Packaging of genomes in bacteriophages: a comparison of ssRNA bacteriophages and dsDNA bacteriophages.

In complex DNA bacteriophages like lambda, T4, T7, P22, P2, the DNA is packaged into a preformed precursor particle which sometimes has a smaller size and often a shape different from that of the phage head. This packaging mechanism is different from the one suggested for the RNA phages, according to which RNA nucleates the shell formation. The different mechanisms could be understood by comparing the genomes to be packaged: single stranded fII RNA has a very compact structure with high helix content. It might easily form quasispherical structures in solution (as seen in the electron microscope by Thach & Thach (1973)) around which the capsid could assemble. Double stranded phage DNA, on the other hand, is a rigid molecule which occupies a large volume in solution and has to be concentrated 15-fold during packaging into the preformed capsid, and the change in the capsid structure observed hereby might provide the necessary DNA condensation energy.     

RNA-mediated specificity of DNA packaging into hybrid lambda/phi 29 proheads.

A small RNA (pRNA, 174 nt) is known to be essential for DNA packaging in bacteriophage phi 29. However, in an in vitro DNA packaging system based on hybrid lambda/phi 29 proheads (made up of head proteins from phage lambda and connectors from phage phi 29), the specificity of DNA packaging is lost, and different RNA molecules fulfil the requirements for DNA packaging, albeit with less efficiency than phi 29 pRNA. Competition assays with RNAs from different sources have shown that phi 29 connectors bind preferentially pRNA. An increase in the efficiency of phi 29 DNA packaging into hybrid proheads induced by phi 29 pRNA is observed because, when phi 29 pRNA is incubated with hybrid proheads, phi 29 DNA is packaged more efficiently than other DNAs of similar length. Furthermore, when hybrid proheads carrying phi 29 pRNA are incubated with a mixture of DNAs from different sources, phi 29 DNA is selectively packaged, thus indicating that phi 29 pRNA determines the specificity of DNA packaging.     

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.     

Common sites for recombination and cleavage mediated by bacteriophage T4 DNA topoisomerase in vitro

We have previously shown that purified T4 DNA topoisomerase promotes illegitimate recombination between two lambda DNA molecules, or between lambda and plasmid DNA in vitro (Ikeda, H. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 922-926). Since the recombinant DNA contains a duplication or deletion, it is inferred that the cross-overs take place between nonhomologous sequences of lambda DNA. In this paper, we have examined the sequences of the recombination junctions produced by the recombination between two lambda DNA molecules mediated by T4 DNA topoisomerase. We have shown that there is either no homology or there are 1-5-base pair homologies between the parental DNAs in seven combinations of lambda recombination sites, indicating that homology is not essential for the recombination. Next, we have shown an association of the recombination sites with the topoisomerase cleavage sites, indicating that a capacity of the topoisomerase to make a transient double-stranded break in DNA plays a role in the illegitimate recombination. A consensus sequence for T4 topoisomerase cleavage sites, RNAY decreases NNNNRTNY, was deduced. The cleavage experiment showed that T4 topoisomerase-mediated cleavage takes place in a 4-base pair staggered fashion and produces 5'-protruding ends.     

Packaging of ColE1 DNA having a lambda phage cohesive end site.

The mechanism of lambda phage-mediated transduction of hybrid colicin E1 DNAs of various lengths was studied, and factors influencing the formation of these transducing particles were investigated. The results were as follows: 1. The presence of a cohesive end site of lambda phage (coslambda) on colicin E1 DNA was essential for packaging of the DNA. 2. Packaging of colicin E1 DNAs, which carry coslambda with molecular sizes corresponding to 68% of that of lambda phage DNA, was observed in the absence of all known recombination functions of E. coli K-12 and of lambda phage. 3. Hybrid colicin E1 DNAs having coslambda with molecular sizes corresponding to 28% of that of lambda phage DNA were packaged within lambda phage particles as trimers; hybrid DNAs with coslambda of 40 and 47% of the length of lambda phage DNA were packaged as dimers; and those with molecular sizes of 68% of that of lambda phage DNA were packaged mostly as monomers. These results demonstrated that two factors are essential for the packaging of DNAs within lambda phage particles; the presence of coslambda on the DNA molecule and an appropriate size of DNA.     

