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.     

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.     

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.     

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.     

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.     

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.     

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.     

Characterisation of an IS1 induced mutation in the carboxy-terminal end of bacteriophage Mu transposase which affects several functional domains of the protein

We show that a mutation in bacteriophage Mu transposase (pA) which was isolated as a deletion of the C-terminal end of the protein actually consists of the replacement of the last 16 amino acids (which are mostly hydrophilic) by 26 mostly hydrophobic amino acids. This change almost completely inactivates the in vivo enzyme activity as well as its capacity to bind Mu ends in vitro, although the end-binding domain of the protein resides at least 150 amino acids from the C-terminus. This sharply contrasts with the properties of a series of missense mutations and short C-terminal deletions in pA described earlier which only slightly decrease the overall transposase activity.     

ClpX protein of Escherichia coli activates bacteriophage Mu transposase in the strand transfer complex for initiation of Mu DNA synthesis.

During transposition bacteriophage Mu transposase (MuA) catalyzes the transfer of a DNA strand at each Mu end to target DNA and then remains tightly bound to the Mu ends. Initiation of Mu DNA replication on the resulting strand transfer complex (STC1) requires specific host replication proteins and host factors from two partially purified enzyme fractions designated Mu replication factors alpha and beta (MRFalpha and beta). Escherichia coli ClpX protein, a molecular chaperone, is a component required for MRFalpha activity, which removes MuA from DNA for the establishment of a Mu replication fork. ClpX protein alters the conformation of DNA-bound MuA and converts STC1 to a less stable form (STC2). One or more additional components of MRFalpha (MRFalpha2) displace MuA from STC2 to form a nucleoprotein complex (STC3), that requires the specific replication proteins and MRFbeta for Mu DNA synthesis. MuA present in STC2 is essential for its conversion to STC3. If MuA is removed from STC2, Mu DNA synthesis no longer requires MRFalpha2, MRFbeta and the specific replication proteins. These results indicate that ClpX protein activates MuA in STC1 so that it can recruit crucial host factors needed to initiate Mu DNA synthesis by specific replication enzymes.     

Cloning of the A gene of bacteriophage Mu and purification of its product, the Mu transposase

The bacteriophage Mu transposase (the Mu A gene product), which is absolutely required for both integration of Mu and replicative transposition during the lytic cycle, has been overproduced by cloning the gene on a plasmid under the control of the phage lambda PL promoter. The protein has been purified to near homogeneity from the lysate of heat-induced cells of a strain carrying the plasmid. The purified protein is active as judged by its ability to complement Mu A- cell extracts for supporting Mu transposition in a cell-free reaction.     

Structural polypeptides and products of late genes of bacteriophage Mu: Characterization and functional aspects

This paper describes the identification and functional role of late gene products of bacteriophage Mu, including an analysis of the structural proteins of the Mu virion.In vitro reconstitution of infectious phage particles has shown that four genes (E, D, I, J) control the formation of phage heads and that a cluster of eight genes (K, L, M, N, P, Q, R, S) controls the formation of phage tails.Sodium dodecyl sulphate/polyacrylamide gel electrophoresis of Mu polypeptides synthesized in Escherichia coli minicells infected by Mu phages carrying amber mutations in various late genes has resulted in the identification of the products of gene C (15.5 × 10³M_r); H (64 × 10³M_r); F (54 × 10³M_r); G (16 × 10³M_r); L (55 × 10³M_r); N (60 × 10³M_r); P (43 × 10³M_r) and S (56 × 10³M_r). Minicells infected with λpMu hybrid phages and deletion mutants of Mu were used to identify polypeptides encoded by the V-β region of the Mu genome. These are the products of genes V, W or R (41.5 × 10³M_r, and 45 × 10³M_r); U (20.5 × 10³M_r) and of genes located in the β region (24 × 10³M_r (gpgin) and 37 × 10³M_r (possibly gpmom)).Analytical separation of the proteins of the Mu virion revealed that it consists of a major head polypeptide with a molecular weight of 33 × 10³, a second head polypeptide of 54 × 10³ (gpF) and two major tail polypeptides with molecular weights of 55 × 10³ and 12.5 × 10³ (gpL and gpY, respectively). In addition, there are five minor components of the tail (including gpN, gpS and gpU) and approximately seven minor components of the head structure of the virion (including gpH).     

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.     

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.     

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.     

