Instability of bacteriophage Mu transposase and the role of host Hfl protein

The activity of the transposase of bacteriophage Mu is unstable, requiring the protein to be synthesized throughout the lytic cycle (Pato and Reich, 1982). Using Western blot analysis, we analysed the stability of the transposase protein during the lytic cycle and found that it, too, is unstable. The instability of the protein is observed both in the presence and the absence of Mu DNA replication, and is independent of other Mu-encoded proteins and the transposase binding sites at the Mu genome ends. Stability of the protein is enhanced in host strains mutated at the hfl locus; however, stability of the transposase activity is not enhanced in these strains, suggesting that functional inactivation of the protein is not simply a result of its proteolysis.     

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.     

Effect of mutations in the C-terminal domain of Mu B on DNA binding and interactions with Mu A transposase

Bacteriophage Mu transposition requires two phage-encoded proteins, the transposase, Mu A, and an accessory protein, Mu B. Mu B is an ATP-dependent DNA-binding protein that is required for target capture and target immunity and is an allosteric activator of transpososome function. The recent NMR structure of the C-terminal domain of Mu B (Mu B223-312) revealed that there is a patch of positively charged residues on the solvent-exposed surface. This patch may be responsible for the nonspecific DNA binding activity displayed by the purified Mu B223-312 peptide. We show that mutations of three lysine residues within this patch completely abolish nonspecific DNA binding of the C-terminal peptide (Mu B223- 312). To determine how this DNA binding activity affects transposition we mutated these lysine residues in the full-length protein. The full-length protein carrying all three mutations was deficient in both strand transfer and allosteric activation of transpososome function but retained ATPase activity. Peptide binding studies also revealed that this patch of basic residues within the C-terminal domain of Mu B is within a region of the protein that interacts directly with Mu A. Thus, we conclude that this protein segment contributes to both DNA binding and protein-protein contacts with the Mu transposase.     

Characterization of amber mutations in bacteriophage Mu transposase: a functional analysis of the protein

We have characterized a series of amber mutations in the A gene of bacteriophage Mu encoding the phage transposase. We tested different activities of these mutant proteins either in a sup0 strain or in different sup bacteria. In conjunction with the results described in the accompanying paper by Bétermier et al. (1989) we find that the C-terminus of the protein is not absolutely essential for global transposase function, but is essential for phage growth. Specific binding to Mu ends is defined by a more central domain. Our results also reinforce the previous findings (Bétermier et al., 1987) that more than one protein may be specified by the A gene.     

Mutational analysis of the att DNA-binding domain of phage Mu transposase.

The transposase (A protein) of phage Mu encodes binding to two families of DNA sites, att sites located at the Mu ends and enhancer sites located internally. Separate subdomains in the N-terminal domain I of Mu A protein are known to be involved in recognition of the att and enhancer sites. We have delineated an approximately 135 aa region within domain I beta gamma that specifies binding to Mu att sites. This peptide was overexpressed and its properties compared with that of the larger domain I beta gamma as well as the intact Mu A protein. Extensive mutagenesis of residues around a putative helix-turn-helix DNA-binding motif within the I beta domain identified several mutants defective in DNA transposition in vivo. Of these, Mu A(K157Q) was completely defective in att DNA-binding. Mu A(F131S) and Mu A(R146N) had a lower affinity for att DNA and low levels of transposition in vitro. Our results indicate that residues in the gamma region are required for activity and that residues outside the beta gamma region must also influence discrimination between the multiple att sites.     

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.     

The bacteriophage Mu transposase protein can form high-affinity protein-DNA complexes with the ends of transposable elements of the Tn 3 family

The 37 kb transposable bacteriophage Mu genome encodes a transposase protein which can recognize and bind to a consensus sequence repeated three times at each extremity of its genome. A subset of this consensus sequence (5'-PuCGAAA(A)-3') is found in the ends of many class II prokaryotic transposable elements. These elements, like phage Mu, cause 5 bp duplications at the site of element insertion, and transpose by a cointegrate mechanism. Using the band retardation assay, we have found that crude protein extracts containing overexpressed Mu transposase can form high-affinity protein-DNA complexes with Mu att R and the ends of the class II elements Tn 3 (right) and IS101. No significant protein-DNA complex formation was observed with DNA fragments containing the right end of the element IS102, or a non-specific pBR322 fragment of similar size. These results suggest that the Mu transposase protein can specifically recognize the ends of other class II transposable elements and that these elements may be evolutionarily related.     

