Involvement of phage Mu-1 early functions in Mu-mediated chromosomal rearrangements

Transposable Phage Mu

Transposable phage Mu has played a major role in elucidating the mechanism of movement of mobile DNA elements. The high efficiency of Mu transposition has facilitated a detailed biochemical dissection of the reaction mechanism, as well as of protein and DNA elements that regulate transpososome assembly and function. The deduced phosphotransfer mechanism involves in-line orientation of metal ion-activated hydroxyl groups for nucleophilic attack on reactive diester bonds, a mechanism that appears to be used by all transposable elements examined to date. A crystal structure of the Mu transpososome is available. Mu differs from all other transposable elements in encoding unique adaptations that promote its viral lifestyle. These adaptations include multiple DNA (enhancer, SGS) and protein (MuB, HU, IHF) elements that enable efficient Mu end synapsis, efficient target capture, low target specificity, immunity to transposition near or into itself, and efficient mechanisms for recruiting host repair and replication machineries to resolve transposition intermediates. MuB has multiple functions, including target capture and immunity. The SGS element promotes gyrase-mediated Mu end synapsis, and the enhancer, aided by HU and IHF, participates in directing a unique topological architecture of the Mu synapse. The function of these DNA and protein elements is important during both lysogenic and lytic phases. Enhancer properties have been exploited in the design of mini-Mu vectors for genetic engineering. Mu ends assembled into active transpososomes have been delivered directly into bacterial, yeast, and human genomes, where they integrate efficiently, and may prove useful for gene therapy.

The Mu story: how a maverick phage moved the field forward

This article traces the pioneering contributions of phage Mu to our current knowledge of how movable elements move/transpose. Mu provided the first molecular evidence of insertion elements in E. coli, postulated by McClintock to control gene activity in maize in the pre-DNA era. An early Mu-based model successfully explained all the DNA rearrangements associated with transposition, providing a blueprint for navigating the deluge of accumulating reports on transposable element activity. Amplification of the Mu genome via transposition meant that its transposition frequencies were orders of magnitude greater than any rival, so it was only natural that the first in vitro system for transposition was established for Mu. These experiments unraveled the chemistry of the phosphoryl transfer reaction of transposition, and shed light on the nucleoprotein complexes within which they occur. They hastened a similar analysis of other transposons and ushered in the structural era where many transpososomes were crystallized. While it was a lucky break that the mechanism of HIV DNA integration turned out to be similar to that of Mu, it is no accident that current drugs for HIV integrase inhibitors owe their discovery to trailblazing experiments done with Mu. Shining the light on how movable elements restructure genomes, Mu has also given of itself generously to understanding the genome.

Application of the bacteriophage Mu-driven system for the integration/amplification of target genes in the chromosomes of engineered Gram-negative bacteria--mini review

The advantages of phage Mu transposition-based systems for the chromosomal editing of plasmid-less strains are reviewed. The cis and trans requirements for Mu phage-mediated transposition, which include the L/R ends of the Mu DNA, the transposition factors MuA and MuB, and the cis/trans functioning of the E element as an enhancer, are presented. Mini-Mu(LR)/(LER) units are Mu derivatives that lack most of the Mu genes but contain the L/R ends or a properly arranged E element in cis to the L/R ends. The dual-component system, which consists of an integrative plasmid with a mini-Mu and an easily eliminated helper plasmid encoding inducible transposition factors, is described in detail as a tool for the integration/amplification of recombinant DNAs. This chromosomal editing method is based on replicative transposition through the formation of a cointegrate that can be resolved in a recombination-dependent manner. (E-plus)- or (E-minus)-helpers that differ in the presence of the trans-acting E element are used to achieve the proper mini-Mu transposition intensity. The systems that have been developed for the construction of stably maintained mini-Mu multi-integrant strains of Escherichia coli and Methylophilus methylotrophus are described. A novel integration/amplification/fixation strategy is proposed for consecutive independent replicative transpositions of different mini-Mu(LER) units with “excisable” E elements in methylotrophic cells.

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.

Handoff from recombinase to replisome: insights from transposition

Bacteriophage Mu replicates as a transposable element, exploiting host enzymes to promote initiation of DNA synthesis. The phage-encoded transposase MuA, assembled into an oligomeric transpososome, promotes transfer of Mu ends to target DNA, creating a fork at each end, and then remains tightly bound to both forks. In the transition to DNA synthesis, the molecular chaperone ClpX acts first to weaken the transpososome's interaction with DNA, apparently activating its function as a molecular matchmaker. This activated transpososome promotes formation of a new nucleoprotein complex (prereplisome) by yet unidentified host factors [Mu replication factors (MRF alpha 2)], which displace the transpososome in an ATP-dependent reaction. Primosome assembly proteins PriA, PriB, DnaT, and the DnaB--DnaC complex then promote the binding of the replicative helicase DnaB on the lagging strand template of the Mu fork. PriA helicase plays an important role in opening the DNA duplex for DnaB binding, which leads to assembly of DNA polymerase III holoenzyme to form the replisome. The MRF alpha 2 transition factors, assembled into a prereplisome, not only protect the fork from action by nonspecific host enzymes but also appear to aid in replisome assembly by helping to activate PriA's helicase activity. They consist of at least two separable components, one heat stable and the other heat labile. Although the MRF alpha 2 components are apparently not encoded by currently known homologous recombination genes such as recA, recF, recO, and recR, they may fulfill an important function in assembling replisomes on arrested replication forks and products of homologous strand exchange.

