Specific contacts between the bacteriophage T3, T7, and SP6 RNA polymerases and their promoters

The specificity and structural simplicity of the bacteriophage T3, T7, and SP6 RNA polymerases make these enzymes particularly well suited for studies of polymerase-promoter interactions. To understand the initial recognition process between the enzyme and its promoters, DNA fragments that carry phage promoters were chemically modified by three different methods: base methylation, phosphate ethylation, and base removal. The positions at which these modifications prevented or enhanced binding by the RNA polymerases were then determined. The results indicate that specific contacts within the major groove of the promoter between positions-5 and -12 are important for phage polymerase binding. Removal of individual bases from either strand of the initiation region (-5 to +3) resulted in enhanced binding of the polymerase, suggesting that disruption of the helix in this region may play a role in stabilization of the polymerase-promoter complexes.     

Identification of a region of the bacteriophage T3 and T7 RNA polymerases that determines promoter specificity

Bacteriophages T7 and T3 encode DNA-dependent RNA polymerases that are 82% homologous, yet exhibit a high degree of specificity for their own promoters. A region of the RNA polymerase gene (gene 1) that is responsible for this specificity has been localized using two approaches. First, the RNA polymerase genes of recombinant T7 x T3 phage that had been generated in other laboratories in studies of phage polymerase specificity were characterized by restriction enzyme mapping. This approach localized the region that determines promoter specificity to the 3' end of the polymerase gene, corresponding to the carboxyl end of the polymerase protein distal to amino acid 623. To define more closely the region of promoter specificity, a series of hybrid T7/T3 RNA polymerase genes was constructed by in vitro manipulation of the cloned genes. The specificity of the resulting hybrid RNA polymerases in vitro and in vivo indicates that an interval of the polymerase that spans amino acids 674 to 752 (the 674 to 752 interval) contains the primary determinant of promoter preference. Within this interval, the amino acid sequences of the T3 and T7 enzymes differ at only 11 out of 79 positions. It has been shown elsewhere that specific recognition of T3 and T7 promoters depends largely upon base-pairs in the region from -10 to -12. An analysis of the preference of the hybrid RNA polymerases for synthetic T7 promoter mutants indicates that the 674 to 752 interval is involved in identifying this region of the promoter, and suggests that another domain of the polymerase (which has not yet been identified) may be involved in identifying other positions where the two consensus promoter sequences differ (most notably at position -15).     

Structure of T7 RNA polymerase complexed to the transcriptional inhibitor T7 lysozyme.

The T7 RNA polymerase-T7 lysozyme complex regulates phage gene expression during infection of Escherichia coli. The 2.8 A crystal structure of the complex reveals that lysozyme binds at a site remote from the polymerase active site, suggesting an indirect mechanism of inhibition. Comparison of the T7 RNA polymerase structure with that of the homologous pol I family of DNA polymerases reveals identities in the catalytic site but also differences specific to RNA polymerase function. The structure of T7 RNA polymerase presented here differs significantly from a previously published structure. Sequence similarities between phage RNA polymerases and those from mitochondria and chloroplasts, when interpreted in the context of our revised model of T7 RNA polymerase, suggest a conserved fold.     

Probing the nucleotide binding sites in T7 RNA polymerase using cibacron blue

T7 RNA polymerase (T7 RNAP) is an enzyme that utilizes ribonucleotides to synthesize the nascent RNA chain in a template-dependent manner. In this work we have studied the interaction of T7 RNAP with cibacron blue, an anthraquinone monochlorotriazine dye, and its effect on the function of the enzyme. T7 RNAP binds to the dye in a bi-phasic manner. The first phase of the binding is characterized by a high affinity (Kd in the nanomolar range) and reversible inactivation of the enzyme. The second binding site is the common substrate binding site. The association of the dye with T7 RNAP is a good model to understand the physiological significance of a high affinity binding of the initiating nucleotide, GTP, earlier reported from our laboratory. The results will be discussed to understand the role of the high affinity GTP binding.     

Affinity modification of DNA-dependent RNA-polymerase from phage T7 with 5'-p-fluorosulfonylbenzoyl adenosine: the effect of modification on the interaction with substrates

T7 RNA polymerase, covalently modified with 5'-p-fluorosulfonylbenzoyl adenosine, looses the ability of binding the promoter (pGEM-2 plasmid) and poly(dC) template as well as the initiating nucleoside triphosphate (GTP). However the enzyme retains the unspecific binding with DNA fragments of considerable length.     

Site-specific DNA binding by the bacteriophage SP01-encoded type II DNA-binding protein

The bacteriophage SP01 genome encodes a virus-specific type II DNA-binding protein, TF1. The bacterial proteins of this ubiquitous and evolutionarily conserved class are thought to bind non-specifically to DNA. In contrast, the experiments described here demonstrate that TF1 binds to specific sites in SP01 DNA. Several of these sites have been characterized by DNase I 'footprinting' and four of them have been shown to overlap strong phage promoters for Bacillus subtilis RNA polymerase holoenzyme. We speculate on the possible structural basis of site-selective DNA binding by a protein of this class.