New map of bacteriophage lambda DNA.

A map of bacteriophage lambda was constructed, including accurate positions for all 41 cut sites made by 12 different restriction enzymes. Over 100 fragments from single, multiple, and partial enzyme digestions were measured versus standards that were calibrated with respect to DNA molecules of known sequence. The data were subjected to least-squares analysis to assign map coordinates. In no case did a fragment size predicted from the map differ from the measurement of the fragment by more than +/- 5%. This low error rate was consistent in all size ranges of fragments. The total length of lambda was calculated as 49,133 nucleotide pairs. This probably is accurate to within 500 base pairs.     

Altered arrangement of the DNA in injection-defective lambda bacteriophage.

We have characterized two variant bacteriophage λ particles, λZ^? and λdocL, that have low infectivity but normal morphology. The low infectivity is due, at least in part, to a defect in DNA injection. This defect is probably the result of an altered location of the right end of the chromosome with respect to the phage tail: the right end of λZ^? and λdocL DNA, in contrast to that of wild-type λ, cannot be cross-linked to the tail. The cross-linking experiments were greatly facilitated by a new technique that allows routine spreading of DNA for electron microscopy without the use of a protein film.We propose that the Z gene product, a tail protein, acts by recognizing a specific feature near the right terminus of the DNA and promoting its insertion into the tail. This feature is presumably missing in most λdocL particles.     

Multiply branched DNA molecules from bacteriophage lambda: putative post-replicational repair DNA intermediates

Previous studies have shown that thymidine deprivation causes the formation of multiply branched molecules among bacteriophage lambda DNA replicative intermediates. In the present report, we present supporting evidence indicating that the induction of the SOS response is involved in this process. Moreover, close inspection of the DNA replicatives intermediates present in a recA deficient strain, shows an accumulation of gapped replicative intermediates. From these observations we postulate a model by which multiply branched DNA molecules may be intermediates or derived intermediates of a post-replicational repair pathway.     

Error-prone DNA repair and translesion DNA synthesis. II: The inducible SOS hypothesis

Evelyn Witkin hypothesized in 1967 that bacterial cell division is controlled by a repressor which, like the lambda repressor, is inactivated by a complex process that starts with the presence of replication-blocking lesions in the DNA. She further suggested that this might not be the only cellular function to show induction by DNA damage. Three years later, Miroslav Radman, in a privately circulated note, proposed that one such function might be an inaccurate (mutation-prone) DNA polymerase under the control of the recA and lexA genes. Thus was born the SOS hypothesis.     

Translesion synthesis by the UmuC family of DNA polymerases.

Translesion synthesis is an important cellular mechanism to overcome replication blockage by DNA damage. To copy damaged DNA templates during replication, specialized DNA polymerases are required. Translesion synthesis can be error-free or error-prone. From E. coli to humans, error-prone translesion synthesis constitutes a major mechanism of DNA damage-induced mutagenesis. As a response to DNA damage during replication, translesion synthesis contributes to cell survival and induced mutagenesis. During 1999-2000, the UmuC superfamily had emerged, which consists of the following prototypic members: the E. coli UmuC, the E. coli DinB, the yeast Rad30, the human RAD30B, and the yeast Rev1. The corresponding biochemical activities are DNA polymerases V, IV, eta, iota, and dCMP transferase, respectively. Recent studies of the UmuC superfamily are summarized and evidence is presented suggesting that this family of DNA polymerases is involved in translesion DNA synthesis.     

The DNA between Rz and cosR in bacteriophage lambda is nonessential

Near the right end of phage lambda DNA, between gene Rz and the cos site, are 2050 bp of apparently non-coding DNA. We have cloned a lambda DNA fragment containing this DNA into a plasmid and constructed a deletion, omega l, extending from a site within the Rz gene to a site about 560 bp from cos. This deletion could be recombined into viable lambda phage at a frequency equal to that observed for the undeleted sequence. Recombinant phage lambda carrying the omega l deletion were demonstrated to have the same burst size and kinetics of phage production as undeleted lambda. The omega l deletion can be used to extend the capacity of lambda cloning vectors and to provide a region for the insertion of heterologous DNA which should exhibit controllable high level expression from the lambda late promoter, p'R.     

