Conserved structural motifs within the N-terminal domain of TFIID tau from Xenopus, mouse and human

Fundamental cellular processes do not require vertebrate-specific sequences within the TATA-binding protein

The 180-amino acid core of the TATA-binding protein (TBPcore) is conserved from Archae bacteria to man. Vertebrate TBPs contain, in addition, a large and highly conserved N-terminal region that is not found in other phyla. We have generated a line of mice in which the tbp allele is replaced with a version, tbp(Delta N), which lacks 111 of 135 N-terminal amino acid residues. Most tbp(Delta N/Delta N) fetuses die in midgestation. To test whether a disruption of general cellular processes contributed to this fetal loss, primary fibroblast cultures were established from +/+, Delta N/+, and Delta N/Delta N fetuses. The cultures exhibited no genotype-dependent differences in proliferation or in expression of the proliferative markers dihydrofolate reductase (DHFR) mRNA (S phase-specific) and cdc25B mRNA (G(2)-specific). The mutation had no effect on transcription initiation site fidelity by either RNA polymerase II (pol II) or pol III. Moreover, the mutation did not cause differences in levels of U6 RNA, a pol III-dependent component of the splicing machinery, in mRNA splicing efficiency, in expression of housekeeping genes from either TATA-containing or TATA-less promoters, or in global gene expression. Our results indicated that general eukaryotic cell functions are unaffected by deletion of these vertebrate-specific sequences from TBP. Thus, all activities of this polypeptide domain must either be compensated for by redundant activities or be restricted to situations that are not represented by primary fibroblasts.

Removing the vertebrate-specific TBP N terminus disrupts placental beta2m-dependent interactions with the maternal immune system

Mammalian TBP consists of a 180 amino acid core that is common to all eukaryotes, fused to a vertebrate-specific N-terminal domain. We generated mice having a modified tbp allele, tbp(DeltaN), that produces a version of TBP lacking 111 of the 135 vertebrate-specific amino acids. Most tbp(DeltaN/DeltaN) fetuses (>90%) died in midgestation from an apparent defect in the placenta. tbp(DeltaN/DeltaN) fetuses could be rescued by supplying them with a wild-type tetraploid placenta. Mutants also could be rescued by rearing them in immunocompromised mothers. In immune-competent mothers, survival of tbp(DeltaN/DeltaN) fetuses increased when fetal/placental beta2m expression was genetically disrupted. These results suggest that the TBP N terminus functions in transcriptional regulation of a placental beta2m-dependent process that favors maternal immunotolerance of pregnancy.

The binding interaction of HMG-1 with the TATA-binding protein/TATA complex

High mobility protein-1 (HMG-1) has been shown to regulate transcription by RNA polymerase II. In the context that it acts as a transcriptional repressor, it binds to the TATA-binding protein (TBP) to form the HMG-1/TBP/TATA complex, which is proposed to inhibit the assembly of the preinitiation complex. By using electrophoretic mobility shift assays, we show that the acidic C-terminal domain of HMG-1 and the N terminus of human TBP are the domains that are essential for the formation of a stable HMG-1/TBP/TATA complex. HMG-1 binding increases the affinity of TBP for the TATA element by 20-fold, which is reflected in a significant stimulation of the rate of TBP binding, with little effect on the dissociation rate constant. In support of the binding target of HMG-1 being the N terminus of hTBP, the N-terminal polypeptide of human TBP competes with and inhibits HMG-1/TBP/TATA complex formation. Deletion of segments of the N terminus of human TBP was used to map the region(s) where HMG-1 binds. These findings indicate that interaction of HMG-1 with the Q-tract (amino acids 55-95) in hTBP is primarily responsible for stable complex formation. In addition, HMG-1 and the monoclonal antibody, 1C2, specific to the Q-tract, compete for the same site. Furthermore, calf thymus HMG-1 forms a stable complex with the TBP/TATA complex that contains TBP from either human or Drosophila but not yeast. This is again consistent with the importance of the Q-tract for this stable interaction and shows that the interaction extends over many species but does not include yeast TBP.

