Duplications in CAENORHABDITIS ELEGANS

Thirteen chromosomal duplications, all unlinked to their linkage of origin, have been identified following X-irradiation. Ten are X-chromosome duplications, of which six are half-translocations on three autosomomal linkage groups and four are free fragments. Five of the half-translocations are homozygous fertile and two are recognizable cytologically as chromosome satellites, both of which show some mitotic instability. The free-X duplications show varying tendencies for loss. Three appear not to overlap in extent previously identified free-X duplications. The fourth carries genes from linkage group V, as well as X. Three duplications of a portion of linkage group II were identified and found to be free and quite stable in hyperploids. Some of the free duplications tend to disjoin from the X chromosome in males. New X-chromosome map data are presented.     

Recombination between Small X Chromosome Duplications and the X Chromosome in Caenorhabditis Elegans

Twelve new X chromosome duplications were identified and characterized. Eight are translocated to autosomal sites near four different telomeres, and four are free. Ten include unc-1(+), which in wild type is near the left end of the X chromosome, and two of these, mnDp72(X;IV) and mnDp73(X;f), extend rightward past dpy-3. Both mnDp72 and mnDp73 recombined with the one X chromosome in males in the unc-1-dpy-3 interval at a frequency 15- to 30-fold higher than was observed for X-X recombination in hermaphrodites in the same interval. Recombinant duplications and recombinant X chromosomes were both recovered. Recombination with the X chromosome in the unc-1-dpy-3 interval was also detected for five other unc-1(+) duplications, even though their right breakpoints lie within the interval. In hermaphrodites, mnDp72 and mnDp73 promoted meiotic X nondisjunction and recombined with an X chromosome in the unc-1-dpy-3 interval at frequencies comparable to that found for X-X recombination; mnDp72(X;IV) also promoted trisomy for chromosome IV. A mutation in him-8 IV was identified that severely reduced recombination between the two X chromosomes in hermaphrodites and between mnDp73 and the X chromosome in males. Recombination between the X chromosome and duplications of either the right end of the X or a region near but not including the left end was rare. We suggest that the X chromosome has one or more elements near its left end that promote meiotic chromosome pairing.     

Microsatellites reveal male recombination and neo-sex chromosome formation in Scaptodrosophila hibisci (Drosophilidae)

In drosophilid flies, male recombination and neo-sex chromosome formation are rare. Following the genotyping of full-sib families with 20 microsatellite markers and subsequent cytological work, we found evidence of both male recombination and neo-sex chromosome formation in Scaptodrosophila hibisci. As far as we are aware, this is the first report of male recombination and neo-sex chromosome formation co-occurring in a drosophilid fly. Two autosomal loci, Sh29c and Sh90, showed aberrant segregation of male parental alleles. We describe how an autosomal fission followed by fusion of one of the autosomal fragments to the Y chromosome to create a Y1Y2X1X2/X1X1X2X2 sex determination system provides the most parsimonious explanation of the patterns we observe. Male recombination was observed in three families, including autosomal linkage groups and the Y1/X2 linkage group. In addition to the X1 linkage group, two autosomal linkage groups were identified.     

A comprehensive linkage map of the pig based on a wild pig - Large White intercross

A comprehensive linkage map, including 236 linked markers with a total sex-average map length of about 2300 cM, covering nearly all parts of the pig genome has been established. Linkage groups were assigned to all 18 autosomes, the X chromosome and the X/Y pseudoautosomal region. Several new gene assignments were made including the assignment of linkage group U1 (EAK-HPX) to chromosome 9. The linkage map includes 77 type I loci informative for comparative mapping and 72 in situ mapped markers physically anchoring the linkage groups on chromosomes. A highly significant heterogeneity in recombination rates between sexes was observed with a general tendency towards an excess of female recombination. The average ratio of female to male recombination was estimated at 1–4:1 but this parameter varied between chromosomes as well as between regions within chromosomes. An intriguing finding was that blood group loci were overrepresented at the distal ends of linkage groups.     

