Approaches to half-tetrad analysis in bacteria: recombination between repeated, inverse-order chromosomal sequences

Biased Gene Conversion in Rhizobium etli Is Caused by Preferential Double-Strand Breaks on One of the Recombining Homologs

Gene conversion, the nonreciprocal transfer of information during homologous recombination, is the main process that maintains identity between members of multigene families. Gene conversion in the nitrogenase (nifH) multigene family of Rhizobium etli was analyzed by using a two-plasmid system, where each plasmid carried a copy of nifH. One of the nifH copies was modified, creating restriction fragment length polymorphisms (RFLPs) spaced along the gene. Once the modified plasmid was introduced into R. etli, selection was done for cointegration with a resident plasmid lacking the RFLPs. Most of the cointegrate molecules harbor gene conversion events, biased toward a gain of RFLPs. This bias may be explained under the double-strand break repair model by proposing that the nifH gene lacking the RFLPs suffers a DNA double-strand break, so the incoming plasmid functions as a template for repairing the homolog on the resident plasmid. To support this proposal, we cloned an SceI site into the nifH homolog that had the RFLPs used for scoring gene conversion. In vivo expression of the meganuclease I-SceI allowed the generation of a double-strand break on this homolog. Upon introduction of this modified plasmid into an R. etli strain lacking I-SceI, biased gene conversion still favored the retention of markers on the incoming plasmid. In contrast, when the recipient strain ectopically expressed I-SceI, a dramatic reversal in gene conversion bias was seen, favoring the preservation of resident sequences. These results show that biased gene conversion is caused by preferential double-strand breaks on one of the recombining homologs.

IMPORTANCE

In this work, we analyzed gene conversion by using a system that entails horizontal gene transfer followed by homologous recombination in the recipient cell. Most gene conversion events are biased toward the acquisition of the incoming sequences, ranging in size from 120 bp to 800 bp. This bias is due to preferential cutting of resident DNA and can be reversed upon introduction of a double-strand break on the incoming sequence. Since conditions used in this work are similar to those in horizontal gene transfer, it provides evidence that, upon transfer, the resident DNA preferentially acquires gene variants.

Comparative genomic analyses of Streptococcus mutans provide insights into chromosomal shuffling and species-specific content

Background

Streptococcus mutans is the major pathogen of dental caries, and it occasionally causes infective endocarditis. While the pathogenicity of this species is distinct from other human pathogenic streptococci, the species-specific evolution of the genus Streptococcus and its genomic diversity are poorly understood.

Results

We have sequenced the complete genome of S. mutans serotype c strain NN2025, and compared it with the genome of UA159. The NN2025 genome is composed of 2,013,587 bp, and the two strains show highly conserved core-genome. However, comparison of the two S. mutans strains showed a large genomic inversion across the replication axis producing an X-shaped symmetrical DNA dot plot. This phenomenon was also observed between other streptococcal species, indicating that streptococcal genetic rearrangements across the replication axis play an important role in Streptococcus genetic shuffling. We further confirmed the genomic diversity among 95 clinical isolates using long-PCR analysis. Genomic diversity in S. mutans appears to occur frequently between insertion sequence (IS) elements and transposons, and these diversity regions consist of restriction/modification systems, antimicrobial peptide synthesis systems, and transporters. S. mutans may preferentially reject the phage infection by clustered regularly interspaced short palindromic repeats (CRISPRs). In particular, the CRISPR-2 region, which is highly divergent between strains, in NN2025 has long repeated spacer sequences corresponding to the streptococcal phage genome.

Conclusion

These observations suggest that S. mutans strains evolve through chromosomal shuffling and that phage infection is not needed for gene acquisition. In contrast, S. pyogenes tolerates phage infection for acquisition of virulence determinants for niche adaptation.

Pilin gene variation in Neisseria gonorrhoeae: reassessing the old paradigms

Neisseria gonorrhoeae displays considerable potential for antigenic variation as shown in human experimental studies. Various surface antigens can change either by antigenic variation using RecA-dependent recombination schemes (e.g. PilE antigenic variation) or, alternatively, through phase variation (on/off switching) in a RecA-independent fashion (e.g. Opa and lipooligosaccharide phase variation). PilE antigenic variation has been well documented over the years. However, with the availability of the N. gonorrhoeae FA1090 genome sequence, considerable genetic advances have recently been made regarding the mechanistic considerations of the gene conversion event, leading to an altered PilE protein. This review will compare the various models that have been presented and will highlight potential mechanistic problems that may constrain any genetic model for pilE gene variation.