Structure and inherent properties of the bacteriophage lambda head shell. IV. Small-head mutants

Missense mutants of bacteriophage lambda that produce small proheads were found among prophage mutants defective in the major head protein gpE. Measurements of the sedimentation coefficient and molecular weight of the small proheads showed that they have the T = 4 structure composed of 240 molecules of gpE instead of the wild-type T = 7 structure composed of 420 molecules of gpE. When the phage mutants were grown in groE mutants of Escherichia coli, they produced small unprocessed proheads, which contained a smaller number (about 60) of the core protein (gpNu3) molecules than normal unprocessed proheads, which contain about 180 molecules of gpNu3. This shows that the major head protein determines the size of not only the shell but also the core of unprocessed proheads. These mutants by themselves produce very few mature small-headed phage particles, partly because the lambda DNA molecule, whose cos sites are separated at a distance of 48,500 bases, is too long to be packaged into the small proheads. However, the small proheads can package shorter DNA in vivo and in vitro at somewhat reduced efficiency, if the length or a multiple of the length between the cos sites of the DNA is 13,000 to 19,000 bases.     

Insertion of the cos-site into DNA of phage M13 and its packing in proteins of phage lambda

The cos-site of lambda phage from pHC79 cosmide is transferred to DNA from M13 mp18 phage. The recombinant DNA thus obtained (MC18) is efficiently packaged into lambda proteins in vitro. The BamHI-HindIII fragment of pGP588 (a pBR322 derivatives containing fragment of human DNA) is subcloned into MC18. Although this pGP588 fragment contains numerous Alu repeats, no essential rearrangements of the insert were revealed. The efficiency infection by recombinant DNA packaged with lambda proteins is about 1 X 10(5) pfu/microgram DNA, whereas in the similar conditions the efficiency of lambda EMBL3A was 1 X 10(6) pfu/microgram. It is assumed that the MC vectors might be suitable for cloning and sequencing large fragments either with cohesive or blunt ends. It opens also the way to construct genomic libraries in single-stranded phages.     

Topoisomerase II and other DNA-delay and DNA-arrest mutations impair bacteriophage T4 DNA packaging in vivo and in vitro.

A survey of DNA packaging in vivo and in vitro during infections caused by T4 DNA-delay and DNA-arrest amber mutants revealed a common DNA packaging-deficient phenotype. Electron microscopy revealed high proportions of proheads partially filled with DNA in vivo, indicating normal initiation but incomplete encapsidation. In contrast, exogenous mature T4 DNA was packaged in vitro by several early-gene mutant extracts. Detailed analysis of gene ts39 mutants (subunit of topoisomerase II) showed that in vivo packaging is defective, yet expression of late proteins appeared normal and the concatemeric DNA was not abnormally short or nicked. Although g39 amber mutant extracts packaged DNA in vitro, two of three ts39 mutant extracts prevented encapsidation of the exogenous DNA. The temperature-sensitive (ts) gp39 in a mutant topoisomerase II complex may have interfered with packaging in vivo and in vitro by interacting with DNA in an anomalous fashion, rendering it unfit for encapsidation. These results support the hypothesis that T4 DNA packaging is sensitive to DNA structure and discriminates against encapsidation of some types of defective DNA.     

DNA poised for release in bacteriophage phi29

We present here the first asymmetric, three-dimensional reconstruction of a tailed dsDNA virus, the mature bacteriophage phi29, at subnanometer resolution. This structure reveals the rich detail of the asymmetric interactions and conformational dynamics of the phi29 protein and DNA components, and provides novel insight into the mechanics of virus assembly. For example, the dodecameric head-tail connector protein undergoes significant rearrangement upon assembly into the virion. Specific interactions occur between the tightly packed dsDNA and the proteins of the head and tail. Of particular interest and novelty, an approximately 60A diameter toroid of dsDNA was observed in the connector-lower collar cavity. The extreme deformation that occurs over a small stretch of DNA is likely a consequence of the high pressure of the packaged genome. This toroid structure may help retain the DNA inside the capsid prior to its injection into the bacterial host.     

Model for DNA packaging into bacteriophage T4 heads.

