Regulation of bacteriophage mu and mini-mu DNA replication in vivo

To study the regulation of bacteriophage Mu DNA's integrative-replication (transposition) during lytic growth in a cell containing both a Mu and a helper-dependent Mini-Mu (short, internally-deleted Mu genome), we placed "marker" genes (bla, lacZ) within either genome and then measured their encoded enzymes as indicators of the gene dosage. These results, corroborated using DNA-DNA hybridization, show that Mu and Mini-Mu DNA transposition is well regulated, requires both the Mu A and B gene products, and can be readily monitored by measuring beta-galactosidase and beta-lactamase expressed from the lacZ and bla genes, respectively.     

Marking the rhizopseudomonas strain 7NSK2 with a Mu d(lac) element for ecological studies

The mini Mu element Mu dII1681, which contains the lac operon genes and a kanamycin resistance gene, was inserted in the chromosome of plant growth-beneficial Pseudomonas aeruginosa 7NSK2 to construct a marked strain (MPB1). In MPB1, beta-galactosidase is permanently expressed under the culture conditions used. The MPB1 strain could be recovered with an efficiency of about 100% from a sandy loam soil on 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside medium containing sebacic acid and kanamycin. The limit of detection is about 10 CFU/g of soil. A detailed comparison was made between the wild-type strain 7NSK2 and the Mu dII1681-containing MPB1 strain. The results showed that no genes essential for growth, siderophore production, survival in sterile and nonsterile conditions, plant growth stimulation, or root colonization had been damaged in the MPB1 strain, which means that MPB1 can reliably be used for ecological studies in soil. MPB1 survived well at 4 or 28 degrees C but died off relatively rapidly in air-dried soil or at subzero temperatures. In these conditions, however, the MPB1 strain did not completely disappear from the soil but survived at a very low level of about 100 CFU/g of soil for more than 3 months. This observation stresses the need for very sensitive counting methods for ecological studies and for the evaluation of released microorganisms. Maize was inoculated with MPB1 via seed inoculation or soil inoculation. Upon seed inoculation, only the upper root parts were effectively colonized, while soil inoculation resulted in a complete colonization of the root system.     

Marking the rhizopseudomonas strain 7NSK2 with a Mu d(lac) element for ecological studies.

The mini Mu element Mu dII1681, which contains the lac operon genes and a kanamycin resistance gene, was inserted in the chromosome of plant growth-beneficial Pseudomonas aeruginosa 7NSK2 to construct a marked strain (MPB1). In MPB1, beta-galactosidase is permanently expressed under the culture conditions used. The MPB1 strain could be recovered with an efficiency of about 100% from a sandy loam soil on 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside medium containing sebacic acid and kanamycin. The limit of detection is about 10 CFU/g of soil. A detailed comparison was made between the wild-type strain 7NSK2 and the Mu dII1681-containing MPB1 strain. The results showed that no genes essential for growth, siderophore production, survival in sterile and nonsterile conditions, plant growth stimulation, or root colonization had been damaged in the MPB1 strain, which means that MPB1 can reliably be used for ecological studies in soil. MPB1 survived well at 4 or 28 degrees C but died off relatively rapidly in air-dried soil or at subzero temperatures. In these conditions, however, the MPB1 strain did not completely disappear from the soil but survived at a very low level of about 100 CFU/g of soil for more than 3 months. This observation stresses the need for very sensitive counting methods for ecological studies and for the evaluation of released microorganisms. Maize was inoculated with MPB1 via seed inoculation or soil inoculation. Upon seed inoculation, only the upper root parts were effectively colonized, while soil inoculation resulted in a complete colonization of the root system.     

Precise excision of bacteriophage Mu DNA

The temperate bacteriophage Mu is a transposable element that can integrate randomly into bacterial DNA, thereby creating mutations. Mutants due to an integrated Mu prophage do not give rise to revertants, as if Mu, unlike other transposable elements, were unable to excise precisely. In the present work, starting with a lacZ::Muc62(Ts) strain unable to form Lac+ colonies, we cloned a lacZ+ gene in vivo on a mini-Mu plasmid, under conditions of prophage induction. In all lac+ plasmids recovered, the wild-type sequence was restored in the region where the Mu prophage had been integrated. The recovery of lacZ+ genes shows that precise excision of Mu does indeed take place; the absence of Lac+ colonies suggests that precise excision events are systematically associated with loss of colony-forming ability.     

