Assembly and characterization of five-arm and six-arm DNA branched junctions.

DNA branched junctions have been constructed that contain either five arms or six arms surrounding a branch point. These junctions are not as stable as junctions containing three or four arms; unlike the smaller junctions, they cannot be shown to migrate as a single band on native gels when each of their arms contains eight nucleotide pairs. However, they can be stabilized if their arms contain 16 nucleotide pairs. Ferguson analysis of these junctions in combination with three-arm and four-arm junctions indicates a linear increase in friction constant as the number of arms increases, with the four-arm junction migrating anomalously. The five-arm junction does not appear to have any unusual stacking structure, and all strands show similar responses to hydroxyl radical autofootprinting analysis. By contrast, one strand of the six-arm junction shows virtually no protection from hydroxyl radicals, suggesting that it is the helical strand of a preferred stacking domain. Both junctions are susceptible to digestion by T4 endonuclease VII, which resolves Holliday junctions. However, the putative helical strand of the six-arm junction shows markedly reduced cleavage, supporting the notion that its structure is largely found in a helical conformation. Branched DNA molecules can be assembled into structures whose helix axes form multiply connected objects and networks. The ability to construct five-arm and six-arm junctions vastly increases the number of structures and networks that can be built from branched DNA components. Icosahedral deltahedra and 11 networks with 432 symmetry, constructed from Platonic and Archimedean solids, are among the structures whose construction is feasible, now that these junctions can be made.     

Three-arm nucleic acid junctions are flexible.

Nucleic acid junctions are stable analogs of branched DNA structures which occur transiently in living systems. We show here that junctions which contain three double helical arms can be enzymatically oligomerized, using conventional sticky-ended ligation procedures, to create larger complexes. The products consist of a series of linked junctions separated by 20 base pairs. Junction dimers are formed that have free termini only, whereas trimers and larger species are found to be both unclosed and cyclized. The formation of a series of macrocyclic products which, surprisingly, begins with trimers and tetramers indicates that this junction is flexible about a bending axis, and perhaps twist-wise as well. We have obtained the same results from three different 3-arm junctions, two in which the junction is flanked by a 3 Watson-Crick base pairs, and one in which a G-G base pair flanks the junction.     

Construction and analysis of monomobile DNA junctions

Immobile DNA junctions are complexes of oligomeric DNA strands that interact to yield branched structures in which the branch point cannot migrate. This is achieved by minimizing the sequence symmetry in the flanking arms, so that base pairs lock at the branch site. Here, we report the design, synthesis, and analysis of two semimobile junctions, structures in which a controlled extent of branch point migratory freedom is deliberately introduced. We have constructed two minimally symmetric four-arm semimobile junctions from synthetic deoxy 17-mers. These junctions, termed "monomobile", contain a single pair of base pairs (A-T or C-G) which can migrate at the site of branching, while the rest of the junction is immobile. We have demonstrated by gel electrophoresis techniques that these junctions form and that they have the predicted 1:1:1:1 stoichiometry. We have compared these junctions with the immobile junction on which they are based, by means of hydroxyl radical protection experiments. From these data, both migratory conformers can be seen to coexist in solution. The semimobile junction with the C-G base pair has the same crossover and stacking pattern observed for the immobile junction, while the junction with the A-T base pair has the opposite pattern. We conclude that crossover and stacking patterns are a direct consequence of the base pairs which flank the junction. In addition, the data indicate that the crossover pattern biases for these junctions are much greater than are the migratory biases.     

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.     

