Genetic map of Escherichia coli strain C

Virulent Drexlervirial Bacteriophage MSK, Morphological and Genome Resemblance With Rtp Bacteriophage Inhibits the Multidrug-Resistant Bacteria

Phage-host interactions are likely to have the most critical aspect of phage biology. Phages are the most abundant and ubiquitous infectious acellular entities in the biosphere, where their presence remains elusive. Here, the novel Escherichia coli lytic bacteriophage, named MSK, was isolated from the lysed culture of E. coli C (phix174 host). The genome of phage MSK was sequenced, comprising 45,053 bp with 44.8% G + C composition. In total, 73 open reading frames (ORFs) were predicted, out of which 24 showed a close homology with known functional proteins, including one tRNA-arg; however, the other 49 proteins with no proven function in the genome database were called hypothetical. Electron Microscopy and genome characterization have revealed that MSK phage has a rosette-like tail tip. There were, in total, 46 ORFs which were homologous to the Rtp genome. Among these ORFs, the tail fiber protein with a locus tag of MSK_000019 was homologous to Rtp 43 protein, which determines the host specificity. The other protein, MSK_000046, encodes lipoprotein (cor gene); that protein resembles Rtp 45, responsible for preventing adsorption during cell lysis. Thirteen MSK structural proteins were identified by SDS-PAGE analysis. Out of these, 12 were vital structural proteins, and one was a hypothetical protein. Among these, the protein terminase large (MSK_000072) subunit, which may be involved in DNA packaging and proposed packaging strategy of MSK bacteriophage genome, takes place through headful packaging using the pac-sites. Biosafety assessment of highly stable phage MSK genome analysis has revealed that the phage did not possess virulence genes, which indicates proper phage therapy. MSK phage potentially could be used to inhibit the multidrug-resistant bacteria, including AMP, TCN, and Colistin. Further, a comparative genome and lifestyle study of MSK phage confirmed the highest similarity level (87.18% ANI). These findings suggest it to be a new lytic isolated phage species. Finally, Blast and phylogenetic analysis of the large terminase subunit and tail fiber protein put it in Rtp viruses' genus of family Drexlerviridae.

Genome rearrangements induce biofilm formation in Escherichia coli C - an old model organism with a new application in biofilm research

Background

Escherichia coli C forms more robust biofilms than other laboratory strains. Biofilm formation and cell aggregation under a high shear force depend on temperature and salt concentrations. It is the last of five E. coli strains (C, K12, B, W, Crooks) designated as safe for laboratory purposes whose genome has not been sequenced.

Results

Here we present the complete genomic sequence of this strain in which we utilized both long-read PacBio-based sequencing and high resolution optical mapping to confirm a large inversion in comparison to the other laboratory strains. Notably, DNA sequence comparison revealed the absence of several genes thought to be involved in biofilm formation, including antigen 43, waaSBOJYZUL for lipopolysaccharide (LPS) synthesis, and cpsB for curli synthesis. The first main difference we identified that likely affects biofilm formation is the presence of an IS3-like insertion sequence in front of the carbon storage regulator csrA gene. This insertion is located 86 bp upstream of the csrA start codon inside the − 35 region of P4 promoter and blocks the transcription from the sigma³² and sigma⁷⁰ promoters P1-P3 located further upstream. The second is the presence of an IS5/IS1182 in front of the csgD gene. And finally, E. coli C encodes an additional sigma⁷⁰ subunit driven by the same IS3-like insertion sequence. Promoter analyses using GFP gene fusions provided insights into understanding this regulatory pathway in E. coli.

Conclusions

Biofilms are crucial for bacterial survival, adaptation, and dissemination in natural, industrial, and medical environments. Most laboratory strains of E. coli grown for decades in vitro have evolved and lost their ability to form biofilm, while environmental isolates that can cause infections and diseases are not safe to work with. Here, we show that the historic laboratory strain of E. coli C produces a robust biofilm and can be used as a model organism for multicellular bacterial research. Furthermore, we ascertained the full genomic sequence of this classic strain, which provides for a base level of characterization and makes it useful for many biofilm-based applications.

Gapless, Unambiguous Genome Sequence for Escherichia coli C, a Workhorse of Industrial Biology

Escherichia coli C is a commonly used strain in the bioprocessing industry, but despite its utility, the publicly available sequence of the E. coli C genome has gaps and 4,180 ambiguous base calls. Here, we present an updated, high-quality, unambiguous genome sequence with no assembly gaps.