Selection for high-level telithromycin resistance in Staphylococcus aureus yields mutants resulting from an rplB-to-rplV gene conversion-like event

While most Staphylococcus aureus telithromycin-resistant mutants isolated in this study possessed duplications within rplV (encoding ribosomal protein L22), four isolates possessed insertions within rplV that were identical to a portion of the gene rplB (encoding ribosomal protein L2). This novel type of mutation is the result of an apparent gene conversion-like event.

Adaptive amplification

Modern techniques are revealing that repetition of segments of the genome, called amplification or gene amplification, is very common. Amplification is found in all domains of life, and occurs under conditions where enhanced expression of the amplified genes is advantageous. Amplification extends the range of gene expression beyond that which is achieved by control systems. It also is reversible because it is unstable, breaking down by homologous recombination. Amplification is believed to be the driving force in the clustering of related functions, in that it allows them to be amplified together. Amplification provides the extra copies of genes that allow evolution of functions to occur while retaining the original function. Amplification can be induced in response to cellular stressors. In many cases, it has been shown that the genomic regions that are amplified include those genes that are appropriate to upregulate for a specific stressor. There is some evidence that amplification occurs as part of a broad, general stress response, suggesting that organisms have the capacity to induce structural changes in the genome. This then allows adaptation to the stressful conditions. The mechanisms by which amplification arises are now being studied at the molecular level, but much is still unknown about the mechanisms in all organisms. Recent advances in our understanding of amplification in bacteria suggests new interpretations of events leading to human copy number variation, as well as evolution in general.

Role for the RecBCD recombination pathway for pilE gene variation in repair-proficient Neisseria gonorrhoeae

The role of the RecBCD recombination pathway in PilE antigenic variation in Neisseria gonorrhoeae is contentious and appears to be strain dependent. In this study, N. gonorrhoeae strain MS11 recB mutants were assessed for recombination/repair. MS11 recB mutants were found to be highly susceptible to DNA treatments that caused double-chain breaks and were severely impaired for growth; recB growth suppressor mutants arose at high frequencies. When the recombination/repair capacity of strain MS11 was compared to that of strains FA1090 and P9, innate differences were observed between the strains, with FA1090 and P9 rec(+) bacteria presenting pronounced recombination/repair defects. Consequently, MS11 recB mutants present a more robust phenotype than the other strains that were tested. In addition, MS11 recB mutants are also shown to be defective for pilE/pilS recombination. Moreover, pilE/pilS recombination is shown to proceed with gonococci that carry inverted pilE loci. Consequently, a novel RecBCD-mediated double-chain-break repair model for PilE antigenic variation is proposed.

Intragenomic variation and evolution of the internal transcribed spacer of the rRNA operon in bacteria

Variation in the internal transcribed spacer (ITS) of the rRNA (rrn) operon is increasingly used to infer population-level diversity in bacterial communities. However, intragenomic ITS variation may skew diversity estimates that do not correct for multiple rrn operons within a genome. This study characterizes variation in ITS length, tRNA composition, and intragenomic nucleotide divergence across 155 Bacteria genomes. On average, these genomes encode 4.8 rrn operons (range: 2-15) and contain 2.4 unique ITS length variants (range: 1-12) and 2.8 unique sequence variants (range: 1-12). ITS variation stems primarily from differences in tRNA gene composition, with ITS regions containing tRNA-Ala + tRNA-Ile (48% of sequences), tRNA-Ala or tRNA-Ile (10%), tRNA-Glu (11%), other tRNAs (3%), or no tRNA genes (27%). Intragenomic divergence among paralogous ITS sequences grouped by tRNA composition ranges from 0% to 12.11% (mean: 0.94%). Low divergence values indicate extensive homogenization among ITS copies. In 78% of alignments, divergence is <1%, with 54% showing zero variation and 81% containing at least two identical sequences. ITS homogenization occurs over relatively long sequence tracts, frequently spanning the entire ITS, and is largely independent of the distance (basepairs) between operons. This study underscores the potential contribution of interoperon ITS variation to bacterial microdiversity studies, as well as unequivocally demonstrates the pervasiveness of concerted evolution in the rrn gene family.

