NF-Y controls fidelity of transcription initiation at gene promoters through maintenance of the nucleosome-depleted region
Andrew J. OldfieldTelmo HenriquesDhirendra KumarAdam BurkholderSenthilkumar CinghuDamien PauletBrian D. BennettPengyi YangBenjamin S. ScruggsChristopher A. LavenderÉric RivalsKaren AdelmanRaja Jothi
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ABSTRACT Faithful transcription initiation is critical for accurate gene expression, yet the mechanisms underlying specific transcription start site (TSS) selection in mammals remain unclear. Here, we show that the histone-fold domain protein NF-Y, a ubiquitously expressed transcription factor, controls the fidelity of transcription initiation at gene promoters. We report that NF-Y maintains the region upstream of TSSs in a nucleosome-depleted state while simultaneously protecting this accessible region against aberrant and/or ectopic transcription initiation. We find that loss of NF-Y binding in mammalian cells disrupts the promoter chromatin landscape, leading to nucleosomal encroachment over the canonical TSS. Importantly, this chromatin rearrangement is accompanied by upstream relocation of the transcription preinitiation complex and ectopic transcription initiation. Further, this phenomenon generates aberrant extended transcripts that undergo translation, disrupting gene expression profiles. These results establish NF-Y as a central player in TSS selection in metazoans and highlight the deleterious consequences of inaccurate transcription initiation.Keywords:
Transcription preinitiation complex
Pioneer factor
Transcription
Ectopic expression
TAF2
General transcription factor
Transcription preinitiation complex
General transcription factor
RNA polymerase II
TATA-binding protein
TAF1
TAF2
TATA-Box Binding Protein
TATA box
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General transcription factor
Transcription coregulator
Transcription preinitiation complex
TAF2
TCF4
Eukaryotic transcription
E-box
Response element
Transcription
RNA polymerase II
Sp3 transcription factor
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Abstract The role of the adenovirus major late upstream transcription factor (MLTF) in transcription from the adenovirus major late and the IVa2 promoters was studied. The transcription initiation site of the IVa2 promoter is located 210 nucleotides upstream from the CAP site of the major late promoter. Transcription from these two promoters occurs on different DNA strands. Thus, this divergent transcription suggests that the same factor could simultaneously regulate the expression of two different genes. This was investigated utilizing a reconstituted transcription system in vitro. The addition of MLTF to reaction mixtures containing the purified general transcription factors and the major late promoter resulted in a 10-12-fold stimulation of transcription. This stimulation was because of an increase of the stability of the preinitiation complex. MLTF allowed DNA template molecules to undergo multiple rounds of transcription. MLTF also stimulated transcription from the adenovirus-encoded IVa2 promoter. Surprisingly, reconstitution experiments indicated that transcription from the IVa2 promoter which does not have a TATA sequence required all the previously described general transcription factors, including TFIID, the TATA binding protein. The requirement for TFIID was demonstrated by reconstitution experiments as well as by oligonucleotide competition experiments. The implications of this observation are discussed.
General transcription factor
TAF2
RNA polymerase II
Transcription preinitiation complex
E-box
Transcription
TATA box
TAF1
Response element
Upstream activating sequence
Sp3 transcription factor
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General transcription factor
TAF2
RNA polymerase II
Transcription preinitiation complex
Transcription
E-box
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Transcription of protein-encoding genes by human RNA polymerase II requires multiple ancillary proteins (transcription factors). Interactions between these proteins and the promoter DNA of a viral class II gene (the major late transcription unit of adenovirus) were investigated by enzymatic and chemical footprinting. The experiments indicated that the assembly of functionally active RNA polymerase II-containing transcription preinitiation complexes requires a complete set of transcription factors, and that both specific protein-DNA and protein-protein interactions are involved. This allows individual steps along the transcription reaction pathway to be tested directly, thus providing a basis for understanding basic transcription initiation mechanisms as well as the regulatory processes that act on them.
