Critical Role of the Second Stirrup Region of the TATA-binding Protein for Transcriptional Activation Both in Yeast and Human*

(Received for publication, August 22, 1996, and in revised form, January 3, 1997)

Tae Kook Kim Dagger and Robert G. Roeder §

From the Laboratory of Biochemistry and Molecular Biology, The Rockefeller University, New York, New York 10021

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

We previously identified three TATA-binding protein (TBP) point mutations (L114K, L189K, and K211L) that have severe effects on transcriptional activation by acidic activators, but no effect on basal transcription, in a yeast-derived TBP-dependent in vitro transcription system (Kim, T. K., Hashimoto, S., Kelleher, R. J., III, Flanagan, P. M., Kornberg, R. D., Horikoshi, M., and Roeder, R. G. (1994) Nature 369, 252-255). These activation defects were also demonstrated in vivo in yeast cells (Lee, M., and Struhl, K. (1995) Mol. Cell. Biol. 15, 5461-5469). Here, the transcriptional activities of these and other TBP mutations were examined in human by both in vitro and in vivo assays. Mutations L189K and E188K, which lie in the second stirrup region of TBP, show defective activation by acidic activators both in yeast and human. Somewhat surprisingly, mutations L114K and K211L have almost no demonstrable effect on activation by acidic activators in human, in contrast to their severe effects on defective activator responses in yeast. The implications of these results for TBP structure and function are discussed.


INTRODUCTION

TBP1 has been proposed to be the direct or indirect target of several upstream activators in addition to playing a crucial role in basal transcription (reviewed in Refs. 1 and 2). Amino acid sequence comparisons of TBP species from yeast to human have revealed a highly conserved carboxyl-terminal domain of 180 amino acids and a variable amino-terminal domain (reviewed in Ref. 3). The conserved carboxyl-terminal core is known to be sufficient for binding to the TATA box and for basal transcription in vitro (reviewed in Refs. 1-3). Despite striking structural and functional similarities among eukaryotic TBPs, yeast cells are not viable when yeast TBP (yTBP) is replaced with human TBP (hTBP) (4-6). One possibility is that TBP might be involved in species-specific interactions with other transcription factors. However, several other studies showed that yTBP can support both basal and activated transcription by acidic activators in a human in vitro system and that hTBP can mediate responses to acidic activators in yeast cells (7, 8). This interchangeability of yeast and human TBPs argues against species-specific interactions, at least for the response to acidic activators.

Despite this functional interchangeability, hTBP is less active for the response to acidic activators than yTBP in yeast based on levels of reporter gene expression both in vivo and in vitro (7, 8). yTBP and hTBP also differ in another respect. The hTBP is found in a very stable complex (TFIID) containing both TBP and TBP-associated factors (TAFs) with coactivator functions (reviewed in Refs. 1, 2, and 9). In contrast, although yeast contains homologous TAFs that can be isolated in association with yTBP (10, 11), the interactions are apparently much weaker than those reported for the human and Drosophila counterparts. Moreover, although TAFs appear to be obligate coactivators for the in vitro function of activators in human and Drosophila systems (Refs. 12 and 13; reviewed in Refs. 1, 2, and 9), recent studies of yeast TAFs suggest that they are not generally required for the several activators tested (14, 15). In this case activation may be more dependent upon other coactivators, such as components of the holoenzyme mediator complex (reviewed in Ref. 16) or the ADA complex (reviewed in Ref. 17). General coactivators other than TAFs have also been reported in the human system, although they are jointly required with human TAFs for activation (18-20). Given apparent differences in requirements for coactivators (especially TAFs) in yeast and human, one might expect variations in activation mechanisms and in the importance of the well documented interactions of activators with general factors such as TBP (reviewed in Ref. 21) and TFIIB (22).

