dif, a recA-independent recombination site in the terminus region of the chromosome of Escherichia coli.

dif (deletion induced filamentation) is a newly identified locus that lies within the terminus region of the Escherichia coli chromosome. The Dif phenotype was characterized by a subpopulation of filamentous cells with abnormal nucleoids and induction of the SOS repair system. Interactions between dif-carrying plasmids as well as between such plasmids and the bacterial chromosome demonstrated that dif is a cis-acting, recA-independent recombination site. Filamentation continued in dif mutants in which SOS-associated division inhibitors were inoperative, which showed that induction of these inhibitors was not the primary cause of filamentation. Filamentation was not observed in dif recA or dif recBC mutants, which were unable to carry out homologous recombination. The dif site shows homology with the cer site of plasmid ColE1, which resolves plasmid multimers to monomers. It is proposed that dif functions to resolve dimeric chromosomes produced by sister chromatid exchange, and that the Dif phenotype is due to the inability of these mutants to resolve multimers prior to cell division.     

Proteins encoded by the Escherichia coli replication terminus region.

The replication terminus region (31 to 35 min) of the Escherichia coli chromosome contains very few mapped genes (two per min) compared with the remainder of the chromosome, and much of the DNA appears dispensable. In order to determine whether, despite this, the terminus region consists of protein-coding sequences, we cloned 44 kb (1 min) of terminus region DNA (that surrounding trg at 31.4 min) and examined its ability to catalyze protein synthesis in vitro or in minicells. We were able to account for more than half the coding capacity of the cloned DNA with proteins synthesized in these systems, indicating that the sparsity of mapped genes in the terminus region does not result from a lack of identifiable coding sequences. We can therefore conclude that the terminus region is composed mainly of expressable, albeit inessential, protein-encoding genes.     

Site-specific recA-independent recombination (fusion) of pMB8-related replicons in Escherichia coli in the region of the replication origins

Escherichia coli recA+ and recA- cells were co-transformed with a mixture of pMB9 (Tcr) and pST8-26 (Apr, pBR325 derivative) plasmid DNAs followed by selection on plates containing both tetracycline and ampicillin. A set of stable Tcr Apr derivatives was isolated from these transformants. Many of the stable Tcr Apr segregants contained fused pMB9::pST8-26 plasmids with lengths that were about 0.8 kb longer than the sum of the lengths of the parental plasmids; one plasmid (pTF8) was about 1.5 kb shorter. The fusion was not stimulated by UV irradiation of co-transformants and occurred both in recA+ and recA- genetic backgrounds. Restriction analysis of the fused plasmids showed the two replicons were in the same relative orientation, and also indicated unique points of fusion in most cases (in 9 out of 10) which are localised within the 1.6-kb regions around the replication origins (RO). Because the fusion of plasmids of the type used in this study was not described before we have tentatively named it RO-fusion (Replication-Origin-fusion).     

Molecular cloning of the region of the terminus of Escherichia coli K-12 DNA replication.

A series of plasmids have been isolated either by ligation of defined restriction fragments to plasmid pBR325 or by screening of a cosmid bank by in situ colony hybridization. Together with one previously isolated plasmid, they spanned 86% of the 30.5- to 34-min region of the genetic map of Escherichia coli K-12. Physical analysis of these plasmids and hybridizations to Southern blots confirmed the endonuclease map of this region, with the exception of a 9.3-kilobase pair inversion.     

Location of sites that inhibit progression of replication forks in the terminus region of Escherichia coli.

We used a Southern hybridization assay to locate precisely the sites at which DNA replication is arrested in the terminus region of the Escherichia coli chromosome. The assay was based on the properties of restriction fragments that contain stalled replication forks. Replication forks that entered the terminus from the clockwise direction with respect to the genetic map were inhibited near manA at a site called T2, which we located at kilobase 442 on the physical map of Bouché (J. P. Bouché, J. Mol. Biol. 154:1-20, 1982). Those that entered the terminus region traveling in the counterclockwise direction were inhibited near pyrF at a site called T1, which we located at kilobase 90. In each case we found only a single, precise site of arrest. Inhibition at T1 was not detectable in our assay in strains lacking the trans-acting locus tus, which is located near T2 and is required for T1 to function. We demonstrated that the sites of inhibition are also used during termination of replication in exponentially growing, wild-type cells. In all previous studies on the terminus of E. coli, inhibition has only been detected in strains that were modified so that the origin used was placed near the terminus to force the use of the sites of inhibition.     

Cloning of the contiguous 165-kilobase-pair region around the terminus of Escherichia coli K-12 DNA replication.

Escherichia coli K-12 chromosomal DNA was partially digested with either EcoRI or HindIII, and cosmid libraries were constructed. By screening these libraries, a series of partially overlapping clones which covered the terC region was isolated. The cloned area spanned about 165 kilobase pairs, corresponding to the 29.7-to-33.2-min region of the genetic map of the E. coli chromosome.     

