Origin of replication, oriC, of the Escherichia coli chromosome: mapping of genes relative to R.EcoRI cleavage sites in the oriC region

Recollections of a Helmstetter Disciple

Nearly fifty years ago, it became possible to construct E. coli minichromosomes using recombinant DNA technology. These very small replicons, comprising the unique replication origin of the chromosome oriC coupled to a drug resistance marker, provided new opportunities to study the regulation of bacterial chromosome replication, were key to obtaining the nucleotide sequence information encoded into oriC and were essential for the development of a ground-breaking in vitro replication system. However, true authenticity of the minichromosome model system required that they replicate during the cell cycle with chromosome-like timing specificity. I was fortunate enough to have the opportunity to construct E. coli minichromosomes in the laboratory of Charles Helmstetter and, for the first time, measure minichromosome cell cycle regulation. In this review, I discuss the evolution of this project along with some additional studies from that time related to the DNA topology and segregation properties of minichromosomes. Despite the significant passage of time, it is clear that large gaps in our understanding of oriC regulation still remain. I discuss some specific topics that continue to be worthy of further study.

RNA modification enzymes encoded by the gid operon: Implications in biology and virulence of bacteria

Ribonucleic acid (RNA) molecules consist of numerous chemically modified nucleosides that are highly conserved in eukarya, archeae, and bacteria, while others are unique to each domain of life. In bacteria, hundreds of RNA modification enzymes have been identified and implicated in biological pathways associated with many cell processes. The glucose-inhibited division (gid) operon encodes genes for two RNA modification enzymes named GidA and GidB. Studies have shown GidA is essential for the proper biosynthesis of 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U) of bacterial transfer RNA (tRNA) with GidB responsible for the methylation of the 16S ribosomal RNA (rRNA). Furthermore, deletion of gidA and gidB has shown to alter numerous bacterial properties like virulence, stress response, morphology, growth, antibiotic susceptibility, and others. In this review, we discuss the present knowledge of the RNA modification enzymes GidA and GidB, and their potential role in the biology and virulence of bacteria.

Phylogenetic relationship of Paenibacillus species based on putative replication origin regions and analysis of an yheCD-like sequence found in this region

To determine the phylogenetic relationship among Paenibacillus species, putative replication origin regions were compared. In the rsmG-gyrA region, gene arrangements in Paenibacillus species were identical to those of Bacillus species, with the exception of an open reading frame (orf14) positioned between gyrB and gyrA, which was observed only in Paenibacillus species. The orf14 product was homologous to the endospore-associated proteins YheC and YheD of Bacillus subtilis. Phylogenetic analysis based on the YheCD proteins suggested that Orf14 could be categorized into the YheC group. In the Paenibacillus genome, DnaA box clusters were found in rpmH-dnaA and dnaA-dnaN intergenic regions, known as box regions C and R, respectively; this localization was similar to that observed in B. halodurans. A phylogenetic tree based on the nucleotide sequences of the whole replication origin regions suggested that P. popilliae, P. thiaminolyticus, and P. dendritiformis are closely related species.

The right half of the Escherichia coli replication origin is not essential for viability, but facilitates multi-forked replication

Replication initiation is a key event in the cell cycle of all organisms and oriC, the replication origin in Escherichia coli, serves as the prototypical model for this process. The minimal sequence required for oriC function was originally determined entirely from plasmid studies using cloned origin fragments, which have previously been shown to differ dramatically in sequence requirement from the chromosome. Using an in vivo recombineering strategy to exchange wt oriCs for mutated ones regardless of whether they are functional origins or not, we have determined the minimal origin sequence that will support chromosome replication. Nearly the entire right half of oriC could be deleted without loss of origin function, demanding a reassessment of existing models for initiation. Cells carrying the new DnaA box-depleted 163 bp minimal oriC exhibited little or no loss of fitness under slow-growth conditions, but were sensitive to rich medium, suggesting that the dense packing of initiator binding sites that is a hallmark of prokaryotic origins, has likely evolved to support the increased demands of multi-forked replication.