The Escherichia coli protein, Fis: specific binding to the ends of phage Mu DNA and modulation of phage growth

We show, using gel retardation, that crude Escherichia coli cell extracts contain a protein which binds specifically to DNA fragments carrying either end of the phage Mu genome. We have identified this protein as Fis, a factor involved in several site-specific recombinational switches. Furthermore, we show that induction of a Mucts62 prophage in a fis lysogen occurs at a lower temperature than that of a wild-type strain, and that spontaneous induction of Mucts62 is increased in the fis mutant. DNasel footprinting using either crude extracts or purified Fis indicate that binding on the left end of Mu occurs at a site which overlaps a weak transposase binding site. Thus, Fis may modulate Mu growth by influencing the binding of transposase, or other proteins, to the transposase binding site(s), in a way similar to its influence on Xis binding in phage lambda.     

The phage Mu repressor c and IS30 transposase proteins are significantly related

The IS30 transposase exhibits significant amino acid sequence homology to the phage Mu repressor c in the amino- and carboxy-terminal regions of the proteins. The conserved sequences include the proposed Mu repressor DNA binding site, which is also related to the proposed Mu and D108 transposase DNA binding sites. The carboxy-terminal homologies are characterised by two almost complete, and one partial, somewhat diverged amino acid sequence repeats. Only weak homologies to this domain are present in the Mu transposase (Mu A). Nevertheless, a clear link between an insertion sequence and a bacteriophage has been established.     

Two mutations of phage mu transposase that affect strand transfer or interactions with B protein lie in distinct polypeptide domains.

Two mutations within the transposase (the A protein) gene of phage Mu with distinct effects on DNA transposition have been studied. The first mutation maps to the central domain (domain II) of A, a protein consisting of three major structural domains. The variant protein is normal in synapsis and cleavage of Mu ends but is temperature-sensitive in the strand transfer reaction, joining the Mu ends to target DNA. The second mutation is a deletion at the C terminus (within domain III); on the basis of genetic studies, the mutant protein is predicted to have lost the ability to interact with the Mu B protein. The B protein, in conjunction with A, promotes efficient intermolecular transposition, while inhibiting intramolecular transposition. We show that the purified mutant protein is proficient in intramolecular, but not intermolecular transposition in vitro. The interactions between A and B proteins have been followed by a proteolysis assay. The chymotrypsin sensitivity of the interdomainal Phe221-Ser222 peptide bond within the bidomainally organized B protein is exquisitely modulated by ATP, DNA and A protein. The sensitive or "open" state of this bond in native B protein becomes partially "open" upon binding of ATP by B, attains a "closed" or resistant configuration upon binding of DNA in presence of ATP, and is rendered "open" again upon addition of the A protein. In this test for the interaction of A protein with B protein-DNA complex, the domain II mutant behaves like wild-type A protein. However, the domain III mutant fails to restore chymotrypsin susceptibility of the Phe221-Ser222 bond.     

A novel DNA binding and nuclease activity in domain III of Mu transposase: evidence for a catalytic region involved in donor cleavage.

