Lindsay W. Black

Cloning, overexpression and purification of the terminase proteins gp16 and gp17 of bacteriophage T4: Construction of a defined in-vitro DNA packaging system using purified terminase proteins☆

Terminases of double-stranded DNA bacteriophages are required for packaging and generation of terminii in replicated concatemeric DNA molecules. Genetic evidence suggests that these functions in phage T4 are carried out by the products of genes 16 and 17. We cloned these T4 genes into a heat-inducible cI repressor-lambda PL promoter vector system, and overexpressed them in Escherichia coli. We developed an in-vitro DNA packaging system, which, consistent with the genetic data, shows an absolute requirement for the terminase proteins. The overexpressed terminase proteins gp16 and gp17 appear to form a specific complex and an ATP binding site is present in the gp17 molecule. We purified the terminase proteins either as individual gp16 or gp17 proteins, or as a gp16-gp17 complex. The gp16 function of the terminase complex is dispensable for packaging mature DNA, whereas gp17 is essential for packaging DNA under any condition tested. We constructed a defined in-vitro DNA packaging system with the purified terminase proteins, purified proheads and a DNA-free phage completion gene products extract. All the components of this system can be stored at -90 degrees C without loss of packaging activity. The terminase proteins, therefore, may serve as useful reagents for mechanistic studies on DNA packaging, as well as to develop T4 as a packaging-cloning vector.

Phage T4 SOC and HOC display of biologically active, full-length proteins on the viral capsid.

The T4 phage capsid accessory protein genes soc and hoc have recently been developed for display of peptides and protein domains at high copy number (Ren et al., 1996. Protein Science 5, 1833-1843; Ren et al., 1997. Gene 195, 303-311). That biologically active and full-length foreign proteins can be displayed by fusion to SOC and HOC on the T4 capsid is demonstrated in this report. A 271-residue heavy and light chain fused IgG anti-EWL (egg white lysozyme) antibody was displayed in active form attached to the COOH-terminus of the SOC capsid protein, as demonstrated by lysozyme-agarose affinity chromatography (>100-fold increase in specific titer). HOC with NH2-terminal fused HIV-I CD4 receptor of 183 amino acids can be detected on the T4 outer capsid surface with human CD4 domain 1 and 2 monoclonal antibodies. The number of molecules of each protein (10-40) bound per phage and their activity suggest that proteins can fold to native conformation and be displayed by HOC and SOC to allow binding and protein-protein interactions on the capsid.

Portal fusion protein constraints on function in DNA packaging of bacteriophage T4

Architecturally conserved viral portal dodecamers are central to capsid assembly and DNA packaging. To examine bacteriophage T4 portal functions, we constructed, expressed and assembled portal gene 20 fusion proteins. C‐terminally fused (gp20–GFP, gp20–HOC) and N‐terminally fused (GFP–gp20 and HOC–gp20) portal fusion proteins assembled in vivo into active phage. Phage assembled C‐terminal fusion proteins were inaccessible to trypsin whereas assembled N‐terminal fusions were accessible to trypsin, consistent with locations inside and outside the capsid respectively. Both N‐ and C‐terminal fusions required coassembly into portals with ∼50% wild‐type (WT) or near WT‐sized 20am truncated portal proteins to yield active phage. Trypsin digestion of HOC–gp20 portal fusion phage showed comparable protection of the HOC and gp20 portions of the proteolysed HOC–gp20 fusion, suggesting both proteins occupy protected capsid positions, at both the portal and the proximal HOC capsid‐binding sites. The external portal location of the HOC portion of the HOC–gp20 fusion phage was confirmed by anti‐HOC immuno‐gold labelling studies that showed a gold ‘necklace’ around the phage capsid portal. Analysis of HOC–gp20‐containing proheads showed increased HOC protein protection from trypsin degradation only after prohead expansion, indicating incorporation of HOC–gp20 portal fusion protein to protective proximal HOC‐binding sites following this maturation. These proheads also showed no DNA packaging defect in vitro as compared with WT. Retention of function of phage and prohead portals with bulky internal (C‐terminal) and external (N‐terminal) fusion protein extensions, particularly of apparently capsid tethered portals, challenges the portal rotation requirement of some hypothetical DNA packaging mechanisms.

PURIFICATION AND CHARACTERIZATION OF THE SMALL SUBUNIT OF PHAGE T4 TERMINASE, GP16, REQUIRED FOR DNA PACKAGING

Phage T4 terminase is an enzyme that binds to the portal protein of proheads and cuts and packages concatemeric DNA. The T4 terminase is composed of two subunits, gene products (gp) 16 and 17. The role of the small subunit, gp16, in T4 DNA packaging is not well characterized. We developed a new purification procedure to obtain large quantities of purified gp16 from an overexpression vector. The pure protein is found in two molecular weight forms, due to specific C-terminal truncation, displays in vitro packaging activity, and binds but does not hydrolyze ATP. gp16 forms specific oligomers, rings, and side-by-side double rings, as judged by native polyacrylamide gel electrophoresis and scanning transmission electron microscopy measurements. The single ring contains about eight monomers, and the rings have a diameter of about 8 nm with a central hole of about 2 nm. A DNA-binding helix-turn-helix motif close to the N terminus of gp16 is predicted. The oligomers do not bind to DNA, but following denaturation and renaturation in the presence of DNA, binding can be demonstrated by gel shift and filter binding assays. gp16 binds to double-stranded DNA but not single-stranded DNA, and appears to bind preferentially to a gene 16-containing DNA sequence.