Escherichia coli minichromosomes: random segregation and absence of copy number control

Minichromosomes, i.e. plasmids that can replicate from an integrated oriC, have been puzzling because of their high copy numbers compared to that of the chromosomal oriC, their lack of incompatibility with the chromosome and their high loss frequencies. Using single cell resistance to tetracycline or ampicillin as an indicator of copy number we followed the development of minichromosome distributions in Escherichia coli cells transformed with minichromosomes and then allowed to grow towards the steady state. The final copy number distribution was not reached within 15 to 20 generations. If the minichromosome carried the sop (partitioning) genes from plasmid F, the development of the copy number distribution was further drastically delayed. We conclude that E. coli cells have no function that directly controls minichromosomal copy numbers, hence the absence of incompatibility in the sense of shared copy number control. We suggest that minichromosomes are subject to the same replication control as the chromosome but segregate randomly in the absence of integrated partitioning genes. This, combined with evidence that the lowest copy number classes are normally present despite high average copy numbers, can account for the high loss frequencies.

UV irradiation inhibits initiation of DNA replication from oriC in Escherichia coli

Irradiation of Escherichia coli with UV light causes a transient inhibition of DNA replication. This effect is generally thought to be accounted for by blockage of the elongation of DNA replication by UV-induced lesions in the DNA (a cis effect). However, by introducing an unirradiated E. coli origin (oriC)-dependent replicon into UV-irradiated cells, we have been able to show that the environment of a UV-irradiated cell inhibits initiation of replication from oriC on a dimer-free replicon. We therefore conclude that UV-irradiation of E. coli leads to a trans-acting inhibition of initiation of replication. The inhibition is transient and does not appear to be an SOS function.

The fim genes responsible for synthesis of type 1 fimbriae in Escherichia coli, cloning and genetic organization

The genes responsible for the expression of type 1 fimbriae, produced by the majority of E. coli strains, have been cloned from an E. coli K12 strain. The "passenger" DNA from an initial cosmid clone was reduced in size and subcloned in pACYC184 and pBR322 vectors. A DNA fragment of around 8 kbp was found to be required for the biosynthesis of type 1 fimbriae. This was further studied by transposon-mediated insertional inactivation and by BAL31-mediated deletions. Four genes, designated fimA, B, C, and D were found to be involved in the synthesis of the fimbriae. They encoded proteins that in their processed form appeared with apparent molecular weights of 16.5 kd, 23 kd, 26 kd, and 89 kd, the 16.6 kd polypeptide being the fimbrial subunit. The order to the genes was found to be: fimB, fimA, fimC, and fimD, organized in three transcriptional units.

The E. coli K-12 chromosome flanked by two IS10 sequences transposes

Transposon are commonly found among prokaryotes and usually range up to 20 kilobases. In this study, we were interested to determine whether a larger DNA segment could transpose. We observed that the E. coli K-12 chromosome, 4,000 kilobases in size, when flanked by two IS10 sequences, could transpose to pACYC177 at a frequency of 10(-8) per cell per generation. We suggest that this transposition event occurs independently of the size and without duplication of the entire DNA sequence flanked by the IS10 elements.

The fimA gene encoding the type-1 fimbrial subunit of Escherichia coli. Nucleotide sequence and primary structure of the protein

The nucleotide sequence was determined of a region of 1450 base pairs encompassing the fimA gene for the subunit of type 1 fimbriae of Escherichia coli as well as flanking regions containing potential regulator sequences. The 'translated' protein contains a 23-residue signal peptide; the processed fimbrial subunit consists of 158 amino acid residues yielding a relative molecular mass of 15706. The elucidated sequence shows significant homology with those of other E. coli fimbrial proteins.

