Gene amplification mechanism for the hyperproduction of T4 bacteriophage gene 17 and 18 proteins.

Bacteriophage T4 mutants hyperproducing gene 17 protein (Hp17) have been isolated at high frequency by growing gene 17 amber mutants on ochre suppressor strains of Escherichia coli. Most mutants showed the co-hyperproduction of gene 18 protein, although one anomalous mutant hyperproduced a 60,000 Mr partial polypeptide of gene 18. Hybridization of T4 late RNAs to cloned plasmid DNA containing genes 17, 18 or control T4 genes revealed that approximately five times more gene 17 mRNA and two to three times more gene 18 mRNA were synthesized in the Hp17 mutant infections. DNA-DNA hybridizations showed that Hp17 mutant DNA contained two to three times more copies of genes 17 and 18 than wild-type DNA. Southern blot analysis suggested that Hp17 mutants carry a direct tandem repeat of the gene 17-18 region, with variable copy number from one to at least six copies. Hyperproduction of gene 17 and 18 proteins appears therefore to result from gene amplification specific to the gene 17-18 region. In contrast to gene duplications reported in lambda and T4 phage, and numerous cases of gene amplification in bacteria, a similar or identical novel junctional fragment created by the amplification event was observed among 28 independent T4 Hp17 isolates; therefore, the mechanism giving gise to amplified sequences may involve specific sequences in this region of the T4 genome.

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.

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.

Activity of foreign proteins targeted within the bacteriophage T4 head and prohead: implications for packaged DNA structure.

The phage-derived expression, packaging, and processing (PEPP) system was used to target foreign proteins into the bacteriophage capsid to probe the intracapsid environment and the structure of packaged DNA. Small proteins with minimal requirements for activity were selected, staphylococcal nuclease (SN) and green fluorescent protein (GFP). These proteins were targeted into the T4 head by means of IPIII (internal protein III) fusions or CTS (capsid targeting sequence) fusions. Additional evidence is provided that foreign proteins are targeted into T4 by the N-terminal ten amino acid residue consensus CTS of IPIII identified in previous work. Fusion proteins were produced within host bacteria by expression from plasmids or by produc tion from recombinant phage carrying the fusion genes. Packaged fusion proteins CTS IPIII SN, CTS IPIII TSN, CTS IPIII GFP, CTS IPIII TGFP, and CTS GFP, where [symbol: see text] indicates a linkage peptide sequence Leu(Ile)-N-Glu cleaved by the T4 head morphogenetic proteinase gp21 during head maturation, are observed to exhibit intracapsid activity. SN activity within the head is demonstrated by loss of phage viability and by digested genomic DNA patterns visualized by gel electrophoresis when viable phage are incubated in Ca2+. Green fluorescent phage result immediately after packaging GFP produced at 30 degreesC and below, and continue to give green fluorescence under 470 nm light after CsCl purification. Non-fluorescent GFP-fusions are produced in bacteria at 37 degreesC, and phage packaged with these proteins achieve a fluorescent state after incubation for several months at 4 degreesC. GFP-packaged phage and proheads analyzed by fluorescence spectroscopy show that the mature head and the DNA-empty prohead package identical numbers of GFP-fusion proteins. Encapsidated GFP and SN can be injected into bacteria and rapidly exhibit intracellular activity. In vivo SN digestion of encapsidated DNA gives an intriguing pattern of DNA fragments by gel analysis, predominantly a repeat pattern of 160 bp multiples, reminiscent of a nucleosome digestion ladder, This quasi-limit DNA digestion pattern, reached >100-fold more slowly than the loss of titer, is invariant over a range

Capsid targeting sequence targets foreign proteins into bacteriophage T4 and permits proteolytic processing.