Differential role of the Mu B protein in phage Mu integration vs. replication: mechanistic insights into two transposition pathways

The Mu B protein is an ATP-dependent DNA-binding protein and an allosteric activator of the Mu transposase. As a result of these activities, Mu B is instrumental in efficient transposition and target-site choice. We analysed in vivo the role of Mu B in the two different recombination reactions performed by phage Mu: non-replicative transposition, the pathway used during integration, and replicative transposition, the pathway used during lytic growth. Utilizing a sensitive PCR-based assay for Mu transposition, we found that Mu B is not required for integration, but enhances the rate and extent of the process. Furthermore, three different mutant versions of Mu B, Mu BC99Y, Mu BK106A, and Mu B1-294, stimulate integration to a similar level as the wild-type protein. In contrast, these mutant proteins fail to support Mu growth. This deficiency is attributable to a defect in formation of an essential intermediate for replicative transposition. Biochemical analysis of the Mu B mutant proteins reveals common features: the mutants retain the ability to stimulate transposase, but are defective in DNA binding and target DNA delivery. These data indicate that activation of transposase by Mu B is sufficient for robust non-replicative transposition. Efficient replicative transposition, however, demands that the Mu B protein not only activate transposase, but also bind and deliver the target DNA.

Starvation-induced Mucts62-mediated coding sequence fusion: a role for ClpXP, Lon, RpoS and Crp

The formation of araB-lacZ coding sequence fusions in Escherichia coli is a particular type of chromosomal rearrangement induced by Mucts62, a thermoinducible mutant of mutator phage Mu. Fusion formation is controlled by the host physiology. It only occurs after aerobic carbon starvation and requires the phage-encoded transposase pA, suggesting that these growth conditions trigger induction of the Mucts62 prophage. Here, we show that thermal induction of the prophage accelerated araB-lacZ fusion formation, confirming that derepression is a rate-limiting step in the fusion process. Nonetheless, starvation conditions remained essential to complete fusions, suggesting additional levels of physiological regulation. Using a transcriptional fusion indicator system in which the Mu early lytic promoter is fused to the reporter E. coli lacZ gene, we confirmed that the Mucts62 prophage was derepressed in stationary phase (S derepression) at low temperature. S derepression did not apply to prophages that expressed the Mu wild-type repressor. It depended upon the host ClpXP and Lon ATP-dependent proteases and the RpoS stationary phase-specific sigma factor, but not upon Crp. None of these four functions was required for thermal induction. Crp was required for fusion formation, but only when the Mucts62 prophage encoded the transposition/replication activating protein pB. Finally, we found that thermally induced cultures did not return to the repressed state when shifted back to low temperature and, hence, remained activated for accelerated fusion formation upon starvation. The maintenance of the derepressed state required the ClpXP and Lon host proteases and the prophage Ner-regulatory protein. These observations illustrate how the cts62 mutation in Mu repressor provides the prophage with a new way to respond to growth phase-specific regulatory signals and endows the host cell with a new potential for adaptation through the controlled use of the phage transposition machinery.

Kinetic and structural analysis of a cleaved donor intermediate and a strand transfer intermediate in Tn10 transposition

Tn10 transposes by a nonreplicative "cut and paste" mechanism. We describe here two protein-DNA complexes that are reaction intermediates in the Tn10 transposition process: a cleaved donor complex whose DNA component consists of transposon sequences cleanly excised from flanking donor DNA, and a strand transfer complex whose DNA component contains transposon termini specifically joined to a target site. The kinetic behavior of the first species suggests that it is an early intermediate in the transposition reaction. These two Tn10 complexes are closely analogous to complexes identified in the pathway for replicative "cointegrate" formation by bacteriophage Mu and thus represent intermediates that may be common to both nonreplicative and replicative transposition. These and other results suggest that the Tn10 and Mu reactions are fundamentally very similar despite their very different biological outcomes. The critical difference between the two reactions is the fate of the DNA strand that is not joined to target DNA.

picA, a novel plant-inducible locus on the Agrobacterium tumefaciens chromosome

We used the transposon Mu dI1681 to identify genes on the Agrobacterium tumefaciens chromosome that are inducible by extracts from carrot roots. One such locus (picA, for plant inducible chromosomal), harbored by A. tumefaciens At156, was inducible 10- to 50-fold by these extracts. Mutation of picA had no detectable effect upon bacterial growth or virulence under laboratory assay conditions. However, A. tumefaciens cells harboring a mutated picA locus aggregated into long "ropes" when incubated with pea root tip cells. Such aggregation was not displayed by the parental strain A. tumefaciens A136. A preliminary characterization of the inducing compound in the carrot root extract suggests that the active substance is an acidic polysaccharide that is most likely derived from the pectic portion of the plant cell wall.