The Mu A protein is a 75 kDa transposase organized into three structural domains. By severing the C-terminal region (domain III) from the remainder of the protein, we unmasked a novel non-specific DNA binding and nuclease activity in this region. Deletion analysis localized both activities to a 26 amino acid stretch (aa 575-600) which remarkably remained active in DNA binding and cleavage. The two activities were shown to be tightly linked by site-directed mutagenesis. To study the importance of these activities in the transposition process, an intact mutant transposase lacking the DNA binding and nuclease activity of domain III was constructed and purified. The mutant transposase was indistinguishable from wild-type Mu A in binding affinity for both the Mu ends and the enhancer, and in strand transfer activity when the cleavage step was bypassed. In contrast, the mutant transposase displayed defects in both synapsis and donor cleavage. Our results strongly suggest that the 26 amino acid region in domain III carries catalytic residues required for donor DNA cleavage by Mu A protein. Furthermore, our data suggest that an active site for donor cleavage activity in the Mu tetramer is assembled from domain II (metal ion binding) in one A monomer and domain III (DNA cleavage) in a separate A monomer. This proposal for active site assembly is in agreement with the recently proposed domain sharing model by Yang et al. (Yang, J.Y., Kim, K., Jayaram, M. and Harshey, R.M. [1995] EMBO J., 14, 2374-2384).     

Criss-crossed interactions between the enhancer and the att sites of phage Mu during DNA transposition.

A bipartite enhancer sequence (composed of the O1 and O2 operator sites) is essential for assembly of the functional tetramer of phage Mu transposase (MuA) on supercoiled DNA substrates. A three-site interaction (LER) between the left (L) and right (R) ends of Mu (att sites) and the enhancer (E) precedes tetramer assembly. We have dissected the role of the enhancer in tetramer assembly by using two transposase proteins that have a common att site specificity, but are distinct in their enhancer specificity. The activity of these proteins on substrates containing hybrid enhancers reveals a 'criss-crossed' pattern of interaction between att and enhancer sites. The left operator, O1, of the enhancer interacts specifically with the transposase subunit at the R1 site (within the right att sequence) that is responsible for cleaving the left end of Mu. The right operator, O2, shows a preferential interaction with the transposase subunit at the L1 site (within the left att sequence) that is responsible for cleaving the right end of Mu.     

Solution structure of the Mu end DNA-binding ibeta subdomain of phage Mu transposase: modular DNA recognition by two tethered domains.

The phage Mu transposase (MuA) binds to the ends of the Mu genome during the assembly of higher order nucleoprotein complexes. We investigate the structure and function of the MuA end-binding domain (Ibetagamma). The three-dimensional solution structure of the Ibeta subdomain (residues 77-174) has been determined using multidimensional NMR spectroscopy. It comprises five alpha-helices, including a helix-turn-helix (HTH) DNA-binding motif formed by helices 3 and 4, and can be subdivided into two interacting structural elements. The structure has an elongated disc-like appearance from which protrudes the recognition helix of the HTH motif. The topology of helices 2-4 is very similar to that of helices 1-3 of the previously determined solution structure of the MuA Igamma subdomain and to that of the homeodomain family of HTH DNA-binding proteins. We show that each of the two subdomains binds to one half of the 22 bp recognition sequence, Ibeta to the more conserved Mu end distal half (beta subsite) and Igamma to the Mu end proximal half (gamma subsite) of the consensus Mu end-binding site. The complete Ibetagamma domain binds the recognition sequence with a 100- to 1000-fold higher affinity than the two subdomains independently, indicating a cooperative effect. Our results show that the Mu end DNA-binding domain of MuA has a modular organization, with each module acting on a specific part of the 22 bp binding site. Based on the present binding data and the structures of the Ibeta and Igamma subdomains, a model for the interaction of the complete Ibetagamma domain with DNA is proposed.     

Carboxyl-terminal mutants of phage Mu transposase

A study of the properties of deletion mutants at the 3’ end ofA, the gene encoding the transposase protein of phage Mu, shows that the mutants are defective in the high-frequency non-replicative transposition observed early after Mu infection as well as the high-frequency replicative transposition observed during Mu lytic growth. They show near-normal levels of lysogenization, low frequency transposition and precise excision. The mutants behave as if they are “blind” to the presence of Mu B, a protein whose function is essential for the high frequency of both replicative and non-replicative Mudna transposition. We have sequenced these deletion mutants as well as the amber mutant A 7110 which is known to be defective in replicative transposition.A 7110 maps at the 3’ end of geneA. We suggest that the carboxyl-terminal region of the A-protein is involved in protein-protein interactions, especially with the B-protein. We also show in this study that mutations upstream of the Shine-Dalgarno sequence of geneA and within the preceding genener, perturb the synthesis of A-protein and that higher levels of A-protein cause an inhibition ofA activity.     