The Effects of Translocations on Recombination Frequency in Caenorhabditis Elegans

In the nematode Caenorhabditis elegans, recombination suppression in translocation heterozygotes is severe and extensive. We have examined the meiotic properties of two translocations involving chromosome I, szT1(I;X) and hT1(I;V). No recombination was observed in either of these translocation heterozygotes along the left (let-362-unc-13) 17 map units of chromosome I. Using half-translocations as free duplications, we mapped the breakpoints of szT1 and hT1. The boundaries of crossover suppression coincided with the physical breakpoints. We propose that DNA sequences at the right end of chromosome I facilitate pairing and recombination. We use the data from translocations of other chromosomes to map the location of pairing sites on four other chromosomes. hT1 and szT1 differed markedly in their effect on recombination adjacent to the crossover suppressed region. hT1 had no effect on recombination in the adjacent interval. In contrast, the 0.8 map unit interval immediately adjacent to the szT1(I;X) breakpoint on chromosome I increased to 2.5 map units in translocation heterozygotes. This increase occurs in a chromosomal interval which can be expanded by treatment with radiation. These results are consistent with the suggestion that the szT1(I) breakpoint is in a region of DNA in which meiotic recombination is suppressed relative to the genomic average. We propose that DNA sequences disrupted by the szT1 translocation are responsible for determining the frequency of meiotic recombination in the vicinity of the breakpoint.     

The synaptonemal complexes of Caenorhabditis elegans: Pachytene karyotype analysis of the Dp 1 mutant and Disjunction Regulator Regions

The duplication mutant Dp1 presents morphological changes of the pachytene nuclei which include enlarged nuclei (58% greater than the wild type (WT)) and increased total length of the synaptonemal complex (SC) complement (32% greater than WT). The size of the nucleolus is similar to that of the wild type. The SC of the XX bivalent is 2.5 m long which is similar to the length in other strains. Genetic analysis (Herman et al. 1976) has shown that a duplicated segment of the X chromosome has been transposed to linkage group V in the Dp1 mutant. The present analysis, however, did not reveal the expected duplication loop in bivalent V of the heterozygous Dp1 strain. There is an average of three Disjunction Regulator Regions (DRR) per nucleus and approximately 1% X-chromosome nondisjunction which is consistent with the notion that the presence of DRRs somehow facilitates regular disjunction of the X chromosome. Statistical analysis, based on 9 different strains and 81 nuclei, indicates that there is a good correlation between the frequency of occurrence of X-chromosome nondisjunction and the number of DRRs.     

Linkage assignment of a DNA sequence (ERCC2L1) homologous to a human DNA repair gene in Xiphophorus fishes: implications for the evolutionary derivation of human chromosome 19.

Fish gene mapping studies have identified several syntenic groups showing conservation over more than 400 million years of vertebrate evolution. In particular, Xiphophorus linkage group IV has been identified as a homolog of human chromosomes 15 and 19. During mammalian evolution, loci coding for glucosephosphate isomerase, peptidase D, muscle creatine kinase, and several DNA repair genes (ERCC1, ERCC2, and XRCC1) appear as a conserved syntenic group on human chromosome 19. When X. clemenciae and X. milleri PstI endonuclease-digested genomic DNA was used in Southern analysis with a human ERCC2 DNA repair gene probe, a strongly cross-hybridizing restriction fragment length polymorphism was observed. Backcrosses to X. clemenciae from X. milleri x X. clemenciae F1 hybrids allowed tests for linkage of the ERCC2-like polymorphism to markers covering a large proportion of the genome. Statistically significant evidence for linkage was found only for ERCC2L1 and CKM (muscle creatine kinase), with a total of 41 parents and 2 recombinants (4.7% recombination, chi 2 = 35.37, P less than 0.001); no evidence for linkage to GPI and PEPD in linkage group IV was detected. The human chromosome 19 synteny of ERCC2 and CKM thus appears to be conserved in Xiphophorus, while other genes located nearby on human chromosome 19 are in a separate linkage group in this fish. If Xiphophorus gene arrangements prove to be primitive, human chromosome 19 may have arisen from chromosome fusion or translocation events at some point since divergence of mammals and fishes from a common ancestor.     

