Baseplate assembly of phage Mu: Defining the conserved core components of contractile-tailed phages and related bacterial systems.

Contractile phage tails are powerful cell puncturing nanomachines that have been co-opted by bacteria for self-defense against both bacteria and eukaryotic cells. The tail of phage T4 has long served as the paradigm for understanding contractile tail-like systems despite its greater complexity compared with other contractile-tailed phages. Here, we present a detailed investigation of the assembly of a "simple" contractile-tailed phage baseplate, that of Escherichia coli phage Mu. By coexpressing various combinations of putative Mu baseplate proteins, we defined the required components of this baseplate and delineated its assembly pathway. We show that the Mu baseplate is constructed through the independent assembly of wedges that are organized around a central hub complex. The Mu wedges are comprised of only three protein subunits rather than the seven found in the equivalent structure in T4. Through extensive bioinformatic analyses, we found that homologs of the essential components of the Mu baseplate can be identified in the majority of contractile-tailed phages and prophages. No T4-like prophages were identified. The conserved simple baseplate components were also found in contractile tail-derived bacterial apparatuses, such as type VI secretion systems, Photorhabdus virulence cassettes, and R-type tailocins. Our work highlights the evolutionary connections and similarities in the biochemical behavior of phage Mu wedge components and the TssF and TssG proteins of the type VI secretion system. In addition, we demonstrate the importance of the Mu baseplate as a model system for understanding bacterial phage tail-derived systems.

Structure of the central hub of bacteriophage Mu baseplate determined by X-ray crystallography of gp44.

Bacteriophage Mu is a double-stranded DNA phage that consists of an icosahedral head, a contractile tail with baseplate and six tail fibers, similar to the well-studied T-even phages. The baseplate of bacteriophage Mu, which recognizes and attaches to a host cell during infection, consists of at least eight different proteins. The baseplate protein, gp44, is essential for bacteriophage Mu assembly and the generation of viable phages. To investigate the role of gp44 in baseplate assembly and infection, the crystal structure of gp44 was determined at 2.1A resolution by the multiple isomorphous replacement method. The overall structure of the gp44 trimer is similar to that of the T4 phage gp27 trimer, which forms the central hub of the T4 baseplate, although these proteins share very little primary sequence homology. Based on these data, we confirm that gp44 exists as a trimer exhibiting a hub-like structure with an inner diameter of 25A through which DNA can presumably pass during infection. The molecular surface of the gp44 trimer that abuts the host cell membrane is positively charged, and it is likely that Mu phage interacts with the membrane through electrostatic interactions mediated by gp44.

Expression and characterization of a baseplate protein for bacteriophage Mu, gp44.

The gene product of gene 44 of Mu phage (gp44) is an essential protein for baseplate assembly and has been designated as gpP, a traditional genetic assignment. The function of gp44 during the assembly or infection process is not known. In the present study, we purified the recombinant gp44 and characterized it by analytical ultracentrifugation and differential scanning microcalorimetry. The results indicate that gp44 forms a trimer comprising a complex consisting of the 42 kDa and 40 kDa subunits that had been cleaved in the C-terminal region. Thermodynamic analysis also suggested that the C-terminal region forms a flexible domain.

Electron microscopic analysis of in vitro transposition intermediates of bacteriophage Mu DNA.

Bacteriophage Mu is a highly efficient transposon and the only moveable element for which an in vitro transposition system has been reported. Recently, this system has been used by Craigie and Mizuuchi [Cell 41 (1985) 867-876] to identify and biochemically characterize intermediates in the transposition process. We have utilized the in vitro transposition system to generate intermediates in the transposition process and have analyzed these intermediates by electron-microscopic methods. Partial denaturation mapping has shown the intermediates to be theta-shaped structures in which the phi X174 target DNA is joined to the mini-Mu plasmid at the ends of the Mu genome. Our results are in agreement with the previous biochemical studies and the type of intermediate we observe is exactly what is predicted by the Shapiro model of transposition [Proc. Natl. Acad. Sci. USA 76 (1979) 1933-1937].

Host factors that promote transpososome disassembly and the PriA-PriC pathway for restart primosome assembly.

Initiation of bacteriophage Mu DNA replication by transposition requires the disassembly of the transpososome that catalyses strand exchange and the assembly of a replisome promoted by PriA, PriB, PriC and DnaT proteins, which function in the host to restart stalled replication forks. Once the molecular chaperone ClpX weakens the very tight binding of the transpososome to the Mu ends, host disassembly factors (MRFalpha-DF) promote the dissociation of the transpososome from the DNA template and the assembly of a new nucleoprotein complex. Prereplisome factors (MRFalpha-PR) further alter the complex, allowing PriA binding and loading of major replicative helicase DnaB onto the template promoted by the restart proteins. MRFalpha-PR is essential for DnaB loading by restart proteins even on the deproteinized Mu fork whereas MRFalpha-DF is not required on the deproteinized template. When the transition from transpososome to replisome was reconstituted using MRFalpha-DF and MRFalpha-PR, initiation of Mu DNA replication was strictly dependent upon added PriC and PriA helicase. In contrast, initiation on the deproteinized template was predominantly dependent upon PriB and did not require PriA's helicase activity. The results indicate that transition mechanisms beginning with the transpososome disassembly can determine the pathway of replisome assembly by restart proteins.

Mutator bacteriophage D108 and its DNA: an electron microscopic characterization.

