Abstract
We have discovered that T7 RNA polymerase, purified to apparent homogeneity from overexpressing Escherichia coli cells, possesses a DNase and an RNase activity. Mutations in the active center of T7 RNA polymerase abolished or greatly decreased the nuclease activity. This nuclease activity is specific for single-stranded DNA and RNA oligonucleotides and does not manifest on double-stranded DNAs. Under the conditions of promoter-driven transcription on double-stranded DNA, no nuclease activity was observed. The nuclease attacks DNA oligonucleotides in mono- or dinucleotide steps. The nuclease is a 3' to 5' exonuclease leaving a 3'-OH end, and it degrades DNA oligonucleotides to a minimum size of 3 to 5 nucleotides. It is completely dependent on Mg2+. The T7 RNA polymerase-nuclease is inhibited by T7 lysozyme and heparin, although not completely. In the presence of rNTPs, the nuclease activity is suppressed but an unusual 3'-end-initiated polymerase activity is unmasked. RNA from isolated pre-elongation and elongation complexes arrested by a psoralen roadblock or naturally paused at the 3'-end of an oligonucleotide template exhibited evidence of nuclease activity. The nuclease activity of T7 RNA polymerase is unrelated to pyrophosphorolysis. We propose that the nuclease of T7 RNA polymerase acts only in arrested or paused elongation complexes, and that in combination with the unusual 3'-end polymerizing activity, causes heterogeneity in elongation complexes. Additionally, during normal transcription elongation, the kinetic balance between nuclease and polymerase is shifted in favor of polymerase.
Highlights
RNAP1 is RNA polymerase, P is promoter, RPc is a closed complex, RPo is an open complex, k is a rate constant for the various steps, and NTPs are ribonucleoside triphosphates
Whereas with wild type T7 RNAP, at 60 min a much smaller distribution was observed (Fig. 1, WT, lane 8). This experiment showed that 1) the nuclease activity is due to the polymerase itself; 2) because the overall pattern of cleavage of both ss RNA and ss DNA appears to be the same, a similar mechanism of cleavage probably occurred; 3) the cleavage rates are different for ss DNA versus ss RNA for both wild type and mutant, perhaps due to differential affinities of the polymerase for ss DNA versus ss RNA; and 4) because the mutant T7 RNAP is defective in promoter binding and catalysis [47] and is defective in our cleavage assay here, cleavage is probably catalyzed by the active center of the enzyme
We examined the RNA composition in two different T7 RNAP ternary complexes: 1) elongation complexes apparently paused at the end of an unmodified 66-mer ds DNA template; and 2) elongation complexes arrested by a psoralen cross-link site placed toward the 3Ј-end of the same 66-mer (66XL) template [3]
Summary
Initiation involves binding of RNAP holoenzyme to promoter DNA (RPc) and the isomerization to open complexes (RPo) (for a review, see Ref. 1). The current view of transcription elongation has been possible because of our ability to arrest elongation at specific sites on DNA templates, partial purification of arrested complexes, and the enzymatic and chemical probing of their structures [3,4,5,6,7,8,9,10,11,12,13,14,15,16,17]. E. coli RNAP and eucaryotic RNAP II are capable of RNA cleavage in binary and ternary complexes (24 –26). Nuclease Activity Associated with T7 RNA Polymerase an unusual 3Ј-end-initiated polymerase activity, the RNase activity produces heterogeneity in stalled/arrested T7 RNAP elongation complexes
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
