Self-Competitive Inhibition of the Bacteriophage P22 Tailspike Endorhamnosidase by O-Antigen Oligosaccharides.

The P22 tailspike endorhamnosidase confers the high specificity of bacteriophage P22 for some serogroups of Salmonella differing only slightly in their O-antigen polysaccharide. We used several biophysical methods to study the binding and hydrolysis of O-antigen fragments of different lengths by P22 tailspike protein. O-Antigen saccharides of defined length labeled with fluorophors could be purified with higher resolution than previously possible. Small amounts of naturally occurring variations of O-antigen fragments missing the nonreducing terminal galactose could be used to determine the contribution of this part to the free energy of binding to be ∼7 kJ/mol. We were able to show via several independent lines of evidence that an unproductive binding mode is highly favored in binding over all other possible binding modes leading to hydrolysis. This is true even under circumstances under which the O-antigen fragment is long enough to be cleaved efficiently by the enzyme. The high-affinity unproductive binding mode results in a strong self-competitive inhibition in addition to product inhibition observed for this system. Self-competitive inhibition is observed for all substrates that have a free reducing end rhamnose. Naturally occurring O-antigen, while still attached to the bacterial outer membrane, does not have a free reducing end and therefore does not perform self-competitive inhibition.

Recognition of an α-helical hairpin in P22 large terminase by a synthetic antibody fragment.

The genome-packaging motor of tailed bacteriophages and herpesviruses is a multisubunit protein complex formed by several copies of a large (TerL) and a small (TerS) terminase subunit. The motor assembles transiently at the portal protein vertex of an empty precursor capsid to power the energy-dependent packaging of viral DNA. Both the ATPase and nuclease activities associated with genome packaging reside in TerL. Structural studies of TerL from bacteriophage P22 have been hindered by the conformational flexibility of this enzyme and its susceptibility to proteolysis. Here, an unbiased, synthetic phage-display Fab library was screened and a panel of high-affinity Fabs against P22 TerL were identified. This led to the discovery of a recombinant antibody fragment, Fab4, that binds a 33-amino-acid α-helical hairpin at the N-terminus of TerL with an equilibrium dissociation constant Kd of 71.5 nM. A 1.51 Šresolution crystal structure of Fab4 bound to the TerL epitope (TLE) together with a 1.15 Šresolution crystal structure of the unliganded Fab4, which is the highest resolution ever achieved for a Fab, elucidate the principles governing the recognition of this novel helical epitope. TLE adopts two different conformations in the asymmetric unit and buries as much as 1250 Å2 of solvent-accessible surface in Fab4. TLE recognition is primarily mediated by conformational changes in the third complementarity-determining region of the Fab4 heavy chain (CDR H3) that take place upon epitope binding. It is demonstrated that TLE can be introduced genetically at the N-terminus of a target protein, where it retains high-affinity binding to Fab4.

Development of a New Biocontainment Strategy in Model Cyanobacterium Synechococcus Strains.

Recent synthetic biology efforts have raised biosafety concerns for possible release of engineered cyanobacteria into natural environments. To address the issues, we developed a controllable metal ion induced biocontainment system for two model cyanobacteria. First, six ion-inducible promoters were respectively evaluated in both Synechococcus elongatus PCC 7942 and the fast-growing cyanobacterium Synechococcus elongatus UTEX 2973, leading to the identification of an iron ion-repressed promoter PisiAB with low leakage and a reduction-fold of 5.4 and 7.9, respectively. Second, holin-endolysin and nuclease NucA systems were introduced, the inhibition rate of which against two Synechococcus strains varied from 61% to 86.4%. Third, two toxin/antitoxin modules were identified capable of inducing programmed suicide in both Synechococcus strains after induction. Furthermore, an escape experiment was conducted and the results showed that the system was able to achieve an escape frequency below the detection limit of 10-9 after 3 days' duration, demonstrating the strategy integrating iron ion-inducible promoter PisiAB and that toxin/antitoxin modules could be a useful tool for cyanobacterium biocontainment.

Multifunctionalized biocatalytic P22 nanoreactor for combinatory treatment of ER+ breast cancer.

