Primary products of break-induced recombination by Escherichia coli RecE pathway.

Alternative models for break-induced recombination predict different distributions of primary products. The double-stranded break-repair model predicts a noncrossover product and equimolar amounts of two crossover products. The one-end pairing model predicts two crossover products, but not necessarily in equimolar amounts, and the single-stranded annealing model predicts deletion of the fragment between the pairing sequences. Depending on the structure of the recombining substrate(s) and the nature of the resectioning step that precedes strand annealing, the single-stranded annealing mechanism would yield only one or both crossover products. We tested these predictions for the RecE recombination pathway of Escherichia coli. Nonreplicating intramolecular recombination substrates with a double-stranded break (DSB) within one copy of a direct repeat were released from chimera lambda phage by in vivo restriction, and the distribution of primary circular recombination products was determined. Noncrossover products were barely detectable, and the molar ratio of the two crossover products was proportional to the length ratio of the homologous ends flanking the DSB. These results suggest an independent pairing of each end with the intact homolog and argue against the double-stranded break-repair model. However, the results do not distinguish alternative pairing mechanisms (strand invasion and strand annealing). The kinetics of heteroduplex formation and heteroduplex strand polarity were investigated. Immediately following the DSB induction, heteroduplex formation was done by pairing the strands ending 3' at the break. A slow accumulation of the complementary heteroduplex made by the pairing of the strands ending 5' at the break (5' heteroduplexes) was observed at a larger stage. The observed bias in heteroduplex strand polarity depended on DSB induction at a specific site. The 5' heteroduplexes may have been generated by reciprocal strand exchange, pairing that is not strand specific, or strand-specific pairing induced at random breaks.     

An in vitro method generating base substitutions in preselected regions of plasmid DNA: application to structural analysis of the replication origin of the Escherichia coli K-12 chromosome

A method for introducing base substitutions in defined regions of plasmid DNA has been developed. In principle, a circular heteroduplex DNA containing a gap is constructed by annealing of two kinds of linear molecules derived from the same plasmid: One is the molecule shortened either by exonucleolytic digestion from the termini generated at a restriction site or by removal of a region flanked by two restriction sites, and the other the full-length molecule linearized at a different site. The deleted region in the shorter linear molecule becomes a single-stranded gap in the circular heteroduplex DNA. The heteroduplex is then treated with sodium bisulfite that converts specifically cytosine residues to uracil residues in single-stranded regions. After filling in the gap by repair synthesis, transformation is carried out to isolate mutant plasmids. Since two kinds of circular heteroduplexes are formed by annealing in which the sequences in the gaps are complementary to each other, mutagenesis of both strands can be accomplished in one experiment. This method was applied to construction of mutants with base substitutions in the replication origin region (oriC) of the Escherichia coli K-12 chromosome which had previously been cloned in colicin E1 plasmid vectors, and various mutants in defined regions of oriC were successfully isolated at high efficiencies. Analysis of these mutants provided evidence that oriC contains special regions, designated spacers, which separate neighboring important sequences specifying interactions with initiation factors for DNA replication at precise distances.     

Action of single-strand specific nucleases on model DNA heteroduplexes of defined size and sequence.

The sensitivity of the model DNAs containing dA-dG and dtg-dG heteroduplex regions of defined length to S1 and mung bean single-strand specific nucleases was tested by polyacrylamide gel electrophoretic analysis of the distribution of product oligonucleotides. Single-base mismatch heteroduplexes were extremely resistant to these nucleases, although low levels of cleavage at the heteroduplex nucleotide were observed at high nuclease concentrations. The nuclease sensitivity of dA-dtg heteroduplex regions increased gradually as the length of the heteroduplex region increased frome one to six nucleotides. The sensitivity of dG-dG heteroduplexes three to five nucleotides long was considerably greater than that of the single dtg-dG mismatch.     

Analysis by electron microscopy of the variable segment in the maxi-circle of kinetoplast DNA from Trypanosoma brucei