Three types of phage particles were observed on CsCl step gradients when D108 was purified from lysates prepared by induction of a prophage. These particle types were identified to be the mature phage, tailless DNA-filled heads, and a form of nucleoprotein aggregates. The nucleoprotein aggregates banded at a density (rho) of greater than 1.6. DNA molecules isolated from mature phage particles were (38.305 +/- 1.226) kilobases (kb) in length. Denaturation and renaturation of D108 DNA resulted in the formation of linear double-stranded molecules with variable-length single-stranded tails at one end. About 30% of the annealed molecules also carried an internal nonhomology, which was shown to be the region called the G-loop in Mu and P1 DNAs. Following the notation used for different regions of denatured, annealed Mu DNA, we measured the lengths of the equivalent D108 DNA regions to be as alpha-D108 = (32.178 +/- 1.370) kb; G-D108 = (3.07 +/- 0.382) kb; beta-D108 = (2.291 +/- 0.306) kb; SE-D108 = (0.966 +/- 0.433) kb. Formation of D108; Mu heteroduplexes disclosed the presence of five nonhomologies, two of which were partial. One of the partial heterologies was in the G-loop region. The largest nonhomology, (1.393 +/- 0.185) kb in size, was near the c end (immunity region) and probably spans the c and the ner genes of Mu. beta-D108 was shown to carry a (0.556 +/- 0.097)-kb insertion close to its right end. A short 100-base-pair region appeared to have been conserved at the ends of D108 and Mu. Occasionally, a 50-to 100-base-pair-long unpaired region was also observed at the left end of D108: Mu heteroduplexes. These sequences were presumably of bacterial DNA. Taken together, our results complement and extend our earlier genetic studies which established that D108 was a mutator phage heteroimmune to Mu with a host range different from Mu's.

Visualizing the assembly and disassembly mechanisms of the MuB transposition targeting complex.

MuB, a protein essential for replicative DNA transposition by the bacteriophage Mu, is an ATPase that assembles into a polymeric complex on DNA. We used total internal reflection fluorescence microscopy to observe the behavior of MuB polymers on single molecules of DNA. We demonstrate that polymer assembly is initiated by a stochastic nucleation event. After nucleation, polymer assembly occurs by a mechanism involving the sequential binding of small units of MuB. MuB that bound to A/T-rich regions of the DNA assembled into large polymeric complexes. In contrast, MuB that bound outside of the A/T-rich regions failed to assemble into large oligomeric complexes. Our data also show that MuB does not catalyze multiple rounds of ATP hydrolysis while remaining bound to DNA. Rather, a single ATP is hydrolyzed, then MuB dissociates from the DNA. Finally, we show that "capping" of the enhanced green fluorescent protein-MuB polymer ends with unlabeled MuB dramatically slows, but does not halt, dissociation. This suggests that MuB dissociation occurs through both an end-dependent mechanism and a slower mechanism wherein subunits dissociate from the polymer interior.

Identification of the bacteriophage Mu kil gene.

The kil gene encoded in bacteriophage Mu DNA was previously shown to reside between the end of the B gene at 4.3 kb and the EcoRI site at 5.1 kb from the left end. To precisely map the kil gene within this region, two series of BAL-31 deletion derivatives were created: one removed Mu DNA rightward from the Hpal site (4.2 kb) and the other removed Mu DNA leftward from the EcoRI site. The deleted Mu DNA was subcloned into the expression vector pUC19 under lac promoter control and tested for the expression of the killing function following IPTG induction. Using DNA sequencing analysis, the Mu DNA in Kil+ and Kil- clones was precisely determined, and the kil gene was mapped to the first open reading frame beyond the B gene. The expression of the kil gene was sufficient to induce dramatic morphological changes: cells became enlarged and predominantly spherical, reminiscent of the phenotype of certain cell mutants.

Immunoelectron microscopic analysis of the A, B, and HU protein content of bacteriophage Mu transpososomes.

Stable protein-DNA complexes or transpososomes mediate the Mu DNA strand transfer reaction in vitro (Surette, M. G., Buch, S. J., and Chaconas, G. (1987) Cell 49, 253-262; Craigie, R., and Mizuuchi, K. (1987) Cell 51, 493-501). Formation of the Type 1 complex, an intermediate in the strand transfer reaction, requires the Mu A and Escherichia coli HU proteins. Generation of the Type 2 complex, in which the Mu ends have been covalently linked to the target DNA, requires the Mu B protein, ATP, and target DNA in addition to A and HU. The protein content of these higher order synaptic complexes has been studied by immunoelectron microscopy using protein A-colloidal gold conjugates to visualize antibody-bound complexes. Under our in vitro transposition conditions, Type 1 complexes were found to contain A and HU; in addition, Type 2 complexes contained Mu B. However, both the HU and the Mu B protein were found to be loosely associated and could be quantitatively removed from the nucleoprotein core of both complexes by incubation in 0.5 M NaCl. Depletion of HU from the Type 1 complex did not affect the ability of this complex to be converted into the strand-transferred product. Hence, the indispensable role of the HU protein in the Mu DNA strand transfer reaction is limited to the formation of the Type 1 transpososome.

True reversal of Mu integration.

We describe a high-temperature (75 degrees C) transition in the Mu integration complex that causes efficient and true reversal of the integration reaction. A second reversal pathway, first described as 'foldback' reversal for the HIV integrase, was also observed upon disassembly/reassembly of the Mu complex at normal temperatures. Both true and foldback reversal severed only one or the other of the two integrated Mu ends, and each exhibited distinct metal ion specificities. Our results directly implicate an altered transposase configuration in the Mu strand transfer complex that inhibits reversal, thereby regulating the directionality of transposition.