Translation of maternal TATA-binding protein mRNA potentiates basal but not activated transcription in Xenopus embryos at the midblastula transition

Early embryonic development in Xenopus laevis is characterized by transcriptional repression which is relieved at the midblastula stage (MBT). Here we show that the relative abundance of TATA-binding protein (TBP) increases robustly at the MBT and that the mechanism underlying this increase is translation of maternally stored TBP RNA. We show that TBP is rate-limiting in egg extract under conditions that titrate nucleosome assembly. Precocious translation of TBP mRNA in Xenopus embryos facilitates transcription before the MBT, without requiring TBP to be prebound to the promoter before injection. This effect is transient in the absence of chromatin titration and is sustained when chromatin is titrated. These data show that translational regulation of TBP RNA contributes to limitations on the transcriptional capacity before the MBT. Second, we examined the ability of trans-acting factors to contribute to promoter activity before the MBT. Deletion of cis-acting elements does not affect histone H2B transcription in egg extract, a finding indicative of limited trans-activation. Moreover, in the context of the intact promoter, neither the transcriptional activator Oct-1, nor TBP, nor TFIID enable transcriptional activation in vitro. HeLa cell extract, however, reconstitutes activated transcription in mixed extracts. These data suggest a deficiency in egg extract cofactors required for activated transcription. We show that the capacity for activated H2B transcription is gradually acquired at the early gastrula transition. This transition occurs well after the blastula stage when the basal transcription machinery can first be complemented with TBP.

The TATA binding protein in the sea urchin embryo is maternally derived

The cDNA encoding the TATA binding protein was isolated from 8- to 16-cell and morula-stage embryonic libraries of two distantly related species of sea urchin, Strongylocentrotus purpuratus and Lytechinus variegatus, respectively. The two proteins are 96% identical over both the N- and C-terminal domains, suggesting a conservation of transcriptional processes between the two species. The prevalence of SpTBP transcripts at several developmental time points was determined using the tracer excess titration method, and the corresponding number of TBP protein molecules was determined by quantitative Western blot analysis. Our results indicate that the amount of TBP mRNA and protein per embryo remains relatively constant throughout development. An initial large pool of TBP protein (>10(9)) molecules in the egg becomes diluted as a consequence of cell division and decreases to about 2 x 10(6) molecules per cell by the gastrula stage. We found by in situ RNA hybridization that the oocyte contains a large amount of TBP mRNA which is depleted late in oogenesis so that the eggs and early embryos have extremely low levels of TBP mRNA. We conclude that the oocyte manufactures nearly all of the TBP protein necessary for embryogenesis.

Upstream binding factor stabilizes Rib 1, the TATA-binding-protein-containing Xenopus laevis RNA polymerase I transcription factor, by multiple protein interactions in a DNA-independent manner

Initiation of RNA polymerase I transcription in Xenopus laevis requires Rib 1 and upstream binding factor (UBF). UBF and Rib 1 combine to form a stable transcription complex on the Xenopus ribosomal gene promoter. Here we show that Rib 1 comprises TATA-binding protein (TBP) and TBP-associated factor components. Thus, Rib 1 is the Xenopus equivalent of mammalian SL 1. In contrast to SL 1, Rib 1 is an unstable complex that readily dissociates into TBP and associated components. We identify a novel function for UBF in stabilizing Rib 1 by multiple protein interactions. This stabilization occurs in solution in a DNA-independent manner. These results may partially explain the difference in UBF requirement between Xenopus and mammalian systems.

