On the internal structure of bacteriophage lambda

The structure of bacteriophage lambda has been studied by electron microscopy of negatively stained particles. The phage particles will eject their DNA if they are heated or dialyzed against a chelating agent. The ghost particles, so formed, have a channel running down their tails. Since the channel is not visible in normal particles, the channel may be filled with part of the DNA molecule. Up to 30% of the ghosts contain round objects about half the internal diameter of the head. The round objects, called "cores," have the same buoyant density as the coat protein. The core may be a protein spool about which the phage DNA is wound.     

On inactivation of bacteriophage lambda by hydroxylamine

Hydroxylamine is a mutagen which is much more active on single-stranded DNA than on double-stranded DNA. It is shown here that the cohesive ends of lambda DNA, with 10 cytidine residues, constitute a hydroxylamine target roughly equal in magnitude to the entire duplex part of the molecule, which contains ca. 25 000 cytidine residues.     

On maturation of the bacteriophage lambda chromosome

Summary Repressed lambda chromosomes that possess a duplication of the cohesive end site (cos site) are matured during lytic growth of 80. This result is in contrast to repressed non-duplication lambda chromosomes that are not matured by 80. DNA molecules matured by 80 are unreplicated and lack the duplication: both cos sites are cleaved. These results indicate that in normal lambda development, mature, unit-length chromosomes are generated from a multichromosomal length of lambda DNA by cleavage of two cos sites.     

On the sequential packaging of bacteriophage P22 DNA.

Bacteriophage P22 is thought to package daughter chromosomes serially along concatemeric DNA. We present experiments which show that the average DNA packaging series length increases with time after infection, which supports this model. In addition, we have analyzed the effect on average series length of lowering the amount of the various individual proteins involved in DNA packaging. These results support the notion that the protein products of gene 2 and gene 3 are both more stringently required for initiation of sequential DNA packaging series than for their extension, and they are compatible with a model for the control of series length in which that length is determined, at least in part, by a competition between series initiation events and extension events.     

On the deacetylase activity of Vi bacteriophage III particles.

1. Using the complete phage particles as an enzyme, O-acetyl (1 leads to 4)-alpha-D-galacturonan (acetylated pectic acid) as a substrate, and gas-liquid-chromatography for the determination of the acid liberated, the virus-catalysed deacetylation of the polymer was studied. The activity was found to be stable up to about 50 degrees C, and from pH 4.5 to 9, with an optimum at pH 7.8; it was not affected by EDTA, or by 1,10-phenanthroline. The initial reaction velocity (at 37 degrees C) exhibited a simple hyperbolical dependence on the substrate concentration, with Km = 10.5 mM for O-acetyl (independent of virus concentration), and Vmax = 15 nmoles/min and 10(10) plaque forming units. The reaction was, however, rapidly inhibited by a partially deacetylated product (but neither by acetate, nor by pectic acid itself). 2. Using the natural substrate, acetylated (1 leads to 4)-2 amino-2-deoxy-alpha-D-galacturonan (Vi polysaccharide, Vi antigen), and a variety of structural analogues, the following conclusions about the substrate specificity of the Vi phage III deacetylase (acetyl-alpha-1,4-galacturonan acylhydrolase) were reached: (a) acetylated galacturonan is as good a substrate as acetylated aminogalacturonan; (b) of the two substrate diastereomers, acetylated alpha-L-guluronan (also 1 ax leads to 4 ax-linked units, but with axial acetyl residues at C-3), and beta-D-mannuronan (1 eq leads to 4 eq-linkages, and axial acetyl groups at C-2), only the former was acted upon, possibly indicating a specificity for the conformation of the polymer rather than for the configuration of the single residues; (c) all acyl analogues tested, O-monofluoroacetyl, O-propionyl, and O-butyryl galacturonan, were inert, showing a high degree of specificity for O-acetyl; (d) the oligomers, acetylated tri- and digalacturonic acid, as well as methyl-alpha-D-galacturonide, were still deacetylated, although more slowly, demonstrating tolerance of the enzyme of substrate size.     