We previously used a series of point mutants in the conserved carboxyl-terminal core of yeast TBP to define residues important specifically for GAL4-VP16-dependent transcription (23). Mutants L114K, L189K, and K211L were found be defective for the response to GAL4-VP16, but nonetheless showed normal basal transcription by RNA polymerase II. A more detailed analysis revealed that activator-induced TFIIB recruitment to (or stabilization within) the preinitiation complex is disrupted by TBP mutations that impair its interaction with VP16 (L114K), TFIIB (L189K), or the TATA element (L114K and K211L). Focusing on these mutations, the objective of the present study was to identify TBP interactions important for transcriptional activation by acidic activators in human as well as yeast, and possible differences in the two systems. In contrast to the behavior of mutants L114K, L189K, and K211L in yeast, where all are severely defective for activator function, two (L114K and K211L) mediated normal activation responses and another (L189K) showed only a modest defect in human systems.


EXPERIMENTAL PROCEDURES

In Vitro Transcription Reactions

Transcription factors TFIIA, TFIIE/F/H, and USA were fractionated from HeLa nuclear extracts by phosphocellulose (P-11) chromatography (24) and further purified as described (19). RNA polymerase II was purified from HeLa nuclear pellet extracts by chromatography through heparin-Sepharose, DEAE-cellulose, and Mono Q columns (25). Flag-tagged TFIID was purified by affinity chromatography (18) and was heat-treated for 5-10 min to inactivate endogenous TBP activity at 47 °C as described (26). Recombinant TFIIB and TBPs were expressed as hexahistidine fusion proteins from the T7 polymerase plasmid pET11d in Escherichia coli strain BL21(DE3)pLysS and were purified by nickel affinity chromatography (27, 28). GAL4-VP16 was expressed in E. coli and purified as described before (23). In vitro reconstituted transcription was performed and analyzed as described before (19, 23, 30, 31).

In Vivo Altered-specificity TBP Assay

HeLa cells were transfected with a c-fos reporter plasmid, TBP and GAL4-VP16 expression plasmids, and an alpha -globin internal reference plasmid (32). After 48 h, RNase protection analysis was performed to quantitate accurately initiated transcription. Site-directed mutagenesis was used (33) to introduce the triple amino acid altered-specificity substitutions (8) into TBP, as well as specific substitutions at the Leu-114, Glu-188, Leu-189, or Lys-211 residues (23).


RESULTS

The previously analyzed TBP mutations, which selectively abolish VP16-activated transcription in yeast (23), occur at residues that are conserved in yTBP and hTBP and located in the conserved carboxyl-terminal domain (Fig. 1A). The corresponding mutant (L114K, L189K, and K211L) and wild-type yTBPs were expressed as hexahistidine fusion proteins in E. coli. The expressed TBPs were purified by nickel affinity chromatography (Fig. 1B) and then employed in various in vitro transcription assays.


Fig. 1. Activation-defective yeast TBP point mutants used in this study. A, comparison of the structure of yTBP and hTBP. The open boxed region indicates the carboxyl-terminal domain that is strongly conserved among all eukaryotes (reviewed in Ref. 3). Arrows represent almost perfect symmetric direct repeats present in the carboxyl-terminal domain (34). The location of mutations used in the study are indicated with numbers in yTBP and hTBP. B, SDS-polyacrylamide gel electrophoresis analysis of the purified yTBP mutant proteins used in transcription assays. Wild-type or mutant yeast TBPs were purified and indicated above each lane of the SDS-polyacrylamide gel.
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To determine the transcription activities of TBP mutants in human, we utilized an in vitro transcription system that was reconstituted with HeLa cell-derived general factors (TFIIA, TFIIB, TFIIE/F/H, RNA polymerase II, and TBP), the USA cofactor fraction, and a heat-treated TFIID (Fig. 2). Heat treatment of TFIID selectively inactivates TBP, leaving a TAF population that, with ectopic TBP, can mediate activator function (albeit at a level lower than that observed with intact TFIID) (26).2 The template used for this analysis contains five GAL4 binding sites preceding the HIV TATA element fused to a G-less cassette (Fig. 2A). As shown in Fig. 2B, in the absence of recombinant TBP, no specific transcription could be detected with general factors and heat-treated TFIID either alone (lane 1) or in combination with either the acidic activator GAL4-VP16 or the USA fraction (lanes 2 and 3). A low level of transcription was detected when both GAL4-VP16 and USA were present (lane 4), probably due to a trace amount of TBP contamination in the transcription system (19). In the presence of recombinant wild-type TBP, general factors, and heat-treated TFIID, a low level of basal transcription was observed (lane 5). This basal transcription was unaffected by the sole addition of GAL4-VP16 (lane 6) or USA (lane 7), but both together gave a significant activation (lane 8). This marked activation by GAL4-VP16 was not observed in the absence of a heat-treated (and near homogeneous) TFIID preparation,2 which presumably supplies essential TAFs that can reassociate with TBP. These results indicate that transcription in this human in vitro reconstituted assay system is dependent upon exogenous TBP.