Sequence organization of replication origin of the Escherichia coli K-12 chromosome

A sequence of 245 base-pairs (oriC) in the replication origin of the Escherichia coli K-12 chromosome has been shown to provide all the information essential for initiation of bidirectional replication. In order to elucidate the sequence organization of oriC, numerous mutants carrying a single-to-multiple transitions from G X C to A X T base-pair were constructed by localized mutagenesis in vitro, which uses sodium bisulfite, and the correlation between the mutation sites and replicating ability (Ori function) was systematically analyzed. By isolating non-defective (Ori+) mutants with multiple base changes, transitions at 71 positions among 101 G X C pairs in oriC were found to have no effect on Ori function. Investigation of defective (Ori-) mutants, on the other hand, showed that individual replacements at 18 positions were detrimental to Ori function to some extent. These irreplaceable G X C pairs fell in the positions where no substitution was detected in the Ori+ mutants. The defect of the Ori- mutants with a single base substitution was generally weaker than that of the previously constructed Ori- mutants lacking a part of oriC. The addition of two or more base changes each giving a faint Ori- phenotype, however, resulted in a more intensive Ori- phenotype. We have previously demonstrated that oriC contains several regions where deletion or insertion of oligonucleotides leads to strong Ori- phenotypes. Transitions in those areas did not cause any defect of Ori function. Combining present results on base substitution mutants with the previous observations together, we assumed that the oriC sequence provides multiple interaction sites with replication initiation factors, and the precise arrangement of these sites are required for Ori function.

Affinity of two different regions of the chromosome to the outer membrane of Escherichia coli

It was found that DNA associated with the outer membrane of Escherichia coli K-12 is enriched for two different regions of the chromosome, which are both on the 5.9-megadalton EcoRI fragment containing the replication origin, oriC. One region overlaps oriC, whereas the other region was found to be associated with a 1-megadalton EcoRI-BamHI fragment located within the atp operon.

Formation of type II F-primes from unstable Hfrs and their recA-independent conversion to other F-prime types

Four E. coli Hfr strains, representing stable (Hfr Cavalli), moderately stable (AB312) and unstable (Ra-1, Ra-2) Hfr states, were used in the isolation of a series of F' plasmids. Type II F's were found to be the most prevalent F' plasmid formed from all of the Hfrs, while the percentages of delta tra F's increased as the stability of the Hfr increased. Two observations suggested that F' formation in unstable Hfrs like Ra-2 may proceed through a type II F' precursor. First, the major F' products of Ra-2 are tra+ type II F's and, second, other F' types (I, II) and classes (tra+, delta tra) from Ra-2 appeared to be deletion derivatives of a larger F' progenitor. By monitoring the molecular changes that occur when the Ra-2 derived type II F' pWS200 is transferred from one recA host to another, we have found that all F' types and classes can be generated from pWS200 in a recA-independent manner. F sequences involved in the genetic conversions of pWS200 include the oriT locus and the directly repeated gamma delta junctions of F and chromosomal DNA. A model for the formation of F's in unstable Hfrs is postulated in which a tra+ type II F' primary excision product is seen to be modified, through recA-independent processes, to other F' types and classes. This model differs from the current model of F' formation in that independent excision events from the Hfr chromosome are not seen as the source of type I and type II F's. These studies have also shown that the formation of delta tra F's is a recA-independent process that can occur from the F' and Hfr states, that gamma delta-mediated deletions in pWS200 often demonstrate regional specificity in having endpoints near the ilv operon and that genetic alterations in either replication origin of pWS200 (F oriV, chromosomal oriC) stabilize the replication of this "mini-Hfr" cointegrate.

Regulation of DNA synthesis and capacity for initiation in DNA temperature sensitive mutants of Escherichia coli I. Reinitiation and chain elongation

The capacity for initiation and subsequent chain elongation was examined in several DNA temperature sensitive mutants of Escherichia coli after the mutants had been held at nonpermissive temperature for approximately 1.5 generation equivalents and then returned to permissive temperature in the presence of chloramphenicol. The results obtained indicate that 4-5 sets of replication forks can be initiated after return to permissive temperature in the presence of chloramphenicol but the forks apparently become stalled and fail to complete chromosomal replication in the presence of chloramphenicol. In temperature reversible dnaA mutants, once the chloramphenicol is removed the forks appear to be able to resume replication at the nonpermissive temperature. The relationship between premature initiation and premature chain termination is discussed.

