Bacteriophage Mu-1: a tool to transpose and to localize bacterial genes

Cupriavidus metallidurans CH34, a historical perspective on its discovery, characterization and metal resistance

Cupriavidus metallidurans, and in particular type strain CH34, became a model bacterium to study bacterial resistance to metals. Although nowadays the routine use of a wide variety of omics and molecular techniques allow refining, deepening and expanding our knowledge on adaptation and resistance to metals, these were not available at the onset of C. metallidurans research starting from its isolation in 1976. This minireview describes the early research and legacy tools used to study its metal resistance determinants, characteristic megaplasmids, ecological niches and environmental applications.

Characterization and Genome Analysis of a Novel Mu-like Phage VW-6B Isolated from the Napahai Plateau Wetland of China

Although bacteriophages are more numerous and have smaller genomes than their bacterial hosts, relatively few have their genomes sequenced. Here, we isolated the Pseudomonas fluorescens bacteriophage from Napahai plateau wetland and performed de novo genome sequencing. Based on the previous biological characteristics and bioinformatics analysis, it was determined that VW-6B was a linear double-stranded DNA (dsDNA) phage with 35,306 bp, with 56.76% G+C content and 197 bp tandem repeats. The VW-6B genome contained 46 open-reading frames (ORFs), and no tRNA genes were found. Based on phage genome structure, sequence comparison, and collinear analysis, VW-6B should be classified into the family Siphoviridae and be considered as a member of a new species in the Mu-like phage. The newly isolated bacteriophage can specifically infect P. fluorescens, which further enriches the diversity of known bacteriophages and provides a basis for the subsequent research and application of bacteriophages.

Use of RP4::Mini-Mu for Gene Transfer

Gene cloning is an invaluable technique in genetic analysis and exploitation of genetic properties of a broad range of bacteria. Numerous in vitro molecular cloning protocols have been devised but the efficiency of these techniques relies on the frequency with which the recombinant DNA can be introduced in the recipient strain. Here, we describe an in vivo gene transfer and cloning technique based on transposable bacteriophage Mu property to rearrange its host genome. This technique uses the broad host range plasmid RP4 carrying a transposable mini-MuA⁺ derivative and was successfully used as well in enteric as in environmental nonenteric bacteria.

Identification and Molecular Characterisation of a Novel Mu-Like Bacteriophage, SfMu, of Shigella flexneri

S. flexneri is the leading cause of bacillary dysentery in the developing countries. Several temperate phages originating from this host have been characterised. However, all S. flexneri phages known to date are lambdoid phages, which have the ability to confer the O-antigen modification of their host. In this study, we report the isolation and characterisation of a novel Mu-like phage from a serotype 4a strain of S. flexneri. The genome of phage SfMu is composed of 37,146 bp and is predicted to contain 55 open reading frames (orfs). Comparative genome analysis of phage SfMu with Mu and other Mu-like phages revealed that SfMu is closely related to phage Mu, sharing >90% identity with majority of its proteins. Moreover, investigation of phage SfMu receptor on the surface of the host cell revealed that the O-antigen of the host serves as the receptor for the adsorption of phage SfMu. This study also demonstrates pervasiveness of SfMu phage in S. flexneri, by identifying complete SfMu prophage strains of serotype X and Y, and remnants of SfMu in strains belonging to 4 other serotypes, thereby indicating that transposable phages in S. flexneri are not uncommon. The findings of this study contribute an advance in our current knowledge of S. flexneri phages and will also play a key role in understanding the evolution of S. flexneri.

