Maturation of bacteriophage P2 DNA in vitro: A complex, site-specific system for DNA cleavage

Bacteriophage P2

P2 is the original member of a highly successful family of temperate phages that are frequently found in the genomes of gram-negative bacteria. This article focuses on the organization of the P2 genome and reviews current knowledge about the function of each open reading frame.

Production of highly knotted DNA by means of cosmid circularization inside phage capsids

BACKGROUND

The formation of DNA knots is common during biological transactions. Yet, functional implications of knotted DNA are not fully understood. Moreover, potential applications of DNA molecules condensed by means of knotting remain to be explored. A convenient method to produce abundant highly knotted DNA would be highly valuable for these studies.

RESULTS

We had previously shown that circularization of the 11.2 kb linear DNA of phage P4 inside its viral capsid generates complex knots by the effect of confinement. We demonstrate here that this mechanism is not restricted to the viral genome. We constructed DNA cosmids as small as 5 kb and introduced them inside P4 capsids. Such cosmids were then recovered as a complex mixture of highly knotted DNA circles. Over 250 mug of knotted cosmid were typically obtained from 1 liter of bacterial culture.

CONCLUSION

With this biological system, DNA molecules of varying length and sequence can be shaped into very complex and heterogeneous knotted forms. These molecules can be produced in preparative amounts suitable for systematic studies and applications.

Assembly of bacteriophage P2 and P4 procapsids with internal scaffolding protein

Assembly of the E. coli bacteriophage P2 into an icosahedral capsid with T = 7 symmetry is dependent on the gpN capsid protein, the gpQ connector protein and the gpO internal scaffolding protein. In the presence of the P4-encoded protein Sid, the same proteins are assembled into a smaller capsid with T = 4 symmetry. Although gpO has long been expected to act as an internal scaffolding protein, it has not been possible to produce P2 procapsids efficiently in vitro or in vivo due to a failure to express gpO at high levels. In this study, we find that full-length gpO undergoes proteolytic degradation within 1 h of induction of expression. However, a truncated version of gpO lacking the N-terminal 25 amino acids (Odelta25) is stably expressed at high levels and is able to direct the formation of P2 size procapsids. In the presence of Sid, Odelta25 is incorporated into P4 procapsids, showing that Sid overrides the effect of gpO on capsid size determination.

The late-expressed region of the temperate coliphage 186 genome

The late-lytic region of the genome of bacteriophage 186 encodes the phage proteins that synthesize the complex viral particle and lyse the bacterial host. We report the completion of the DNA sequence of the late region and the assignment of 18 previously identified genes to open reading frames in the sequence. The 186 late region is similar to the late region of phage P2, sharing 26 genes of known function: the single gene for activation of late gene transcription, 6 genes for construction of DNA-containing heads, 16 for tail morphogenesis, and 3 for cell lysis. We identified two 186 late genes with unknown function; one is homologous to previously unrecognised genes in P2, HP1, and phiCTX, and the other may modulate DNA packaging. The 186 late region, like the rest of the genome, lacks the lysogenic conversion genes that are carried by P2, allowing the 186 late region to be transcribed from only three late promoters rather than four. The relative absence of lysogenic conversion genes in 186 suggests that the two phages have evolved to use the lytic and lysogenic reproductive modes to different extents.

In vitro assembly of infectious virions of double-stranded DNA phage phi 29 from cloned gene products and synthetic nucleic acids

