Molecular characterization of transforming plasmid rearrangements in transgenic rice reveals a recombination hotspot in the CaMV 35S promoter and confirms the predominance of microhomology mediated recombination

The characterization of plasmid-genomic DNA junctions following plant transformation has established links between DNA double-strand break repair (DSBR), illegitimate recombination and plasmid DNA integration. The limited information on plasmid-plasmid junctions in plants comes from the dicot species tobacco and Arabidopsis. We analyzed 12 representative transgenic rice lines, carrying a range of transforming plasmid rearrangements, which predominantly reflected microhomology mediated illegitimate recombination involving short complementary patches at the recombining ends. Direct end-ligation, in the absence of homology between the recombining molecules, occurred only rarely. Filler DNA was found at some of the junctions. Short, purine-rich tracts were present, either at the junction site or in the immediate flanking regions. Putative DNA topoisomerase I binding sites were clustered around the junctions. Although different regions of the transforming plasmid were involved in plasmid-plasmid recombination, we showed that a 19 bp palindromic sequence, including the TATA box of the CaMV 35S promoter, acted as a recombination hotspot. The purine-rich half of the palindromic sequence was specifically involved at the recombination junctions. This recombination hotspot is located within the 'highly recombinogenic' region of the full-length CaMV RNA that has been shown to promote viral recombination in dicot plants. Clustering of plasmid recombination events in this highly recombinogenic region, even in the absence of viral enzymes and other cis-acting elements proves that the plant cellular machinery alone is sufficient to recognize and act on these viral sequences. Our data also show the similarity between mechanisms underlying junction formation in dicot and monocot plants transformed using different procedures.     

Reciprocal crossovers and a positional preference for strand exchange in recombination events resulting in deletion or duplication of chromosome 17p11.2

Smith-Magenis syndrome (SMS) is caused by an approximately 4-Mb heterozygous interstitial deletion on chromosome 17p11.2 in approximately 80%-90% of affected patients. Three large ( approximately 200 kb), complex, and highly homologous ( approximately 98%) low-copy repeats (LCRs) are located inside or flanking the SMS common deletion. These repeats, also known as "SMS-REPs," are termed "distal," "middle," and "proximal." The directly oriented distal and proximal copies act as substrates for nonallelic homologous recombination resulting in both the deletion associated with SMS and the reciprocal duplication: dup(17)(p11.2p11.2). Using restriction enzyme cis-morphism analyses and direct sequencing, we mapped the regions of strand exchange in 16 somatic-cell hybrids that harbor only the recombinant SMS-REP. Our studies showed that the sites of crossovers were distributed throughout the region of homology between the distal and proximal SMS-REPs. However, despite approximately 170 kb of high homology, 50% of the recombinant junctions occurred in a 12.0-kb region within the KER gene clusters. DNA sequencing of this hotspot (positional preference for strand exchange) in seven recombinant SMS-REPs narrowed the crossovers to an approximately 8-kb interval. Four of them occurred in a 1,655-bp region rich in polymorphic nucleotides that could potentially reflect frequent gene conversion. For further evaluation of the strand exchange frequency in patients with SMS, novel junction fragments from the recombinant SMS-REPs were identified. As predicted by the reciprocal-recombination model, junction fragments were also identified from this hotspot region in patients with dup(17)(p11.2p11.2), documenting reciprocity of the positional preference for strand exchange. Several potential cis-acting recombination-promoting sequences were identified within the hotspot. It is interesting that we found 2.1-kb AT-rich inverted repeats flanking the proximal and middle KER gene clusters but not the distal one. The role of any or all of these in stimulating double-strand breaks around this positional recombination hotspot remains to be explored.     

The RecE recombination pathway mediates recombination between partially homologous DNA sequences: structural analysis of recombination products

Escherichia coli generalized recombination, utilizing the RecA RecB recombination pathway, requires large stretches (70-200 bp) of complete DNA sequence homology. In contrast, we have found that the RecE pathway can promote recombination between DNA with only short stretches of homology. A plasmid containing 10 partially homologous direct repeats was linearized by digestion with specific restriction enzymes. After transformation, a RecE+ (sbcA) host was able to circularize the plasmid by recombination between partially homologous direct repeat sequences. Recombination occurred in regions of as little as 6 bp of perfect homology. Recombination was enhanced in the regions adjacent to restriction sites used to linearize the plasmid, consistent with a role of double-strand breaks in promoting recombination. A mechanism is proposed in which the 5' exonuclease, ExoVIII, produces 3' single-stranded ends from the linearized plasmid. These pair with other sequences of partial homology. Partial homologies in the sequences flanking the actual join serve to stabilize this recombination intermediate. Recombination is completed by a process of "copy and join." This recombination mechanism requires less homology to stabilize intermediates than the degree of homology needed for mechanisms involving strand invasion. Its role in nature may be to increase genomic diversity, for example, by enhancing recombination between bacteriophages and regions of the bacterial chromosome.     

