The arrangement of DNA in lambda phage heads. II. lambda DNA after exposure to micrococcal nuclease at the site of head-tail joining

DNA in lambda phage heads (lacking tails) is damaged by treatment with micrococcal nuclease. Alkaline sucrose gradient sedimentation of the DNA extracted from nuclease-treated and untreated heads reveals no hydrolysis of internal phosphodiester bonds. Transformation of helper-infected cells by whole or half molecules of treated DNA is as efficient as by control DNA. Thus, the site of nuclease damage must be near the ends and very limited.     

Initiation of lambda DNA replication in vitro promoted by isolated P-gene product.

The product of the P gene of bacteriophage lambda was isolated from heat-induced lambda-lysogenic Escherichia coli cells. It was found to bind to DNA, to be devoid of nuclease activity acting on double-stranded lambda DNA and of nicking/closing activity. Initiation of lambda DNA replication promoted by the P-gene product in a complementation assay in vitro was sensitive to rifampicin. Sedimentation analysis of the products and their hybridization to separated lambda DNA strands indicate that lambda DNA was formed in a reaction similar to ring-to-ring replication in vivo. The reaction was symmetric from the beginning, i.e. both lambda DNA strands were copied without delay.     

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.     

Construction of a yeast mutant lacking the mitochondrial nuclease.

The nuclear gene from Saccharomyces cerevisiae that encodes the major mitochondrial nuclease was cloned. Gene sequences were identified from a lambda gt11 library by antibodies specific to the mitochondrial nuclease. DNA from the phage recombinant was used to isolate the entire nuclease gene from a plasmid library. Yeast strains containing the nuclease gene on a multicopy plasmid vector overproduced mitochondrial nuclease 20-40 times relative to a wild-type strain. Strains containing a null allele of the nuclease gene lacked all traces of mitochondrial nuclease. Both cell types, however, were phenotypically wild-type indicating that the nuclease is not an essential enzyme for mitochondrial function. The locus encoding the mitochondrial nuclease is termed NUC1.     

Injection of DNA into liposomes by bacteriophage lambda

Small unilamellar vesicles (75-100 nm diameter) and large liposomes (greater than 1 micron in diameter) were prepared containing the lamB protein, an outer membrane protein of Escherichia coli and Shigella which serves as the receptor for bacteriophage lambda. Bacteriophage were observed to bind to these liposomes and vesicles by their tails and in most cases the heads of the bound bacteriophage appeared empty or partially empty of DNA. The lambda DNA was usually only partially ejected from the bacteriophage head when small unilamellar liposomes were used, presumably because the vesicles are too small to contain all the DNA. The partially ejected DNA was not susceptible to DNase unless the vesicle bilayer was first disrupted suggesting that DNA injection of phage DNA into the vesicle had occurred. After disruption of these vesicles on electron microscope grids, the bacteriophage are seen to have partially empty heads and a small mass of DNA associated with their tails. Using larger liposomes prepared by the fusion of lamB bearing vesicles with polyethylene glycol and n-hexyl bromide, the heads of most of the bound bacteriophage appeared to be completely empty of DNA. Disruption of these preparations on electron microscope grids revealed circular arrays of empty-headed bacteriophage surrounding DNA which had apparently been contained within the intact liposomes. These results indicate that high molecular weight DNA can be entrapped within liposomes with high efficiency by ejection from bacteriophage lambda. The possible use of these DNA-containing liposomes to facilitate gene transfer in eukaryotic cells is discussed.     

Cloning in Escherichia coli of the gene specifying the DNA-entry nuclease of Bacillus subtilis

With the aim of cloning genes involved in transformation of Bacillus subtilis, a set of transformation-deficient mutants was isolated by means of insertional mutagenesis with plasmid pHV60 (Vosman et al., 1986). Analysis of these mutants showed that those mapping in the aroI region lacked the DNA-entry nuclease activity. Plasmid pHV60 derivatives, containing flanking chromosomal DNA fragments, were isolated from these mutants and were used to screen a library of B. subtilis chromosomal DNA in phage lambda EMBL4. In Escherichia coli lysates, prepared with the phages that hybridized to the pHV60-based probe, a prominent nuclease activity could be detected. The nuclease encoded by the phage DNA had the same Mr as the B. subtilis DNA-entry nuclease and its activity was strongly stimulated by Mn2+, which is also characteristic for the B. subtilis DNA-entry nuclease. From these results it was concluded that the gene specifying the B. subtilis DNA-entry nuclease had been cloned. It was shown that the nuclease activity was specified by a 700-bp EcoRI-PstI fragment.     