Multi-omics Quantification of Species Variation of Escherichia coli Links Molecular Features with Strain Phenotypes

Escherichia coli strains are widely used in academic research and biotechnology. New technologies for quantifying strain-specific differences and their underlying contributing factors promise greater understanding of how these differences significantly impact physiology, synthetic biology, metabolic engineering, and process design. Here, we quantified strain-specific differences in seven widely used strains of E. coli (BL21, C, Crooks, DH5a, K-12 MG1655, K-12 W3110, and W) using genomics, phenomics, transcriptomics, and genome-scale modeling. Metabolic physiology and gene expression varied widely with downstream implications for productivity, product yield, and titer. These differences could be linked to differential regulatory structure. Analyzing high-flux reactions and expression of encoding genes resulted in a correlated and quantitative link between these sets, with strain-specific caveats. Integrated modeling revealed that certain strains are better suited to produce given compounds or express desired constructs considering native expression states of pathways that enable high-production phenotypes. This study yields a framework for quantitatively comparing strains in a species with implications for strain selection.

The genes and enzymes for the catabolism of galactitol, D-tagatose, and related carbohydrates in Klebsiella oxytoca M5a1 and other enteric bacteria display convergent evolution

Enteric bacteria (Enteriobacteriaceae) carry on their single chromosome about 4000 genes that all strains have in common (referred to here as "obligatory genes"), and up to 1300 "facultative" genes that vary from strain to strain and from species to species. In closely related species, obligatory and facultative genes are orthologous genes that are found at similar loci. We have analyzed a set of facultative genes involved in the degradation of the carbohydrates galactitol, D-tagatose, D-galactosamine and N-acetyl-galactosamine in various pathogenic and non-pathogenic strains of these bacteria. The four carbohydrates are transported into the cell by phosphotransferase (PTS) uptake systems, and are metabolized by closely related or even identical catabolic enzymes via pathways that share several intermediates. In about 60% of Escherichia coli strains the genes for galactitol degradation map to a gat operon at 46.8 min. In strains of Salmonella enterica, Klebsiella pneumoniae and K. oxytoca, the corresponding gat genes, although orthologous to their E. coli counterparts, are found at 70.7 min, clustered in a regulon together with three tag genes for the degradation of D-tagatose, an isomer of D-fructose. In contrast, in all the E. coli strains tested, this chromosomal site was found to be occupied by an aga/kba gene cluster for the degradation of D-galactosamine and N-acetyl-galactosamine. The aga/kba and the tag genes were paralogous either to the gat cluster or to the fru genes for degradation of D-fructose. Finally, in more then 90% of strains of both Klebsiella species, and in about 5% of the E. coli strains, two operons were found at 46.8 min that comprise paralogous genes for catabolism of the isomers D-arabinitol (genes atl or dal) and ribitol (genes rtl or rbt). In these strains gat genes were invariably absent from this location, and they were totally absent in S. enterica. These results strongly indicate that these various gene clusters and metabolic pathways have been subject to convergent evolution among the Enterobacteriaceae. This apparently involved recent horizontal gene transfer and recombination events, as indicated by major chromosomal rearrangements found in their immediate vicinity.

Pathways for the utilization of N-acetyl-galactosamine and galactosamine in Escherichia coli

Among enteric bacteria, the ability to grow on N-acetyl-galactosamine (GalNAc or Aga) and on D-galactosamine (GalN or Gam) differs. Thus, strains B, C and EC3132 of Escherichia coli are Aga+ Gam+ whereas E. coli K-12 is Aga- Gam-, similarly to Klebsiella pneumoniae KAY2026, Klebsiella oxytoca M5a1 and Salmonella typhimurium LT2. The former strains carry a complete aga/kba gene cluster at 70.5 min of their gene map. These genes encode an Aga-specific phosphotransferase system (PTS) or IIAga (agaVWE) and a GalN-specific PTS or IIGam (agaBCD). Both PTSs belong to the mannose-sorbose family, i.e. the IIB, IIC and IID domains are encoded by different genes, and they share a IIA domain (agaF). Furthermore, the genes encode an Aga6P-deacetylase (agaA), a GalN6P deaminase (agaI), a tagatose-bisphosphate aldolase comprising two different peptides (kbaYZ) and a putative isomerase (agaS), i.e. complete pathways for the transport and degradation of both amino sugars. The genes are organized in two adjacent operons (kbaZagaVWEFA and agaS kbaYagaBCDI) and controlled by a repressor AgaR. Its gene agaR is located upstream of kbaZ, and AgaR responds to GalNAc and GalN in the medium. All Aga- Gam- strains, however, carry a deletion covering genes agaW' EF 'A; consequently they lack active IIAga and IIGam PTSs, thus explaining their inability to grow on the two amino sugars. Remnants of a putative recombination site flank the deleted DNA in the various Aga- Gam- enteric bacteria. Derivatives with an Aga+ Gam- phenotype can be isolated from E. coli K-12. These retain the DeltaagaW' EF 'A deletion and carry suppressor mutations in the gat and nag genes for galactitol and N-acetyl-glucosamine metabolism, respectively, that allow growth on Aga but not on GalN.