Gene Conversions and Crossing over during Homologous and Homeologous Ectopic Recombination in Saccharomyces Cerevisiae

The pma1-105 mutation reduces the activity of the yeast plasma membrane H(+)-ATPase and causes cells to be both low pH and ammonium ion sensitive and resistant to the antibiotic hygromycin B. Revertants that can grow at pH 3.0 and on ammonium-containing plates frequently arise by ectopic recombination between pma1-105 and PMA2, a diverged gene that shares 85% DNA sequence identity with PMA1. The gene conversion tracts of revertants of pma1-105 were determined by DNA sequencing the hybrid PMA1::PMA2 genes. Gene conversion tracts ranged from 18-774 bp. The boundaries of these replacements were short (3-26 bp) regions of sequences that were identical between PMA1 and PMA2. These boundaries were not located at the regions of greatest shared identity between the two PMA genes. Similar results were obtained among low pH-resistant revertants of another mutation, pma1-147. One gene conversion was obtained in which the resulting PMA1::PMA2 hybrid was low pH-resistant but still hygromycin B-resistant. This partially active gene differs from a wild-type revertant only by the presence of two PMA2-encoded amino acid substitutions. Thus, some regions of PMA2 are not fully interchangeable with PMA1. We have also compared the efficiency of recombination between pma1-105 and either homeologous PMA2 sequence or homologous PMA1 donor sequences inserted at the same location. PMA2 X pma1-105 recombination occurred at a rate approximately 75-fold less than PMA1 X pma1-105 events. The difference in homology between the interacting sequences did not affect the proportion of gene conversion events associated with a cross-over, as in both cases approximately 5% of the Pma(+) recombinants had undergone reciprocal translocations between the two chromosomes carrying pma1-105 and the donor PMA sequences. Reciprocal translocations were identified by a simple and generally useful nutritional test.     

T-DNA integration: a mode of illegitimate recombination in plants.

Transferred DNA (T-DNA) insertions of Agrobacterium gene fusion vectors and corresponding insertional target sites were isolated from transgenic and wild type Arabidopsis thaliana plants. Nucleotide sequence comparison of wild type and T-DNA-tagged genomic loci showed that T-DNA integration resulted in target site deletions of 29-73 bp. In those cases where integrated T-DNA segments turned out to be smaller than canonical ones, the break-points of target deletions and T-DNA insertions overlapped and consisted of 5-7 identical nucleotides. Formation of precise junctions at the right T-DNA border, and DNA sequence homology between the left termini of T-DNA segments and break-points of target deletions were observed in those cases where full-length canonical T-DNA inserts were very precisely replacing plant target DNA sequences. Aberrant junctions were observed in those transformants where termini of T-DNA segments showed no homology to break-points of target sequence deletions. Homology between short segments within target sites and T-DNA, as well as conversion and duplication of DNA sequences at junctions, suggests that T-DNA integration results from illegitimate recombination. The data suggest that while the left T-DNA terminus and both target termini participate in partial pairing and DNA repair, the right T-DNA terminus plays an essential role in the recognition of the target and in the formation of a primary synapsis during integration.     

A general model for site-specific recombination by the integrase family recombinases.

We present here a general model for integrase family site-specific recombination using the geometric relationships of the cleavable phosphodiester bonds and the disposition of the recombinase monomers (defined by their binding planes) with respect to them. The 'oscillation model' is based largely on the conformations of the recombinase-bound DNA duplexes and their dynamics within Holliday junctions. The duplex substrate or the Holliday junction intermediate is capable of 'oscillating' between two cleavage-competent asymmetric states with respect to corres-ponding chemically inert 'equilibrium positions'. The model accommodates several features of the Flp system and predicts two modes of DNA cleavage during a normal recombination event. It is equally applicable to other systems that mediate recombination across 6, 7 or 8 bp long strand exchange regions (or spacers). The model is consistent with approximately 0-1, 1-2 and 2-3 bp of branch migration during recombination reactions involving 6, 7 and 8 bp spacers, respectively.     