Letting Escherichia coli teach me about genome engineering

A career of following unplanned observations has serendipitously led to a deep appreciation of the capacity that bacterial cells have for restructuring their genomes in a biologically responsive manner. Routine characterization of spontaneous mutations in the gal operon guided the discovery that bacteria transpose DNA segments into new genome sites. A failed project to fuse lambda sequences to a lacZ reporter ultimately made it possible to demonstrate how readily Escherichia coli generated rearrangements necessary for in vivo cloning of chromosomal fragments into phage genomes. Thinking about the molecular mechanism of IS1 and phage Mu transposition unexpectedly clarified how transposable elements mediate large-scale rearrangements of the bacterial genome. Following up on lab lore about long delays needed to obtain Mu-mediated lacZ protein fusions revealed a striking connection between physiological stress and activation of DNA rearrangement functions. Examining the fate of Mudlac DNA in sectored colonies showed that these same functions are subject to developmental control, like controlling elements in maize. All these experiences confirmed Barbara McClintock's view that cells frequently respond to stimuli by restructuring their genomes and provided novel insights into the natural genetic engineering processes involved in evolution.

Microarray analysis of transposition targets in Escherichia coli: the impact of transcription

Transposable elements have influenced the genetic and physical composition of all modern organisms. Defining how different transposons select target sites is critical for understanding the biochemical mechanism of this type of recombination and the impact of mobile genes on chromosome structure and function. Phage Mu replicates in Gram-negative bacteria using an extremely efficient transposition reaction. Replicated copies are excised from the chromosome and packaged into virus particles. Each viral genome plus several hundred base pairs of host DNA covalently attached to the prophage right end is packed into a virion. To study Mu transposition preferences, we used DNA microarray technology to measure the abundance of >4,000 Escherichia coli genes in purified Mu phage DNA. Insertion hot- and cold-spot genes were found throughout the genome, reflecting >1,000-fold variation in utilization frequency. A moderate preference was observed for genes near the origin compared to terminus of replication. Large biases were found at hot and cold spots, which often include several consecutive genes. Efficient transcription of genes had a strong negative influence on transposition. Our results indicate that local chromosome structure is more important than DNA sequence in determining Mu target-site selection.

Bacteriophage Mu genome sequence: analysis and comparison with Mu-like prophages in Haemophilus, Neisseria and Deinococcus

We report the complete 36,717 bp genome sequence of bacteriophage Mu and provide an analysis of the sequence, both with regard to the new genes and other genetic features revealed by the sequence itself and by a comparison to eight complete or nearly complete Mu-like prophage genomes found in the genomes of a diverse group of bacteria. The comparative studies confirm that members of the Mu-related family of phage genomes are genetically mosaic with respect to each other, as seen in other groups of phages such as the phage lambda-related group of phages of enteric hosts and the phage L5-related group of mycobacteriophages. Mu also possesses segments of similarity, typically gene-sized, to genomes of otherwise non-Mu-like phages. The comparisons show that some well-known features of the Mu genome, including the invertible segment encoding tail fiber sequences, are not present in most members of the Mu genome sequence family examined here, suggesting that their presence may be relatively volatile over evolutionary time. The head and tail-encoding structural genes of Mu have only very weak similarity to the corresponding genes of other well-studied phage types. However, these weak similarities, and in some cases biochemical data, can be used to establish tentative functional assignments for 12 of the head and tail genes. These assignments are strongly supported by the fact that the order of gene functions assigned in this way conforms to the strongly conserved order of head and tail genes established in a wide variety of other phages. We show that the Mu head assembly scaffolding protein is encoded by a gene nested in-frame within the C-terminal half of another gene that encodes the putative head maturation protease. This is reminiscent of the arrangement established for phage lambda.

A phasmid shuttle vector for the cloning of complex operons in Salmonella

Phasmid (phage plasmid hybrid) P4 vir1 can be propagated in Escherichia coli as a helper-dependent lytic phage, as a plasmid, or as a prophage. On the basis of an understanding of these modes of propagation, derivatives of P4 have been constructed for use as cloning vectors. In this report we demonstrate that phasmid P4 (i) will propagate as a helper-dependent lytic phage and as a plasmid in Salmonella spp. and (ii) can be used as a high efficiency phage shuttle vector for the reversible transfer of cloned genes between Salmonella spp. and E. coli. For both E. coli and Salmonella spp., P4 phage-mediated gene transfer proved to be only 10-fold lower than plaquing efficiency. For the case of Salmonella spp., this frequency is ca. 10(4)-fold more efficient than is typically found for the transformation of DNA molecules. The usefulness of this cloning vector system for analyses of pathogenic virulence factors is demonstrated by the cloning and expression of both the P pilus adhesin operon and the hemolysin operon of uropathogenic E. coli.