Transduction-like gene transfer in the methanogen Methanococcus voltae

Strain PS of Methanococcus voltae (a methanogenic, anaerobic archaebacterium) was shown to generate spontaneously 4.4-kbp chromosomal DNA fragments that are fully protected from DNase and that, upon contact with a cell, transform it genetically. This activity, here called VTA (voltae transfer agent), affects all markers tested: three different auxotrophies (histidine, purine, and cobalamin) and resistance to BES (2-bromoethanesulfonate, an inhibitor of methanogenesis). VTA was most effectively prepared by culture filtration. This process disrupted a fraction of the M. voltae cells (which have only an S-layer covering their cytoplasmic membrane). VTA was rapidly inactivated upon storage. VTA particles were present in cultures at concentrations of approximately two per cell. Gene transfer activity varied from a minimum of 2 x 10(-5) (BES resistance) to a maximum of 10(-3) (histidine independence) per donor cell. Very little VTA was found free in culture supernatants. The phenomenon is functionally similar to generalized transduction, but there is no evidence, for the time being, of intrinsically viral (i.e., containing a complete viral genome) particles. Consideration of VTA DNA size makes the existence of such viral particles unlikely. If they exist, they must be relatively few in number;perhaps they differ from VTA particles in size and other properties and thus escaped detection. Digestion of VTA DNA with the AluI restriction enzyme suggests that it is a random sample of the bacterial DNA, except for a 0.9-kbp sequence which is amplified relative to the rest of the bacterial chromosome. A VTA-sized DNA fraction was demonstrated in a few other isolates of M. voltae.

Mutations that extend the specificity of the endonuclease activity of lambda terminase

Terminase, an enzyme encoded by the Nu1 and A genes of bacteriophage lambda, is crucial for packaging concatemeric DNA into virions. cosN, a 22-bp segment, is the site on the virus chromosome where terminase introduces staggered nicks to cut the concatemer to generate unit-length virion chromosomes. Although cosN is rotationally symmetric, mutations in cosN have asymmetric effects. The cosN G2C mutation (a G-to-C change at position 2) in the left half of cosN reduces the phage yield 10-fold, whereas the symmetric mutation cosN C11G, in the right half of cosN, does not affect the burst size. The reduction in phage yield caused by cosN G2C is correlated with a defect in cos cleavage. Three suppressors of the cosN G2C mutation, A-E515G, A-N509K, and A-R504C, have been isolated that restore the yield of lambda cosN G2C to the wild-type level. The suppressors are missense mutations that alter amino acids located near an ATPase domain of gpA. lambda A-E515G, A-N509K, and A-R504C phages, which are cosN+, also had wild-type burst sizes. In vitro cos cleavage experiments on cosN G2C C11G DNA showed that the rate of cleavage for A-E515G terminase is three- to fourfold higher than for wild-type terminase. The A-E515G mutation changes residue 515 of gpA from glutamic acid to glycine. Uncharged polar and hydrophobic residues at position 515 suppressed the growth defect of lambda cosN G2C C11G. In contrast, basic (K, R) and acidic (E, D) residues at position 515 failed to suppress the growth defect of lambda cosN G2C C11G. In a lambda cosN+ background, all amino acids tested at position 515 were functional. These results suggest that A-E515G plays an indirect role in extending the specificity of the endonuclease activity of lambda terminase.

The sigma-70 subunit from Escherichia coli C differs from that of E. coli K-12

The nucleotide sequence of the rpoD gene (encoding the primary sigma-70 (sigma 70) subunit of RNA polymerase) from Escherichia coli C was determined. This gene differs from that of E. coli K-12 by a 30-bp deletion and five single-bp substitutions, resulting in a sigma 70 subunit with three amino acid (aa) changes and a deletion of ten acidic aa.

Mutational analysis of the bacteriophage P2 Ogr protein: truncation of the carboxy terminus

The Ogr protein is a 72-residue, zinc-binding transcription factor essential for activation of late gene expression in bacteriophage P2. Analysis of C-terminal truncated proteins generated by stop codon mutagenesis shows that deletion of residues distal to position 51 had negligible effects on Ogr function. More-extensive deletion resulted in unstable products with severely reduced activity. These results, as well as the effects of other mutations in this region, support the idea that the 21 C-terminal residues are not required for transactivation.

