DNA and protein sequence conservation at the replication terminus in Bacillus subtilis 168 and W23.

Cloned DNA from the replication terminus region of Bacillus subtilis 168 was used to identify and construct a restriction map of the homologous region in B. subtilis W23. With this information, DNA from the terminus region of W23 was cloned and the sequence was determined for a 1,499-base-pair segment spanning the expected terC site. The position of the site was then located more precisely. Use of the cloned DNA from strain W23 as a probe for digests of DNA from exponentially growing cells of the same strain established the presence of the slowly migrating replication termination intermediate (forked DNA). The orientation and dimensions of the forked molecule were consistent with arrest of the clockwise fork at the terC site in W23, as has been shown to occur in strain 168. Thus, despite significant differences between the two strains, the same termination mechanism appears to be used. The DNA sequences spanning the terC site in strains 168 and W23 showed a high level of homology (90.2%) close to the site but very little at a distance of approximately 250 base pairs from the site in one particular direction. The overall sequence comparison emphasised the importance of the open reading frame for a 122-amino-acid protein adjacent to terC. Although there were 22 base differences in the open reading frames between the strains, the amino acid sequence of the encoded protein was completely conserved. It is suggested that the amino acid sequence conservation reflects a role for the protein in the clockwise fork arrest mechanism as proposed earlier (M.T. Smith and R.G. Wake, J. Bacteriol. 170:4083-4090, 1988).     

Expression of the rtp gene of Bacillus subtilis is required for replication fork arrest at the chromosome terminus

It was earlier proposed that clockwise replication fork arrest at the chromosome terminus in Bacillus subtilis is dependent upon expression of the rtp gene adjacent to the site of arrest, terC [Smith and Wake, J. Bacteriol. 170 (1988) 4083-4090]. A merodiploid strain of B. subtilis, in which rtp was placed under the control of the IPTG-inducible spac-1 promoter, was constructed. Replication fork arrest at terC, as monitored by the level of a forked DNA molecule of predicted dimensions, was shown to be dependent upon IPTG-induced expression of rtp in this strain. The very low concentration of IPTG needed to induce a substantial level of fork arrest suggests that relatively little RTP, the protein product of rtp, is needed for fork arrest at terC.     

Sequence features of the replication terminus of the Bacillus subtilis chromosome.

The sequence of 1267 nucleotides spanning the replication terminus, terC, of the Bacillus subtilis 168 chromosome has been determined. The site of arrest of the clockwise fork, which defines terC, has been localized to a 30-nucleotide portion (approximately) within this sequence. The arrest site occurs in an A + T-rich region between two open reading frames and very close to one of two imperfect inverted repeats (47-48 nucleotides each) which are separated by 59 nucleotides. The closeness of approach of the arrested clockwise fork to the first imperfect inverted repeat encountered in this region raises the possibility of a role for the inverted repeats in the mechanism of fork arrest.     

Normal terC-region of the Bacillus subtilis chromosome acts in a polar manner to arrest the clockwise replication fork

A procedure is described for relocating a functional terC-region to various sites on the Bacillus subtilis chromosome, and in alternative orientations. The relocated terC-region comprised the IRR-rtp portion of the chromosome contained within a 1.75 x 10(3) base-pair segment of DNA. This segment was first cloned into the Tn 917 vector pTV20 in both orientations, and the two new plasmids used for inserting the terC-region into chromosomal copies of Tn 917. When relocated to the pyr and metD loci (139 degrees and 100 degrees positions on the 360 degrees map) it was found that clockwise replication fork arrest occurred only when the IRR-rtp (or terC-) region was oriented, in relation to the direction of approach of the fork, in the same way as in the wild-type strain. Thus, the complete IRR when located in the chromosome, and apparently made up of opposing terminators which might enable it to function in both orientations, is polar in its action. Of the two inverted repeats present in the IRR, it appears that IRI is functional in the chromosome, but not IRII.     

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.     

Replication fork arrest at relocated replication terminators on the Bacillus subtilis chromosome.

