A rapid purification method for human RNA polymerase II by two-step affinity chromatography.

The molecular dissection of transcription mechanisms is greatly facilitated by constructing and manipulating defined transcription systems in vitro. This approach requires highly purified transcription factors. A major enzyme participating in the transcription reaction is RNA polymerase II (RNAPII), which is composed of at least 12 subunits (RPB1-12). Due to its complex structure, it is difficult to prepare highly pure RNAPII by the conventional purification procedure. We transfected HeLa cells with a plasmid expressing RPB3 with a double FLAG-histidine tag on its amino-terminus. A high yielding clone was isolated and its extracts were subjected to immunoaffinity purification and then Co(2+) affinity chromatography. This resulted in a preparation of RNAPII complexes that consisted of all the core subunits, including the double-tagged RPB3 protein. Transcription reactions with oligo (dC)-tailed templates and transcription assays involving general transcription factors revealed that the double-tagged RNAPII complexes are active and functional in basal and activated transcription. Our method is superior to the conventionally used purification procedure in that the final preparation is markedly more pure (92% versus 40%), and the procedures are much less time-consuming. Thus, this two-step affinity purification method is an uncomplicated and effective method by which active and functional RNAPII can be prepared.

Effects of endogenous DNA base lesions on transcription elongation by mammalian RNA polymerase II. Implications for transcription-coupled DNA repair and transcriptional mutagenesis.

The blockage of transcription elongation by RNA polymerase II (pol II) is thought to be a trigger for transcription-coupled repair in the pathway of nucleotide excision repair. Purified pol II and oligo(dC)-tailed templates containing a single non-bulky DNA lesion on the transcribed strand such as an apurinic/apyrimidinic (AP) site, uracil, or 8-oxoguanine (8-oxoG) were used for transcription elongation assays. In this system pol II could bypass both the AP site and uracil without pausing and insert cytosine opposite the AP site and either guanine or adenine opposite to uracil. Thus, the AP site on the DNA templates could lead to correct transcription only if depurination at guanine occurred, whereas uracil generated either the correct transcriptional product or an incorrect one with a G:C to A:T transition. In the case of 8-oxoG, pol II stalled at the lesion, but sometimes bypassed it and inserted a cytosine residue or the incorrect adenine residue leading to a G:C to T:A transversion. These findings indicate that 8-oxoG lesions caused a blockage of transcription elongation and/or the misincorporation of a ribonucleotide by pol II, implying the initiation of transcription-coupled repair of 8-oxoG and/or transcriptional mutagenesis.