The genes for the eight subunits of the membrane bound ATP synthase of Escherichia coli

The genes for the eight subunits of the membrane bound ATP synthase of Escherichia coli (Ca++, Mg++ dependent ATPase, EC 3.6.1.3) were mapped through genetic, physical and functional analysis of specialized transducing phages lambda asn (von Meyenburg et al. 1978). The ATP synthase genes, designated atp1, are located at 83.2 min in a segment of the chromosome between 3.5 and 11.3 kb left (counterclockwise) of the origin of replication oriC. The counterclockwise order of the genes for the eight subunits, the expression of which starts from a control region at 3.5 kb-L, was found to be: a, (c, b, delta), alpha, gamma, (epsilon, beta) which in the notation of Downie el al. (1981) reads atp B (EFH) A G (C D). The analysis was in part based on the isolation of new types of atp (unc, Suc-) mutations. We made use of the fact that specialized transducing phages lambda asn carrying oriC can establish themselves as minichromosomes rendering asnA cells Asn+, and that the resulting Asn+ cells grow slowly if the lambda asn carries part or all of the atp operon. Selecting for fast growing strains mutations were isolated on the lambda asn which either eliminated atp genes or affected their expression ("promoter" mutations). The relationship between these atp mutations and the cop mutations of Ogura et al. (1980), which also appear to map in front of or within the atp genes, is discussed.

Replication of M13 oriC bacteriophages in Escherichia coli rep mutant is dependent on the cloned Escherichia coli replication origin

The involvement of the Escherichia coli rep protein in the replication of M13 chimeric deoxyribonucleic acids (DNAs) carrying the E. coli chromosomal DNA replication origin (oriC) has been examined. Previous studies indicate that the cloning of a 3,550-base-pair sequence of chromosomal DNA containing oriC into an M13 vector allows extensive replication of the M13 oriC chimeric DNA in an E. coli rep-3 mutant. We have extended these studies by preparing a 330-base-pair deletion that specifically deletes the oriC sequence in the M13 oriC DNAs, to demonstrate that the replication observed in the rep-3 host is dependent on the cloned origin. Thus, a DNA-unwinding enzyme other than the rep protein may be involved in the strand separation process accompanying replication which initiates at oriC in the M13 oriC chimeric DNAs and in the E. coli chromosome. The rep assay used for assessing the functionality of the cloned oriC is useful for analysis of any rep-independent origin of replication functional in E. coli. A direct selection for a cloned origin of replication is possible in the rep-3 recA56 host. Since the cloned origin is nonessential for propagation of the M13 chimeric phage in a rep+ host, mutations in the cloned origin may be constructed, and the mutant phage may be examined by a simple transductional analysis of the rep-3 recA56 mutant strain.

Site-specific integration of an F' lac pro factor in the region of the replication origin (oriC) of E. coli

An episome, F128, which carries approximately 8 x 10(4) base pairs of chromosomal DNA homologous to the lac pro region of the E. coli chromosome, has been found to integrate into the oriC region of the chromosome in a site specific reaction. While the event appears to be recA-dependent, no homology between the episome and this region of the chromosome was detected. The Hfr strains formed result from the integration of intact F128 molecules. The structure of the Hfr strains generated has been determined and their transfer properties analyzed.

Functional analysis of minichromosome replication: bidirectional and unidirectional replication from the Escherichia coli replication origin, oriC

Replicating molecules of minichromosomes pCM959 and pOC24 were analyzed by electron microscopy. Replication of pCM959 proceeded bidirectionally from the replication origin, oriC, in about 60% of the molecules; the rest of the molecules replicated unidirectionally in either direction. pOC24, in which deoxyribonucleic acid to the right (clockwise) of the oriC segment is deleted, seemed to replicate predominantly unidirectionally counterclockwise from oriC.