Structure and sequence of the mitochondrial 20S rRNA and tRNA tyr gene of Paramecium primaurelia

The sequence and structure of the large (20s) mitochondrial (mt) rRNA gene and flanking regions from Paramecium primaurelia have been determined. The gene contains two regions of strong homology with other large mt rRNAs: one 44-base region near the 5' end and a 321-base region near the 3' end. Another region of strong homology to both ends of E. coli 23s RNA exists at loci consistent with these regions. The Paramecium gene appears to be 2204 bases in length and contains slightly more homology to E. coli rRNA than its mammalian or fungal counterparts. The gene, located about 1200 bp from the replicative terminal end of the linear mt DNA, is transcribed in the same polarity as replication. Previous R-looping studies detected no large introns within the gene. Here we describe sequences resembling degenerate rRNAs, one of which could represent a small intron. A tRNA tyr gene was found on the same DNA strand, 127 bp downstream from the large rRNA presumptive 3' end. The tRNA is flanked on both sides by short DNA regions of approximately 90% A + T content.     

Nature of recombination involved in excision and rearrangement of human repetitive DNA

An alphoid-like human repetitive DNA of the Sau3A family is present extrachromosomally and in the chromosomes. In the chromosomes, the DNA is located on chromosome 11 but related sequences are present in chromosome 17. We characterized the nature of the recombination involved in the excision of the extrachromosomal DNA from chromosome 11. The results show that the recombination occurs both between the homologous subunits and between the heterologous subunits with only a 70 to 80% sequence homology among them, suggesting that a DNA structure other than a sequence homology mediates the recombination process. The same type of recombination is responsible for the rearrangement of the related sequences in chromosome 17.     

Electron microscope study of the base sequence homology between simian virus 40 and human papovavirus BK.

The base sequence homology between the genomes of simian virus 40 (SV40) and human papovavirus BK (BKV) was studied by the heteroduplex method of Ferguson and Davis (J. Mol. Biol. 94:135-149, 1975). When mounted for microscopy in 30% formamide (Tm-35 degrees C), BKV/SV40 heteroduplexes were an average of 92% double-stranded and contained only two small nonhomologous regions that mapped near the junctions between the early and late regions of the SV40 Genome. At higher formamide concentrations, the fraction of duplex DNA in the BKV/SV40 heteroduplexes decreased, indicating significant base mismatching in the homologous regions. The strongest regions of homology were located in the late region.     

Characterization of RAD51-independent break-induced replication that acts preferentially with short homologous sequences

Repair of double-strand breaks by gene conversions between homologous sequences located on different Saccharomyces cerevisiae chromosomes or plasmids requires RAD51. When repair occurs between inverted repeats of the same plasmid, both RAD51-dependent and RAD51-independent repairs are found. Completion of RAD51-independent plasmid repair events requires RAD52, RAD50, RAD59, TID1 (RDH54), and SRS2 and appears to involve break-induced replication coupled to single-strand annealing. Surprisingly, RAD51-independent recombination requires much less homology (30 bp) for strand invasion than does RAD51-dependent repair (approximately 100 bp); in fact, the presence of Rad51p impairs recombination with short homology. The differences between the RAD51- and RAD50/RAD59-dependent pathways account for the distinct ways that two different recombination processes maintain yeast telomeres in the absence of telomerase.     

Directional recombination is initiated at a double strand break in human nuclear extracts.

