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A complex that contains proteins binding to the PSE and TATA sites in a human U6 small nuclear RNA promoter
Gene, 148(1994)269-215 0 1994 Elsevier Science B.V. All rights reserved.
269
0378-l 119/94/$07.00
GENE 08212
A complex that contains proteins binding to the PSE and TATA sites in a human U6 small nuclear RNA promoter (Eukaryotic promoters; RNA polymerase III; snRNA gene transcription factors)
Randal S. Goomer*,
Olgui Urso and Gary R. Kunkel
Department of Biochemistry and Biophysics, Texas A&M University, College Station, TX 77843-2128, USA Received by J.A. Gorman:
22 November
1993; Revised/Accepted:
23 May/24
May 1994; Received at publishers:
27 June 1994
SUMMARY
The proximal promoter of a human U6 small nuclear RNA (snRNA)-encoding gene contains two separate elements, the proximal sequence element (PSE) and the TATA box. We investigated the interaction of the PSE- and TATA-binding proteins (PBP and TBP) with normal and mutant U6 proximal promoters using an electrophoretic mobility shift assay. We detected a complex containing both PBP and TBP bound to the wild-type U6 promoter. Efficient formation of the triple complex was dependent on the presence of the PSE and the TATA box on the template DNA. Mutant U6 promoters containing an increased spacing between the PSE and TATA box of 5 or 10 bp were impaired in the ability to form a complex that includes TBP. We infer from these results that PBP and TBP interact when their binding sites are properly positioned in a U6 gene promoter.
INTRODUCTION
Promoter elements in the 5’ flanking sequences of vertebrate U6 snRNA genes are very similar to those of RNA polymerase-II-transcribed genes. The proximal promoter of U6 consists of a TATA-box sequence Correspondence to: Dr. G.R. Kunkel,
Department
Biophysics,
College
Texas A&M
University,
USA. Tel. (l-409) 845-6257; Fax (l-409) e-mail: [email protected] *Present
address:
Department
of Biochemistry
Station,
and
TX 77843-2128,
845-9274;
of Neurobiology,
The Scripps
Research
Institute, 10666 N. Torrey Pines Road, La Jolla, CA 92037, USA. Tel. (1-619) 554-3634; Fax (1-619) 554-6660. Abbreviations: Ab, antibody(ies); bp, base pair(s); BSA, bovine serum albumin; de, decreased; dpm, disintegrations per min; DTT, dithiothreitol; EMSA, electrophoretic mobility-shift assay; h, human; HEPES, 4-[2-hydroxyethyll-1-piperazine-ethanesulfonic acid; in, increased; PA, polyacrylamide; PAGE, PA-gel electrophoresis; PBP, PSE-binding protein; PCR, polymerase chain reaction; P-D complex, PBP-DNA complex; P-D-T complex, PBP-DNA-TBP complex; pol, RNA polymerase; PSE, proximal sequence element; re-, recombinant; SDS, sodium dodecyl sulfate; snRNA, small nuclear RNA; TBP, TATA-binding protein; wt, wild type; y, yeast. SSDI 0378-l
119(94)00423-4
(-29TATATA-24 m . a human gene) and a PSE sequence (-66CTTACCGTAACTTGAAAGTA-47 in a human gene). The U6 TATA element is required for transcription by RNA polymerase III (pol III) and its elimination results in transcription exclusively by pol II (Mattaj et al., 1988; Lobo and Hernandez, 1989). It has been shown recently that TATA-binding re-protein (TBP) is required for U6 transcription in vitro (Margottin et al., 1991; Simmen et al., 1991; Lobo et al., 1991). Furthermore, a role for TBP in the transcription of 5s and tRNA genes by pol III and rRNA genes by pol I has been shown (White et al., 1992; Cormack and Struhl, 1992; Schultz et al., 1992; Taggart et al., 1992; Lobo et al., 1992; White and Jackson, 1992b; Kassavetis et al., 1992; Comai et al., 1992). TBP has emerged as a general transcription factor for transcription by all three RNA polymerases (Sharp, 1992; White and Jackson, 1992a; Rigby, 1993; Hernandez, 1993). The vertebrate pol-II-transcribed genes that encode the abundant spliceosomal snRNAs (UI, U2, U4 and U5), do not require the presence of a TATA box. Instead the proximal promoters of these genes contain the PSE that
270 is necessary
for
transcription
(Skuzeski
Ciliberto
et al., 1985; Mattaj
Murphy
et al., 1987). In addition,
efficient
transcription
Hernandez, groups
have identified
region and is required (PBP, PTF or SNAP,; et al., 1992; Murphy Sadowski
a PSE is required I/6 gene (Lobo
and Pederson,
a protein Waldschmidt
reduction
in transfected Goomer
of a rigid others
cells (Mattaj
spacing
et al., 1993;
et al., 1993).
changes
in transcriptional
and Kunkel,
in the PSE
et al.. 1991; Simmen
the TATA results
in a
efficiency in vitro and
have hypothesized
the two elements, that
the protein
we and
factors
that
bind the PSE and the TATA box may interact with one another, either directly or indirectly. Using a gel mobilityshift analysis, we detected a complex containing both the PBP and recombinant human TBP on the U6 promoter. DNA fragments containing spacing changes that greatly reduce transcriptional efficiency in vitro supported a reduced level of this complex. Thus we conclude that these transcription factors interact when bound to the U6 gene promoter.
RESULTS
u-TBP
Ab was added
(Fig. 2, lanes 2 4). Addition control
(a-TFIIB)
detected
to the binding of another
rabbit
complex
upon addition
Ab, even when these experiments
out with purified
Ah as ;I
had little effect (Fig. 2, lanes 5- 7). We
no discrete supershifted
of a-TBP
reaction
Ab (results
not shown).
were carried Although
this
experiment did not rule out the possibility of a distinct PBP polypeptide that shares a TBP epitope, it is likely that
the P-D complex
contains
TBP.
Furthermore.
in PSE-binding
not bind the TATA box, since no difference plex formation probes
was detected
were compared
when
protein
we does
in P-D com-
wt and
TATAmut
(Fig. 5. lanes 2 and 6).
