Relationships between the physical and genetic maps of a 470 x 10(3) base-pair region around the terminus of Escherichia coli K12 DNA replication

Interplay between chromosomal architecture and termination of DNA replication in bacteria

Faithful transmission of the genome from one generation to the next is key to life in all cellular organisms. In the majority of bacteria, the genome is comprised of a single circular chromosome that is normally replicated from a single origin, though additional genetic information may be encoded within much smaller extrachromosomal elements called plasmids. By contrast, the genome of a eukaryote is distributed across multiple linear chromosomes, each of which is replicated from multiple origins. The genomes of archaeal species are circular, but are predominantly replicated from multiple origins. In all three cases, replication is bidirectional and terminates when converging replication fork complexes merge and 'fuse' as replication of the chromosomal DNA is completed. While the mechanics of replication initiation are quite well understood, exactly what happens during termination is far from clear, although studies in bacterial and eukaryotic models over recent years have started to provide some insight. Bacterial models with a circular chromosome and a single bidirectional origin offer the distinct advantage that there is normally just one fusion event between two replication fork complexes as synthesis terminates. Moreover, whereas termination of replication appears to happen in many bacteria wherever forks happen to meet, termination in some bacterial species, including the well-studied bacteria Escherichia coli and Bacillus subtilis, is more restrictive and confined to a 'replication fork trap' region, making termination even more tractable. This region is defined by multiple genomic terminator (ter) sites, which, if bound by specific terminator proteins, form unidirectional fork barriers. In this review we discuss a range of experimental results highlighting how the fork fusion process can trigger significant pathologies that interfere with the successful conclusion of DNA replication, how these pathologies might be resolved in bacteria without a fork trap system and how the acquisition of a fork trap might have provided an alternative and cleaner solution, thus explaining why in bacterial species that have acquired a fork trap system, this system is remarkably well maintained. Finally, we consider how eukaryotic cells can cope with a much-increased number of termination events.

Termination of DNA replication at Tus-ter barriers results in under-replication of template DNA

The complete and accurate duplication of genomic information is vital to maintain genome stability in all domains of life. In Escherichia coli, replication termination, the final stage of the duplication process, is confined to the 'replication fork trap' region by multiple unidirectional fork barriers formed by the binding of Tus protein to genomic ter sites. Termination typically occurs away from Tus-ter complexes, but they become part of the fork fusion process when a delay to one replisome allows the second replisome to travel more than halfway around the chromosome. In this instance, replisome progression is blocked at the non-permissive interface of the Tus-ter complex, termination then occurs when a converging replisome meets the permissive interface. To investigate the consequences of replication fork fusion at Tus-ter complexes, we established a plasmid-based replication system where we could mimic the termination process at Tus-ter complexes in vitro. We developed a termination mapping assay to measure leading strand replication fork progression and demonstrate that the DNA template is under-replicated by 15-24 bases when replication forks fuse at Tus-ter complexes. This gap could not be closed by the addition of lagging strand processing enzymes or by the inclusion of several helicases that promote DNA replication. Our results indicate that accurate fork fusion at Tus-ter barriers requires further enzymatic processing, highlighting large gaps that still exist in our understanding of the final stages of chromosome duplication and the evolutionary advantage of having a replication fork trap.

A Fork Trap in the Chromosomal Termination Area Is Highly Conserved across All Escherichia coli Phylogenetic Groups

Termination of DNA replication, the final stage of genome duplication, is surprisingly complex, and failures to bring DNA synthesis to an accurate conclusion can impact genome stability and cell viability. In Escherichia coli, termination takes place in a specialised termination area opposite the origin. A 'replication fork trap' is formed by unidirectional fork barriers via the binding of Tus protein to genomic ter sites. Such a fork trap system is found in some bacterial species, but it appears not to be a general feature of bacterial chromosomes. The biochemical properties of fork trap systems have been extensively characterised, but little is known about their precise physiological roles. In this study, we compare locations and distributions of ter terminator sites in E. coli genomes across all phylogenetic groups, including Shigella. Our analysis shows that all ter sites are highly conserved in E. coli, with slightly more variability in the Shigella genomes. Our sequence analysis of ter sites and Tus proteins shows that the fork trap is likely to be active in all strains investigated. In addition, our analysis shows that the dif chromosome dimer resolution site is consistently located between the innermost ter sites, even if rearrangements have changed the location of the innermost termination area. Our data further support the idea that the replication fork trap has an important physiological role that provides an evolutionary advantage.

