(Received for publication, August 15, 1995)
From the
Previous studies in this laboratory have identified an essential AP-1 recognition sequence (C1 region; -69 to -63) in the human Pi class glutathione S-transferase (GSTP1) promoter and a negatively acting regulatory element (-105 to -86) that acts to suppress GSTP1 transcription in the human mammary carcinoma cell line, MCF7(1) . The data presented here further delineate the functional characteristics of the GSTP1 promoter by examining the significance of two potential binding sites for the transcription factor, Sp1 (-57 to -49 and -47 to -39). The introduction of mutations within these Sp1-like elements and the use of Sp1 antisera in electrophoretic mobility shift assays demonstrated that Sp1 was bound to this region of the GSTP1 promoter in three different cell lines, MCF7, VCREMS, and EJ. Moreover, these in vitro studies indicated that only one of the two putative Sp1 response elements was utilized. Transient transfection assays using GSTP1 promoter constructs that incorporated mutations of the Sp1 elements clearly demonstrated that binding of Sp1 to the GSTP1 promoter was absolutely required for optimal levels of GSTP1 transcription. In particular, disruption of the distal Sp1 recognition motif (-57 to -49) markedly reduced GSTP1 promoter activity in each cell line, thus indicating preferential binding of Sp1 to the distal site. However, insertion of the repressor binding site (-105 to -86) into these constructs suggested that Sp1 was not involved in mediating the suppressive effects of the GSTP1 transcriptional repressor in MCF7 cells, because inhibition of Sp1 binding did not alleviate repressor activity. Therefore, these studies provide strong evidence that Sp1 plays a central role in regulating basal levels of GSTP1 transcription.
Glutathione S-transferases (GSTs) ()are an
important family of enzymes primarily responsible for the
detoxification of a large number of electrophilic xenobiotics by
catalyzing the nucleophilic conjugation of these compounds with
glutathione. There are five mammalian subclasses of GSTs, namely Alpha,
Pi, Mu, Theta, and microsomal, with different classifications of
substrate specificity(2, 3) .
Overexpression of the Pi class of GST enzymes has been associated with tumor development and carcinogenesis(4, 5, 6, 7, 8, 9) and in the acquisition of antineoplastic drug resistance(10, 11, 12, 13) . Therefore, understanding the transcriptional regulatory mechanisms of this particular gene family has stimulated much research activity.
In this regard, functional studies of the rat GSTP promoter have identified several regulatory elements that are important for basal and inducible expression(14, 15, 16, 17, 18) . Moreover, preliminary analysis of the human GSTP1 promoter had identified a putative AP-1 response element(19, 20, 21, 22, 23) .
Recent studies in this laboratory have established that the AP-1 recognition sequence is absolutely required for transcriptional activity of the GSTP1 promoter(1) . The transcription factor AP-1 is comprised of members of the Jun (c-Jun, JunB, and JunD) and Fos (c-Fos, FosB, Fra1, and Fra2) protein families(24, 25) . We have demonstrated that a Jun-Fos heterodimer is an integral component of the nuclear complex bound to this essential GSTP1 promoter element in a multidrug-resistant derivative (VCREMS) of the human mammary carcinoma cell line, MCF7. In addition, we have identified a negative regulatory element (-105 to -86) that acts to suppress GSTP1 transcription in MCF7 cells(1) .
Analysis of the GSTP1 proximal promoter revealed the presence of two putative Sp1 binding sites (-57 to -49 and -47 to -39) located downstream of the AP-1 response element. The transcription factor Sp1 was first identified as a regulatory protein that bound multiple GC-rich boxes in the 21-bp repeat elements of the SV40 early promoter(26, 27, 28, 29, 30) . Since this initial observation, Sp1 has been shown to regulate the activity of a large number of viral and cellular promoters. The DNA binding domain of Sp1 consists of three zinc finger motifs (31) and recognizes the 9-bp sequence GGGGCGGGG, in which each triplet is thought to be contacted by one of the three zinc fingers(32, 33, 34, 35) .