On the catalytic mechanism of bacteriophage endolysins: Opportunities for engineering

Bacteriophage endolysins have the potential to be a long-term antibacterial replacement for antibiotics. The exogenous application of endolysins on some bacteria results in rapid cell lysis. The prospects for endolysins are furthered by the ability to engineer them; novel endolysins can be developed with optimised stability, specificity, and lytic function. But the success of endolysin engineering and application requires a comprehensive understanding of the relationship between the enzymes biochemical, biophysical and bacteriolytic properties. Here, we examine their catalytic mechanisms, opportunities for developing novel endolysins, and highlight areas where a better understanding would support their long-term success as antibacterial agents.     

On the receptor for bacteriophage T4 inEscherichia coli K12

Purified lipopolysaccharide (LPS) from a mutant strain ofEscherichia coli K12 altered in its LPS has been shown to serve as a receptor for bacteriophage T4, which contrasts with LPS from a wild-type strain. Studies of extragenic suppression of a mutation in the gene specifying protein 1b revealed that the galactose residue in the LPS normally masks the LPS receptor and that in the absence of this residue protein 1b is not a necessary component of the T4 receptor.     

Transduction of bacteriophage lambda by bacteriophage T1.

When bacteriophage T1 was grown on bacteriophage lambda-lysogenic cells, phenotypically mixed particles were formed which had the serum sensitivity, host range, and density of T1 but which gave rise to lambda phage. T1 packaged lambda genomes more efficiently both when the length of the prophage was less than that of wild-type lambda and when the host cell was polylysogenic. Expression of the red genes of lambda or the recE system of Escherichia coli during T1 growth enhanced pickup of lambda by T1, whereas packaging was reduced in recB cells. If donors were singly lysogenic, the expression of transduced lambda genomes as a PFU required lambda-specified excisive recombination, whereas lambda genomes transduced from polylysogens required only lambda- or E. coli-specified general recombination to give a productive infection.     

Transduction of bacteriophage Mu by bacteriophage T1.

Phage T1 transduces phage Mu PFU from Mu-lysogenic donor cells to sensitive recipient cells. The efficiency of transduction depends on the chromosomal location of the Mu prophage. T1, therefore, appears to package different regions of the bacterial chromosome with different efficiencies. Although T1 transduces bacterial markers with different efficiencies, there is no direct correlation between the efficiency of transduction of a bacterial marker and the efficiency of transduction of Mu PFU from donor cells with the Mu prophage located in that marker.     

On the repair mechanism responsible for multiplicity reactivation in bacteriophage T4

Summary Multiplicity reactivation has been studied using two T4 phages carrying a large number, twenty six, of genetic markers covering the whole viral genome. It has been found that in the progeny of irradiated phages the observed increase of recombination frequencies is not limited to the vicinity of radiation-induced lethal lesions, it can occur all along the phage genome. Most of the single bursts produced by multiplicity reactivation contain phages of entirely parental genotype. This fact may reveal the existence of repair by recombination between replication products of a single viral genome.     

On the mutagenicity of homologous recombination and double-strand break repair in bacteriophage

The double-strand break (DSB) repair via homologous recombination is generally construed as a high-fidelity process. However, some molecular genetic observations show that the recombination and the recombinational DSB repair may be mutagenic and even highly mutagenic. Here we developed an effective and precise method for studying the fidelity of DSB repair in vivo by combining DSBs produced site-specifically by the SegC endonuclease with the famous advantages of the recombination analysis of bacteriophage T4 rII mutants. The method is based on the comparison of the rate of reversion of rII mutation in the presence and in the absence of a DSB repair event initiated in the proximity of the mutation. We observed that DSB repair may moderately (up to 6-fold) increase the apparent reversion frequency, the effect of being dependent on the mutation structure. We also studied the effect of the T4 recombinase deficiency (amber mutation in the uvsX gene) on the fidelity of DSB repair. We observed that DSBs are still repaired via homologous recombination in the uvsX mutants, and the apparent fidelity of this repair is higher than that seen in the wild-type background. The mutator effect of the DSB repair may look unexpected given that most of the normal DNA synthesis in bacteriophage T4 is performed via a recombination-dependent replication (RDR) pathway, which is thought to be indistinguishable from DSB repair. There are three possible explanations for the observed mutagenicity of DSB repair: (1) the origin-dependent (early) DNA replication may be more accurate than the RDR; (2) the step of replication initiation may be more mutagenic than the process of elongation; and (3) the apparent mutagenicity may just reflect some non-randomness in the pool of replicating DNA, i.e., preferential replication of the sequences already involved in replication. We discuss the DSB repair pathway in the absence of UvsX recombinase.