Fluorescence study of secondary structure of DNA within bacteriophage lambda

Bromoacetaldehyde (BAA) was used to study the secondary structure of DNA in lambda-phage particles. It was determined that about 1% of the adenines in the intraphage lambda-DNA reacts readily with BAA, thus, they are placed in DNA sites with disturbed complementary interactions. These adenines are close to the tryptophan residues of the phage protein. Fluorescence emission of epsilon A in the intraphage DNA is dramatically quenched. This, apparently, indicates the interaction between epsilon A and Trp- and/or Tyr- and/or Met-residues of phage protein.     

The Z-form of bacteriophage lambda DNA, modified in situ

Using the methods of chemical modification, restriction analysis and immune-electron microscopy it has been shown that the definite regions of the bacteriophage lambda DNA contain unpaired bases in situ. The distribution map of such sites along the genome has been constructed. The correlation of the in situ modification and the reaction with anti-Z-DNA antibodies is shown for the 44972 bp site of bacteriophage DNA. The possibility of the existence of Z-form DNA in situ is discussed.     

Complex of single-stranded phage DNA and protein--a product of bacteriophage fl gene 3. Distribution of gene 3 protein in the DNA molecule

Upon a 50% isopropanol treatment of phage fl in a 1 M NaCl solution protein A (gene 3 product)--DNA complex is precipitated while protein B (gene 8 product) was still solubilized. After such a treatment the DNA--protein complex containing 10--40% of protein A and less than 0.0025% of protein B was obtained. Evidence was obtained that there was no non-specific rearrangement of protein A during the isolation procedure. The complex was treated with endonuclease R.HAC III, followed by electrophoresis of the resulted fragments and estimation of the [14C] protein A (labeled with [14C]histidine) throughout the gel. The maximal radioactivity coincided with the DNA bands, being proportional to the DNA content in the respective bands. The data obtained indicate that protein A is iniformly arranged along the DNA molecule.     

Temperate bacteriophage ZF40 of Erwinia carotovora: phage particle structure and DNA restriction analysis

Structural organization of the temperate bacteriophage ZF40 of Erwinia carotovora was studied. Phage ZF40 proved to be a typical member of the Myoviridae family (morphotype A1). Phage particles consist of an isometric head 58.3 nm in diameter and a contractile 86.3-nm-long tail with a complex basal plate and short tail fibers (31.5 nm). Phage tail sheath, a truncated cone in shape, is characterized by specific packaging of structural subunits. The ZF40 phage genome is 45.8 kb in size, as determined by restriction analysis, and contains DNA cohesive ends. The ZF40 phage of Erwinia carotovora is assumed to be a new species of bacteriophages specific for enterobacteria.     

Characterization of bacteriophage N3 DNA.

The DNA from Haemophilus influenzae temperate phage N3 was characterized by centrifugation and by electrophoresis after nuclease digestion. The double-stranded DNA, with a mass of 25.8 X 10(6) daltons, had single-strand cohesive ends. Strand association through cohesion was reduced by heat and removed by S1 nuclease digestion. N3 DNA contained five EcoRI, one KpnI, two SacI, six XbaI, and four XhoI cleavage sites. The cohesive end segments were identified by heating the digests before electrophoresis. This was the first step in the construction of the physical maps of this DNA.     

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.     

Codon usage and secondary structure of MS2 phage RNA.

MS2 is an RNA bacteriophage (3569 bases). The secondary structure of the RNA has been determined, and is known to play an important role in regulating translation. Paired regions of the genome have a higher G+C content than unpaired regions. It has been suggested that this reflects selection for high G+C content to encourage pairing, but a re-analysis of the data together with computer simulation suggest that it is an automatic consequence in any RNA sequence of the way it folds up to minimise its free energy. It has also been suggested that the three registers in which pairing can occur in a coding region are used differentially to optimise the use of the redundancy of the genetic code, but re-analysis of the data shows only weak statistical support for this hypothesis.     

The rolling-circle replicative structure of a bacteriophage lambda DNA

Intermediates of λ DNA replication in the second half of the latent period have been isolated and investigated in the electron microscope. The isolated replicative structures were predominantly single-branched “$\text{rolling-circle}$” replicative forms. The long linear tails (concatemers) may be the precursor of mature λ DNA.     

Role of cytosine photohydrates in the UV-induced mutagenesis of phage Sd]

Substitution of H2O for D2O does not affect the rate of UV-inactivation of the extracellular phage Sd, containing double-stranded DNA. However, the yield of plaque-mutants induced by UV-irradiation in D2O is significantly lower, that in H2O. This difference is mostly pronounced at doses greater than 100 erg/mm2. Since the substitution of H2O for D2O selectively decelerate photohydration of pyrimidines (only cytosines in DNA), one could conclude that the formation of cytosine photohydrates in DNA accounts for significant part of UV-induced mutations but it is not an essential reason for UV-inactivation of extracellular phage Sd.     

Circular dichroism and DNA secondary structure.

The change in average rotation of the DNA helix has been determined for the transfer from 0.05 M NaCl to 3.0 M CsCl, 6.2 M LiCl and 5.4 M NH4Cl. This work, combined with data at lower salt from other laboratories, allows us to relate the intensity of the CD of DNA at 275 nm directly to the change in the number of base pairs per turn. The change in secondary structure for the transfer of DNA from 0.05 M NaCl (where it is presumably in the B-form) to high salt (where the characteristic CD has been interpreted as corresponding to C-form geometry) is found to be -0.22 (+/- 0.02) base pairs per turn. In the case of mononucleosomes, where the CD indicates the "C-form", the change in secondary structure (including temperature effects) would add -0.31 (+/- 0.03) turns about the histone core to the -1.25 turns estimated from work on SV40 chromatin. Accurate winding angles and molar extinction coefficients were determined for ethidium.     

Phylogenetic analysis and secondary structure of the Bacillus subtilis bacteriophage RNA required for DNA packaging

An unusual RNA molecule encoded by the Bacillus subtilis bacteriophage phi 29 is a structural component of the viral prohead and is required for the ATP-dependent packaging of DNA. Here we report a model of secondary structure for this prohead RNA developed from a phylogenetic analysis of the primary sequences of prohead RNAs of related phages. Twenty-nine phages related to phi 29 were found to produce prohead RNAs. These RNAs were analyzed by their ability to replace phi 29 RNA in in vitro phage assembly, by Northern blot hybridization with a probe complementary to phi 29 RNA, and by partial and complete sequence analyses. These analyses revealed four quite different sequences ranging in length from 161 to 174 residues. The secondary structure deduced from these sequences, in agreement with earlier observations, indicated that prohead RNA is organized into two domains. The larger 5'-domain (Domain I) is composed of 113-117 residues and contains four helices. Three of these helices appear to be organized into a central stem that is interrupted by two unpaired loops and the fourth helix and loop. The smaller 3'-domain (Domain II) is composed of 40-44 residues and consists of two helices. Domains I and II are separated by 8-13 unpaired residues. Nuclease cleavage occurs readily in this single-stranded joining region, and this cleavage allows the subsequent separation of the two RNA domains. The separated Domain I is fully active in DNA packaging in vitro. The functional significance and biological role of Domain II are unknown. The phylogenetic secondary structure model provides a basis for further analysis of the role of this RNA in bacteriophage morphogenesis.