Up to 6 x 10(7) PFU of infectious virions of the double-stranded DNA bacteriophage phi 29 per ml were assembled in vitro, with 11 proteins derived from cloned genes and nucleic acids synthesized separately. The genomic DNA-gp3 protein conjugate was efficiently packaged into a purified recombinant procapsid with the aid of a small viral RNA (pRNA) transcript, a DNA-packaging ATPase (gp16), and ATP. The DNA-filled capsids were subsequently converted into infectious virions after the addition of four more recombinant proteins for neck and tail assembly. Electron microscopy and genome restriction mapping confirmed the identity of the infectious phi 29 virions synthesized in this system. A nonstructural protein, gp13, was indispensable for the assembly of infectious virions. The overproduced tail protein gp9 was present in solution in mostly dimeric form and was purified to homogeneity. The purified gp9 was biologically active for in vitro phi 29 assembly. Higher-order concentration dependence of in vitro phi 29 assembly on gp9 suggests that a complete tail did not form before attaching to the DNA-filled capsid, a result contrary to earlier findings for phages T4 and lambda. The work described here constitutes an extremely sensitive assay system for the analysis of components in phi 29 assembly and dissection of functional domains of structural components, enzymes, and pRNA (C.-S. Lee and P. Guo, Virology 202:1039-1042, 1995). Efficient packaging of foreign DNA in vitro and synthesis of viral particles from recombinant proteins facilitate the development of phi 29 as an in vivo gene delivery system. The finding that purified tail protein was able to incorporate into infectious virions might allow the construction of chimeric phi 29 carrying a tail fused to ligands for specific receptor of human cells.

Structure of viral connectors and their function in bacteriophage assembly and DNA packaging

The viruses have been an attractive model for the study of basic mechanisms of protein/protein and protein/nucleic acid interactions involved in the assembly of macromolecular aggregates. This has been due primarily to their relative genetic simplicity as compared to their structural and functional complexity. Although most of the initial studies were carried out on bacterial and plant viruses, increasing data has also been accumulated from animal viruses, which has led to an understanding of some basic principles, as well as to many specific strategies in every system. The study of virus assembly has been a source of ideas that underlie our present knowledge of the organization of biological systems. It has also provided, since the production of bacteriophage mutants which have allowed the study of assembly intermediates, the first system in which the genetic studies played a dominant role. The increasing volume of data over the last years has revealed how the structural components can interact sequentially through an ordered pathway to yield macromolecular assemblies that satisfy the demands of stability required for a successful transfer of genetic information from host to host.

Mechanisms of genome propagation and helper exploitation by satellite phage P4

Temperate coliphage P2 and satellite phage P4 have icosahedral capsids and contractile tails with side tail fibers. Because P4 requires all the capsid, tail, and lysis genes (late genes) of P2, the genomes of these phages are in constant communication during P4 development. The P4 genome (11,624 bp) and the P2 genome (33.8 kb) share homologous cos sites of 55 bp which are essential for generating 19-bp cohesive ends but are otherwise dissimilar. P4 turns on the expression of helper phage late genes by two mechanisms: derepression of P2 prophage and transactivation of P2 late-gene promoters. P4 also exploits the morphopoietic pathway of P2 by controlling the capsid size to fit its smaller genome. The P4 sid gene product is responsible for capsid size determination, and the P2 capsid gene product, gpN, is used to build both sizes. The P2 capsid contains 420 capsid protein subunits, and P4 contains 240 subunits. The size reduction appears to involve a major change of the whole hexamer complex. The P4 particles are less stable to heat inactivation, unless their capsids are coated with a P4-encoded decoration protein (the psu gene product). P4 uses a small RNA molecule as its immunity factor. Expression of P4 replication functions is prevented by premature transcription termination effected by this small RNA molecule, which contains a sequence that is complementary to a sequence in the transcript that it terminates.

Control of gene expression in the temperate coliphage 186. IX. B is the sole phage function needed to activate transcription of the phage late genes

Using plasmid clones we have determined that the late control function B is the only phage function that is needed to activate a late promoter of coliphage 186, and we predict that it functions as an auxiliary factor to RNA polymerase in the activation of late transcription. We have also shown that a high concentration of B will activate late transcription from a prophage, and we conclude that replicating DNA is not a template requirement for B to function. The original demonstration of a need for the replication gene A in late transcription can be explained by the fact that replication leads to an increase in B gene dosage, with the consequent increase in B concentration leading to the efficient activation of the late promoters.