The replication origin region of Escherichia coli: nucleotide sequence and functional units

The minichromosome pCM959 contains the DNA segment from bp -677 (left) to bp + 3335 (right) of the Escherichia coli replication origin, oriC. The nucleotide sequence of this plasmid was determined. The coding regions for proteins were identified, and the possible function of those proteins is discussed. Within oriC two extended systems of dyad symmetry were found, and their possible significance is considered.     

Multiple IS insertion sequences near the replication terminus in Escherichia coli K-12.

In order to assess the feasibility of semi-automatic procedures for large genome sequencing, a fragment of 9.4 kb of Escherichia coli chromosomal DNA isolated at random was sequenced. It was found to map at 30 min on the chromosome map and to harbour two insertion sequences (IS2 and IS30) as well as several putative coding sequences which had no feature in common with known proteins.     

The segregation of the Escherichia coli origin and terminus of replication

Escherichia coli chromosome replication forks are tethered to the cell centre. Two opposing models describe how the chromosomes segregate. In the extrusion-capture model, newly replicated DNA is fed bi-directionally from the forks toward the cell poles, forming new chromosomes in each cell half. Starting with the origins, chromosomal regions segregate away from their sisters progressively as they are replicated. The termini segregate last. In the sister chromosome cohesion model, replication produces sister chromosomes that are paired along much of their length. The origins and most other chromosomal regions remain paired until late in the replication cycle, and all segregate together. We use a combination of microscopy and flow cytometry to determine the relationship of origin and terminus segregation to the cell cycle. Origin segregation frequently follows closely after initiation, in strong support of the extrusion-capture model. The spatial disposition of the origin and terminus sequences also fits this model. Terminus segregation occurs extremely late in the cell cycle as the daughter cells separate. As the septum begins to invaginate, the termini of the completed sister chromosomes are transiently held apart at the cell centre, on opposite sides of the cell. This may facilitate the resolution of topological linkages between the chromosomes.     

Preferential unequal recombination in the glyS region of the Escherichia coli chromosome.

Duplications of the Escherichia coli chromosomal region carrying the glyS and xylloci can be selected by deoxyadenosine treatment of trpA36 glyS_LglyTsu_AGA or (glyUsu_AGA) cultures. The deoxyadenosine lowers the suppression efficiency of these missense suppressors, and growth is severely limited by the resulting tryptophan starvation. Prolonged growth in the presence of 250 μg deoxyadenosine/ml leads to the accumulation of mutants with two (or more) copies of the allele for glycyl-transfer RNA synthetase, glyS_L. The same duplication is obtained each time the selective pressure is applied. This was shown by physically isolating the duplicated region in the form of circular DNA excised from the duplication by recombination. In repeated experiments, a circular species 140,000 base-pairs in size was isolated. These results are interpreted as showing that there are two loci, one on each side of the glyS locus, and spaced 140,000 base-pairs apart, which are prone to recombining with each other in a manner leading to a genetic duplication.     

Expansion of DNA repeats in Escherichia coli: effects of recombination and replication functions.

Duplication or expansion of directly repeated sequence elements is associated with a number of human genetic diseases. To study the mechanisms of repeat expansion, we have developed a plasmid assay in Escherichia coli. Our assay involves two simple repeats of 787 bp in length; expansion to three or more copies of the repeat can be selected by restoration of an intact tetracycline-resistance gene. Expansions occurred at relatively high rates, >10(-5), in the population. Both RecA-dependent recombination and RecA-independent slipped misalignments contributed to the observed expansion events. Mutations that impair DNA polymerase III (DnaE, DnaQ subunits) or the replication fork helicase, DnaB, stimulated both RecA-dependent and RecA-independent expansion events. In these respects, the properties of repeat expansion resemble repeat deletion and suggest that difficulties in DNA replication may trigger both classes of rearrangements. About 20% of the RecA-independent expansion events are accompanied by reciprocal sister-chromosome exchange, producing dimeric plasmids carrying one triplicated and one deleted locus. These products are explained by a model involving misaligned strands across the replication fork. This model predicts that the location of a replication stall site may govern the types of resulting rearrangements. The specific location of such a stall site can also, in theory, account for propensity towards expansion or deletion of repeat arrays. This may have relevance to trinucleotide repeat expansion in human genetic disease.     

Hyperrecombination in the terminus region of the Escherichia coli chromosome: possible relation to nucleoid organization.

