Transfection with Mu-DNA

Rec dependence of mu transposition from P22-transduced fragments

Derivatives of bacteriophage Mu carrying a lac operon and a selectable drug resistance element (Mu d phages) are frequently used tools of bacterial genetics. Mu d prophages used in this way can be treated as transposons, in that the inserted material can be transduced from one strain to another by general transducing phages, such as P1 and P22. When a Mu d prophage is transduced into a new recipient by P1 or P22, the Mu d element can transpose from the transduced fragment into the bacterial chromosome. Transposition of the Mu d element from a P22-transduced fragment shows several striking differences from transposition of a Mu d genome injected by a Mu virion. First, the frequency of transposition from a transduced fragment is greatly enhanced by a P22 helper genome. Second, transposition requires the host recA, B, and C functions. Transposition of Mu following injection by a Mu virion is rec independent. While the basis of these observations is not understood, we suggest that the Mu X protein, a 65-kilodalton protein injected by a Mu virion and required for Mu transposition, may not be packaged by P22. We suggest that the effects seen reflect the behavior of a Mu genome in the absence of the X protein.

Purification of the gam gene-product of bacteriophage Mu and determination of the nucleotide sequence of the gam gene

The gam gene of bacteriophage Mu encodes a protein which protects linear double stranded DNA from exonuclease degradation in vitro and in vivo. We purified the Mu gam gene product to apparent homogeneity from cells in which it is over-produced from a plasmid clone. The purified protein is a dimer of identical subunits of 18.9 kd. It can aggregate DNA into large, rapidly sedimenting complexes and is a potent exonuclease inhibitor when bound to DNA. The N-terminal amino acid sequence of the purified protein was determined by automated degradation and the nucleotide sequence of the Mu gam gene is presented to accurately map its position in the Mu genome.

Mutants of Escherichia coli defective for replicative transposition of bacteriophage Mu

We isolated 142 Hir- (host inhibition of replication) mutants of an Escherichia coli K-12 Mu cts Kil- lysogen that survived heat induction and the killing effect of Mu replicative transposition. All the 86 mutations induced by insertion of Tn5 or a kanamycin-resistant derivative of Tn10 and approximately one-third of the spontaneous mutations were found by P1 transduction to be linked to either zdh-201::Tn10 or Tn10-1230, indicating their location in or near himA or hip, respectively. For a representative group of these mutations, complementation by a plasmid carrying the himA+ gene or by a lambda hip+ transducing phage confirmed their identification as himA or hip mutations, respectively. Some of the remaining spontaneously occurring mutations were located in gyrA or gyrB, the genes encoding DNA gyrase. Mutations in gyrA were identified by P1 linkage to zei::Tn10 and a Nalr gyrA allele; those in gyrB were defined by linkage to tna::Tn10 and to a gyrB(Ts) allele. In strains carrying these gyrA or gyrB mutations, pBR322 plasmid DNA exhibited altered levels of supercoiling. The extent of growth of Mu cts differed in the various gyrase mutants tested. Phage production in one gyrA mutant was severely reduced, but it was only delayed and slightly reduced in other gyrA and gyrB mutants. In contrast, growth of a Kil- Mu was greatly reduced in all gyrase mutant hosts tested.

Localization of the gam gene of bacteriophage mu and characterisation of the gene product

Using cloning techniques in conjunction with an in vitro assay for activity of the gam-coded protein (pgam), the gam gene has been located on a 930-bp fragment immediately to the right of an AccI site situated 5.75 kb from the left-hand end of the phage Mu genome. An analysis of the properties of pgam obtained from an overproducing clone indicates that it is a non-specific DNA-binding protein which interacts with linear duplex plasmid DNA having a variety of different termini and confers protection against exonuclease action (Gam function). It also stimulates the frequency with which linear plasmid DNA transforms Escherichia coli to antibiotic resistance (Sot function). The preliminary results reported here suggest that pgam is potentially a useful 'tool' in molecular biology, although the molecular details of pgam activity require further clarification.

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.

Infecting bacteriophage mu DNA forms a circular DNA-protein complex

Upon superinfection of immune (lysogenic) cells with bacteriophage Mu, a form of Mu DNA accumulates that sediments about twice as fast as the linear phage DNA marker in neutral sucrose gradients. This form is also detected upon infection of sensitive cells with Mu. We have purified it and examined its physical nature. Under the electron microscope it appears circular and supertwisted. Upon treatment with Pronase, phenol or sodium dodecyl sulfate, however, it is converted to a linear Mu-length form, indicating that the circle is not covalently closed. The linear DNA still has heterogeneous host sequences at its termini. The circular DNA is resistant to the action of Escherichia coli exonuclease III and T7 exonuclease, but becomes sensitive to these nucleases after treatment with Pronase showing the presence of a protein that binds non-covalently to the ends of the DNA to circularize it as well as protect it from digestion with exonucleases. The complex is resistant to high salt (up to 6 M-NaCl) but can undergo transitions between forms that are partially open, open circular, linear and circular dimers and trimers. Examination of DNA from mature phage particles reveals that a circular DNA species is present in at least 0.1 to 1% of the population. The purified complex is extremely efficient in transfection of E. coli spheroplasts. We estimate the molecular weight of the protein in this DNA-protein complex to be approximately 64,000, and suggest that this complex might represent the integrative precursor of infecting Mu DNA.