Too Much of a Good Thing: How Ectopic DNA Replication Affects Bacterial Replication Dynamics

Each cell division requires the complete and accurate duplication of the entire genome. In bacteria, the duplication process of the often-circular chromosomes is initiated at a single origin per chromosome, resulting in two replication forks that traverse the chromosome in opposite directions. DNA synthesis is completed once the two forks fuse in a region diametrically opposite the origin. In some bacteria, such as Escherichia coli, the region where forks fuse forms a specialized termination area. Polar replication fork pause sites flanking this area can pause the progression of replication forks, thereby allowing forks to enter but not to leave. Transcription of all required genes has to take place simultaneously with genome duplication. As both of these genome trafficking processes share the same template, conflicts are unavoidable. In this review, we focus on recent attempts to add additional origins into various ectopic chromosomal locations of the E. coli chromosome. As ectopic origins disturb the native replichore arrangements, the problems resulting from such perturbations can give important insights into how genome trafficking processes are coordinated and the problems that arise if this coordination is disturbed. The data from these studies highlight that head-on replication–transcription conflicts are indeed highly problematic and multiple repair pathways are required to restart replication forks arrested at obstacles. In addition, the existing data also demonstrate that the replication fork trap in E. coli imposes significant constraints to genome duplication if ectopic origins are active. We describe the current models of how replication fork fusion events can cause serious problems for genome duplication, as well as models of how such problems might be alleviated both by a number of repair pathways as well as the replication fork trap system. Considering the problems associated both with head-on replication-transcription conflicts as well as head-on replication fork fusion events might provide clues of how these genome trafficking issues have contributed to shape the distinct architecture of bacterial chromosomes.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Division inhibition gene dicF of Escherichia coli reveals a widespread group of prophage sequences in bacterial genomes

The genomes of various eubacteria were analyzed by Southern blot hybridization to detect sequences related to the segment of the defective lambdoid prophage Kim which encodes DicF RNA, an antisense inhibitor of cell division gene ftsZ in Escherichia coli K-12. Among the homologous sequences found, one fragment from E. coli B, similar to a piece of Rac prophage, and two fragments from Shigella flexneri were cloned and sequenced. dicF-like elements similar to transcriptional terminators were found in each sequence, but unlike dicF these had no effect on division in E. coli K-12. Like dicF, these sequences are flanked by secondary structures which form potential sites for RNase III recognition. Coding sequences located upstream from the dicF-like feature in E. coli B are related to gene sieB of bacteriophage lambda, while sequences downstream of the S. flexneri elements are similar to the immunity region of satellite bacteriophage P4. Under hybridization conditions in which only strong sequence homologies were detected in E. coli B and S. flexneri, the genomes of a large variety of microorganisms, including some gram-positive bacteria, hybridized to the dicF probe. Our results suggest that dicF and its flanking regions are markers of a widespread family of prophage-like elements of different origins.

TerF, the sixth identified replication arrest site in Escherichia coli, is located within the rcsC gene

We report the existence of a sixth replication arrest site, TerF, that is located within the coding sequences of the rcsC gene, a negative regulator of capsule biosynthesis. The TerF site is oriented to allow transcription of the rcsC gene but prevent DNA replication in the terminus-to-origin direction. Our results demonstrate that the TerF site is functional in both chromosomal and plasmid environments and that the stability of the Tus-TerF protein-DNA complex more closely resembles the plasmid R6K Ter sites than the chromosomal TerB site.

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.

Toward cloning and mapping the genome of Drosophila

An ultimate goal of Drosophila genetics is to identify and define the functions of all the genes in the organism. Traditional approaches based on the isolation of mutant genes have been extraordinary fruitful. Recent advances in the manipulation and analysis of large DNA fragments have made it possible to develop detailed molecular maps of the Drosophila genome as the initial steps in determining the complete DNA sequence.

Toward cloning and mapping the genome of Drosophila

An ultimate goal of Drosophila genetics is to identify and define the functions of all the genes in the organism. Traditional approaches based on the isolation of mutant genes have been extraordinary fruitful. Recent advances in the manipulation and analysis of large DNA fragments have made it possible to develop detailed molecular maps of the Drosophila genome as the initial steps in determining the complete DNA sequence.

Cloning, mapping, and sequencing of the gene encoding Escherichia coli quinoprotein glucose dehydrogenase

Escherichia coli contains pyrroloquinoline quinone-dependent glucose dehydrogenase. We cloned and sequenced the gene (gcd) encoding this enzyme and showed that the derived amino acid sequence is highly homologous to that of the gdhA gene product of Acinetobacter calcoaceticus. Stretches of homology also exist between the amino acid sequence of E. coli glucose dehydrogenase and other pyrroloquinoline quinone-dependent dehydrogenases from several bacterial species. The position of gcd on the chromosomal map of E. coli was determined to be at 3.1 min.

Linkage map of Escherichia coli K-12, edition 8

The linkage map of Escherichia coli K-12 depicts the arrangement of genes on the circular chromosome of this organism. The basic units of the map are minutes, determined by the time-of-entry of markers from Hfr into F- strains in interrupted-conjugation experiments. The time-of-entry distances have been refined over the years by determination of the frequency of cotransduction of loci in transduction experiments utilizing bacteriophage P1, which transduces segments of DNA approximately 2 min in length. In recent years, the relative positions of many genes have been determined even more precisely by physical techniques, including the mapping of restriction fragments and the sequencing of many small regions of the chromosome. On the whole, the agreement between results obtained by genetic and physical methods has been remarkably good considering the different levels of accuracy to be expected of the methods used. There are now few regions of the map whose length is still in some doubt. In some regions, genetic experiments utilizing different mutant strains give different map distances. In other regions, the genetic markers available have not been close enough to give accurate cotransduction data. The chromosome is now known to contain several inserted elements apparently derived from lambdoid phages and other sources. The nature of the region in which the termination of replication of the chromosome occurs is now known to be much more complex than the picture given in the previous map. The present map is based upon the published literature through June of 1988. There are now 1,403 loci placed on the linkage group, which may represent between one-third and one-half of the genes in this organism.