Fig. 2. Human TBP-dependent in vitro transcription system. A, the chimeric GAL4-VP16 activator protein contains the amino-terminal 94 amino acids of GAL4 (with the DNA binding domain) fused to the carboxyl-terminal 78 amino acids of VP16. The template DNA (pG5HMC2AT) for in vitro transcription contains a TATA box from the HIV promoter with five GAL4 DNA binding sites. B, in vitro transcription was reconstituted with recombinant or partially purified general factors and heat-treated TFIID in the presence (+) or absence (-) of GAL4-VP16 or USA fraction as described under "Experimental Procedures" (19).
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Using the TBP-dependent human in vitro system described above, we analyzed the response of activation-defective TBP mutants (23) to acidic activators (Fig. 3). Fig. 3A shows an analysis of transcription with different concentrations of TBP in this reconstituted transcription system. Additionally, we analyzed the response of TBP mutants (23) to GAL4-VP16 using non-saturating levels of TBPs (Fig. 3B). While comparable to wild-type TBP with respect to basal activity, the L189K mutant was defective for activation (lanes 5 and 6 versus lanes 1 and 2). This is consistent with the effect of the L189K mutation in yeast, although the defect was much less severe in the human system as compared with the yeast system. Somewhat surprisingly, mutants L114K and K211L, which were also severely defective for activated (but not basal) transcription in yeast (23), supported activated transcription by GAL4-VP16 as efficiently as did wild-type TBP. These contrasting activities of TBP mutants in the yeast versus the human system, including the moderately defective activation response with L189K in the human system, were also observed with different acidic activators (e.g. GAL4-AH).2


Fig. 3. Response of TBP mutants to GAL4-VP16 in the human in vitro transcription system. Transcription in the human reconstituted system was performed with the pG5HMC2AT template as described in Fig. 2. A, relative amounts of TBP assayed for titration of basal transcription were in multiples of 7.5 ng. B, the presence (+) or absence (-) of GAL4-VP16 and specific mutant or wild-type (WT) TBPs (10-15 ng) are indicated above each lane. Numbers below the lanes represent the activation (n-fold) in the presence of GAL4-VP16.
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The contrasting activities of TBP mutants in the yeast versus the human system might be due to the different promoters used in the respective assays. The HIV promoter was used in the human system, whereas CYC1 was used in the previous yeast transcription assay (23). To rule out this possibility, we determined the transcription activities of three TBP mutants in the yeast in vitro system with templates containing the HIV human promoter (Fig. 4). In this case, all the mutants (L114K, L189K, and 211L) were shown to be severely defective for GAL4-VP16 activation. These results indicate that the differences in the ability of mutant TBPs to mediate activation in yeast versus human systems are not due to the different promoters used to perform the assays and suggest, along with the data in Fig. 3, that certain interactions might be different for the function of acidic activators in yeast and human. The contrasting responses by TBP mutants appear to be specific for activated transcription, since all of the 34 original mutant TBPs tested (see Ref. 23) showed either undetectable activities or basal activities comparable to those displayed by wild-type TBP in both human (Table I) and yeast (23) transcription systems.