The involvement of a double strand break in the initiation of homologous recombination was examined in human nuclear extracts. M13 duplex derivatives, containing inserts in the LacZ' region (producing white plaques), were cleaved by restriction enzymes and coincubated in the extracts with a circular plasmid containing the LacZ' region without insert, and unable to produce plaques. Repair was estimated by the ability to produce plaques after transfection into JM109 (recA1) bacteria. Recombination with the plasmid enhances the number of plaques and also the frequency of M13 producing blue plaques. Heterologous insertions in the region surrounding the break were analyzed for their effects on initiation of recombination. The extent of repair by recombination (number of plaques) was compared with the number of blue plaques among the repaired population. Initiation of recombination is inhibited when heterologous insertions are located at 7bp from the break, on the right side as well as on the left side. A low level of recombination is measurable for 27 bp of homology but the maximum efficiency of recombination occurred with homologies of 165 or 320 bp from the break to the heterologous insertion. At 320 bp, the extent of recombinational repair remained at a plateau level but the frequency of blue plaques progressively decreases. We have also analyzed the effect of different sizes of inserts. With longer inserts, a longer length of homology adjacent to the break is required for optimum recombination. However, the size of the insert does not affect the low level of recombination that occurred with a short homology (27 bp). The results indicate that the process is initiated at or near the break, requires homology on both sides of the break and is followed by an elongation from the double strand break to the distal regions of the DNA. Our data provide some support to the double-strand-break repair model established for meiotic recombination in yeast.     

Role of DNA ligase in the illegitimate recombination that generates lambdabio-transducing phages in Escherichia coli

We studied the role of DNA ligase in illegitimate recombination in Escherichia coli. A temperature-sensitive mutation in the lig gene reduced the frequency with which lambdabio-transducing phages were generated to 10-14% of that of wild type under UV irradiation. Reintroduction of the lig gene into this mutant restored the frequency of recombinant phage generation to that of wild type. Furthermore, overexpression of DNA ligase enhanced illegitimate recombination by 10-fold with or without UV irradiation. In addition, when DNA ligase was present in only limited amounts, UV-induced or spontaneous illegitimate recombination occurred exclusively at hotspot sites that have relatively long sequences of homology (9 or 13 bp). However, when DNA ligase was overexpressed, most of the illegitimate recombination took place at non-hotspot sites having only short sequences of homology (<4 bp). Thus, the level of ligase activity affects the frequency of illegitimate recombination, the length of sequence homology at the recombination sites, and the preference for recombination at hotspots, at least after UV irradiation. These observations support our hypothesis that the illegitimate recombination that generates lambdabio-transducing phages is mediated by the DNA break-and-join mechanism.     

The Deinococcus radiodurans-encoded HU protein has two DNA-binding domains

Deinococcus radiodurans can reconstitute its genome from double-strand breaks, most likely due to unusually efficient DNA repair and recombination. Factors that may contribute to such processes include the histone-like protein HU. The D. radiodurans-encoded HU (DrHU), which binds preferentially to DNA recombination intermediates, contains a 47-amino acid extension preceding the fold characteristic of HU proteins. Here we use electrophoretic mobility shift assays and DNA footprinting to show that the DrHU N-terminal domain significantly modulates DNA binding. The truncated DrHU (deltaDrHU), comprising only the conserved DNA-binding fold, has a site size of approximately 11 bp in contrast to full-length DrHU which does not stably engage DNA shorter than approximately 50 bp. Unlike wild-type DrHU, deltaDrHU distinguishes between linear DNA and DNA with nicks or gaps. DeltaDrHU also binds preferentially to four-way junction (4WJ) DNA, with half-maximal saturation of 1.4 +/- 0.4 nM compared to 20 +/- 2 nM for 37 bp duplex DNA. However, in contrast to full-length protein which binds the junction arms, deltaDrHU primarily protects the junction crossover. Evidently, the DrHU N-terminus changes the mode of binding to both 4WJ DNA, duplex DNA, and DNA with nicks or gaps, thereby resulting in DrHU binding preferentially only to 4WJ structures. Combined with Western blots that confirm the presence of the extended form of DrHU in vivo, our data provide mechanistic insight into discrimination between 4WJ DNA and other distorted DNA constructs and suggest that an in vivo role of DrHU may be to stabilize DNA junctions.     

A novel sequence common to the centromere regions of Schizosaccharomyces pombe chromosomes.

An approximately 4 kb long sequence (designated dh) is located in the centromere regions of all three chromosomes of S. pombe. There is one copy each of dh per centromere in chromosomes I and II and multiples in the centromere of chromosome III. Nucleotide sequence determination shows that dhI and dhII are highly homologous. A part of the sequence (ca. 300-400 bp) contains short direct repeats, otherwise dh is in general internally non-repetitious. Although there are three segmental deletions (total 821 bp) and two insertions (27 bp) in dhII (an 80% overall homology to dhI), there are only nine substitutions between dhI and dhII in the remaining 3980 bp, giving a 99.77% homology. The substitutions are restricted to the non-repetitious domains and are only of the pyrimidine-pyrimidine or purine-purine types. A possible conformational role of dh is discussed.     