Integration of bacteriophage lambda into the cryptic lambdoid prophages of Escherichia coli

Bacteriophage lambda missing its chromosomal attachment site will integrate into recA+ Escherichia coli K-12 and C at the sites of cryptic prophages. The specific regions in which these recombination events occur were identified in both lambda and the bacterial chromosomes. A NotI restriction site on the prophage allowed its physical mapping. This allowed us to identify the locations of Rac, Qin, and Qsr' cryptic prophages on the NotI map of E. coli K-12 and, by analogy, to identify the cryptic prophage in E. coli C as Qin. No new cryptic prophages were detected in E. coli K-12.

A family of genes encoding a cell-killing function may be conserved in all gram-negative bacteria

The relF gene in Escherichia coli is related to the hok gene on plasmid R1. Both genes encode small proteins which, when overexpressed in E. coli lead to collapse of the membrane potential and cell death. A third gene, designated gef, which encodes a homologous cell-toxic protein, has been isolated from E. coli DNA. Both gef and relF are transcribed in E. coli and subject to post-transcriptional regulation which, in the case of gef, is coupled to translation of a leader sequence. The finding of homologous sequences in such distantly related bacteria as Agrobacterium and Rhizobium species suggests an important physiological role.

Analysis of the recE locus of Escherichia coli K-12 by use of polyclonal antibodies to exonuclease VIII

Exonuclease VIII (exoVIII) of Escherichia coli has been purified from a strain carrying a plasmid-encoded recE gene by using a new procedure. This procedure yielded 30 times more protein per gram of cells, and the protein had a twofold higher specific activity than the enzyme purified by the previously published procedure (J. W. Joseph and R. Kolodner, J. Biol. Chem. 258:10411-10417, 1983). The sequence of the 12 N-terminal amino acids was also obtained and found to correspond to one of the open reading frames predicted from the nucleic acid sequence of the recE region of Rac (C. Chu, A. Templin, and A. J. Clark, manuscript in preparation). Polyclonal antibodies directed against purified exoVIII were also prepared. Cell-free extracts prepared from strains containing a wide range of chromosomal- or plasmid-encoded point, insertion, and deletion mutations which result in expression of exoVIII were examined by Western blot (immunoblot) analysis. This analysis showed that two point sbcA mutations (sbcA5 and sbcA23) and the sbc insertion mutations led to the synthesis of the 140-kilodalton (kDa) polypeptide of wild-type exoVIII. Plasmid-encoded partial deletion mutations of recE reduced the size of the cross-reacting protein(s) in direct proportion to the size of the deletion, even though exonuclease activity was still present. The analysis suggests that 39 kDa of the 140-kDa exoVIII subunit is all that is essential for exonuclease activity. One of the truncated but functional exonucleases (the pRAC3 exonuclease) has been purified and confirmed to be a 41-kDa polypeptide. The first 18 amino acids from the N terminus of the 41-kDa pRAC3 exonuclease were sequenced and fond to correspond to one of the translational start signals predicted from the nucleotide sequence of radC (Chu et al., in preparation).

Packaging of transducing DNA by bacteriophage P1

P1 transduces bacterial chromosomal markers with widely differing frequencies. We use quantitative Southern hybridisations here to show that, despite this, most markers are packaged at similar levels. Exceptions are a group of markers near 2 min and another at 90 min which seem to be packaged at levels two- to threefold higher. We thus conclude that certain marker frequency variations in transduction can be explained by differences in packaging level, but that most cannot. The limited range in packaging levels suggests that P1 can initiate the packaging of chromosomal DNA from many sites. This idea is supported by our failure to find any chromosomal sequences with homology to the phage pac site and by the occurrence of hybridising bands which seem to suggest sequential packaging from a large number of specific sites. We eliminate the possibility that chromosomal DNA packaging is the result of endonucleolytic cutting by the P1 res enzyme.

Identification and sequence of gene dicB: translation of the division inhibitor from an in-phase internal start

The dicA1 mutation, located in the replication termination region of Escherichia coli at 34.9 min, confers a temperature-sensitive, division defective phenotype to its hosts. Previous analysis had suggested that dicA codes for a repressor of a nearby division inhibition gene dicB. We show now that gene dicB is part of a complex operon. Five open reading frames (ORFs 1 to 5) preceeded by a promoter sensitive to dicA repression are found within a 1500 bp segment, and are organized into two clusters separated by a long untranslated region. Evidence for expression of these ORFs was obtained from in vitro or in vivo translation of plasmid-coded genes. IPTG-dependent cell filamentation was obtained when either the entire or the C-terminal part of the fourth ORF was placed under control of the lac promoter. In both cases, a 7 KD protein corresponding to translation from an in-frame ATG of ORF4 (dicB) was made. We propose that this C-terminal protein is the division inhibitor synthesized in dicA1 mutants.

