptor molecules attached pairwise in all possible permutations to the 5' termini of the duplex arms of the four-way structure. The conclusions are based upon a comparison between a series of many identical DNA molecules which have been labeled on different positions, rather than a determination of a few absolute distances. Details of the FRET analysis are presented; features of the analysis with particular relevance to DNA structures are emphasized. Three methods were employed to determine the efficiency of FRET: (1) enhancement of the acceptor fluorescence, (2) decrease of the donor quantum yield, and (3) shortening of the donor fluorescence lifetime. The FRET results indicate that the arms of the four-way junction are arranged in an antiparallel stacked X-structure when salt is added to the solution. The ion-related conformational change upon addition of salt to a solution originally at low ionic strength progresses in a continuous noncooperative manner as the ionic strength of the solution increases. The mode of ion interaction at the strand exchange site of the junction is discussed.     

Quantitation of metal ion and DNA junction binding to the Holliday junction endonuclease Cce1

Cce1 is a magnesium-dependent Holliday junction endonuclease involved in the resolution of recombining mitochondrial DNA in Saccharomyces cerevisiae. Cce1 binds four-way DNA junctions as a dimer, opening the junction into an extended, 4-fold symmetric structure, and resolves junctions by the introduction of paired nicks in opposing strands at the point of strand exchange. In the present study, we have examined the interactions of wild-type Cce1 with a noncleavable four-way DNA junction and metal ions (Mg(2+) and Mn(2+)) using isothermal titration calorimetry, EPR, and gel electrophoresis techniques. Mg(2+) or Mn(2+) ions bind to Cce1 in the absence of DNA junctions with a stoichiometry of two metal ions per Cce1 monomer. Cce1 binds to four-way junctions with a stoichiometry of two Cce1 dimers per junction molecule in the presence of EDTA, and one dimer of Cce1 per junction in 15 mM magnesium. The presence of 15 mM Mg(2+) dramatically reduces the affinity of Cce1 for four-way DNA junctions, by about 900-fold. This allows an estimation of DeltaG degrees for stacking of four-way DNA junction 7 of -4.1 kcal/mol, consistent with the estimate of -3.3 to -4.5 kcal/mol calculated from branch migration and NMR experiments [Overmars and Altona (1997) J. Mol. Biol. 273, 519-524; Panyutin et al. (1995) EMBO J. 14, 1819-1826]. The striking effect of magnesium ions on the affinity of Cce1 binding to the four-way junction is predicted to be a general one for proteins that unfold the stacked X-structure of the Holliday junction on binding.     

Helical junctions as determinants for RNA folding: origin of tertiary structure stability of the hairpin ribozyme

Helical junctions are ubiquitous structural elements that govern the folding and tertiary structure of RNAs. The tobacco ringspot virus hairpin ribozyme consists of two helix-loop-helix elements that lie on adjacent arms of a four-way junction. In the active form of the hairpin ribozyme, the loops are in proximity. The nature of the helical junction determines the stability of the hairpin ribozyme tertiary structure [Walter, N. G., Burke, J. M., and Millar, D. P. (1999) Nat. Struct. Biol. 6, 544-549] and thus its catalytic activity. We used two-, three-, and four-way junction hairpin ribozymes as model systems to investigate the thermodynamic basis for the different tertiary structure stabilities. The equilibrium between docked and extended conformers was analyzed as a function of temperature using time-resolved fluorescence resonance energy transfer (trFRET). As the secondary and tertiary structure transitions overlap, information from UV melting curves and trFRET had to be combined to gain insight into the thermodynamics of both structural transitions. It turned out that the higher tertiary structure stability observed in the context of a four-way junction is the result of a lower entropic cost for the docking process. In the two- and three-way junction ribozymes, a high entropic cost counteracts the favorable enthalpic term, rendering the docked conformer only marginally stable. Thus, two- and three-way junction tertiary structures are more sensitive toward regulation by ligands, whereas four-way junctions provide a stable scaffold. Altogether, RNA folding and stability appear to be governed by principles similar to those for the folding of proteins.     

Structural recognition between a four-way DNA junction and a resolving enzyme

Resolving enzymes bind highly selectively to four-way DNA junctions, but the mechanism of this structural specificity is poorly understood. In this study, we have explored the role of interactions between the dimeric enzyme and the helical arms of the junction, using junctions with either shortened arms, or circular permutation of arms. We find that DNA-protein contacts in the arms containing the 5' ends of the continuous strands are very important, conferring a significant level of sequence discrimination upon both the choice of conformer and the order of strand cleavage. We have exploited these properties to obtain hydroxyl radical footprinting data on endonuclease I-junction complexes that are not complicated by the presence of alternative conformers, with results that are in good agreement with the arm permutation and shortening experiments. Substitution of phosphate groups at the center of the junction reveals the importance of electrostatic interactions at the point of strand exchange in the complex. Our data show that the form of the complex between endonuclease I and a DNA junction depends on the core of the junction and on interactions with the first six base-pairs of the arms containing the 5' ends of the continuous strands.     

Triple helices containing arabinonucleotides in the third (Hoogsteen) strand: effects of inverted stereochemistry at the 2'-position of the sugar moiety.

Arabinonucleic acid, the 2'-stereoisomer of RNA, was tested for its ability to recognize double-helical DNA, double-helical RNA and RNA-DNA hybrids. A pyrimidine oligoarabinonucleotide (ANA) was shown to form triple-helical complexes only with duplex DNA and hybrid DNA (Pu):RNA (Py) with an affinity that was slightly lower relative to the corresponding pyrimidine oligodeoxynucleotide (DNA) third strand. Neither the ANA nor DNA third strands were able to bind to duplex RNA or hybrid RNA (Pu):DNA (Py). In contrast, an RNA third strand recognized all four possible duplexes (DD, DR, RD and RR), as previously demonstrated. Such an understanding can be applied to the design of sequence-selective oligonucleotides which interact with double-stranded nucleic acids and emphasizes the role of the 2'-OH group as a general recognition and binding determinant of RNA.     