et al., 1988; Lobo et al., 1991;
1992). Based upon the requirement between
rabbit
infer that this TBP present
between
box and the PSE in the U6 gene promoter drastic
and
U6 gene transcription
et al., 1992; Wanandi
of spacing
for
1988). Several
that binds
for efficient
et al.. 1993; Bernues
Introduction
1984:
et al.. 1985; Ares et al., 1985:
of a human
1989; Kunkel
et al.,
AND DISCUSSION
(a) Detection of a complex on the human U6 proximal promoter that contains PBP Fig. 1A depicts the labeled probes used in these experiments. Probe A contained the wt U6 sequence from -84 to + 111 that includes the U6 proximal promoter along with most of the U6 coding region. Probe B contained exclusively 5’ flanking sequences from - 148 to - 1. Where tested, each probe gave essentially identical results in the experiments reported here. A partially purified fraction of PBP from human 293 cells retarded the mobility of the wt probe A in a nondenaturing PA gel (the P-D complex; Fig. lB, lane 2). The shifted complex could be competed effectively by an unlabeled U6 plasmid containing the PSE (the wt or the TATAmut plasmids; Fig. 1A) but not a plasmid that contained a mutated PSE sequence (PSEmut) (Fig. 1B; compare lanes 3 and 4 with lane 5). It has been reported recently that a different preparation of HeLa cell PSE-binding protein, SNAP,, contained TBP (Sadowski et al., 1993). We explored whether the P-D complex could be disrupted by addition of an Ab that reacts against human TBP. Indeed, the ability to detect the P-D complex was drastically reduced when
(h) Formation of a complex containing PBP and re-TBP on the human U6 proximal promoter Inclusion
of recombinant
human
TATA-binding
pro-
tein (re-hTBP) along with PBP resulted in the formation of another complex of reduced mobility on the wt probe (the P-D-T complex; Fig. lB, lane 6). The P-D-T complex, along with the P-D complex could be competed away by the wt or the TATAmut U6 plasmids but not the PSEmut plasmid (Fig. 1B; compare lanes 7 and 8 with lane 9). The ability of PSE-containing plasmids and not the PSEmut plasmid to efficiently compete both the P-D and P-D-T complexes provides evidence that the PSE-binding activity is present in both complexes. It is curious that the PSEmut plasmid DNA did not compete the P-D-T complex whose presence depended on the addition of TBP. since this plasmid template contains an intact TATA box. Large amounts of recombinant TBP were used in these binding assays, and we calculate that the molar concentrations of TBP and Uh promoter were nearly equivalent when competitor plasmid DNA was included in the reaction. The band marked with an asterisk represents binding of nonspecific protein(s) present in the PBP preparation, since it was not competed by relatively high levels of the unlabeled specific competitor (Fig. 1B). The collection of heterogeneous bands marked with an open bracket was observed only when re-TBP was present in the reaction mixture and was not efficiently reduced by specific competitors (Fig. lB, lanes 7-9). These broad bands were observed only when TATA-containing templates were used in the presence of TBP, and their intensities were enhanced when PBP was included in the reaction also. One implication of this observation is that these bands represent TBP-DNA complexes that are facilitated to form in the presence of PBP. Yeast TATA-binding protein (re-yTBP) also formed a distinct, slower-mobility complex when incubated with the human PBP preparation and the U6 DNA probe. The PBP-DNA-re-yTBP complex had a slightly greater mobility than the PBP-DNA-re-hTBP complex (Fig. 3:
A,1S wtU6
-84
-148
probe A probe 8
l
1 PSE
TATA
P-D-T L P-D -
=
TATAmut
PSEmut *inP series
D-
spacing mutants PBP (P)
inP3 PSE
TATA
re_hmpm
-
++++++++
-
-
-
-
-
++++
123456789
inP5 s?“-=
TATA
inP1 Cl
Probe: r
A
TATA
Fig. 1. Detection of protein-DNA complexes on the human U6 promoter. (A) U6 promoter constructs used in EMSA. The TATAmut and PSEmut promoters contained clustered point mutations to disrupt the TATA box and the PSE, respectively (Kunkel and Danzeiser, 1992). The inP3, inP5 and inPl0 mutant constructs contained increased spacing between the PSE and the TATA box of 3, 5 or 10 bp, respectively (Goomer and Kunkel, 1992). (B) EMSA: The PBP fraction (2 pg protein) was incubated with a radiolabeled wt U6 probe A for 30 min and electrophoresed on a 4% PA non-denaturing gel to separate complexes. In lanes 2 to 5, PBP (2 ug) was incubated with the radiolabeled wt U6 probe in the presence of 1 ug of the specific and non-specific unlabeled competitor DNAs (approx. lO%fold molar excess). In lanes 6 to 9, PBP (2 ug) and re-hTBP (0.08 ug) were incubated with radiolabeled wt U6 probe in the presence of 1 ug (approx. lOO-fold molar excess) of the same competitor DNAs. The asterisk marks a non-specific complex. The open bracket identifies a series of bands present in reactions containing re-hTBP. Methods: The radiolabeied U6 promoter probes used in this study were generated by PCR. For probe A, the ‘U6’ primer (5’-TATGGAACGCTTCAC) was end-labeled and paired with the ‘Rsa’ primer (S-ACAAAATACGTGACGTAGAA). This probe was truncated by digestion at position - 84 with Draf. For probe B, the ‘Rsa’ primer was end-labeled and paired with the ‘cU6-1’ primer (T-GGTGTTTCGTCCTTTCCACA). Probes were purified by gel electrophoresis and dissolved in 10 mM Tris/l mM EDTA (pH 7.5) to give 20000 dpm/ul (approx. spec. act. 5 x lo6 dpm/pmol). PBP was purified from 20 litres 293 cells (a human embryonic kidney cell line) grown in suspension in Joklik’s minimum essential medium containing 5% calf serum and 1% newborn calf serum. SlOO extract (approx. 14-17 mg/ml; Goomer and Kunkel, 1992) was loaded onto a phosphocellulose (Whatman Pll) column (10 mg protein per ml of resin) equilibrated with buffer D (20 mM HEPES pH 7.9/20% glycerol/O.2 mM EDTA/O.S mM DTT/O.I M KCl). The transcriptionally active fractions (present in the 0.1 to 0.6 M KC1 eluate at approx. 2.5 mg/ml protein concentration) were dialyzed against buffer B (50 mM TrisHCl pH 7.9/0.1 mM EDTA,/2 mM DTT) containing 50 mM (NH&SO, and loaded onto a DEAE-Sephadex column equilibrated with the same buffer ( 1mg protein/ml of resin). PBP activity eluted with buffer B containing 0.15 M (NH4)$04 and was dialyzed against buffer D. P&E-binding activity was monitored by EMSA as described below. This sample (approx. 10 mg protein) was loaded onto a heparin-agarose column ( 10 ml resin) equilibrated with buffer D. Fractions containing the PSE-binding activity were step-eluted between 0.2 M and 0.35 M KC1 and dialyzed against buffer D. The heparin eluate (approx. 0.5 mg/mI protein) was loaded onto a 100 ml Sephacryl-HR2~ (Pha~acia) column equilibrated with buffer D. All of the FSE-binding activity was present in fractions that eluted immediately after the void volume (approx. 0.2 mg/ml protein). Fractions were pooled and quick frozen in liquid nitrogen and stored at -80°C. Purified re-hTBP was the gift of the D.D. Peterson laboratory (Department of Biochemistry and Biophysics, Texas A&M University). The cDNA for hTBP (Peterson et al., 1990) was subcloned into the pET3c vector. The purity of the hTBP preparation was estimated to be approx. 50-60%, as determined by SDS-PAGE. The protein was stored in TMO.1 buffer (50 mM TrisHCl pH 7.9/i mM EDTA/12.5 mM MgCI,/l mM DTT/ZO% glycerol/100 mM KCl) at -80°C in individual-use aliquots. Binding reactions for gel mobility shift assays contained about 4 fmol of radiolabeled probe A (20000 dpm)/lO ul of Buffer A (25 mM HEPES pH 7.9/5 mM MgC1,/0.5 mM EDTA/SO mM KCl/0.5 mM DTTjtOX glycerol/O.5 ug BSA)/SOOng poly [d(G-C)]/l ug of nonspecific or specific competitor plasmid DNA and the indicated proteins in a 25 ul total reaction volume. The reactions were incubated for 30 min at 30°C and electrophoresed on a 4% polyacrylamide gel for 2.5 h at 200 V (constant voltage) in TGEM (25 mM TrisCl pH 8.3/0.19 M glycine/l mM EDTA/2 mM MgCl,) with 10% glycerol and 0.1% NP40 (Nonidet P-40). Gel electrophoresis was performed in 0.5 x TGEM buffer. Dried gels were autoradiographed with an intensifying screen.
compare lanes 6-8 and 10-12). This difference in the mobility of the P-D-T complex due to the addition of re-yTBP versus re-hTBP is consistent with the smaller mass of yTBP (27 kDa) versus hTBP (38 kDa) (Hahn et al., 1989; Peterson et al., 1990; Kao et al., 1990). We tested the dependence of the P-D-T complex on the presence of the TATA box in the human U6 promoter.