Copy-number mutants of the plasmid carrying the replication origin of the Escherichia coli chromosome: evidence for a control region of replication

A composite plasmid (pXX11) was constructed by joining of an oriC plasmid (pMCR115) carrying the replication origin (oriC) of the Escherichia coli chromosome and a mini-F plasmid (pSC138) carrying the ampicillin-resistance gene (bla). Plasmid pXX11 can replicate, by using oriC, in Hfr cells and mafA mutant cells that cannot support replication of an F plasmid. This plasmid is stably maintained in these host cells during cell growth even under nonselective conditions by use of the partition mechanism of the mini-F genome. In contrast to other oriC plasmids reported previously, pXX11 has no detectable effect on host cell growth. Higher copy-number (Cop-) mutants of pXX11 were isolated, and some of them were found to carry an insertion or deletion within a region derived from the E. coli chromosome. This region, designated cop (copy number), covers about 0.7 kilobase pair and is located approximately 3 kilobase pairs away from the oriC region at the side opposite the asn gene. Evidence suggests that the normal cop region locted on the oriC plasmid acts to reduce the copy number of the plasmid. Plasmid pXX11 complements the uncB402 mutation located on the host chromosome, but some of the Cop- plasmids do not, suggesting that the cop region is vey closely linked to uncB.

Isolation and characterization of lambda b221poriCasnA, a plaque-forming specialized transducing phage carrying the origin of replication of the Escherichia coli chromosome

A specialized transducing phage lambda b221poriCasnA has been isolated carrying oriC the origin of chromosomal replication of Escherichia coli. All phage genes required for lytic growth are retained, thus the phage is capable of lytic growth. The presence of the oriC locus confers upon infecting phage DNA the ability to replicate as a plasmid using only host DNA replication functions. The presence of both oriC and ansA markers has allowed the development of a plaque assay for origin function which can be used to identify mutants at these loci. Comparison of restriction endonuclease cleavage sites present on lambda b221proiCasnA DNA to those on its parent, lambda b221 rex::Tn10 suggests the steps involved in the formation of the transducing phage.

Replication origin of the Escherichia coli K-12 chromosome: the size and structure of the minimum DNA segment carrying the information for autonomous replication

A DNA fragment containing the replication origin of the Eschericia coli K-12 chromosome was inserted in two correlations at either the BamHI or SalI site of pBR322 DNA. All the resulting hybrid plasmids were found to replicate in both polA and polA+ cells, whereas pBR322 replicates only in polA+ cells. This characteristic provided a method for assaying the autonomously replicating ability (Ori function of the E. coli origin. In order to define the minimum DNA region (ori) that determines Ori function, deletions of various sizes were introduced from either side of the ori-containing segment in the hybrid plasmids by in vitro techniques, and the correlation between the Ori phenotype and nucleotide sequence of the deletion derivatives was analyzed. It was found that the left end of ori is between positions 23 and 35, and the right end is either position 266 or 267 in our nucleotide coordinate (Sugimoto et al., 1979). Therefore, ori is present within a region of minimum 232 base pairs and maximum 245 base pairs in length. The Ori+ and Ori- phenotypes were clearly resolved at both sides of these boundaries by the above assay procedure. To obtain information about the effect of mutations in the internal region of the defined ori stretch, short sequences were inserted or deleted in vitro in the vicinity of several restriction sites within ori on the hybrid plasmids. Most of these plasmids carrying modified sequences showed Ori- phenotype, suggesting that most parts of the ori stretch play important roles in Ori function.

Inititation and termination of chromosome replication in Escherichia coli subjected to amino acid starvation

Initiation and termination of chromosome replication in an Escherichia coli auxotroph subjected to amino acid starvation were examined by following the incorporation of [3H]thymidine into the EcoRI restriction fragments of the chromosome. The pattern of incorporation observed upon restoration of the amino acid showed that starvation blocks the process of initiation prior to deoxyribonucleic acid synthesis within any significant portion of the EcoRI fragment which contains the origin of replication, oriC. In this experiment, no incorporation of [3H]thymidine into EcoRI fragments from the terminus of replication was observed, nor was it found when a dnaC initiation mutant was used to prevent incorporation at the origin which might have obscured labeling of terminus fragments. Thus amino acid starvation does not appear to block replication forks shortly before termination of replication. Attempted synchronization of replication initiation by including a period of thymine starvation subsequent to the amino acid starvation led to simultaneous incorporation of [3H]-thymidine into all EcoRI fragments within the 240-kilobase region that surrounds oriC. It is shown that the thymine starvation step allowed initiation and a variable, but limited, amount of replication to occur.