Functional domains of bacteriophage Mu transposase: properties of C-terminal deletions

We have generated a series of 3' deletions of a cloned copy of the bacteriophage Mu transposase (A) gene. The corresponding truncated proteins, expressed under the control of the lambda PI promoter, were analysed in vivo for their capacity to complement a super-infecting MuAam phage, both for lytic growth and lysogeny, and for their effect on growth of wild-type Mu following infection or induction of a lysogen. Using crude cell extracts, we have also examined binding properties of these proteins to the ends of Mu. The results allow us to further define regions of the protein important in replicative transposition, establishment of lysogeny and DNA binding.

Mini-D3112 bacteriophage transposable elements for genetic analysis of Pseudomonas aeruginosa

Small bacteriophage D3112 transposable elements deleted for most of the phage-lytic functions while retaining the sites required for transposition and packaging were constructed to facilitate genetic studies in Pseudomonas aeruginosa. These mini-D derivatives were constructed with the terminal 1.85 kilobases (kb) of the phage left end and 1.4 kb of the phage right end and either the Tn5 kanamycin resistance or the pSC101 (pBR322) tetracycline resistance determinant. Thermally induced lysates of strains lysogenic for both a mini-D element and D3112 cts (temperature-sensitive repressor) transduced P. aeruginosa PAO recipients to drug resistance at frequencies of between 10(-4) and 10(-5)/PFU of the helper phage. As for the parent plaque-forming D3112 phage, the mini-D171 element could insert itself into many different sites in the chromosome but the frequency of insertion into particular genes varied widely. Among 1,000 insertions, none resulted in auxotrophy but 10 resulted in pigment production. Insertions were also selected in a cloning plasmid with a transduction scheme. At least eight different insertion sites were found to have been used among 10 individual insertions. Transductants harboring these mini-D elements were immune to infection by D3112, since they contained the D3112 repressor gene in the left 1.85-kb terminal fragment. Chromosomal genes were transduced in a generalized fashion 100 to 1,000 times more frequently by the mini-D-D3112 cts lysates than by the D3112 cts phage alone. Mini-D171-D3112 cts lysates also yielded some transductants that retained the drug resistance marker of the mini-D element and which were unstable for the chromosomal transduced marker. This is consistent with the miniduction properties of Mu whereby transduced genes are flanked by two mini-D elements in the same orientation.

In vivo cloning of Pseudomonas aeruginosa genes with mini-D3112 transposable bacteriophage

The transposition properties of the Pseudomonas aeruginosa mutator bacteriophage D3112 were exploited to develop an in vivo cloning system. Mini-D replicon derivatives of D3112 were constructed by incorporating broad host range plasmid replicons between short terminal D3112 sequences. These elements were made with small replication regions from the RK2, Sa, and pVS1 plasmids and selectable genes for tetracycline, carbenicillin, kanamycin, and gentamicin resistance. Some of the mini-D replicons also contain the RK2 oriT origin-of-transfer sequence, which allows them to be mobilized by conjugation to many different species of gram-negative bacteria. These elements were used to clone DNA by preparing lysates from P. aeruginosa cells harboring an inducible D3112 cts prophage and a mini-D replicon plasmid. These lysates were used to infect sensitive P. aeruginosa recipients and select recombinant plasmids as drug-resistant transductant colonies. These transductants form a gene library from which particular clones can be selected, such as by their ability to complement specific mutations. This system was used to clone nine different genes from the PAO chromosome. The ability of this system to precisely identify a gene was demonstrated by isolating clones of the argF+ and cys-59+ genes. Restriction maps of clones of these genes, which have different amounts of flanking DNA, located the positions of these genes. The sizes of the chromosomal DNA segments from 10 individual clones examined ranged from 6 to 21 kilobases (kb), with an average of about 10 kb. This is consistent with the approximately 40-kb DNA-packaging size of the D3112 phage.

A subsequence-specific DNA-binding domain resides in the 13 kDa amino terminus of the bacteriophage Mu transposase protein

We have previously reported that the 13 kDa amino terminus of the 70 kDa bacteriophage D108 transposase protein (A gene product) contains a two-component, sequence-specific DNA-binding domain which specifically binds to the related bacteriophage Mu's right end (attR) in vitro. To extend these studies, we examined the ability of the 13 kDa amino terminus of the Mu transposase protein to bind specifically to Mu attR in crude extracts. Here we report that the Mu transposase protein also contains a Mu attR specific DNA-binding domain, located in a putative alpha-helix-turn-alpha-helix region, in the amino terminal 13 kDa portion of the 70 kDa transposase protein as part of a 23 kDa fusion protein with beta-lactamase. We purified for this attR-specific DNA-binding activity and ultimately obtained a single polypeptide of the predicted molecular weight for the A'--'bla fusion protein. We found that the pure protein bound to the Mu attR site in a different manner compared with the entire Mu transposase protein as determined by DNase I-footprinting. Our results may suggest the presence of a potential primordial DNA-binding site (5'-PuCGAAA-3') located several times within attR, at the ends of Mu and D108 DNA, and at the extremities of other prokaryotic class II elements that catalyze 5 base pair duplications at the site of element insertion. The dissection of the functional domains of the related phage Mu and D108 transposase proteins will provide clues to the mechanisms and evolution of DNA transposition as a mode of mobile genetic element propagation.