BACKGROUND: Tamoxifen is the standard endocrine therapy for breast cancers, which require metabolic activation by cytochrome P450 enzymes (CYP). However, the lower and variable concentrations of CYP activity at the tumor remain major bottlenecks for the efficient treatment, causing severe side-effects. Combination nanotherapy has gained much recent attention for cancer treatment as it reduces the drug-associated toxicity without affecting the therapeutic response. RESULTS: Here we show the modular design of P22 bacteriophage virus-like particles for nanoscale integration of virus-driven enzyme prodrug therapy and photodynamic therapy. These virus capsids carrying CYP activity at the core are decorated with photosensitizer and targeting moiety at the surface for effective combinatory treatment. The estradiol-functionalized nanoparticles are recognized and internalized into ER+ breast tumor cells increasing the intracellular CYP activity and showing the ability to produce reactive oxygen species (ROS) upon UV365 nm irradiation. The generated ROS in synergy with enzymatic activity drastically enhanced the tamoxifen sensitivity in vitro, strongly inhibiting tumor cells. CONCLUSIONS: This work clearly demonstrated that the targeted combinatory treatment using multifunctional biocatalytic P22 represents the effective nanotherapeutics for ER+ breast cancer.

Biocatalytic virus capsid as nanovehicle for enzymatic activation of Tamoxifen in tumor cells.

Most of the drugs used in chemotherapy should be activated by a transformation catalyzed by cytochrome P450 (CYP) enzymes. In this work, bacteriophage P22 virus-like particles (VLPs) containing CYP activity, immunologically inert and functionalized in order to be recognized by human cervix carcinoma cells and human breast adenocarcinoma cells were designed. The CYP was encapsulated inside the virus capsid obtained from the bacteriophage P22. CYP and coat protein were both heterologously expressed in E. coli. The VLPs with enzymatic activity were covered with polyethylene glycol that was functionalized in its distal end with folic acid in order to be recognized by folate receptors exhibited on tumor cells. The capacity of biocatalytic VLPs to be recognized and internalized into tumor cells is demonstrated. The VLP-treated cells showed enhanced capacity for the transformation of the pro-drug tamoxifen, which resulted in an increase of the cell sensitivity to this oncological drug. In this work, the potential use of biocatalytic VLPs vehicles as a delivery system of medical relevant enzymes is clearly demonstrated. In addition to cancer treatment, this technology also offers an interesting platform as nano-bioreactors for intracellular delivery of enzymatic activity for other diseases originated by the lack of enzymatic activity.

Encapsulation of an enzyme cascade within the bacteriophage P22 virus-like particle.

Developing methods for investigating coupled enzyme systems under conditions that mimic the cellular environment remains a significant challenge. Here we describe a biomimetic approach for constructing densely packed and confined multienzyme systems through the co-encapsulation of 2 and 3 enzymes within a virus-like particle (VLP) that perform a coupled cascade of reactions, creating a synthetic metabolon. Enzymes are efficiently encapsulated in vivo with known stoichiometries, and the kinetic parameters of the individual and coupled activities are characterized. From the results we develop and validate a mathematical model for predicting the expected kinetics for coupled reactions under co-localized conditions.

Small terminase couples viral DNA binding to genome-packaging ATPase activity.

Packaging of viral genomes into empty procapsids is powered by a large DNA-packaging motor. In most viruses, this machine is composed of a large (L) and a small (S) terminase subunit complexed with a dodecamer of portal protein. Here we describe the 1.75 Å crystal structure of the bacteriophage P22 S-terminase in a nonameric conformation. The structure presents a central channel ∼23 Å in diameter, sufficiently large to accommodate hydrated B-DNA. The last 23 residues of S-terminase are essential for binding to DNA and assembly to L-terminase. Upon binding to its own DNA, S-terminase functions as a specific activator of L-terminase ATPase activity. The DNA-dependent stimulation of ATPase activity thus rationalizes the exclusive specificity of genome-packaging motors for viral DNA in the crowd of host DNA, ensuring fidelity of packaging and avoiding wasteful ATP hydrolysis. This posits a model for DNA-dependent activation of genome-packaging motors of general interest in virology.

Structure of p22 headful packaging nuclease.