Distribution and diversity of hsd genes in Escherichia coli and other enteric bacteria

We screened Salmonella typhimurium, Citrobacter freundii, Klebsiella pneumoniae, Shigella boydii, and many isolates of Escherichia coli for DNA sequences homologous to those encoding each of two unrelated type I restriction and modification systems (EcoK and EcoA). Both K- and A-related hsd genes were identified, but never both in the same strain. S. typhimurium encodes three restriction and modification systems, but its DNA hybridized only to the K-specific probe which we know to identify the StySB system. No homology to either probe was detected in the majority of E. coli strains, but in C. freundii, we identified homology to the A-specific probe. We cloned this region of the C. freundii genome and showed that it encoded a functional, A-related restriction system whose specificity differs from those of known type I enzymes. Sequences immediately flanking the hsd K genes of E. coli K-12 and the hsd A genes of E. coli 15T- were shown to be homologous, indicating similar or even identical positions in their respective chromosomes. E. coli C has no known restriction system, and the organization of its chromosome is consistent with deletion of the three hsd genes and their neighbor, mcrB.

Method for localization of cloned DNA fragments on the Escherichia coli chromosome

In exponentially growing cultures of Escherichia coli strains carrying the dnaC28 mutation, DNA replication can be synchronized by temperature changes (R. L. Rodriguez, M. S. Dalbey, and C. I. Davern, J. Mol. Biol. 74:599-604, 1973). We used this synchronization procedure and DNA-DNA hybridization to develop a technique for the localization of cloned chromosomal fragments on the genetic map. Because of the bidirectional nature of replication in E. coli, our method gave two possible positions (one on each replication arm). However because of the precision obtained for each position (+/- 1 map unit), the final mapping with various genetic techniques was greatly facilitated. Using this technique and a simple chromosomal mobilization test, we located at 93.2 +/- 1 min a cloned DNA fragment carrying an extragenic suppressor of dnaA46, a thermosensitive mutation in the dnaA initiation gene. Further analysis showed that the groES (mopA) and groEL (mopB) genes, both located at 94.2 min on the standard map, were indeed carried by the cloned suppressor fragment.

The normal replication terminus of the Bacillus subtilis chromosome, terC, is dispensable for vegetative growth and sporulation

The Bacillus subtilis strains CU1693, CU1694 and CU1695 were shown by hybridization analysis to carry large deletions of the terminus region that originated within discrete fragments of the SP beta prophage genome. The absence of terC in CU1693 was demonstrated definitively by the identification of a novel junction fragment comprising SP beta DNA and DNA that lies on the other side of terC in the parent strain. This represented the deletion of approximately 230 kb of CU1693 DNA, with the removal of approximately 150 kb to the left of terC and approximately 80 kb to the right of terC. The lack of hybridization of CU1694 and CU1695 DNA to cloned DNA carrying the terC sequence and to cloned DNAs flanking terC suggested that terC is absent from the chromosome of each of these strains also, and that the deletions in CU1694 and CU1695 extend beyond the segment of the terminus region that has been mapped and cloned. The normal growth rate and morphology of CU1693, CU1694 and CU1695 relative to the parent strain when grown in complex medium indicated dispensability of terC for vegetative growth and division. B. subtilis SU153 was constructed using a specific deletion-insertion vector that was designed to effect the deletion of 11.2kb of DNA spanning terC, with the removal of approximately 9.7kb to the left of terC and approximately 1.kb to the right of terC. This manipulation did not introduce any readily detectable auxotrophic requirement. Physiological characterization of SU153 confirmed the dispensability of terC for vegetative growth and cell division, and also established the lack of requirement of terC for the specialized cell division that is associated with formation of the bacterial endospore.

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.

The terminus region of the Escherichia coli chromosome contains two separate loci that exhibit polar inhibition of replication

The terminus region of the chromosome of Escherichia coli contains two separate sites, called T1 and T2, that inhibit replication forks. T1 is located near 28.5 min, which is adjacent to trp, and T2 is located at 34.5-35.7 min on the opposite side of the terminus region, near manA. The sites act in a polar fashion, and replication forks traveling in a clockwise direction with respect to the genetic map are not inhibited as they pass through T1 but are inhibited at T2. Similarly, counterclockwise forks are not inhibited at T2 but are inhibited at T1. Consequently, forks are not inhibited until they have passed through the terminus region and are about to leave it. Studies with deletion strains have located T2 within a 58-kilobase interval, which corresponds to kilobase coordinates 387-445 on the physical map of the terminus region.

Early increases in the frequency of DNA initiations and of phospholipid synthesis discontinuities after nutritional shift-up in Escherichia coli

Cultures of Escherichia coli (strains ML30 and K12 AB1157), synchronized by repeated phosphate starvation, were submitted to nutritional shifts-up at various cell ages. The progression of the replication forks was assessed by DNA-DNA hybridization of pulse-labelled chromosomal DNA with plasmid DNA probes containing specific chromosomal sequences. The rate of phospholipid synthesis and its cyclic discontinuities were measured by continuous and pulse labelling with palmitate. The DNA-DNA hybridization experiments showed that a shift-up induces a burst of initiation from the oriC region. These hybridization results, taken together with older data from the literature, suggest that most DNA initiations belonging to this burst are not followed by complete replication. Following a shift-up, the rate of phospholipid synthesis is maintained for 13-20 min, depending on cell age at shift-up, then doubles. The new steady-state rate of phospholipid synthesis is reached through a series of three doublings, while the cell mass doubles approximately twice. This discrepancy brings the rate of phospholipid synthesis per mass unit to its steady-state postshift value.