Polymorphism and gene conversion of the 16S rRNA genes in the multiple rRNA operons of Vibrio parahaemolyticus

The genome sequence of a strain of Vibrio parahaemolyticus holds 11 copies of rRNA operons (rrn) with identical 16S rRNA genes (rrs). Conversely, the species type strain contains two rrs classes differing in 10 nucleotide sites within a short segment of 25 bp. Furthermore, we show here that the sequence of this particular segment largely differs between some strains of this species. We also show that of the eleven rrn operons in the species type strain, seven contain one rrs class and four the other, indicating gene conversion. Our results support the hypothesis that the rrs differences observed between strains of this species were caused by lateral transfer of an rrs segment and subsequent conversion.

Gene conversion tracts associated with crossovers in Rhizobium etli

Gene conversion has been defined as the nonreciprocal transfer of information between homologous sequences. Despite its broad interest for genome evolution, the occurrence of this mechanism in bacteria has been difficult to ascertain due to the possible occurrence of multiple crossover events that would mimic gene conversion. In this work, we employ a novel system, based on cointegrate formation, to isolate gene conversion events associated with crossovers in the nitrogen-fixing bacterium Rhizobium etli. In this system, selection is applied only for cointegrate formation, with gene conversions being detected as unselected events. This minimizes the likelihood of multiple crossovers. To track the extent and architecture of gene conversions, evenly spaced nucleotide changes were made in one of the nitrogenase structural genes (nifH), introducing unique sites for different restriction endonucleases. Our results show that (i) crossover events were almost invariably accompanied by a gene conversion event occurring nearby; (ii) gene conversion events ranged in size from 150 bp to 800 bp; (iii) gene conversion events displayed a strong bias, favoring the preservation of incoming sequences; (iv) even small amounts of sequence divergence had a strong effect on recombination frequency; and (v) the MutS mismatch repair system plays an important role in determining the length of gene conversion segments. A detailed analysis of the architecture of the conversion events suggests that multiple crossovers are an unlikely alternative for their generation. Our results are better explained as the product of true gene conversions occurring under the double-strand break repair model for recombination.

Unequal access of chromosomal regions to each other in Salmonella: probing chromosome structure with phage lambda integrase-mediated long-range rearrangements

We have investigated the fluidity of the Salmonella chromosome architecture using the phage lambda site-specific recombination system as a probe. We determined how chromosome position affects the extent of integrase-mediated recombination between pairs of inversely oriented att sites at various loci. We also investigated the accessibility of each chromosomal att site to an extrachromosomal partner carried on a low-copy plasmid. Recombination events were assayed by semi-quantitative polymerase chain reaction of the attP product. The extent of recombination between the chromosome and the plasmid was generally higher than intrachromosomal recombination except for two loci, araA::attL and galT::attL, which gave no detectable recombination with any other locus. Based on 20 intervals, we found that chromosomal locations are not equally accessible to each other. Although multiple factors probably affect accessibility, the most important is the specific combination of the end-points used. Neither the size of the intervals nor the accessibility of individual end-points to extrachromosomal sequences is as important. These results suggest that the chromosome is not completely fluid but rather organized in some way, with barriers that limit the movement of DNA within the cell. The nature of the barriers involved in chromosomal organization remains to be determined.

Evidence against reciprocal recombination as the basis for tuf gene conversion in Salmonella enterica serovar Typhimurium

The duplicate tuf genes on the Salmonella enterica serovar Typhimurium chromosome co-evolve by a RecA-, RecB-dependent gene conversion mechanism. Gene conversion is defined as a non-reciprocal transfer of genetic information. However, in a replicating bacterial chromosome there is a possibility that a reciprocal genetic exchange between different tuf genes sitting on sister chromosomes could result in "apparent" gene conversion. We asked whether the major mechanism of tuf gene conversion was classical or apparent. We devised a genetic selection that allowed us to isolate and examine both expected products from a reciprocal recombination event between the tuf genes. Using this selection we tested within individual cultures for a correlation in the frequency of jackpots as expected if recombination were reciprocal. We found no correlation, either in the frequency of each type of recombinant product, or in the DNA sequences of the products resulting from each recombination event. We conclude that the evidence argues in favor of a non-reciprocal gene conversion mechanism as the basis for tuf gene co-evolution.