Packaging of viral genomes into preformed procapsids requires the controlled and synchronized activity of an ATPase and a genome-processing nuclease, both located in the large terminase (L-terminase) subunit. In this paper, we have characterized the structure and regulation of bacteriophage P22 L-terminase (gp2). Limited proteolysis reveals a bipartite organization consisting of an N-terminal ATPase core flexibly connected to a C-terminal nuclease domain. The 2.02 Å crystal structure of P22 headful nuclease obtained by in-drop proteolysis of full-length L-terminase (FL-L-terminase) reveals a central seven-stranded ß-sheet core that harbors two magnesium ions. Modeling studies with DNA suggest that the two ions are poised for two-metal ion-dependent catalysis, but the nuclease DNA binding surface is sterically hindered by a loop-helix (L(1)-α(2)) motif, which is incompatible with catalysis. Accordingly, the isolated nuclease is completely inactive in vitro, whereas it exhibits endonucleolytic activity in the context of FL-L-terminase. Deleting the autoinhibitory L(1)-α(2) motif (or just the loop L(1)) restores nuclease activity to a level comparable with FL-L-terminase. Together, these results suggest that the activity of P22 headful nuclease is regulated by intramolecular cross-talk with the N-terminal ATPase domain. This cross-talk allows for precise and controlled cleavage of DNA that is essential for genome packaging.

Nanoreactors by programmed enzyme encapsulation inside the capsid of the bacteriophage P22.

The virus like particle (VLP) derived from bacteriophage P22 presents a unique platform for constructing catalytically functional nanomaterials by encapsulation of enzymes into its interior. Encapsulation has been engineered to be genetically programmed allowing "one pot" synthesis and incorporation of desired enzymes. The unique characteristic that separates P22 from other VLP systems is the ability to modulate the overall volume and porosity of the VLP structure, thus controlling substrate access to the encapsulated enzyme. The present study demonstrates incorporation of an enzyme, alcohol dehydrogenase D, with the highest internal loading for an active enzyme by any VLP described thus far. In addition, we show that not only does encapsulating AdhD inside P22 affect its kinetic parameters in comparison with the "free" enzyme, but transformation of P22 to different morphological states, which changes the internal volume of the VLP, yields changes in the overall activity of the encapsulated enzyme as well. The findings reported here clearly illustrate that P22 holds potential for synthetic approaches to create nanoreactors, by design, using the power of highly evolved enzymes for chemical transformations.

Crystallization of the nonameric small terminase subunit of bacteriophage P22.

The packaging of viral genomes into preformed empty procapsids is powered by an ATP-dependent genome-translocating motor. This molecular machine is formed by a heterodimer consisting of large terminase (L-terminase) and small terminase (S-terminase) subunits, which is assembled into a complex of unknown stoichiometry, and a dodecameric portal protein. There is considerable confusion in the literature regarding the biologically relevant oligomeric state of terminases, which, like portal proteins, form ring-like structures. The number of subunits in a hollow oligomeric protein defines the internal diameter of the central channel and the ability to fit DNA inside. Thus, knowledge of the exact stoichiometry of terminases is critical to decipher the mechanisms of terminase-dependent DNA translocation. Here, the gene encoding bacteriophage P22 S-terminase in Escherichia coli has been overexpressed and the protein purified under native conditions. In the absence of detergents and/or denaturants that may cause disassembly of the native oligomer and formation of aberrant rings, it was found that P22 S-terminase assembles into a concentration-independent nonamer of ∼168 kDa. Nonameric S-terminase was crystallized in two different crystal forms at neutral pH. Crystal form I belonged to space group P2(1)2(1)2, with unit-cell parameters a=144.2, b=144.2, c=145.3 Å, and diffracted to 3.0 Šresolution. Crystal form II belonged to space group P2(1), with unit-cell parameters a=76.48, b=100.9, c=89.95 Å, ß=93.73°, and diffracted to 1.75 Šresolution. Preliminary crystallographic analysis of crystal form II confirms that the S-terminase crystals contain a nonamer in the asymmetric unit and are suitable for high-resolution structure determination.

Assembly architecture and DNA binding of the bacteriophage P22 terminase small subunit.

