Topology of yeast RNA polymerase II subunits in transcription elongation complexes studied by photoaffinity cross-linking.

The subunits of Saccharomyces cerevisiae RNA polymerase II (RNAP II) in proximity to the DNA during transcription elongation have been identified by photoaffinity cross-linking. In the absence of transcription factors, RNAP II will transcribe a double-stranded DNA fragment containing a 3'-extension of deoxycytidines, a "tailed template". We designed a DNA template allowing the RNAP to transcribe 76 bases before it was stalled by omission of CTP in the transcription reaction. This stall site oriented the RNAP on the DNA template and allowed us to map the RNAP subunits along the DNA. The DNA analogue 5-[N-(p-azidobenzoyl)-3-aminoallyl]-dUTP (N(3)RdUTP) [Bartholomew, B., Kassavetis, G. A., Braun, B. R., and Geiduschek, E. P. (1990) EMBO J. 9, 2197-205] was synthesized and enzymatically incorporated into the DNA at specified positions upstream or downstream of the stall site, in either the template or nontemplate strand of the DNA. Radioactive nucleotides were positioned beside the photoactivatable nucleotides, and cross-linking by brief ultraviolet irradiation transferred the radioactive tag from the DNA onto the RNAP subunits. In addition to N(3)RdUTP, which has a photoreactive azido group 9 A from the uridine base, we used the photoaffinity cross-linker 5N(3)dUTP with an azido group directly on the uridine ring to identify the RNAP II subunits closest to the DNA at positions where multiple subunits cross-linked. In cross-linking reactions dependent on transcription, RPB1, RPB2, and RPB5 were cross-linked with N(3)RdUTP. With 5N(3)dUTP, only RPB1 and RPB2 were cross-linked. Under certain circumstances, RPB3, RPB4, and RPB7 were cross-linked. From the information obtained in this topological study, we developed a model of yeast RNAP II in a transcription elongation complex.

Use of asymmetric PCR to generate long primers and single-stranded DNA for incorporating cross-linking analogs into specific sites in a DNA probe.

Photoactivatable DNA analogs have been incorporated enzymatically into DNA and used to map the locations of polypeptides in protein complexes bound to DNA. We have developed a procedure for generating long primers from short oligodeoxyribonucleotides (oligos) to incorporate DNA cross-linkers at specific sites within either strand of DNA probes of < or = 206 bp. Single-stranded DNA molecules of 52-206 nucleotides in length were generated by asymmetric polymerase chain reactions (aPCR), using an excess of one short sense-strand primer to be extended and a limiting amount of each short antisense primer that is complementary to and defines the 3' end of the long primer to be generated. The noncross-linking strand of the DNA probe was also generated by aPCR from the DNA sequence of interest. The long primers were annealed to the full-length noncross-linking DNA strand to form a partially double-stranded DNA. Cross-linking analogs and radioactive deoxyribonucleotides (dNTPs), followed by normal dNTPs, were enzymatically incorporated onto the long primers to form the double-stranded DNA cross-linking probes. This method is reproducible and avoids many of the difficulties encountered by other published methods.