Transcription-induced barriers to supercoil diffusion in the Salmonella typhimurium chromosome

Transcription and replication both influence and are influenced by superhelical changes in DNA. Explaining how supercoil movement is channeled in living chromosomes has been a major problem for 30 years. Transcription of membrane-associated proteins leads to localized hypersupercoiling of plasmid DNA, and this behavior indicates the presence of aberrant supercoil diffusion. Using the lambda Red recombination system, we constructed model domains in the Salmonella typhimurium chromosome to analyze supercoiling dynamics of regions encoding membrane proteins. Regulation of Tn10-derived tetracycline resistance involves a repressor, TetR, and a membrane-bound export pump, TetA. Strains deficient in TetR activity had 60-fold higher transcription levels (from P(A)) than TetR-positive strains. High tetA transcription caused a 10- to 80-fold decrease in the gammadelta resolution efficiency for the domain that includes the Tet module. Replacing tetA with genes encoding cytosolic proteins LacZ and Kan also caused the appearance of supercoil diffusion barriers in a defined region of the chromosome. In strains containing a functional TetR located next to a regulated lacZ reporter (P(R)tetR-P(A)lacZ), induction of transcription with chlortetracycline caused a 5-fold drop in resolution efficiency in the test domain interval. A short half-life resolvase showed that barriers appeared and disappeared over a 10- to 20-min span. These studies demonstrate the importance of transcription in chromosome structure and the plasticity of supercoil domains in bacterial chromosomes.

Genome sequence of an M3 strain of Streptococcus pyogenes reveals a large-scale genomic rearrangement in invasive strains and new insights into phage evolution

Group Astreptococcus (GAS) is a gram-positive bacterial pathogen that causes various suppurative infections and nonsuppurative sequelae. Since the late 1980s, streptococcal toxic-shock like syndrome (STSS) and severe invasive GAS infections have been reported globally. Here we sequenced the genome of serotype M3 strain SSI-1, isolated from an STSS patient in Japan, and compared it with those of other GAS strains. The SSI-1 genome is composed of 1,884,275 bp, and 1.7 Mb of the sequence is highly conserved relative to strain SF370 (serotype M1) and MGAS8232 (serotype M18), and almost completely conserved relative to strain MGAS315 (serotype M3). However, a large genomic rearrangement has been shown to occur across the replication axis between the homologous rrn-comX1 regions and between two prophage-coding regions across the replication axis. Atotal of 1 Mb of chromosomal DNA is inverted across the replication axis. Interestingly, the recombinations between the prophage regions are within the phage genes, and the genes encoding superantigens and mitogenic factors are interchanged between two prophages. This genomic rearrangement occurs in 65% of clinical isolates (64/94) collected after 1990, whereas it is found in only 25% of clinical isolates (7/28) collected before 1985. These observations indicate that streptococcal phages represent important plasticity regions in the GAS chromosome where recombination between homologous phage genes can occur and result not only in new phage derivatives, but also in large chromosomal rearrangements.

Rates and consequences of recombination between rRNA operons

A mutant strain of Escherichia coli was created by inserting a cassette encoding sucrose sensitivity and neomycin resistance (sacB-neo) into the small-subunit rRNA-encoding gene rrs in the rrnB operon. During growth in a complex medium, the cassette was lost from the population, and a complete rrs gene was restored at a rate of 5 x 10(-9) per cell division. Repair of this lesion required flanking regions of DNA that were similar to the six remaining intact rRNA operons and reestablished the full complement of seven rRNA operons. The relative fitness of strains with restored rrnB operons was 1 to 2% higher than that of the mutant strain. The rrnB operon normally contains a spacer region between the 16S and 23S rRNA-encoding genes that is similar in length and tRNA gene content to the spacer in rrnC, -E, and -G. In 2 of the 14 strains in which rrnB was restored, the spacer region had the same length as the spacer region in rrnA, -D, and -H. The requirement for flanking regions of nearly identical DNA and the replication of the spacer region from other rRNA operons during the repair of rrnB suggest that the restoration was accomplished via gene conversion. The rate of gene conversion was 10-fold less than the fixation of point mutations in the same region of the chromosome but was apparently sufficient to homogenize the sequences of rRNA genes in E. coli. These findings are discussed in the context of a conceptual model describing the presence of sequence heterogeneity in coevolving rRNA genes.