TATA-box DNA binding activity and subunit composition for RNA polymerase III transcription factor IIIB from Xenopus laevis

The RNA polymerase III transcription initiation factor TFIIIB contains the TATA-box-binding protein (TBP) and polymerase III-specific TBP-associated factors (TAFs). Previous studies have shown that DNA oligonucleotides containing the consensus TATA-box sequence inhibit polymerase III transcription, implying that the DNA binding domain of TBP is exposed in TFIIIB. We have investigated the TATA-box DNA binding activity of Xenopus TFIIIB, using transcription inhibition assays and a gel mobility shift assay. Gel shift competition assays with mutant and nonspecific DNAs demonstrate the specificity of the TFIIIB-TATA box DNA complex. The apparent dissociation constant for this protein-DNA interaction is approximately 0.4 nM, similar to the affinity of yeast TBP for the same sequence. TFIIIB transcriptional activity and TATA-box binding activity cofractionate during a series of four ion-exchange chromatographic steps, and reconstituted transcription reactions demonstrate that the TATA-box DNA-protein complex contains TFIIIB TAF activity. Polypeptides with apparent molecular masses of 75 and 92 kDa are associated with TBP in this complex. These polypeptides were renatured after elution from sodium dodecyl sulfate-gels and tested individually and in combination for TFIIIB TAF activity. Recombinant TBP along with protein fractions containing the 75- and 92-kDa polypeptides were sufficient to reconstitute TFIIIB transcriptional activity and DNA binding activity, suggesting that Xenopus TFIIIB is composed of TBP along with these polypeptides.

Phosphorylation of the N-terminal domain of Xenopus TATA-box binding protein by DNA-dependent protein kinase depends on the C-terminal core domain

DNA-dependent protein kinase (DNA-PK) has been shown to phosphorylate several transcription factors in vitro, suggesting that this nuclear enzyme - in addition to its role in DNA repair and recombination - may be involved in transcriptional regulation. In the typical mechanism the DNA-bound kinase phosphorylates a substrate that is bound to the same DNA molecule. Here I report that the Xenopus TATA-box binding protein (xTBP) is hyperphosphorylated by DNA-PK in vitro. The phosphorylation is in the N-terminal domain of the protein but depends fully on the presence of the C-terminal core domain.

The sequence of a Xenopus laevis TFIID subunit reveals remarkable conservation among vertebrates

A cDNA clone encoding a Xenopus laevis (Xl) homologue of human transcription factor IID (TFIID) subunit p80 was isolated and sequenced. The deduced 618-amino-acid (aa) sequence was compared to the homologous from human, mouse, rat and Drosophila melanogaster (Dm). A highly conserved region exists in the central region among these species. In contrast, the C-terminal region has significant homology among vertebrates, whereas the corresponding region of the Dm homologue shows poor homology.

Structures of genes encoding TATA box-binding proteins from Trimeresurus gramineus and T. flavoviridis snakes

A cDNA encoding the Trimeresurus gramineus (Tg; green habu snake) TATA-box-binding protein (TgTBP) was cloned and sequenced. The cDNA encodes a 33-kDa protein with an extensive sequence similarity to those derived from other organisms, except for the N-terminal domain. Genes encoding TgTBP and Trimeresurus flavoviridis (Tf; habu snake) TBP (TfTBP) were isolated using a TgTBP cDNA and their nt sequences were determined. They are the first TBP genes entirely sequenced in higher animals. Both genes span over 15 kb and are constructed from eight exons and seven introns. Comparison of the loci of introns on the aligned amino-acid sequences of TBP from six organisms (Tg, Tf, mouse, Arabidopsis thaliana, Schizosaccharomyces pombe and Acanthamoeba castellanii) indicated that there are three highly conserved loci in the C-terminal domain.

Functional interaction of yeast and human TATA-binding proteins with an archaeal RNA polymerase and promoter

TATA boxes are common structural features of eucaryal class II and archaeal promoters. In addition, a gene encoding a polypeptide with sequence similarity to eucaryal TATA-binding protein (TBP) has recently been detected in Archaea, but its relationship to the archaeal transcription factors A (aTFA) and B (aTFB) was unclear. Here, we demonstrate that yeast and human TBP can substitute for aTFB in a Methanococcus-derived archaeal cell-free transcription system. Template-commitment studies show that eucaryal TBP is stably sequestered at the archaeal promoter and that this interaction is further stabilized in combination with aTFA. Binding studies revealed that recognition of an archaeal promoter by TBP involves specific binding to the TATA box. These findings demonstrate a common function of TBP and aTFB and imply a common evolutionary origin of eucaryal and archaeal transcriptional machinery.