Site-directed mutagenesis of an amino acid residue in the bacteriophage P2 ogr protein implicated in interaction with Escherichia coli RNA polymerase

The P2 ogr gene encodes a 72-amino-acid protein required for P2 late gene expression. This gene was defined originally by a class of compensatory mutations which overcome the block to P2 late transcription imposed by a host mutation, rpoA109, in the gene encoding the alpha subunit of Escherichia coli RNA polymerase. Spontaneous compensatory ogr mutations substitute a Cys for a Tyr residue at amino acid 42 in the Ogr polypeptide. Using suppression of an ogr amber mutation and site-directed oligonucleotide mutagenesis, we have studied the effect of amino acid substitutions at this position in Ogr. Substitution of charged residues at this site renders Ogr protein inactive, in rpoA+ and rpoA109 strains. While 11 different amino acids are capable of replacing the wild-type Tyr-42 to allow P2 growth to varying degrees in a wild-type E. coli strain, only three of these allow phage growth in strains carrying the rpoA109 mutation. Phages carrying Cys or Ala in place of Tyr-42 gave burst sizes at least as high as P2 ogr+ in a rpoA+ strain; a Gly substitution also allowed P2 to grow in either a rpoA+ or rpoA109 background, but markedly reduced the burst size. These results are consistent with a direct interaction between Ogr and the alpha subunit of E. coli RNA polymerase in positive control of P2 late transcription, and indicate that the block imposed by the rpoA109 mutation is due to steric hindrance.

Cloning and transposon vectors derived from satellite bacteriophage P4 for genetic manipulation of Pseudomonas and other gram-negative bacteria

We developed transposon and cloning shuttle vectors for genetic manipulation of Pseudomonas and other gram-negative bacteria, exploiting the unique properties and the broad host range of the satellite bacteriophage P4. P4::Tn5 AP-1 and P4::Tn5 AP-2 are suicide transposon vectors which have been used for efficient Tn5 mutagenesis in Pseudomonas putida. pKGB2 is a phasmid vector with a cloning capacity of about 7.5 kb; useful unique cloning sites are SacI and SacII in the streptomycin resistance determinant and PvuI and XhoI in the kanamycin resistance determinant. pKGB4 is a cosmid derived from pKGB2 and carries the additional cloning site SmaI in the kanamycin resistance determinant; its cloning capacity is about 18 kb. These vectors and their recombined derivatives were transferred from Escherichia coli to P. putida by transduction and may be used for other bacterial species susceptible to P4 infection.

Attachment sites for bacteriophage P2 on the Escherichia coli chromosome: DNA sequences, localization on the physical map, and detection of a P2-like remnant in E. coli K-12 derivatives

Integration of bacteriophage P2 into the Escherichia coli genome involves recombination between two attachment sites, attP and attB, one on the phage and one on the host genome, respectively. At least 10 different attB sites have been identified over the years. In E. coli C, one site, called locI, is preferred, being occupied before any of the others. In E. coli K-12, no such preference is seen (reviewed in L. E. Bertani and E. W. Six, p. 73-143, in R. Calendar, ed., The Bacteriophages, vol. 2, 1988). The DNA sequence of locI has been determined, and it shows a core sequence of 27 nucleotides identical to attP (A. Yu, L. E. Bertani, and E. Haggård-Ljungquist, Gene 80:1-12, 1989). By inverse polymerase chain reactions, the prophage-host junctions of DNA extracted from P2 lysogenic strains have been amplified, cloned, and sequenced. By combining the attL and attR sequences, the attB sequences of locations II, III, and H have been deduced. The core sequence of location II had 20 matches to the 27-nucleotide core sequence of attP; the sequences of locations III and H had 17 matches. Thus, the P2 integrase accepts at least up to 37% mismatches within the core sequence. The E. coli K-12 strains examined all contain a 639-nucleotide-long cryptic remnant of P2 at a site with a sequence similar to that of locI but that may have a different map position. The P2 remnant consists of the C-terminal part of gene D, all of gene ogr, and attR. Locations II, III, and H have been located on Kohara's physical map to positions 3670, 1570 to 1575, and 2085, respectively.

Escherichia coli K-12 and B contain functional bacteriophage P2 ogr genes

The bacteriophage P2 ogr gene encodes an essential 72-amino-acid protein which acts as a positive regulator of P2 late transcription. A P2 ogr deletion phage, which depends on the supply of Ogr protein in trans for lytic growth on Escherichia coli C, has previously been constructed. E. coli B and K-12 were found to support the growth of the ogr-defective P2 phage because of the presence of functional ogr genes located in cryptic P2-like prophages in these strains. The cryptic ogr genes were cloned and sequenced. Compared with the P2 wild-type ogr gene, the ogr genes in the B and K-12 strains are conserved, containing mostly silent base substitutions. One of the base substitutions in the K-12 ogr gene results in replacement of an alanine with valine at position 57 in the Ogr protein but does not seem to affect the function of Ogr as a transcriptional activator. The cryptic ogr genes are constitutively transcribed, apparently at a higher level than the wild-type ogr gene in a P2 lysogen.