Parallel symmetric immobile DNA junctions as substrates for E. coli RuvC Holliday junction resolvase

RuvC is a well-characterized Holliday junction resolvase from E. coli. The presence of symmetry in its preferred recognition sequence leads to ambiguity in the position of the crossover point in the junction, because a symmetric junction can undergo branch migration. Symmetric immobile junctions are junctions that contain such symmetric sites, but are prevented from migrating by their physical characteristics. RuvC activity had been analyzed previously by traditional symmetric immobile junctions, in which the helix axes are held antiparallel in a double-crossover motif. Bowtie junctions are branched four-arm molecules containing 5',5' and 3',3' linkages at their crossover points. A new type of symmetric immobile junction can be made by flanking the crossover point of a Bowtie junction with a symmetric sequence. The junction is immobile because mobility would lead to pairing between parallel, rather than antiparallel, nucleotide pairs. In contrast to conventional Holliday junctions and their analogues, the Bowtie junction assumes a parallel, rather than antiparallel, helical domain conformation, offering a new type of substrate for Holliday junction resolvases. Here, we report the digestion of Bowtie junctions by RuvC. We demonstrate that Bowtie junctions can function as symmetric immobile junctions in this system. We also show that RuvC cleaves antiparallel junctions much more efficiently than parallel junctions, where the protein can bind (and cleave) only one site at a time. These data suggest that the presence of two binding sites leads to communication between the two subunits of the enzyme to increase its activity.     

DNase I cleavage of branched DNA molecules

We report here a potentially useful signature of branched DNA structures. The base 5' to the branch and the five bases flanking the 3' side of the branch site are protected from cleavage by DNase I in both three- and four-arm branched DNA molecules. Our procedure is to measure the cleavage profile for each 5' -labeled strand in a control duplex and compare this with that of the same strand in a branched structure under conditions yielding less than one cut per strand. The resulting cleavage pattern in an immobile four-arm junction is roughly 2-fold symmetric, consistent with the pattern of Fe(II).EDTA-induced cleavage that has been observed previously. In the three-arm junction, the DNase I cleavage pattern is asymmetric, indicating lack of 3-fold symmetry. A variable pattern of protection occurs to the 5' side of the branch in some strands only for both three- and four-arm junctions, extending 2-4 residues 5' to the branch.     

Asymmetric structure of a three-arm DNA junction

We present here experimental evidence that three-arm branched DNA molecules form an asymmetric structure in the presence of Mg2+. Electrophoretic mobility and chemical and enzymatic footprinting experiments on a three-arm branched DNA molecule formed from three 16-mer strands are described. The electrophoretic mobilities of three species of a three-arm junction in which pairs of arms are extended are found to differ in the presence of Mg2+: one combination of elongated arms migrates significantly faster than the other two. This effect is eliminated in the absence of Mg2+, leading us to suggest that the three-arm DNA junction forms an asymmetric structure due to preferential stacking of two of the arms at the junction in the presence of Mg2+. The pattern of self-protection of each 16-mer strand of the core complex exposed to Fe(II).EDTA and DNase I scission is unique, consistent with formation of an asymmetric structure in the presence of Mg2+. We conclude that three-arm junctions resemble four-arm junctions in showing preferential stacking effects at the branch site. Comparison of the scission patterns of linear duplexes and the branched trimer by the reactive probes methidiumpropyl-EDTA.Fe(II) [MPE.Fe(II)] and Cu(I)-[o-phenanthroline]2 [(OP)2CuI] further indicates that the branch point represents a site of enhanced binding for drugs, as it does in the four-arm case. Reaction with diethyl pyrocarbonate (DEPC), a purine-specific probe sensitive to conformation, is enhanced at the branch site, consistent with loosening of base pairing or unpairing at this point.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Determination of the extent of DNA bending by an adenine-thymine tract

We determined the magnitude of the bend induced in DNA by an adenine-thymine tract by measuring the rate of cyclization of DNA oligonucleotides containing phased A tracts. A series of linear multimers with 2-bp single-stranded ends, in which the (A.T)6 tracts are separated by CG2-3C sequences and are positioned 10 and 11 bp apart alternately, were prepared from 21 bp long synthetic duplexed deoxyoligonucleotides. The cyclization rates of the multimers (105-210 bp) and the bimolecular association rate of the 84 bp long multimer were measured in the presence of DNA ligase. From the rate constants of the cyclization and bimolecular association reactions, ring closure probabilities were obtained for the multimers. The systematically bent molecules were simulated by Monte Carlo methods, and the ring closure probabilities were calculated for a given set of junction bend angles. By comparing the calculated values of ring closure probabilities to experimental values and adjusting the junction bend angles to fit experimental values, the extent of bending at the junctions (or the extent of bending for an adenine tract) was determined. We conclude that an A6 tract bends the DNA helix by 17-21 degrees.     