A much reduced ratio of the amount of complex with the mobility of P-D-T relative to P-D was formed on a radiolabeled TATAmut probe (Fig. 4, lanes 7-10; also see Fig. 5, lane II). When a very high amount of re-hTBP was present in the binding reaction (approx. 0.34 ug; Fig. 4, lane lo), we observed a band of reduced mobility. This slowest mobility complex could be a P-D-T com-
272
antibody:
_ P-D-T
top -
P-D !z’
c
P-D-
re-yTJ3P
*lz
-
-
-
-
+
+
+
+
-
re_n-t-np -
-
-
-
-
_
_
_
+
+
+
+
9
10
11
12
12345678 Fig. 3. EMSA of the slow mobility human
or yeast TBP is bound
are described was incubated
D-
of polyclonal
the P-D complex. bated with approx.
Ab against
hTBP
A radiolabeled wt Uh probe 2 ug PBP protein preparation
inhibits
formation
of
B (Fig. IA) was incuwith or without rabbit
Ab as designated above each lane. The sample loaded in lane I contained no Ab. Samples loaded in lanes 224 contained 0.1 ~1. 0.3 1.11and 1 ~1, respectively. of rabbit Ab that binds to hTBP. Samples loaded in lanes 557 contained 0.1 pl, 0.3 ul and 1 ul of rabbit Ab that binds to human
TFIIB,
for EMSA
used as a control
were as described
for this experiment.
in the legend
Conditions
to Fig. I. except
the position
used
that the
samples contained 1 ug poly [d(G-C)]:2 mM MgClz:5 mM Bands labeled with the asterisk identify non-specific complexes. denotes
-
( P-D-T) complex is different when
to the promoter.
Conditions
in the legend to Fig. 1. A radiolabeled with an increasing amount of added
for EMSA
wt C’h probe A PBP: Lanes: 1, 5
and 9, no PBP; 2, 6 and 10, approx.
0.5 ug PBP; 3. 7 and
1.25 pg PBP: 4, 8 and
2 pg PBP.
12: approx.
-
I I: approx.
The concentration
of
re-yTBP was kept constant in lanes 558 at approx. 0.04 pg. In lanes 9 to 12 a constant amount of re-hTBP was added to each of the EMSA
1234567 Fig. 2. Addition
-
DTT. ‘Top’
of the well.
plex, implying that the PBP bound on the TATAmut promoter can tether TBP into a P-D-T complex. On the wt promoter we observed that the predominant shifted complex corresponded to P-D-T after a large amount of TBP was titrated into the binding reaction (Fig. 4, lanes l-6). Interestingly, the total amount of P-D plus P-D-T complexes was increased in the presence of higher concentrations of TBP. Possibly, TBP facilitates the binding of PBP to the promoter. Several independent indirect observations identify the P-D-T complex as containing both the TBP and PBP bound to the U6 proximal promoter. (i) The observed expected difference in the mobility of the re-yTBP and re-hTBP dependent slow mobility complexes provides evidence that TBP is present in the P-D-T complex (Fig. 3). (ii) The slow mobility complex was dependent on the TATA box sequence. The P-D-T complex was detected readily on the normal promoter, while, at the same concentration of TBP, a very low level of P-D-T
(approx. 0.08 ug re-hTBP). The D-yT band represents a complex formed solely due to the incubation of re-yTBP with DNA. A smear present in lanes containing
re-hTBP
(lanes 9912) is marked
by an open bracket.
Purified re-yTBP was provided by the D.O. Peterson laboratory (Department of Biochemistry and Biophysics, Texas A&M University) and was estimated SDS-PAGE.
complex
to bc approx.
was observed
80 90%
pure,
on the TATAmut
as determined
probe
by
(Figs. 4
and 5). (iii) Increasing the concentration of TBP in the binding reaction resulted in an increased ratio of the P-D-T to P-D complexes, implying a precursor-product relationship between PBP-DNA and PBP-DNA-TBP complexes (Fig. 4). Taken together, the above observations imply that the complex identified as P-D-T contains both PBP and TBP bound to the U6 proximal promoter. (c) Spacing mutants that result in a greatly reduced level of transcription in vitro are also deficient in the ability to support formation of a complex containing both PBP and TBP In a previous study we had either increased (inP constructs) or decreased (deP constructs) the spacing between the PSE and TATA box by 1, 2, 3, 5 or 10 bp. Mutant promoters containing an increased spacing (of 5 or more bp) between the PSE and the TATA box supported a greatly reduced level of U6 specific transcription in vitro (Goomer and Kunkel, 1992). In order to investigate the stable binding of transcription factors on these mutant U6 proximal promoters, we prepared radiolabeled DNA fragments from these spacing change constructs (Fig. 1A). The specific radioactivity of each probe
213
Probes: P-D-T L P-D -
P-D-T L P-D -
c
c
**-
DPBP (P) l-BP(T)
-
+++++
++++
1
-++++ 23456
++++ 78910
I
I
I
TATAmut
wt promoter
Probe:
Fig. 4. Efficient detection dependent TATAmut
D-
of the slowest
mobility
complex
(P-D-T)
is
on the presence of a TATA box in the U6 probe. The wt or probes were incubated with a constant amount of PBP and
an increasing concentration of re-hTBP, EMSA was as described in the legend to Fig. 1. The experiments using the wt probe (lanes l-6) and TATAmut
probe
(lanes
7710) were carried
out at different
times. In
lanes 2 to 10 a constant amount of PBP (2 ug protein) was incubated with the probe. Lanes 3 and 7 contained 40 ng re-hTBP, lanes 4 and 8 contained 80 ng re-hTBP; lanes 5 and 9 contained 0.17 ug re-hTBP; and lanes 6 and 10 contained 0.34 ug re-hTBP. The band marked by the asterisk only
indentifies
in the wt probe
denoted
a non-specific reactions
complex.
containing
A diffuse band re-hTBP
(lanes
present 3-6)
is
by an open bracket.
was identical, since the same kinased oligodeoxynucleotide was used for each preparation. Fig. 5 shows the binding of PBP or PBP and TBP to these probes. A stable P-D complex was formed on all constructs tested, i.e., the wt, inP3, inP5, inPl0 or TATAmut DNA fragments (Fig. 5, lanes 2-6). However, the formation of the P-D-T complex was affected by a change in spacing between the two elements and was dependent on the presence of the TATA box. Relatively equal ratios of P-D to P-D-T complexes were detected on the wt and inP3 probes (Fig. 5, lanes 7, 8). However, for the inP5 and inPl0 probes, the ratio of the P-D to P-D-T complexes was much greater (Fig. 5, lanes 9, 10). The P-D-T complex was barely detectable on the TATAmut promoter probe in this experiment (Fig. 5, lane 11). In addition, we examined the formation of proteinDNA complexes on probes containing a decreased spacing between the PSE and the TATA box (deP5 or dePl0 constructs from Goomer and Kunkel, 1992), and found no change in the amount of P-D-T or P-D complexes compared to the wt U6 promoter probe (data not shown).
PBP
-
re-hTBP
++++++++++ -
-+++++
of the P-D-T complex
is dependent
1234567891011
Fig. 5. Detection
of the TATA box to the PSE in the U6 proximal
on the proximity
promoter
probes. The
wt and mutant probes used in EMSA (as described in Fig. 1) are noted above each lane. Lanes 2 to 6 contained 2 ug PBP added to the radiolabeled probes.
Lanes 7 to 11 contained
2 ug PBP and 0.08 ug re-hTBP
added to the radiolabeled probes. The band marked by an asterisk represents a non-specific complex. An open bracket indicates a smear whose
presence
containing
was dependent
on the addition
of TBP
to a probe
the TATA box.