DNA replication termination in Escherichia coli parB (a dnaG allele), parA, and gyrB mutants affected in DNA distribution

We investigated the Escherichia coli mutants carrying the parB, parA, and gyrB mutations, all of which display faulty chromosome partitioning at the nonpermissive temperature, to see whether their phenotype reflected a defect in the termination of DNA replication. In the parB strain DNA synthesis slowed down at 42 degrees C and the SOS response was induced, whereas in the parA strain DNA synthesis continued normally for 120 min and there was no SOS induction. To see whether replication forks accumulated in the vicinity of terC at the nonpermissive temperature, the mutants were incubated for 60 min at 42 degrees C and then returned to low temperature and pulse-labeled with [3H]thymidine. In all cases the restriction pattern of the labeled DNA was incompatible with that of the terC region, suggesting that replication termination was normal. In the parA mutant no DNA sequences were preferentially labeled, whereas in the parB and gyrB strains there was specific labeling of sequences whose restriction pattern resembled that of oriC. In the case of parB this was confirmed by DNA-DNA hybridization with appropriate probes. This test further revealed that the parB mutant over initiates at oriC after the return to the permissive temperature. Like dna(Ts) strains, the parB mutant formed filaments at 42 degrees C in the absence of SOS-associated division inhibition, accompanied by the appearance of anucleate cells of nearly normal size (28% of the population after 3 h), as revealed by autoradiography. The DNA in the filaments was either centrally located or distributed throughout. The parB mutation lies at 67 min, and the ParB- phenotype is corrected by a cloned dnaG gene or by a plasmid primase, strongly suggesting that parB is an allele of dnaG, the structural gene of the E. coli primase. It is thus likely that the parB mutant possesses an altered primase which does not affect replication termination but causes a partial defect in replication initiation and elongation and in chromosome distribution.

Random-clone strategy for genomic restriction mapping in yeast

An approach to global restriction mapping is described that is applicable to any complex source DNA. By analyzing a single restriction digest for each member of a redundant set of lambda clones, a data base is constructed that contains fragment-size lists for all the clones. The clones are then grouped into subsets, each member of which is related to at least one other member by a significant overlap. Finally, a tree-searching algorithm seeks restriction maps that are consistent with the fragment-size lists for all the clones in each subset. The feasibility of the approach has been demonstrated by collecting data on 5000 lambda clones containing random 15-kilobase inserts of yeast DNA. It is shown that these data can be analyzed to produce regional maps of the yeast genome, extending in some cases for over 100 kilobases. In combination with hybridization probes to previously cloned genes, these local maps are already useful for defining the physical arrangement of closely linked genes. They may in the future serve as building blocks for the construction of a continuous global map.

Molecular cloning and expression of hipA, a gene of Escherichia coli K-12 that affects frequency of persistence after inhibition of murein synthesis

The hipA gene at 33.8 min on the Escherichia coli chromosome controls the frequency of persistence upon inhibition of murein synthesis; for strains bearing hipA+ the frequency is 10(-6), and for hipA- strains the frequency is 10(-2). hip+ has been cloned by selection for a kanamycin resistance determinant at 33.9 min. hipA+ is dominant over hipA- in both recA+ and recA- backgrounds. The smallest DNA insert which contains hipA+, as determined by the ability of the plasmids to complement hipA- strains, is 1,885 base pairs. Both orientations of hipA+ are obtained when the cloning site of vector is remote from strong promoters; both orientations complement hipA-, and both encode a unique peptide of 50,000 Mr. The probable direction of transcription has been deduced from the pattern of peptides encoded by plasmids from which either end of the insert and adjacent vector sequences have been deleted. This information and the recovery of only one orientation of hipA+ when the cloning site is close to a strong promoter suggest that a high level of expression of the gene is not tolerated by E. coli.

Characterization and properties of very large inversions of the E. coli chromosome along the origin-to-terminus axis

Suppression of a dnaA46 mutation by integration of plasmid R100.1 derivatives in the termination region of chromosome replication in E. coli results in medium dependence, the suppressed bacteria being sensitive to rich medium at 42 degrees C. Derivatives of such bacteria have been selected for growth at 42 degrees C in rich medium and we have analyzed representatives of the most frequently observed type: bacteria displaying, once cured of the suppressor plasmid, both rich-medium sensitivity and temperature sensitivity. We found, in all cases, that the chromosome had undergone a major inversion event between two inverted IS5's. One is located at 29.2 min on the chromosome map and the other at either one of two positions between 69 and 80 min. The consequences of such inversions for cell growth are discussed. Some of them result from the fact that the replication terminator T2 is located, in inverted chromosomes, close to oriC in the orientation which allows its functioning as a terminus (de Massy et al. in press). Our observations allow an estimation of the frequency of inversions arising from recombination between pairs of inverted chromosomal IS, which could be as high as 10(-2) per cell per generation. We also found that inversion reversal occurs frequently after Hfr conjugational transfer of one of the IS5's, in its wild-type location. This led us to propose a new mechanism of recombination, in which the incoming DNA strands serve as guides to favor recombination between the resident sequences.