Nucleotide sequence of the DNA packaging and capsid synthesis genes of bacteriophage P2

Overlapping DNA fragments containing the DNA packaging and capsid synthesis gene region of bacteriophage P2 were cloned and sequenced. In this report we present the complete nucleotide sequence of this 6550 bp region. Each of six open reading frames found in the interval was assigned to one of the essential genes (Q, P, O, N, M and L) by correlating genetic, physical and mutational data with DNA and protein sequence information. Polypeptides predicted were: a capsid completion protein, gpL; the major capsid precursor, gpN; the presumed capsid scaffolding protein; gpO; the ATPase and proposed endonuclease subunits of terminase, gpP and gpM, respectively; and a candidate for the portal protein, gpQ. These gene and protein sequences exhibited no homology to analogous genes or proteins of other bacteriophages. Expression of gene Q in E. coli from a plasmid caused production of a Mr 39,000 Da protein that restored Qam34 growth. This sequence analysis found only genes previously known from analysis of conditional-lethal mutations. No new capsid genes were found.

Identification and characterization of a gene responsible for inhibiting propagation of methylated DNA sequences in mcrA mcrB1 Escherichia coli strains

Identifying and eliminating endogenous bacterial enzyme systems can significantly increase the efficiency of propagation of eukaryotic DNA in Escherichia coli. We have recently examined one such system which inhibits the propagation of lambda DNA rescued from transgenic mouse tissues. This rescue procedure utilizes lambda packaging extracts for excision of the lambda DNA from the transgenic mouse genome, as well as E. coli cells for subsequent infection and propagation. This assay, in combination with conjugal mating, P1 transduction, and gene cloning, was used to identify and characterize the E. coli locus responsible for this difference in efficiency. It was determined that the E. coli K-12 mcrB gene when expressed on a high-copy-number plasmid can cause a decrease in rescue efficiency despite the presence of the mcrB1 mutation, which inactivates the classic McrB restriction activity. (This mutation was verified by sequence analysis.) However, this McrB1 activity is not observed when the cloned mcrB1 gene is inserted into the E. coli genome at one copy per chromosome. A second locus was identified which causes a decrease in rescue efficiency both when expressed on a high-copy-number plasmid and when inserted into the genome. The data presented here suggest that this locus is mrr and that the mrr gene product can recognize and restrict cytosine-methylated sequences. Removal of this DNA region including the mrr gene from E. coli K-12 strains allows high rescue efficiencies equal to those of E. coli C strains. These modified E. coli K-12 plating strains and lambda packaging extract strains should also allow a significant improvement in the efficiency and representation of eukaryotic genomic and cDNA libraries.

Nucleotide sequence of the genes encoding the major tail sheath and tail tube proteins of bacteriophage P2

The major structural components of the contractile tail of bacteriophage P2 are proteins FI and FII, which are believed to be the tail sheath and tube proteins, respectively. Both proteins were mapped previously to the P2 late gene F, based on the pattern of protein synthesis in various P2 amber mutants. In order to clarify the gene arrangement and to provide a basis for structural comparisons with other contractile phage tails, we have determined the nucleotide sequence of the region of the P2 genome encoding these two proteins. The coding regions were confirmed by location of the Fam4 mutation and by N-terminal amino acid sequencing of both proteins. The molecular weight and amino acid composition predicted by each of the coding regions correspond well to those determined experimentally for each protein. FII is encoded by a newly identified P2 late gene. These proteins bear little resemblance to their functional homologues in bacteriophage T4.

Bacteriophage P2 ogr and P4 delta genes act independently and are essential for P4 multiplication

Satellite bacteriophage P4 requires the products of the late genes of a helper phage such as P2 for lytic growth. Expression of the P2 late genes is positively regulated by the P2 ogr gene in a process requiring P2 DNA replication. Transactivation of P2 late gene expression by P4 requires the P4 delta gene product and works even in the absence of P2 DNA replication. We have made null mutants of the P2 ogr and P4 delta genes. In the absence of the P4 delta gene product, P4 multiplication required both the P2 ogr protein and P2 DNA replication. In the absence of the P2 ogr gene product, P4 multiplication required the P4 delta protein. In complementation experiments, we found that the P2 ogr protein was made in the absence of P2 DNA replication but could not function unless P2 DNA replicated. We produced P4 delta protein from a plasmid and found that it complemented the null P4 delta and P2 ogr mutants.

Nonessential region of bacteriophage P4: DNA sequence, transcription, gene products, and functions

We sequenced the leftmost 2,640 base pairs of bacteriophage P4 DNA, thus completing the sequence of the 11,627-base-pair P4 genome. The newly sequenced region encodes three nonessential genes, which are called gop, beta, and cII (in order, from left to right). The gop gene product kills Escherichia coli when the beta protein is absent; the gop and beta genes are transcribed rightward from the same promoter. The cII gene is transcribed leftward to a rho-independent terminator. Mutation of this terminator creates a temperature-sensitive phenotype, presumably owing to a defect in expression of the beta gene.