Bacteriophage Mu sites required for transposition immunity

Plasmids with bacteriophage Mu sequences receive additional Mu insertions 20-700 times less frequently than plasmids without Mu sequences. The Mu sites required for this transposition immunity were mapped near each end, either of which was sufficient. The left site was between 127 and 203 base pairs from the left end, and the right site was between 22 and 93 base pairs from the right end. These sequences include the innermost but not the outermost of the three binding sites for the Mu A transposition protein at each end of Mu. Transposition immunity was cis-acting and independent of its location on a target plasmid. An additional copy of an immunity site reduced transposition a factor of 10 further. Transposition immunity was seen both during full phage lytic growth, with all the bacteriophage Mu genes, and during normal cellular growth, with a mini-Mu element containing only the Mu c and ner regulatory and A and B transposition genes.

Binding of the Tn3 transposase to the inverted repeats of Tn3

The transposase protein and the inverted repeat sequences of Tn3 are both essential for Tn3 cointegrate formation and transposition. We have developed two assays to detect site-specific binding of transposase to the inverted repeats: (1) a nitrocellulose filter binding assay in which transposase preferentially retains DNA fragments containing inverted repeat sequences, and (2) a DNase 1 protection assay in which transposase prevents digestion of the inverted repeats by DNase 1. Both assays show that transposase binds directly to linear, duplex DNA containing the inverted repeats. The right inverted repeat of Tn3 binds slightly more strongly than the left one. Site-specific binding requires magnesium but does not require a high energy cofactor.

In vivo mutagenesis of bacteriophage Mu transposase

We devised a method for isolating mutations in the bacteriophage Mu A gene which encodes the phage transposase. Nine new conditional defective A mutations were isolated. These, as well as eight previously isolated mutations, were mapped with a set of defined deletions which divided the gene into 13 100- to 200-base-pair segments. Phages carrying these mutations were analyzed for their ability to lysogenize and to transpose in nonpermissive hosts. One Aam mutation, Aam7110, known to retain the capacity to support lysogenization of a sup0 host (M. M. Howe, K. J. O'Day, and D. W. Shultz, Virology 93:303-319, 1979) and to map 91 base pairs from the 3' end of the gene (R. M. Harshey and S. D. Cuneo, J. Genet. 65:159-174, 1987) was shown to be able to complement other A mutations for lysogenization, although it was incapable of catalyzing either the replication of Mu DNA or the massive conservative integration required for phage growth. Four Ats mutations which map at different positions in the gene were able to catalyze lysogenization but not phage growth at the nonpermissive temperature. Phages carrying mutations located at different positions in the Mu B gene (which encodes a product necessary for efficient integration and lytic replication) were all able to lysogenize at the same frequency. These results suggest that the ability of Mu to lysogenize is not strictly correlated with its ability to perform massive conservative and replicative transposition.

Interactions of the transposase with the ends of Mu: formation of specific nucleoprotein structures and non-cooperative binding of the transposase to its binding sites

Transposition of the E. coli bacteriophage Mu requires the phage encoded A and B proteins, the host protein HU and the host replication proteins. The ends of the genome of the phage, on which some of these proteins act, both contain three transposase (A) binding sites. The organization of these binding sites on each end, however, is different. Here we show, using DNase footprinting experiments with purified A protein, that mutant A binding sites, which affect transposition, have decreased affinity for the transposase. Furthermore the transposase binds non-cooperatively to all A binding sites both in the left and right end of Mu. Electron microscopic studies show that the A protein forms specific nucleoprotein structures upon binding to the ends of Mu. The A and B proteins interact with the ends of Mu to generate larger structures than with the A protein alone.

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.

B protein of bacteriophage mu is an ATPase that preferentially stimulates intermolecular DNA strand transfer

A DNA strand-transfer reaction is an early step in the transposition of phage Mu. It has been shown that an efficient reaction in vitro requires, in addition to buffer and salt, only the Mu A protein, Mu B protein, host protein HU, ATP, and Mg2+. We have determined that, of the three protein factors involved, only the Mu B protein has an ATPase activity. The Mu B ATPase is stimulated by Mu A protein and DNA but not by either of these factors alone. Double-stranded DNA is a much better cofactor than single-stranded DNA, but there is no apparent sequence specificity. In the absence of the Mu B protein and/or ATP, the intermolecular Mu DNA strand-transfer reaction is extremely inefficient, and the strand-transfer products are predominantly the result of an intramolecular reaction. This contrasts with the efficient intermolecular reaction that occurs if Mu B protein and ATP are provided. The Mu B protein, in the presence of Mu A protein and protein HU, therefore, seems to facilitate interactions between potential DNA target sites and pairs of Mu DNA ends.