This result was unexpected,
since transcription
from both
inP and deP mutant promoters was impaired when the spacing between the PSE and TATA box was altered by more than 2 bp (Goomer and Kunkel, 1992). It is interesting that formation of the P-D-T complex on the deP5 probe was not reduced, in contrast to the inP5 probe, since the relative helical orientation of the binding sites was markedly changed with both mutant probes. It appears as if the distance of the separation between the PSE and the TATA box is more important than the rotational orientation on the double helix. By comparing EMSA and DNaseI footprinting results of re-yTBP-DNA complexes, Hawley and coworkers have demonstrated that these protein-DNA complexes dissociate in gels (Hoopes et al., 1992). The lower intensity of the P-D-T complex formed on the inPl0 promoter may reflect either the disability of TBP to become incorporated into a P-D-T (i.e., a lower k,, for inP10) or the relative ease of dissociation of TBP from P-D-T (i.e., a higher koff for inP10). When binding reactions were incubated longer (up to 120 min) and the time of electrophoresis was unchanged, no additional complex formation could be detected (data nbt shown). When gels were electrophoresed longer, the amount of P-D-T complex
274 detected ished shorter
on both
wt and inPl0
significantly
probes
in comparison
was not dimin-
to that
seen
after
times (data not shown).
(1) A HE-binding
protein
on the human
of re-TBP
moter probe resulted taining both proteins (3) Formation on mutant
(P-D)
can
be
This complex
of polyclonal
Ab prepared
along with PBP to a U6 pro-
in the formation (P-D-T).
of the P-D-T
U6 promoters
ally and contain
complex
116 gene promoter.
was disrupted by the addition against re-TBP. (2) Addition
I transcription factor. SLI. Cell 6X ( 1992) 965 976. Cormack. B.P. and Struhl, K.: The TATA-binding protein for transcription by all three nuclear cells. Cell 69 ( 1992) 685 ~696.
(d) Conclusions detected
L.. TaneSc, N. and ~JI:LI~. R.. Ifhc TATA-binding ~I-V~CII~ and associated factors arc integral components of the RNA polymct-asc
C’Olnai,
complex
of a complex
con-
was diminished
that are defective transcription-
increased
spacing
between
the PSE and
TATA box.
Goomer, R.S. and Kunkcl. G.R.: The transcriptional human U6 small nuclear RNA gene is dictated
together,
the above
observations
indicate
that the protein factors that bind the PSE and the TATA box on the U6 proximal promoter interact with one another, either directly or indirectly. Since our PBP fraction was not homogeneous, these experiments cannot rule out the possibility of the involvement of other ‘bridge factors’ that may facilitate the apparent interaction between PBP and TBP. The ‘bridge factors’ could be stably bound PBP-associated factors or independent proteins that cofractionate with PBP in our preparations.
in yeast
start site for a by a compound
promoter element consisting of the PSE and the TATA box. Nucleic Acids Res. 20 ( 1992) 4903 4912. Hahn. S.. Buratowski. S.. Sharp. PA. and Guarente. L.: Isolation of the gene encoding the yeast TATA binding protein TFIID: a gene identical to the SPTIS
suppressor
of Ty element
insertions.
Cell 58
(1989)1173~11X1. Hernander, N.: TBP. a universal Dev. 7 (1993) 1291 130X. Hoopes,
eukaryotic
B.C., LeBIanc, J.F. and Hawley,
transcription
P.M.. Schmidt.
factor‘? Genes
D.K.: Kinetic analysis
TFIID-TATA box complex formation suggests way. J. Biol. Chem. 267 ( 1992) I1539- 11547. Kao. C.C., Lieberman.
(4) Taken
is required
RNA polymerases
of yeast
a multi-step
path-
M.C.. Zhou, Q.. Pei. R. and Berk,
A.J.: Cloning of a transcriptionally active factor. Science 248 ( 1990) 1646-- 1650.
human
TATA binding
Kassavetis. G.A., Joazeiro. C.A.P.. Pisano, M.. Geiduschek. E.P.. Colbert. T., Hahn, S. and Blanco. J.A.: The role of the TATA-binding protein in the assembly and function of the multisubunit yeast RNA polymerase 111 transcription factor. TFIIIB. Cell 71 (1992) 1055%1064. Kunkel, G.R. and Danzeiser,
D.A.: Formation
of a template
committed
complex on the promoter of a gene for the U6 small nuclear RNA from the human requires multiple sequence elements, including the distal region. J. Biol. Chem. 267 (1992) 14250~~14258. Kunkel. G.R. and Pederson,
T.: Upstream
elements required
for efficient
transcription of a human U6 RNA gene resemble those of Ul and U2 genes even though a different polymerase is used. Genes Dev. 2 ACKNOWLEDGEMENTS
We would like to thank Tjian’s laboratory (U.C. Berkeley) for the hTBP cDNA, Kathy Beifuss from the David 0. Peterson laboratory (Texas A&M) for TBP preparations, Rachel Meyers and Phillip Sharp (MIT) for rabbit laboratory,
a-TBP Ab and Stephan Kopytek (Peterson Texas A&M) for rabbit a-TFIIB Ab. We are
grateful for the expert assistance of Deborah A. Danzeiser with cell culture and protein purification, and JungSun Park for subcloning the hTBP cDNA into a pET3c vector. This work was supported by grants from the NSF (DMB-8903970 and MCB-9304799).
REFERENCES Ares Jr., M., Mangin, M. and Weiner, A.M.: Orientation-dependent transcriptional activator upstream from a human U2 snRNA gene. Mol. Cell. Biol. 5 (1985) 1560-1570. Bernues, J., Simmen, K.A., Lewis, J.D., Gunderson, S.I., PolycarpouSchwarz. M., Moncollin, V., Egly, J.-M. and Mattaj, I.W.: Common and unique transcription factor requirements of human Ul and U6 snRNA genes. EMBO J. 12 (1993) 3573-3585. Ciliberto, G., Buckland, R., Cortese, R. and Philipson, L.: Transcription signals in embryonic Xenopus la& Ul RNA genes. EMBO J. 4 (1985) 1537-1543.
(1988) 196-204. Lobo, S.M. and Hernandez.
N.: A 7 bp mutation
converts
a human
RNA polymerase II snRNA promoter into an RNA polymerase III promoter. Cell 58 (1989) 55-67. Lobo, S.M., Lister. J.. Sullivan. M.L. and Hernandez. N.: The cloned RNA polymerase II transcription ase III to transcribe the human
factor IID selects RNA polymcrU6 gene in vitro. Genes Dev. 5
(1991) 1477 1489. Lobo, SM.. Tanaka, M.. Sullivan, M.L. and Hernandez, N.: A TBP complex essential for transcription from TATA-less but not TATAcontaining RNA polymerase III promoters is part of the TFIIIB fraction.
Cell 71
( 1992) IO29- 1040.
Margottin, F., Dujardin, G., Gerard, M., Egly, J.-M., Huet, J. and Sentenac. A.: Participation of the TATA factor in transcription of the yeast U6 gene by RNA polymerase C. Science 251 (1991) 424-426. Mattaj. I.W.. Lienhard, S.. Jiricny, J. and De Robertis. EM.: An enhancer-like sequence within the Xenopus U2 gene promoter facilitates the formation of stable transcription complexes. Nature 316 (1985) 163~ 167. Mattaj, I.W.. Dathan, N.A.. Parry, H.D.. Carbon, P. and Krol. A.: Changing the RNA polymerase speciticity of U snRNA gene promoters. Cell 55 (1988) 435-442. Murphy, J.T., Skuzeski, J.T., Lund, E., Steinberg. T.H., Burgess, R.R. and Dahlberg, J.E.: Functional elements of the human Ul RNA promoter. Identification of five separate regions required for efficient transcription and template competition. J. Biol. Chem. 262 (1987) 1795~1803. Murphy, S., Yon, J.-B., Gerster, T. and Roeder, R.G.: Oct.1 and Ott-2 potentiate functional interactions of a transcription factor with the proximal sequence element of small nuclear RNA genes. Mol. Cell. Biol. 12 (1992) 3247-3261.
215 Peterson,
M.G.,
domains binding
Tanese,
N., Pugh,
and upstream protein.