Nucleotide sequence of the DNA packaging and capsid synthesis genes of bacteriophage P2

Overlapping DNA fragments containing the DNA packaging and capsid synthesis gene region of bacteriophage P2 were cloned and sequenced. In this report we present the complete nucleotide sequence of this 6550 bp region. Each of six open reading frames found in the interval was assigned to one of the essential genes (Q, P, O, N, M and L) by correlating genetic, physical and mutational data with DNA and protein sequence information. Polypeptides predicted were: a capsid completion protein, gpL; the major capsid precursor, gpN; the presumed capsid scaffolding protein; gpO; the ATPase and proposed endonuclease subunits of terminase, gpP and gpM, respectively; and a candidate for the portal protein, gpQ. These gene and protein sequences exhibited no homology to analogous genes or proteins of other bacteriophages. Expression of gene Q in E. coli from a plasmid caused production of a Mr 39,000 Da protein that restored Qam34 growth. This sequence analysis found only genes previously known from analysis of conditional-lethal mutations. No new capsid genes were found.

Characterization of the cos sites of bacteriophages P2 and P4

A 641-bp cos-containing P2 DNA fragment was sequenced and compared to the P4 cos region. Alignment of the P2 and P4 cos regions shows a homologous region of 55 bp that has only three mismatches and contains a completely conserved region of dyad symmetry. A number of P4- and P2-derived cosmids were tested in an in vivo transduction assay in order to determine the minimal cos region required for packaging. These experiments show that the common region of 55 bp is sufficient for transduction with low frequency, but that a 125-bp cos-containing fragment contains all the information for transduction with optimal frequency.

Essential interaction between lambdoid phage 21 terminase and the Escherichia coli integrative host factor

Lambdoid phage 21 requires the Escherichia coli integrative host factor (IHF) for growth. lambda-21 hybrids that have 21 DNA packaging specificity also require IHF. IHF-independent (her) mutants have been isolated. her mutations map in the amino-terminal half of the 21 1 gene. The 1 gene encodes the small subunit of the 21 terminase, and the amino-terminal half of the 1 polypeptide is a functional domain for specifically binding 21 DNA. Hence changes in the DNA-binding domain of terminase, her mutations, render 21 terminase able to function in the absence of IHF. Three of four her mutations studied are trans-dominant. An in vitro system was used to show that packaging of 21 DNA is IHF-dependent. IHF is directly required during the early, terminase-dependent steps of assembly. It is concluded that IHF is a host factor required for function of the 21 terminase. It is proposed, in analogy to the role of IHF in lambda integration, that IHF facilitates proper binding of 21 terminase to phage DNA. Consistent with this proposal, possible IHF-binding sites are present in the 21 cohesive end site.

Bacteriophage phi 29 proteins required for in vitro DNA-gp3 packaging

In vitro assembly of bacteriophage phi 29 in crude extracts involves efficient packaging of a DNA-protein complex (DNA- gp3 ) into a prohead with the aid of the gene 16 product ( gp16 ) and subsequent assembly of neck and tail proteins ( Bjornsti et al., J. Virol. 41:508-517, 1982; Bjornsti et al., J. Virol. 45:383-396, 1983; Bjornsti et al., Proc. Natl. Acad. Sci. U.S.A. 78:5861-5865, 1981). To define the viral proteins required for the DNA- gp3 encapsidation phase, we purified biologically active proheads and DNA- gp3 and constructed a chimeric plasmid, pUM101 , which contained and expressed gene 16 of phi 29 and no other viral genes. The plasmid-specified gp16 was both necessary and sufficient to package 24% of the DNA- gp3 added to the purified proheads , and the DNA-filled heads so produced were efficiently complemented to infectious phage by the addition of neck and tail proteins. Purified proheads and DNA- gp3 gave linear dose-response curves with slopes of approximately 1; in contrast, a 4-fold dilution of gp16 resulted in a 1,000-fold reduction of phi 29, suggesting a requirement for multiple copies of this protein.

