The cis-acting DNA sequences required in vivo for bacteriophage Mu helper-mediated transposition and packaging

The 37,000 bp double-stranded DNA genome of bacteriophage Mu behaves as a plaque-forming transposable element of Escherichia coli. We have defined the cis-acting DNA sequences required in vivo for transposition and packaging of the viral genome by monitoring the transposition and maturation of Mu DNA-containing pSC101 and pBR322 plasmids with an induced helper Mu prophage to provide the trans-acting functions. We found that nucleotides 1 to 54 of the Mu left end define an essential domain for transposition, and that sequences between nucleotides 126 and 203, and between 203 and 1,699, define two auxiliary domains that stimulate transposition in vivo. At the right extremity, the essential sequences for transposition require not more than the first 62 base pairs (bp), although the presence of sequences between 63 and 117 bp from the right end increases the transposition frequency about 15-fold in our system. Finally, we have delineated the pac recognition site for DNA maturation to nucleotides 32 to 54 of the Mu left end which reside inside of the first transposase binding site (L1) located between nucleotides 1–30. Thus, the transposase binding site and packaging domains of bacteriophage Mu DNA can be separated into two well-defined regions which do not appear to overlap.Abbreviations attL attachment site left - attR attachment site right - bp base pairs - Kb kilobase pair - nt nucleotide - Pu Purine - Py pyrimidine - Tn transposable element State University of New York, Downstate Medical Center, Brooklyn, NY 11204 USA     

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.     

Recombinant fusion proteins TAT-Mu, Mu and Mu-Mu mediate efficient non-viral gene delivery

BACKGROUND: The inherent ability of certain peptides or proteins of viral, prokaryotic and eukaryotic origin to bind DNA was used to generate novel peptide-based DNA delivery protocols. We have developed a recombinant approach to make fusion proteins with motifs for DNA-binding ability, Mu and membrane transduction domains, TAT, and tested them for their DNA-binding, uptake and transfection efficiencies. In one of the constructs, the recombinant plasmid was designed to encode the Mu moiety of sequence MRRAHHRRRRASHRRMRGG in-frame with TAT of sequence YGRKKRRQRRR to generate TAT-Mu, while the other two constructs, Mu and Mu-Mu, harbor a single copy or two copies of the Mu moiety. METHODS: Recombinant his-tag fusion proteins TAT-Mu, Mu and Mu-Mu were purified by overexpression of plasmid constructs using cobalt-based affinity resins. The peptides were characterized for their size and interaction with DNA, complexed with plasmid pCMVbeta-gal, and shown to transfect MCF-7, COS and CHOK-1 cells efficiently. RESULTS: Recombinant fusion proteins TAT-Mu, Mu and Mu-Mu were cloned and overexpressed in BL21(DE3)pLysS with greater than 95% purity. The molecular weight of TAT-Mu was determined by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) to be 11.34 kDa while those of Mu and Mu-Mu were 7.78 and 9.83 kDa, respectively. Live uptake analysis of TAT-Mu, Mu and Mu-Mu as DP (DNA+peptide) or DPL (DNA+peptide+lipid) complexes into MCF-7 cells, followed by immunostaining and laser scanning confocal microscopy, demonstrated that the complexes are internalized very efficiently and localized in the nucleus. DNA:peptide complexes (DP) transfect MCF-7, COS and CHOK-1 cells. The addition of cationic liposomes enhances the uptake of the ternary complexes (DPL) further and also brings about 3-7-fold enhancement in reporter gene expression compared to DP alone. CONCLUSIONS: Recombinant proteins that are heterologous fusions, having DNA-binding domains and nuclear localization epitopes, generated in this study have considerable potential to facilitate DNA delivery and enhance transfection. The domains in these fusion proteins would be promising in the development of non-viral gene delivery vectors particularly in cells that do not divide.     

Regulation and expression of the bacteriophage mu mom gene: mapping of the transactivation (dad) function to the C region

Expression of the bacteriophage Mu mom gene is under tight regulatory control. One of the factors required for mom gene expression is the trans-acting function (designated Dad) provided by another Mu gene. To facilitate studies on the signals mediating mom regulation, we have constructed a mom-lacZ fusion plasmid which synthesizes beta-galactosidase only when the Mu Dad transactivating function is provided. lambda pMu phages carrying different segments of the Mu genome have been assayed for their ability to transactivate beta-galactosidase expression by the fusion plasmid. The results of these analyses indicated that the Dad transactivation function is encoded between the leftmost EcoRI site and the lys gene of Mu; this region includes the C gene, which is required for expression of all Mu late genes. Cloning of an approx. 800-bp fragment containing the C gene produced a plasmid which could complement MuC- phages for growth and could transactivate the mom-lacZ fusion plasmid to produce beta-galactosidase. These results suggest that the C gene product mediates the Dad transactivation function.     