The 20.5-kbp maxi-circle from the kinetoplast DNA of Trypanosoma brucei contains a 5-kbp segment which is not cut by most restriction endonucleases and which varies in size in closely-related trypanosome strains (Borst, P., Fase-Fowler, F., Hoeijmakers, J.H.J. and Frasch, A.C.C. (1980) Biochim. Biophys. Acta 610, 197–210). We have now analysed partial denaturation maps of the linearized maxi-circles by electron microscopy and find that the variable segment is not more AT-rich than the remainder of the maxi-circle. Early denaturation begins at two separate regions of the maxi-circle outside the variable region and one of these corresponds with the position of the gene for the large (12 S) ribosomal RNA. Denaturation-renaturation of maxi-circles leads to the formation of partially mismatched duplexes that look like underwound loops in electron micrographs. These loops are only found in the variable region and they vary in size and appearance. Under our renaturation conditions single-stranded maxi-circle DNA is devoid of secondary structure and this suggests that the underwound loops arise by misalignment of straight tandem repeats in the DNA. We have also analysed heteroduplexes between maxi-circles from two closely related T. brucei strains that differ by 1 kbp in the size of their variable segment. Most molecules had no underwound loops and contained mismatched regions in the variable segment only. The appearance of these regions is diverse, varying from fully duplex with two single-stranded loops to molecules with a heterogeneous array of smaller loops. The total size of single-stranded DNA in the heteroduplexes may be as high as 1.2 μm, i.e., a factor 4 higher than the size difference between the heteroduplex partners. We conclude that the variable region consists of imperfect tandem repeats of a sequence that evolves rapidly. This region might contain the origin of maxi-circle replication.     

Heteroduplex Strand-Specificity in Restriction-Stimulated Recombination by the Rece Pathway of Escherichia Coli

The RecE recombination pathway is active in Escherichia coli recB recC sbcA mutants. To isolate and characterize products and intermediates of RecE-mediated, break-induced, intramolecular recombination, we infected recB recC sbcA mutants, expressing EcoRI endonuclease, with chimeric λ phages that allow EcoRI-mediated release of cloned linear recombination substrates. Substrates with direct terminal repeats recombined to yield a circular product with one copy of the repeated sequence. Some recombinants were heteroallelic for the recombining markers. Markers distant to the break were recovered in the circular product at a higher frequency than markers close to the break. To examine the heteroduplex structures that may have yielded the heteroallelic recombinants, nonreplicative substrates were employed. Some of the nonreplicative recombination products contained heteroduplexes, with a strong bias for paired strands ending 3' at the break. This strand bias in heteroduplex formation is consistent with recombination models that postulate homologous pairing of protruding 3' single-stranded ends.     

Reduction of heteroduplex formation in PCR amplification

Heteroduplex formation is known to occur during mixed-template polymerase chain reaction (PCR) using universal primers, and may represent a serious problem in several PCR-based analyses. A common way to eliminate heteroduplex formation is to use reconditioning PCR. Because we detected that reconditioning PCR was not always sufficient to prevent heteroduplex formation, we focused on developing methods for the elimination of heteroduplexes during PCR. We detected that the heteroduplex to homoduplex ratio can be decreased by the addition of Taq polymerase and by a decrease in the number of PCR cycles. An appropriate combination of both of these approaches can be a method generally applicable to decrease the formation of heteroduplexes.     

Spontaneous DNA-DNA interaction of homologous duplexes and factors affecting the result of heteroduplex formation

Mutation detection and mismatch repair investigations based on heteroduplex formation require a linear DNA structure. DNA branching, described previously under physiological conditions, has been analysed in the heteroduplex formation process. Symmetrical chi-structures were detected after heteroduplex formation by gel electrophoresis and electron microscopy. Buffer composition, DNA concentration and duplex end-sequences influence DNA branching. Duplexes with homologous central regions but non-complementary ends do not form hybrid heteroduplexes or hybrid Holliday junctions. Our results explain the requirements for efficient heteroduplex formation, which were previously determined empirically: special solution composition, optimal DNA concentration and GC clamps. This provides the theoretical background for further optimisation of the procedure.     

The isolation of DNA from agarose gels by electrophoretic elution onto malachite green-polyacrylamide columns

Electrophoretic elution of DNA coupled with direct adsorption onto malachite green-polyacrylamide columns was used to isolate double- and single-stranded DNA from agarose gels. Subsequently, DNA was eluted with a high salt buffer and filtered through Sephadex which permitted recovery of the DNA in a low salt buffer at concentrations suitable for heteroduplex analysis by electron microscopy. This method was tested by examining hetero-duplexes formed from the isolated complementary single strands of T7 wild type DNA and a T7 deletion mutant. More than 80% of the reannealed molecules were intact heteroduplexes showing the deletion loop. Irradiation of single-stranded DNA with 254 nm light resulted in distorted, convoluted heteroduplexes while 366 nm light did not show this effect.     

The regulatory region of the L-arabinose operon: its isolation on a 1000 base-pair fragment from DNA heteroduplexes.

