Study of chromosome rearrangements associated with the trpE26 mutation of Bacillus subtilis

Chromosome rearrangements involved in the formation of merodiploid strains in the Bacillus subtilis 168-166 system were explained by postulating the existence of intrachromosomal homology regions. This working hypothesis was tested by analysing sequences and restriction patterns of the, as yet uncharacterized, junctions between chromosome segments undergoing rearrangements in parent, 168 trpC2 and 166 trpE26, as well as in derived merodiploid strains. Identification, at the Ia/Ib chromosome junction of both parent strains, of a 1.3 kb segment nearly identical to a segment of prophage SPbeta established the existence of one of the postulated homology sequences. Inspection of relevant junctions revealed that a set of different homology regions, derived from prophage SPbeta, plays a key role in the formation of so-called trpE30, trpE30+, as well as of new class I merodiploids. Analysis of junctions involved in the transfer of the trpE26 mutation, i.e. simultaneous translocation of chromosome segment C and rotation of the terminal relative to the origin moiety of the chromosome, did not confirm the presence of any sequence suitable for homologous recombination. We propose a model involving simultaneous introduction of four donor DNA molecules, each comprising a different relevant junction, and their pairing with the junction regions of the recipient chromosome. The resolution of this structure, resting on homologous recombination, would confer the donor chromosome structure to the recipient, achieving some kind of 'transstamping'. In addition, a rather regular pattern of inverse and direct short sequence repeats in regions flanking the breaking points could be correlated with the initial, X-ray-induced, rearrangement.     

Merodiploid ribosomal loci arising by transformation and mutation in pneumococcus

Merodiploid states have been detected in the ery and str loci of the pneumococcal genome. They are associated with particular mutations (ery-r10 and str-d2) which add to, rather than replace their homologous sites during deoxyribonucleic acid (DNA)-mediated transformation. Markers at linked sites do not become diploid at the same time. The heterozygous condition thus produced is maintained during cell reproduction. However, in the case of the ery merodiploid at least, segregation of haploid types does occasionally occur. The transforming properties of DNA isolated from the merodiploids, taken together with the segregation patterns of the merodiploids, reveal the heterozygous condition. The merodiploid condition can be transferred via a single molecule of DNA, which can be explained by assuming that both alleles at the diploid site are integrated into the linear continuity of the bacterial chromosome. In the case of the ery merodiploid, two distinct, relatively stable but interconvertible states are recognizable. Their interconvertibility, as well as the segregation of hapliod descendants, can be explained as the result of occasional pairing of the duplicated regions with loss of one of these duplicated regions by recombination.     

Replication terminus of the Bacillus subtilis chromosome.

Bidirectional replication of the Bacillus subtilis chromosome terminates at a point on the circular chromosome which is symmetrically opposite to the replication origin. Since replication rates are similar in both "halves" of the chromosome, termination presumably occurs at the meeting point of the two replication forks. To investigate whether the DNA sequence of this region of the chromosome contributes to the termination event, we have determined the latest replicating region of a chromosome in which this DNA sequence is no longer symmetrically opposite to the origin. The merodiploid strain GSY1127 has a very large nontandem duplication (approximately 25% of the total chromosome length) in the left-hand half of the chromosome, so that size and symmetry of this chromosome are grossly different from those of normal strains. We have examined the replication order of genetic markers in this strain by measuring subtilis terminal marker for replication remains a terminal marker in the merodiploid, i.e., replicates later than a marker situated symmetrically opposite to the replication origin. These results were supported by replication orders determined by pulse-density transfer experiments during synchronous replication. The data obtained indicate that there is a preferred site for the termination of replication in the B. subtilis chromosome.     