Fig. 4. Response of TBP mutants to GAL4-VP16 in the yeast in vitro transcription system with the human promoter. Reactions reconstituted with yeast transcription factors as described before (23) were incubated with pG5HMC2AT (human HIV promoter containing five GAL4 binding sites) templates in the presence (+) or absence (-) of GAL4-VP16 or TBP.
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Table I.

Transcription properties of TBP mutants in yeast and human

A series of TBP point mutants containing leucine (L) to lysine (K) or lysine to leucine changes and wild-type (WT) TBP were analyzed for basal and acidic activator-dependent transcriptions in the TBP-dependent yeast (Ref. 23) and human in vitro transcription systems.
TBP Yeast
Human
Basal Activated Basal Activated

L67K  -  -  -  -
L76K  -  -  -  -
L80K  -  -  -  -
L82K  -  -  -  -
K83L +++ +++ +++ +++
L87K +++ +++ +++ +++
K97L +++ +++ +++ +++
K110L +++ +++ +++ +++
L114K +++ +/- +++ +++
K120L +++ +++ +++ +++
K127L +++ +++ +++ +++
K133L +++ +++ +++ +++
L134K +++ +++ +++ +++
K138L +++ +++ +++ +++
K145L +++ +++ +++ +++
K151L +++ +++ +++ +++
K156L +++ +++ +++ +++
K167L +++ +++ +++ +++
L172K  -  -  -  -
L175K  -  -  -  -
L189K +++ +/- +++ +
L193K  -  -  -  -
K199L +++ +++ +++ +++
K201L +++ +++ +++ +++
L204K  -  -  -  -
L205K  -  -  -  -
K211L +++ +/- +++ +++
L214K  -  -  -  -
K218L +++ +++ +++ +++
L234K  -  -  -  -
L239K +++ +++ +++ +++
WT +++ +++ +++ +++

To further examine the contrasting responses with TBP, wild-type yTBP and hTBP were compared for their ability to support activated transcription in the TBP-dependent human and yeast in vitro systems. Wild-type yTBP was indistinguishable from wild-type hTBP in support of activation by GAL4-VP16 in the human in vitro system (Fig. 5B). In contrast, wild-type hTBP supported the response to acidic activators much less efficiently than wild-type yTBP in the yeast transcription system (Fig. 5A). This is consistent with the defective response of TBP mutants only in yeast (see Figs. 3 and 4). Apparently, the human transcription system is less sensitive to changes in the structure of TBP than is the yeast transcription system.


Fig. 5. Comparison of responses to GAL4-VP16 by wild-type yTBP versus hTBP in the yeast and the human in vitro transcription systems. Wild-type yTBP and hTBP were tested for the ability to support activated transcription by GAL4-VP16 in the TBP-dependent yeast (A) and human (B) transcription systems (3, 7). GAL4-VP16 was added in increasing amount to transcription reactions. Relative amounts of GAL4-VP16 assayed are given in multiples of 30 ng. Radioactivity incorporated into specific transcripts is expressed as relative transcription and plotted as a function of the GAL4-VP16 concentration.
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Next we assessed the in vivo significance of the in vitro results described above by using an altered-specificity TBP in transfection assays (32). Various point mutations (L114K, L189K, and K211L) were introduced into a TBP derivative that can recognize an altered TATA box (T<UNL>G</UNL>TAAA) in a c-fos promoter containing four GAL4 DNA binding sites (Fig. 6A). Individual TBP and GAL4-VP16 activator proteins were coexpressed by transfection with c-fos reporter constructs in human (HeLa) cells. Transcription from the c-fos reporter was measured by RNase protection analysis with normalization to transcription from an alpha -globin internal control plasmid (Fig. 6B). Expression of each TBP mutant was determined by immunoblot analyses from transfected cells, and the amounts of the TBP expression plasmids used for transfection were adjusted to give the same level of expression for each.2 Under these conditions, and consistent with the in vitro results, mutants L114K and K211L supported transcriptional activation by GAL4-VP16 as well as did wild-type TBP (Fig. 6B). In contrast the mutation L189K significantly (over 2-fold) reduced the ability of TBP to respond to GAL4-VP16 in human cells (lane 2). These results support the conclusion that TBP shows contrasting activation responses in yeast and human and that the Leu-189 region plays an important role in transcriptional activation.