Conformational isomerization in phage Mu transpososome assembly: effects of the transpositional enhancer and of MuB.

Initiation of phage Mu DNA transposition requires assembly of higher order protein-DNA complexes called Mu transpososomes containing the two Mu DNA ends and MuA transposase tetramer. Mu transpososome assembly is highly regulated and involves multiple DNA sites for transposase binding, including a transpositional enhancer called the internal activation sequence (IAS). In addition, a number of protein cofactors participate, including the target DNA activator MuB ATPase. We investigated the impact of the assembly cofactors on the kinetics of transpososome assembly with the aim of deciphering the reaction steps that are influenced by the cofactors. The transpositional enhancer IAS appears to have little impact on the initial pairing of the two Mu end segments bound by MuA. Instead, it accelerates the post-synaptic conformational step(s) that converts the reversible complex to the stable transpososome. The transpososome assembly stimulation by MuB does not require its stable DNA binding activity, which appears critical for directing transposition to sites distant from the donor transposon.     

DNA-protein complexes during attachment-site synapsis in Mu DNA transposition.

Initial events in Mu DNA transposition involve specific recognition of Mu DNA ends (att sites) and an internal enhancer site by the Mu transposase (A protein). This interaction between A protein and Mu DNA sequences present on a supercoiled DNA substrate leads to the formation of a stable synaptic complex in which the att ends are nicked, prior to DNA strand transfer. This study examines the properties of a synaptic complex proficient for DNA transposition. We show that the A protein binds as a monomer to its binding sites, and causes the DNA to bend through approximately 90 degrees at each site. All six att binding sites (three at each Mu end) are occupied by A within the synaptic complex. Three of these sites are loosely held and can be emptied of A upon challenge with heparin. A synaptic complex with only three sites occupied is stable and is fully competent in the subsequent strand-transfer step of transposition.     

Characterization of functionally important sites in the bacteriophage Mu transposase protein

The 663 amino acid Mu transposase protein is absolutely required for Mu DNA transposition. Mutant proteins were constructed in vitro in order to locate regions of transposase that may be important for the catalysis of DNA transposition. Deletions in the A gene, which encodes the transposase, yielded two stable mutant proteins that aid in defining the end-specific DNA-binding domain. Linker insertion mutagenesis at eight sites in the Mu A gene generated two proteins, FF6 and FF14 (resulting from two and four amino acid insertions, respectively, at position 408), which were thermolabile for DNA binding in vitro at 43°C. However, transposition activity in vivo was severely reduced for all mutant proteins at 37°C, except those with insertions at positions 328 and 624. In addition, site-specific mutagenesis was performed to alter tyrosine 414, which is situated in a region that displays amino acid homology to the active sites of a number of nicking/closing enzymes. Tyrosine 414 may reside within an important, yet non-essential, site of transposase, as an aspartate-substituted protein had a drastically reduced frequency of transposition, while the remaining mutants yielded reduced, but substantial, frequencies of Mu transposition in vivo.     

The Mu three-site synapse: a strained assembly platform in which delivery of the L1 transposase binding site triggers catalytic commitment

The Mu DNA transposition reaction proceeds through a three-site synaptic complex (LER), including the two Mu ends and the transpositional enhancer. We show that the LER contains highly stressed DNA regions in the enhancer and in the L1 transposase binding site. We propose that the L1 site acts as the keystone for assembly of a catalytically competent transpososome. Delivery of L1 through HU-mediated bending completes LER assembly, provides the trigger for necessary conformational transitions in transpososome formation, and allows target capture to occur. Relief of the stress at L1 and the enhancer may help drive Mu A tetramerization and engagement of the Mu ends by the transposase active site.     

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.