Effect of sequence on the structure of three-arm DNA junctions

We have investigated the geometry of a number of three-arm branched DNA molecules by measuring the relative electrophoretic mobilities of analogues of each junction in which one pair of arms is extended. In general, the mobilities of three species of three-arm junctions in which the duplex arms are extended pairwise differ in the presence of Mg2+. This effect is eliminated by the absence of Mg2+ or by an increase in temperature, leading us to conclude that the three-arm DNA junctions are not 3-fold symmetric, because of either preferential stacking or asymmetric kinking of the arms at the branch that occurs in the presence of Mg2+. The geometry of the junction is governed by the base sequence at the branch and 1 bp removed from the branch. The pairwise elongated analogues of junctions that contain identical base pairs at the branch or 1 bp from the branch show mobility differences; when both positions have the same sequence no mobility differences are detected even in the presence of Mg2+. Formation of a branch in three-arm DNA junctions can be seen to produce a strain or deformation that propagates about one turn of the helix from the branch, leading thymines in this region to become hyperreactive to osmium tetraoxide. Surprisingly, the effect is independent of the presence or absence of metal cations. The structure of the three-arm junction is thus quite different in character from that of four-arm junctions both in the presence and absence of high concentrations of metal cations.     

Resolution of undistorted symmetric immobile DNA junctions by vaccinia topoisomerase I

Holliday junctions are intermediates in genetic recombination. They consist of four strands of DNA that flank a branch point. In natural systems, their sequences have 2-fold (homologous) sequence symmetry. This symmetry enables the molecules to undergo an isomerization, known as branch migration, that relocates the site of the branch point. Branch migration leads to polydispersity, which makes it difficult to characterize the physical properties of the junction and the effects of the sequence context flanking the branch point. Previous studies have reported two symmetric junctions that do not branch migrate: one that is immobilized by coupling to an asymmetric junction in a double crossover context, and a second that is based on molecules containing 5',5' and 3',3' linkages. Both are flawed by distorting the structure of the symmetric junction from its natural conformation. Here, we report an undistorted symmetric immobile junction based on the use of DNA parallelogram structures. We have used a series of these junctions to characterize the junction resolution reaction catalyzed by vaccinia virus DNA topoisomerase. The resolution reaction entails cleavage and rejoining at CCCTT/N recognition sites arrayed on opposing sides of the four-arm junction. We find that resolution is optimal when the scissile phosphodiester (Tp/N) is located two nucleotides 5' to the branch point on the helical strand. Covalent topoisomerase-DNA adducts are precursors to recombinant strands in all reactions, as expected. Kinetic analysis suggests a rate limiting step after the first-strand cleavage.     

NMR analysis of DNA junctions: imino proton NMR studies of individual arms and intact junction

The NMR resonances from the hydrogen-bonded guanine and thymine imino protons of base pairs in the four separate complexes forming the arms of a stable DNA four-arm junction have been assigned by using sequential nuclear Overhauser effects connecting protons in adjacent pairs. Comparison of the spectra of these individual duplex arms with that of the intact four-stranded junction suggests that base pairing occurs at the site of branching. The presence of new resonances in the spectrum of the junction can be inferred from comparison of the junction spectrum with the simulated spectra of the four individual arms. In addition, upfield shifts of the ring protons in the base pairs at the penultimate positions in the complex are observed, consistent with a change in the structure at the site of branching. These studies represent the first stage of a detailed analysis of the structure and dynamics of a DNA junction.     