Mutations in two unlinked genes are required to produce asparagine auxotrophy in Escherichia coli

Escherichia coli K-12 has two genes, asnA+ and asnB+, either one of which is able to satisfy the need of cells for asparagine. In order for a strain to have an auxotrophic requirement for asparagine, both genes must be mutationally inactivated. We obtained mutants with Tn5 inserted in asnB. asnB was mapped by conjugation and by three-factor P1 transductions at 15 min on the E coli K-12 linkage map, between ubiF and nagB. Specialized transducing phage lamba 781 supE was shown to carry asnB, as well as supE, ubiF, nagA, and nagB. asnA is the previously mapped ilv-linked asn locus, whiich is between uncB and rbs. E. coli C also has two asn genes, corresponding to asnA and asnB.

Requirement of DNA gyrase for the initiation of chromosome replication in Escherichia coli K-12

It has been found that strains carrying mutations in the dnaA gene are unusually sensitive to COU, NAL or NOV, which are known to inhibit DNA gyrase activities. The delay in the initiation of chromosome replication after COU treatment has been observed in cells with chromosomes synchronized by amino acid starvation or by temperature shift-up (dnaA46). The unusual sensitivity of growth to COU of the initiation mutant runs parallel to a higher sensitivity to the drug of the initiation of chromosome replication. The double mutant, dnaA46, cou-110 has been isolated and mutation cou-110 conferring resistance of growth, initiation and elongation of chromosome replication to COU was mapped in the gene coding for the subunit of DNA gyrase. The reduced frequency of appearance of the mutants resistant to COU, NAL, or NOV in the initiation mutant suggests that some mutations in genes coding for DNA gyrase subunits cannot coexist with the dnaA46 mutation. The possible mechanisms of the requirement of DNA gyrase for dnaA-dependent initiation of E. coli chromosome are discussed.

Deoxyribonucleic acid and outer membrane: strains diploid for the oriC region show elevated levels of deoxyribonucleic acid-binding protein and evidence for specific binding of the oriC region to outer membrane

We have recently reported that part of the chromosomal deoxyribonucleic acid (DNA) of Escherichia coli is associated with the outer membrane fraction and that an outer membrane protein having a molecular weight of 31,000 probably is involved in this association (H. Wolf-Watz and A. Norqvist, J. Bacteriol. 140:43-49, 1979). We have now found that F' merodiploid strains containing two copies of the DNA between bglB and ilv have increased levels of this protein and an increased amount of DNA in their outer membranes. Increased levels of the protein are also found when lambda asn phage, containing at 1.5-megadalton fragment of DNA located to the right of the uncA uncB genes but to the left of oriC, are induced. It therefore seems that this 1.5-megadalton fragment of DNA either codes for or binds to the 31,000-dalton outer membrane protein. Hybridization studies utilizing DNA found to be bound to outer membrane and DNA isolated from a specialized transducing phage lambda asn 132 revealed that at least 5 to 10% of outer membrane DNA has a DNA sequence homologous with a chromosomal segment carried by this oriC-containing phage.

Location and characterisation of a new replication origin in the E. coli K12 chromosome

A segment of DNA located in the region of the E. coli K12 chromosome previously identified by the Rac phenotype can function as a self-replicating plasmid. Evidence is presented that this plasmid, the oriJ plasmid, contains the origin of replication of a defective prophage postulated to be located in this chromosomal region by Low (1973). The plasmid can only be maintained in strains in which this postulated prophage has been deleted. In strains which possess the prophage selection for plasmid maintenance permits the isolation of clones containing new deletions which we postulate are the result of prophage excision.