Micrococcal nuclease digestion study of spermidine-condensed DNA

Spermidine-condensed lambda DNA tertiary structures have been studied by micrococcal nuclease digestion. Broad but discrete DNA bands were observed in gel electrophoresis experiments of digests at sizes of: 1003 +/- 115 bp, 1972 +/- 190 bp and 3100 +/- 350 bp. These bands comprise an arithmetic series, similar to, but larger than, arithmetic DNA band series sizes we have observed previously in calf thymus and phi x-174 DNA condensates. The 1003bp monomer lambda DNA band size corresponds to wrapping B DNA once circumferentially about the toroidal-shaped tertiary structures, the predominant condensed structures present in these preparations, and is consistent with the measured electron microscopic dimensions for hydrated lambda DNA toruses previously presented. DNA fragment length stability was determined by release from the digested condensates. Fragments of 80-85bp and sizes below are thermodynamically unstable in the lambda DNA condensates. This fragment size agrees well with a recent determination of the cooperativity size in DNA condensates.     

DNA polymerase lambda from calf thymus preferentially replicates damaged DNA

A new gene (POLL), has been identified encoding the novel DNA polymerase lambda and mapped to mouse chromosome 19 and at human chromosome 10. DNA polymerase lambda contains all the critical residues involved in DNA binding, nucleotide binding, nucleotide selection, and catalysis of DNA polymerization and has been assigned to family X based on sequence homology with polymerase beta, lambda, mu, and terminal deoxynucleotidyltransferase. Here we describe a purification of DNA polymerase lambda from calf thymus that preferentially can replicate damaged DNA. By testing polymerase activity on non-damaged and damaged DNA, DNA polymerase lambda was purified trough five chromatographic steps to near homogeneity and identified as a 67-kDa polypeptide that cross-reacted with monoclonal antibodies against DNA polymerase beta and polyclonal antibodies against DNA polymerase lambda. DNA polymerase lambda had no detectable nuclease activities and, in contrast to DNA polymerase beta, was aphidicolin-sensitive. DNA polymerase lambda was a 6-fold more accurate enzyme in an M13mp2 forward mutation assay and 5-fold more accurate in an M13mp2T90 reversion system than human recombinant DNA polymerase beta. The biochemical properties of the calf thymus DNA polymerase lambda, described here for the first time, are discussed in relationship to the proposed role for this DNA polymerase in vivo.     

The old exonuclease of bacteriophage P2.

The Old protein of bacteriophage P2 is responsible for interference with the growth of phage lambda and for killing of recBC mutant Escherichia coli. We have purified Old fused to the maltose-binding protein to 95% purity and characterized its enzymatic properties. The Old protein fused to maltose-binding protein has exonuclease activity on double-stranded DNA as well as nuclease activity on single-stranded DNA and RNA. The direction of digestion of double-stranded DNA is from 5' to 3', and digestion initiates at either the 5'-phosphoryl or 5'-hydroxyl terminus. The nuclease is active on nicked circular DNA, degrades DNA in a processive manner, and releases 5'-phosphoryl mononucleotides.     

Influence of nonhistone chromatin protein HMG-1 on the enzymatic digestion of purified DNA

The effect of chicken erythrocyte High Mobility Group protein 1 (HMG-1) on the enzymatic hydrolysis of purified double-stranded and single-stranded bacteriophage lambda DNA was studied. HMG-1 was found to inhibit the digestion of single- and double-stranded DNA by S1 nuclease and DNase I, respectively. HMG-I increased the rate of hydrolysis of double-stranded DNA by micrococcal nuclease, particularly at low HMG-1/DNA ratios, and had little effect on the hydrolysis of single-stranded DNA by micrococcal nucleases, even at high HMG-1 DNA ratios. We also present a semi-quantitative estimate that HMG-1 and HMG-2 occur in chromatin from rapidly dividing, cultured rat hepatoma cells at about 8 times the level that they occur in adult rat liver chromatin.     