Cre-loxP recombination system for large genome rearrangements in Lactococcus lactis

We have used a new genetic strategy based on the Cre-loxP recombination system to generate large chromosomal rearrangements in Lactococcus lactis. Two loxP sites were sequentially integrated in inverse order into the chromosome either at random locations by transposition or at fixed points by homologous recombination. The recombination between the two chromosomal loxP sites was highly efficient (approximately 1 x 10(-1)/cell) when the Cre recombinase was provided in trans, and parental- or inverted-type chromosomal structures were isolated after removal of the Cre recombinase. The usefulness of this approach was demonstrated by creating three large inversions of 500, 1,115, and 1,160 kb in size that modified the lactococcal genome organization to different extents. The Cre-loxP recombination system described can potentially be used for other gram-positive bacteria without further modification.

Co-evolution of the tuf genes links gene conversion with the generation of chromosomal inversions

The tufA and tufB genes in Salmonella typhimurium co-evolve by recombination and exchange of genetic material. A model is presented which predicts that co-evolution is achieved by gene conversions and chromosomal inversions. Analysis of recombinants reveals that conversion and inversion each occur with similar rates and each depends on RecBCD activity. The model predicts sequence structures for different classes of post-recombination tuf genes. Sequence analysis reveals the presence of each of these structures and classes, with a predicted bias in the absence of mismatch repair. An implication of these data is that co-evolution of gene families can be linked with the generation of chromosomal rearrangements.

Multiple recombination events maintain sequence identity among members of the nitrogenase multigene family in Rhizobium etli

A distinctive characteristic of the Rhizobium genome is the frequent finding of reiterated sequences, which often constitute multigene families. Interestingly, these families usually maintain a high degree of nucleotide sequence identity. It is commonly assumed that apparent gene conversion between reiterated elements might lead to concerted variation among members of a multigene family. However, the operation of this mechanism has not yet been demonstrated in the Rhizobiaceae. In this work, we employed different genetic constructions to address the role of apparent gene conversion as a homogenizing mechanism between members of the plasmid-located nitrogenase multigene family in Rhizobium etli. Our results show that a 28-bp insertion into one of the nitrogenase reiterations can be corrected by multiple recombination events, including apparent gene conversion. The correction process was dependent on the presence of both a wild-type recA gene and wild-type copies of the nitrogenase reiterations. Frequencies of apparent gene conversion to the wild-type nitrogenase reiterations were the same when the insertion to be corrected was located either in cis or in trans, indicating that this event frequently occurs through intermolecular interactions. Interestingly, a high frequency of multiple crossovers was observed, suggesting that these large plasmid molecules are engaging repeatedly in recombination events, in a situation akin to phage recombination or recombination among small, high-copy number plasmids.

Recombination between rRNA operons created most of the ribotype variation observed in the seventh pandemic clone of Vibrio cholerae

Individual rrn operons and their flanking regions have been analysed in a study of the molecular basis of ribotype variation in the seventh pandemic clone of Vibrio cholerae. The genome of an early isolate of the seventh pandemic clone had nine rrn operons of which two were in tandem with other rrn operons. The site for BglI, the most discriminatory enzyme used for ribotyping, was found to be present in the 16S sequence of three of the operons of the earliest isolate. This site was observed to be gained or lost in specific operons in many later isolates, presumably by recombination, and this gave most of the ribotype variation. Additional rrn recombination events were uncovered by analysis of the 16S-23S intergenic spacers associated with each operon. Spacers of 431, 509, 607 and 711 bp were found. A total of at least eight rrn recombination events were detected. Three rrn loci were primarily involved in this recombination, with four new forms generated from that in the early strains for operon B and two new forms each for operons C and G. In addition there was variation due to deletion of tandem operons. The frequency of recombination between rrn operons was very high as there were nine new ribotypes found among 47 isolates sampled over the 33 year period of study. This means that any variation could undergo precise reversion by the same recombination event within the time frame covered by the study. Recombination between rrn operons may be a factor in ribotype variation in all systems. The recombination observed is thought to be that which results in concerted evolution and the data give an indication of the rate involved.