The terminus region of the Escherichia coli chromosome is the scene of frequent homologous recombination. This can be demonstrated by formation of deletions between directly repeated sequences which flank a genetic marker whose loss can be easily detected. We report here that terminal recombination events are restricted to a relatively large terminal recombination zone (TRZ). On one side of the TRZ, the transition from the region with a high excision rate to the normal (low) excision rates of the rest of the chromosome occurs along a DNA stretch of less than 1 min. No specific border of this domain has been defined. To identify factors inducing terminal recombination, we examined its relation to two other phenomena affecting the same region, site-specific recombination at the dif locus and site-specific replication pausing. Both the location and the efficiency of terminal recombination remained unchanged after inactivation of the dif-specific recombination system. Similarly, inactivation of site-specific replication pausing or displacement of the replication fork trap so that termination occurs about 200 kb away from the normal region had no clear effect on this phenomenon. Therefore, terminal recombination is not a direct consequence of either dif-specific recombination or replication termination. Furthermore, deletions encompassing the wild-type TRZ do not eliminate hyperrecombination. Terminal recombination therefore cannot be attributed to the activity of some unique sequence of the region. A possible explanation of terminal hyperrecombination involves nucleoid organization and its remodeling after replication: we propose that post replicative reconstruction of the nucleoid organization results in a displacement of the catenation links between sister chromosomes to the last chromosomal domain to be rebuilt. Unrelated to replication termination, this process would facilitate interactions between the catenated molecules and would make the domain highly susceptible to recombination between sister chromosomes.     

Activity of the replication terminus of plasmid R6K in hybrid replicons in Escherichia coli.

Hybrids between the antibiotic resistance plasmid R6K and RSF2124, a derivative of plasmid ColEl were constructed in vetro. These hybrids exhibit the replication properties of both parents in Escherichia coli, including the use of either the R6K or the ColEl origin of replication during logarithmic phase growth. Incompatibility properties of both parental plasmids also are expressed by the hybrid plasmids. Analysis of replicative intermediates showed that the asymmetric terminus of R6K was functional in the hybrids. In the absence of protein synthesis where replication of the hybrid plasmid is initiated only from the ColE1 origin, the R6K terminus either prevents or severely impedes the progress of the replication fork. The activity of the R6K terminus region is expressed independent of the direction of DNA replication and in the absence of the R6K replication origin.     

Identification of the DNA sequence from the E. coli terminus region that halts replication forks

The terminus region of the E. coli chromosome contains two loci, T1 and T2, that inhibit the progress of replication forks and require the trans-acting factor tus. We have identified a 23 bp terminator signal at T1 and T2 that is within 100 bp of the sites of replication arrest. When an oligodeoxyribonucleotide containing the terminator signal was inserted into a plasmid, replication was halted only in a tus+ strain and when the terminator signal was oriented properly. We also found this terminator sequence in the terminus region of the plasmid R6K and in the origin region of RepFIIA class plasmids. In addition, we found striking similarities between the E. coli terminator signal and the terminator sequence of B. subtilis.     

P1 transduction map spanning the replication terminus of Escherichia coli K12

Summary The region of the E. coli chromosome that contains the replication terminus has not previously been spanned by P1 cotransduction. We have used Tn5, Tn9 and Tn10 transposons inserted in this region as genetic markers, and have constructed a genetic map that extends from fnr (min 29.3) to manA (min 35.7). The relevant transposons that have been mapped in this region and which are described in this report are trgl::Tn5 (min 31.1), zdc-235::Tn10 (min 32.3), zdd-230::Tn9 (min 33.3), and zde-234::Tn10 (min 34.2). The size of this region as determined by P1 cotransduction is very similar to previous estimates obtained by bacterial conjugation.     

RecA-mediated rescue of Escherichia coli strains with replication forks arrested at the terminus

The recombinational rescue of chromosome replication was investigated in Escherichia coli strains with the unidirectional origin oriR1, from the plasmid R1, integrated within oriC in clockwise (intR1(CW)) or counterclockwise (intR1(CC)) orientations. Only the intR1(CC) strain, with replication forks arrested at the terminus, required RecA for survival. Unlike the strains with RecA-dependent replication known so far, the intR1(CC) strain did not require RecBCD, RecF, RecG, RecJ, RuvAB, or SOS activation for viability. The overall levels of degradation of replicating chromosomes caused by inactivation of RecA were similar in oriC and intR1(CC) strains. In the intR1(CC) strain, RecA was also needed to maintain the integrity of the chromosome when the unidirectional replication forks were blocked at the terminus. This was consistent with suppression of the RecA dependence of the intR1(CC) strain by inactivating Tus, the protein needed to block replication forks at Ter sites. Thus, RecA is essential during asymmetric chromosome replication for the stable maintenance of the forks arrested at the terminus and for their eventual passage across the termination barrier(s) independently of the SOS and some of the major recombination pathways.     

A newly identified DNA replication terminus site, TerE, on the Escherichia coli chromosome.

To search for heretofore unidentified DNA replication termination (Ter) sites on the Escherichia coli chromosome, we screened the entire Kohara lambda bacteriophage library using as probes the four known 22-bp Ter sequences. We found a Ter site, which we named TerE, located at 23.2 min on the linkage map. TerE inhibits only counterclockwise DNA replication. Macroscopically, five Ter sites are located in a periodic arrangement on the genome.