Proteolytic DNA for mapping protein-DNA interactions

We describe a technique to determine sites on proteins involved in protein-DNA interactions. DNA was synthesized via polymerase chain reaction (PCR) to produce four polynucleotide products with phosphorothioate nucleotides at the A, T, G, or C residues. Limited conjugation with the chemical protease FeBABE results in the surface of DNA being randomly labeled at the phosphorothioate sites with this protein-cleaving reagent. After formation of a protein-DNA complex, the proteolytic DNA can be activated to cleave the protein backbone at sites near the DNA. This technique was used to study the bacterial RNA polymerase/lacUV5 DNA open promoter complex, about which significant structural information is available. Cleavage sites on the two largest subunits of RNA polymerase, beta and beta', agree well with a recent model based on the crystal structure of the core enzyme alpha(2)betabeta' [Naryshkin, N., Revyakin, A., Kim, Y., Mekler, V., and Ebright, R. H. (2000) Cell 101, 601-611]. The cleavage site present on alpha supports previous studies regarding DNA binding regions of the alpha subunit. Cleavage sites identified throughout the sigma(70) subunit help to orient it with respect to the open promoter complex.     

Structure and function of lineage-specific sequence insertions in the bacterial RNA polymerase beta' subunit

The large beta and beta' subunits of the bacterial core RNA polymerase (RNAP) are highly conserved throughout evolution. Nevertheless, large sequence insertions in beta and beta' characterize specific evolutionary lineages of bacteria. The Thermus aquaticus RNAP beta' subunit contains a 283 residue insert between conserved regions A and B that is found in only four bacterial species. The Escherichia coli RNAP beta' subunit contains a 188 residue insert in the middle of conserved region G that is found in a wide range of bacterial species. Here, we present structural studies of these two beta' insertions. We show that the inserts comprise repeats of a previously characterized fold, the sandwich-barrel hybrid motif (as predicted from previous sequence analysis) and that the inserts serve significant roles in facilitating protein/protein and/or protein/nucleic acid interactions.     

Distinctive protein signatures provide molecular markers and evidence for the monophyletic nature of the deinococcus-thermus phylum

The Deinococcus-Thermus group of species is currently recognized as a distinct phylum solely on the basis of their branching in 16S rRNA trees. No unique biochemical or molecular characteristics that can distinguish this group from all other bacteria are known at present. In this work, we describe eight conserved indels (viz., inserts or deletions) in seven widely distributed proteins that are distinctive characteristics of the Deinococcus-Thermus phylum but are not found in any other group of bacteria. The identified signatures include a 7-amino-acid (aa) insert in threonyl-tRNA synthetase, 1- and 3-aa inserts in the RNA polymerase beta' subunit, a 5-aa deletion in signal recognition particle (Ffh/SR54), a 2-aa insert in major sigma factor 70 (sigma70), a 2-aa insert in seryl-tRNA synthetase (SerRS), a 1-aa insert in ribosomal protein L1, and a 2-aa insert in UvrA homologs. By using PCR primers for conserved regions, fragments of these genes were amplified from a number of Deinococcus-Thermus species, and all such fragments (except SerRS in Deinococcus proteolyticus) were found to contain the indicated signatures. The presence of these signatures in various species from all three known genera within this phylum, viz., Deinococcus, Thermus, and Meiothermus, provide evidence that they are likely distinctive characteristics of the entire phylum which were introduced in a common ancestor of this group. The signature in SerRS, which is absent in D. proteolyticus, was likely introduced after the branching of this species. Phylogenetic studies as well as the nature of the inserts in some of these proteins (viz., sigma70 and SerRS) also support a sister group relationship between the Thermus and the Meiothermus genera. The identified signatures provide strong evidence for the monophyletic nature of the Deinococcus-Thermus phylum. These molecular markers should prove very useful in the identification of new species related to this group.