Natural Genetic Transformation Generates a Population of Merodiploids in Streptococcus pneumoniae

Partial duplication of genetic material is prevalent in eukaryotes and provides potential for evolution of new traits. Prokaryotes, which are generally haploid in nature, can evolve new genes by partial chromosome duplication, known as merodiploidy. Little is known about merodiploid formation during genetic exchange processes, although merodiploids have been serendipitously observed in early studies of bacterial transformation. Natural bacterial transformation involves internalization of exogenous donor DNA and its subsequent integration into the recipient genome by homology. It contributes to the remarkable plasticity of the human pathogen Streptococcus pneumoniae through intra and interspecies genetic exchange. We report that lethal cassette transformation produced merodiploids possessing both intact and cassette-inactivated copies of the essential target gene, bordered by repeats (R) corresponding to incomplete copies of IS861. We show that merodiploidy is transiently stimulated by transformation, and only requires uptake of a ∼3-kb DNA fragment partly repeated in the chromosome. We propose and validate a model for merodiploid formation, providing evidence that tandem-duplication (TD) formation involves unequal crossing-over resulting from alternative pairing and interchromatid integration of R. This unequal crossing-over produces a chromosome dimer, resolution of which generates a chromosome with the TD and an abortive chromosome lacking the duplicated region. We document occurrence of TDs ranging from ∼100 to ∼900 kb in size at various chromosomal locations, including by self-transformation (transformation with recipient chromosomal DNA). We show that self-transformation produces a population containing many different merodiploid cells. Merodiploidy provides opportunities for evolution of new genetic traits via alteration of duplicated genes, unrestricted by functional selective pressure. Transient stimulation of a varied population of merodiploids by transformation, which can be triggered by stresses such as antibiotic treatment in S. pneumoniae, reinforces the plasticity potential of this bacterium and transformable species generally.     

Peptidyl-tRNA hydrolase in Bacillus subtilis,encoded by spoVC,is essential to vegetative growth,whereas the homologous enzyme in Saccharomyces cerevisiae is dispensable

Peptidyl-tRNA hydrolase in Escherichia coli, encoded by pth, is essential for recycling tRNA molecules sequestered as peptidyl-tRNA as a result of pre-mature dissociation from the ribosome during translation. Genes homologous to pth are present in other bacteria, yeast and man, but not in archaea. The homologous gene in Bacillus subtilis, spoVC, was first identified as a gene involved in sporulation. A second copy of spoVC, under the control of the xyl promoter, was integrated into B. subtilis at the amy locus. In this background, interruption of the original gene was possible provided that expression of the copy at the amy locus was induced. When spoVC was interrupted, both vegetative growth and sporulation were dependent on xylose, showing that SpoVC is essential. The role of SpoVC in sporulation is discussed and appears to be consistent with previous hypotheses that a relaxation of translational accuracy may occur during sporulation. The homologous gene in Saccharomyces cerevisiae, yHR189W, has been interrupted in both haploid and diploid strains. The mutant haploid strains remain viable, as do the yHR189W mutant spores obtained by tetrad dis-section, with either glucose or glycerol as carbon source, showing that the yHR189W gene product is dispensable for cell growth and for mitochondrial respiration.     

Cloning of an autonomously replicating sequence (ars) from the Bacillus subtilis chromosome

Cloning of an autonomously replicating sequence (ars) from the origin region of Bacillus subtilis was previously unsuccessful because of the strong incompatibility exerted by sequences located within the oriC region. Using an ars searching vector which would be selective for drug resistance even at one copy per cell, and by cloning large fragments covering as much as possible of the oriC region, we have succeeded in isolating ars fragments from the origin region of the chromosome. The minimum essential fragment contains two DnaA-box regions (non-translatable regions containing multiple repeats of DnaA-box) separated by the dnaA gene. Neither one of the DnaA-box regions by itself showed ars activity. When constructed as oriC plasmids, the dnaA coding region could be removed without affecting ars activity. The minimum distance between the two DnaA-box regions obtained so far is 274 bp. The copy number of the oriC plasmid is estimated as one per replicating chromosome. These plasmids are unstable and tend to be lost or integrated into chromosome.     

Comparison of dnaA nucleotide sequences of Escherichia coli, Salmonella typhimurium, and Serratia marcescens.