The Instability of Neurospora Duplication Dp(IL-->IR)H4250 , and Its Genetic Control

Previous work (Newmeyer and Taylor 1967) showed that a nontandem duplication, Dp(IL-->IR)H4250, is regularly produced by recombination in crosses heterozygous for the effectively terminal pericentric inversion In(IL-->IR)H4250. The duplications initially have strongly inhibited growth because they are heterozygous for mating type, which behaves like a vegetative-incompatibility (het) locus. Such cultures "escape" from the inhibition as a result of events that eliminate the mating-type heterozygosity. The product of a given escape event may be barren or fertile. (Neurospora duplications are characteristically barren; that is, when crossed, they make many perithecia but few ascospores.)-The present paper reports on a genetic analysis of the instability of Dp(IL-->IR)H4250 . Most of the barren escape products behave as if due either to mitotic crossovers, which make mating type and distal markers homozygous, or to very long deletions which uncover mating type and all distal markers; presumably the latter would retain enough duplicated material to render them barren. It is difficult to distinguish between these two possibilities, but homozygosis seems more probable and has been clearly demonstrated in one case. Only a few barren escapes could be due to short deletions or to changes at the mating-type locus.-The fertile escape products appear to be euploid. Most of these behave as if they arose by precise deletion of one or the other duplicated segment, thus restoring one of the parental sequences. A large majority of the precise deletions restore normal sequence; only a few restore inversion sequence. Preferential restoration of the normal sequence has also been found by other workers for Neurospora duplications from several other rearrangements. A hypothesis is presented to explain these findings; it is posulated that the precise deletions result from mitotic crossing over in homologous material located at chromosome tips and tip-break-points.-There is a smaller group of fertile escapes that are unlike either parental sequence; at least one of these involves a chromosome break outside the duplicated region.-Duplications in which the vegetative incompatibility is suppressed by the unlinked modifier tol are extremely barren; they only rarely lose a duplicated segment so as to become fertile.-The instability of Dp(IL-->IR)H4250 , with and without tol, is markedly altered by factors in the genetic background. The two factors studied in detail have qualitatively different effects.     

Chromosome segment duplications in Neurospora crassa and their effects on repeat-induced point mutation and meiotic silencing by unpaired DNA

The size and extent of four Neurospora crassa duplications, Dp(AR17), Dp(IBj5), Dp(OY329), and Dp(B362i), was determined by testing the coverage of RFLP markers. The first three duplications were all > approximately 350 kb and have been shown in earlier studies to act as dominant suppressors of repeat-induced point mutation (RIP) in gene-sized duplications, possibly via titration of the RIP machinery. Dp(B362i), which is only approximately 117 kb long, failed to suppress RIP. RIP suppression in gene-sized duplications by large duplications was demonstrated using another test gene, dow, and supposedly applies generally. Crosses homozygous for Dp(AR17) or Dp(IBj5) were as barren as heterozygous crosses. Barrenness of the heterozygous but not the homozygous crosses was suppressible by Sad-1, a semidominant suppressor of RNAi-dependent meiotic silencing by unpaired DNA. A model is proposed in which large duplications recessively suppress semidominant Sad-1 mutations. The wild-isolated Sugartown strain is hypothesized to contain a duplication that confers not only dominant suppression of RIP but also a barren phenotype, which is linked (9%) to supercontig 7.118 in LG VII.     

Regulation of rRNA gene number in Drosophila melanogaster: new aspects resulting from the use of free duplications

Summary We have isolated a bobbed (bb) mutant on the free duplication Dp(1; f)122bb ⁺ and we have measured the rDNA content of the bb ⁺ and the bb loci in genetic combinations in which none of the phenomena involved in the change of the rDNA redundancy occurs. We have also measured the rDNA content of the two bb loci carried by the free duplications in two different genetic combinations: (1) and females in which there are two attached X chromosomes completely deleted for the nucleolus organizer (NO) regions and there-fore the only rDNA is contributed by the free duplication; (2) X/Dp122bb ⁺ and X/Dp122bb males, in which there are two bb loci, one on the X chromosome and the other on the X free duplication.The bb ⁺ and the bb duplications produced an overall increase of the rDNA content in the two genetic conditions tested.These results are not in favour of both a cis and trans effect of the regulator locus (cr ⁺ locus) hypothesised as being involved in the disproportionate replication of rRNA genes.     

