Localized remodeling of the Escherichia coli chromosome: the patchwork of segments refractory and tolerant to inversion near the replication terminus.

The behavior of chromosomal inversions in Escherichia coli depends upon the region they affect. Regions flanking the replication terminus have been termed nondivisible zones (NDZ) because inversions ending in the region were either deleterious or not feasible. This regional phenomenon is further analyzed here. Thirty segments distributed between 23 and 29 min on the chromosome map have been submitted to an inversion test. Twenty-five segments either became deleterious when inverted or were noninvertible, but five segments tolerated inversion. The involvement of polar replication pause sites in this distribution was investigated. The results suggest that the Tus/pause site system may forbid some inversion events, but that other constraints to inversion, unrelated to this system, exist. Our current model for deleterious inversions is that the segments involved carry polar sequences acting in concert with other polar sequences located outside the segments. The observed patchwork of refractory and tolerant segments supports the existence of several NDZs in the 23- to 29-min region. Microscopic observations revealed that deleterious inversions are associated with high frequencies of abnormal nucleoid structure and distribution. Combined with other information, the data suggest that NDZs participate in the organization of the terminal domain of the nucleoid.

Interplay between recombination, cell division and chromosome structure during chromosome dimer resolution in Escherichia coli.

Chromosome dimers form in bacteria by recombination between circular chromosomes. Resolution of dimers is a highly integrated process involving recombination between dif sites catalysed by the XerCD recombinase, cell division and the integrity of the division septum-associated FtsK protein and the presence of dif inside a restricted region of the chromosome terminus, the dif activity zone (DAZ). We analyse here how these phenomena collaborate. We show that (i) both inter- and intrachromosomal recombination between dif sites are activated by their presence inside the DAZ; (ii) the DAZ-specific activation only occurs in conditions supporting the formation of chromosome dimers; (iii) overexpression of FtsK leads to a general increase in dif recombination irrespective of dif location; (iv) overexpression of FtsK does not improve the ability of dif sites inserted outside the DAZ to resolve chromosome dimers. Our results suggest that the formation of an active XerCD-FtsK-dif complex is restricted to when a dimer is present, the features of chromosome organization that determine the DAZ playing a central role in this control.

Polarization of the Escherichia coli chromosome. A view from the terminus.

The E. coli chromosome replication arms are polarized by motifs such as RRNAGGGS oligomers, found preferentially on leading strands. Their skew increases regularly from the origin to dif (the site in the center of the terminus where chromosome dimer resolution occurs), to reach a value of 90% near dif. Convergent information indicates that polarization in opposite directions from the dif region controls tightly the activity of dif, probably by orienting mobilization of the terminus at cell division. Another example of polarization is the presence, in the region peripheral to the terminus, of small non-divisible zones whose inversion interferes with spatial separation of sister nucleoids. The two phenomena may contribute to the organization of the Ter macrodomain.

Functional polarization of the Escherichia coli chromosome terminus: the dif site acts in chromosome dimer resolution only when located between long stretches of opposite polarity.

In Escherichia coli, chromosome dimers are generated by recombination between circular sister chromosomes. Dimers are lethal unless resolved by a system that involves the XerC, XerD and FtsK proteins acting at a site (dif) in the terminus region. Resolution fails if dif is moved from its normal position. To analyse this positional requirement, dif was transplaced to a variety of positions, and deletions and inversions of portions of the dif region were constructed. Resolution occurs only when dif is located at the convergence of multiple, oppositely polarized DNA sequence elements, inferred to lie in the terminus region. These polar elements may position dif at the cell septum and be general features of chromosome organization with a role in nucleoid dynamics.

Prophage lambda induces terminal recombination in Escherichia coli by inhibiting chromosome dimer resolution. An orientation-dependent cis-effect lending support to bipolarization of the terminus.