The dnaA genes of Salmonella typhimurium and Serratia marcescens, which complemented the temperature-sensitive dnaA46 mutation of Escherichia coli, were cloned and sequenced. They were very homologous to the dnaA gene of E. coli. The 63 N-terminal amino acids and the 333 C-terminal amino acids of the corresponding DnaA proteins were identical. The region in between, corresponding to 71 amino acids in E. coli, exhibited a number of changes. This variable region coincided with a nonhomologous region found in the comparison of E. coli dnaA and Bacillus subtilis "dnaA" genes. The regions upstream of the genes were also homologous. The ribosome-binding area, one of the promoters, the DnaA protein-binding site, and many GATC sites (Dam methyltransferase-recognition sequence) were conserved in these three enteric bacteria.     

Nonhomologous end-joining deficiency allows large chromosomal deletions to be produced by replacement-type recombination in Aspergillus oryzae

Gene targeting is a technique of introducing a genetic trait at a predetermined site within a genome; it is also used to eliminate undesirable chromosomal regions from the relevant genome. Thus far, replacement-type recombination between two homologous regions separated by a large nonhomologous sequence has been hardly achieved probably due to the low frequency of homologous recombination in filamentous fungi. In this study, we report the successful and highly efficient deletion by replacement-type recombination of up to 470-kb regions of chromosome 8 and 200-kb region in chromosome 3, which includes a homologue of aflatoxin gene cluster, by nonhomologous end-joining deficient strains of Aspergillus oryzae. Our study results indicate that the deficiency of nonhomologous end-joining increases the distance of nonhomologous regions in replacement-type recombination, i.e., the possible deletion range in generation of large chromosomal deletion by one cycle of replacement-type recombination is increased in nonhomologous end-joining deficient strains.     

Ectopic integration of chromosomal genes in Streptococcus pneumoniae.

When a DNA fragment containing a marker gene was ligated to random chromosomal fragments of Streptococcus pneumoniae and used to transform a recipient strain lacking that gene, the gene was integrated at various locations in the chromosome. Such ectopic integration was demonstrated for the malM gene, and its molecular basis was analyzed with defined donor molecules consisting of ligated fragments containing the malM and sul genes of S. pneumoniae. In a recipient strain deleted in the mal region of its chromosome, these constructs gave Mal+ transformants in which the malM and sul genes were now linked, with malM located between duplicate sul segments. Ectopic integration was unstable under nonselective conditions; mal(sul) ectopic insertions were lost at a rate of 0.05% per generation. Several possible mechanisms of ectopic integration were examined. The donor molecule is most likely to be a circular form of ligated homologous and nonhomologous fragments that, after entry into the cell, undergoes circular synapsis with the recipient chromosome at the site of homology, followed by repair and additive integration.     

Effects of chemical and physical mutagens on the frequency of a large genetic duplication in Salmonella typhimurium. I. Induction of duplications.

In Salmonella typhimurium a simple selection has been described to detect bacteria that are merodiploid for almost one-third of the chromosome. The selective procedure is based upon improved utilization of L-malate as the sole carbon source in merodiploid strains. The spontaneous frequency of the duplication in haploid strains is approximately 10(-4) per cell plated. Following the exposure of a haploid strain to mutagenic agents, there is a dose-dependent increase in the duplication frequency above the spontaneous level. In this paper we describe the induction of genetic duplications in Salmonella typhimurium by X-rays, ultraviolet light (UV), ethyl methanesulfonate (EMS), nitrous acid, and the azaacridine half mustard, ICR-372.     

Lethality of a dut (deoxyuridine triphosphatase) mutation in Escherichia coli.