Efficient cloning of a mutant adenylate-kinase-encoding gene from Escherichia coli

An optimized system has been developed for the transfer of a mutant gene from the Escherichia coli chromosome to a plasmid carrying the wild type (wt) allele. The wt allele was first cloned into a low-copy-number, self-transmissible plasmid with a single EcoRI, HindIII, and BamHI site. The plasmid was then transferred to a mutant strain that had been previously transformed with a high-copy-number plasmid carrying the recA+ gene to allow efficient homologous recombination. A 15% frequency of homogenotization was obtained during cloning of an adk gene that encodes a temperature-sensitive adenylate kinase (AK). The mutant AK had decreased mobility on sodium dodecyl sulfate-polyacrylamide gels compared with the wt enzyme. This was due to a point mutation that changed leucine-107 in the wt enzyme to glutamine-107 in the mutant enzyme as determined by nucleotide sequencing.

Introduction of Shigella flexneri 2a type and group antigen genes into oral typhoid vaccine strain Salmonella typhi Ty21a

For protection against dysentery caused by Shigella flexneri 2a, an in vivo-constructed recombinant plasmid with genes specifying the S. flexneri type and group antigens located near the pro (min 6) and his (min 44) chromosomal markers, respectively, was made and transferred to the galE Salmonella typhi strain Ty21a. Strain Ty21a carrying this recombinant plasmid was shown by immunological and biochemical analyses to express the S. flexneri 2a type and group antigens. Mice immunized with this vaccine strain were found to be protected against challenge with virulent S. flexneri 2a, but not significantly against S. typhi challenge, presumably because synthesis of the Shigella antigens interfered with expression of the typhoid antigens. Elimination of the recombinant plasmid from Ty21a allowed this strain to again express typical S. typhi O antigens. Mouse protection against both S. typhi and S. flexneri 2a challenges was achieved with a whole-cell vaccine mixture composed of equal parts of Ty21a and the Ty21a-S. flexneri 2a hybrid strain.

Mini-Mu transposition of bacterial genes on the transmissible plasmid

Using the pRM30 plasmid, an Aps deletion derivative of broad host range plasmid RP4 with integrated new miniMu 5 (11 kb), we followed the transfer of Escherichia coli chromosomal genes to the recipient strain. The miniMu 5-mediated transposition of chromosomal genes occurs onto the plasmid with integrated miniMu 5 rather than onto the "recipient" plasmid pNH602. The plasmid DNA in recipient cells was detected by electrophoresis. One of the acquired hybrid plasmids pTB2 was analyzed genetically and by restriction endodeoxyribonuclease digestion. A structure consisting of miniMu-chromosomal segment-miniMu as a product of Mu-mediated transposition was detected.

Cloning of genes from members of the family Enterobacteriaceae with mini-Mu bacteriophage containing plasmid replicons

An in vivo cloning system that uses derivatives of the Escherichia coli bacteriophage Mu with plasmid replicons has been extended to five different species of the family Enterobacteriaceae. Mu and these mini-Mu replicon elements were introduced into strains of E. coli, Shigella flexneri, Salmonella typhimurium, Citrobacter freundii, and Proteus mirabilis by infection, by transformation, or by conjugation with newly constructed broad-host-range plasmids containing insertions of these elements. Lysates from these cells, lysogenic for Mu and mini-Mu elements, were used to infect sensitive recipient strains of E. coli, S. typhimurium, and C. freundii. Drug-resistant transductants had mini-Mu replicon elements with inserts of different DNA sequences. All of the lysogens made could be induced to yield high phage titers, including those coming from strains that were resistant to Mu and Mu derivatives. Clones of 10 particular genes were isolated by their ability to complement specific mutations in the recipient strains, even in the presence of the E. coli K-12 restriction system. Some of the mini-Mu replicon elements used contained lac gene fusing segments and resulted in fusions of the lac operon to control regions in the cloned sequences.