Cloning of the glutamine synthetase I gene from Rhizobium meliloti

Glutamine synthetase is a major enzyme in the assimilation of ammonia by members of the genus Rhizobium. Two forms of glutamine synthetase are found in members of the genus Rhizobium, a heat-stable glutamine synthetase I (GSI) and a heat-labile GSII. As a step toward clarifying the role of these enzymes in symbiotic nitrogen fixation, we have cloned the structural gene for GSI from Rhizobium meliloti 104A14. A gene bank of R. meliloti was constructed by using the bacteriophage P4 cosmid pMK318. Cosmids that contain the structural gene for GSI were isolated by selecting for plasmids that permit ET8051, an Escherichia coli glutamine autotroph, to grow with ammonia as the sole nitrogen source. One of the cosmids, pJS36, contains an insert of 11.9 kilobases. ET8051(pJS36) grows slowly on minimal media. When a 3.7-kilobase HindIII fragment derived from this DNA is cloned into the HindIII site of pACYC177 and the plasmids are transformed into ET8051, rapid growth is observed when the insert is in one orientation (pJS44) but not the other (pJS45). Glutamine synthetase activity can be detected in ET8051(pJS44); most of this activity is heat stable. pJS36 hybridizes with the glnA structural gene from Escherichia coli. Insertion of a 2.7-kilobase Tetr determinant into a BglII site located within pJS44 abolishes all glutamine synthetase activity. This interrupted version of a glutamine synthetase gene was substituted for the normal R. meliloti sequence by homologous recombination in R. meliloti. Recombinants lose GSI activity, but retain GSII activity and grow well with ammonia as the sole nitrogen source. These mutants are unaffected in nodulation and nitrogen fixation.

Bacteriophage P2 late promoters. Transcription initiation sites for two late mRNAs

Divergent transcription of two of the bacteriophage P2 late mRNAs, encoding genes QP and ONMLKRS, is initiated from opposite strands of the DNA in a region near the left end of the P2 genome. The first gene in each of these transcription units (P and O) has been located in the nucleotide sequence by amino-terminal sequence analysis of the P gene product and by DNA sequence determination of the single nucleotide changes in two O amber mutants. The 5' ends of the P and O gene mRNAs are separated by 109 nucleotide pairs in the DNA template. The locations of these 5' termini were determined by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with nuclease S1. Sequence analysis of mRNA that had been labeled at the 5' end with [alpha-32P]GTP and guanylyl transferase confirmed that these termini resulted from initiation of transcription. The DNA sequences preceding the O and P transcription starts have poor homologies to the bacterial promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The O and P promoter regions also have no detectable homology to each other in the -10 or -35 regions, and are unusually G + C-rich. There are, however, blocks of sequence homology within the transcribed region of each of these two late operons near the 5' end. Satellite phage P4 induces P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 P and O gene transcripts are the same during P4 "transactivation" as during normal P2 late gene expression. Thus the regulation of P2 late gene expression by P4 does not involve a change in the site for initiation of transcription.

In vitro assembly of the Bacillus subtilis bacteriophage phi 29

In vitro assembly of the Bacillus subtilis bacteriophage phi 29 that approaches the efficiency of assembly in vivo has been demonstrated. Proheads, DNA, and gene 16 product (gp16) were essential for DNA encapsidation, and the average yield in extracts was 180 phage per prohead donor cell. The in vitro maturation was very similar to in vivo assembly in terms of yield, intermediates, and abortive structures. More that 30% of the proheads in the extract were converted to phage, and about 20% of DNA--protein extracted from phage could be repackaged. In vitro assembly was blocked by the addition of DNase I, EDTA, pyrophosphatase, or the ATP analogues adenosine 5'-[alpha, beta-methylene]triphosphate and adenosine 5'-[beta, gamma-methylene]triphosphate. Less than 1% of the proheads isolated in sucrose gradients can accept DNA--protein in packaging in vitro.

Genetic analysis of bacteriophage P4 using P4-plasmid ColE1 hybrids

A set of plasmids that contain fragments of the bacteriophage P4 genome has been constructed by deleting portions of a P4-ColE1 hybrid. A P4 genetic map has been established and related to the physical map by examining the ability of these plasmids to rescue various P4 mutations. The P4 virl mutation and P4 genes involved in DNA replication (alpha), activation of P2 helper genes (delta and epsilon), polarity suppression (psu) and head size determination (sid) have been mapped, as has the region responsible for synthesis of a nonessential P4 protein. One of the deleted plasmids contains only 5900 base pairs (52%) of P4 but will form plaques if additional DNA is added to increase its total size to near that of P4. This plasmid is also unique in that it will not form stable associations with P2 lysogens of E. coli which are recA+. P4 alpha mutants can be suppressed as a result of replication under control of the ColE1 part of the hybrid.