Analysis of the ends of bacteriophage Mu using site-directed mutagenesis

We showed previously that two regions at the left end (L1 and L3) and one at the right end (R2) of bacteriophage Mu are essential for transposition. These regions all contain a 22 base-pair sequence with the consensus YGtTTCAYtNNAARYRCGAAAR, where Y and R represent any pyrimidine and purine, respectively. The Mu A protein binds to these regions in vitro, and weakly to sequences between nucleotides 1 and 30 of the right end (R1) and between nucleotides 110 and 135 of the left end (L2). These weak A binding sites contain the sequence AARYRCGAAAR. Here we show, using site-directed mutagenesis, that the weak A binding sites are essential for transposition. Mutations in these weak A binding sites have a greater effect on transposition than mutations of corresponding base-pairs in the stronger A binding sites, located adjacent to these weak A binding sites. We confirm the importance of several of the conserved base-pairs in the consensus sequence YGtTTCAYtNNAARYRCGAAAR. The base-pairs in the A binding sites that are shown to be essential for transposition are all conserved in the ends of the related bacteriophage D108. Furthermore, it is shown that the distance of 90 base-pairs between the two regions at the left end (L1 and L2L3) is essential.

A defined system for the DNA strand-transfer reaction at the initiation of bacteriophage Mu transposition: protein and DNA substrate requirements

An early step in the transposition of bacteriophage Mu DNA in vitro is a DNA strand-transfer reaction that generates an intermediate DNA structure in which the Mu donor DNA and the target DNA are covalently joined. DNA replication, initiated at the DNA forks in this intermediate, generates a cointegrate product; simple insert products can also be formed from the same intermediate by degradation of a specific segment of the structure, followed by gap repair. This DNA strand-transfer reaction requires ATP, magnesium, the Mu A and Mu B proteins, and a factor supplied by an Escherichia coli cell extract. We have now shown that the host protein factor requirement can be satisfied by purified protein HU. The defined system has been used to determine the DNA substrate requirements for the reaction. The reaction requires the two Mu ends, located on the same DNA molecule, in the same relative orientation to one another as in the phage Mu genome. To participate in the strand-transfer reaction efficiently the mini-Mu plasmid, used as the transposon donor, must be supercoiled; the target DNA molecule may be supercoiled, relaxed circular, or linear.

A truncated form of the bacteriophage Mu B protein promotes conservative integration, but not replicative transposition, of Mu DNA

The phage-encoded proteins required for conservative integration of infecting bacteriophage Mu DNA were investigated. Our findings show that functional gpA, an essential component of the phage transposition system, is required for integration. The Mu B protein, which greatly enhances replicative transposition of Mu DNA, is also required. Furthermore, a truncated form of gpB lacking 18 amino acids from the carboxy terminus is blocked in replicative transposition, but not conservative integration. Our results point to a more prominent role for gpB than simply a replication enhancer in Mu DNA transposition. The ability of a truncated form of B to function in conservative integration, but not replicative transposition, also suggests a key role for the carboxy-terminal domain of the protein in the replicative reaction. The existence of a shortened form of gpB, which uncouples conservative integration from replicative transposition, should be invaluable for future dissection of Mu DNA transposition.

Mechanism of transposition of bacteriophage Mu: structure of a transposition intermediate

Mu transposition works efficiently in vitro and generates both cointegrate and simple insert products. We have examined the reaction products obtained under modified in vitro reaction conditions that do not permit efficient initiation of DNA replication. The major product is precisely the intermediate structure predicted from one of the current models of DNA transposition. Both cointegrates and simple inserts can be made in vitro using this intermediate as the DNA substrate, demonstrating that it is indeed a true transposition intermediate. The requirements for efficient formation of the intermediate include the Mu A protein, the Mu B protein, an unknown number of E. coli host proteins, ATP, and divalent cation. Only E. coli host proteins are required for conversion of the intermediate to cointegrate or simple insert products. Structures resulting from DNA strand transfer at only one end of the transposon are not observed, suggesting that the strand transfers at each end of the transposon are tightly coupled.