A membrane-independent morphogenetic viral signal peptide is identified within bacteriophage T4 internal protein III (IPIII). Utilizing a phagederived expression-packaging-processing system, which packages foreign proteins fused with IPIII into the phage capsid, a synthetic cleavage site introduced at the C terminus of IPIII, is demonstrated to be functional and permits processing of fusion proteins. IPIII, which possesses a native P21 cleavage site at its N terminus, is altered to possess a second P21 cleavage site at its C terminus where cleavage occurs by means of the scaffold proteinase P21 within the capsid. The altered IPIII was inserted into an expression vector to permit the creation of fusion proteins with staphylococcal nuclease, EcoRI endonuclease, beta-globin, and luciferase. Western immunoblot analysis of packaged T4eG326 indicates that the IPIII:fusion-proteins are packaged into phage and proteolytically processed, thus the synthetic P21 cleavage site positioned at the C terminus of IPIII is demonstrated to be functional, and 20 to 200 protein molecules are packaged per capsid. Truncation experiments identified the minimal portion of IPIII required to achieve targeting into the phage capsid as a ten amino acid residue from the N terminus, which includes the N-terminal methionine residue and the proteinase P21 cleavage site, designated the CTS (capsid targeting sequence). The addition of the CTS to a fragment of luciferase permits the protein to be packaged and processed, which demonstrates that the CTS is by itself sufficient to target foreign protein to the capsid. The imputed dual function of the CTS is supported by site-directed PCR mutagenesis, which reveals two functionally separate domains of the CTS for targeting and processing. The CTS appears to function in a core-related targeting mechanism that directs a polymorphic set of proteins into the T-even capsid or scaffold. Although structure formation is often assumed to involve extended protein interfaces, the analysis shows that a limited but specific sequence, the CTS, drives the interaction required to achieve targeting.

Mutational analysis of the sequence-specific recombination box for amplification of gene 17 of bacteriophage T4.

Bacteriophage T4 gene 17 amplification mutants Hp17 that carry two to six tandem repeats of the genes 17-18 region were isolated by growth of gene 17 amber mutants on ochre suppressor strains of Escherichia coli. These mutants arise from an initial sequence-specific recombination between two GCTCA sequences in a 24 bp imperfect homology box in genes 16 and 19. The initial recombination occurred in the wild-type phage T4 population, as shown by polymerase chain reaction, at a frequency of about 10(-6), which is consistent with the frequency of mutant isolation. T4 phage with mutations of the 3rd, 6th, 9th, 12th, or 15th positions in the 24 bp box of gene 16 either failed to produce gene amplification mutant Hp17 or produced gene amplification mutants from an initial recombination at other regions. Among the mutants that failed to produce gene amplification mutants, the initial recombination generally occurred at lower frequencies at either the GCTCA sequence or other sequences. Since the gene amplification mutations are eliminated or shifted to different sequences by base changes that increase as well as decrease homology, the predominant recombination event between the gene 16 and 19 recombination boxes appears to be sequence-dependent rather than homology-dependent.

Analysis of capsid portal protein and terminase functional domains: interaction sites required for DNA packaging in bacteriophage T4.

Bacteriophage DNA packaging results from an ATP-driven translocation of concatemeric DNA into the prohead by the phage terminase complexed with the portal vertex dodecamer of the prohead. Functional domains of the bacteriophage T4 terminase and portal gene 20 product (gp20) were determined by mutant analysis and sequence localization within the structural genes. Interaction regions of the portal vertex and large terminase subunit (gp17) were determined by genetic (terminase-portal intergenic suppressor mutations), biochemical (column retention of gp17 and inhibition of in vitro DNA packaging by gp20 peptides), and immunological (co-immunoprecipitation of polymerized gp20 peptide and gp17) studies. The specificity of the interaction was tested by means of a phage T4 HOC (highly antigenicoutercapsid protein) display system in which wild-type, cs20, and scrambled portal peptide sequences were displayed on the HOC protein of phage T4. Binding affinities of these recombinant phages as determined by the retention of these phages by a His-tag immobilized gp17 column, and by co-immunoprecipitation with purified terminase supported the specific nature of the portal protein and terminase interaction sites. In further support of specificity, a gp20 peptide corresponding to a portion of the identified site inhibited packaging whereas the scrambled sequence peptide did not block DNA packaging in vitro. The portal interaction site is localized to 28 residues in the central portion of the linear sequence of gp20 (524 residues). As judged by two pairs of intergenic portal-terminase suppressor mutations, two separate regions of the terminase large subunit gp17 (central and COOH-terminal) interact through hydrophobic contacts at the portal site. Although the terminase apparently interacts with this gp20 portal peptide, polyclonal antibody against the portal peptide appears unable to access it in the native structure, suggesting intimate association of gp20 and gp17 possibly internalizes terminase regions within the portal in the packasome complex. Both similarities and differences are seen in comparison to analogous sites which have been identified in phages T3 and lambda.