A prophage lambda inserted by homologous recombination near dif, the chromosome dimer resolution site of Escherichia coli, is excised at a frequency that depends on its orientation with respect to dif. In wild-type cells, terminal hyper- (TH) recombination is prophage specific and undetectable by a test involving deletion of chromosomal segments between repeats identical to those used for prophage insertion. TH recombination is, however, detected in both excision and deletion assays when Deltadif, xerC, or ftsK mutations inhibit dimer resolution: lack of specialized resolution apparently results in recombinogenic lesions near dif. We also observed that the presence near dif of the prophage, in the orientation causing TH recombination, inhibits dif resolution activity. By its recombinogenic effect, this inhibition explains the enhanced prophage excision in wild-type cells. The primary effect of the prophage is probably an alteration of the dimer resolution regional control, which requires that dif is flanked by suitably oriented (polarized) stretches of DNA. Our model postulates that the prophage inserted near dif in the deleterious orientation disturbs chromosome polarization on the side of the site where it is integrated, because lambda DNA, like the chromosome, is polarized by sequence elements. Candidate sequences are oligomers that display skewed distributions on each oriC-dif chromosome arm and on lambda DNA.

Ndd, the bacteriophage T4 protein that disrupts the Escherichia coli nucleoid, has a DNA binding activity.

Early in a bacteriophage T4 infection, the phage ndd gene causes the rapid destruction of the structure of the Escherichia coli nucleoid. Even at very low levels, the Ndd protein is extremely toxic to cells. In uninfected E. coli, overexpression of the cloned ndd gene induces disruption of the nucleoid that is indistinguishable from that observed after T4 infection. A preliminary characterization of this protein indicates that it has a double-stranded DNA binding activity with a preference for bacterial DNA rather than phage T4 DNA. The targets of Ndd action may be the chromosomal sequences that determine the structure of the nucleoid.

Unraveling a region-specific hyper-recombination phenomenon: genetic control and modalities of terminal recombination in Escherichia coli.

The propensity of the terminus of the Escherichia coli chromosome for recombination has been further explored, using a test based on the selectable loss of a lambda prophage inserted between repeated sequences from Tn10. Terminal recombination appears region-specific and unrelated to replication termination in a strain harboring a major chromosomal rearrangement. It requires RecBC(D) activity and must therefore occur between sister chromosomes, to conserve genomic integrity in spite of DNA degradation by RecBCD. Terminal recombination is maximal in the dif region and its intensity on either side of this recombination site depends on the orientation of the repeated sequences, probably because of the single chi site present in each repeat. Additional observations support the model that the crossover is initiated by single-strand invasion between sister chromosomes followed by RecBCD action as a consequence of DNA breakage due to the initial invasion event. Crossover location within repeats inserted at dif position supports the possibility that sister chromosomes are tightly paired in the centre of the terminal recombination zone. These data reinforce the model that postreplicative reconstruction of nucleoid organization creates a localized synapsis between the termini of sister chromosomes.

Restriction of the activity of the recombination site dif to a small zone of the Escherichia coli chromosome.

The recombination site dif is the target on the Escherichia coli chromosome of the site-specific recombinases XerC and XerD. The dif/XerC-D system plays a role during the cell cycle, probably by favoring sister chromosome monomerization or separation. A phenomenon of regional control over dif activity, also analyzed in this issue, is demonstrated here by translocation of dif to a series of loci close to the normal locus. We found that the site is physiologically active only within a narrow zone around its natural position. Competence for dif activity does not depend on the sequence of the normal dif activity zone (DAZ), because delta(dif) deletions larger than the DAZ result in Dif+ bacteria when dif is reinserted at the junction point. Although dif maps where replication normally terminates, termination of replication is not the elicitor. A strain with a large inversion that places dif and its surrounding region close to oriC remains Dif+, even when a Tus- mutation allows replication to terminate far away from it. Preliminary data suggest the possibility that specialized sequences separate the competent zone from the rest of the chromosome. We suspect that these sequences are members of a set of sequences involved in a polarized process of postreplicative reconstruction of the nucleoid structure. We propose that this reconstruction forces catenation links between sister chromosomes to accumulate within the DAZ, where they eventually favor recombination at dif.

The effects on Escherichia coli of expression of the cloned bacteriophage T4 nucleoid disruption (ndd) gene.

Immediately after T4 bacteriophage infection, the Escherichia coli nucleoid undergoes rapid delocalization. The ndd gene of T4 is responsible for this nuclear disruption phenomenon. We have cloned two alleles of this gene and studied the effects of their expression on E. coli cells. We have shown that the Ndd protein (i) is able to reproduce the disruption of the nucleoid characteristic of T4 infection, (ii) is highly toxic and results in a logarithmic decrease in cell viability, and (iii) inhibits genomic DNA replication by blocking progression of replication forks. Induction of Ndd does not result in degradation of genomic DNA and does not significantly alter the general processes of transcription and translation during the entire period of exponential cell death. These results support the notion that the target of Ndd is some aspect of the nucleoid architecture.

