The Legacy of 20th Century Phage Research.

The Golden Age of Phage Research, where phage was the favored material for attacking many basic questions in molecular biology, lasted from about 1940 to 1970. The era was initiated by Ellis and Delbrück, whose analysis defined the relevant parameters to measure in studying phage growth, and depended on the fact that the contents of a plaque can comprise descendants of a single infecting particle. It ended around 1970 because definitive methods had then become available for answering the same questions in other systems. Some of the accomplishments of phage research were the demonstration by Hershey and Chase that the genetic material of phage T2 is largely composed of DNA, the construction of linkage maps of T2 and T4 by Hershey and Rotman and their extension to very short molecular distances by Benzer, and the isolation of conditionally lethal mutants in T4 by Epstein et al. and in λ by Campbell. The dissection of the phage life cycle into causal chains was explored by Edgar and Wood for T4 assembly and later in the regulation of lysogeny by Kaiser, extended to the molecular level by Ptashne and others. Restriction/modification was discovered in λ by Bertani and Weigle, and the biochemical mechanism was elucidated by Arber and by Smith.

Preferential orientation of natural lambdoid prophages and bacterial chromosome organization.

All known lambdoid prophages of Escherichia coli have the same orientation with respect to direction of chromosomal replication. This includes 12 prophages that are replicated in one direction and five in the other. Among candidate explanations, the most amenable to experimental study is an effect on dif site function in assuring chromosomal segregation. This is but one of numerous examples of strand bias in the E. coli genome, all of which may interact with one another.

Predicting gene expression levels from codon biases in alpha-proteobacterial genomes.

Predicted highly expressed (PHX) genes in five currently available high G+C complete alpha-proteobacterial genomes are analyzed. These include: the nitrogen-fixing plant symbionts Sinorhizobium meliloti (SINME) and Mesorhizobium loti (MESLO), the nonpathogenic aquatic bacterium Caulobacter crescentus (CAUCR), the plant pathogen Agrobacterium tumefaciens (AGRTU), and the mammalian pathogen Brucella melitensis (BRUME). Three of these genomes, SINME, AGRTU, and BRUME, contain multiple chromosomes or megaplasmids (>1 Mb length). PHX genes in these genomes are concentrated mainly in the major (largest) chromosome with few PHX genes found in the secondary chromosomes and megaplasmids. Tricarboxylic acid cycle and aerobic respiration genes are strongly PHX in all five genomes, whereas anaerobic pathways of glycolysis and fermentation are mostly not PHX. Only in MESLO (but not SINME) and BRUME are most glycolysis genes PHX. Many flagellar genes are PHX in MESLO and CAUCR, but mostly are not PHX in SINME and AGRTU. The nonmotile BRUME also carries many flagellar genes but these are generally not PHX and all but one are located in the second chromosome. CAUCR stands out among available prokaryotic genomes with 25 PHX TonB-dependent receptors. These are putatively involved in uptake of iron ions and other nonsoluble compounds.