Bacteriophage T4 gene 17 amplification mutants: evidence for initiation by the T4 terminase subunit gp16.

Bacteriophage T4 genes 16 and 19 containing the 24 bp homology regions that recombine to form Hp17 mutants were cloned into plasmids. When the two homology sequences were cloned either together into one or separately into two compatible plasmids, a polymerase chain reaction assay showed that recombination occurred in vivo. The recombinant sequence was identical with that found in T4 phage Hp17 mutants, and was produced in recombination-deficient Escherichia coli. Mutational analysis revealed a requirement for functional gene 16 but not gene 17 to recombine the sequences. Moreover, gp16, the terminase small subunit, was required, since an amber gene 16 produced the recombinant sequence only when suppressed. Mutations in the gene 16 recombination sequence (3GA and 15TG) that eliminated Hp17 formation in T4 phage increased the synthesis of the large terminase subunit, gp17 in T4 infections, suggesting gp16 interaction with this site. gp16 binding to gene 16 and gene 19 pac-like sites may synapse the homologous sequences to lead to Hp17 mutant formation, and this suggests a synapsis mechanism for control of T4 DNA maturation and concatemer processing in packaging.

Membrane-associated assembly of a phage T4 DNA entrance vertex structure studied with expression vectors.

The DNA entrance vertex of the phage head is critical for prohead assembly and DNA packaging. A single structural protein comprises this dodecameric ring substructure of the prohead. Assembly of the phage T4 prohead occurs on the cytoplasmic membrane through a specific attachment at or near the gp20 DNA entrance vertex. An auxiliary head assembly gene product, gp40, was hypothesized to be involved in assembling the gp20 substructure. T4 genes 20, 40 and 20 + 40 were cloned into expression vectors under lambda pL promoter control. The corresponding T4 gene products were synthesized in high yield and were active as judged by their ability to complement the corresponding infecting T4 mutants in vivo. The cloned T4 gene 20 and gene 40 products were inserted into the cytoplasmic membrane as integral membrane proteins; however, gp20 was inserted into the membrane only when gp40 was also synthesized, whereas gp40 was inserted in the presence or absence of gp20. The gp20 insertion required a membrane potential, was not dependent upon the Escherichia coli groE gene, and assumed a defined membrane-spanning conformation, as judged by specific protease fragments protected by the membrane. The inserted gp20 structure could be probed by antibody binding and protein A-gold immunoelectron microscopy. The data suggest that a specific gp20-gp40-membrane insertion structure constitutes the T4 prohead assembly initiation complex.

Reiterated gene amplifications at specific short homology sequences in phage T4 produce Hp17 mutants.

Bacteriophage T4 gene 17 amplification mutants (Hp17) selected by growth of gene 17 amber mutants on ochre suppressor strains of Escherichia coli carry two to more than sixfold tandem head-to-tail repeats of the gene 17-18 region (Wu & Black, 1987). We characterized the structures of Hp17 isolates by restriction enzyme mapping and Southern blot analysis. The left and right boundaries of the amplified sequences were mapped within genes 16 and gene 18 or 19, respectively. The TaqI-restriction fragments containing the novel junctions arising from fusion of the amplified gene were then cloned and sequenced. Three Hp17 mutants arose from rearrangement in one five base-pair (bp) block within a G + C-rich region of partial homology (24 bp with 4 mismatches) between genes 16 and 19. Moreover, an oligonucleotide probe showed that 190/191 mutants isolated had recombined within the 5 bp block, and other rearrangements within this 24 bp region were not detected. Only one anomalous Hp mutant rearranged elsewhere between genes 16 and 18 in a 14 bp homology region with one mismatch. Elimination of gene alt of phage T4 is required for isolation of Hp17 mutants, apparently because more DNA can be packaged into alt- heads. Requirements for the dispensable replication and recombination genes of T4 were probed; T4 topoisomerase (39, 52, 60), primase (58/61), and uvsX are required, whereas the host recA gene and T4 denV gene do not appear to be required for isolation of the Hp17 mutants. The evidence suggests an initiating sequence-specific rearrangement leads to the T4 Hp17 amplification mutants.

Conformational changes of a viral capsid protein. Thermodynamic rationale for proteolytic regulation of bacteriophage T4 capsid expansion, co-operativity, and super-stabilization by soc binding.