In vivo cloning of DNA into multicopy cosmids by mini-Mu-cosduction

A general in vivo procedure for cloning Escherichia coli genes into cosmids has been developed. The method we describe here uses a deleted Mu phage (a mini-Mu) to transpose E. coli genes into cosmids during mini-Mu replication. The resulting cosmids clones are packaged in vivo into lambda phage particles. Plasmids carrying a particular DNA sequence can be selectively recovered after infection of a new host with the in vivo constructed genomic cosmid library. This system was used successfully to clone several E. coli genes.

Mini-mu bacteriophage with plasmid replicons for in vivo cloning and lac gene fusing

New mini-Mu transposons with plasmid replicons were constructed with additional features for in vivo DNA cloning and lac gene fusing in Escherichia coli. These mini-Mu replicons can be used to clone DNA by growing them with a complementing Mu bacteriophage and by using the resulting lysate to transduce Mu-lysogenic cells. These mini-Mu phage have selectable genes for resistance to kanamycin, chloramphenicol, and spectinomycin-streptomycin, and replicons from the high-copy-number plasmids pMB1 and P15A and the low-copy, broad-host-range plasmid pSa. The most efficient of these elements can be used to clone genes 100 times more frequently than with the previously described mini-Mu replicon Mu dII4042, such that complete gene banks can be made with as little as 1 microliter of a lysate containing 10(6) helper phage. The 39-kilobase-pair Mu headful DNA packaging mechanism limits the size of the clones formed. The smallest of the mini-Mu elements is only 7.9 kilobase pairs long, allowing the cloning of DNA fragments of up to 31.1 kilobase pairs, and the largest of them is 21.7 kilobase pairs, requiring that clones carry insertions of less than 17.3 kilobase pairs. Elements have been constructed to form both transcriptional and translational types of lac gene fusions to promoters present in the cloned fragment. Two of these elements also contain the origin-of-transfer sequence oriT from the plasmid RK2, so that clones obtained with these mini-Mu bacteriophage can be efficiently mobilized by conjugation.

Anomalous expression of the E. coli lac operon in Proteus mirabilis. I. Effects of L8 and L8 UV5

The lac operon shows anomalous expression in Proteus mirabilis: the maximal induced level is 10% or less of that in E. coli, while repression reduces this by a factor of only 2-5. We have sought to determine whether this effect relates in any way to CRP-mediated activation of expression, by comparing expression in P. mirabilis of lac operons (introduced for technical reasons on IncP1 plasmids) either regulatorily wild-type or bearing L8 or L8UV5. Derivatives of RP1 bearing L8UV5 were obtained by homogenotisation of pGC9114 (RP1::Tn951) in a L8UV5 background; while derivatives of RP4 bearing lac+, L8 or L8UV5 were obtained by Mu-mediated translocation of chromosomal regions bearing these alleles, following partial heat-induction of Mucts62 on pGM14 (RP4::Mucts62) in the appropriate hosts. These plasmids could be readily transferred to, and stably maintained in, the P. mirabilis strains employed. It was found that L8 reduced the maximal level of beta-galactosidase activity, and L8UV5 restored this activity to around wild-type, in P. mirabilis quantitatively very much as in E. coli. Nevertheless, the low maximal level of expression and high basal level characteristic of the former host were unchanged. The simplest explanation of these results is that P. mirabilis contains a protein that mimics the E. coli CRP protein in interacting with the appropriate DNA binding site and thereby stimulating transcription; and that the anomalous regulation of lac in this host is unconnected with the CRP system.