Morphogenesis of bacteriophage P22 involves the packaging of double-stranded DNA into a preassembled procapsid. DNA is translocated by a powerful virally encoded molecular motor called terminase, which comprises large (gp2, 499 residues) and small (gp3, 162 residues) subunits. While gp2 contains the phosphohydrolase and endonuclease activities of terminase, the function of gp3 may be to regulate specific and nonspecific modes of DNA recognition as well as the enzymatic activities of gp2. Electron microscopy shows that wild-type gp3 self-assembles into a stable and monodisperse nonameric ring. A three-dimensional reconstruction at 18 A resolution provides the first glimpse of P22 terminase architecture and implies two distinct modes of interaction with DNA-involving a central channel of 20 A diameter and radial spikes separated by 34 A. Electromobility shift assays indicate that the gp3 ring binds double-stranded DNA nonspecifically in vitro via electrostatic interactions between the positively charged C-terminus of gp3 (residues 143-152) and phosphates of the DNA backbone. Raman spectra show that nonameric rings formed by subunits truncated at residue 142 retain the subunit fold despite the loss of DNA-binding activity. Difference density maps between gp3 rings containing full-length and C-terminally truncated subunits are consistent with localization of residues 143-152 along the central channel of the nonameric ring. The results suggest a plausible molecular mechanism for gp3 function in DNA recognition and translocation.

Purification and characterization of bacteriophage P22 Xis protein.

The temperate bacteriophages lambda and P22 share similarities in their site-specific recombination reactions. Both require phage-encoded integrase (Int) proteins for integrative recombination and excisionase (Xis) proteins for excision. These proteins bind to core-type, arm-type, and Xis binding sites to facilitate the reaction. lambda and P22 Xis proteins are both small proteins (lambda Xis, 72 amino acids; P22 Xis, 116 amino acids) and have basic isoelectric points (for P22 Xis, 9.42; for lambda Xis, 11.16). However, the P22 Xis and lambda Xis primary sequences lack significant similarity at the amino acid level, and the linear organizations of the P22 phage attachment site DNA-binding sites have differences that could be important in quaternary intasome structure. We purified P22 Xis and studied the protein in vitro by means of electrophoretic mobility shift assays and footprinting, cross-linking, gel filtration stoichiometry, and DNA bending assays. We identified one protected site that is bent approximately 137 degrees when bound by P22 Xis. The protein binds cooperatively and at high protein concentrations protects secondary sites that may be important for function. Finally, we aligned the attP arms containing the major Xis binding sites from bacteriophages lambda, P22, L5, HP1, and P2 and the conjugative transposon Tn916. The similarity in alignments among the sites suggests that Xis-containing bacteriophage arms may form similar structures.

An intersubunit active site between supercoiled parallel beta helices in the trimeric tailspike endorhamnosidase of Shigella flexneri Phage Sf6.

Sf6 belongs to the Podoviridae family of temperate bacteriophages that infect gram-negative bacteria by insertion of their double-stranded DNA. They attach to their hosts specifically via their tailspike proteins. The 1.25 A crystal structure of Shigella phage Sf6 tailspike protein (Sf6 TSP) reveals a conserved architecture with a central, right-handed beta helix. In the trimer of Sf6 TSP, the parallel beta helices form a left-handed, coiled-beta coil with a pitch of 340 A. The C-terminal domain consists of a beta sandwich reminiscent of viral capsid proteins. Further crystallographic and biochemical analyses show a Shigella cell wall O-antigen fragment to bind to an endorhamnosidase active site located between two beta-helix subunits each anchoring one catalytic carboxylate. The functionally and structurally related bacteriophage, P22 TSP, lacks sequence identity with Sf6 TSP and has its active sites on single subunits. Sf6 TSP may serve as an example for the evolution of different host specificities on a similar general architecture.

Subunit conformations and assembly states of a DNA-translocating motor: the terminase of bacteriophage P22.