A new dispensable genetic locus of the terminus region involved in control of cell division in Escherichia coli

Temperature-sensitive mutants defective in cell division were isolated after localised mutagenesis of the terminus region of the Escherichia coli chromosome. The defective gene in one of these mutants, dicA, was mapped at 34.9 min by linkage with manA and with three physically characterized Tn10 insertions. Temperature-sensitivity conferred by mutation dicA1 in a recA background [corrected] was suppressed by the presence of hybrid plasmids carrying the wild-type gene. In addition, the mutation was suppressed either by tranposon inactivation of a nearby gene, dicB, or by deletion of the entire dicA-dicB interval. These results define the dicA-dicB locus as a new dispensable genetic cluster involved in the control of cell division.

Cloning and location of the dgsA gene of Escherichia coli

The dgsA locus of Escherichia coli was isolated on plasmids obtained from the library of L. Clarke and J. Carbon (Cell 9:91-99, 1976). Restriction fragment analysis and further subcloning demonstrated that the gene is located at kilobase 425 on the Bouché physical map of the terminus region (J. P. Bouché, J. Mol. Biol., 154:1-20, 1982). This corresponds to 35.2 min on the Bachmann genetic map (B. J. Bachmann, Microbiol. Rev. 47:180-230, 1983).

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.

Mutation-dependent suppression of recB21 recC22 by a region cloned from the Rac prophage of Escherichia coli K-12

Using pBR322 as a vector, we cloned a 5.95-kilobase fragment of the Rac prophage together with 1.70 kilobases of a flanking Escherichia coli chromosome sequence. The resulting plasmid (pRAC1) was unable to suppress the mitomycin and UV sensitivity and recombination deficiency of a recB21 recC22 strain. Five spontaneous mitomycin-resistant derivatives contained deletion mutant plasmids. These plasmids also suppressed the UV sensitivity and recombination deficiency of their recB21 recC22 hosts. All five deletions were contained within a 2.45-kilobase EcoRI-to-HindIII segment of the plasmid. By substituting the corresponding 2.45-kilobase EcoRI-toHindIII fragments of Rac prophage isolated from sbcA+, sbcA6, and sbcA23 strains for the shortened segment of one of the deletion mutant plasmids, we were able to show that sbcA mutations map in this region. Also in this region is the site (or closely linked sites) at which previous studies had shown that insertion of Tn5 and IS50 leads to suppression of recB21 recC22. The sequence in this region that must be altered or circumvented to allow suppression is discussed. Also presented are data correlating the expression of nuclease activity with the degree of suppression.

Deletion of the terminus region (340 kilobase pairs of DNA) from the chromosome of Escherichia coli

A strain of Escherichia coli with a 7-minute (340 kilobase pairs of DNA) deletion of the terminus region of the chromosome was isolated. This deletion was probably an IS10-promoted event and its extent was characterized by both genetic and DNA hybridization analyses. The most dramatic property of strains harboring this deletion was the absence of the sites that inhibit clockwise- and counterclockwise-traveling replication forks. These strains also grew slowly, produced many nonviable cells, were filamentous, and appeared to have an induced SOS system.

DNA-protein interactions during replication of genetic elements of bacteria

Specific interactions of DNA with proteins are required for both the replication of deoxyribonucleic acid proper and its regulation. Genetic elements of bacteria, their extrachromosomal elements in particular, represent a suitable model system for studies of these processes at the molecular level. In addition to replication enzymes (DNA polymerases), a series of other protein factors (e.g. topoisomerases, DNA unwinding enzymes, and DNA binding proteins) are involved in the replication of the chromosomal, phage and plasmid DNA. Specific interactions of proteins with DNA are particularly important in the regulation of initiation of DNA synthesis. Association of DNAs with the cell membrane also plays an important role in their replication in bacteria.

Nucleotide sequence and transcriptional start point of the phosphomannose isomerase gene (manA) of Escherichia coli

A 1.6-kb MspI-HindIII chromosomal DNA segment, carrying the complete coding region of the 6-phosphomannose isomerase (PMI) structural gene, manA, and the 5' end of the gene encoding the major fumarase activity, fumA, of Escherichia coli K-12, has been sequenced using the chain termination method. The start points of manA and fumA transcripts were located by S1 mapping using 32P-labelled M13 ssDNA probes, and the two genes were shown to be transcribed divergently. The sequence of the 390 amino acid residues comprising the PMI monomer has been deduced, and the predicted Mr of 42 716 agrees with that for the protein of Mr 42 000 identified previously by the maxicell procedure.

Physical map of the Bacillus subtilis replication terminus region: its confirmation, extension and genetic orientation

The library of Bacillus subtilis DNA previously cloned in the cosmid vector pHC79 has been screened for the replication terminus region using a higher level of terminus probe. 24 of 48 recombinant cosmids which gave a positive response had restriction fragment compositions consistent with their inserts originating from or extending into the terminus region for which a 150-kb restriction map has already been constructed (Weiss and Wake, 1983). DNA spanning terC, the site of termination, appears to be missing from the library, although DNA to either side of terC has been cloned. A detailed analysis of four of the newly identified recombinant cosmids has confirmed most of the previous 150-kb map and allowed it to be extended to 180 kb. Physical linkage of the two cosmid inserts that most closely approach terC on each side has been demonstrated. The location of the genetic marker gltA and the orientation of the restriction map relative to the genetic map of the B. subtilis chromosome have also been established.