Fig. 6. Response of TBP mutants to GAL4-VP16 in vivo in human cells. A, the chimeric GAL4-VP16 activator protein contains the amino-terminal 94 amino acids of GAL4 (with the DNA binding domain) fused to the carboxyl-terminal 78 amino acids of VP16. The template DNA for in vivo transcription contains an altered T<UNL>G</UNL>TAAA box from the c-fos promoter with four GAL4 DNA binding sites. B, RNase protection analysis was performed with RNA isolated from HeLa cells transiently transfected with the c-fos T<UNL>G</UNL>TAAA reporter, GAL4-VP16 expression construct and expression constructs for wild-type (WT) or specific TBP mutants (23) as indicated (32). All the TBPs carried the altered-specificity substitutions as described before (8). Accurately initiated c-fos transcripts, normalized to the alpha -globin signal, are shown.
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In the three-dimensional TBP structure (34, 35), the L189K mutation maps within the second stirrup region that connects strands S2' and S3' (Fig. 8). To further assess the important role of this region in transcriptional activation in the human system, we tested a mutation (E188K) in an adjacent residue (Glu-188) whose side chain points in the same general direction as the Leu-189 residue. In both the in vivo and in vitro assay systems described above, mutant E188K showed a defective response to GAL4-VP16 that was considerably greater than that observed for L189K (Fig. 7). In conjunction with the less dramatic but highly reproducible effect of the L189K mutant, this compromised activation response by E188K indicates that the second stirrup region of TBP is critical for transcriptional activation by acidic activators in the human system.


Fig. 8. Schematic drawing of the second-stirrup region of TBP, which is critical for transcriptional activation in yeast and human. The alpha -carbon backbone is shown as a solid white line. Also shown are the side chains of several residues (Glu-186, Pro-187, Glu-188, Leu-189, Phe-190, and Pro-191) located in the second stirrup-like loop region spanning S2' and S3' (34, 35). Two mutations (E188K and L189K) were shown to be defective in transcriptional activation by acidic activators (present study; see also Ref. 23).
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Fig. 7. Defective activation by the E188K mutation, which is located in the second stirrup region of TBP. In vivo (A) and in vitro (B) human transcription assays were performed as described in Figs. 6 and 2, respectively. The E188K mutant had 30-50% the activity of wild-type TBP for basal transcription in vitro (see Footnote 2). Activated transcription was compared by normalizing the basal level of transcription. B, numbers below the lanes represent the activation (n-fold) in the presence of GAL4-VP16.
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DISCUSSION

Here we describe TBP mutants that are defective in transcriptional activation in both yeast and human systems. These mutations (L189K and E188K) map within the second stirrup region of TBP connecting strands S2' and S3' in the three-dimensional TBP structure (34, 35) (see Fig. 8). Importantly, the co-crystal structure of the TBP·TFIIB·DNA ternary complex shows that these mutations are located in the TBP·TFIIB interface where the basic surface of TFIIB interacts with the acidic second stirrup region of TBP and the negatively charged phosphodiester backbone of DNA (35). Consistent with this, the L189K mutation was previously demonstrated to be defective both in TFIIB interactions and in activator-induced TFIIB recruitment (23, 28, 36). Based on these results, it was proposed that activators may induce qualitative or quantitative alterations in TFIIB binding to TBP (or TFIID)·promoter complexes through interactions with either TFIID or TFIIB, or possibly through simultaneous interactions with both (22, 23, 28, 36). The activator could either stabilize, or effect the de novo assembly of, an activation-specific TBP(TFIID)·TFIIB·promoter complex (e.g. one with a specific conformation), thereby enhancing the ability of TBP(TFIID)·TFIIB·promoter complexes to interact with downstream general factors (TFIIE, -F, and -H and RNA polymerase II) in preinitiation complex assembly (see Refs. 23 and 36 for detailed discussions). Thus, these activation-defective TBP mutants should be very helpful in gaining further insights into dynamic structural changes in promoter complexes during preinitiation complex assembly and function, and especially the activation-specific TBP(TFIID)·TFIIB·promoter complex.