Bacteriophage P22, a podovirus infecting strains of Salmonella typhimurium, packages a 42-kbp genome using a headful mechanism. DNA translocation is accomplished by the phage terminase, a powerful molecular motor consisting of large and small subunits. Although many of the structural proteins of the P22 virion have been well characterized, little is known about the terminase subunits and their molecular mechanism of DNA translocation. We report here structural and assembly properties of ectopically expressed and highly purified terminase large and small subunits. The large subunit (gp2), which contains the nuclease and ATPase activities of terminase, exists as a stable monomer with an alpha/beta fold. The small subunit (gp3), which recognizes DNA for packaging and may regulate gp2 activity, exhibits a highly alpha-helical secondary structure and self-associates to form a stable oligomeric ring in solution. For wild-type gp3, the ring contains nine subunits, as demonstrated by hydrodynamic measurements, electron microscopy, and native mass spectrometry. We have also characterized a gp3 mutant (Ala 112-->Thr) that forms a 10-subunit ring, despite a subunit fold indistinguishable from wild type. Both the nonameric and decameric gp3 rings exhibit nonspecific DNA-binding activity, and gp2 is able to bind strongly to the DNA/gp3 complex but not to DNA alone. We propose a scheme for the roles of P22 terminase large and small subunits in the recruitment and packaging of viral DNA and discuss the model in relation to proposals for terminase-driven DNA translocation in other phages.

Extension to 2268 atoms of direct methods in the ab initio determination of the unknown structure of bacteriophage P22 lysozyme.

The X-ray crystal structure of the previously unknown bacteriophage P22 lysozyme, the product of gene 19, has been determined ab initio by direct methods using the program SIR2002. The presence of several partially occupied iodine anions and samarium cations augmented the ability of direct methods to locate all 2268 non-H protein atoms in the asymmetric unit, making this one of the largest structures to date to be determined ab initio. The iodides were introduced from a quick soak, which the crystal survived sufficiently well to diffract to 1.04 angstroms resolution. The complete heavy-atom substructure contributed 6.6% of the total scattering power. The initial determination of the structure assumed that there were two iodide ions in the asymmetric unit, although it was later determined that these sites correspond to partially occupied samarium ions. Tests suggested that it is better to overestimate rather than underestimate the heavy-atom content. While experimental phases from all of the successful tests were of high quality, the best results came from a SAD experiment using the programs SHELXD and SHELXE. Nonetheless, ab initio structure determination by direct methods was found to be a viable alternative to traditional protein crystallographic methods provided that the X-ray data extend to atomic resolution and heavy atoms with sufficient scattering power are present in the crystal.

Peptidoglycan hydrolytic activities associated with bacteriophage virions.

Murein hydrolases appear to be widespread in the virions of bacteriophages infecting Gram-positive or Gram-negative bacteria. Muralytic activity has been found in virions of the majority of a diverse collection of phages. Where known, the enzyme is either part of a large protein or found associated with other structural components of the virion that limit enzyme activity. In most cases, the lack of genetic and structural characterization of the phage precludes making a definitive identification of the enzymatic protein species. However, three proteins with muralytic activity have been unequivocally identified. T7gp16 is a 144 kDa internal head protein that is ejected into the cell at the initiation of infection; its enzyme activity is required only when the cell wall is more highly cross-linked. P22gp4 is part of the neck of the particle and is essential for infectivity. The activity associated with virions of Bacillus subtilis phage ø29 and its relatives lies in the terminal protein gp3. These studies lead to a general mechanism describing how phage genomes are transported across the bacterial cell wall.

Prophage insertion sites.

Insertion of viral DNA into host chromosomes is an ancient process essential for propagation in the proviral form. Many present-day bacteriophages insert at specific sites on the host chromosome. Insertion by two coliphage families (lambdoid and P4-like) is compared. For both families, insertion sites frequently lie within tRNA genes. The lambdoid phages insert at anticodon loops, whereas the p4-like phages insert in the TpsiC loops downstream from them. The association of both groups with tRNA genes suggests that the primordial insertion site of both groups may have been within a tRNA gene. The integrase proteins used in phage insertion may have originated at that stage, with subsequent diversification of specificity.

Characterization of the protrimer intermediate in the folding pathway of the interdigitated beta-helix tailspike protein.