A DNA fragment containing the l-arabinose operon regulatory region of Escherichia coli was purified from DNA heteroduplexes formed between opposite strands of two non-defective ara transducing phage. The phage and arabinose gene orientation is such that the heteroduplex contains two single-stranded “bubbles”. The ara regulatory region and short portions of the flanking araB and araC genes are in the short duplex between the “bubbles”. Extensive regions of homology between the phage genomes allowed nearly half of the DNA renatured from a mixture of the two phage DNAs to be in the form of heteroduplexes. Digestion of the reannealed DNA containing heteroduplexes and homoduplexes with the easily purified, single-strand specific nuclease S₁ yielded the 1000 (1017 ± 20, n = 36) base-pair ara DNA duplex plus half and whole phage-length duplexes. The larger DNA duplexes were selectively precipitated by polyethylene glycol before the final purification by preparative electrophoresis on polyacryl-amide gels. By these methods 10 to 20 μg of the 1000 base-pair DNA fragment were purified.     

Specific fragmentation of adenovirus heteroduplex DNA molecules with single-strand specific nucleases of Neurospora crassa

Heteroduplex DNA molecules, prepared by hybridizing DNA of adenovirus serotypes 1, 2 and 5 in all three combinations, have been shown by electron microscopy to contain two specifically located mismatched regions.Single-strand specific nucleases from Neurospora crassa cleaved the heteroduplexes into three fragments as demonstrated by sucrose gradient analysis, agarose gel electrophoresis and electron microscopy. These were produced in equimolar amounts, and were shown by alkaline sucrose gradient analysis to be free of internal single-strand interruptions. The size of each of the fragments was determined by sucrose gradient analysis and by electron microscopic measurements of the contour lengths. The three values obtained correspond to the lengths of the three double-stranded regions in the untreated heteroduplex molecules. The fragments, free of detectable single-stranded tails, have been isolated preparatively from neutral sucrose gradients. Renaturation kinetic analyses support the conclusion that each fragment represents a unique segment of the adenovirus genome.     

Highly Mismatched Molecules Resembling Recombination Intermediates Efficiently Transform Mismatch Repair Proficient Escherichia Coli

The ability of related DNAs to undergo recombination decreases with increased sequence divergence. Mismatch repair has been proposed to be a key factor in preventing homeologous recombination; however, the contribution of mismatch repair is not universal. Although mismatch repair has been proposed to act by preventing strand exchange and/or inactivating multiply mismatched heteroduplexes, there has been no systematic study to determine at what step(s) in recombination mismatch repair acts in vivo. Since heteroduplex is a commonly proposed intermediate in many models of recombination, we have investigated the consequences of mismatch repair on plasmids that are multiply mismatched in heteroduplex structures that are similar to those that might arise during recombination. Plasmids containing multiply mismatched regions were transformed into wild-type and Mut(-) Eschericia coli mutants. There was only a 30-40% reduction in transformation of Mut(+) as compared to mutS and mutL strains for DNAs containing an 18% mismatched heteroduplex. The products obtained from mutS hosts differed from those obtained from Mut(+) hosts in that there were many more colonies containing mixtures of two plasmids, due to survival of both strands of the heteroduplex. There were nearly 10 times more recombinants obtained from the mutS as compared to the wild-type host. Based on these results and those from other studies with E. coli and yeast, we propose that the prevention of recombination between highly diverged DNAs may be at step earlier than heteroduplex formation.     

Mismatch cleavage by single-strand specific nucleases

We have investigated the ability of single-strand specific (sss) nucleases from different sources to cleave single base pair mismatches in heteroduplex DNA templates used for mutation and single-nucleotide polymorphism analysis. The TILLING (Targeting Induced Local Lesions IN Genomes) mismatch cleavage protocol was used with the LI-COR gel detection system to assay cleavage of amplified heteroduplexes derived from a variety of induced mutations and naturally occurring polymorphisms. We found that purified nucleases derived from celery (CEL I), mung bean sprouts and Aspergillus (S₁) were able to specifically cleave nearly all single base pair mismatches tested. Optimal nicking of heteroduplexes for mismatch detection was achieved using higher pH, temperature and divalent cation conditions than are routinely used for digestion of single-stranded DNA. Surprisingly, crude plant extracts performed as well as the highly purified preparations for this application. These observations suggest that diverse members of the S₁ family of sss nucleases act similarly in cleaving non-specifically at bulges in heteroduplexes, and single-base mismatches are the least accessible because they present the smallest single-stranded region for enzyme binding. We conclude that a variety of sss nucleases and extracts can be effectively used for high-throughput mutation and polymorphism discovery.     