Impediment to replication fork movement in the terminus region of the Bacillus subtilis chromosome

The terminus regions of the chromosomes of three strains of Bacillus subtilis 168 were radioactively labelled by supplying [3H]thymine towards the end of a round of replication. These strains lacked or contained the prophage SP beta c2. Following restriction endonuclease digestion of the purified DNA and fluorography, an SP beta c2-related perturbation of the terminus-labelling profile was observed, which was completely consistent with the previously suggested existence of an impediment to replication fork movement (terC) within a BamHI 24.8 X 10(3) base fragment (Weiss & Wake, 1983). The present data suggest that terC is located within the 11.4 X 10(3) base BamHI + SalI double-digest portion of this BamHI fragment.

The spacing of Escherichia coli DNA gyrase sites cleaved in vivo by treatment with oxolinic acid and sodium dodecyl sulfate

In an attempt to locate gyrase binding sites in a specific region of the chromosome of E. coli, we have reinvestigated gyrase-promoted cleavage of chromosomal DNA by oxolinic acid and sodium dodecyl sulfate. Contrary to a previous report suggesting the presence of one site every 100 kb of DNA (Snyder and Drlica, J. Mol. Biol. 131, 287-302), we found frequencies of one cleavage every 25 or 12 kb depending on the growth medium. A search for cleavage sites by Southern blot hybridization failed to reveal any binding site cleaved at a high frequency. These results suggest that the actual spacing of sites is much closer than that determined from the frequency of cleavage. Measurement of the average size of fragments containing defined DNA sequences indicated that the frequency of sites varies along the chromosome. The region located opposite to oriC carries relatively few sites.

Multiple origin usage for DNA replication in sdrA(rnh) mutants of Escherichia coli K-12. Initiation in the absence of oriC

In stable DNA replication (sdrA/rnh) mutants of Escherichia coli, initiation of rounds of DNA replication occurs in the absence of the normal origin of replication, oriC. To determine whether or not the initiation occurs at a fixed site(s) on the chromosome in sdrA mutants, the DNA from exponentially growing sdrA mutant cells with or without the oriC site (delta oriC) was analyzed for the relative copy numbers of various genes along the chromosome. The results suggest that there are at least four fixed sites or regions of the sdrA delta oriC chromosome from which DNA replication can be initiated in the absence of the oriC sequence.

Deletion of 60 kilobase pairs of DNA from the terC region of the chromosome of Escherichia coli

The terminus of replication (terC) of the chromosome of Escherichia coli is located between the rac (min 30.0) and manA (min 35.7) loci, presumably close to the trg (min 31.4) locus. We have used a strain containing lambda reverse (min 30.0) and trg-2::Tn10 (min 31.4) to obtain deletions of the entire 60 kilobase pair region that separates these elements. Strains harboring these deletions possessed fusion fragments that contained DNA homologous to both lambda reverse and trg region DNA. In addition, chromosomal DNA normally present between min 30.0 and min 31.4 was absent in these strains. The strains had no readily apparent mutant phenotype, which demonstrates that this large region of DNA is not essential for normal growth.

Restriction map of DNA spanning the replication terminus of the Bacillus subtilis chromosome

The Bacillus subtilis 168 dna-1 chromosome was labelled during sporulation with [3H]thymine for five minutes immediately before termination of replication. The isolated radioactive DNA was cleaved with BamHI (or SalI) and the resulting restriction fragments separated by agarose gel electrophoresis. The individual fragments, fractionated into a series of slices cut from the gel, were then cleaved with SalI (or BamHI) and the double-digest fragments identified by electrophoresis and fluorography. All major fragments and most minor ones present in a whole double-digest were assigned to BamHI and SalI parents. Such information enabled the construction of an unambiguous restriction map of 150 X 10(3) bases of the approximately 250 X 10(3) bases of DNA labelled in the five minutes. In conjunction with published data on the order of replication of restriction fragments as termination is approached, it was clear that most (105 X 10(3) bases) of the mapped DNA was replicated by a major fork moving in one direction towards a BamHI 24.8 X 10(3) base fragment. The 45 X 10(3) bases extending to the other side of this region were labelled only slightly, and presumably was replicated by a fork that approached the other in an opposite direction until its progress was blocked or severely impeded within this region at a site, referred to as terC, sometime (less than 5 min) earlier. The regions of the map replicated in the final 2.5 and 1.0 minute by the major fork were also identified.