Long-range correlations in prokaryotic chromosomes

One of the fascinating properties of the DNA sequences of prokaryotic and eukaryotic chromosomes is that they possess long-range order. Computational methods like spectral analysis, mutual information and DNA random walks have been used to probe long-range order via-long range correlations. This work attempts to show the advantage of using the Information Theoretic measure of mutual information for this purpose. A number Mu is found which indicates the existence of long-range order. Mu is the ratio between the value of mutual information function between two nucleotides of a DNA sequence separated by a large distance of 100 kilobases to the value expected from a randomized sequence of the same DNA. It is found that in spite of the constant shuffling of nucleotides due to insertion, deletion, inversion and recombination that occur during evolution, the chromosomal structure of prokaryotes is not always mosaic. While all archaeal chromosomes show mosaic structure and lack long-range order, a sizable fraction of the bacterial chromosomes do possess long-range order. A statistical multivariate analysis has been done to find which of the physical variables like genome size or GC% affects the organization of the chromosome or correlates with the long-range order. The existence of long-range order in bacterial chromosomes could be directly correlated to the degree of gene strand bias shown by it. Firmicutes which have low GC content also have pronounced strand bias and show long-range correlations. It is observed that the occurrence of long-range order in bacteria is independent of genome size, but depends on its GC content and gene strand bias.     

Evolution of the long range structure of satellite DNAs in the genus Apodemus.

The temperate bacteriophage Mu causes mutations by inserting its DNA randomly into the genes of its host bacterium Escherichia coli. It is shown here that Mu DNA can be precisely excised from the different integration sites and that as a result wild-type function of the gene into which Mu was inserted is restored. The excision of Mu DNA is observable only if the Mu prophage carries mutations at the X locus. Thus, lac⁺ revertants from six strains, containing heat-inducible prophage Mu cts62 at different locations in the Z gene of the lac operon, were readily obtained by first introducing the X mutation into Mu cts62. The lac⁺ revertants produced wild-type β-galactosidase, and no trace of Mu DNA could be detected in them; this indicates that the junction of Mu DNA and host DNA can be specifically recognized. However, the excision of Mu DNA is generally not perfect, because in most cases it does not lead to the wild-type genotype. The function of gene A of Mu appears to be required for excision. Since the lethal functions of Mu are completely blocked in the Mu cts62 X prophage, the X locus probably has a regulatory function. At least one X mutation is caused by an insertion of about 900 base-pairs in Mu DNA. The discovery of the X mutants opens the way for studying the reversible interaction of the host and Mu chromosomes, and for using Mu to manipulate the host genome in various ways.     

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.     

Comparison of left-end DNA sequences of bacteriophages Mu and D108

The nucleotide sequences of the left ends of bacteriophage Mu DNA and that of its close relative D108 have been determined. The first 100 bp of phages Mu and D108 are substantially the same except for an octanucleotide change from bp 53 to 61 and other small interspersed base-pair changes from bp 61 to 200. The first five host nucleotides preceding the host-phage junction are generally, but not always, G + C-rich and these five nucleotides display no obvious consensus sequence. Both phages Mu and D108 share striking similarity in their end DNA sequences to the end sequences of the newly described Escherichia coli movable genetic element IS30.     

Cloning and biological characterization of the immunity region of Escherichia coli phage Mu.

The construction of three hybrid plasmids containing different parts of the left or immunity and end of phage Mu DNA is described. The recombinant plasmids pKN05 and pKN54 carry the HindIII.C and PstI.C fragments of Mu DNA, respectively. Neither of these plasmids expresses the killing function. Moreover, they do not allow plating of superinfecting Mu phages. Plasmid pKN62 harbors the fragment located in between the left PstI and EcoRI cleavage sites on Mu DNA, allows plating of superinfecting Mu phages, but does not express the killing function. These data suggest that the gene coding for the killing function is either positively regulated by a product from the EcoRI.C fragment, or the killing function requires a second product not coded for by pKN62. Mu Vir A- or Mu Vir B- phages are able to grow on bacteria harboring the recombinant plasmid pKN001 which carries the left and EcoRI-C fragment of Mu DNA. This indicates that the superinfecting phages can induce the corresponding gene functions from pKN001. No such induction could be detected in cells harboring the hybrid plasmids pKN05, pKN54 or pKN62.     

Differential activity of a transposable element in Escherichia coli colonies.