Frequency of x-ray induced mitotic recombination in genotypes with different X-Y-combination-chromosomes in Drosophila melanogaster

Summary In first and second instar larvae of Drosophila melanogaster mitotic recombination has been induced by X-rays. Resulting mosaic spots were analysed in the eyes of adult females. The five examined genotypes varied in the combination of different X-chromosomes and in the presence or absence of the duplication Dp(1;3)N ^264-58. X-chromosomes used have been elongated by proximally or distally linked arms of the Y-chromosome. The portion of Y-heterochromatin in the genome is negatively correlated with the frequency of twin mosaic spots (Fig. 1). The frequency of these spots is lower in flies bearing the duplication than in those without the duplication. With respect to the X-chromosome combinations, there are no marked differences in the frequencies of single mosaic spots (Fig. 2); with respect to the duplication they are absent. In the genotype Y ^S X/X.Y ^S prophases of neuroblast mitoses (Fig. 4) show normal pairing of homologous chromosome sections. Reasons for the different spot frequencies are discussed.

---

---

Vorgelegt von E. Hadorn     

Unequal VH gene rearrangement frequency within the large VH7183 gene family is not due to recombination signal sequence variation, and mapping of the genes shows a bias of rearrangement based on chromosomal location.

Much of the nonrandom usage of V, D, and J genes in the Ab repertoire is due to different frequencies with which gene segments undergo V(D)J rearrangement. The recombination signal sequences flanking each segment are seldom identical with consensus sequences, and this natural variation in recombination signal sequence (RSS) accounts for some differences in rearrangement frequencies in vivo. Here, we have sequenced the RSS of 19 individual V(H)7183 genes, revealing that the majority have one of two closely related RSS. One group has a consensus heptamer, and the other has a nonconsensus heptamer. In vitro recombination substrate studies show that the RSS with the nonconsensus heptamer, which include the frequently rearranging 81X, rearrange less well than the RSS with the consensus heptamer. Although 81X differs from the other 7183-I genes at three positions in the spacer, this does not significantly increase its recombination potency in vitro. The rearrangement frequency of all members of the family was determined in microMT mice, and there was no correlation between the in vitro recombination potential and V(H) gene rearrangement frequency in vivo. Furthermore, genes with identical RSS rearrange at different frequencies in vivo. This demonstrates that other factors can override differences in RSS potency in vivo. We have also determined the gene order of all V(H)7183 genes in a bacterial artificial chromosome contig and show that most of the frequently rearranging genes are in the 3' half of the region. This suggests that chromosomal location plays an important role in nonrandom rearrangement of the V(H)7183 genes.     

Construction and analysis of a two-chromosome double reciprocal translocation that functions as a ‘balancer’ inNeurospora crassa

T(IIL; VL;IIR; VR) BLNC-1 is a compound chromosome rearrangement inNeurospora crassa that combines two reciprocal translocations:T(IIL; VL) AR30 which interchanges the left end of linkage group II with the left end of linkage group V, andT(IIR;VR) ALS154 which interchanges the right end of linkage group II with the right end of linkage group V.BLNC-1 acts as a crossover suppressor for most of both linkage groups II and V since single crossovers between the rearrangement breakpoints result in progeny with lethal unbalanced duplications and deficiencies. The integrity ofBLNC-1 following meiosis was tested in crosses of markedBLNC-1 by marked Normal sequence, with markers located at critical points on linkage groups II and V. Although recombination between distal markers in the four arms was reduced markedly, double crossovers in the long intervening regions occurred with a frequency of 21%. Of these double crossovers, most were coincidental crossovers, one in each of the long intervening regions, resulting in the resolution of the complex into its component rearrangements (16%), while a minority of the double crossovers (5%) were crossovers involving only one of the two component linkage groups, and resulted in the insertion of a segment between the breakpoints. - TheBLNC-1 balancer can be used for: (1) mapping new loci to linkage groups II and V, especially for identifying markers mapping near the tips of the linkage groups; (2) for isolating genetically intact chromosomes from natural populations or for quantitative genetic studies; and (3) for studying recombinational hot-spots which can be detected as escapes from crossover suppression. -Based on experience withBLNC-1, future two-chromosome balancers should be designed with two breakpoints near, but not at, the opposite ends of the chromosome to be balanced, and the other two breakpoints close to, but spanning, the centromere of a second chromosome. Such a construction when combined with appropriately placed selective markers should prevent breakdown of the complex, and should resemble an inversion in eliminating crossover products. Contribution no. 85-218-J from the Department of Plant Pathology, Kansas Agricultural Experiment Station, Kansas State University, Manhattan.     