The replication terminus region of the Bacillus subtilis chromosome, comprising TerI and TerII plus the rtp gene (referred to as the terC region) was relocated to serC (257 degrees) and cym (10 degrees) on the anticlockwise- and clockwise-replicating segments of the chromosome, respectively. In both cases, it was found that only the orientation of the terC region that placed TerI in opposition to the approaching replication fork was functional in fork arrest. When TerII was opposed to the approaching fork, it was nonfunctional. These findings confirm and extend earlier work which involved relocations to only the clockwise-replicating segment, at metD (100 degrees) and pyr (139 degrees). In the present work, it was further shown that in the strain in which TerII was opposed to an approaching fork at metD, overproduction of the replication terminator protein (RTP) enabled TerII to function as an arrest site. Thus, chromosomal TerII is nonfunctional in arrest in vivo because of a limiting level of RTP. Marker frequency analysis showed that TerI at both cym and metD caused only transient arrest of a replication fork. Arrest appeared to be more severe in the latter situation and caused the two forks to meet at approximately 145 degrees (just outside or on the edge of the replication fork trap). The minimum pause time erected by TerI at metD was calculated to be approximately 40% of the time taken to complete a round of replication. This significant pause at metD caused the cells to become elongated, indicating that cell division was delayed. Further work is needed to establish the immediate cause of the delay in division.     

Cloning and localization of the Bacillus subtilis chromosome replication terminus, terC

A 10.9-kb segment of the Bacillus subtilis 168 chromosome has been cloned in an Escherichia coli plasmid and shown to contain terC (the replication terminus of the chromosome). The terC-containing portion of this plasmid has been subcloned within each of two overlapping fragments of DNA, 1.75 and 1.95 kb, again in E. coli plasmids. These have afforded a more precise definition of the location of terC in the B. subtilis chromosome and provided material for a detailed analysis of the structure and functioning of this site.     

Sequence limits of DNA strands in the arrest replication fork at the Bacillus subtilis chromosome terminus.

The DNA sequence limits of the leading and lagging strands in the arrested clockwise replication fork at the terminus of the Bacillus subtilis chromosome have been investigated. On the basis of hybridization to synthetic oligonucleotides corresponding to known positions in the terminus region sequence it has been shown that neither the leading nor lagging strands, as they approach terC, traverse the distal inverted repeat, IRI. But a small fraction of the leading strands pass through the proximal inverted repeat, IRII. This is consistent with IRI being the functional inverted repeat in arresting the clockwise fork. But most of the forks appear to stop at least 100 nucleotides short of IRI, and at various positions extending over a distance of at least 100 nucleotides.     

Definition and polarity of action of DNA replication terminators in Bacillus subtilis.

The first stage in termination of chromosome replication in Bacillus subtilis involves arrest of the clockwise fork at the inverted repeat region (IRR), comprising the opposed IRI and IRII sequences, adjacent to the upstream region of the rtp gene, which encodes the replication terminator protein RTP. RTP binds to IRI and IRII. The ability of the IRR and its components to function as terminators, in conjunction with RTP, and their polarity of action have now been tested by the use of plasmids replicating in B. subtilis as unidirectional theta structures and into which potential terminator sequences were inserted in alternate orientations relative to fork movement. When the complete IRR was inserted into such plasmids and the new plasmids transferred into a B. subtilis strain overproducing RTP, it was able to block movement of a replication fork approaching from either direction. IRI and IRII were shown to function as polar terminators, each blocking movement of a fork when it approached from one particular direction but not the other. Furthermore, the polarity of action was in accordance with the IRR being able to operate as a replication fork trap. Thus, a fork approaching the IRR would pass through the first terminator encountered (IRI or IRII) and be halted by the second. The previously observed nonfunctioning of a particular orientation of chromosomal IRR as a fork arrest site probably reflects a limiting level of RTP in the cell. Interestingly, a 21 base-pair core sequence spanning a single RTP binding site within IRI (the 47 base-pair IRI contains 2 binding sites) was unable to arrest a fork approaching from either direction in the plasmid system. This suggests that both binding sites within an IR must be filled in order to function as an arrest site. It is possible that co-operative interaction between adjacent dimers within IRI or IRII provides the necessary conformation for causing fork arrest.     

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.     