An archaeal Holliday junction resolving enzyme from Sulfolobus solfataricus exhibits unique properties

The rearrangement and repair of DNA by homologous recombination often involves the creation of Holliday junctions, which must be cleaved by junction-specific endonucleases to yield recombinant duplex DNA products. Holliday junction resolving enzymes are a ubiquitous class of proteins with diverse structural and mechanistic characteristics. We have characterised an endonuclease (Hje) from the thermophilic crenarchaeote Sulfolobus solfataricus that exhibits a high degree of specificity for Holliday junctions via an apparently novel mechanism. Hje resolves four-way DNA junctions by the introduction of paired nicks in a reaction that is independent of the local nucleotide sequence, but is restricted solely to strands that are continuous in the stacked-X form of the junction. Three-way DNA junctions are cleaved only when the presence of a bulge in one strand allows the junction to stack in an analogous manner to four-way junctions. These properties differentiate Hje from all other known junction resolving enzymes.     

Nucleotide sequence analysis of human hypoxanthine phosphoribosyltransferase (HPRT) gene deletions.

We have determined the nucleotide sequences of 10 intragenic human HPRT gene deletion junctions isolated from thioguanine-resistant PSV811 Werner syndrome fibroblasts or from HL60 myeloid leukemia cells. Deletion junctions were located by fine structure blot hybridization mapping and then amplified with flanking oligonucleotide primer pairs for DNA sequence analysis. The junction region sequences from these 10 HPRT mutants contained 13 deletions ranging in size from 57 bp to 19.3 kb. Three DNA inversions of 711, 368, and 20 bp were associated with tandem deletions in two mutants. Each mutant contained the deletion of one or more HPRT exon, thus explaining the thioguanine-resistant cellular phenotype. Deletion junction and donor nucleotide sequence alignments suggest that all of these HPRT gene rearrangements were generated by the nonhomologous recombination of donor DNA duplexes that share little nucleotide sequence identity. This result is surprising, given the potential for homologous recombination between copies of repeated DNA sequences that constitute approximately a third of the human HPRT locus. No difference in deletion structure or complexity was observed between deletions isolated from Werner syndrome or from HL60 mutants. This suggests that the Werner syndrome deletion mutator uses deletion mutagenesis pathway(s) that are similar or identical to those used in other human somatic cells.     

Thermodynamics of DNA branching.

Branched DNA molecules arise transiently as intermediates in genetic recombination or on extrusion of cruciforms from covalent circular DNA duplexes that contain palindromic sequences. The free energy of these structures relative to normal DNA duplexes is of interest both physically and biologically. Oligonucleotide complexes that can form stable branched structures, DNA junctions, have made it possible to model normally unstable branched states of DNA such as Holliday recombinational intermediates. We present here an evaluation of the free energy of creating four-arm branch points in duplex DNA, using a system of two complementary junctions and four DNA duplexes formed from different combinations of the same set of eight 16-mer strands. The thermodynamics of formation of each branched structure from the matching pair of intact duplexes have been estimated in two experiments. In the first, labeled strands are allowed to partition between duplexes and junctions in a competition assay on polyacrylamide gels. In the second, the heats of forming branched or linear molecules from the component strands have been determined by titration microcalorimetry at several temperatures. Taken together these measurements allow us to determine the standard thermodynamic parameters for the process of creating a branch in an otherwise normal DNA duplex. The free energy for reacting two 16-mer duplexes to yield a four-arm junction in which the branch site is incapable of migrating is + 1.1 (+/- 0.4) kcal mol-1 (at 18 degrees C, 10 mM-Mg2+). Analysis of the distribution of duplex and tetramer products by electrophoresis confirms that the free energy difference between the four duplexes and two junctions is small at this temperature. The associated enthalpy change at 18 degrees C is +27.1 (+/- 1.3) kcal mol-1, while the entropy is +89 (+/- 30) cal K-1 mol-1. The free energy for branching is temperature dependent, with a large unfavorable enthalpy change compensated by a favorable entropy term. Since forming one four-stranded complex from two duplexes should be an entropically unfavorable process, branch formation is likely to be accompanied by significant changes in hydration and ion binding. A significant apparent delta Cp is also observed for the formation of one mole of junction, +0.97 (+/-0.05) kcal deg-1 mol-1.     