Rigby, P.W.J.:
activation
B.F. and properties
Tjian,
R.: Functional
of cloned human TATA
Three in one and one in three: it all depends
element: a TBP-containing through
P.A.: TATA-binding
protein
the
is a classless factor.
I, II, and III Cell 68 (1992)
B., Egly, J.-M. and Mattaj,
for in vitro transcription III. EMBO Simmen,
of the human
H.G., Berkenstam,
I.W.: TFIID
is required
U6 gene by RNA polymerase
R., Bernues,
I.W.: Proximal
species specificity
sequence
in vertebrate
J., Parry, element
U6 snRNA
H.D., Seifart, K.H. factor
promoters.
binding
and
J. Mol. Biol.
Skuzeski,
J.M., Lund,
E., Murphy,
J.T., Steinberg,
T.H., Burgess,
R.R.
initiation protein
of Pol III transcription
factor
Waldschmidt, R., Wanandi, I. and Seifart, K.H.: Identification of transcription factors required for the expression of mammalian U6 genes Wanandi,
J. 10 (1991) 259552603.
I., Waldschmidt,
tion factor
R. and Seifart, K.H.: Mammalian
PBP. Characterization sequence
element
of its binding
transcrip-
properties
to the
of U6 genes. J. Biol. Chem. 268 (1993)
662996640. in transcription
S.P.: The TATA-binding
by RNA polymerases
protein:
a central role
I, II and III. Trends
Genet.
of TATA-binding
protein
8 (1992a) 284-288. White,
R.J. and Jackson,
S.P.: Mechanism
to a TATA-less
class
III promoter.
Cell 71 (1992b)
1041-1053. White, R.J., Jackson, binding
protein
as a general
223 (1992) 873-884.
for transcription
Cell 71 (1992) 1015-1028.
recruitment
J. 10 (1991) 185331862.
K.A., Waldschmidt,
and Mattaj,
TFIIIB.
factors are components
White, R.J. and Jackson,
Simmen, K.A., Bernues, J., Parry, H.D., Stunnenberg,
Ul RNA, II. Identification
essential
A.K.P., Fisher, T.S. and Pugh, B.F.: The TATA-binding
proximal
819-821. A.. Cavallini,
Taggart,
of human
+ 1. J. Biol. Chem. 259 (1984) 834558352.
in vitro. EMBO
of the TATA-binding
protein can distinguish subsets of RNA polymerase promoters. Cell 69 (1992) 697-702. Sharp,
on TBP.
N.: Targeting
complex activates transcription from snRNA promoters PSE. Genes Dev. 7 (1993) 153551548. Schultz, M.C., Reeder, R.H. and Hahn, S.: Variants
of the promoter
and associated
Cell 72 (1993) 7-10. Sadowski, CL., Henry, R.W., Lobo, S.M. and Hernandez, box &-regulatory
J.E.: Synthesis
at position
Science 248 (1990) 1625-1630.
TBP to a non-TATA
and Dahlberg, of two regions
S.P. and Rigby, P.W.J.: A role for the TATA-boxcomponent
of the transcription
RNA polymerase
III transcription
Acad. Sci. USA 89 (1992) 194991953.
factor IID complex factor.
Proc. Natl.
269
0378-l 119/94/$07.00
GENE 08212
A complex that contains proteins binding to the PSE and TATA sites in a human U6 small nuclear RNA promoter (Eukaryotic promoters; RNA polymerase III; snRNA gene transcription factors)
Randal S. Goomer*,
Olgui Urso and Gary R. Kunkel
Department of Biochemistry and Biophysics, Texas A&M University, College Station, TX 77843-2128, USA Received by J.A. Gorman:
22 November
1993; Revised/Accepted:
23 May/24
May 1994; Received at publishers:
27 June 1994
SUMMARY
The proximal promoter of a human U6 small nuclear RNA (snRNA)-encoding gene contains two separate elements, the proximal sequence element (PSE) and the TATA box. We investigated the interaction of the PSE- and TATA-binding proteins (PBP and TBP) with normal and mutant U6 proximal promoters using an electrophoretic mobility shift assay. We detected a complex containing both PBP and TBP bound to the wild-type U6 promoter. Efficient formation of the triple complex was dependent on the presence of the PSE and the TATA box on the template DNA. Mutant U6 promoters containing an increased spacing between the PSE and TATA box of 5 or 10 bp were impaired in the ability to form a complex that includes TBP. We infer from these results that PBP and TBP interact when their binding sites are properly positioned in a U6 gene promoter.
INTRODUCTION
Promoter elements in the 5’ flanking sequences of vertebrate U6 snRNA genes are very similar to those of RNA polymerase-II-transcribed genes. The proximal promoter of U6 consists of a TATA-box sequence Correspondence to: Dr. G.R. Kunkel,
Department
Biophysics,
College
Texas A&M
University,
USA. Tel. (l-409) 845-6257; Fax (l-409) e-mail: [email protected] *Present
address:
Department
of Biochemistry
Station,
and
TX 77843-2128,
845-9274;
of Neurobiology,
The Scripps
Research
Institute, 10666 N. Torrey Pines Road, La Jolla, CA 92037, USA. Tel. (1-619) 554-3634; Fax (1-619) 554-6660. Abbreviations: Ab, antibody(ies); bp, base pair(s); BSA, bovine serum albumin; de, decreased; dpm, disintegrations per min; DTT, dithiothreitol; EMSA, electrophoretic mobility-shift assay; h, human; HEPES, 4-[2-hydroxyethyll-1-piperazine-ethanesulfonic acid; in, increased; PA, polyacrylamide; PAGE, PA-gel electrophoresis; PBP, PSE-binding protein; PCR, polymerase chain reaction; P-D complex, PBP-DNA complex; P-D-T complex, PBP-DNA-TBP complex; pol, RNA polymerase; PSE, proximal sequence element; re-, recombinant; SDS, sodium dodecyl sulfate; snRNA, small nuclear RNA; TBP, TATA-binding protein; wt, wild type; y, yeast. SSDI 0378-l
119(94)00423-4
(-29TATATA-24 m . a human gene) and a PSE sequence (-66CTTACCGTAACTTGAAAGTA-47 in a human gene). The U6 TATA element is required for transcription by RNA polymerase III (pol III) and its elimination results in transcription exclusively by pol II (Mattaj et al., 1988; Lobo and Hernandez, 1989). It has been shown recently that TATA-binding re-protein (TBP) is required for U6 transcription in vitro (Margottin et al., 1991; Simmen et al., 1991; Lobo et al., 1991). Furthermore, a role for TBP in the transcription of 5s and tRNA genes by pol III and rRNA genes by pol I has been shown (White et al., 1992; Cormack and Struhl, 1992; Schultz et al., 1992; Taggart et al., 1992; Lobo et al., 1992; White and Jackson, 1992b; Kassavetis et al., 1992; Comai et al., 1992). TBP has emerged as a general transcription factor for transcription by all three RNA polymerases (Sharp, 1992; White and Jackson, 1992a; Rigby, 1993; Hernandez, 1993). The vertebrate pol-II-transcribed genes that encode the abundant spliceosomal snRNAs (UI, U2, U4 and U5), do not require the presence of a TATA box. Instead the proximal promoters of these genes contain the PSE that
270 is necessary
for
transcription
(Skuzeski
Ciliberto
et al., 1985; Mattaj
Murphy
et al., 1987). In addition,
efficient
transcription
Hernandez, groups
have identified
region and is required (PBP, PTF or SNAP,; et al., 1992; Murphy Sadowski
a PSE is required I/6 gene (Lobo
and Pederson,
a protein Waldschmidt
reduction
in transfected Goomer
of a rigid others
cells (Mattaj
spacing
et al., 1993;
et al., 1993).
changes
in transcriptional
and Kunkel,
in the PSE
et al.. 1991; Simmen
the TATA results
in a
efficiency in vitro and
have hypothesized
the two elements, that
the protein
we and
factors
that
bind the PSE and the TATA box may interact with one another, either directly or indirectly. Using a gel mobilityshift analysis, we detected a complex containing both the PBP and recombinant human TBP on the U6 promoter. DNA fragments containing spacing changes that greatly reduce transcriptional efficiency in vitro supported a reduced level of this complex. Thus we conclude that these transcription factors interact when bound to the U6 gene promoter.