Directed mutagenesis of the bacteriophage P2 ogr gene defines an essential function

The ogr gene of bacteriophage P2 codes for a basic protein of 72 amino acids which is thought to be essential for activation of P2 late gene transcription. However, conditionally lethal mutations in the ogr gene have never been isolated. We have constructed a P2 ogr deletion mutant by in vitro techniques. This deletion phage, P2-del15, grows in a host which provides the ogr gene product in trans from a plasmid but fails to grow in hosts lacking the ogr plasmid. This demonstrates that the ogr gene is essential for P2 lytic growth. The deletion in P2del15 has removed about half of the carboxy-terminal part of the ogr gene. The transcript from this deletion mutant can be distinguished from the wild-type transcript by S1 nuclease protection. The analysis of such transcripts suggests that the ogr gene product may negatively regulate its own transcription.

sub, a host mutation that specifically allows growth of replication-deficient gene B mutants of coliphage P2

Bacteriophage P2 normally requires the products of its early genes A and B for lytic growth in its host, Escherichia coli C. A host mutation, sub-1, which allows P2 to grow without a functional B gene product is described. The sub-1 mutation is recessive and maps at approximately 10 min on the E. coli genetic map.

Regulation of bacteriophage P2 late-gene expression: the ogr gene

The ogr gene product of bacteriophage P2 is a positive regulatory factor required for P2 late-gene transcription. We have determined the nucleotide sequence of the ogr gene, which encodes a basic polypeptide of 72 amino acids. P2 growth is blocked by a host mutation, rpoA109, in the alpha subunit of DNA-dependent RNA polymerase. The ogr52 mutation, which allows P2 to grow in an rpoA109 strain, was shown to be a single nucleotide change, in the codon for residue 42, that changes tyrosine to cysteine. The predicted amino acid sequence of the Ogr protein does not show similarity to DNA-binding proteins that are known to affect promoter recognition, to sigma factors, or to other characterized transcriptional regulatory proteins. We have inserted the ogr gene into a plasmid under control of the leftward promoter and operator of bacteriophage lambda. Thermal induction of ogr gene expression in this plasmid results in overproduction of a small protein that has been shown by complementation to possess Ogr function.

Knotting of DNA molecules isolated from deletion mutants of intact bacteriophage P4

DNA molecules isolated from tailless phage particles (capsids) of bacteriophage P4 virl del10 are known to be knotted. We have found by electron microscopy that 80% of DNA molecules isolated from intact phage particles of P4 virl del10 also contained knots. This observation indicates that the predominant form of P4 virl del10 DNA within the intact phage particle is either knotted or in a configuration that permits knotting upon isolation. In comparison to P4 virl del10 (deleted 1000 basepairs), DNA molecules isolated from intact P4 virl del2 (deleted 650 basepairs) and P4 virl (non-deleted) contained 50% and 15% knots respectively, showing an association of decreased size of deletion of DNA with a decreased fraction of knotted genomes.

Bacteriophage P2 late promoters. II. Comparison of the four late promoter sequences

The late genes of bacteriophage P2 are clustered into four transcription units. We have reported the transcription initiation sites for two of the late messenger RNAs, encoding genes QP and ONMLKRS. We have now located the 5' ends of the two remaining late mRNAs. The first gene in the VJHG transcription unit has been located by DNA sequence determination of the single nucleotide change in a V amber mutant. Location of the first gene in the FETUD transcription unit has been inferred from the DNA sequence. The 5' ends of the mRNAs for these two transcription units were located by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with nuclease S1. Similar protection of hybrids using RNA that had been 5' end-labeled with [alpha-32P]GTP and guanylyl transferase confirmed that these 5' termini resulted from initiation of transcription. The DNA sequences preceding the P2 late transcription starts are different from the Escherichia coli promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The four P2 late promoters do share sequence homologies in the -10 and -35 regions, however, and several additional homologies further upstream. P2 late gene expression also appears to involve negative regulation by a product of the ONMLKRS gene cluster. When cells are infected with P2 polar O amber mutants, a marked increase in the levels of proteins encoded by the other three gene clusters is observed. This increase is reflected in the amounts of late mRNAs, suggesting that RNA synthesis is normally repressed or that late mRNAs are more labile in the presence of a gene product from the ONMLKRS transcription unit. Satellite phage P4 induced P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 late mRNAs are the same during P4 transactivation as during normal P2 late gene expression. Thus, the regulation of P2 late gene expression by P4 does not involve altered promoter selection.