Construction of three-dimensional stick figures from branched DNA

Stable DNA branched junction molecules can be used as the building blocks for stick-figures in which the edges are double-helical DNA and the vertices correspond to the branch points of the junctions. Sticky-ended cohesion is used to direct the association of individual branched complexes. The sequences of these molecules are assigned by a sequence-symmetry minimization procedure. Successful ligation experiments include the oligomerization of individual three-arm and four-arm junctions, the assembly of a quadrilateral from four junctions with different sticky ends, and the recent construction of a molecule with the connectivity of a cube. Possible applications include the assembly of molecular electronic devices, the formation of macromolecular-scale zeolites to host biological complexes for diffraction analysis, and the development of new catalysts.     

Structure of Three-Way DNA Junctions 1. Non-Planar DNA Geometry

Abstract

Three-way junctions were obtained by annealing two synthetic DNA-oligomers. One of the strands contains a short palindrome sequence, leading to the formation of a hairpin with four base pairs in the stem and four bases in the loop. Another strand is complementary to the linear arms of the first hairpin-containing strand. Both strands were annealed to form a three-way branched structure with sticky ends on the linear arms. The branched molecules were ligated, and the ligation mixture was analysed on a two-dimensional gel in conditions which separated linear and circular molecules. Analysis of 2D-electrophoresis data shows that circular molecules with high mobility are formed. Formation of circular molecules is indicative of bends between linear arms. We estimate the magnitude of the angle between linear arms from the predominant size of the circular molecules formed. When the junction-to-junction distance is 20–21 bp, trimers and tetramers are formed predominately, giving an angle between linear arms as small as 60–90°. Rotation of the hairpin position in the three- way junction allowed us to measure angles between other arms, yielding similar values. These results led us to conclude that the three-way DNA junction possesses a non-planar pyramidal geometry with 60–90° between the arms. Computer modeling of the three-way junction with 60° pyramidal geometry showed a predominantly B-form structure with local distortions at the junction points that diminish towards the ends of the helices. The size distributions of circular molecules are rather broad indicating a dynamic flexibility of three-way DNA junctions.     

Helix bending as a factor in protein/DNA recognition

Normal vectors perpendicular to individual base pairs are a powerful tool for studying the bending behavior of B-DNA, both in the form of normal vector plots and in matrices that list angles between vectors for all possible base pair combinations. A new analysis program, FREEHELIX, has been written for this purpose, and applied to 86 examples of sequence-specific protein/DNA complexes whose coordinates are on deposit in the Nucleic Acid Data Base. Bends in this sample of 86 structures almost invariably follow from roll angles between adjacent base pairs; tilt makes no net contribution. Roll in a direction compressing the broad major groove is much more common than that which compresses the minor groove. Three distinct types of B-DNA bending are observed, each with a different molecular origin: (1) Localized kinking is produced by large roll at single steps or at two steps separated by one turn of helix. (2) Smooth, planar curvature is produced by positive and negative roll angles spaced a half-turn apart, with random side-to-side zigzag roll at intermediate points, rather than a tilt contribution that might have been expected theoretically. (3) Three-dimensional writhe results from significant roll angles at a continuous series of steps. Writhe need not change the overall direction of helix axis, if it is continued indefinitely or for an integral number of helical turns. A-DNA itself can be formally considered as possessing uniform, continuous writhe that yields no net helix bending. Smooth curvature is the most intricate deformation of the three, and is least common. Writhe is the simplest deformation and is most common; indeed, a low level of continuous writhe is the normal condition of an otherwise unbent B-DNA helix of general sequence. With one exception, every example of major kinking in this sample of 86 structures involves a pyrimidine–purine step: C–A/T–G, T–A, or C–G. Purine–purine steps, especially A–A, show the least tendency toward roll deformations. © 1998 John Wiley & Sons, Inc. Biopoly 44: 361–403, 1997     

Base sequence criteria and Cartesian coordinates for stable B/Z and B/Z/B junctions in relaxed DNA.