Characterization of the Spodoptera frugiperda TATA-binding protein: nucleotide sequence and response to baculovirus infection

A cDNA clone containing a 921 bp open-reading frame (307 amino acids; 34 kDa) homologous to the TATA-binding protein (TBP) was isolated and sequenced from a Spodoptera frugiperda cell line that is commonly used in the baculovirus expression system. Analysis of the S. frugiperda TBP (SfTBP) sequence showed that the amino-terminal portion of SfTBP diverged significantly from that of other TBP sequences including Drosophila melanogaster whereas the carboxy-terminal sequence was highly conserved. Southern blot analysis indicated that SfTBP was encoded by a single gene in the S. frugiperda genome. Northern blot analysis indicated that steady-state levels of the 1.3 kb SfTBP transcript declined by 24 h post-infection corresponding to the time of virus-induced inhibition of host-cell transcription. Corresponding western blot analysis showed that TBP protein levels remain constant up to 72 h post-infection.

Codon reiteration and the evolution of proteins

Sequence data banks have been searched for proteins possessing uninterrupted reiterations of any amino acid. Hydrophilic amino acids, and particularly glutamine, account for a large proportion of the longer reiterants. In the genes for these proteins, the most common reiterants are those that contain poly(CAG), even out-of-frame or, to a lesser degree, those that contain repeated doublets of CA, AG, or GC. The preferential generation of such reiterants requires that DNA strand-specific signals predispose to reiteration and thus to the extension of coding regions.

Mitotic repression of RNA polymerase III transcription in vitro mediated by phosphorylation of a TFIIIB component

Interphase cytosol extracts prepared from Xenopus laevis eggs are active in RNA polymerase III (Pol III) transcription. Addition of recombinant B1 cyclin to these extracts activates mitotic protein kinases that repress transcription. Affinity-purified p34cdc2-cyclin B kinase (mitosis-promoting factor) is sufficient to effect this repression in a simplified Pol III transcription system. This mitotic repression involves the direct phosphorylation of a component of the Pol III transcription initiation factor TFIIIB, which consists of the TATA box-binding protein (TBP) and associated Pol III-specific factors. The transcriptional activity of the TFIIIB-TBP fraction can be modulated in vitro by phosphorylation with mitotic kinases and by dephosphorylation with immobilized alkaline phosphatase.

Evolution of sequence repetition and gene duplications in the TATA-binding protein TBP (TFIID)

Analysis of TBP gene sequences from a variety of species for clustering of short sequence motifs and for over- and underrepresentation of short sequence motifs suggests involvement of slippage in the recent evolution of the TBP N-terminal domains in metazoans, Acanthamoeba and wheat. AGC, GCA and CAG are overrepresented in TBP genes of other species, suggesting that opa arrays were amplified from motifs overrepresented in ancestral species. The phylogenetic distribution of recently slippage-derived sequences in TBP is similar to that observed in the large subunit ribosomal RNAs, suggesting a propensity for certain evolutionary lineages to incorporate slippage-generated motifs into protein-coding as well as ribosomal RNA genes. Because length increase appears to have taken place independently in lineages leading to vertebrates, insects and nematodes, TBP N-terminal domains in these lineages are not homologous. All gene duplications in the TBP gene family appear to have been recent events despite strong protein sequence similarity between TRF and P. falciparum TBP. The enlargement of the TBP N-terminal domain may have coincided with acquisition of new functions and may have accompanied molecular coevolution with domains of other proteins, resulting in the acquisition of new or more complex mechanisms of transcription regulation.

Unusual charge configurations in transcription factors of the basic RNA polymerase II initiation complex

A systematic analysis of the primary sequences of the polymerase II initiation complex has revealed unusual charge features in the TFII family proteins. In particular, the proteins TFIIA alpha, TFIIE alpha, and TFIIF carry multiple charge clusters and hyper charge runs, sequence features occurring in < 4% of all (available) eukaryotic proteins. Possible implications for these charge structures are discussed in relation to the assembly and function of the polymerase II transcriptional complex.