Animals have some TBP-related factors (TRF;
TBPL1/
TBPL2). They can replace TBP in some special contexts.[7]
TBP recruits TFIIA, then TFIIB, to the promoter.
TFIIB recruits RNA polymerase II and TFIIF to the promoter.
TFIIE joins the growing complex and recruits TFIIH which has protein kinase activity (phosphorylates RNA polymerase II within the CTD) and DNA helicase activity (unwinds DNA at promoter). It also recruits nucleotide-excision repair proteins.
Subunits within TFIIH that have
ATPase and
helicase activity create negative
superhelical tension in the DNA.
Negative superhelical tension causes approximately one turn of DNA to
unwind and form the
transcription bubble.
The template strand of the transcription bubble engages with the RNA polymerase II active site.
RNA synthesis begins.
After synthesis of ~10 nucleotides of RNA, and an obligatory phase of several abortive transcription cycles, RNA polymerase II escapes the promoter region to transcribe the remainder of the gene.
An alternative hypothesis of PIC assembly postulates the recruitment of a pre-assembled "
RNA polymerase II holoenzyme" directly to the promoter (composed of all, or nearly all GTFs and RNA polymerase II and regulatory complexes), in a manner similar to the bacterial RNA polymerase (RNAP).
Other preinitiation complexes
In Archaea
Archaea have a preinitiation complex resembling that of a minimized Pol II PIC, with a TBP and an
Archaeal transcription factor B (TFB, a TFIIB homolog). The assembly follows a similar sequence, starting with TBP binding to the promoter. An interesting aspect is that the entire complex is bound in an inverse orientation compared to those found in eukaryotic PIC.[8] They also use TFE, a TFIIE homolog, which assists in transcription initiation but is not required.[9][10]
Formation of the Pol I preinitiation complex requires the binding of
selective factor 1 (SL1 or TIF-IB) to the core element of the
rDNA promoter.[11] SL1 is a complex composed of
TBP and at least three
TBP-associated factors (TAFs). For basal levels of transcription, only SL1 and the initiation-competent form of
Pol I (Pol Iβ), characterized by
RRN3 binding, are required.[12][13]
For activated transcription levels,
UBTF (UBF) is also required. UBTF binds as a dimer to both the upstream control element (UCE) and core element of the rDNA promoter, bending the DNA to form an
enhanceosome.[13][12] SL1 has been found to stabilize the binding of UBTF to the rDNA promoter.[11]
The subunits of the Pol I PIC differ between organisms.[14]
Pol III has three classes of initiation, which start with different factors recognizing different control elements but all converging on TFIIIB (similar to TFIIB-TBP; consists of TBP/TRF, a
TFIIB-related factor, and a
B″ unit) recruiting the Pol III preinitiation complex. The overall architecture resembles that of Pol II. Only TFIIIB needs to remain attached during elongation.[15]
^Bell, SD; Jackson, SP (June 1998). "Transcription and translation in Archaea: a mosaic of eukaryal and bacterial features". Trends in Microbiology. 6 (6): 222–8.
doi:
10.1016/S0966-842X(98)01281-5.
PMID9675798.