Remodeling protein complexes: insights from the AAA+ unfoldase ClpX and Mu transposase

Multiprotein complexes in the cell are dynamic entities that are constantly undergoing changes in subunit composition and conformation to carry out their functions. The protein-DNA complex that promotes recombination of the bacteriophage Mu is a prime example of a complex that must undergo specific changes to carry out its function. The Clp/Hsp100 family of AAA+ ATPases plays a critical role in mediating such changes. The Clp/Hsp100 unfolding enzymes have been extensively studied for the roles they play in protein degradation. However, degradation is not the only fate for proteins that come in contact with the ATP-dependent unfolding enzymes. The Clp/Hsp100 enzymes induce structural changes in their substrates. These structural changes, which we refer to as "remodeling", ultimately change the biological activity of the substrate. These biological changes include activation, inactivation (not associated with degradation), and relocation within the cell. Analysis of the interaction between Escherichia coli ClpX unfoldase and the Mu recombination complex, has provided molecular insight into the mechanisms of protein remodeling. We discuss the key mechanistic features of the remodeling reactions promoted by ClpX and possible implications of these findings for other biological reactions.     

The Mu transposase interwraps distant DNA sites within a functional transpososome in the absence of DNA supercoiling

A Mu transpososome assembled on negatively supercoiled DNA traps five supercoils by intertwining the left (L) and right (R) ends of Mu with an enhancer element (E). To investigate the contribution of DNA supercoiling to this elaborate synapse in which E and L cross once, E and R twice, and L and R twice, we have analyzed DNA crossings in a transpososome assembled on nicked substrates under conditions that bypass the supercoiling requirement for transposition. We find that the transposase MuA can recreate an essentially similar topology on nicked substrates, interwrapping both E-R and L-R twice but being unable to generate the single E-L crossing. In addition, we deduce that the functional MuA tetramer must contribute to three of the four observed crossings and, thus, to restraining the enhancer within the complex. We discuss the contribution of both MuA and DNA supercoiling to the 5-noded Mu synapse built at the 3-way junction.     

Structure-function relationships in the transposition protein B of bacteriophage Mu

The B-protein of phage Mu, which is required for high frequency intermolecular transposition in vivo, shows ATPase activity in vitro, binds nonspecifically to DNA, and stimulates intermolecular strand transfer. To elucidate the structural bases for B-protein function, it was subjected to limited proteolysis with two different proteases, trypsin and chymotrypsin. The resulting fragments were mapped by amino acid sequencing. These data show that the B-protein is organized in two domains: an amino-terminal domain of 25 kDa and a carboxyl-terminal domain of 8-kDa. A fragment analogous to the amino-terminal domain, produced by deleting the 3' end of a cloned B gene, proved to be insoluble and had to be renatured after elution from a sodium dodecyl sulfate gel. The renatured protein retains ATP-binding activity and to a lesser extent the DNA-binding activity of the MuB protein, but is unable to hydrolyze ATP or function in transposition. We also show in this study that efficient DNA-strand transfer by the B-protein occurs even in the absence of a detectable ATPase activity or in the presence of adenosine 5'-O-(thio)triphosphate (ATP gamma S).     

Multidimensional analysis of intracellular bacteriophage T7 DNA: effects of amber mutations in genes 3 and 19.

By use of rate-zonal centrifugation, followed by either one- or two-dimensional agarose gel electrophoresis, the forms of intracellular bacteriophage T7 DNA produced by replication, recombination, and packaging have been analyzed. Previous studies had shown that at least some intracellular DNA with sedimentation coefficients between 32S (the S value of mature T7 DNA) and 100S is concatemeric, i.e., linear and longer than mature T7 DNA. The analysis presented here confirmed that most of this DNA is linear, but also revealed a significant amount of circular DNA. The data suggest that these circles are produced during DNA packaging. It is proposed that circles are produced after a capsid has bound two sequential genomes in a concatemer. The size distribution of the linear, concatemeric DNA had peaks at the positions of dimeric and trimeric concatemers. Restriction endonuclease analysis revealed that most of the mature T7 DNA subunits of concatemers were joined left end to right end. However, these data also suggest that a comparatively small amount of left-end to left-end joining occurs, possibly by blunt-end ligation. A replicating form of T7 DNA that had an S value greater than 100 (100S+ DNA) was also found to contain concatemers. However, some of the 100S+ DNA, probably the most branched component, remained associated with the origin after agarose gel electrophoresis. It has been found that T7 protein 19, known to be required for DNA packaging, was also required to prevent loss, probably by nucleolytic degradation, of the right end of all forms of intracellular T7 DNA. T7 gene 3 endonuclease, whose activity is required for both recombination of T7 DNA and degradation of host DNA, was required for the formation of the 32S to 100S molecules that behaved as concatemers during gel electrophoresis. In the absence of gene 3 endonuclease, the primary accumulation product was origin-associated 100S+ DNA with properties that suggest the accumulation of branches, primarily at the left end of mature DNA subunits within the 100S+ DNA.