Induction and cleavage of Salmonella typhimurium UmuD protein

Summary Two different chromosomal locations of major genes controlling extreme resistance to potato virus X (PVX) were found by restriction fragment length polymorphism (RFLP) analysis of two populations segregating for the resistance. The resistance geneRx1 mapped to the distal end of chromosome XII, whereasRx2 was located at an intermediate position on linkage group V in a region where reduced recombination and segregation distortion have also been observed. These linkage anomalies were due to abnormal behaviour of the chromosome contributed by the resistant parent P34. The results presented were obtained using two different strategies for mapping genes of unknown location. One approach was the use of probes revealing polymorphic loci spread throughout the genome and resulted in the mapping ofRx1. The second approach was based on the assumption of possible linkage between the resistance gene and clone-specific DNA fragments introduced from a wild potato species.Rx2 was mapped by adopting this strategy.     

Determining the order of genes,centromeres, and rearrangement breakpoints inNeurospora by tests of duplication coverage

Nontandem segmental duplications provide a useful alternative to conventional recombination mapping for determining gene order in a haploid organism such asNeurospora. When an insertional or terminal rearrangement is crossed by Normal sequence, a class of progeny is produced that have a precisely delimited chromosome segment duplicated. In such Duplication progeny, a recessive gene in the Normal-sequence donor chromosome may or may not be masked (“covered”) by its dominant wild-type allele in the translocation-sequence recipient chromosome. Coverage depends upon whether the gene in question is left or right of the rearrangement breakpoint. The recessive gene will be heterozygous and covered (not expressed) if its locus is within the duplicated segment, but it will be haploid and expressed if the locus is outside the segment. Not only genes but also centromeres can be mapped by means of duplications, because genes included in. the same viable duplication must reside in the same chromosome arm. - Numerous sequences in the current genetic maps ofN. crassa have been determined using duplications. Gene order in the albino region and in the centromere region of linkage group I provide examples. Over 50 insertional or terminal rearrangements are available from which nontandem duplications of defined content can be obtained at will; collectively these cover about 75% of the genome. - Intercrosses between partially overlapping chromosome rearrangements also produce Duplication progeny containing two copies of regions between the breakpoints. The 180 mapped reciprocal translocations and inversions include numerous overlapping combinations that can be used for duplication mapping.     

The Meiotic Behavior of an Inversion in Caenorhabditis Elegans

The rearrangement hIn1(I) was isolated as a crossover suppressor for the right end of linkage group (LG) I. By inducing genetic markers on this crossover suppressor and establishing the gene order in the homozygote, hIn1(I) was demonstrated to be the first genetically proven inversion in Caenorhabditis elegans. hIn1(I) extensively suppresses recombination in heterozygotes in the right arm of chromosome I from unc-75 to unc-54. This suppression is associated with enhancement of recombination in other regions of the chromosome. The enhancement observed maintains the normal distribution of events but does not extend to other chromosomes. The genetic distance of chromosome I in inversion heterozygotes approaches 50 map units (m.u.), approximately equal to one chiasma per meiosis. This value is maintained in hIn1(I)/szT1(I;X) heterozygotes indicating that small homologous regions can pair and recombine efficiently. hIn1(I)/hT2(I;III) heterozygotes share no uninverted homologous regions and segregate randomly, suggesting the importance of chiasma formation in proper segregation of chromosomes. The genetic distance of chromosome I in these heterozygotes is less that 1 m.u., indicating that crossing over can be suppressed along an entire chromosome. Since one of our goals was to develop an efficient balancer for the right end of LGI, the effectiveness of hIn1(I) as a balancer was tested by isolating and maintaining lethal mutations. The meiotic behaviour of hIn1(I) is consistent with other genetic and cytogenetic data suggesting the meiotic chromosomes are monocentric. Rare recombinants bearing duplications and deficiencies of chromosome I were recovered from hIn1(I) heterozygotes, leading to the proposal the inversion was paracentric.     

Unstable chromosome rearrangements associated with male recombination in Drosophila melanogaster

The male recombination second chromosome 23.5 MRF isolated from the same Greek natural population with the second chromosome 31.1 MRF induced high frequencies of chromosome rearrangements, including specific deletions and duplications. A number of the duplications recovered were found to be highly unstable. The duplicated chromosome segments of the unstable duplications had been either completely or partially lost. The loss occurred most probably by excision of the corresponding segments and not by unequal crossing-over involving sister chromatids. As regards the unstable deletions, they became either shorter or longer or they showed complete restoration. Hypotheses explaining the high frequencies of the unstable chromosome mutations detected are discussed.     