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.

Plasmid pSC101 harbors a recombination site, psi, which is able to resolve plasmid multimers and to substitute for the analogous chromosomal Escherichia coli site dif.

Plasmid pSC101 harbors a 28-bp sequence which is homologous to dif, the target site of the XerC/XerD-dependent recombination system in Escherichia coli. Using a technique which allows very sensitive detection of plasmid loss, we show that recombination at this site, termed psi for pSC101 stabilized inheritance, causes a moderate increase in pSC101 stability. The role of the psi sequence in site-specific recombination has been explored in two other contexts. It was cloned in a derivative of plasmid p15A and inserted into the chromosome in place of dif. In the first situation, psi activity requires accessory sequences and results in multimer resolution; in the second situation, it suppresses the effects of the dif deletion and can promote intermolecular exchanges. Thus, psi is a site whose recombinational activity depends on the context, the first in the cer/dif family known to exhibit such flexibility.

Direct PCR sequencing of the ndd gene of bacteriophage T4: identification of a product involved in bacterial nucleoid disruption.

The rapid disruption of the Escherichia coli nucleoid after T4 infection requires the activity of the phage-encoded ndd gene. We have genetically identified the sequence encoding ndd. Determination of the sequence of a 2.5-kb segment including ndd closed the last significant gap in the sequence of the T4 genome. This analysis was performed on PCR-amplified fragments that were purified by gel-exclusion chromatography and then submitted to linear amplification cycle sequencing. This technology permitted sequence comparison of two ndd mutants (ndd44 and ndd98) with the wild-type gene. The analysis of ndd from six bacteriophages of the T-even family indicated that the protein encoded by this nonessential gene is surprisingly conserved.

Analysis and possible role of hyperrecombination in the termination region of the Escherichia coli chromosome.

The frequency of excisive homologous recombination has been measured at various positions along the Escherichia coli chromosome. The reporter system makes use of a lambda cI857 prophage integrated by homologous recombination within Tn5 or Tn10 transposons already installed at known positions in the E. coli chromosome. The excision frequency per cell and per generation was determined by monitoring the evolution of the relative number of temperature-resistant (cured) bacteria is a function of the age of the cultures. Excisions, due to RecA-dependent homologous exchanges, appeared to occur more frequently in the preferential termination zone for chromosome replication. The highest frequency of excision observed is compatible with a recombination event at each replication cycle in this region. On the basis of these data, we propose a model involving homologous recombination in the final steps of bacterial chromosome replication and separation.

Constraints in chromosomal inversions in Escherichia coli are not explained by replication pausing at inverted terminator-like sequences.

Regions close to the replication terminus of the Escherichia coli chromosome are strongly refractory to genomic inversions. Since these regions also harbour polar replication terminator-like sequences or pause sites, we have investigated the possibility that slowing of replication as a result of pausing at inverted pause sites is responsible for inability to isolate stable inversions affecting these regions. A mutation in the tus gene is known to abolish replication pausing at terminators. We show here that the distribution of invertible and noninvertible segments along the chromosome is not affected by tus mutations. This observation eliminates replication pausing as a cause for the reduced fitness of bacteria harbouring certain chromosomal inversions.

Chromosome replication pattern in dam mutants of Escherichia coli.

The replication cycle of Escherichia coli dam mutants was analysed and compared with that of isogenic Dam+ strains. Marker frequency analyses indicated no gross difference between the strains. In the Dam- as well as in the Dam+ bacteria, initiation most likely occurs at oriC, replication forks move at a constant and invariant velocity, and termination takes place in the terC region. An analysis of replication terminator activity indicated that this activity is unaffected by the methylation status. Taken together with previous results, our data are compatible with Dam methylation controlling initiation timing but no subsequent step of the replication process.

Properties of new Escherichia coli Hfr strains constructed by integration of pSC101-derived conjugative plasmids.