We have used differential scanning calorimetry in conjunction with cryo-electron microscopy to investigate the conformational transitions undergone by the maturing capsid of phage T4. Its precursor shell is composed primarily of gp23 (521 residues): cleavage of gp23 to gp23* (residues 66 to 521) facilitates a concerted conformational change in which the particle expands substantially, and is greatly stabilized. We have now characterized the intermediate states of capsid maturation; namely, the cleaved/unexpanded, state, which denatures at tm = 60 degrees C, and the uncleaved/expanded state, for which tm = 70 degrees C. When compared with the precursor uncleaved/unexpanded state (tm = 65 degrees C), and the mature cleaved/expanded state (tm = 83 degrees C, if complete cleavage precedes expansion), it follows that expansion of the cleaved precursor (delta tm approximately +23 degrees C) is the major stabilizing event in capsid maturation. These observations also suggest an advantage conferred by capsid protein cleavage (some other phage capsids expand without cleavage): if the gp23-delta domains (residues 1 to 65) are not removed by proteolysis, they impede formation of the stablest possible bonding arrangement when expansion occurs, most likely by becoming trapped at the interface between neighboring subunits or capsomers. Icosahedral capsids denature at essentially the same temperatures as tubular polymorphic variants (polyheads) for the same state of the surface lattice. However, the thermal transitions of capsids are considerably sharper, i.e. more co-operative, than those of polyheads, which we attribute to capsids being closed, not open-ended. In both cases, binding of the accessory protein soc around the threefold sites on the outer surface of the expanded surface lattice results in a substantial further stabilization (delta tm = +5 degrees C). The interfaces between capsomers appear to be relatively weak points that are reinforced by clamp-like binding of soc. These results imply that the "triplex" proteins of other viruses (their structural counterparts of soc) are likely also to be involved in capsid stabilization. Cryo-electron microscopy was used to make conclusive interpretations of endotherms in terms of denaturation events. These data also revealed that the cleaved/unexpanded capsid has an angular polyhedral morphology and has a pronounced relief on its outer surface. Moreover, it is 14% smaller in linear dimensions than the cleaved/expanded capsid, and its shell is commensurately thicker.

Assembly-dependent conformational changes in a viral capsid protein. Calorimetric comparison of successive conformational states of the gp23 surface lattice of bacteriophage T4.

Inter- and intra-subunit bonding within the surface lattice of the capsid of bacteriophage T4 has been investigated by differential scanning calorimetry of polyheads, in conjunction with electron microscopy, limited proteolysis and sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The bonding changes corresponding to successive stages of assembly of the major capsid protein gp23, including its maturation cleavage, were similarly characterized. The uncleaved/unexpanded surface lattice exhibits two endothermic transitions. The minor event, at 46 degrees C, does not visibly affect the surface lattice morphology and probably represents denaturation of the N-terminal domain of gp23. The major endotherm, at 65 degrees C, represents denaturation of the gp23 polymers. Soluble gp23 from dissociated polyheads is extremely unstable and exhibits no endotherm. Cleavage of gp23 to gp23* and the ensuing expansion transformation effects a major stabilization of the surface lattice of polyheads, with single endotherms whose melting temperatures (t*m) range from 73 to 81 degrees C, depending upon the mutant used and the fraction of gp23 that is cleaved to gp23* prior to expansion. Binding of the accessory proteins soc and hoc further modulates the thermograms of cleaved/expanded polyheads, and their effects are additive. hoc binding confers a new minor endotherm at 68 degrees C corresponding to at least partial denaturation of hoc. Denatured hoc nevertheless remains associated with the surface lattice, although in an altered, protease-sensitive state which correlates with delocalization of hoc subunits visualized in filtered images. While hoc binding has little effect on the thermal stability of the gp23* matrix, soc binding further stabilizes the surface lattice (delta Hd approximately +50%; delta t*m = +5.5 degrees C). It is remarkable that in all states of the surface lattice, the inter- and intra-subunit bonding configurations of gp23 appear to be co-ordinated to be of similar thermal stability. Thermodynamically, the expansion transformation is characterized by delta H much less than 0; delta Cp approximately 0, suggesting enhancement of van der Waals' and/or H-bonding interactions, together with an increased exposure to solvent of hydrophobic residues of gp23* in the expanded state. These findings illuminate hypotheses of capsid assembly based on conformational properties of gp23: inter alia, they indicate a role for the N-terminal portion of gp23 in regulating polymerization, and force a reappraisal of models of capsid swelling based on the swivelling of conserved domains.