Breakdown and quantitation of the forked termination of replication intermediate of Bacillus subtilis

Using a procedure that minimizes shear forces, the BamHI-derived forked termination of replication intermediate of Bacillus subtilis, called band I DNA, can be extracted with little or no accompanying band II DNA. It has been shown that band II DNA is a product of band I breakdown. Nuclease P1-mediated breakdown of the forked band I DNA proceeds in two steps. The first causes the release of one of the arms as band II DNA; in the second step, the remaining arm is cleaved away to yield the free stem. It is concluded that band I represents the primary termination of replication intermediate. A quantitative assessment of the level of band I in DNA from cells of the merodiploid strain, GSY1127, growing at different rates has been made. For cells grown in a minimal medium, at least, the experimentally measured level of band I is of the order (approx. 60%) of that predicted for a complete block to movement of the clockwise fork at the replication terminus, terC.     

Mechanisms of polar arrest of a replication fork

A DNA replication terminator sequence blocks an approaching replication fork when the moving replisome approaches from just one direction. The mechanism underlying polar arrest has been debated for years, but recent work has helped to reveal how a replication fork is blocked in Escherichia coli . Early work suggested that asymmetric interaction between terminator protein and terminator DNA contributes to polar fork arrest. A later study demonstrated that if the terminator DNA is partially unwound, the resulting melted DNA could bind tightly to the terminator protein, suggesting a mechanism for polar arrest that involves a locked complex. However, recent evidence suggests that the terminator protein–DNA contacts are not sufficient for polar arrest in vivo . Furthermore, polar arrest of a replication fork still occurs in the absence of a locked complex between the terminator protein and DNA. In E. coli and Bacillus subtilis , the bound terminator protein makes protein–protein contacts with the replication fork helicase, and these contacts are critical in blocking progression of the advancing fork. Thus, we propose that interactions between the replication fork helicase and terminator protein are the primary mechanism for polar fork arrest in bacteria, and that this primary mechanism is modulated by asymmetric contacts between the terminator protein and its cognate DNA sequence. In yeast, terminator sequences are present in rDNA non-transcribed spacers and a region immediately preceding the mating type switch locus Mat1, and the mechanism of polar arrest at these regions is beginning to be elucidated.     

Evidence of a ter specific binding protein essential for the termination reaction of DNA replication in Escherichia coli.

Activity binding specifically to the 22 bp of the DNA replication terminus (ter) sequence on plasmid R6K and the Escherichia coli genome was detected in the crude extract of E. coli cells. This activity was inactivated by heat or by protease but not by RNase treatments. Overproduction of the ter binding activity was observed when the extract was prepared from the cell carrying a plasmid with a chromosomal-derived 5.0 kb EcoRI fragment, on which one of the four terC sites, terC2, was also located. By mutagenesis of the 5.0 kb fragment on the plasmid with transposon Tn3 and subsequent replacement of the corresponding chromosomal region with the resulting mutant alleles, we isolated tau- mutants completely defective in ter binding activity. These mutants simultaneously lost the activity to block the progress of the DNA replication fork at any ter site, on the genome or the plasmid. It would thus appear that the ter binding protein plays an essential role in the termination reaction, at the ter sites.     

Utilization of subsidiary chromosomal replication terminators in Bacillus subtilis

The Bacillus subtilis merodiploid strain GSY1127 contains a large nontandem duplication of a portion of its chromosome within its left (anticlockwise) replication segment. This causes displacement of the replication terminus region to a noticeably asymmetric location relative to oriC. The utilization of the subsidiary replication terminators, TerIII and TerV, in the merodiploid strain has been compared with that in B. subtilis 168. It is shown that TerIII is utilized to a significant extent in GSY1127 and that TerV is used only marginally at the most. Neither of these terminators is used to a measurable extent in the 168 strain. It is concluded that TerIII and TerV do indeed function as backups to the major terminator TerI, as has been generally thought. It is further concluded that, in the 168 strain, the vast majority of clockwise forks are arrested at the highly efficient TerI terminator, with fork fusion between the approaching forks occurring frequently while the clockwise fork is stationary at TerI.     

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.     

EcoRI cleavage sites in the argECBH region of the Escherichia coli chromosome.