RESULTS
u-TBP
Ab was added
(Fig. 2, lanes 2 4). Addition control
(a-TFIIB)
detected
to the binding of another
rabbit
complex
upon addition
Ab, even when these experiments
out with purified
Ah as ;I
had little effect (Fig. 2, lanes 5- 7). We
no discrete supershifted
of a-TBP
reaction
Ab (results
not shown).
were carried Although
this
experiment did not rule out the possibility of a distinct PBP polypeptide that shares a TBP epitope, it is likely that
the P-D complex
contains
TBP.
Furthermore.
in PSE-binding
not bind the TATA box, since no difference plex formation probes
was detected
were compared
when
protein
we does
in P-D com-
wt and
TATAmut
(Fig. 5. lanes 2 and 6).
et al., 1988; Lobo et al., 1991;
1992). Based upon the requirement between
rabbit
infer that this TBP present
between
box and the PSE in the U6 gene promoter drastic
and
U6 gene transcription
et al., 1992; Wanandi
of spacing
for
1988). Several
that binds
for efficient
et al.. 1993; Bernues
Introduction
1984:
et al.. 1985; Ares et al., 1985:
of a human
1989; Kunkel
et al.,
AND DISCUSSION
(a) Detection of a complex on the human U6 proximal promoter that contains PBP Fig. 1A depicts the labeled probes used in these experiments. Probe A contained the wt U6 sequence from -84 to + 111 that includes the U6 proximal promoter along with most of the U6 coding region. Probe B contained exclusively 5’ flanking sequences from - 148 to - 1. Where tested, each probe gave essentially identical results in the experiments reported here. A partially purified fraction of PBP from human 293 cells retarded the mobility of the wt probe A in a nondenaturing PA gel (the P-D complex; Fig. lB, lane 2). The shifted complex could be competed effectively by an unlabeled U6 plasmid containing the PSE (the wt or the TATAmut plasmids; Fig. 1A) but not a plasmid that contained a mutated PSE sequence (PSEmut) (Fig. 1B; compare lanes 3 and 4 with lane 5). It has been reported recently that a different preparation of HeLa cell PSE-binding protein, SNAP,, contained TBP (Sadowski et al., 1993). We explored whether the P-D complex could be disrupted by addition of an Ab that reacts against human TBP. Indeed, the ability to detect the P-D complex was drastically reduced when
(h) Formation of a complex containing PBP and re-TBP on the human U6 proximal promoter Inclusion
of recombinant
human
TATA-binding
pro-
tein (re-hTBP) along with PBP resulted in the formation of another complex of reduced mobility on the wt probe (the P-D-T complex; Fig. lB, lane 6). The P-D-T complex, along with the P-D complex could be competed away by the wt or the TATAmut U6 plasmids but not the PSEmut plasmid (Fig. 1B; compare lanes 7 and 8 with lane 9). The ability of PSE-containing plasmids and not the PSEmut plasmid to efficiently compete both the P-D and P-D-T complexes provides evidence that the PSE-binding activity is present in both complexes. It is curious that the PSEmut plasmid DNA did not compete the P-D-T complex whose presence depended on the addition of TBP. since this plasmid template contains an intact TATA box. Large amounts of recombinant TBP were used in these binding assays, and we calculate that the molar concentrations of TBP and Uh promoter were nearly equivalent when competitor plasmid DNA was included in the reaction. The band marked with an asterisk represents binding of nonspecific protein(s) present in the PBP preparation, since it was not competed by relatively high levels of the unlabeled specific competitor (Fig. 1B). The collection of heterogeneous bands marked with an open bracket was observed only when re-TBP was present in the reaction mixture and was not efficiently reduced by specific competitors (Fig. lB, lanes 7-9). These broad bands were observed only when TATA-containing templates were used in the presence of TBP, and their intensities were enhanced when PBP was included in the reaction also. One implication of this observation is that these bands represent TBP-DNA complexes that are facilitated to form in the presence of PBP. Yeast TATA-binding protein (re-yTBP) also formed a distinct, slower-mobility complex when incubated with the human PBP preparation and the U6 DNA probe. The PBP-DNA-re-yTBP complex had a slightly greater mobility than the PBP-DNA-re-hTBP complex (Fig. 3:
A,1S wtU6
-84
-148
probe A probe 8
l
1 PSE
TATA
P-D-T L P-D -
=
TATAmut
PSEmut *inP series
D-
spacing mutants PBP (P)
inP3 PSE
TATA
re_hmpm
-
++++++++
-
-
-
-
-
++++
123456789
inP5 s?“-=
TATA
inP1 Cl
Probe: r
A
TATA
Fig. 1. Detection of protein-DNA complexes on the human U6 promoter. (A) U6 promoter constructs used in EMSA. The TATAmut and PSEmut promoters contained clustered point mutations to disrupt the TATA box and the PSE, respectively (Kunkel and Danzeiser, 1992). The inP3, inP5 and inPl0 mutant constructs contained increased spacing between the PSE and the TATA box of 3, 5 or 10 bp, respectively (Goomer and Kunkel, 1992). (B) EMSA: The PBP fraction (2 pg protein) was incubated with a radiolabeled wt U6 probe A for 30 min and electrophoresed on a 4% PA non-denaturing gel to separate complexes. In lanes 2 to 5, PBP (2 ug) was incubated with the radiolabeled wt U6 probe in the presence of 1 ug of the specific and non-specific unlabeled competitor DNAs (approx. lO%fold molar excess). In lanes 6 to 9, PBP (2 ug) and re-hTBP (0.08 ug) were incubated with radiolabeled wt U6 probe in the presence of 1 ug (approx. lOO-fold molar excess) of the same competitor DNAs. The asterisk marks a non-specific complex. The open bracket identifies a series of bands present in reactions containing re-hTBP. Methods: The radiolabeied U6 promoter probes used in this study were generated by PCR. For probe A, the ‘U6’ primer (5’-TATGGAACGCTTCAC) was end-labeled and paired with the ‘Rsa’ primer (S-ACAAAATACGTGACGTAGAA). This probe was truncated by digestion at position - 84 with Draf. For probe B, the ‘Rsa’ primer was end-labeled and paired with the ‘cU6-1’ primer (T-GGTGTTTCGTCCTTTCCACA). Probes were purified by gel electrophoresis and dissolved in 10 mM Tris/l mM EDTA (pH 7.5) to give 20000 dpm/ul (approx. spec. act. 5 x lo6 dpm/pmol). PBP was purified from 20 litres 293 cells (a human embryonic kidney cell line) grown in suspension in Joklik’s minimum essential medium containing 5% calf serum and 1% newborn calf serum. SlOO extract (approx. 14-17 mg/ml; Goomer and Kunkel, 1992) was loaded onto a phosphocellulose (Whatman Pll) column (10 mg protein per ml of resin) equilibrated with buffer D (20 mM HEPES pH 7.9/20% glycerol/O.2 mM EDTA/O.S mM DTT/O.I M KCl). The transcriptionally active fractions (present in the 0.1 to 0.6 M KC1 eluate at approx. 2.5 mg/ml protein concentration) were dialyzed against buffer B (50 mM TrisHCl pH 7.9/0.1 mM EDTA,/2 mM DTT) containing 50 mM (NH&SO, and loaded onto a DEAE-Sephadex column equilibrated with the same buffer ( 1mg protein/ml of resin). PBP activity eluted with buffer B containing 0.15 M (NH4)$04 and was dialyzed against buffer D. P&E-binding activity was monitored by EMSA as described below. This sample (approx. 10 mg protein) was loaded onto a heparin-agarose column ( 10 ml resin) equilibrated with buffer D. Fractions containing the PSE-binding activity were step-eluted between 0.2 M and 0.35 M KC1 and dialyzed against buffer D. The heparin eluate (approx. 0.5 mg/mI protein) was loaded onto a 100 ml Sephacryl-HR2~ (Pha~acia) column equilibrated with buffer D. All of the FSE-binding activity was present in fractions that eluted immediately after the void volume (approx. 0.2 mg/ml protein). Fractions were pooled and quick frozen in liquid nitrogen and stored at -80°C. Purified re-hTBP was the gift of the D.D. Peterson laboratory (Department of Biochemistry and Biophysics, Texas A&M University). The cDNA for hTBP (Peterson et al., 1990) was subcloned into the pET3c vector. The purity of the hTBP preparation was estimated to be approx. 50-60%, as determined by SDS-PAGE. The protein was stored in TMO.1 buffer (50 mM TrisHCl pH 7.9/i mM EDTA/12.5 mM MgCI,/l mM DTT/ZO% glycerol/100 mM KCl) at -80°C in individual-use aliquots. Binding reactions for gel mobility shift assays contained about 4 fmol of radiolabeled probe A (20000 dpm)/lO ul of Buffer A (25 mM HEPES pH 7.9/5 mM MgC1,/0.5 mM EDTA/SO mM KCl/0.5 mM DTTjtOX glycerol/O.5 ug BSA)/SOOng poly [d(G-C)]/l ug of nonspecific or specific competitor plasmid DNA and the indicated proteins in a 25 ul total reaction volume. The reactions were incubated for 30 min at 30°C and electrophoresed on a 4% polyacrylamide gel for 2.5 h at 200 V (constant voltage) in TGEM (25 mM TrisCl pH 8.3/0.19 M glycine/l mM EDTA/2 mM MgCl,) with 10% glycerol and 0.1% NP40 (Nonidet P-40). Gel electrophoresis was performed in 0.5 x TGEM buffer. Dried gels were autoradiographed with an intensifying screen.
