Intermediates in the maturation of bacteriophage lambda DNA

Late stages in bacteriophage lambda head morphogenesis: in vitro studies on the action of the bacteriophage lambda D-gene and W-gene products

The in vitro maturation of bacteriophage lambda can be divided into discrete steps. Concatemers of lambda DNA bind terminase to form complex I. This DNA-terminase complex then binds a prohead to form a ternary complex (II). Complex II in turn can be converted to infectious phage by the addition of extracts containing the products of the phage genes D, W, FII, as well as phage tails. By using in vitro complementation assays gpD and gpW have been partially purified and their interactions with complex II studied. gpD can bind to complex II in vitro to form a new complex (III) which can be isolated by sedimentation on neutral sucrose gradients. This complex requires only the addition of gpW, gpFII, and phage tails to form mature phage particles. The sedimentation of complex III is virtually identical to that of complex II; however, the resistance of the former to inactivation by DNase is higher, likely due to the partial packaging of the DNA. In similar experiments it was shown that gpW cannot bind to complex II but can effectively interact with complex III. This latter reaction converts complex III to a DNase-resistant form which sediments in a manner identical to that of full phage heads (complex IV). After isolation of the complex IV only gpFII and tails are required for mature phage formation in vitro. gpW is a heat-stable protein of molecular weight approximately 10,000.

cis Functions involved in replication and cleavage-encapsidation of pseudorabies virus

Serial passage at high multiplicity of pseudorabies virus generates defective interfering particles (DIPs) whose genomes consist at least in part of reiterations of segments of DNA in which sequences originating from different regions of the genome have become covalently linked (F. J. Rixon and T. Ben-Porat, Virology 97:151-163). To determine whether some cis functions present in these reiterated DNA sequences may be responsible for the amplification of DIP DNA, BamHI restriction fragments of this DNA were cloned. These fragments were analyzed and tested for their ability to promote the amplification of covalently linked pBR325 DNA when cotransfected into cells with helper pseudorabies virus DNA. The cloned DIP BamHI DNA fragments consisted of various combinations of sequences originating from either one or both ends as well as sequences from the middle of the unique long (UL) segment of the genome. Only plasmids with inserts consisting of segments of defective DNA originating from the middle of the UL, as well as from both ends of the genome, were able to replicate and be encapsidated autonomously. This finding indicated that signals present at both ends of the genome may be necessary for efficient cleavage-encapsidation. To confirm this observation, we constructed plasmids in which DNA segments containing an origin of replication and sequences from either one or both ends of the virus genome were linked. These experiments showed that efficient cleavage-encapsidation requires the presence of sequences derived from both ends of the genome. Two origins of replication, one at the end of the UL segment and one in the middle of the UL segment, were also identified.

The maturation of coliphage lambda DNA in the absence of its packaging

In vivo, lambda DNA cannot be cleaved at cos (matured) if proheads are not present; in vitro, however, cos cleavage readily takes place in the absence of proheads. In order to investigate this paradox, we have constructed plasmids that synthesize lambda terminase in vivo upon induction. The plasmids also contain cos at the normal position, about 190 bp upstream of lambda gene Nul. One of the plasmids, pFM3, produces levels of terminase comparable to those found after phage induction. If cells carrying pFM3 are thermoinduced, almost 100% of the intracellular plasmid DNA has a double-strand interruption at or near cos. Since the only lambda genes that pFM3 carries are Nul, A, W and B, this in vivo cleavage is occurring in the absence of proheads. Previous failure to observe lambda maturation with phages carrying prohead mutations may be due to exonucleolytic degradation of the unprotected DNA ends, a different DNA topology or compartmentalization, or terminase inhibition in the absence of prohead by the product of another lambda gene that maps to the right of gene B.

Early intermediates in bacteriophage lambda prohead assembly. II. Identification of biologically active intermediates

The morphogenesis of bacteriophage lambda proheads is under the control of the four phage genes B, C, Nu3, and E, as well as the E. coli genes groEL and groES. It has been previously shown that extracts prepared from cells infected with a lambda C-E- mutant accumulate biologically active gpB and gpNu3 (Murialdo, H., and Becker, A., J. Mol. Biol. 125, 57-74 (1978) ). To characterize the nature of these intermediates in prohead assembly, extracts prepared from these cells were fractionated by DEAE-cellulose chromatography as well as velocity sedimentation. Intermediates containing gpB were identified by SDS-polyacrylamide gel electrophoresis and by their ability to be assembled into biologically active proheads in vitro. The results indicate that the most abundant, biologically active intermediate (greater than 98% of the gpB activity) is a 25 S gpB-containing polymer. A second biologically active intermediate (about 1% of the total gpB activity) was identified as a gpB-gpgroEL complex.

The starting point and direction of rolling-circle replicative intermediates of coliphage lambda DNA

Intermediates of lambda DNA replication in the second half of the latent period after phage lambda infection were isolated and investigated in the electron microscope by denaturation mapping. The isolated replicative forms (RF) are predominantly single branched circular DNA. The starting points of replication in these lariat molecules located at the same region as the first round lambda DNA replication. About 60% of the RF replicate from left to right and the other 40% replicate in the reverse direction. The free ends of the tails are located at many sites on the lambda genome. Replicating circles with a linear DNA tail longer than one unit length of lambda genome represent about 30% of the replicating molecules. These long linear tails (concatemers) produced by the rolling-circle (Gilbert and Dressler, 1968; Eisen et al., 1968; Skalka et al., 1972; Takahashi, 1974) are one of the best candidates for a precursor DNA of progeny phage.

Isolation of the bacteriophage lambda A-gene protein

An in vitro assay for measuring the activity of the phage lambda A-gene product has been developed. The assay is based on the observation that A-donor extracts complement A minus extracts for packaging of exogenous immature lambda DNA into phage particles. A partial purification of the A-gene product activity using this assay is presented. A method is suggested by which this A protein-dependent in vitro system might be manipulated to analyze the mechanism of reforming the lambda cohesive termini during chromosome assimilation into phage precursors.