The mechanism of DNA packaging into bacteriophage T4 heads in vivo was investigated by glucosylation of hydroxymethylcytosine residues in a conditionally glucose-deficient host. Cytoplasmic DNA associated with partially packaged ts49 heads can be fully glucosylated, whereas DNA already packaged into these heads is shown to be resistant to glucosylation. After temperature shift and completion of arrested packaging into the reversible temperature-sensitive ts49 head, the structure of the DNA in the mature ts49 phage was investigated by restriction enzyme digestion, autoradiography, and other techniques. Such mature DNA appears to be fully glucosylated along part of its length and nonglucosylated on the remainder. Its structure suggests that the DNA is run into the head linearly and unidirectionally from one mature end and that there is little sequence specificity in that portion of the T4 DNA which first enters the capsid. This technique should be useful in investigation of the three-dimensional structure of first- and last-packaged DNA within the head; preliminary studies including autoradiography of osmotically shocked phage suggest that the DNA which first enters the head is deposited toward the center of the capsid and that the end of the DNA which first enters the head exits first upon injection. In conjunction with studies of the structure of condensed DNA, the positions and functions of T4 capsid proteins in DNA packaging, and the order of T4 packaging functions [Earnshaw and Harrison, Nature (London) 268:598-602, 1977; Hsiao and Black, Proc. Natl. Acad. Sci. U.S.A. 74:3652-3656, 1977; Müller-Salamin et al., J. Virol. 24:121-134, 1977; Richards et al., J. Mol. Biol. 78:255-259, 1973], the features described above suggest the following model: the first DNA end is fixed to the proximal apex of the head at p20 and the DNA is then pumped into the head enzymatically by proteins (p20 + p17) which induce torsion in the DNA molecule.     

Hairpin structures formed by alpha satellite DNA of human centromeres are cleaved by human topoisomerase IIalpha

Although centromere function has been conserved through evolution, apparently no interspecies consensus DNA sequence exists. Instead, centromere DNA may be interconnected through the formation of certain DNA structures creating topological binding sites for centromeric proteins. DNA topoisomerase II is a protein, which is located at centromeres, and enzymatic topoisomerase II activity correlates with centromere activity in human cells. It is therefore possible that topoisomerase II recognizes and interacts with the alpha satellite DNA of human centromeres through an interaction with potential DNA structures formed solely at active centromeres. In the present study, human topoisomerase IIα-mediated cleavage at centromeric DNA sequences was examined in vitro. The investigation has revealed that the enzyme recognizes and cleaves a specific hairpin structure formed by alpha satellite DNA. The topoisomerase introduces a single-stranded break at the hairpin loop in a reaction, where DNA ligation is partly uncoupled from the cleavage reaction. A mutational analysis has revealed, which features of the hairpin are required for topoisomerease IIα-mediated cleavage. Based on this a model is discussed, where topoisomerase II interacts with two hairpins as a mediator of centromere cohesion.     

Bacteriophage lambda derivatives carrying two copies of the cohesive end site

A spontaneously arising tandem duplication derivative of bacteriophage lambda has been isolated, which carries two copies of the site where the cohesive ends are formed (designated cos). Its structure has been determined by electron microscopy of DNA heteroduplexes. These heteroduplexes reveal that the duplication is usually, but not always, carried on the left end of the chromosome. A second duplication phage having two copies of cos, constructed by Feiss &; Campbell (1974), has also been studied by electron microscopy and is found to have a similar property.Unlike most tandem duplication derivatives of phage λ, the mutant studied here is not stable during growth in the absence of generalized recombination, but segregates both the triplication and the parental phage. This verifies that both cos sites are functional. The triplication does not arise as a result of end-to-end aggregation of phage chromosomes or site-specific recombination catalyzed by the chromosome maturation system at cos. It must therefore result from the cutting of mature ι chromosomes from concatemeric replication intermediates. The pattern of cutting observed shows that the λ cohesive ends are not created by a free nuclease acting on unpackaged DNA. The cutting appears to be influenced by the amount of DNA previously packaged into a phage head. A model for λ packaging is presented which explains the results.The duplication phage of Feiss &; Campbell (1974) carries a novel addition containing self-complementary sequences.     

Studies on the maturation of the head of bacteriophage T4.

The presentation focuses on the structural rearrangements of the subunits and the processing of the various protein constituents which accompany the maturation events of the head of bacteriophage T4. The major features of the maturation steps of the head are the following: (a) the viral DNA is pulled into an empty head in a series of events; (b) cleavage of two core proteins, P22 (mol. mass = 31000), to small fragments and the internal protein IPIII (mol. mass = 23000) to IPIII (mol. mass = 21000) appears to be intimately linked to the DNA packaging event, whereas the cleavage of the major head protein of the viral coat, P23 (mol. mass = 55000), to P23 (mol. mass = 45000) precedes the DNA packaging event. Recently, we have obtained information about the mechanism by which the viral DNA is pulled into a preformed empty head. Our evidence suggests that the DNA becomes attached to the inside of the empty head and is subsequently collapsed in the interior by the so-called internal peptides. These are highly acidic and derived from a large precursor protein by cleavage.     