An Escherichia coli gene required for bacteriophage P2-lambda interference

The gene old of bacteriophage P2 is known to (i) cause interference with phage lambda growth; (ii) kill recB- mutants of Escherichia coli after P2 infection; and (iii) determine increased sensitivity of P2 lysogenic cells to X-ray irradiation. In all of these phenomena, inhibition of protein synthesis occurs. We have isolated bacterial mutants, named pin (P2 interference), able to suppress all of the above-mentioned phenomena caused by the old+ gene product and the concurrent protein synthesis inhibition. Pin mutations are recessive, map at 12 min on the E. coli map, and identify a new gene. Satellite bacteriophage P4 does not plate on pin-3 mutant strains and causes cell lethality and protein synthesis inhibition in such mutants. P4 mutants able to grow on pin-3 strains have been isolated.

Properties and products of the cloned int gene of bacteriophage P2

Fragments of DNA of the temperate phage P2, generated by treatment with the restriction enzyme PstI, have been cloned into the plasmid pBR322. One such fragment, which has its endpoints within phage genes T and C, carries the structural P2 int gene as well as its promoter and the phage att site. When introduced into a suitable bacterial host, the cloned fragment mediates the integration and excision of int- mutants of P2 and recombination within the phage att site in mixed infection. All these activities are independent of the orientation of the fragment within the plasmid. When introduced into minicells, the fragment produces, in addition to the products of genes D and U, a protein of 35-37,000 daltons identified as the int protein. A study of the map location of two amber int mutants, together with the sizes of the polypeptides they produce, indicates that the P2 int gene is transcribed from right to left on the P2 map, i.e. starting near gene C and proceeding toward att.

Bacteriophage P2 late promoters. Transcription initiation sites for two late mRNAs

Divergent transcription of two of the bacteriophage P2 late mRNAs, encoding genes QP and ONMLKRS, is initiated from opposite strands of the DNA in a region near the left end of the P2 genome. The first gene in each of these transcription units (P and O) has been located in the nucleotide sequence by amino-terminal sequence analysis of the P gene product and by DNA sequence determination of the single nucleotide changes in two O amber mutants. The 5' ends of the P and O gene mRNAs are separated by 109 nucleotide pairs in the DNA template. The locations of these 5' termini were determined by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with nuclease S1. Sequence analysis of mRNA that had been labeled at the 5' end with [alpha-32P]GTP and guanylyl transferase confirmed that these termini resulted from initiation of transcription. The DNA sequences preceding the O and P transcription starts have poor homologies to the bacterial promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The O and P promoter regions also have no detectable homology to each other in the -10 or -35 regions, and are unusually G + C-rich. There are, however, blocks of sequence homology within the transcribed region of each of these two late operons near the 5' end. Satellite phage P4 induces P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 P and O gene transcripts are the same during P4 "transactivation" as during normal P2 late gene expression. Thus the regulation of P2 late gene expression by P4 does not involve a change in the site for initiation of transcription.

Circular genetic map of satellite bacteriophage P4

A genetic map of satellite bacteriophage P4 has been constructed by means of standard multifactor crosses. The genetic map appears to be a circular permutation of the mature DNA physical map. In addition, a set of markers appear to be linked both to the left and to the right of the same gene alpha. These facts suggest that the P4 genetic map is circular. Since terminal redundancy and/or cyclic permutation are not known to be present in P4 mature DNA, the circularity of P4 genetic map may reflect the physical circularity of the molecules involved in the recombination process. The low frequency of recombination and the strong negative interference observed are in agreement with the above hypothesis.

Propagation of satellite phage P4 as a plasmid

Satellite phage P4 has two known options for propagation. In its lytic cycle, its regulatory functions can act in trans to alter the actions of a helper virus (P2), which then provides necessary gene products, including capsid proteins. P4 also can be propagated in the absence of a helper as a prophage, with distinct sites for integration within the Escherichia coli chromosome. We determined that a single spontaneous mutation (vir1) of phage P4 allows a third mode of propagation: as a plasmid (along with continued integration into the host chromosome). Hence, the P4 regulatory element is capable of (i) temperate; (ii) lytic, helper-dependent; and (iii) plasmid modes of development. These findings emphasize the close relationship between defective viruses and plasmids.

Plasmids coding for enterotoxins, K88 antigen and colicins in porcine Escherichia coli strains of O-group 149

This study was carried out to determine whether the strong epidemiological correlation observed in Sweden between production of the adhesin K88, the heat-stable (ST) and the heat-labile (LT) enterotoxins in E. coli strains of O-group 149 isolated from piglet diarrhea might be explained by linkage of their genetic determinants. From 22 different isolates plasmids coding for these virulence factors were investigated by conjugation and transduction experiments and analysis on agarose gels. The genes coding for ST production could be transferred by selection for antibiotic resistance, but behaved as transposable elements most often residing on a 55 Mdal plasmid coding for colicin B. The genes coding for raffinose fermentation and K88 antigen production were located on a 45 Mdal plasmid and the genes coding for LT production on plasmids within the 45-70 Mdal size. Thus the epidemiological importance and spread of this O-group in Sweden was explained by its stable content of two or three virulence plasmids, which could be transferred independently of one another.