Phage display of intact domains at high copy number: a system based on SOC, the small outer capsid protein of bacteriophage T4.

Peptides fused to the coat proteins of filamentous phages have found widespread applications in antigen display, the construction of antibody libraries, and biopanning. However, such systems are limited in terms of the size and number of the peptides that may be incorporated without compromising the fusion proteins' capacity to self-assemble. We describe here a system in which the molecules to be displayed are bound to pre-assembled polymers. The polymers are T4 capsids and polyheads (tubular capsid variants) and the display molecules are derivatives of the dispensable capsid protein SOC. In one implementation, SOC and its fusion derivatives are expressed at high levels in Escherichia coli, purified in high yield, and then bound in vitro to separately isolated polyheads. In the other, a positive selection vector forces integration of the modified soc gene into a soc-deleted T4 genome, leading to in vivo binding of the display protein to progeny virions. The system is demonstrated as applied to C-terminal fusions to SOC of (1) a tetrapeptide; (2) the 43-residue V3 loop domain of gp120, the human immunodeficiency virus type-1 (HIV-1) envelope glycoprotein; and (3) poliovirus VP1 capsid protein (312 residues). SOC-V3 displaying phage were highly antigenic in mice and produced antibodies reactive with native gp120. That the fusion protein binds correctly to the surface lattice was attested in averaged electron micrographs of polyheads. The SOC display system is capable of presenting up to approximately 10(3) copies per capsid and > 10(4) copies per polyhead of V3-sized domains. Phage displaying SOC-VP1 were isolated from a 1:10(6) mixture by two cycles of a simple biopanning procedure, indicating that proteins of at least 35 kDa may be accommodated.

In vitro packaging into phage T4 particles and specific recircularization of phage lambda DNAs.

Concatemeric phage lambda imm434 DNA packaged in vitro into phage T4 particles produced plaques on a selective host. Moreover, lambda DNA containing a pBR322 derivative flanked by the lambda attL and attR sites could be specifically recircularized by excisive lambda recombination to yield the pBR322 derivative. A host deficient in generalized recombination and containing a defective lambda c Its prophage which provided Int and Xis proteins was the recipient for this plasmid derivative carried by T4. Such a T4-lambda hybrid may potentially allow almost one T4 headful of donor DNA (166 kb) to be packaged and recircularized.

Cloning, sequence, and expression of the temperature-dependent phage T4 capsid assembly gene 31.

The products of the bacteriophage T4 capsid assembly gene 31, the T4 major capsid protein gene 23, and the Escherichia coli heat-shock groE genes participate in an interdependent mechanism in capsid protein oligomerization early in prohead assembly. Gene 31 was cloned, sequenced and expressed, and its regulation during infection was characterized. Gene 31 is more stringently required at high than at low temperature, and this requirement is reduced by temperature adaptation of the bacteria prior to infection. However, T4 gene 31 expression does not appear to be temperature regulated, nor does gene 31 apparently display sequence homology with the E. coli groE and other heat-shock genes.

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.

An expression-packaging-processing vector which selects and maintains 7-kb DNA inserts in the blue T4 phage genome.

We have developed an efficient positive-selection vector to insert foreign DNA segments fused to the T4 ipIII gene (encoding internal protein IPIII) into the bacteriophage T4 genome. By using partial deletions of the T4 e gene, which encodes phage lysozyme, lysozyme activity required for plaque formation is used to select plasmid integrants which restore the e gene. In this work, we demonstrate that DNA inserts more than 7.0 kb in length can be incorporated into a T4 genome lacking the alt gene. In addition, the recombinant T4 not only contains a fusion gene driven by the T4 ipIII promoters, but also packages the fusion protein into the T4 capsid due to targeting by the IPIII portion. This expression-packaging-processing system shows that active IPIII::beta Gal fusion reporter protein is produced and packaged during phage infection.

A phage T4 in vitro packaging system for cloning long DNA molecules.