compare lanes 6-8 and 10-12). This difference in the mobility of the P-D-T complex due to the addition of re-yTBP versus re-hTBP is consistent with the smaller mass of yTBP (27 kDa) versus hTBP (38 kDa) (Hahn et al., 1989; Peterson et al., 1990; Kao et al., 1990). We tested the dependence of the P-D-T complex on the presence of the TATA box in the human U6 promoter.
A much reduced ratio of the amount of complex with the mobility of P-D-T relative to P-D was formed on a radiolabeled TATAmut probe (Fig. 4, lanes 7-10; also see Fig. 5, lane II). When a very high amount of re-hTBP was present in the binding reaction (approx. 0.34 ug; Fig. 4, lane lo), we observed a band of reduced mobility. This slowest mobility complex could be a P-D-T com-
272
antibody:
_ P-D-T
top -
P-D !z’
c
P-D-
re-yTJ3P
*lz
-
-
-
-
+
+
+
+
-
re_n-t-np -
-
-
-
-
_
_
_
+
+
+
+
9
10
11
12
12345678 Fig. 3. EMSA of the slow mobility human
or yeast TBP is bound
are described was incubated
D-
of polyclonal
the P-D complex. bated with approx.
Ab against
hTBP
A radiolabeled wt Uh probe 2 ug PBP protein preparation
inhibits
formation
of
B (Fig. IA) was incuwith or without rabbit
Ab as designated above each lane. The sample loaded in lane I contained no Ab. Samples loaded in lanes 224 contained 0.1 ~1. 0.3 1.11and 1 ~1, respectively. of rabbit Ab that binds to hTBP. Samples loaded in lanes 557 contained 0.1 pl, 0.3 ul and 1 ul of rabbit Ab that binds to human
TFIIB,
for EMSA
used as a control
were as described
for this experiment.
in the legend
Conditions
to Fig. I. except
the position
used
that the
samples contained 1 ug poly [d(G-C)]:2 mM MgClz:5 mM Bands labeled with the asterisk identify non-specific complexes. denotes
-
( P-D-T) complex is different when
to the promoter.
Conditions
in the legend to Fig. 1. A radiolabeled with an increasing amount of added
for EMSA
wt C’h probe A PBP: Lanes: 1, 5
and 9, no PBP; 2, 6 and 10, approx.
0.5 ug PBP; 3. 7 and
1.25 pg PBP: 4, 8 and
2 pg PBP.
12: approx.
-
I I: approx.
The concentration
of
re-yTBP was kept constant in lanes 558 at approx. 0.04 pg. In lanes 9 to 12 a constant amount of re-hTBP was added to each of the EMSA
1234567 Fig. 2. Addition
-
DTT. ‘Top’
of the well.
plex, implying that the PBP bound on the TATAmut promoter can tether TBP into a P-D-T complex. On the wt promoter we observed that the predominant shifted complex corresponded to P-D-T after a large amount of TBP was titrated into the binding reaction (Fig. 4, lanes l-6). Interestingly, the total amount of P-D plus P-D-T complexes was increased in the presence of higher concentrations of TBP. Possibly, TBP facilitates the binding of PBP to the promoter. Several independent indirect observations identify the P-D-T complex as containing both the TBP and PBP bound to the U6 proximal promoter. (i) The observed expected difference in the mobility of the re-yTBP and re-hTBP dependent slow mobility complexes provides evidence that TBP is present in the P-D-T complex (Fig. 3). (ii) The slow mobility complex was dependent on the TATA box sequence. The P-D-T complex was detected readily on the normal promoter, while, at the same concentration of TBP, a very low level of P-D-T
(approx. 0.08 ug re-hTBP). The D-yT band represents a complex formed solely due to the incubation of re-yTBP with DNA. A smear present in lanes containing
re-hTBP
(lanes 9912) is marked
by an open bracket.
Purified re-yTBP was provided by the D.O. Peterson laboratory (Department of Biochemistry and Biophysics, Texas A&M University) and was estimated SDS-PAGE.
complex
to bc approx.
was observed
80 90%
pure,
on the TATAmut
as determined
probe
by
(Figs. 4
and 5). (iii) Increasing the concentration of TBP in the binding reaction resulted in an increased ratio of the P-D-T to P-D complexes, implying a precursor-product relationship between PBP-DNA and PBP-DNA-TBP complexes (Fig. 4). Taken together, the above observations imply that the complex identified as P-D-T contains both PBP and TBP bound to the U6 proximal promoter. (c) Spacing mutants that result in a greatly reduced level of transcription in vitro are also deficient in the ability to support formation of a complex containing both PBP and TBP In a previous study we had either increased (inP constructs) or decreased (deP constructs) the spacing between the PSE and TATA box by 1, 2, 3, 5 or 10 bp. Mutant promoters containing an increased spacing (of 5 or more bp) between the PSE and the TATA box supported a greatly reduced level of U6 specific transcription in vitro (Goomer and Kunkel, 1992). In order to investigate the stable binding of transcription factors on these mutant U6 proximal promoters, we prepared radiolabeled DNA fragments from these spacing change constructs (Fig. 1A). The specific radioactivity of each probe
213
Probes: P-D-T L P-D -
P-D-T L P-D -
c
c
**-
DPBP (P) l-BP(T)
-
+++++
++++
1
-++++ 23456
++++ 78910
I
I
I
TATAmut
wt promoter
Probe:
Fig. 4. Efficient detection dependent TATAmut
D-
of the slowest
mobility
complex
(P-D-T)
is
on the presence of a TATA box in the U6 probe. The wt or probes were incubated with a constant amount of PBP and
an increasing concentration of re-hTBP, EMSA was as described in the legend to Fig. 1. The experiments using the wt probe (lanes l-6) and TATAmut
probe
(lanes
7710) were carried
out at different
times. In
lanes 2 to 10 a constant amount of PBP (2 ug protein) was incubated with the probe. Lanes 3 and 7 contained 40 ng re-hTBP, lanes 4 and 8 contained 80 ng re-hTBP; lanes 5 and 9 contained 0.17 ug re-hTBP; and lanes 6 and 10 contained 0.34 ug re-hTBP. The band marked by the asterisk only
indentifies
in the wt probe
denoted
a non-specific reactions
complex.