It seems increasingly evident that if the Z form of DNA exists in the genome it must exist as short sections of alternating pyrimidine-purine sequences in the midst of very long sections of B-form DNA. We have determined the minimum length of a string of alternating CG base pairs that can go into the Z form in the middle of a long B form. Self-complimentary oligomers of the form T(M)(CG)(N)A(M) were synthesized. The conformation of the resulting duplex was determined in 6M aqueous NaCl solution by Raman scattering. We have found that 12 alternating CG base pairs is the minimum length required to form a stable Z form of DNA inside of a long B form section. Only the 4 center CG base pairs go into the Z form. These 4 CG base pairs in the Z form are flanked on each side by 4 CG base pairs in a non-Z (probably B) form as well as the ..TT.. ..AA.. sequences in the B form. We propose a model of the B/Z junction in which the double helix flips directly from the B form to the Z form so that there are no base pairs in the junction. In this model the B form is nucleated in the AT base pairs on each end and is propagated into the CG base pairs in the center. This model is supported by isotopic H/D exchange experiments that shows that the H/D exchange of the non-Z form CG base pairs is highly retarded and indicates that they remain in the B form. A Thermodynamic analysis of the concentration dependence of the melting point of the duplexes in both low and high salt, supports our model and rules out the possibility of hairpin formation. The enthalpy for the formation of a B/Z junction is determined to be about +16 kcal/junction. A comparison of these results with recent results on B/Z junctions in super-coiled DNA is given. Molecular modeling calculations permit us to obtain values for the coordinates and torsional angles of the oligomers showing both B/Z and B/Z/B junctions. The Cartesian coordinates for these oligomers as well as stereo figures of these models in color are available from the authors.     

Features of two hepatitis B virus (HBV) DNA integrations suggest mechanisms of HBV integration.

Two integrated hepatitis B virus (HBV) DNA molecules were cloned from two primary hepatocellular carcinomas each containing only a single integration. One integration (C3) contained a single linear segment of HBV DNA, and the other integration (C4) contained a large inverted duplication of viral DNA at the site of a chromosome translocation (O. Hino, T.B. Shows, and C.E. Rogler, Proc. Natl. Acad. Sci. USA 83:8338-8342, 1986). Sequence analysis of the virus-cell junctions of C3 placed the left virus-cell junction at nucleotide 1824, which is at the 5' end of the directly repeated DR1 sequence and is 6 base pairs from the 3' end of the long (L) negative strand. The right virus-cell junction was at nucleotide 1762 in a region of viral DNA (within the cohesive overlap) which shared 5-base-pair homology with cellular DNA. Sequence analysis of the normal cellular DNA across the integration site showed that 11 base pairs of cellular DNA were deleted at the site of integration. On the basis of this analysis, we suggest a mechanism for integration of the viral DNA molecule which involves strand invasion of the 3' end of the L negative strand of an open circular or linear HBV DNA molecule (at the DR1 sequence) and base pairing of the opposite end of the molecule with cellular DNA, accompanied by the deletion of 11 base pairs of cellular DNA during the double recombination event. Sequencing across the inverted duplication of HBV DNA in clone C4 located one side of the inversion at nucleotide 1820, which is 2 base pairs from the 3' end of the L negative strand. Both this sequence and the left virus-cell junction of C3 are within the 9-nucleotide terminally redundant region of the HBV L negative strand DNA. We suggest that the terminal redundancy is a preferred topoisomerase I nicking region because of both its base sequence and forked structure. Such nicking would lead to integration and rearrangement of HBV molecules within the terminal redundancy, as we have observed in both our clones.