Ty1-promoted expression of aspartate transcarbamylase in the yeast Saccharomyces cerevisiae

An entire copy of a Ty1 yeast transposon has been found inserted between two regions comprising the single transcriptional and translational URA2 units in yeast that code respectively for carbamylphosphate synthetase (CPSase) and aspartate transcarbamylase (ATCase). The mutant Rev 16 was obtained from an ATCase- strain blocked by multiple nonsense mutations in the proximal CPSase region and submitted to selective pressure for recovery of the enzyme activity coded by the distal part of the gene. The inserted Ty1 has one XhoI site in both delta elements, delimiting a 5.6 kb piece of DNA that shows a classical Ty1 restriction pattern. The orientation of this sequence in URA2 is the same as in the previously described examples in which Ty1 has positive effects on the expression of adjacent genes. In this case the Ty1 is situated more than 1 kb from the URA2 region in which ATCase structural mutants have been mapped. Nevertheless, transcription of the entire sequence distal to the Ty1 is restored and has become subject to mating-type control, leading to a weak enzyme activity. Our observations are in agreement with generally accepted ideas regarding the way in which Ty1 elements affect gene expression, and additionally, represent the first example of a Ty1 -promoted reinitiation occurring in the middle of a single transcription unit.

In vivo DNA cloning and adjacent gene fusing with a mini-Mu-lac bacteriophage containing a plasmid replicon

A mini-Mu bacteriophage containing a high copy number plasmid replicon was constructed to clone genes in vivo. A chloramphenicol resistance gene for independent selection and the lacZYA operon to form gene fusions were also incorporated into this phage. This mini-Mu element can transpose at a high frequency when derepressed, and it can be complemented by a helper Mu prophage for lytic growth. DNA sequences that are flanked by two copies of this mini-Mu can be packaged along with them. After infection, homologous recombination can occur between the mini-Mu sequences, resulting in the formation of plasmids carrying the transduced sequences. lac operon fusions can be formed with promoters and translation initiation sites on the cloned sequences in the resulting plasmids. The utility of this system was demonstrated by cloning genes from eight different Escherichia coli operons and by identifying lac fusions to the regulated araBAD operon among clones selected for the nearby leu operon.

In vivo formation of gene fusions encoding hybrid beta-galactosidase proteins in one step with a transposable Mu-lac transducing phage

A Mu-lac bacteriophage transposon, MudII301 (Ap, lac), was constructed to form hybrid protein gene fusions. When it integrates into structural genes in the appropriate direction and reading phase, transcription and translation from outside gene controlling regions can proceed across 116 nucleotides from the right end of Mu into lacZ codons to form hybrid proteins that are enzymatically active for beta-galactosidase. Integration can be obtained either by infection to form lysogens or by transposition during growth of a lysogen. The size of the hybrid protein product either corresponds to or, in the cases of translation restart or protein degradation, is a minimal estimate of the distance of the Mu insertion from the translation initiation site of the gene. Hybrid proteins formed by insertions in randomly selected genes and in the araB and A genes were examined by polyacrylamide gel electrophoresis.

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

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

Involvement of Escherichia coli K-12 DNA polymerase I in the growth of bacteriophage Mu

We examined several aspects of bacteriophage Mu development in Escherichia coli strains that carry mutations in the polA structural gene for DNA polymerase I (PolI). We found that polA mutants were markedly less efficient than PolI wild-type (PolI+) strains in their capacity to form stable Mu lysogens and to support normal lytic growth of phage Mu. The frequency of lysogenization was determined for polA mutants and their isogenic PolI+ derivatives, with the result that mutants were lysogenized 3 to 8 times less frequently than were PolI+ cells. In one-step growth experiments, we found that phage Mu grew less efficiently in polA cells than in PolI+ cells, as evidenced by a 50 to 100% increase in the latent period and a 20 to 40% decrease in mean burst size in mutant cells. A further difference noted in infected polA strains was a 10-fold reduction in the frequency of Mu-mediated transposition of chromosomal genes to an F plasmid. Pulse labeling and DNA-DNA hybridization assays to measure the rate of phage Mu DNA synthesis after the induction of thermosensitive prophages indicated that phage Mu replication began at about the same time in both polA and PolI+ strains, but proceeded at a slower rate in polA cells. We conclude that PolI is normally involved in the replication and integration of phage Mu. However, since phage Mu does not exhibit an absolute requirement for normal levels of PolI, it appears that residual PolI activity in the mutant strains, other cellular enzymes, or both can partially compensate for the absence of normal PolI activity.