Generation of a Restriction Fragment Length Polymorphism Linkage Map for Toxoplasma Gondii

We have constructed a genetic linkage map for the parasitic protozoan, Toxoplasma gondii, using randomly selected low copy number DNA markers that define restriction fragment length polymorphisms (RFLPs). The inheritance patterns of 64 RFLP markers and two phenotypic markers were analyzed among 19 recombinant haploid progeny selected from two parallel genetic crosses between PLK and CEP strains. In these first successful interstrain crosses, these RFLP markers segregated into 11 distinct genetic linkage groups that showed close correlation with physical linkage groups previously defined by molecular karyotype. Separate linkage maps, constructed for each of the 11 chromosomes, indicated recombination frequencies range from approximately 100 to 300 kb per centimorgan. Preliminary linkage assignments were made for the loci regulating sinefungin resistance (snf-1) on chromosome IX and adenine arabinoside (ara-1) on chromosome V by linkage to RFLP markers. Despite random segregation of separate chromosomes, the majority of chromosomes failed to demonstrate internal recombination events and in 3/19 recombinant progeny no intramolecular recombination events were detected. The relatively low rate of intrachromosomal recombination predicts that tight linkage for unknown genes can be established with a relatively small set of markers. This genetic linkage map should prove useful in mapping genes that regulate drug resistance and other biological phenotypes in this important opportunistic pathogen.     

Techniques for Manipulating Chromosomal Rearrangements and Their Application to DROSOPHILA MELANOGASTER. II. Translocations

Translocations have long been valued for their segregational properties. This paper extends the utility of translocations by considering recombinational derivatives of pairs of simple reciprocal translocations. Three major derivative structures are noted. One of these derivatives is suitable for use in half-tetrad experiments. A second should find use in recombining markers with translocation breakpoints. The third is an insertional-tandem duplication: it has a section of one chromosome inserted into a heterologue with a section of the latter chromosome tandemly repeated about the breaks of the insert. All of these structures are contained in "constellations" of chromosomes that regularly segregate aneuploid-1 products (informationally equivalent to nonrecombinant adjacent-1 segregants) for one of the parental translocations but do not segregate euploid products. This is in contrast to the parental T₁/T₂ constellations which segregate euploid products but not aneuploid-1 products. Methods are described for selecting translocation recombinants on the basis of this dichotomy. Several examples of translocation recombinants have been recovered with these techniques, and the recombination frequencies seem to be consistent with those observed for crossovers between inversion breakpoints. Recombinant chromosomes tend to disjoin, but it is observed that the tendency may vary according to the region involved in the recombination, and it is suggested that this difference reflects a difference in chiasmata terminalization times. Special consideration is given to insertional-tandem duplications. Large insertional-tandem duplications are useful in cytogenetic screens. Small insertional-tandem duplications are useful in gene dosage studies and other experiments that require an insert from one chromosome to another. Large duplications can be deleted to form small duplications. To generate a small insert for a specified region, it is only necessary to have one translocation with a breakpoint flanking the region of interest. The second translocation can have a breakpoint quite far from the region: an insertional-tandem duplication containing the region that has one closely flanking breakpoint can be deleted to create a smaller duplication that has two closely flanking breakpoints.     

Recombination between Chromosomal Is200 Elements Supports Frequent Duplication Formation in Salmonella Typhimurium

Spontaneous tandem chromosomal duplications are common in populations of Escherichia coli and Salmonella typhimurium. They range in frequency for a given locus from 10(-2) to 10(-4) and probably form by RecA-dependent unequal sister strand exchanges between repetitive sequences in direct order. Certain duplications have been observed previously to confer a growth advantage under specific selective conditions. Tandem chromosomal duplications are unstable and are lost at high frequencies, representing a readily reversible source of genomic variation. Six copies of a small mobile genetic element IS200 are evenly distributed around the chromosome of S. typhimurium strain LT2. A survey of 120 independent chromosomal duplications (20 for each of six loci) revealed that recombination between IS200 elements accounted for the majority of the duplications isolated for three of the loci tested. Duplications of the his operon were almost exclusively due to recombination between repeated IS200 elements. These data add further support to the idea that mobile genetic elements provide sequence repeats that play an important role in recombinational chromosome rearrangements, which may contribute to adaptation of bacteria to stressful conditions.