A chloramphenicol resistance gene was cloned into a plasmid-borne dut gene, producing an insertion mutation that was then transferred to the chromosome by allelic exchange. The mutation could not be acquired by haploid strains through substitutive recombination, even when two flanking markers were simultaneously transduced. The insertion was easily transferred, via generalized transduction, into the chromosomal dut region of strains harboring a lambda dut + transducing phage; however, the resulting dut mutant/lambda dut + merodiploid could not then be cured of the prophage. This apparent lethality of the mutation could not be explained by effects on adjacent genes; the dfp gene retained complementing activity, and a ttk insertion mutant was viable. The dut gene product, deoxyuridine triphosphatase, is known to reduce incorporation of uracil into DNA and to be required in the de novo synthesis of thymidylate. Therefore, an attempt was made to determine whether the dut insertion would be tolerated in strains carrying the following compensatory mutations: dcd (dCTP deaminase) and cdd (deoxycytidine deaminase), which should reduce dUTP formation; ung (uracil-DNA glycosylase), which should reduce fatally excessive excision repair; deoA (thymidine phosphorylase), which should enhance the utilization of exogenous thymidine; and sulA, which should reduce the lethal side effects of SOS regulon induction. These mutations, either alone or in various combinations, did not permit the survival of a haploid dut insertion mutant, suggesting that the dut gene product might have an essential function apart from its deoxyuridine triphosphatase activity.     

Directed formation of chromosomal deletions in Salmonella typhimurium : targeting of specific genes induced during infection

In vivo expression technology (IVET) has resulted in the isolation of more than 100 Salmonella typhimurium genes that are induced during infection. Many of these in vivo induced (ivi) genes, as well as other virulence genes, are clustered in regions of the chromosome that are specific for Salmonella and are not present in Escherichia coli (e.g., pathogenicity islands). It would be desirable to be able to delete such putative virulence regions of the chromosome, and if the deletion removes genes that play a role in pathogenesis subsequent efforts can then be focused on individual genes that reside within that region. We therefore have developed a strategy for constructing chromosomal deletions which are not limited in size, have defined endpoints with a selectable marker at the joint point, and are not dependent on prior knowledge of sequences contained within the deleted region. Such deletion strategies can be applied to almost any bacterium with homologous recombination and to plasmid-based mutational systems where homologous recombination is not desired or feasible.     

Genes and their organization in the replication origin region of the bacterial chromosome

Genes and their organization are conserved in the replication origin region of the bacterial chromosome. To determine the extent of the conserved region in Gram-positive and Gram-negative bacteria, which diverged 1.2 billion years ago, we have further sequenced the region upstream from the dnaA genes in Bacillus subtilis and Pseudomonas putida. Fifteen open reading frames (ORFs) and 11 ORFs were identified in the 13.6 kb and the 9.8 kb fragments in B. subtilis and P. putida, respectively. Eight consecutive P. putida genes, except for one small ORF (homologous to gene 9K of Escherichia coli) in between, are homologous in sequence and relative locations to genes in B. subtilis. Altogether, 12 genes and their organization are conserved in B. subtilis and P. putida in the origin region. We found that the conserved region terminated on one side after the orf290 in P. putida (orf282 in B. subtilis). In the B. subtilis chromosome, five additional ORFs were found in between the conserved genes, suggesting that they are added after Gram-positive bacteria were diverged from the Gram-negative bacteria. One of the ORFs is a duplicate of the conserved gene. The third non-translatable region containing multiple repeats of DnaA-box (second in the case of P. putida) was found flanking gidA in both organisms. This result shows clearly that E. coli oriC and flanking genes gidA and gidB have been translocated by the inversion of some 40 kb fragment.     

Bacteriophage infection of minicells

Summary Off the transconjugants formed in theR. lupini conjugation 0.5 to 5% are merodiploids. When two differently pigmented parents are used in the crossing experiment the diploid transconjugants can be differentiated from the haploid recombinants by their additive pigmentation type. The segregation patterns of these diploid clones were analyzed. The results are in agreement with the theory that the exogenotic donor DNA can be integrated at different sites of the homologous recipient chromosomal region forming a tandem sequence. Consequently the segregants of these merodiploid clones are formed by endochromosomal recombination. This work was supported by the Deutsche Forschungsgemeinschaft and Stiftung Volkswagenwerk.     

Synaptic Adjustment of Inversion Loops in Neurospora Crassa

Heterozygotes for three long inversions on chromosome 1 were analyzed by serial reconstruction from electron micrographs. Measurements of loop lengths at different meiotic prophase substages revealed that the homologous synapsis of the inverted region was gradually replaced by nonhomologous synapsis as loops were eliminated during pachytene. This synaptic adjustment was apparently not affected by crossovers which occurred within the 150- and 160-cM long loops.     