The effect of gamma-irradiation on mu DNA transposition and gene expression

Mobile genetic elements are a ubiquitous presence in the genomes of all well-studied organisms. The effect of genomic stress on the status and transposition of these elements has not, as yet, been extensively characterized. We have been using temperate, transposable bacteriophage Mu as a model system to examine the behavior of mobile genetic elements and have previously shown that many DNA-damaging agents did not induce a Mu prophage to enter the lytic cycle of multiple rounds of DNA transposition. To extend these results and to examine the possibility that they were a reflection of damage to the DNA substrate for Mu transposition, we have constructed a mini-Mu plasmid, pMD12, which contains the early region of Mu, flanked by both extremities required for transposition in cis, and the beginning of the transposase gene A fused in frame to the lacZ gene. This A'-lacZ fusion protein maintains beta-galactosidase enzymatic activity under the control of the expression of the Mu transposase A gene and thus, the capacity for Mu transposition can be easily monitored by assaying for beta-galactosidase. By measuring the amount of beta-galactosidase after various doses of gamma-irradiation, we found that doses of up to 75 krad had no effect on the expression of the Mu transposase gene A. This was confirmed by the lack of induction of a Mu prophage in strains containing a chromosomally inserted Mu genome. Although the plaque-forming units per colony-forming unit of strain CSH67, containing a chromosomally inserted lambda prophage, increased approximately 100-fold from 0 to 75 krad, no stimulation of induction of prophage Mu lytic growth was observed. We also found that plasmid pMD12 did not transpose and chromosomally associate upon gamma-irradiation. This supports the assertion that DNA-damaging agents, including gamma-rays, do not induce the transposition of prokaryotic mobile genetic elements.     

PhoA gene fusions in Legionella pneumophila generated in vivo using a new transposon, MudphoA

To enable effective use of phoA gene fusions in Legionella pneumophila, we constructed MudphoA, a derivative of the mini-Mu phage Mu dII4041, which is capable of generating gene fusions to the Escherichia coli alkaline phosphatase gene (EC 3.1.3.1). Although an existing fusion-generating transposon, TnphoA, has been a useful tool for studying secreted proteins in other bacteria, this transposon and other Tn5 derivatives transpose inefficiently in Legionella pneumophila, necessitating the construction of a more effective vector for use in this pathogen. Using MudphoA we generated fusions to an E. coli gene encoding a periplasmic protein and to an L. pneumophila gene encoding an outer membrane protein; both sets of fusions resulted in alkaline phosphatase activity. We have begun to use MudphoA to mutate secreted proteins of L. pneumophila specifically, since this subset of bacterial proteins is most likely to be involved in host-bacterial interactions. This modified transposon may be useful for studies of other bacteria that support transposition of Mu, but not Tn5, derivatives.     

lacZ gene fusions and insertion mutagenesis in the TL-region of Agrobacterium rhizogenes Ri plasmid

Agrobacterium rhizogenes induces root formation and inserts a fragment of its plasmid into the genome of infected plants. A part of the transferred region (TL-region) of the Ri plasmid of A. rhizogenes strain A4 was cloned in pBR322. Insertions of the Escherichia coli lacZ coding region into the hybrid plasmids were made in vivo using mini-Mu-duction. Two mini-Mus were used, one with the Mu A and B transposase genes (MudII1681) and the other without (MudII1734). Two inserts which result in E. coli lacZ expression where shown to be located in the T-DNA region. This indicates that portions of the T-DNA are capable of expression in bacteria. When these two hybrid plasmids were transformed into Agrobacterium only the one harboring MudII1734 insert gave transformants which correspond to homologous recombination. These results indicate that gene fusion and insertion directed mutagenesis can be simultaneously obtained with this mini-Mu and could be used to study Agrobacterium gene expression.     

Transposable lambda placMu bacteriophages for creating lacZ operon fusions and kanamycin resistance insertions in Escherichia coli.

We have constructed several derivatives of bacteriophage lambda that translocate by using the transposition machinery of phage Mu (lambda placMu phages). Each phage carries the c end of Mu, containing the Mu cIts62, ner (cII), and A genes, and the terminal sequences from the Mu S end (beta end). These sequences contain the Mu attachment sites, and their orientation allows the lambda genome to be inserted into other chromosomes, resulting in a lambda prophage flanked by the Mu c and S sequences. These phages provide a means to isolate cells containing fusions of the lac operon to other genes in vivo in a single step. In lambda placMu50, the lacZ and lacY genes, lacking a promoter, were located adjacent to the Mu S sequence. Insertion of lambda placMu50 into a gene in the proper orientation created an operon fusion in which lacZ and lacY were expressed from the promoter of the target gene. We also introduced a gene, kan, which confers kanamycin resistance, into lambda placMu50 and lambda placMu1, an analogous phage for constructing lacZ protein fusions (Bremer et al., J. Bacteriol. 158:1084-1093, 1984). The kan gene, located between the cIII and ssb genes of lambda, permitted cells containing insertions of these phages to be selected independently of their Lac phenotype.     