Conjugative temperature-sensitive plasmids were derived from pSC101. These plasmids are useful in genetic analysis for two reasons: (i) they render possible the construction of new Hfr lines by plasmid integration at predetermined chromosomal loci via Tn10 inverse transposition, and (ii) the Hfr characters are transducible via bacteriophage P1. We also showed that replication from pSC101 origin is deleterious for the plasmid-chromosome fusion.

The terminus of the Escherichia coli chromosome is flanked by several polar replication pause sites.

Replication of two small 'constrained' regions of the Escherichia coli chromosome, one bordered by replication terminator T1 and the other by T2, displays normal velocity in the normal direction whereas it is much slower in the opposite direction (de Massy et al., 1987). The presence of multiple polar terminators has been investigated, using a bacteriophage lambda derivative which provides a replication origin movable to predetermined loci and inducible on demand. The amount of DNA made from this induced origin was determined by in vivo labelling and hybridization to probes of the surrounding region. A redundancy of terminator-like sequences, or pause sites, has been disclosed. So far, two polar pause sites, in the same orientation and separated by 50 or 80 kb, have been localized on each side of the terminus region. The results are discussed in relation to previously observations indicating that these regions are refractory to genomic inversions.

Detection and possible role of two large nondivisible zones on the Escherichia coli chromosome.

Inversion of many predetermined segments of the Escherichia coli chromosome was attempted by using a system for in vivo selection of genomic rearrangements. Two types of constraints on these inversions were observed: (i) a sensitivity to rich medium when the distance between oriC and the 86- to 91-min region (which carries loci essential for transcription and translation) is increased; (ii) a poor viability or inviability of inversions having at least one endpoint in the one-third of the chromosome around replication terminators (with an exception for some inversions ending between these terminators). Although the first constraint is simply explained by a decreased dosage of the region involved, the second one may result from disruption of two long-range chromosomal organizations. The nondivisible zones thus disclosed coincide remarkably well with the two zones that we have previously described, which are polarized with respect to their replication. It is proposed that the two phenomena result from a sequence-dependent and polarized organization of the terminal region of the chromosome, which defines chromosome replication arms and may participate in nucleoid organization.

Inhibition of replication forks exiting the terminus region of the Escherichia coli chromosome occurs at two loci separated by 5 min.

The replication cycle of Escherichia coli strains duplicating their chromosome from the same plasmid origin placed at various locations or of strains having undergone a major inversion event along the origin-to-terminus axis was studied by marker-frequency analysis. It was observed that replication forks are unidirectionally inhibited at two loci of the termination region: counterclockwise-moving forks are inhibited at terminator T1 (28.5 min), and forks moving in the opposite direction are inhibited at terminator T2 (33.5 min). By determining the strand preference of Okazaki fragments that are specific for markers from the T1-T2 interval, it was shown that this interval is replicated in either direction, depending upon the strain analyzed. In addition, we also observed that forks moving in the "unnatural" direction along each oriC-T1 or -T2 arm are very slow, especially in the one-third portion of the chromosome around the terminators. We propose that this phenomenon is a consequence of nucleoid organization, which is proposed to be symmetrical on the two oriC-T1 or -T2 arms and polarized with respect to the direction of replication. We also propose that T1 and T2 are the terminal limits of these two polarized half-nucleoid bodies.

Suppression of the Escherichia coli dnaA46 mutation by amplification of the groES and groEL genes.

A lambda hybrid phage (lambda Sda1), containing an 8.1 kb EcoRI DNA fragment from the Escherichia coli chromosome, was selected on the basis of its ability to suppress bacterial thermosensitivity caused by the dnaA46 mutation. We have shown that this suppression is due to a recA+-dependent amplification of the 8.1 kb fragment; consistent with this observation, cloning of the 8.1 kb fragment into a high copy number plasmid (pBR325) leads also to suppression of dnaA46. In the suppressed strains growing at high temperature, bidirectional replication starts in or near the oriC region and requires the presence of the DnaA polypeptide. These findings suggest that the overproduction of a gene product(s), encoded by the cloned 8.1 kb fragment, can restore dnaA-dependent initiation of replication at high temperature in the oriC region. Genetic mapping shows that the groES (mopB) and groEL (mopA) genes are located on the 8.1 kb suppressor fragment. Further analysis, including in vitro mutagenesis and subcloning, demonstrates that the amplification of the groES and groEL genes is both necessary and sufficient to suppress the temperature sensitive phenotype of the dnaA46 mutation.