Translesion DNA synthesis in the context of cancer research

During cell division, replication of the genomic DNA is performed by high-fidelity DNA polymerases but these error-free enzymes can not synthesize across damaged DNA. Specialized DNA polymerases, so called DNA translesion synthesis polymerases (TLS polymerases), can replicate damaged DNA thereby avoiding replication fork breakdown and subsequent chromosomal instability. We focus on the involvement of mammalian TLS polymerases in DNA damage tolerance mechanisms. In detail, we review the discovery of TLS polymerases and describe the molecular features of all the mammalian TLS polymerases identified so far. We give a short overview of the mechanisms that regulate the selectivity and activity of TLS polymerases. In addition, we summarize the current knowledge how different types of DNA damage, relevant either for the induction or treatment of cancer, are bypassed by TLS polymerases. Finally, we elucidate the relevance of TLS polymerases in the context of cancer therapy.     

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.     

Hyperfine structure in melting profile of bacteriophage lambda DNA.

A high-resolution plotter of differential melting profiles of DNA, RNA, or related biopolymers with an on-line mini-computer is described. With this device, more than 15 transition steps were identified in the thermal melting profile of DNA from bacteriophage lambda. These fine structures were found to be reproducible, and some of them disappear in the deletion mutant. To Examine the melting profile, computer simulations for several hypothetical polynucleotide sequences were performed, and compared with experimental data. The sharp peaks that appeared in the differential melting profile of λ DNA may come from some homogeneous sequences of 500 bases or longer.     

Nucleotide sequence of bacteriophage lambda DNA

The nucleotide sequence of the DNA of bacteriophage λ has been determined using the dideoxy chain termination method in conjunction with random cloning in M13 vectors. Various methods were studied for sequencing specific regions to complete the sequence, but all were much slower than the random approach. The DNA in its circular form contains 48,502 base-pairs. Open reading frames were identified and, where possible, ascribed to genes by comparing with the previously determined genetic map. The reading frames for 46 genes were clearly identified, though in about 20 the position of the protein initiation site could not be rigorously established. Probable positions for the kil, cIII and lom genes are suggested but remain uncertain. There are about 20 other unidentified reading frames that may code for proteins.The genome is fairly compact with comparatively little non-coding DNA. In many cases the translation terminators and initiators overlap, particularly in the sequence A-T-G-A where the TGA terminates one gene and the ATG initiates the next. Such structures seem to be characterized by a purine-rich sequence, rather than by a specific “Shine and Dalgarno” sequence, before the initiator. In the whole of the left arm the codon CTA, which is normally read by a minor leucine tRNA, is absent. The distribution of other rare codons in the genes of the left arm suggests that they may have a controlling function on the relative amounts of the proteins produced.     

Activities involved in base excision repair of bacteriophage T4 and lambda DNA in vivo

Summary The in vivo excision repair functions of Escherichia coli exonuclease III and 3-methyladenine DNA glycosylase I, and bacteriophage T4 pyrimidine dimer-DNA glycosylase were investigated. Following exposure of bacteriophage T4 or lambda to methyl methanesulfonate or ultraviolet irradiation, survival was determined by plating on E. coli have various genetic backgrounds. Although exonuclease III was shown to participate in base excision repair initiated by 3-methyladenine DNA glcosylase I, it had no detectable role in base excision repair initiated by the T4 pyrimidine dimer-DNA glycosylase. Despite its 3 apurinic/apyrimidinic endonuclease activity in vitro, T4 pyrimidine dimer-DNA glycosylase, even in large quantities, did not complement mutants defective in exonuclease III in the repair of apurinic sites generated by 3-methyladenine DNA glycosylase I in vivo.