Isolation and Characterization of T4 Bacteriophage gp17 Terminase, a Large Subunit Multimer with Enhanced ATPase Activity

Phage T4 terminase is a two-subunit enzyme that binds to the prohead portal protein and cuts and packages a headful of concatameric DNA. To characterize the T4 terminase large subunit, gp17 (70 kDa), gene 17 was cloned and expressed as a chitin-binding fusion protein. Following cleavage and release of gp17 from chitin, two additional column steps completed purification. The purification yielded (i) homogeneous soluble gp17 highly active inin vitro DNA packaging (∼10% efficiency, >108 phage/ml of extract); (ii) gp17 lacking endonuclease and contaminating protease activities; and (iii) a DNA-independent ATPase activity stimulated >100-fold by the terminase small subunit, gp16 (18 kDa), and modestly by portal gp20 and single-stranded binding protein gp32 multimers. Analyses revealed a preparation of highly active and slightly active gp17 forms, and the latter could be removed by immunoprecipitation using antiserum raised against a denatured form of the gp17 protein, leaving a terminase with the increased specific activity (∼400 ATPs/gp17 monomer/min) required for DNA packaging. Analysis of gp17 complexes separated from gp16 on glycerol gradients showed that a prolonged enhanced ATPase activity persisted after exposure to gp16, suggesting that constant interaction of the two proteins may not be required during packaging.

DNA packaging of bacteriophage T4 proheads in vitro. Evidence that prohead expansion is not coupled to DNA packaging.

We developed a system for DNA packaging of isolated bacteriophage T4 proheads in vitro and studied the role of prohead expansion in DNA packaging. Biologically active proheads have been purified from a number of packaging-deficient mutant extracts. The cleaved mature prohead is the active structural precursor for the DNA packaging reaction. Packaging of proheads requires ATP, Mg2+ and spermidine, and is stimulated by polyethylene glycol and dextran. Predominantly expanded proheads (ELPs) are produced at 37 degrees C and predominantly unexpanded proheads (ESPs) are produced at 20 degrees C. Both the expanded and unexpanded proheads are active in DNA packaging in vitro. This is based on the observations that (1) both ESPs and ELPs purified by chromatography on DEAE-Sephacel showed DNA packaging activity; (2) apparently homogeneous ELPs prepared by treatment with sodium dodecyl sulfate (which dissociates ESPs) retained significant biological activity; (3) specific precipitation of ELPs with anti-hoc immunoglobulin G resulted in loss of DNA packaging activity; and (4) ESPs upon expansion in vitro to ELPs retained packaging activity. Therefore, contrary to the models that couple DNA packaging to head expansion, in T4 the expansion and packaging appear to be independent, since the already expanded DNA-free proheads can be packaged in vitro. We therefore propose that the unexpanded to expanded prohead transition has evolved to stabilize the capsid and to reorganize the prohead shell functionally from a core-interacting to a DNA-interacting inner surface.

Structure and assembly of bacteriophage T4 head

The bacteriophage T4 capsid is an elongated icosahedron, 120 nm long and 86 nm wide, and is built with three essential proteins; gp23*, which forms the hexagonal capsid lattice, gp24*, which forms pentamers at eleven of the twelve vertices, and gp20, which forms the unique dodecameric portal vertex through which DNA enters during packaging and exits during infection. The past twenty years of research has greatly elevated the understanding of phage T4 head assembly and DNA packaging. The atomic structure of gp24 has been determined. A structural model built for gp23 using its similarity to gp24 showed that the phage T4 major capsid protein has the same fold as that found in phage HK97 and several other icosahedral bacteriophages. Folding of gp23 requires the assistance of two chaperones, the E. coli chaperone GroEL and the phage coded gp23-specific chaperone, gp31. The capsid also contains two non-essential outer capsid proteins, Hoc and Soc, which decorate the capsid surface. The structure of Soc shows two capsid binding sites which, through binding to adjacent gp23 subunits, reinforce the capsid structure. Hoc and Soc have been extensively used in bipartite peptide display libraries and to display pathogen antigens including those from HIV, Neisseria meningitides, Bacillus anthracis, and FMDV. The structure of Ip1*, one of the components of the core, has been determined, which provided insights on how IPs protect T4 genome against the E. coli nucleases that degrade hydroxymethylated and glycosylated T4 DNA. Extensive mutagenesis combined with the atomic structures of the DNA packaging/terminase proteins gp16 and gp17 elucidated the ATPase and nuclease functional motifs involved in DNA translocation and headful DNA cutting. Cryo-EM structure of the T4 packaging machine showed a pentameric motor assembled with gp17 subunits on the portal vertex. Single molecule optical tweezers and fluorescence studies showed that the T4 motor packages DNA at a rate of up to 2000 bp/sec, the fastest reported to date of any packaging motor. FRET-FCS studies indicate that the DNA gets compressed during the translocation process. The current evidence suggests a mechanism in which electrostatic forces generated by ATP hydrolysis drive the DNA translocation by alternating the motor between tensed and relaxed states.