While TBP mutants L189K and E188K are defective in activation both in yeast and human, somewhat surprisingly, mutants L114K and K211L, which do not mediate normal activation in yeast (23), support activated transcription by acidic activators as efficiently as wild-type TBP. These contrasting activities of TBP mutants for activator function in the yeast versus the human system are also observed with some other TBP mutants (37, 38), including a K138T/Y139A mutant (29) that cannot interact with TFIIA. These mutants can support transcriptional activation in human but are severely defective for activation responses in yeast.3 Interestingly, all the TBP mutants (23, 37, 38) showing contrasting activation responses have been proposed to affect TBP-TATA element interactions. Since TFIIA can stabilize the interaction of TBP on the TATA element, the K138T/Y139A mutation (29) could also affect the formation of an activation-specific TBP·promoter complex. Thus, one implication from these TBP mutational analyses is that the TBP-TATA element interaction (23, 29, 37, 38) is relatively less important for transcriptional activation in human, compared with the direct interaction of TFIIB with TBP through the second stirrup region.

Based on the contrasting activities of TBP mutants for activation in yeast versus human systems, there may be activation-specific TBP interactions, which are not conserved from yeast to human or which are not essential in the human systems analyzed (e.g. because of redundant or alternative activation mechanisms). It is known that transcriptional stimulation by activators in yeast and human is dependent upon coactivators distinct from the minimal basal factors (reviewed in Refs. 1-3, 16, 17, and 39). In human, both TBP-associated TAFs (reviewed in Refs. 1 and 9) and USA-derived components (18-20) are obligatory for activation in vitro; these components, as well as basal factors that include TFIIB (22), have been identified as direct targets for activators, reflecting increased recruitment of TFIID, TFIIB, and other general initiation factors. Studies in yeast have identified TBP-interacting TAFs, which can facilitate activation function in vitro (10, 11), as well as a complex of other coactivators (SRBs and other genetically defined coactivators) that form part of a holoenzyme complex with RNA polymerase II (reviewed in Refs. 16, 17, and 39). Importantly, both in vitro (40, 41) and in vivo (14, 15) studies have shown that the yeast TAFs may not be generally required for activation in yeast, in sharp contrast to their critical role in human systems. Possibly related, the TBP-TAF interactions in yeast appear much weaker than those reported for human TFIID. Mechanistic studies in yeast have shown that activators can interact directly with coactivators to effect holoenzyme recruitment (42; reviewed in Ref. 16) and that TBP recruitment, potentially by direct activator interactions, can also be limiting for activation in yeast (reviewed in Ref. 39). Given that activation through multiply bound activators most likely involves interactions with several of many potential targets in the general transcription machinery (43, 44), the variable effects of TBP mutants L114K and K211L in yeast versus human may simply reflect differential utilization of various activator-coactivator-basal factor interactions and, especially, variations in requirements for the well documented interactions of activators with TBP in yeast and human (reviewed in Ref. 21).


FOOTNOTES

*   This study was supported by grants from the National Institute of Health (to R. G. R.) and the Human Frontiers Science Program (to R. G. R.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    Present address: Dept. of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138.
§   To whom correspondence should be addressed. Tel.: 212-327-7601; Fax: 212-327-7949.
1   The abbreviations used are: TBP, TATA-binding protein; yTBP, yeast TBP; hTBP, human TBP; TAF, TBP-associated factor; TF, transcription factor; HIV, human immunodeficiency.
2   T. K. Kim and R. G. Roeder, unpublished data.
3   S. K. Mahanta and J. Strominger, personal communication.

Acknowledgments

We thank W. Tansey and W. Herr for the altered-specificity TBP constructs, and S. K. Mahanta and J. Strominger for sharing unpublished data.


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