The EcoRI cleavage of deoxyribonucleic acids (DNAs) from lambdadarg phages, carrying argECBH, has been examined. The phages are derived from the heat-inducible, lysis-defective strain lambda y199, and their bacterial DNA, including argECBH, is derived from Escherichia coli K-12. Such cleavage of the phage DNAs, in each case, produces the D, E, and F segments of lambda. Additionally, these DNAs yield segments, ordered from left to right, of length (in kilobases [kb]) determined by electron microscopy and 0.7% agarose slab gel electrophoresis as follows: lambdadarg13 (ppc argECBH bfe), 13.9, 2.8, 1.5, and 5.6; lambdadarg14 (ppc argECBH), 3.0, 2.0, 17.3, and 6.2; and lambdadarg23 (argECBH), 18.4 and 6.2. For lambdadarg13 sup102 DNA, the segment analogous to the 13.9-kb segment measures 12.2 kb. The direction from left to right corresponds to the clockwise orientation of the E. coli genetic map. The EcoRI segments define five cleavage sites near the arg region of the E. coli chromosome. For each of the DNAs, the arg genes occur on the largest segment produced. The 17.3-kb segment, being entirely bacterial, represents the argECBH-bearing EcoRI segment of the E. coli chromosome. The location of the arg genes was demonstrated electron microscopically in heteroduplex experiments.     

Nonrandom cosmid cloning and prophage SP beta homology near the replication terminus of the Bacillus subtilis chromosome.

From a library of Bacillus subtilis DNA cloned with the Escherichia coli cosmid vector pHC79, 85 recombinant cosmids containing DNA from near the replication terminus, terC, were identified. The DNA inserts of these cosmids were confined to three regions of a 350-kilobase segment of the chromosome extending from the left end of the SP beta prophage to approximately 75 kilobases on the right of terC. All B. subtilis genes known to reside in this segment, as well as the portion of the SP beta prophage that is expressed early in the lytic cycle of the phage, appeared to be absent from the library. A region of SP beta homology distinct from the prophage and just to the left of terC was identified.     

Cloning and comparison of the DNA encoding ammelide aminohydrolase and cyanuric acid amidohydrolase from three s-triazine-degrading bacterial strains.

DNA encoding the catabolism of the s-triazines ammelide and cyanuric acid was cloned from Pseudomonas sp. strain NRRLB-12228 and Klebsiella pneumoniae 99 with, as a probe, a 4.6-kb PstI fragment from a third strain, Pseudomonas sp. strain NRRLB-12227, which also encodes these activities. In strains NRRLB-12228 and 99 the ammelide aminohydrolase (trzC) and cyanuric acid amidohydrolase (trzD) genes are located on identical 4.6-kb PstI fragments which are part of a 12.4-kb DNA segment present in both strains. Strain NRRLB-12227 also carries this 12.4-kb DNA segment, except that a DNA segment of 0.8 to 1.85 kb encoding a third enzyme, ammeline aminohydrolase (trzB), has been inserted next to the ammelide aminohydrolase gene with the accompanying deletion of 1.1 to 2.15 kb of DNA. In addition, the s-triazine catabolic genes are flanked in strain NRRLB-12227 by apparently identical 2.2-kb segments that are not present in the other two strains and that seem to cause rearrangements in adjacent DNA.     

Molecular cloning of the delta-endotoxin gene of Bacillus thuringiensis var. israelensis

A transformant of Bacillus megaterium, VB131, was isolated which carries a 6.3-kb XbaI segment of the crystal toxin gene of Bacillus thuringiensis var. israelensis (BTI) cloned in a vector plasmid pBC16 to yield pVB131. The chimeric plasmid DNA from VB131 was introduced into a transformable Bacillus subtilis strain by competence transformation. Both the B. megaterium VB131 strain and the B. subtilis strain harboring the chimeric plasmid produced irregular, parasporal, phase-refractile, crystalline inclusions (Cry+) during sporulation. The sporulated cells as well as the isolated crystal inclusions of the pVB131-containing B. megaterium and B. subtilis strains were highly toxic to the larvae of Aedes aegypti. Also, the solubilized crystal protein preparation from VB131[pVB131] showed clear immuno cross-reaction with antiserum to the BTI crystal toxin. 32P-labeled pVB131 plasmid DNA showed specific hybridization with a 112-kb plasmid DNA of Cry+ strains of BTI, and no hybridization with other plasmid or chromosomal DNA of either Cry+ or Cry- variants. These results are in agreement with our previous findings (González and Carlton, 1984) that the 112-kb plasmid of BTI is associated with the production of the crystal toxin.