Flanking sequence effects within the pyrimidine triple-helix motif characterized by affinity cleaving.

Nearest neighbor interactions affect the stabilities of triple-helical complexes. Within a pyrimidine triple-helical motif, the relative stabilities of natural base triplets T.AT, C + GC, and G.TA, as well as triplets, D3.TA and D3.CG, containing the nonnatural deoxyribonucleoside 1-(2-deoxy-beta-D-ribofuranosyl)-4-(3-benzamido)phenylimidazole (D3) were characterized by the affinity cleaving method in the context of different flanking triplets (T.AT, T.AT: T.AT, C + GC: C + GC, T.AT: G + GC, C + GC). The to be insensitive to substitutions in either the 3' or 5' directions, while the relative stabilities of triple helices containing C + GC triplets decreased as the number of adjacent C + GC triplets increased. Triple helices incorporating a G.TA interaction were most stable when this triplet was flanked by two T.AT triplets and were adversely affected when a C + GC triplet was placed in the adjacent 5' direction. Similarly, complexes containing D3.TA or D3.CG triplets were most stable when the triplet was flanked by two T.AT triplets but were destabilized when the adjacent 3' neighbor position was occupied with a C + GC triplet. This information regarding sequence composition effects in triple-helix formation establishes a set of guidelines for targeting sequences of double-helical DNA by the pyrimidine triple-helix motif.     

Cruciform cutting endonucleases from Saccharomyces cerevisiae and phage T4 show conserved reactions with branched DNAs.

We have purified a cruciform DNA resolving endonuclease (Endo X3) greater than 1000-fold from crude extracts of mitotically growing Saccharomyces cerevisiae. The enzyme shows high specificity for DNAs with secondary structures and introduces characteristic patterns of staggered 'nicks' in the immediate vicinity of the structure. The following substrates were analyzed in detail: (i) naturally occurring four-way X junctions in cruciform DNA of a supercoiled plasmid; (ii) synthetic four-way X junctions with arms of 9 bp; (iii) synthetic three-way Y junctions with arms of 10 bp; and (iv) heteroduplex loops with 19 nucleotides in the loop. Cleavages were always found in the double stranded portion of the DNA, located immediately adjacent to the junction of the respective structure. The Endo X3 induced cleavage patterns are identical or very similar to the cleavage patterns induced in the same substrates by endonuclease VII (Endo VII) from phage T4. Furthermore, the activity of Endo X3 is completely inhibited in the presence of anti-Endo VII antiserum. Endo X3 has an apparent mol. wt of 43,000 daltons, determined by gel filtration and of approximately 18,000 daltons in SDS--polyacrylamide gels. Maximum activity of the enzyme was obtained in the presence of 10 mM MgCl2 at 31 degrees C in Tris-HCl buffer over a broad pH range with a maximum approximately 8.0. About 70% of maximal activity was obtained when Mg2+ was replaced by equimolar amounts of Mn2+ or Ca2+.     

Endonuclease VII resolves Y-junctions in branched DNA in vitro.

Endonuclease VII (gp 49 of phage T4) resolves four-way junctions in branched DNAs. We have extended our investigations of the specificity of endo VII and tested its activity with three-way junctions (Y-structures) constructed in vitro. Both 'closed' and 'open' Y-structures were made, absolutely identical in sequence but differing from each other by a single nick in one of the three arms. Pure Y-structures were obtained on a preparative scale by annealing plus and minus strands from two M13mp strains. One strain has an inverted repeat of 2 X 31 nucleotides cloned into the single EcoRI site while in the other strain this repeat is absent. The structures were used in reactions with endo VII, which recognizes the branch point of both structures and introduces a characteristic number of nicks, 3' to the junction in each arm of the structure. Strong and weak sites could be distinguished and the cleavage pattern differed significantly between the two structures. The observed resolution of Y-junctions by endo VII in vitro is compatible with a model for the resolution of recombinant Y-branches in DNA.     

Conformational preference and ligand binding properties of DNA junctions are determined by sequence at the branch

Four-arm DNA branched junctions are stable analogues of Holliday recombinational intermediates. A number of four-arm DNA junctions synthesized from oligonucleotides have now been studied. Gel mobility or chemical footprinting experiments on several immobile four-arm junctions indicate that in the presence of Mg2+, they assume a preferred conformation consisting of two helical domains, each formed by stacking a particular pair of arms on each other. We show here that a junction we designate as J1c that has the same chemical composition as one we have previously studied in detail, J1, but is formed from the four strands complementary to those of the latter, exhibits the reverse stacking preference. The pattern of self-protection of the strands of J1c exposed to Fe(II).EDTA-induced scission reveals that twofold symmetry is preserved, but the opposite pair of strands preferentially cross over. Moreover, the Fe(II).EDTA scission profiles of J1c indicate that this junction exhibits a weaker bias as to which strands cross over than is observed in J1. The preference for the dominant species in J1 is 1.3 times greater than in J1c at 4 degrees C and in the presence of 10 mM Mg2+, based on chemical reactivity data. This is confirmed by a cleavage experiment using the resolvase enzyme, endonuclease I, from bacteriophage T7. This difference could reflect either sequence-dependent differences in the equilibrium among isomers, or in the structure of these junctions. Chemical footprinting experiments using the probes MPE.Fe(II) and (OP)2Cu(I) show that the high-affinity ligand binding site in immobile junctions is determined by junction geometry.