Gene amplification and genomic plasticity in prokaryotes

Gene amplification is a common feature of the genome of prokaryotic organisms. In this review, we analyze different instances of gene amplification in a variety of prokaryotes, including their mechanisms of generation and biological role. Growing evidence supports the concept that gene amplification be considered not as a mutation but rather as a dynamic genomic state related to the adaptation of bacterial populations to changing environmental conditions or biological interactions. In this context, the potentially amplifiable DNA regions impose a defined dynamic structure on the genome. If such structure has indeed been selected during evolution, it is a particularly challenging hypothesis.

Enhancement of somatic intrachromosomal homologous recombination in Arabidopsis by the HO endonuclease

The HO endonuclease promotes gene conversion between mating-type alleles in yeast by a DNA double-strand break at the site of conversion (the MAT-Y/Z site). As a first step toward understanding the molecular basis of homologous recombination in higher plants, we demonstrate that expression of HO in Arabidopsis enhances intrachromosomal recombination between inverted repeats of two defective beta-glucuronidase (gus) genes (GUS- test construct). One of these genes has the Y/Z site. The two genes share 2.5 kb of DNA sequence homology around the HO cut site. Somatic recombination between the two repeats was determined by using a histochemical assay of GUS activity. The frequency of Gus+ sectors in leaves of F1 plants from a cross between parents homozygous for the GUS- test construct and HO, respectively, was 10-fold higher than in F1 plants from a cross between the same plant containing the GUS- test construct and a wild-type parent. Polymerase chain reaction analysis showed restoration of the 5' end of the GUS gene in recombinant sectors. The induction of intrachromosomal gene conversion in Arabidopsis by HO reveals the general utility of site-specific DNA endonucleases in producing targeted homologous recombination in plant genomes.

Generation of Campylobacter fetus S-layer protein diversity utilizes a single promoter on an invertible DNA segment

Wild-type strains of Campylobacter fetus contain a monomolecular array of surface layer proteins (SLPs) and vary the antigenicity of the predominant SLP expressed. Reciprocal recombination events among the eight genomic SLP gene cassettes, which encode 97- to 149 kDa SLPs, permit this variation. To explore whether SLP expression utilizes a single promoter, we created mutant bacterial strains using insertional mutagenesis by rescue of a marker from plasmids. Experimental analysis of the mutants created clearly indicates that SLP expression solely utilizes the single sapA promoter, and that for variation C. fetus uses a mechanism of DNA rearrangement involving inversion of a 6.2 kb segment of DNA containing this promoter. This DNA inversion positions the sapA promoter immediately upstream of one of two oppositely oriented SLP gene cassettes, leading to its expression. Additionally, a second mechanism of DNA rearrangement occurs to replace at least one of the two SLP gene cassettes bracketing the invertible element. As previously reported promoter inversions in prokaryotes, yeasts and viruses involve alternate expression of at most two structural genes, the ability of C. fetus to use this phenomenon to express one of multiple cassettes is novel.

DNA rearrangement mediated by inverted repeats

Inverted repeats of DNA are widespread in the genomes of eukaryotes and prokaryotes and can mediate genome rearrangement. We studied rearrangement mediated by plasmid-borne inverted repeats in Escherichia coli. We show that inverted repeats can mediate an efficient and recA-independent recombination event. Surprisingly, the product of this recombination is not that of simple inversion between the inverted repeats, but almost exclusively an unusual head-to-head dimer with complex DNA rearrangement. Moreover, this recombination is dramatically reduced by increasing the distance separating the repeats. These results can be readily explained by a model involving reciprocal switching of the leading and lagging strands of DNA replication within the inverted repeats, which leads to the formation of a Holliday junction. Reciprocal strand switching during DNA replication might be a common mechanism for genome rearrangement associated with inverted duplication.