A Bipartite Bacteriophage T4 SOC and HOC Randomized Peptide Display Library: Detection and Analysis of Phage T4 Terminase (gp17) and Late σ Factor (gp55) Interaction

HOC and SOC are dispensable T4 capsid proteins that can be used for phage display of multiple copies of peptides and proteins. A bipartite phage T4 peptide library was created by displaying on tetra-alanine linker peptides five randomized amino acids from the carboxyl-terminus of SOC and five randomized amino acids from the amino terminus of HOC. The bipartite library was biopanned against the phage T4 terminase large subunit gp17 to identify T4 gene products that may interact with the terminase. The sequences of selected phages displayed matches to those T4 gene products previously known by genetic and biochemical criteria to interact with gp17: gp20 (portal protein), gp32 (single-stranded DNA binding protein), gp16 (terminase small subunit), and gp17 (self). In addition, matches were found to gp55 (T4 late sigma factor), gp45 (sliding clamp), gp44 (clamp loader), gp2 (DNA end protein), and gp23 (major capsid protein). Abundant amino acid sequence matches were found to aa region 118-134 of gp55. Immunoprecipitation and affinity column chromatography demonstrated direct binding of gp17 and gp55; moreover, gp17 bound specifically to a column-coupled peptide corresponding to gp55 residues 111-136. Measurements of gene 17 and other mRNA levels in mutant-infected bacteria did not support a role of gp17-gp55 interaction in regulation of terminase or other late gene transcription. However, whereas DNA concatemers that accumulate in prohead and terminase defective phage T4 infections could be packaged in vitro to approximately 10% wild-type efficiency, 55am33am defective concatemeric DNA was packaged at least 100-fold less efficiently. Moreover, gp55 residues 111-136 peptide specifically blocked DNA packaging in vitro. These results suggest that the T4 terminase interaction with T4 late sigma factor gp55 plays a role in DNA packaging in vivo. The gp55 interaction may function to load the terminase onto DNA for packaging.

Modulation of the packaging reaction of bacteriophage t4 terminase by DNA structure.

Bacteriophage terminases package DNA through the portal ring of a procapsid during phage maturation. We have probed the mechanism of the phage T4 large terminase subunit gp17 by analyzing linear DNAs that are translocated in vitro. Duplex DNAs of random sequence from 20 to 500 bp were efficiently packaged. Dye and short, single-stranded end extensions were tolerated, whereas 20-base extensions, hairpin ends, 20-bp DNA-RNA hybrid, and 4-kb dsRNA substrates were not packaged. Molecules 60 bp long with 10 mismatched bases were translocated; substrates with 20 mismatched bases, a related D-loop structure, or ones with 20-base single-strand regions were not. A single nick in 100- or 200-bp duplexes, irrespective of location, reduced translocation efficiency, but a singly nicked 500-bp molecule was packaged as effectively as an unnicked control. A fluorescence-correlation-spectroscopy-based assay further showed that a 100-bp nicked substrate did not remain stably bound by the terminase-prohead. Taken together, two unbroken DNA strands seem important for packaging, consistent with a proposed torsional compression translocation mechanism.

Bacteriophage T4 internal protein mutants: Isolation and properties

Abstract Mutants defective in synthesis of the three phage T4 internal proteins (IPs), IPI, IPII, and IPIII, were isolated by an immunological screening procedure. Crosses between these chain termination mutants, as well as the use of deletions through gene e (lysozyme) which also block synthesis of one or more of the IPs, allow their structural genes to be located on the genetic and physical maps of phage T4. These locations are in good agreement with the known transcription properties of the internal protein genes: Regulation of transcription from this region of the T4 genome is discussed. A triple mutant, IP o , which lacks all three internal proteins is viable, and therefore these internal proteins found in the mature T4 head are not required for DNA condensation or head formation. Early events in phage growth, including T4 DNA injection and expression, occur normally in IP o infected Escherichia coli B E cells, but phage formation is affected, with reduced head assembly and incomplete head protein maturation. This appears to be due primarily to the absence of IPIII, since mutants lacking IPIII are similar to IP o in assembly defectiveness. These results are discussed in terms of an assembly-core model for T4 head formation ( Showe and Black, 1973 ).