Morphogenetic structures present in lysates of amber mutants of bacteriophage Mu

The Mu phage particle is structurally similar to that of the T-even phages, consisting of an icosahedral head and contractile tail. This study continues an analysis of the morphogenesis of the Mu phage particle by defining the structural defects resulting from mutations in specific Mu genes. Defective lysates produced by induction of 55 amber mutants, representing 24 essential genes, were examined in the electron microscope and categorized into eight classes based on the observed phage-related structures. (1) Mutations in genes lys, F and G, and some H mutations, did not cause a visible alteration in particle structure. (2) Mutants defective in genes A, B, and C produced no detectable phage structures, consistent with their lack of production of late RNA. (3) Extracts defective in genes L, M, Y, N, P, Q, V, W, and R contained only head structures, and these appeared normal. (4) K-defective mutants accumulated free heads as well as free tails which were longer than normal and variable in length. (5) Tails which appeared normal were the only structures found in T- and some I-defective extracts. (6) Free tails and empty heads accumulated in D-, E-, and some I- and H-defective extracts. These heads were as much as 16% smaller than normal heads. The heads found in some I amber lysates had a protruding neck-like structure and unusually thick shells suggestive of a scaffolding-like structure. (7) Defects in gene J resulted in the accumulation of unattached tails and full heads. (8) Previous analysis of lysates produced by inversion-defective gin mutants fixed in the G(+) orientation demonstrated that S and U mutants produced particles lacking tail fibers (F.J. Grundy and M.M. Howe (1984), Virology 134, 296-317). In these experiments with Gin+ phages S and U mutants produced apparently normal phage particles. Presumably the tail fiber defects were masked by the production of S' and U' proteins by G(-) phages in the population.

DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition

We have determined the minimal DNA sequences at the ends of the genome of bacteriophage Mu that are required for its transposition. A mini-Mu was constructed on a multicopy plasmid that enabled the manipulation of the DNA sequences at its ends without affecting the genes essential for transposition. The genes A and B, which were cloned outside the ends of the mini-Mu on the same plasmid, were both needed for optimal transposition. In our experimental system the predominant end products of the transposition are cointegrates both in the presence and in the absence of B. Two regions ending approximately 25 and 160 bp from the left end and one ending approximately 50 bp from the right end appear to be essential for optimal transposition. Overlapping with these regions, a 22-base-pair sequence was recognized with the consensus Y-G-T-T-C-A-Y-T-N-N-A-A-R-Y-R-C-G-A-A-A-A, where Y and R represent any pyrimidine and purine, respectively. At the left end these sequences occur as direct repeats; at the right end this sequence is inverted with respect to those at the left end.

Site-specific recognition of the bacteriophage Mu ends by the Mu A protein

The Mu A protein binds site-specifically to the ends of Mu DNA. Two blocks of protection against nuclease are seen at the left (L) end; the right (R) end exhibits one continuous block of protection. We interpret the nuclease protection pattern and sequence data as evidence for three Mu A protein binding sites at each end of Mu. Both the L and R ends have one site close to the terminus; each end also has two additional sites that differ in location between the L and R ends. The Mu A protein protection patterns on the L ends of Mu and the closely related phage D108 are, despite many interspersed sequence differences in one of the protected regions, essentially identical. We show that the A proteins of Mu and D108 can function, at different efficiencies, interchangeably on the Mu and D108 L ends in vivo. Purified Mu repressor, in addition to its primary binding in the operator region, also binds less strongly to the Mu ends at the same sites as the Mu A protein. This affinity of Mu repressor for DNA sites recognized by the Mu A protein may play a role as a second level of control of transposition by the repressor.

The nucleotide sequence of the B gene of bacteriophage Mu

Bacteriophage Mu is a highly efficient transposon which requires the products of the Mu A and B genes in order to transpose at a normal frequency. We have determined the nucleotide sequence of the B gene as well as that of the A-B intergenic region upstream of B. The protein product of the gene contains 312 amino acids and has a predicted molecular weight of 35,061. As expected, there do not appear to be any potential promoter sequences in the intergenic region prior to the gene, but it is preceded by a strong Shine-Dalgarno sequence. The intergenic region does not contain any obvious transcription termination sequences. The frequency of optimal codon usage is similar to that for other transposon and phage genes, and the amino acid composition is comparable to that of an "average" E. coli protein. A region near the amino terminus of the protein resembles the highly conserved bihelical fold which is involved in DNA contact and sequence specific recognition in a number of DNA binding proteins.

Multiple factors and processes involved in host cell killing by bacteriophage Mu: characterization and mapping

The regions of bacteriophage Mu involved in host cell killing were determined by infection of a lambda-immune host with 12 lambda pMu-transducing phages carrying different amounts of Mu DNA beginning at the left end. Infecting lambda pMu phages containing 5.0 (+/- 0.2) kb or less of the left end of Mu DNA did not kill the lambda-immune host, whereas lambda pMu containing 5.1 kb did kill, thus locating the right end of the kil gene between approximately 5.0 and 5.1 kb. For the Kil+ phages the extent of killing increased as the multiplicity of infection (m.o.i.) increased. In addition, killing was also affected by the presence of at least two other regions of Mu DNA: one, located between 5.1 and 5.8 kb, decreased the extent of killing; the other, located between 6.3 and 7.9 kb, greatly increased host cell killing. Killing was also assayed after lambda pMu infection of a lambda-immune host carrying a mini-Mu deleted for most of the B gene and the middle region of Mu DNA. Complementation of mini-Mu replication by infecting B+ lambda pMu phages resulted in killing of the lambda-immune, mini-Mu-containing host, regardless of the presence or absence of the Mu kil gene. The extent of host cell killing increased as the m.o.i. of the infecting lambda pMu increased, and was further enhanced by both the presence of the kil gene and the region located between 6.3 and 7.9 kb. These distinct processes of kil-mediated killing in the absence of replication and non-kil-mediated killing in the presence of replication were also observed after induction of replication-deficient and kil mutant prophages, respectively.