Heteroduplex-induced mutagenesis in mammalian cells

We have shown previously that heteroduplexes containing single-stranded loops are repaired efficiently in monkey cells, but not always correctly: 2% of the repair products acquired mutations within a 350 base-pair target (Weiss, U. and Wilson, J.H., Proc. Natl. Acad. Sci. USA 87:1123-1126, 1987). The structures of the mutant genomes, which are described here, are consistent with an error-prone repair system. The spectrum of mutations includes about 25% point mutations and 75% rearrangements, which consist of deletions, duplications, and substitutions. The mutations are clustered in the vicinity of single-stranded loops in the original heteroduplex. The high frequency of mutation, their clustering, and the positions of rearrangement endpoints suggest that the mutations were generated during repair of the heteroduplexes.     

Heteroduplex resolution using T7 endonuclease I in microbial community analyses

Microbial community analyses using molecular techniques, such as PCR followed by genomic library construction, have been helpful in better understanding microbial communities. This is especially critical in ecological systems where most of the microbes present cannot be cultured using traditional techniques. Unfortunately, there are problems associated with the use of such molecular techniques for the analysis of microbial community structure, primarily from the frequent formation of PCR artifacts. Multitemplate PCR is often subject to errors such as heteroduplex formation that is generated during the amplification of a particular gene from a mixed community of DNA. Based on work in this laboratory, heteroduplexes may be resolved before carrying out genomic library construction by including a digestion step with T7 endonuclease I. Here, the 18S rDNA gene of fungi was amplified from soil community DNA and digested with T7 endonuclease I to resolve any heteroduplexes present in the PCR product before cloning. These samples were compared with replicates that did not receive the T7 endonuclease I treatment. Digestion of the amplified community 18S rDNA with 10 U T7 endonuclease I/microgram DNA prior to cloning eliminated heteroduplexes, leaving only the desired clones. Without the T7 endonuclease I treatment, heteroduplexes were produced in approximately 10% of the recombinants screened. The addition of this step may eliminate heteroduplexes from PCR products and ensure that subsequent genomic library construction is not compromised.     

Patterns of heteroduplex formation associated with the initiation of meiotic recombination in the yeast Saccharomyces cerevisiae

The double-strand break repair (DSBR) model of recombination predicts that heteroduplexes will be formed in regions that flank the double-strand break (DSB) site and that the resulting intermediate is resolved to generate either crossovers or noncrossovers for flanking markers. Previous studies in Saccharomyces cerevisiae, however, failed to detect heteroduplexes on both sides of the DSB site. Recent physical studies suggest that some recombination events involve heterodupex formation by a mechanism, synthesis-dependent strand annealing (SDSA), that is inherently asymmetric with respect to the DSB site and that leads exclusively to noncrossovers of flanking markers. Below, we demonstrate that many of the recombination events initiated at the HIS4 recombination hotspot are consistent with a variant of the DSBR model in which the extent of heteroduplex on one side of the DSB site is much greater than that on the other. Events that include only one flanking marker in the heteroduplex (unidirectional events) are usually resolved as noncrossovers, whereas events that include both flanking markers (bidirectional events) are usually resolved as crossovers. The unidirectional events may represent SDSA, consistent with the conclusions of others, although other possibilities are not excluded. We also show that the level of recombination reflects the integration of events initiated at several different DSB sites, and we identify a subset of gene conversion events that may involve break-induced replication (BIR) or repair of a double-stranded DNA gap.     

Fluorescent heteroduplex assay for monitoring Bacillus anthracis and close relatives in environmental samples

A fluorescent heteroduplex method was developed to assess the presence of 16S rRNA gene (rDNA) sequences from Bacillus anthracis and close relatives in PCR-amplified 16S rDNA sequence mixtures from environmental samples. The method uses a single-stranded, fluorescent DNA probe, 464 nucleotides in length, derived from a B. anthracis 16S rRNA gene. The probe contains a unique, engineered deletion such that all probe-target duplexes are heteroduplexes with an unpaired G at position 343 (deltaG343). Heteroduplex profiles of sequences >/=85% similar to the probe were produced using an ABI 377 sequencer in less than 3 h. The method divides strains of the Bacillus cereus-Bacillus thuringiensis-B. anthracis group into two subgroups. Each subgroup is defined by a specific 16S rRNA gene sequence type. Sequence type A, containing one mismatch with the probe, occurs in B. anthracis and a small number of closely related clonal lineages represented mostly by food-borne pathogenic isolates of B. cereus and B. thuringiensis. Sequence type B, containing two mismatches with the probe, is found in the majority of B. cereus and B. thuringiensis strains examined to date. Sequence types A and B, when hybridized to the probe, generate two easily differentiated heteroduplexes. Thus, from heteroduplex profiles, the presence of B. cereus-B. thuringiensis-B. anthracis subgroups in environmental samples can be inferred unambiguously. The results show that fluorescent heteroduplex analysis is an effective profiling technique for detection and differentiation of sequences representing small phylogenetic or functional groups in environmental samples.     