containing
A diffuse band re-hTBP
(lanes
present 3-6)
is
by an open bracket.
was identical, since the same kinased oligodeoxynucleotide was used for each preparation. Fig. 5 shows the binding of PBP or PBP and TBP to these probes. A stable P-D complex was formed on all constructs tested, i.e., the wt, inP3, inP5, inPl0 or TATAmut DNA fragments (Fig. 5, lanes 2-6). However, the formation of the P-D-T complex was affected by a change in spacing between the two elements and was dependent on the presence of the TATA box. Relatively equal ratios of P-D to P-D-T complexes were detected on the wt and inP3 probes (Fig. 5, lanes 7, 8). However, for the inP5 and inPl0 probes, the ratio of the P-D to P-D-T complexes was much greater (Fig. 5, lanes 9, 10). The P-D-T complex was barely detectable on the TATAmut promoter probe in this experiment (Fig. 5, lane 11). In addition, we examined the formation of proteinDNA complexes on probes containing a decreased spacing between the PSE and the TATA box (deP5 or dePl0 constructs from Goomer and Kunkel, 1992), and found no change in the amount of P-D-T or P-D complexes compared to the wt U6 promoter probe (data not shown).
PBP
-
re-hTBP
++++++++++ -
-+++++
of the P-D-T complex
is dependent
1234567891011
Fig. 5. Detection
of the TATA box to the PSE in the U6 proximal
on the proximity
promoter
probes. The
wt and mutant probes used in EMSA (as described in Fig. 1) are noted above each lane. Lanes 2 to 6 contained 2 ug PBP added to the radiolabeled probes.
Lanes 7 to 11 contained
2 ug PBP and 0.08 ug re-hTBP
added to the radiolabeled probes. The band marked by an asterisk represents a non-specific complex. An open bracket indicates a smear whose
presence
containing
was dependent
on the addition
of TBP
to a probe
the TATA box.
This result was unexpected,
since transcription
from both
inP and deP mutant promoters was impaired when the spacing between the PSE and TATA box was altered by more than 2 bp (Goomer and Kunkel, 1992). It is interesting that formation of the P-D-T complex on the deP5 probe was not reduced, in contrast to the inP5 probe, since the relative helical orientation of the binding sites was markedly changed with both mutant probes. It appears as if the distance of the separation between the PSE and the TATA box is more important than the rotational orientation on the double helix. By comparing EMSA and DNaseI footprinting results of re-yTBP-DNA complexes, Hawley and coworkers have demonstrated that these protein-DNA complexes dissociate in gels (Hoopes et al., 1992). The lower intensity of the P-D-T complex formed on the inPl0 promoter may reflect either the disability of TBP to become incorporated into a P-D-T (i.e., a lower k,, for inP10) or the relative ease of dissociation of TBP from P-D-T (i.e., a higher koff for inP10). When binding reactions were incubated longer (up to 120 min) and the time of electrophoresis was unchanged, no additional complex formation could be detected (data nbt shown). When gels were electrophoresed longer, the amount of P-D-T complex
274 detected ished shorter
on both
wt and inPl0
significantly
probes
in comparison
was not dimin-
to that
seen
after
times (data not shown).
(1) A HE-binding
protein
on the human
of re-TBP
moter probe resulted taining both proteins (3) Formation on mutant
(P-D)
can
be
This complex
of polyclonal
Ab prepared
along with PBP to a U6 pro-
in the formation (P-D-T).
of the P-D-T
U6 promoters
ally and contain
complex
116 gene promoter.
was disrupted by the addition against re-TBP. (2) Addition
I transcription factor. SLI. Cell 6X ( 1992) 965 976. Cormack. B.P. and Struhl, K.: The TATA-binding protein for transcription by all three nuclear cells. Cell 69 ( 1992) 685 ~696.
(d) Conclusions detected
L.. TaneSc, N. and ~JI:LI~. R.. Ifhc TATA-binding ~I-V~CII~ and associated factors arc integral components of the RNA polymct-asc
C’Olnai,
complex
of a complex
con-
was diminished
that are defective transcription-
increased
spacing
between
the PSE and
TATA box.
Goomer, R.S. and Kunkcl. G.R.: The transcriptional human U6 small nuclear RNA gene is dictated
together,
the above
observations
indicate
that the protein factors that bind the PSE and the TATA box on the U6 proximal promoter interact with one another, either directly or indirectly. Since our PBP fraction was not homogeneous, these experiments cannot rule out the possibility of the involvement of other ‘bridge factors’ that may facilitate the apparent interaction between PBP and TBP. The ‘bridge factors’ could be stably bound PBP-associated factors or independent proteins that cofractionate with PBP in our preparations.
in yeast
start site for a by a compound
promoter element consisting of the PSE and the TATA box. Nucleic Acids Res. 20 ( 1992) 4903 4912. Hahn. S.. Buratowski. S.. Sharp. PA. and Guarente. L.: Isolation of the gene encoding the yeast TATA binding protein TFIID: a gene identical to the SPTIS
suppressor
of Ty element
insertions.
Cell 58
(1989)1173~11X1. Hernander, N.: TBP. a universal Dev. 7 (1993) 1291 130X. Hoopes,
eukaryotic
B.C., LeBIanc, J.F. and Hawley,
transcription
P.M.. Schmidt.
factor‘? Genes
D.K.: Kinetic analysis
TFIID-TATA box complex formation suggests way. J. Biol. Chem. 267 ( 1992) I1539- 11547. Kao. C.C., Lieberman.
(4) Taken
is required
RNA polymerases
of yeast
a multi-step
path-
M.C.. Zhou, Q.. Pei. R. and Berk,
A.J.: Cloning of a transcriptionally active factor. Science 248 ( 1990) 1646-- 1650.
human
TATA binding
Kassavetis. G.A., Joazeiro. C.A.P.. Pisano, M.. Geiduschek. E.P.. Colbert. T., Hahn, S. and Blanco. J.A.: The role of the TATA-binding protein in the assembly and function of the multisubunit yeast RNA polymerase 111 transcription factor. TFIIIB. Cell 71 (1992) 1055%1064. Kunkel, G.R. and Danzeiser,
D.A.: Formation
of a template
committed
complex on the promoter of a gene for the U6 small nuclear RNA from the human requires multiple sequence elements, including the distal region. J. Biol. Chem. 267 (1992) 14250~~14258. Kunkel. G.R. and Pederson,
T.: Upstream
elements required
for efficient
transcription of a human U6 RNA gene resemble those of Ul and U2 genes even though a different polymerase is used. Genes Dev. 2 ACKNOWLEDGEMENTS
We would like to thank Tjian’s laboratory (U.C. Berkeley) for the hTBP cDNA, Kathy Beifuss from the David 0. Peterson laboratory (Texas A&M) for TBP preparations, Rachel Meyers and Phillip Sharp (MIT) for rabbit laboratory,
a-TBP Ab and Stephan Kopytek (Peterson Texas A&M) for rabbit a-TFIIB Ab. We are
grateful for the expert assistance of Deborah A. Danzeiser with cell culture and protein purification, and JungSun Park for subcloning the hTBP cDNA into a pET3c vector. This work was supported by grants from the NSF (DMB-8903970 and MCB-9304799).
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