Plasmid rearrangements in the photosynthetic bacterium Rhodopseudomonas sphaeroides

Mu d1(Ap lac) was introduced into the photosynthetic bacterium Rhodopseudomonas sphaeroides 2.4.1. via the R-plasmid R751 in an attempt to isolate fusion derivatives involving photosynthetic operons. The selection system is potentially very powerful since R. sphaeroides is normally Lac negative. Among the exconjugants, photosynthesis-deficient mutants were recovered, some of which had elevated beta-galactosidase levels. Among the mutants examined, beta-galactosidase expression was linked exclusively to R751 . Many of the photosynthesis-deficient mutants were found to have alterations in their indigenous plasmids which apparently involved the exchange of DNA from one plasmid to another. Southern blot analysis revealed that there are extensive DNA sequences which are shared by the two plasmids that are involved in the rearrangements and that no exogenous DNA sequences appear to be involved. It was further discovered that plasmid rearrangement is a general phenomenon which can occur spontaneously in R. sphaeroides 2.4.1 and shows a high correlation with a photosynthesis minus phenotype.

Mu DNA replication in vitro: criteria for initiation

An in vitro system for investigating Mu replication nd transposition using film lysates has recently been described (Higgins et al. 1983). Under most conditions examined, little or no replication initiation takes place in vitro. The data are consistent with Mu specific replication forks being initiated in vivo, and completing but not reinitiating a round of replication in vitro. Since Mu DNA replication is from left to right, an excess of right end sequences compared to left end sequences are replicated on the film lysates. Two conditions reported to specifically decrease Mu DNA replication in vivo ( Pato and Reich 1982) were assessed for their effects on in vitro replication. Protein synthesis inhibition in vivo drastically decreased Mu specific DNA synthesis both in vivo and in the film lysates. However, temperature-sensitive (ts) A cells (A ts) incubated at the non-permissive temperature gave increased Mu synthesis at the permissive temperature in vitro. These conditions result in preferential mobilization of Mu specific forks, equal replication of the left and right end sequences of Mu, and meet minimal criteria for Mu replication initiation in the Ats lysates. The results are consistent with the Mu A protein limiting the initiation of Mu replication in vitro.

Cloning and expression of the phage Mu A gene

We have cloned the phage Mu A gene, with and without the gene ner, under the control of the pL promoter of phage lambda in a multicopy plasmid vector. We demonstrate that plasmid-carrying cells are able to support growth of superinfecting Mu A am phages in a temperature-dependent fashion in a host strain carrying a defective lambda prophage which specifies the cI857-coded lambda repressor. In addition, we show that the presence of the ner gene reduces the efficiency of plating of the superinfecting phage. Analysis of proteins specified by the cloned Mu fragments indicates that two proteins, 70 and 33 kDal, are synthesized. The level of synthesis, compared to that of the vector-encoded beta-lactamase, was found to increase with temperature. This indicates that their transcription is driven by the pL promoter. The Mr of the 70-kDal protein is identical to that previously observed for pA.

Escherichia coli K-12 gyrB gene product is involved in the lethal effect of the ligts2 mutant of bacteriophage Mu

Mu ligts2 mutants, defective for development and integration, show a high killing effect on the infected host. A number of survivors to Mu ligts2 infection were analyzed; they are characterized by nonpermissivity for both development and lysogenization of bacteriophage Mu. Bacteriophages D108 and P1 are also inhibited in these strains as is transposon Tn9. The corresponding mutation site was mapped at 82 min and identified with the Escherichia coli gyrB site.

In vitro transposition of bacteriophage Mu: a biochemical approach to a novel replication reaction

The transposition-replication reaction of phage Mu has been reproduced in a cell-free reaction system. Two assay methods were used for the detection of transposition products. The first method uses lambda DNA as the target of transposition and a plasmid containing the ends of Mu DNA and an ampicillin-resistance gene as the donor; after the reaction, in vitro lambda packaging allows the scoring of ampr transducing phages generated by transposition. In the second method, the products made in the presence of a radioactive precursor for DNA synthesis are directly analyzed by gel electrophoresis and unique product species are identified. The reaction requires a donor DNA carrying the two Mu ends in their proper relative orientation, extracts containing the A and B gene products of Mu, and host factor(s). RNA synthesis by E. coli RNA polymerase is not required for the reaction. The products include both cointegrates and simple inserts. Both types of products show incorporation of radioactive DNA precursors; however, simple inserts do not seem to undergo a full round of DNA replication.