DNA base sequence homology between coliphages T7 and phiII and between T3 and phiII as determined by heteroduplex mapping in the electron microscope

The genetic relatedness of the similar coliphages T7, T3 and øII was investigated by electron microscopic observations of the DNA heteroduplexes formed with one DNA strand from coliphage T7 (or T3) and the complementary strand from øII. The T7-øII heteroduplex is almost invariant with denaturing conditions, below the melting temperature of T7 DNA. This observation indicates that the DNAs of T7 and øII have regions of complete homology and regions of complete non-homology. In direct contrast, the T3-øII heteroduplex varies with denaturing conditions. The fraction of the T3-øII heteroduplex observed as double-stranded decreases with an increase in denaturing conditions below the melting temperature. This observation indicates that the DNAs of T3 and øII have extensive sequences of partial homology.     

The roles of RecBCD, Ssb and RecA proteins in the formation of heteroduplexes from linear-duplex DNA in vitro

Summary The formation of heteroduplexes from linear duplex DNA, where one molecule possesses a DNA doublestrand break, was assayed by agarose gel electrophoresis. Using unlabeled whole-length linear duplex DNA and ³H-labeled half-length linear duplex DNA (obtained from plasmid pACYC184), the appearance of ³H-labeled DNA that migrated as whole-length linear DNA was taken as evidence for formation of heteroduplex DNA. When the DNA mixtures were incubated with RecA, RecBCD, or Ssb proteins, or any double or triple combination of these proteins under a variety of reaction conditions, no heteroduplex DNA was detected. However, heteroduplex DNA was detected when the DNA mixtures were first incubated briefly with the RecBCD and Ssb proteins under reaction conditions that allow unwinding to proceed, and then the MgCl₂ concentration was raised such that renaturation could proceed. The inclusion of the RecBCD and Ssb proteins was sufficient to catalyze the slow formation of heteroduplex DNA, but the presence of RecA protein greatly increased the kinetics. The roles of the RecBCD, Ssb and RecA proteins in heteroduplex formation in vitro are discussed.     

Destruction of low efficiency markers is a slow process occurring at a heteroduplex stage of transformation

Summary Direct evidence is presented that the mechanism which discriminates against low efficiency markers in transformation of Diplococcus pneumoniae of genotype hex ⁺ acts on them after the formation of donor-recipient heteroduplexes. This conclusion is based on assays of the transforming activity of donor markers in lysates made after various times of incubation of recipient cells following exposure to DNA. The activity of a low efficiency marker rises substantially, indicating formation of native-like heteroduplex structures, and then falls. At 37° C the process is essentially completed 10 minutes after entry, and the apparent half life of a susceptible heteroduplex is 1.5 to 2 minutes. Data from these and other experiments imply that about as many of the surviving low efficiency markers have simply escaped attack as have been inserted into both strands by the excision-repair process suggested by Ephrussi-Taylor.     

Relationship of group P1 plasmids revealed by heteroduplex experiments: RP1, RP4, R68 and RK2 are identical.

The molecular relationships of the IncP1 plasmids RP1, RP4, R68 and RK2 were tested by electron microscopic examination of heteroduplexes. In several hybridization experiments molecules were detected which had a 7.8% portion of incomplete reannealing. This 'heterologous region' could be explained by the typical renaturation behaviour of the transposon Tn1. The identity of the Tn1 transposon present in RP1 and RP4 was proved by heteroduplex experiments with lambda phage DNA containing this transposon. These results indicated that the plasmids RP1 and RP4 are identical. Additional heteroduplex experiments between plasmids R68.45 and RP8 and between R68.45 and RK2 were performed. R68.45, a derivative of R68, has a small DNA insertion and RP8 can be regarded as a large insertion mutant of RP4; both insertions were used as single-stranded hybridization markers. From the hybrid molecules formed, it was deduced that R68 and RK2 are identical with RP1 and RP4 as far as molecular structure is revealed by the technique used.