Characterization of the dnaA, gyrB and other genes in the dnaA region of the Escherichia coli chromosome on specialized transducing phages lambda tna

Specialized transducing phages lambda tna (tryptophanase) harboring chromosomal DNA and genetic markers from the dnaA region of the Escherichia coli chromosome were isolated. Transductional analysis showed that some of these tnaA transducing phages carry two genes important in DNA replication, namely the dnaA gene (initiation of chromosome replication) and the gyrB gene (subunit B of DNA gyrase), formerly designated couR. The following clockwise order of genetic markers was found: uhp, gyrB, dnaA, rimA, tnaA, bglB. The gene-protein relationship was established by the determination of the gene products encoded on the chromosomal DNA of the different lambda tna. A 54 kD and a 91 kD polypeptide appear to be coded for by the dnaA and gyrB genes, respectively; the 91 kD protein is encoded on a region in which coumermycin sensitivity maps and is with respect to electrophoretic behavior identical to subunit B of DNA gyrase. The 54 kD protein is encoded on the region in which different independently isolated dnaA(Ts) mutations (dnaA5, dnaA46, dnaA167, dnaA203, dnaA204, dnaA205, dnaA211, dnaA508) are located. Additional genes which code for polypeptides with hitherto unknown functions were identified and mapped. The acriflavin sensitivity mutation acrB1 was found to be an allele of the gyrB gene (see "Note Added in Proof").

Genetic mapping of the chromosomal replication origin of Salmonella typhimurium

Two hundred strains of Escherichia coli harboring Filv+ plasmids which carry a segment of the Salmonella typhimurium chromosome were isolated independently. Among them, two strains were found to harbor F' plasmids that are able to replicate in Hfr cells of E. coli; i.e., they carry a site designated poh (permissive on Hfr) of the S. typhimurium chromosome. The poh site is presumably identical with the replication origin (oriC) of the bacterial chromosome. These two plasmids carry the dnaA-uncA-rbs-ilv-cya-metE region of the chromosome of S. typhimurium. Other F' plasmids which only carried the ilv-cya-metE region were unable to be maintained in Hfr cells. The poh site (= oriC) of S. typhimurium thus is located in the uhp-ilv region of the chromosome. The two plasmids carrying the poh site of S. typhimurium can suppress the temperature-sensitive character of an E. coli mutant that carries the temperature-sensitive dnaA46 allele, when the plasmids exist in the mutant cells. This suggests that the dnaA chromosome in place of the dnaA gene product of E. coli itself. The ability of the plasmids carrying the poh site of S. typhimurium to replicate in Hfr cells of E. coli suggests that the replication system of E. coli can recognize the Salmonella replication origin.

DNA synthesis in UV-irradiated Escherichia coli K-12 strains carrying dnaA mutations

It has been found that UV irradiation of dnaA mutants of E. coli K-12 enables the initiation of DNA synthesis at a temperature restrictive to these mutants. The UV-induced DNA synthesis is dependent on protein synthesis and on a transcriptional event at a time when protein synthesis is no longer required. In contrast to dnaA mutants UV irradiation fails to induce DNA synthesis in the two other initiation mutants dnaC2 and dnaB252. DNA synthesis at the restrictive temperature is initiated also when the tif-1 phenotype is expressed in the dnaA46 tif-1 double mutant. Possible mechanisms of the observed capability of dnaA mutants to synthesize DNA at the restrictive temperature after UV irradiation or under conditions of tif-1 expression are discussed.

The structure of the phi 80d3 ilv+ Su+7 transducing phage and the origin of its Su+7 tRNA-gene containing fragment

The Bam HI, XhoI, and EcoRI sites of the transducing phage phi 80d3Su+7ilv+ are located. The 1.2 x 10(6) MD EcoRI fragment which, when cloned, contains tRNAAsp and expresses the mutant tRNATry gene, Su+7, and which also relaxes control of stable RNA synthesis is found immediately adjacent to the rrnC region. Its tRNA genes, tRNAAsp and tRNATry, are transcribed in the same direction as the ribosomal RNA genes, though no mature rRNA subsequences are on the fragment. This fragment also exists as such in another F-prime factor derived from the same Hfr host, and therefore presumably also in the Hfr chromosome itself. It is composed of about half ordinary chromosomal and half F DNA sequences, the latter from the gamma-delta region of F. The advantages of a novel mapping method used are discussed.