Coupled homologous and nonhomologous repair of a double-strand break preserves genomic integrity in mammalian cells

DNA double-strand breaks (DSBs) may be caused by normal metabolic processes or exogenous DNA damaging agents and can promote chromosomal rearrangements, including translocations, deletions, or chromosome loss. In mammalian cells, both homologous recombination and nonhomologous end joining (NHEJ) are important DSB repair pathways for the maintenance of genomic stability. Using a mouse embryonic stem cell system, we previously demonstrated that a DSB in one chromosome can be repaired by recombination with a homologous sequence on a heterologous chromosome, without any evidence of genome rearrangements (C. Richardson, M. E. Moynahan, and M. Jasin, Genes Dev., 12:3831-3842, 1998). To determine if genomic integrity would be compromised if homology were constrained, we have now examined interchromosomal recombination between truncated but overlapping gene sequences. Despite these constraints, recombinants were readily recovered when a DSB was introduced into one of the sequences. The overwhelming majority of recombinants showed no evidence of chromosomal rearrangements. Instead, events were initiated by homologous invasion of one chromosome end and completed by NHEJ to the other chromosome end, which remained highly preserved throughout the process. Thus, genomic integrity was maintained by a coupling of homologous and nonhomologous repair pathways. Interestingly, the recombination frequency, although not the structure of the recombinant repair products, was sensitive to the relative orientation of the gene sequences on the interacting chromosomes.     

Allelic and Ectopic Interactions in Recombination-Defective Yeast Strains

Ectopic recombination in the yeast Saccharomyces cerevisiae has been investigated by examining the effects of mutations known to alter allelic recombination frequencies. A haploid yeast strain disomic for chromosome III was constructed in which allelic recombination can be monitored using leu2 heteroalleles on chromosome III and ectopic recombination can be monitored using ura3 heteroalleles on chromosomes V and II. This strain contains the spo13-1 mutation which permits haploid strains to successfully complete meiosis and which rescues many recombination-defective mutants from the associated meiotic lethality. Mutations in the genes RAD50, SPO11 and HOP1 were introduced individually into this disomic strain using transformation procedures. Mitotic and meiotic comparisons of each mutant strain with the wild-type parental strain has shown that the mutation in question has comparable effects on ectopic and allelic recombination. Similar results have been obtained using diploid strains constructed by mating MATa and MAT alpha haploid derivatives of each of the disomic strains. These data demonstrate that ectopic and allelic recombination are affected by the same gene products and suggest that the two types of recombination are mechanistically similar. In addition, the comparison of disomic and diploid strains indicates that the presence of a chromosome pairing partner during meiosis does not affect the frequency of ectopic recombination events involving nonhomologous chromosomes.     

PCR-mediated one-step deletion of targeted chromosomal regions in haploid <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Chromosome rearrangements, especially chromosomal deletions, have been exploited as important resources for functional analysis of genomes. To facilitate this analysis, we applied a previously developed method for chromosome splitting for the direct deletion of a designed internal or terminal chromosomal region carrying many nonessential genes in haploid Saccharomyces cerevisiae. The method, polymerase chain reaction (PCR)-mediated chromosomal deletion (PCD), consists of a two-step PCR and one transformation per deletion event. In this paper, we show that the PCD method efficiently deletes internal regions in a single transformation. Of the six chromosomal regions targeted for deletion by this method, five regions (16 to 38 kb in length) containing 10 to 19 nonessential genes were successfully eliminated at high efficiency. The one targeted region on chromosome XIII that was not deleted was subsequently found to contain sequences essential for yeast growth. While 14 individual genes in this region have been reported to be nonessential, synthetic lethal interactions may occur among these nonessential genes. Phenotypic analysis showed that four deletion strains still exhibited normal growth while possible synthetic growth defects were observed in another strain harboring a 19-gene deletion on chromosome XV. These results demonstrate that the PCD method is a useful tool for deleting genes and for analyzing their functions in defined chromosomal regions.