In Escherichia coli colonies, patterns of differential gene expression can be visualized by the use of Mu d(lac) fusion elements. Here we report that patterned beta-galactosidase expression in colonies of strain MS1534 resulted from a novel mechanism, spatially localized replication of the Mu dII1681 element causing lacZ transposition to active expression sites. Mu dII1681 replication did not occur constitutively with a fixed probability but was dependent on the growth history of the bacterial population. The bacteria in which Mu dII1681 replication and lacZ transposition had occurred could no longer form colonies. These results lead to several interesting conclusions about cellular differentiation during colony development and the influence of bacterial growth history on gene expression and genetic change.     

Fusions of the lac operon to the transfer RNA gene tyrT of Escherichia coli.

The tyrT gene codes for one of the tyrosirie tRNA species. Using the Casadabatn (1976a) technique, strains of Escherichia coli were isolated in which the lac structural genes are fused to the promoter of the tyrT gene. This procedure involved obtaining a number of insertions of phage Mu DNA in the tyrT gene, lysogenizing the Mu insertion strains with a λplac-Mu hybrid phage, and selecting Lac⁺ derivatives of such lysogens. In a number of Lac⁺ strains thus obtained, the synthesis of β-galactosidase, the product of the lacZ gene, is regulated in a similar fashion to the synthesis of stable RNA. The fusion strains were shown directly to be tyrT-lac fusions by demonstrating that a Mu insertion in the tyrT gene when genetically recombined into the presumed fusion, inactivates the expression of the lac genes. This result shows that tyrT gene sequences are fused to and control the expression of the lac genes in these strains. This is the first report in which genes which code for proteins have been fused to a stable RNA gene in vivo.     

Progressive structural transitions within Mu transpositional complexes

Assembly of the Mu transpososome is dependent on specific binding sites for the MuA transposase near the ends of the phage genome. MuA also contacts terminal nucleotides but only upon transpososome assembly, and base-specific recognition of the terminal nucleotides is critical for assembly. We show that Mu ends lacking the terminal 5 bp can form transpososomes, while longer DNA substrates with mutated terminal nucleotides cannot. The impact of the mutations can be suppressed by base mismatches near the end of Mu. Deletion of the flanking strands or mutation of the terminal nucleotides has differential effects on the cleavage and strand transfer reactions. These results show that the terminal nucleotides control the assembly and activation of transpososomes by influencing conformational changes around the active site.     

Bacteriophage Mu DNA replication in vitro

An in vitro system for bacteriophage Mu DNA replication using lysates on cellophane discs is described. Mu replication was monitored by DNA hybridization. Using a thermoinducible Mu lysogen, 30-50% of all DNA synthesis in vitro was Mu-specific. Mu DNA synthesis is semidiscontinuous. In the presence of the DNA ligase inhibitor NMN, about one-half of the DNA was in Okazaki pieces and one-half in large DNA. The Mu Okazaki pieces hybridized mainly to the Mu light strand; the large DNA hybridized mainly to the Mu heavy strand. Okazaki pieces isolated from uninfected cells also hybridized to 2000-3000 bases of host DNA present in Mu-separated strands. However, the host Okazaki pieces hybridize to both Mu strands symmetrically. Most, if not all, host sequences were represented in mature Mu viral DNA. The in vitro data are most consistent with models in which Mu sequences, oriented randomly in both directions in the host chromosome, have recruited a bacterial replisome which traverses the Mu genome from left to right.     

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.     

DNA Rearrangements Associated with Reversion of Bacteriophage Mu-Induced Mutations

Excision of transposable genetic elements from host DNA is different from the classical prophage lambda type of excision in that it occurs at low frequency and is mostly imprecise; only a minority of excision events restores the wild-type host sequences. In bacteriophage Mu, a highly efficient transposon, imprecise excision is 10-100 times more frequent than precise excision. We have examined a large number of these excision events by starting with mucts X mutants located in the Z gene of the lac operon of Escherichia coli. Mucts X mutants are defective prophages whose excision occurs at a measurable frequency. Imprecise excision was monitored by selecting for melibiose+ (Mel+) phenotype, which requires only a functioning lacY gene. Mel+ revertants exhibit an array of DNA rearrangements and fall in four main classes, the predominant one being comprised of revertants that have no detectable Mu DNA. Most of these revertants can further revert to Lac+. Perhaps 5 base-pair duplications, originally present at prophage-host junctions, are left in these lacZ-Y+ revertants, and they can be further repaired to lacZ+. Another class has, in addition to the loss of Mu DNA, deletions that extend generally, but not always, to only one side of the prophage. The other two classes of revertants, surprisingly, still have Mu DNA in the lacZ gene. One class has deletions in the Z gene, whereas, no deletions can be detected in the other. Many of the revertants in the last class can further revert to lacZ+, indicating that the lacY gene must have been turned on by a rearrangement within Mu DNA. Apparently, all of the detectable precise and most of the imprecise excision events require functioning of the Mu A gene. We suggest that a block in large-scale Mu replication allows the excision process to proceed.