Conditions optimized for the preparation of single-stranded DNA (ssDNA) employing lambda exonuclease digestion in generating DNA aptamer

The generation of DNA aptamer by Systematic Evolution of Ligands by Exponential Enrichment requires a good method of ssDNA generation. There are various methods developed to generate ssDNA such as streptavidin-biotin based separation techniques, asymmetric PCR and strand separation of the PCR product containing primer with a terminator and an extension of 20 nucleotides on denaturing urea-polyacrylamide gel. In the present investigation, we have shown the possible improvements for the regular lambda nuclease digestion under optimized conditions. Optimization of the PCR cycles, time course studies on lambda nuclease digestion and purification of the ssDNA from the lambda exonuclease digestion mixture was found to be able to recover ssDNA amounting up to 39.19 ± 2.48 % of the starting amount of dsDNA. These strategies can be applied to the techniques involving essential usage of ssDNA.     

Sepcific fragmentation of DNA heteroduplex molecules of two bacteriophage lambda mutants with endonuclease Si from Aspergillus oryzae.

Heteroduplex DNA molecules of two bacteriophage mutants (lambda b2 and lambda i434ct68) were obtained by the method of molecular hybridization. These heteroduplexes possessed two types of loops formed as a result of: a) deletion in one of the DNA strands; and b) substitution of a DNA fragment for nonhomological one. The digestion of heteroduplexes with single-stranded specific nuclease SI from Aspergillus oryzae produced two fragments at 37 degrees C and three ones at 55 degrees C. The separation of fragments and determination of their molecular weight were carried out by means of electrophoresis in agarose. The molecular weights both measured and preliminarily calculated proved to be close. One of the fragments was identificated by its biological activity in CaCl2-dependent infectious system with helperphage.     

Morphogenesis of bacteriophage lambda deletion mutants. I. Abnormal head-related structures produced in normal Escherichia coli.

Late in the morphogenesis of bacteriophage lambda, DNA condenses into the nascent head and is cut from a concatemeric replicative intermediate by a nucleolytic function, Ter, acting at specific sites, called cos. As a result of this process, heads of lambda deletion mutants contain less DNA than those of the wild-type phage. It has been reported that phage with very large deletions (22% of the genome or more) grow poorly but that normal growth can be restored by the non-specific addition of DNA to the genome. This finding implies that DNA content may exert a physical effect on some stage of head assembly.We have investigated the effects of two long deletions, b221 and tdel33, on head assembly. Bacteria infected with the mutants were lysed with non-ionic detergent under conditions favoring stabilization of labile structures containing condensed DNA. It has proved possible to isolate two aberrant head-related structures produced by the deletion mutants. One of these (“overfilled heads”) contains DNA which is longer than the deletion mutant genome and is about the same size as that found in wild-type heads. These structures appear to be unable to attach tails. The second type of structure (“incompletely filled heads”) contains a short piece of DNA, 40% of the length of the mutant genome. The incompletely filled heads are found both with and without attached tails. Both of these abnormal structures are initially attached to the replicating DNA but are released by treatment with DNAase. The nature of these abnormal structures indicates that very small genomes affect a late stage of head morphogenesis, after the DNA is complexed with a capsid of normal size. The results presented suggest that underfilling of the capsid interferes with the ability of the Ter function to properly cleave cos.     

A minimal kinetic model for a viral DNA packaging machine

Terminase enzymes are common to both eukaryotic and prokaryotic double-stranded DNA viruses. These enzymes possess ATPase and nuclease activities that work in concert to "package" a viral genome into an empty procapsid, and it is likely that terminase enzymes from disparate viruses utilize a common packaging mechanism. Bacteriophage lambda terminase possesses a site-specific nuclease activity, a so-called helicase activity, a DNA translocase activity, and multiple ATPase catalytic sites that function to package viral DNA. Allosteric interactions between the multiple catalytic sites have been reported. This study probes these catalytic interactions using enzyme kinetic, photoaffinity labeling, and vanadate inhibition studies. The ensemble of data forms the basis for a minimal kinetic model for lambda terminase. The model incorporates an ADP-driven conformational reorganization of the terminase subunits assembled on viral DNA, which is central to the activation of a catalytically competent packaging machine. The proposed model provides a unifying mechanism for allosteric interaction between the multiple catalytic sites of the holoenzyme and explains much of the kinetic data in the literature. Given that similar packaging mechanisms have been proposed for viruses as dissimilar as lambda and the herpes viruses, the model may find general utility in our global understanding of the enzymology of virus assembly.     