In vitro replication of a DNA fragment containing the vicinity of the origin of E. coli DNA replication

The restriction nuclease cleavage pattern of E. coli DNA synthesized in vitro in the cellophane membrane system (Schaller et al., 1972) is similar to the one obtained after labelling E. coli in vivo. This is shown for exponentially growing cells and for cells synchronized by amino acid starvation followed by thymine starvation. In synchronized cells a piece of some 180 kilobase pairs is labelled containing oriC and neighbouring regions at 82 min on the genetic map of E. coli. A pulse label in vitro is incorporated into the same piece of DNA, but the center of this region, i.e. the EcoR1 fragment of 8.6 kbp length which contains the oriC region (Marsh and Worcel, 1977; v. Meyenburg et al., 1977; Yasuda and Hirota, 1977) is missing.

Map location of the Escherichia coli origin of replication

Working with restriction fragments obtained directly from the Escherichia coli K12 chromosome, the EcoRI-HindIII restriction map of the section of the chromosome containing the replication origin has been extended by 14 kilobase pairs (kb) to cover 56 kb. Within this newly mapped portion, the ilv and rrnC cistrons have been identified by (1) hybridization of individual restriction fragmanents to the ilv-transducing phage lambdadilv5 and (2) a comparison of the restriction map of this region with the EcoRI map of lambda dilv5 and the Hind III map of the plasmid pJC110, a ColEl-ilv hybrid. The replication origin is located approximately 30 kb from the ilvE gene and 20 kb from the rrnC 16S rRNA cistron. This places the origin near 82.7 min on the genetic map, close to uncA.

Chromosomal location of a gene (nmpA) involved in expression of a major outer membrane protein in Escherichia coli

The phenotypic expression of protein E, a recently described major outer membrane protein, is associated with a mutation at a locus on the Escherichia coli chromosome that we call nmpA. nmpA is located between rbsK and uncA at 82.7 min on the E. coli linkage map. The nmpA locus is also the site of the mutations which lead to the formation of major outer membrane proteins Ic or e. It is likely proteins E, Ic, and e are closely related or identical. The mutant nmpA allele is dominant.

A ribosomal RNA gene, rrnC, of Escherichia coli, mapped by specialized transducing lambdadilv and lambda drbs phages

Specialized transducing phages carrying segments of the Escherichia coli chromosome from the rbs-ilv region including rrn genes have been isolated. These phages carry rrn transcription units coding for 16S and 23S rRNA with the direction of transcription clockwise towards the ilv operon. While one of the phages (lambdad279rbs) appears to carry the genuine rrn gene, denoted rrnC, located between rbs and ilv at 82 min on the E. coli chromosome another one isolated as an ilv transducing phage, lambda5ilv, carries a hybrid rrn gene, denoted rrnX, which has originated from a recombinational cross-over between the rrnC and one of the other rrn genes.

Mini-chromosomes: plasmids which carry the E. coli replication origin

We have isolated plasmids by linking the 5.9 MD EcoRI fragment of E. coli that carries the origin of replication to an EcoRI fragment that carries an amplicillin resistance determinant, but lacks an origin of replication. 3 plasmids of this type, pOC1, pOC2, and pOC3, are described in detail in this report. Although the plasmids have some adverse effect on the growth properties of the host strain, their existence shows that two functioning chromosomal origins can coexist in one cell. Deletions generated from this type of plasmids allow an allocation of the origin of replication of E. coli within a DNA segment less than 0.4 MD in size.

Map position of the replication origin on the E. coli chromosome

Strains carrying a dnaA temperature sensitive (t.s.) mutation and a Mu-1 prophage inserted within different genes near the origin of replication have been constructed. For each strain, integratively suppressed Hfrs, named G and D in which the ori region was replicated clockwise and counterclockwise respectively, were isolated. The strand preferences of Mu-1 specific Okazaki fragments were subsequently determined for each t.s. strain and its Hfr derivatives. Their comparison led us to establish the direction of replication of the Mu-1 marker from ori. The site ori was confined to the bglB-C--rbsK-P interval.