Chromosome transfer and R-prime plasmid formation mediated by plasmid pULB113 (RP4::mini-Mu) in Alcaligenes eutrophus CH34 and Pseudomonas fluorescens 6.2

Plasmid pULB113 (RP4::mini-Mu), which contains the mini-Mu transposon, promoted both homologous and heterologous gene transfer from Pseudomonas fluorescens 6.2 and Alcaligenes eutrophus CH34. Homologous gene transfer in P. fluorescens 6.2 and A. eutrophus CH34 occurred at a frequency of 10(-4) to 10(-5), and recombinants inherited unselected recessive markers, suggesting a process of chromosome mobilization. Loci involved in autotrophic growth were among those transferred in A. eutrophus. In heterospecific matings, markers were transferred from P. fluorescens to A. eutrophus, Salmonella typhimurium LT2, and Escherichia coli, from A. eutrophus to P. fluorescens, and from Erwinia carotovora subsp. chrysanthemi to A. eutrophus. Heterospecific matings resulted in the formation of R-prime plasmids at frequencies of 10(-7) to 10(-4) per transferred plasmid. When S. typhimurium was the recipient, we observed R-prime plasmids with both restriction-proficient and restriction-deficient strains, although restriction markedly affected the frequency of transfer of pULB113. R-prime plasmids were quite stable, but lost the transposed marker more easily in a rec+ background than in a recA background, suggesting excision of transposed material by reciprocal recombination between flanking copies of mini-Mu. R-prime plasmids could be transferred easily into different recipients and were used in complementation studies. PstI restriction digests of four R-prime plasmids carrying P. fluorescens 6.2 DNA showed a number of additional bands, suggesting that several genes were transposed together with the selected marker on the plasmid.

In vivo cloning of Erwinia carotovora genes involved in the catabolism of hexuronates

Using the RP4::mini-Mu pULB113 plasmid, an RP4 derivative carrying a deleted Mu prophage which allows the plasmid to pick up any chromosomal DNA segment to form R' plasmids, we cloned all of the genes of Erwinia carotovora involved in the catabolism of the hexuronates and in the transport of these substrates. With the R' plasmids we isolated, we performed complementation analysis and found that, in the Erwinia carotovora strain we used, the genes involved in the catabolism of the hexuronates are clustered in four regions of the chromosome. This genetic organization is compared with that of Escherichia coli K-12.

Genetic and biochemical analyses of Escherichia coli mutants altered in the temperature-dependent regulation of membrane lipid composition

We have previously studied two mutants of Escherichia coli altered in the regulation of membrane lipid composition by temperature. One class (represented by the fabFl allele) fails to regulate upon temperature shift and is defective in cis-vaccenic acid synthesis owing to the lack of the fatty acid elongation enzyme beta-ketoacyl-acyl carrier protein synthase II(EC 2.3.1.41). A second class of mutant, given the phenotypic designation Vtr, overproduces cis-vaccenic acid at all temperatures and hence is altered in temperature regulation. In this paper we report evidence for the following conclusions. (i) The Vtr and fabFl mutations show very tight genetic linkage. (ii) The Vtr lesion is allelic to the fabFl mutation since the presence of the fabFl mutation in merodiploid strains carrying the Vtr or fabF(+) alleles results in fatty acid compositions intermediate between those of the two monoploid strains. Merodiploids carrying both the fabF(+) and Vtr alleles likewise show an intermediate composition. These results indicate intra-allelic complementation. (iii) The two E. coli proteins recently discovered by Rock (J. Bacteriol. 152:1298-1300, 1982) that form mixed disulfide cross-links to acyl carrier protein are directly demonstrated to be beta-ketoacyl-acyl carrier protein synthases I and II. (iv) The fabFl strains produce a synthase II band of altered electrophoretic mobility, indicating that the fabF locus is the structural gene for synthase II. (v) The synthase II of Vtr strains is abnormally sensitive to cerulenin, an antibiotic that specifically inhibits synthases I and II. This increased sensitivity is readily demonstrated in vivo, but in vitro we failed to detect an increased sensitivity of the Vtr synthase II to cerulenin, nor have we detected any other kinetic or structural alteration in the enzyme. We interpret these results in terms of specific interactions of synthase II with other cellular components which occur in vivo but are not duplicated in vitro.