Recombinant plasmid DNAs containing long DNA inserts that can be propagated in Escherichia coli would be useful in the analysis of complex genomes. We tested a bacteriophage T4 in vitro DNA packaging system that has the capacity to package about 170 kb of DNA into its capsid for cloning long DNA fragments. We first asked whether the T4 in vitro system can package foreign DNA such as concatemerized lambda imm434 DNA and phage P1-pBR322 hybrid DNA. The data suggest that the T4 system can package foreign DNA as efficiently as the mature phage T4 DNA. We then tested the system for its ability to clone foreign DNA fragments using the P1-pBR322 hybrid vectors constructed by Sternberg [Proc. Natl. Acad. Sci. USA 87 (1990) 103-107]. E. coli genomic DNA fragments were ligated with the P1 vectors containing two directly oriented loxP sites, and the ligated DNA was packaged by the T4 in vitro system. The packaged DNA was then transduced into E. coli expressing the phage P1 cyclization recombination protein recombinase to circularize the DNA by recombination between the loxP sites situated at the ends of the transduced DNA molecule. Clones with long DNA inserts were obtained by using this approach, and these were maintained as single-copy plasmids under the control of the P1 plasmid replicon. Clones with up to about 122-kb size inserts were recovered using this approach.

Cloning of linear DNAs in vivo by overexpressed T4 DNA ligase: construction of a T4 phage hoc gene display vector.

A method was developed to clone linear DNAs by overexpressing T4 phage DNA ligase in vivo, based upon recombination deficient E. coli derivatives that carry a plasmid containing an inducible T4 DNA ligase gene. Integration of this ligase-plasmid into the chromosome of such E. coli allows standard plasmid isolation following linear DNA transformation of the strains containing high levels of T4 DNA ligase. Intramolecular ligation allows high efficiency recircularization of cohesive and blunt-end terminated linear plasmid DNAs following transformation. Recombinant plasmids could be constructed in vivo by co-transformation with linearized vector plus insert DNAs, followed by intermolecular ligation in the T4 ligase strains to yield clones without deletions or rearrangements. Thus, in vitro packaged lox-site terminated plasmid DNAs injected from phage T4 were recircularized by T4 ligase in vivo with an efficiency comparable to CRE recombinase. Clones that expressed a capsid-binding 14-aa N-terminal peptide extension derivative of the HOC (highly antigenic outer capsid) protein for T4 phage hoc gene display were constructed by co-transformation with a linearized vector and a PCR-synthesized hoc gene. Therefore, the T4 DNA ligase strains are useful for cloning linear DNAs in vivo by transformation or transduction of DNAs with nonsequence-specific but compatible DNA ends.

Protection from proteolysis using a T4::T7-RNAP phage expression-packaging-processing system.

DNA coding for bacteriophage T7 RNA polymerase (T7-RNAP) was inserted into a positive selection-vector form of the T4 genome, placing it under the control of bacteriophage T4 ipIII promoters. The recombinant T4::T7-RNAP fusion phage retained infectivity and produced T7-RNAP in infected cells. Fusion genes were constructed by insertion into a plasmid containing an iPIII (encoding internal protein III) target portion and a bacteriophage T7 promoter region. When Escherichia coli cells containing the plasmid were infected with the T4::T7-RNAP re-phage, the bacteria produced fusion protein at high levels. The newly synthesized T4::T7-RNAP re-phage progeny package and process the fusion protein into the phage capsid during head morphogenesis. In this paper, we demonstrate that truncated T4 internal protein IPIII, human IPIII::beta Glo (beta-globin) fusion protein, E. coli IPIII::beta Glo::beta Gal (beta-galactosidase) triple-fusion protein and IPIII::V3 fusion protein (human immunodeficiency virus envelope protein gp120 V3 region) are expressed at high levels by T4::T7-RNAP induction. With IPIII::beta Glo, expression-packaging-processing (EPP) occurs simultaneously with T4::T7-RNAP re-phage infection. We also demonstrate that T4::T7-RNAP re-phage stabilize unstable proteins such as the X90 fragment of beta Gal, thought to be degraded by the lon protease. An unstable 20-kDa fragment of the large subunit of human cytochrome b558, an integral membrane protein in phagocytes, is subject to proteolytic degradation even when produced in the lon-deficient BL21 strain. However, upon induction with T4::T7-RNAP re-phage, the 20-kDa protein is produced intact.(ABSTRACT TRUNCATED AT 250 WORDS)