Homologous Recombination in ESCHERICHIA COLI: Dependence on Substrate Length and Homology

We studied the in vivo recombination between homologous DNA sequences cloned in phage lambda and a pBR322-derived plasmid by assaying for the formation of phage-plasmid cointegrates by a single (or an odd number of) reciprocal exchange. (1) Recombination proceeds by the RecBC pathway in wild-type cells and by low levels of a RecF-dependent pathway in recBC- cells. The RecE pathway appears not to generate phage-plasmid cointegrates. (2) Recombination is linearly dependent on the length of the homologous sequences. In both RecBC and RecF-dependent pathways there is a minimal length, called the minimal efficient processing segment (MEPS), below which recombination becomes inefficient. The length of MEPS is between 23-27 base pairs (bp) and between 44-90 bp for the RecBC- and RecF-dependent pathways, respectively. A model, based on overlapping MEPS, of the correlation of genetic length with physical length is presented. The bases for the different MEPS length of the two pathways are discussed in relationship to the enzymes specific to each pathway. (3) The RecBC and the RecF-dependent pathways are each very sensitive to substrate homology. In wild-type E. coli, reduction of homology from 100% to 90% decreases recombinant frequency over 40-fold. The homology dependence of the RecBC and RecF-dependent pathways are similar. This suggests that a component common to both, probably recA, is responsible for the recognition of homology.     

Homologous recombination of SV40 DNA in COS7 cells occurs with high frequency in a gene dose independent fashion.

Homologous recombination between microinjected SV40 DNA fragments and endogenous SV40 DNA in COS7 cells was analysed by immunofluorescence staining and DNA blotting. Time course experiments revealed that recombination between the transferred (trans) DNA and the chromosomal DNA occurred about 8 hours after microinjection with high efficiency in a gene dose independent fashion. Deletions of up to 1018 basepairs (bp) within the early or the late SV40 region were efficiently repaired after the transfer of linear but not of circular DNA molecules. A 22 bp homology between the trans DNA and the endogenous DNA was sufficient to initiate recombination but 14 nonhomologous bp at one open end of the SV40 DNA fragments hindered gap repair.     

Sequence of the junction in adenovirus 2-SV40 hybrids: examples of illegitimate recombination.

The nucleotide sequences of six Ad2-SV40 junctions from three Ad2-SV40 hybrid viruses (Ad2++HEY, Ad2++LEY and Ad2+D1) were determined. Comparison of parental adenovirus 2 and SV40 DNA sequences with the sequence at the Ad2-SV40 junctions revealed that 5 out of 6 junctions are abrupt transitions from Ad2 to SV40 DNA, and in one case (Ad2++LEY, right junction) there is an additional nucleotide at the junction, which cannot be ascribed to either DNA. Ad2++HEY and Ad2+D1 right junctions are identical and Ad2++LEY and Ad2+ND4 left junctions are identical, a result that strongly suggests these Ad2-SV40 hybrids arose by recombination between the linear Ad2 DNA and circular SV40 DNA, followed by recombination between Ad2 DNA and SV40 DNA present in the Ad2-SV40 hybrid DNA. The unambiguous transition of Ad2 DNA into SV40 DNA at the junction sites is an example of recombination events which have apparently occurred without any homology at the recombination site.     

Illegitimate recombination in Bacillus subtilis: nucleotide sequences at recombinant DNA junctions

Summary The illegitimate integration of plasmid pGG20 (the hybrid between Staphylococcus aureus plasmid pE194 and Escherichia coli plasmid pBR322) into the Bacillus subtilis chromosome was studied. It was found that nucleotide sequences of both parental plasmids could be involved in this process. The recombinant DNA junctions between plasmid pGG20 and the chromosome were cloned and their nucleotide sequences were determined. The site of recombination located on the pBR322 moiety carried a short region (8 bp) homologous with the site on the chromosome. The nucleotide sequences of the pE194 recombination sites did not share homology with chromosomal sequences involved in the integration process. Two different pathways of illegitimate recombination in B. subtilis are suggested.