A study of phi X-174 DNA torus and lambda DNA torus tertiary structure and the implications for DNA self-assembly

Hydrated torus shaped complexes were examined by transmission electron microscopy in both spermidine-condensed linear and nicked circular phi X-174 DNA and lambda DNA preparations. Freeze-etch replicas of both these torus samples, produced with very low Pt metal deposition levels (9APt/C), were found to have circumferentially wound single DNA double helix size surface fibers in the range of 30A width. Measurements of torus inner and outer circumference as well as ring thickness were performed. Observed differences in the torus dimension distributions from circular phi X-174 DNA and linear phi X-174 DNA may be related to the different topological constraints on DNA folding in these two samples (1). On the basis of annulus thickness measurements phi X-174 DNA toruses, in contrast to lambda DNA toruses, were observed to fall into two classes identified as being formed from monomer DNA condensation and multimer DNA condensation. All of the torus substructure and population dimensions observed here are consistent with the continuous circumferential DNA winding model of torus organization proposed by Marx and Reynolds (1) to explain the micrococcal nuclease cleavage properties of the toruses. End-on view measurements of the torus thickness were made from micrographs obtained by extensive tilting of the object replica. These direct measurements confirmed quaternary structure interpretations made from simple strand packing models. We compared the measured torus properties in this linear DNA size series (5386-48000 bp). With increasing DNA length the pattern of DNA strand self-assembly was found to be more varied producing lambda DNA toruses of varying shape. The relevance of our study to the problem of lambda bacteriophage DNA head packaging was discussed.     

Apparent alteration in properties of arl mutants of Escherichia coli

The published properties of lambda phages grown in Escherichia coli arl mutants, and plasmids maintained in them, included increased homologous recombination, decreased DNA-cytosine methylation, and increased sensitivity of DNA to nuclease S1. Some of these properties now appear altered; others remain approximately as published.     

Stability of Lambdoid bacteriophage heads: antagonism between polyamines and tryptamine.

The biological activity of heads of bacteriophages phi 80 and lambda in in vitro assembly with tails was inhibited by dialysis, filtration on gels, and treatment with tryptamine. Inhibition by these three treatments could be prevented but not reversed by putrescine. Other diamines with shorter or longer carbon chain lengths were either less effective or not effective at all. It is suggested that tryptamine acts by loosening the tightly packed DNA in heads, whereas putrescine stabilizes it.     

Membrane-associated nuclease activities in mycoplasmas.

Membrane-associated nucleases of various mycoplasmal species were investigated by using two nuclease assays. A lambda DNA assay was developed to measure nuclease activity associated with whole-cell suspensions, activity released from intact cells, and activity associated with detergent-disrupted cells. In most species, nuclease activities were entirely membrane associated, and disruption by a detergent had a stimulatory effect on these activities. All mycoplasmal species contained nuclease activity, but Mycoplasma capricolum was unusual because its activity was dependent upon magnesium and was inhibited by calcium. We developed a sodium dodecyl sulfate-polyacrylamide gel electrophoresis system that produced reproducible nuclease patterns, and this system was used to determine the apparent molecular weights of the nuclease proteins. An examination of 20 mycoplasmal species failed to identify common bands in their nuclease patterns. An examination of 11 Mycoplasma pulmonis strains, however, indicated that nuclease patterns on polyacrylamide gels may provide a means for categorizing strains within a species. Our results suggest that nucleases are important constituents of mycoplasmal membranes and may be involved in the acquisition of host nucleic acids required for growth.     

Protection of particular endonuclease R. Hind III cleavage sites by distamycin A, propyl-distamycin and netropsin.

It is shown that three related antibiotics, distamycin A, propyl-distamycin and netropsin, can protect certain endo R.Hind III cleavage sites from attack by endonuclease, giving rise, after endo R.Hind III digestion, to larger DNA fragments. Bacteriophage lambda DNA has six recognition sites for Hind III enzyme. Three of these sites: shind III 2, 3 and 6 can be protected from nuclease action by all the antibiotics used. Propyl-distamycin protects partly shind III 5, too. Netropsin protects partly sites shind III 5 and 4, while distamycin A protects all the sites but shind III 1 so the Hind III digestion produces only two large fragments of lambda DNA.