Evidence for a conservative pathway of transposition of bacteriophage Mu

During its lytic cycle bacteriophage Mu uses repeated transposition as a mode of DNA synthesis. These transpositional events are undoubtedly replicative, and presumably semi-conservative. In a Mu lysogen this type of transposition can start immediately after prophage induction. However, in an infective cycle the Mu genome (which is injected into the host cell as a linear molecule flanked by short random sequences of bacterial DNA) must first become integrated into the host chromosome. Little is known about how this occurs apart from the fact that the bacterial sequences at either end of the Mu genome are lost in the process. The integration is thus similar to a transposition event. In an attempt to determine whether this type of Mu transposition (between a linear donor molecule and a circular recipient) is also semi-conservative we have analysed the progeny phage arising from an infective cycle in which the parental DNA was heterozygous for a known genetic marker. The expectation is that if integration of the infecting Mu genome occurs by a single semi-conservative transpositional event then pure phage bursts should be produced as the genetic information on only one strand would be preserved throughout the lytic cycle. The experiments reported here do not support this expectation in that the infected cells yield mixed bursts, suggesting that Mu integration is a conservative, rather than a semi-conservative event.

Bacteriophage Mu DNA replication is stimulated by non-essential early functions

The replication of a spontaneous Kil- mutant of bacteriophage Mu has been investigated. The Kil- mutation (Mucts62-13/4), which was introduced into a defective prophage, is pleiotrophic, leading to the loss of also the Gam, Cim and Sot functions. The mutation is caused by an insertion with the characteristics of IS1, located just outside the B gene. Mucts62-1 3/4 phages form extremely small plaques on wildtype indicator strains. The replication of the insertion mutant as compared to Mucts62 is strongly reduced. Normal replication could be restored by relieving the polarity of the insertion or by complementation with defective prophages which express all early functions. Apparently, early genes other than A and B are involved in normal Mu DNA replication.

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.

Partial purification and properties of an exonuclease inhibitor induced by bacteriophage Mu-1

From an induced lysogen of bacteriophage Mu-1, we partially purified a substance of high molecular weight that blocks the action of several exonucleases on double-stranded DNA. The presence of the inhibitor in cell-free extracts is dependent on induction of a Mu prophage. The Mu-related inhibitor acts by binding to double-stranded DNA rather than by interacting with the DNase. The inhibitor protects linear duplex DNA of Mu, P22, and phi X174am3 from exonucleolytic degradation by recBC DNase and lambda exonuclease. Single-stranded DNA, however, is not protected by the inhibitor from degradation by either recBC DNase or exonuclease I. The inhibitor preparation contains a protein that binds to linear duplex DNA, but not to circular duplex DNA; ends are required for binding to occur. Single-stranded DNA is not a substrate for the binding protein. These and other results suggest that the binding protein and the inhibitor are the same activity.

Transcription of bacteriophage Mu. II. Transcription of the repressor gene

Using pBR322 as a vector, three plasmids were constructed, pGP2, pGP3, and pGP7, containing respectively 5, 100, 700-950, and 1,000 base pairs derived from the immunity end of bacteriophage Mu. All three plasmids contain a functional repressor gene coding for a thermosensitive repressor. RNAs produced when the DNA of these plasmids was used as template in in vitro RNA synthesis, were analysed by hybridization to the DNA of several lambda pMu transducing phages. In spite of the differences in length of the Mu fragments all three plasmids show the same amount of Mu specific l-strand transcription. Since the repressor gene comprises at least 70% of the Mu fragments of pGP3 and pGP7, these results indicate that the repressor gene c of bacteriophage Mu is transcribed on the l-strand. Analysis of in vivo RNA from cells harboring the plasmids pGP2, pGP3, or pGP7 also indicates that the repressor gene of phage Mu is transcribed on the l-strand, as all Mu-specific RNA extracted from these cells at 28 degrees C hybridizes with the l-strand of the first 3,100 basepairs from the Mu immunity end.

Thermo-inducible expression of cloned early genes of bacteriophage Mu

An EcoRI fragment, containing approx. 5100 base pairs (bp) of the immunity-end of bacteriophage Mu, was inserted into the multicopy plasmid pMB9 by in vitro recombination. The expression of early Mu genes, located on the cloned fragment, is thermo-inducible because of the presence of the ts mutation in gene c. The isolation of a transformant harbouring the recombinant plasmid, pGP1, was possible only when expression of Mu genes was prevented. pGP1 can be maintained at 28 degrees C at high copy number, but at 42 degrees C the pGP1 containing cells are killed due to the expression of the kil gene of Mu. The following Mu genes are present on pGP1: the ner gene, the integration and replication genes A and B, the cim gene, and the kil gene. pGP1 containing cells do not show Gam and Sot activity at 42 degrees C, therefore the leftmost EcoRI site on the Mu DNA is located between genes kil and gam or sot, or within the gam or sot gene.