Limited homology between trg and the other transducer proteins of Escherichia coli

Transducers are transmembrane proteins that are central to the chemotactic system of Escherichia coli. The proteins transduce ligand recognition into an excitatory signal and function in adaptation as methyl-accepting proteins. The transducer genes tsr, tar, and tap have extensive homology with each other. However, previous studies revealed little indication of homology between those three transducer genes and a fourth gene, trg. We investigated the relationship between trg and the other genes by blot-hybridization experiments and the relationship between Trg and the other transducer proteins by immune precipitation and experiments with an antiserum raised to purified Trg protein. In experiments in which 35% mismatch would be tolerated, weak hybridization of trg was detected to a DNA fragment containing tar and tap but not to a fragment containing tsr. In experiments in which only 30% mismatch would be tolerated, no trg hybridization was apparent either to total chromosomal DNA or to DNA from hybrid plasmids carrying the other transducer genes. An anti-Trg serum formed immune precipitates with the Tsr and Tar proteins as well as with the Trg protein to which it was raised. We conclude that there is homology between Trg and the other transducer, but the homology is more limited than that shared among the other transducers. Furthermore, we found no indication of additional transducer genes closely related to trg. Thus, the trg gene is a somewhat distant cousin within a single transducer gene family of E. coli.

A third defective lambdoid prophage of Escherichia coli K12 defined by the lambda derivative, lambdaqin111

We describe the isolation and characterization of a new Q-independent substitution mutant of lambda, lambdaqin111, which differs from other characterized Q-independent lambda phages. This mutant defines a new lambda-like prophage in the bacterial chromosome, as seen by homologous recombination between lambdaqin111 and the host DNA and by DNA/DNA hybridization methods. Genetic and electron microscopy data show that this new prophage carries, at least, genes analogous to Q-S-R of lambda and also a cos site functionally identical to lambda cos. It is located near 34 min on the Escherichia coli K12 map, i.e. in the same region but at a different site from the defective Rac prophage.

Restriction nuclease and enzymatic analysis of transposon-induced mutations of the Rac prophage which affect expression and function of recE in Escherichia coli K-12

Fourteen Tn5-generated mutations of the Rac prophage, called sbc because they suppress recB21 recC22, were found to fall into two distinct types: type I mutations, which were insertions of Tn5, and type II mutations, which were insertions of IS50. Both orientations of Tn5 and IS50 were represented among the mutants and were arbitrarily labeled A and B. All 14 of the Tn5 and IS50 insertions occurred in the same location (+/- 100 base pairs) approximately 5.6 kilobases from one of the hybrid attachment sites. Eleven of the mutants contained essentially the same amount of exonuclease VIII, the product of recE. The possibility that a promoter for recE was created by the insertion of Tn5 and IS50 was considered. Two IS50 mutants in which such a promoter could not have been created showed three to four times as much exonuclease VIII, and another showed one-half as much as the majority. The possibility was considered that a promoter internal to IS50 is responsible for this heterogeneity. Restriction alleviation was measured in all 14 mutants. An insertion of the transposon Tn10 which reduces expression of exonuclease VIII (recE101::Tn10) was located within the Rac prophage at a position 2.35 kilobases from the left hybrid attachment site. Location and orientation of the Rac prophage on the Escherichia coli genetic map are discussed in light of these results.

Cloning DNA from the replication terminus region of the Bacillus subtilis chromosome

DNA from the Bacillus subtilis 168 prototroph, SB19, was partially cleaved with MboI and cloned into the BamHI site of the Escherichia coli cosmid vector, pHC79. [3H]thymine-labelled DNA from the replication terminus region of the B. subtilis dna-1 chromosome was used to identify, by hybridization, clones harboring recombinant cosmids carrying inserts from the terminus region. Restriction maps have been constructed for two such cosmids carrying overlapping DNA inserts that cover or extend into four of the previously identified five SalI fragments which are replicated last. The composite map of the cloned region, together with the available data on the replication order of fragments within it, is consistent with its replication being achieved by the unidirectional movement of a fork through it and towards the late replicating 16.2-kb SalI fragment. Most, if not all, of the terminus sequences in at least one of the recombinant cosmids are missing from a viable strain of B. subtilis that carries a deletion in the SP beta-gltA region of the chromosome.

hipA, a newly recognized gene of Escherichia coli K-12 that affects frequency of persistence after inhibition of murein synthesis

Except for a small fraction of persisters, 10(-6) to 10(-5), Escherichia coli K-12 is killed by prolonged inhibition of murein synthesis. The progeny of persisters are neither more resistant to inhibition of murein synthesis nor more likely to persist than normal cells. Mutants have been isolated in which a larger fraction, 10(-2), persists. The persistent response of the mutants, Hip (high persistence), is to inhibition of murein synthesis at early or late steps by antibiotics (phosphomycin, cycloserine, and ampicillin) or by metabolic block (starvation for diaminopimelic acid). Killing of the parent strain by each of the four inhibitors has two phases: The first is rapid and lasts about 30 min; the second is slower, but still substantial, and lasts 3 to 4 h. The first phase also occurs in the Hip mutants, but then viability of the mutants remains constant after about 30 min. Neither tolerance, resistance, impaired growth, nor reversion of spheroplasts accounts for high-frequency persistence. Two of the mutations map at 33.8 min in a region containing few other recognized functions. This position and the phenotypes define hipA as a newly recognized gene. Transposons Tn5 and Tn10 have been inserted close to hipA making it possible to explore the molecular genetics of persistence, a long recognized but poorly understood phenomenon.