Identification of sequences necessary for packaging DNA into lambda phage heads

Several species of DNA molecules are packaged into lambda phage heads if they carry the region around the cohesive end site of lambda phage (cos lambda). The minimal functional sequence around cos lambda needed for packaging was examined by cloning in pBR322. The results showed that the minimal region contained 85 bp around cos lambda; 45 bp of the left arm of lambda phage and 40 bp of the right arm. A 75-bp region located to the right of the minimal region seems to enhance packaging. A 223-bp fragment containing these regions can be used as a portable element for plasmid DNA packaging into lambda phage heads. Plasmid ppBest 322, a derivative of pBR322 carrying this portable packager and both amp and tet genes, was constructed. This plasmid is useful for cloning of large DNA fragments.     

Inhibition of topoisomerases from Pneumocystis carinii by aromatic dicationic molecules.

Pentamidine and related derivatives inhibit an ATP-dependent topoisomerase activity from Pneumocystis carinii extracts. Since it would be extremely difficult to purify ample quantities of the organisms to allow characterization of the enzyme and carry out drug binding experiments, we have begun the cloning of the topoisomerase genes with a goal towards expression of each gene in a heterologous system. Following construction of genomic libraries in the vectors lambda DASH and lambda ZAP, oligonucleotides corresponding to conserved regions of both topoisomerases I and II were used in the polymerase chain reaction (PCR) of P. carinii DNA to generate probes. Candidate clones for both genes have been identified. Partial DNA sequence of the topoisomerase II gene has been determined.     

Capsid transformation during packaging of bacteriophage lambdaDNA.

Assembly pathways of complex viruses might not be simple additions of one protein after another with rigid tertiary structure. It might in fact involve shifts in subunit structure, movement of subunits relative to each other to form new arrangements, transient action of proteins and protein segments, involvement of structure forming 'microenvironments' of the host. Thus morphogenesis of the bacteriophage lambda head starts with the formation of a core-containing DNA-free petit lambda particle. In a first transition, and dependent on a host function, the core is released, minor protein components of the capsid are processed and the particle's structure is altered, as shown by a change of its hydrodynamic properties. The resulting 'prehead' undergoes a second transition triggered by a complex of DNA and recognition protein (A-protein). This transition is more drastic than the first one. The particle doubles its volume without increasing in protein mass, the shell becomes thinner, and the surface structure is changed. Concomitantly with this process, the DNA becomes packaged and the particle becomes able to bind the small 'D-protein' in amounts equimolar to the capsid protein, which it could not do before. The D-protein addition probably causes another shift of the capsid structure. DNA packaging is completed, and the DNA is cut from concatemeric precursors to unit length molecules. Binding sites are created for the tail connector molecules which in turn allow the independently assembled tail to attach. Research on these processes proceeds along several lines: comparison of physical and chemical properties of particles accumulating in mutants; pulse-chase experiments on assembly precursors; morphogenesis in vitro; and model transitions of aberrant lambda polyheads.     

Formation of oligomeric structures from plasmid DNA carrying cos lambda that is packaged into bacteriophage lambda heads.

Plasmids that carry cos lambda, the region necessary for lambda phage packaging and that are as small as four kilobases in size can be packaged into lambda phage heads in head-to-tail tandem oligomeric structures. Multimeric oligomers as large as undecamers have been detected. Oligomer formation depends upon the products of red and gam of lambda, and the general recombination occurs between different plasmids that share homologous DNA regions. The packaging efficiency of plasmids depends on its copy number in cells and its genome size. Upon injection into a cell, the DNA establishes itself as a plasmid in a tandem structure. When such a plasmid in a high oligomeric structure is used as the source of packaging DNA, the packaging efficiency of the plasmids is elevated. The oligomers are stable in recA cells, whereas they drift toward lower oligomers in recA+ cells.     

Jekyll, a family of phage-plasmid shuttle vectors

A series of shuttle vectors has been constructed, which consist of a plasmid carrying a polylinker sequence and an M13 origin integrated into a lambda vector. A short direct repeat flanking the plasmid allows plasmid excision by homologous recombination. Sequences are cloned into unique restriction sites within the plasmid, and can be recovered either in phage or plasmid form, or can be packaged further as single-stranded DNA phage. These vectors therefore combine the efficiency of phage lambda cloning and screening with the ease of handling or analysing plasmid or M13 clones.