P22 tailspike is a homotrimeric, thermostable adhesin that recognizes the O-antigen lipopolysaccharide of Salmonella typhimurium. The 70 kDa subunits include long beta-helix domains. After residue 540, the polypeptide chains change their path and wrap around one another, with extensive interchain contacts. Formation of this interdigitated domain intimately couples the chain folding and assembly mechanisms. The earliest detectable trimeric intermediate in the tailspike folding and assembly pathway is the protrimer, suspected to be a precursor of the native trimer structure. We have directly analyzed the kinetics of in vitro protrimer formation and disappearance for wild type and mutant tailspike proteins. The results confirm that the protrimer intermediate is an on-pathway intermediate for tailspike folding. Protrimer was originally resolved during tailspike folding because its migration through nondenaturing polyacrylamide gels was significantly retarded with respect to the migration of the native tailspike trimer. By comparing protein mobility versus acrylamide concentration, we find that the retarded mobility of the protrimer is due exclusively to a larger overall size than the native trimer, rather than an altered net surface charge. Experiments with mutant tailspike proteins indicate that the conformation difference between protrimer and native tailspike trimer is localized toward the C-termini of the tailspike polypeptide chains. These results suggest that the transformation of the protrimer to the native tailspike trimer represents the C-terminal interdigitation of the three polypeptide chains. This late step may confer the detergent-resistance, protease-resistance, and thermostability of the native trimer.

The interdigitated beta-helix domain of the P22 tailspike protein acts as a molecular clamp in trimer stabilization.

The P22 tailspike adhesin is an elongated thermostable trimer resistant to protease digestion and to denaturation in sodium dodecyl sulfate. Monomeric, dimeric, and protrimeric folding and assembly intermediates lack this stability and are thermolabile. In the native trimer, three right-handed parallel beta-helices (residues 143-540), pack side-by-side around the three-fold axis. After residue 540, these single chain beta-helices terminate and residues 541-567 of the three polypeptide chains wrap around each other to form a three-stranded interdigitated beta-helix. Three mutants located in this region -- G546D, R563Q, and A575T -- blocked formation of native tailspike trimers, and accumulated soluble forms of the mutant polypeptide chains within cells. The substitutions R563Q and A575T appeared to prevent stable association of partially folded monomers. G546D, in the interdigitated region of the chain, blocked tailspike folding at the transition from the partially-folded protrimer to the native trimer. The protrimer-like species accumulating in the G546D mutant melted out at 42 degrees C and was trypsin and SDS sensitive. The G546D defect was not corrected by introduction of global suppressor mutations, which correct kinetic defects in beta-helix folding. The simplest interpretation of these results is that the very high thermostability (T(m) = 88 degrees C), protease and detergent resistance of the native tailspike acquired in the protrimer-to-trimer transition, depends on the formation of the three-stranded interdigitated region. This interdigitated beta-helix appears to function as a molecular clamp insuring thermostable subunit association in the native trimer.

Nucleotide sequence of coliphage HK620 and the evolution of lambdoid phages.

HK620 is a temperate lambdoid bacteriophage that adsorbs to the O-antigen of its host, Escherichia coli H. The genome of a temperature-sensitive clear-plaque mutant consists of 38,297 nucleotides in which we recognize 60 open reading frames (orfs). Eighteen of these lie in a region of the genome that we call the virion structure domain. The other 42 orfs lie in what we call the metabolic domain. Virions of HK620 resemble those of phage P22. The virion structural orfs encode three kinds of putative proteins relative to the virion proteins of P22: (1) those that are nearly (about 90 %) identical; (2) those that are weakly (about 30 %) identical; and (3) those composed of nearly and weakly identical segments. We hypothesize that these composite proteins form bridges between the virion proteins of the other two kinds. Three of the putative virion proteins that are only weakly identical to P22 proteins are 71, 60 and 79 % identical to proteins encoded by the phage APSE-1, whose virions also resemble those of P22. Because the hosts of APSE-1 and HK620 have been separated from each other by an estimated 200 My, we propose using the amino acid differences that have accumulated in these proteins to estimate a biological clock for temperate lambdoid phages. The putative transcriptional regulatory gene circuitry of HK620 seems to resemble that of phage lambda. Integration, on the other hand, resembles that of satellite phage P4 in that the attP sequence lies between the leftward promoter and int rather than downstream of int. Comparing the metabolic domains of several lambdoid phage genomes reveals seven short conserved sequences roughly defining boundaries of functional modules. We propose that these boundary sequences are foci of genetic recombination that serve to assort the modules and make the metabolic domain highly mosaic genetically.