Physical characterization of mini-mu and mini-D108

Several derivatives of phages Mu and D108 have been isolated that carry an internal deletion generated by one of the IS1 components of a Tn9 transposon located in the A, B, or S gene of the prenatal phage. The deletions remove most of the lytic functions of the phage but leave intact either genes A and B or gene A and the left and the right end of the phages. These deleted derivatives, called mini-Mu and mini-D108, were physically characterized by electron microscopy and digestion with restriction enzymes. Mini-Mu and mini-D108, which carry an antibiotic resistance marker, are described and some of their genetic properties are summarized in the paper by Toussaint et al. (1981).

Nitrate reductase and cytochrome bnitrate reductase structural genes as parts of the nitrate reductase operon

The existence of a nitrate-reductase operon in the tryptophane region was deduced from the effects of prophage insertion in each of chlI and chlC genes and from transposition of the Mu-mediated host DNA fragments of F-prime. This operon appears to be polarized from chlC to chlI and the gene order in the region is trp -- chlI -- chlC -- purB.

Introduction of bacteriophage Mu into bacteria of various genera and intergeneric gene transfer by RP4::Mu

The host range of coliphage Mu was greatly expanded to various genera of gram-negative bacteria by using the hybrid plasmic RP4::Mu cts, which is temperature sensitive and which confers resistance to ampicillin, kanamycin, and tetracycline. These drug resistance genes were transferred from Escherichia coli to members of the general Klebsiella, Enterobacter, Citrobacter, Salmonella, Proteus, Erwinia, Serratia, Alcaligenes, Agrobacterium, Rhizobium, Pseudomonas, Acetobacter, and Bacillus. Mu phage was produced by thermal induction from the lysogens of all these drug-resistant bacteria except Bacillus. Mu phage and RP4 or the RP4::Mu plasmid were used to create intergeneric recombinant strains by transfer of some genes, including the arylsulfatase gene, between Klebsiella aerogenes and E. coli. Thus, genetic analysis and intergeneric gene transfer are possible in these RP4::Mu-sensitive bacteria.

Mutations in nif genes that cause Klebsiella pneumoniae to be derepressed for nitrogenase synthesis in the presence of ammonium

Four Nif+ revertants from strains with polar insertions in nifL, were insensitive to ammonium and amino acid repression of nitrogenase synthesis. These strains have mutations located in or near the nifL region. The derepressed phenotype was dominant in a merodiploid containing a nif+ plasmid. These nif regulatory mutations also suppressed the Nif- phenotype of Gln- strains. Thus, regulation by fixed nitrogen (possible via glutamine synthetase) occurs on the nifLA operon but not on the other six nif operons.

Bacteriophage Mu-mediated gene transposition and in vitro cloning of the enterochelin gene cluster of Escherichia coli

Transposition of chromosomal genes using bacteriophage Mu has been used to obtain a partial order of the nine closely linked genes of the enterochelin-dependent iron transport system of Escherichia coli K-12. Fragments of the ent gene cluster were transposed into the conjugative plasmid RP4 and were characterized by genetic complementation. The partial gene order (entD, fes), entF, fep, entC, ent(ABEG)...lip was derived using six plasmids which carried overlapping parts of the cluster, and the fep mutations were shown to belong to a single complementation group. Two restriction fragments, one carrying ent(ABCEG) and the other carrying fep, were cloned in vitro using one of the RP4::ent plasmids as a source of DNA enriched in enterochelin system genes. A further restriction fragment, carrying the three remaining genes, entD, fes and entF was cloned directly from the chromosome. The three restriction fragments collectively cover a region of the chromosome 29 kg in length, indicating that the genes of the enterochelin system are clustered but not contiguous.