Stoichiometric use of the transposase of bacteriophage Mu

The transposase of bacteriophage Mu (gene A protein) mediates the coupled replication and integration processes that constitute transposition during the lytic cycle. Our previous results showed that the activity of the A protein is unstable, as its continued synthesis is required to maintain Mu DNA replication throughout the lytic cycle. We present here the results of experiments in which the A protein is used stoichiometrically and must be synthesized de novo for each round of Mu DNA replication. Induction of a Mu lysogen in the absence of DNA replication allows accumulation of potential for a single round of Mu DNA replication. Once achieved, this potential is stable even in the absence of further protein synthesis. Release of inhibition of DNA replication leads to a single semi-conservative replicative transposition event, followed by later rounds only if additional synthesis of the A protein is allowed.     

Replication forks of Escherichia coli are not the preferred sites for lysogenic integration of bacteriophage Mu.

The question of whether bacteriophage Mu prefers replication forks for lysogenic integration into Escherichia coli chromosomes was tested by using two different systems. In the first, inactivation of genes was scored in synchronized cultures infected by Mu at various times. No increase in the mutation frequency of a gene was found after infection at the time of its replication. In the second, the composition of colonies formed by bacteria lysogenized by Mu was determined; the newly formed lysogens should give rise to mixed colonies (containing lysogenized as well as nonlysogenized bacteria), uniform colonies, or both, depending on the mode of integration. Both types of colonies were found, and the fraction of uniform colonies was proportional to the relative length of the unreplicated segment of an average chromosome in the culture. The results in both systems clearly preclude the possibility that a lysogenizing Mu integrates with high preference at the chromosome replication forks.     

Simultaneous expression of a bacteriophage Mu transposase and repressor: a way of preventing killing due to mini-Mu replication

In vitro studies of bacteriophage Mu transposition have shown that the phage-encoded transposase and repressor bind the same sequences on the phage genome. We attempted to test that prediction in vivo and found that Mu repressor directly inhibits transposition. We also found that, in the absence of repressor, constitutive expression of Mu transposition functions pA and pB is lethal in Escherichia coli strains lysogenic for a mini-Mu and that this is the result of intensive replication of the mini-Mu. These findings have important consequences where such mini-Mus are used as genetic tools. We also tested whether in Erwinia chrysanthemi the effect of transposition functions on a resident mini-Mu was the same as in E. coli. We observed that expression of pA alone was lethal in E. chrysanthemi and that a large fraction of the survivors underwent precise excision of the mini-Mu.     

Patterns of gene expression in Bacillus subtilis colonies.

Bacillus subtilis 5:7, a derivative of macrofiber-producing strain FJ7, carries the lacZ reporter gene within Tn917 at an unknown location in the host genome. Expression of the host gene carrying lacZ within colonies of 5:7 was observed by examining growth under different conditions in the presence of 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal). At a high plating density small colonies arose that expressed the host gene early and throughout the colony, whereas at a low density large colonies were produced that expressed the host gene late in development and only in cells forming a ring pattern close to the colony periphery. A highly regulated spatial and temporal gene expression pattern was observed in growth from cross-streaks, suggesting that gene expression is responsive to concentration gradient fields established by neighboring growth. Colonies cultured on agar blocks revealed that expression was governed by depletion of a medium component and also by the geometry of the substrate upon which the colonies grew. At least three factors influenced the control of expression: (i) the concentration of a diffusible component of the medium exhausted by cell growth, (ii) a spatial-temporal factor related to growth within the colony, and (iii) the geometry of the growth substrate.     

The influence of host DNA replication on the formation of infectious and transducing Mu-particles

Summary We have investigated the influence of bacterial DNA replication on the formation of infectious and transducing Mu-particles.The data obtained agree with the previous findings that growth of phage Mu is independent of the host dnaA gene product (Toussaint and Faelen 1974), but requires bacterial replication forks (Fitts and Taylor 1980). The replication of transducting DNA during phage development (Teifel and Schmieger 1979) is controlled by the host and is not a precondition for its packaging. Packaging of transducing DNA does not require a nearby Mu genome.     

Regulation of bacteriophage Mu transposition

Bacteriophage Mu is a transposon and a temperate phage which has become a paradigm for the study of the molecular mechanism of transposition. As a prophage, Mu has also been used to study some aspects of the influence of the host cell growth phase on the regulation of transposition. Through the years several host proteins have been identified which play a key role in the replication of the Mu genome by successive rounds of replicative transposition as well as in the maintenance of the repressed prophage state. In this review we have attempted to summarize all these findings with the purpose of emphasizing the benefit the virus and the host cell can gain from those phage-host interactions.