Coliphage 186 Replication is delayed when the host cell is UV irradiated before infection

In contrast to results with injections by lambda and P2, the latent period for infection by coliphage 186 is extended when the host cell is UV irradiated before infection. We find that 186 replication is significantly delayed in such a cell, even though the phage itself has not been irradiated. In contrast, replication of the closely related phage P2 under the same conditions is not affected.

Identification of the E. coli dnaJ gene product

We have previously shown that a mutation (groPC259) in the E. coli dnaJ gene renders the cell inviable at high temperatures and arrests bacteriophage lambda DNA replication at all temperatures (Sunshine et al., 1977). We have isolated lambda dnaJ+ transducing phages both by in vitro cloning and by abnormal excision of a lambda dnaK transducing phage integrated near the dnaJ locus. The dnaJ gene product has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells by lambda dnaJ+ derivative phages. It is a polypeptide chain with an apparent molecular weight of 37,000-daltons. This has been verified by the fact that a transducing phage carrying an amber mutation in the dnaJ gene fails to induce the synthesis of the 37,000-dalton polypeptide chain upon infection of sup+ bacteria, but does so upon infection of supF or supD bacteria.

Recombination in bacteriophage P2: recA dependent enhancement by ultraviolet irradiation and by transfection with mixed DNA dimers

Bacteriophage P2 is known for its exceptionally low rate of spontaneous (non-integrative) recombination, which however may be stimulated by ultraviolet irradiation of the phage. We show here that ligated dimers, made in vitro from mixtures of DNAs of two P2 mutants, upon transfection of lysozyme-spheroplasts give origin to recombinants at high frequency. While spontaneous P2 recombination occurs independently of the main recombination pathway of the bacteria, P2 recombinant formation following either ultraviolet irradiation or transfection with DNA dimers requires at least some element of such a pathway, since it is absent or greatly reduced in recA- bacteria or spheroplasts. It would seen that, in the course of its lytic development, P2 deploys a mechanism that inhibits the main recombination pathway of the host cell, or assumes DNA configurations refractory to it.

Cloning of the immunity repressor determinant of bacteriophage P2 in the pBR322 plasmid

Through in vitro recombination of DNA restriction fragments, we have constructed a plasmid, which expressed in vivo the immunity repressor gene (C) of bacteriophage P2. A bacterial strain carrying such a plasmid showed a high level of P2 specific immunity. It was lysogenized normally by an infecting P2, but the frequency of spontaneous phage production was reduced about 10(4) fold as compared to a normal P2 lysogen. Satellite phage P4, known to derepress P2 lysogens, was unable to derepress the plasmid-carrying lysogenic strain so to allow growth of coinfecting P2. Phage P4 multiplied on the plasmid-carrying, P2-lysogenic strain, but due to a prolonged latent period failed to form plaques on this strain.

Small arrays of electron-dense cylinders in Escherichia coli cells

Electron microscopy of unstained Escherichia coli cells from cultures kept near 0 degrees C after incubation at 37 degrees C revealed small areas of geometrically arranged electron-dense cylinders. Their morphology, organization, and occurrence are described.

X-ray sensitivity of Escherichia coli lysogenic for bacteriophage P2

Strains of Escherichia coli C or K lysogenic for the non-inducible phage P2 show a lower survival following X-ray irradiation as compared to nonlysogenic strains. This difference in X-ray sensitivity is not accompanied by a significant difference in X-ray induced mutability. The capacity of X-irradiated P2 lysogens to multiply any of a number of unirradiated infecting phages is severely impaired. These effects of X-ray treatment can be most simply explained as a consequence of the fact that protein and RNA syntheses are strongly inhibited in P2 lysogens after X-irradiation. All the above events specifically occurring in X-rayed P2 lysogens are dependent on the P2 gene old.

Characterization of mutationally altered dihydropteroate synthase and its ability to form a sulfonamide-containing dihydrofolate analog

Among spontaneous mutants of Escherichia coli selected for resistance against sulfonamides, thermosensitive strains were found. These were shown to possess a changed dihydropteroate synthase (EC 2.5.1.15), which had a substantially higher Km value for its normal substrate, p-aminobenzoic acid, and an about 150-fold higher Km for sulfonamides. The mutationally changed dihydropteroate synthase was found to be thermosensitive by in vitro assays. The thermosensitivity was used as an enzyme marker to demonstrate the complex formation between 2-amino-4-hydroxy-6-pyrophosphorylmethyl pteridine and sulfonamides by partially purified dihydropteroate synthase. The formation of folate from 2-amino-4-hydroxy-6-pyrophosphorylmethyl pteridine and p-aminobenzoylglutamic acid by dihydropteroate synthase was found to be very sensitive to inhibition by sulfonamides and very inefficient with the mutationally changed enzyme.