Expression of E. coli genes carried by hybrids of plasmid RP4

Hybrids of the RP4 plasmid, containing bacteriophage Mu and chromosomal genes of Escherichia coli, were transferred into Salmonella typhimurium, Pseudomonas putida, Pseudomonas aeruginosa and Proteus mirabilis. The individual genes of the arginine, histidine, leucine and threonine operons were expressed in these microorganisms.

Inversion induced by temperature bacteriophage mu-1 in the chromosome of Escherichia coli K-12

Induction of the Mu prophage of a lysogenic HfrP4X strongly stimulates the early transfer of the purE gene, which is located far from the origin of transfer. By using a rec- Mu cts62 X lysogenic donor, it was established that this process reflects the inversion of the origin of transfer in part of the Hfr population. Hfr's with inverted polarity of gene transfer were isolated; their analysis suggests that two Mu genomes in opposite orientation surround the inverted DNA fragment. Due to the presence of the Mu genome of the invertible G segment, homologous regions in the same orientation can appear in Mu genomes in opposite orientation. In a Rec+ background, Hfr's with inverted polarity (i) return to their original polarity of transfer by recomination between the two inverted Mu and (ii) produce new F' strains by recombination between the two similarly oriented G segments.

Integration of bacteriophage Mu at host chromosomal replication forks during lytic development

The target site for bacteriophage Mu integration in a lytic cycle of infection was investigated. DNA synthesis in five Hfr strains of Escherichia coli K-12 was synchronized by amino acid starvation and was allowed to proceed for 0, 8, or 15 min before infection. The Hfr cells were then infected with Mu and were subsequently mated with nonimmune F- recipient cells. Mating was interrupted mechanically at 5-min intervals and samples were assayed for infective centers. Conjugal transfer of Mu was delayed in Hfr strains that have transfer origins 15 map units or more from the E. coli replication origin, and the delays increased as the distance between an Hfr point of origin and the replication origin increased. When a gene A mutant of Mu was used for the infection, no infective centers were generated. Infection with a gene B mutant resulted in infective center formation only after long periods of mating. These data are most consistent with a model in which infecting Mu DNA or its progeny integrate at host chromosomal replication forks.

Tandem and inverted repeats of arginine genes in Escherichia coli: structural and evolutionary considerations

Duplications of arg genes produced in the Rec+ and in the recA genetic backgrounds are shown by heteroduplex analysis to be strictly tandem at the level of resolution of this technique. The formation of these particular rearrangements therefore does not require the inclusion of transposons or other sequences of an appreciable size in their final structure. Duplications of short segments (about 2,000 nucleotides) appear unexpectedly stable when compared with duplications of longer segments (about 10,000 nucleotides). One of the structures analyzed displays two inversely repeated argE genes rearranged into an artificial divergent operon. The bearing of this observation on the origin of bipolar operons, of "mirror-image" map symmetries and on the production of inverted repeats in general, is discussed.

Transposition of DNA inserted into deletions of the Tn5 kanamycin resistance element

Tn5-trp hybrid transposons have been constructed by insertion of a trpPOED Hind III fragment into an in vivo Tn5 internal deletion mutant or by substitution of trp for the internal Tn5 Hind III fragment. These hybrids are called, respectively, Tn409 and Tn410. Both Tn409 and Tn410 will transpose into lambda in the presence of a complementing Tn5 element. In the absence of a wild Tn5, lysogens carrying R1162::Tn409 and R1162::Tn410 plasmids will yield lambdatrp phages at less than six per cent of the complemented frequency. This reduction indicates that Tn409 and Tn410 lack a diffusible transposition function provided by wild Tn5 elements. However, the formation of lambdatrp phages without complementation is real. Most of these transducing particles contain Tn409 and Tn410 still linked to the carrier R1162 plasmid. This observation suggests that uncomplemented Tn409 and Tn410 elements mediate the formation of lambda-transposon-plasmid cointegrate structures. Thus, the missing transposition function may be involved in resolving these cointegrate structures to the final lambda::Tn409 or lambda::Tn410 product.