Interaction of Escherichia coli DNA polymerase I with azidoDNA and fluorescent DNA probes: identification of protein-DNA contacts

The synthesis of an azidoDNA duplex and its use to photolabel DNA polymerases have been previously described (Gibson & Benkovic, 1987). We now present detailed experiments utilizing this azidoDNA photoprobe as a substrate for Escherichia coli DNA polymerase I (Klenow fragment) and the photoaffinity labeling of the protein. The azidoDNA duplex is an efficient substrate for both the polymerase and 3'----5' exonuclease activities of the enzyme. However, the hydrolytic degradation of the azido-bearing base is dramatically impaired. On the basis of the ability of these duplexes to photolabel the enzyme, we have determined that the protein contacts between five and seven bases of duplex DNA. Incubation of azidoDNA with the Klenow fragment in the presence of magnesium results in the in situ formation of a template-primer with the azido-bearing base bound at the polymerase catalytic site of the enzyme. Photolysis of this complex followed by proteolytic digestion and isolation of DNA-labeled peptides results in the identification of a single residue modified by the photoreactive DNA substrate. We identify Tyr766 as the modified amino acid and thus localize the catalytic site for polymerization in the protein. A mansyl-labeled DNA duplex has been prepared as a fluorescent probe of protein structure. This has been utilized to determine the location of the primer terminus when bound to the Klenow fragment. When the duplex contains five unpaired bases in the primer strand of the duplex, the primer terminus resides predominantly at the exonuclease catalytic site of the enzyme. Removal of the mismatched bases by the exonuclease activity of the enzyme yields a binary complex with the primer terminus now bound predominantly at the polymerase active site. Data are presented which suggest that the rate-limiting step in the exonuclease activity of the enzyme is translocation of the primer terminus from polymerase to exonuclease catalytic sites.     

Interaction of Escherichia coli RNA polymerase with eukaryotic TATA-binding protein

Interaction with eukaryotic TATA-binding protein (TBP) was analyzed for natural Escherichia coli RNA polymerase or the recombinant holoenzyme, minimal enzyme, or its sigma subunit. Upon preincubation of full-sized RNA polymerase with TBP and further incubation with a constant amount of 32P-labeled phosphamide derivative of a TATA-containing oligodeoxyribonucleotide, the yield of the holoenzyme-oligonucleotide covalent complex decreased with increasing TBP concentration. This was considered as indirect evidence for complexing of RNA polymerase with TBP. In gel retardation assays, the holoenzyme, but neither minimal enzyme nor the sigma subunit, interacted with TPB, since the labeled probe formed complexes with both proteins in the reaction mixture combining TBP with the minimal enzyme or the sigma subunit. It was assumed that E. coli RNA polymerase is functionally similar to eukaryotic RNA polymerase II, and that the complete ensemble of all subunits is essential for the specific function of the holoenzyme.     

Conformation of fork junction DNA in a complex with Escherichia coli RNA polymerase

Escherichia coli RNA polymerase is able to bind fork junction DNA containing a conserved -10 promoter element in a sequence-specific manner, and it is believed that polymerase-fork junction DNA interaction mimics those between the enzyme and the promoter DNA in the open complex. In this report we determined the conformation of polymerase-bound fork junction DNA in solution. A series of distances between sites in the fork junction DNA in complex with polymerase were determined using luminescence and fluorescence resonance energy transfer. A series of fork junction DNAs were prepared containing the luminescent or fluorescent donor probe at the upstream or at the downstream end of the fork DNA and acceptor probes at nine positions within the fork junction DNA. The measured distances were compared with analogous distances in a model reference DNA duplex, and the observed distance differences were used to build a model of the fork junction DNA in a complex with the polymerase. The obtained model revealed an insignificant perturbation of the duplex part of the fork DNA in a complex with the polymerase whereas a sharp kink of DNA was observed at the ds/ss DNA boundary of the fork junction DNA.     

Interaction of Cibacron Blue F3GA with Escherichia coli DNA polymerase I and with T4 DNA polymerase.

Individual rapid procedures for the enrichment of Escherichia coli DNA polymerase I and of bacteriophage T4 DNA polymerase free of endonuclease activity are described using Blue dextran-Sepharose chromatography. The blue dye of Blue dextran-Sepharose selectively binds to the deoxynucleoside triphosphate substrate site of the E. coli but not the T4 enzyme indicating that the catalytic sites of these two enzymes which catalyze the same polymerization reaction in vitro are quite distinct.     

Physiochemical studies on interactions between DNA and RNA polymerase. Unwinding of the DNA helix by Escherichia coli RNA polymerase.

In a medium containing 10mM Tris, pH 8, 10 mM MG++, 50 mM K+ and 10 mM NH4, the binding of an E. coli RNA polymerase holoenzyme unwinds the DNA helix by about 240 degrees at 37 degrees C. In this medium the total unwinding of the DNA increases linearly with the molar ratio of polymerase to DNA. The number of binding sites at which unwinding can occur is very large. If the K+ concentration is increased at 200 mM, the enzyme binds to only a limited number of sites, and the bound and free enzyme molecules do not exchange at an appreciable rate. The unwinding angle of the DNA per bound enzyme in this high salt medium is measured to be 140 degrees at 37 degrees C. The total unwinding angle for a fixed number of bound polymerase molecules per DNA is strongly temperature dependent, and decreases with decreasing temperature.     

Flexibility of the DNA enhances promoter affinity of Escherichia coli RNA polymerase.

Two types of mechanisms are discussed for the formation of active protein-DNA complexes: contacts with specific bases and interaction via specific DNA structures within the cognate DNA. We have studied the effect of a single nucleoside deletion on the interaction of Escherichia coli RNA polymerase with a strong promoter. This study reveals three patterns of interaction which can be attributed to different sites of the promoter, (i) direct base contact with the template strand in the '-35 region' (the 'recognition domain'), (ii) a DNA structure dependent interaction in the '-10 region' (the 'melting domain'), and (iii) an interaction which is based on a defined spatial relationship between the two domains of a promoter, namely the 'recognition domain' and the 'melting domain'.