Cin-mediated recombination at secondary crossover sites on the Escherichia coli chromosome

The Cin recombinase is known to mediate DNA inversion between two wild-type cix sites flanking genetic determinants for the host range of bacteriophage P1. Cin can also act with low frequency at secondary (or quasi) sites (designated cixQ) that have lower homology to either wild-type site. An inversion tester sequence able to reveal novel operon fusions was integrated into the Escherichia coli chromosome, and the Cin recombinase was provided in trans. Among a total of 13 Cin-mediated inversions studied, three different cixQ sites had been used. In two rearranged chromosomes, the breakpoints of the inversions were mapped to cixQ sites in supB and ompA, representing inversions of 109 and 210 kb, respectively. In the third case, a 2.1-kb inversion was identified at a cixQ site within the integrated sequences. This derivative itself was a substrate for a second inversion of 1.5 kb between the remaining wild-type cix and still another cixQ site, thus resembling a reversion. In analogy to that which is known from DNA inversion on plasmids, homology of secondary cix sites to wild-type recombination sites is not a strict requirement for inversion to occur on the chromosome. The chromosomal rearrangements which resulted from these Cin-mediated inversions were quite stable and suffered no growth disadvantage compared with the noninverted parental strain. The mechanistic implications and evolutionary relevance of these findings are discussed.

Genetic control of intrachromosomal recombination

Intrachromosomal recombination between direct repeats can occur either as gene conversion events, which maintain exactly the number of repeat units, or as deletions, which reduce the number of repeat units. Gene conversions are classical recombination events that utilize the standard chromosome recombination machinery. Spontaneous deletions between direct repeats are generally recA-independent in E. coli and RAD52-independent in S. cerevisiae. This independence from the major recombination genes does not mean that deletions form through a nonrecombinational process. Deletions have been suggested to result from sister chromatid exchange at the replication fork in a recA-independent process. The same type of exchange is proposed to be RAD52-independent in Saccharomyces cerevisiae. RAD52-dependent events encompass all events that involve the initial steps of a recombination reaction, which include strand invasion to form a heteroduplex intermediate.

Use of a chromosomal inverted repeat to demonstrate that the RAD51 and RAD52 genes of Saccharomyces cerevisiae have different roles in mitotic recombination

An intrachromosomal recombination assay that monitors events between alleles of the ade2 gene oriented as inverted repeats was developed. Recombination to adenine prototrophy occurred at a rate of 9.3 x 10(-5)/cell/generation. Of the total recombinants, 50% occurred by gene conversion without crossing over, 35% by crossover and 15% by crossover associated with conversion. The rate of recombination was reduced 3,000-fold in a rad52 mutant, but the distribution of residual recombination events remained similar to that seen in the wild type strain. In rad51 mutants the rate of recombination was reduced only 4-fold. In this case, gene conversion events unassociated with a crossover were reduced 18-fold, whereas crossover events were reduced only 2.5-fold. A rad51 rad52 double mutant strain showed the same reduction in the rate of recombination as the rad52 mutant, but the distribution of events resembled that seen in rad51. From these observations it is concluded that (i) RAD52 is required for high levels of both gene conversions and reciprocal crossovers, (ii) that RAD51 is not required for intrachromosomal crossovers, and (iii) that RAD51 and RAD52 have different functions, or that RAD52 has functions in addition to those of the Rad51/Rad52 protein complex.

Construction of chromosomal rearrangements in Salmonella by transduction: inversions of non-permissive segments are not lethal

Homologous sequences placed in inverse order at particular separated sites in the bacterial chromosome (termed "permissive") can recombine to form an inversion of the intervening chromosome segment. When the same repeated sequences flank other chromosome segments ("non-permissive"), recombination occurs but the expected inversion rearrangement is not found among the products. The failure to recover inversions of non-permissive chromosomal segments could be due to lethal effects of the final rearrangement. Alternatively, local chromosomal features might pose barriers to reciprocal exchanges between sequences at particular sites and could thereby prevent formation of inversions of the region between such sites. To distinguish between these two possibilities, we have constructed inversions of two non-permissive intervals by means of phage P22-mediated transduction crosses. These crosses generate inversions by simultaneous incorporation of two transduced fragments, each with a sequence that forms one join-point of the final inversion. We constructed inversions of the non-permissive intervals trp ('34) to his ('42) and his ('42) to cysA ('50). Strains with the constructed inversions are viable and grow normally. These results show that our previous failure to detect formation of these inversions by recombination between chromosomal sequences was not due to lethal effects of the final rearrangement. We infer that the "non-permissive" character of some chromosomal segments reflects the inability of the recombination system to perform the needed exchanges between inverse order sequences at particular sites. Apparently these mechanistic problems were circumvented by the transductional method used here to direct inversion formation.