Transcription preinitiation complex
General transcription factor
RNA polymerase II
Transcription
TAF2
E-box
Response element
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Class II gene transcription commences with the assembly of the Preinitiation Complex (PIC) from a plethora of proteins and protein assemblies in the nucleus, including the General Transcription Factors (GTFs), RNA polymerase II (RNA pol II), co-activators, co-repressors, and more. TFIID, a megadalton-sized multiprotein complex comprising 20 subunits, is among the first GTFs to bind the core promoter. TFIID assists in nucleating PIC formation, completed by binding of further factors in a highly regulated stepwise fashion. Recent results indicate that TFIID itself is built from distinct preformed submodules, which reside in the nucleus but also in the cytosol of cells. Here, we highlight recent insights in transcription factor assembly and the regulation of transcription preinitiation.
Transcription preinitiation complex
General transcription factor
TAF2
RNA polymerase II
TATA-Box Binding Protein
TAF1
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Commitment of a TATA box-driven class II gene to transcription requires binding of only one transcription factor, TFIID. Additional factors (TFIIB, TFIIE, and RNA polymerase II) do not remain associated with the TFIID-promoter complex during the course of transcription. This indicates that there are two intermediates along the transcription reaction pathway which may be potential targets for the regulation of gene expression.
TAF1
TAF2
General transcription factor
TATA box
RNA polymerase II
Transcription preinitiation complex
E-box
Transcription coregulator
TATA-Box Binding Protein
Transcription
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The transcriptional activation of eukaryotic class II genes by sequence-specific regulatory proteins requires cofactors in addition to the general transcription factors. One cofactor (termed PC3) was purified from HeLa cells and identified by sequence analysis and functional assays as human DNA topoisomerase I (EC5.99.1.2). Under identical conditions PC3 mediates both a net activation of transcription by the acidic activator GAL4-AH and repression of basal transcription, thereby leading to a large induction of transcription by the activator. PC3-mediated activation of transcription is dependent on the presence of both the GAL4-AH activation domain and the TATA-binding protein (TBP)-associated-factors (TAFs) in natural transcription factor TFIID, while repression of basal transcription is observed with either TFIID or the derived TBP alone. These results suggest novel functions, apparently through distinct mechanisms, for human DNA topoisomerase I in the regulation of transcription initiation by RNA polymerase II.
General transcription factor
TAF2
RNA polymerase II
Transcription preinitiation complex
Transcription
TAF1
E-box
TATA box
TATA-Box Binding Protein
Eukaryotic transcription
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We have isolated a cDNA encoding Drosophila transcription factor IIB (dTFIIB) and characterized the properties of recombinant dTFIIB with a reconstituted in vitro transcription system derived from Drosophila embryos. Purified, recombinant dTFIIB is fully active at a concentration of one molecule per template DNA. With different promoters, the transcriptional activity of dTFIIB was similar but not identical to that of human TFIIB, which suggests that there may be variations in the mechanisms by which TFIIB functions in transcription. We have also found that recombinant dTFIIB suppressed nonspecific initiation of transcription by RNA polymerase II by a mechanism that appears to involve direct interaction between TFIIB and the polymerase. Addition of excess dTFIIB to transcription reactions resulted in promoter-specific repression of transcription. These experiments have led to the hypothesis that TFIIB interacts with a basal transcription factor that is required for transcription of some, but not all, genes and that the presence of excess dTFIIB results in sequestration of the promoter-specific basal factor to prevent its assembly into a productive transcription complex. Excess dTFIIB did not, however, affect the ability of either GAL4-VP16 or Sp1 to stimulate transcription. These data indicate that in contrast to current models, GAL4 derivatives do not activate transcription by increasing the rate of assembly of TFIIB into the transcription complex.
General transcription factor
Transcription preinitiation complex
RNA polymerase II
Transcription
TAF2
E-box
Transcription coregulator
Eukaryotic transcription
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