Switch in the transposition products of Mu DNA mediated by proteins: Cointegrates versus simple insertions

Bacteriophage Mu is a self-contained mobile unit encoding functions that mediate its movement. There appear to be two alternate pathways for Mu DNA transposition that differ with respect to the end products they generate. During the lytic cycle of phage Mu growth the end products of transposition are predominantly cointegrates in an experimental system in which the induced Mu prophage is located on pSC101, a low-copy-number plasmid. On the other hand, Mu insertions into the host genome during lysogenization contain Mu DNA as simple insertions. Two Mu functions, encoded by the A and B genes, are required for Mu DNA transposition during its lytic growth. However, during lysogeny the product of gene B is not required for integration of Mu DNA. Evidence is presented here which shows that in the absence of the B gene product the majority of transposition events are simple insertions. This is in striking contrast to the situation in which the majority of the products are cointegrates in the presence of both A and B gene products. Additional evidence also suggests that these simple insertions do not arise through the resolution of cointegrate structures.

Nucleotide sequence of the immunity region of bacteriophage Mu

The leftmost 1590 bp of Mu DNA covering the immunity region have been sequenced. This region encodes the cI repressor, the cII or ner function and the beginning of gene A. An open reading frame extends from position 863 to 342 on the l-strand corresponding to cI protein with a molecular weight of 19212. It is preceded by a sequence resembling a promoter. To the right of the HindIII site an open reading frame extends from position 1099 to 1323 corresponding to cII or ner protein (molecular weight of 8505) followed by the beginning of gene A at position 1328. Between position 863 and 1099 promoters for leftward and rightward transcription and operator-like structures can be recognized in the sequence. The promoter for rightward transcription overlaps with the HindIII site and coincides with a RNA polymerase binding site as demonstrated by electron microscopy.

Instability of transposase activity: evidence from bacteriophage mu DNA replication

Transposition of genetic elements involves coupled replication and integration events catalyzed in part by a class of proteins called transposases. We have asked whether the transposase activity of bacteriophage Mu (the Mu A protein) is stable and capable of catalyzing multiple rounds of coupled replication/integration, or whether its continued synthesis is required to maintain Mu DNA replication. Inhibition of protein synthesis during the lytic cycle with chloramphenicol inhibited Mu DNA synthesis with a half-life of approximately 3 min, demonstrating a need for continued protein synthesis to maintain Mu DNA replication. Synthesis of specific Mu-encoded proteins was inhibited by infecting a host carrying a temperature-sensitive suppressor, at permissive temperature, with Mu amber phages, then shifting to nonpermissive temperature. When Aam phages were used, Mu DNA replication was inhibited with kinetics essentially identical to those with chloramphenicol addition; hence, it is likely that continued synthesis of the Mu A protein is required to maintain Mu DNA replication. The data suggest that the activity of the Mu A protein is unstable, and raise the possibility that the Mu A protein and other transposases may be used stoichiometrically rather than catalytically.

Transfection of Escherichia coli spheroplasts with a bacteriophage Mu DNA-protein complex

We disrupted bacteriophage Mu particles by freeze-thaw treatment and recovered the DNA by CsCl density gradient centrifugation. This CsCl-purified DNA had a buoyant density which was indistinguishable from that of phenol-extracted Mu DNA. It was, however, 10(3) times more infective than phenol-extracted DNA for spheroplasts of exoV endI Escherichia coli. Infectivity was destroyed by proteinase K as well as by pancreatic DNase, indicating that the infective form was a DNA-protein complex. The infective properties of the complex demonstrated that the protein protects. Mu DNA against degradation by exonuclease V and that it serves at least one other function in bacteriophage Mu infection. The infectivity of the CsCl-purified DNA was due to a small class of highly infective molecules which sedimented 1.2. times faster than phenol-extracted Mu DNA on neutral sucrose gradients. This change in sedimentation rate is best explained by the formation of protein-linked circular monomers or linear dimers of Mu DNA. In vitro labeling of the DNA-protein complex, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, showed that the CsCl-purified DNA contained a noncovalently associated 65,000-dalton polypeptide. A 65,000-dalton protein was also found to be a minor component of the bacteriophage Mu particle. No protein was found in phenol-extracted Mu DNA. These results suggest that the 65,000-dalton protein is necessary for successful phage infection and is normally injected into the host cell with the Mu genome.

Abnormal cointegrate structures mediated by gene B mutants of phage Mu: their implications with regard to gene function

A system where the transposition of MupApl (a derivative of phage Mu carrying a determinant coding for ampicillin resistance) is followed from the small plasmid pML2 into the conjugative plasmid R388 has been used to investigate the influence on Mu transposition of B, an early Mu gene which is involved in normal phage DNA synthesis. In the absence of active B protein a low level (about 1% of normal) of transposition was detected. Roughly a third of these transpositional events was found to lead to the formation of cointegrate DNA structures which were shown to consist of R388, two complete copies of Mu and part only of pML2. The pML2 deletions vary in size but all those investigated appear to originate at an end of Mu. An explanation of these observations is proposed which envisages the B protein as part of the normal transposition complex.