These present studies examine the ability of these potential Sp1 response elements in the GSTP1 promoter to bind Sp1 in vitro. In addition, the functional significance of these DNA-protein interactions in regulating GSTP1 promoter activity is addressed. Finally, we investigate the involvement of Sp1 in mediating the suppressive effects of the GSTP1 transcriptional repressor in MCF7 cells.
In competition experiments, the reaction mixture was preincubated for 20 min at room temperature with 100-fold molar excess of unlabeled DNA (or 3 µl of polyclonal anti-human Sp1 antisera; a generous gift from Dr. Stephen Jackson) before the addition of radiolabeled probe.
The following oligonucleotides and their complementary sequences were used as probes and competitors: the GSTP1 promoter fragment -61 to -32, 5`-CACTGGGGCGGAGCGGGGCGGGACCACCCT-3`; 5`-CACTGTCAAGGAGCGGGGCGGGACCACCCT-3` (M1); 5`-CACTGGGGCGGAGCGTCAAGGGACCACCCT-3` (M2); 5`-CACTG TCAAGGAGCG TCAAGGGACCACCCT-3` (M3); the GSTP1 promoter fragment -53 to -32, 5`-CGGAGCGGGGCGGGACCACCCT-3` and the Sp1 consensus sequence 5`-ATTCGATCGGGGCGGGGCGAGC-3` from the SV40 early promoter (32) and the AP-1 binding site from the human collagenase promoter, 5`-AGCTTGATGAGTCAGCCG-3`(41) .
Using p73CAT as a template, mutated GSTP1 promoter fragments were generated by PCR using the following upstream primers (with HindIII linkers) to prepare p73Sp1M1CAT, p73Sp1M2CAT, and p73Sp1M3CAT: 5`-GCCGTGACTCAGCACTGTCAAGGAGCGGGGCGGGACCACCCT-3` (p73Sp1M1CAT), 5`-GCCGTGACTCAGCACTGGGGCGGAGCGTCAAGGGACCACCCT-3` (p73Sp1M2CAT), and 5`-GCCGTGACTCAGCACTGTCAAGGAGCGTCAAGGGACCACCCT-3` (p73Sp1M3CAT).
Using p73Sp1M1CAT, p73Sp1M2CAT, or p73Sp1M3CAT as a template, an oligonucleotide representing the GSTP1 promoter region -105 to -59, was used as an upstream primer (with HindIII linker) in PCR to generate the three mutated GSTP1 promoter fragments used to prepare p105Sp1M1CAT, p105Sp1M2CAT, and p105Sp1M3CAT: 5`-AGTCCGCGGGACCCTCCAGAAGAGCGGCCGGCGCCGTGACTCAGCAC-3`.
The downstream primer (nucleotides +17 to +36 with SalI linker) used in PCR to generate the six mutated fragments for preparation of the three p73CAT and three p105CAT mutant constructs was 5`-ACTCACTGGTGGCGAAGACT-3`.
Following preparation, all constructs were sequenced by the dideoxy chain termination method(42) .
Figure 1: Cell-specific expression of GSTP1 mRNA. The relative levels of GSTP1 mRNA in MCF7, VCREMS, EJ, HeLa, and HepG2 cells were determined by Northern analysis (10 µg/lane) using a full-length human GSTP1 cDNA fragment as a probe. The ethidium bromide-stained gel is shown to confirm equal loading of RNA samples. kb, kilobase.
The cell line expressing the highest amount of GSTP1 mRNA was the human bladder carcinoma cell line, EJ. In addition, we also used the human mammary carcinoma cell line, MCF7, in which GSTP1 mRNA was not detectable by Northern analysis, and its multidrug-resistant derivative, VCREMS in which substantial levels of GSTP1 mRNA were readily measurable.
Figure 2: Primary structure of the GSTP1 proximal promoter. The putative AP-1 (-69 to -63) and Sp1 (-57 to -49 and -47 to -39) recognition motifs are shaded.
The ability of these potential recognition sequences in the GSTP1 promoter to bind Sp1 was assessed by electrophoretic mobility shift assays. For these studies, four double stranded DNA probes spanning the GSTP1 promoter region, -61 to -32, were prepared (Fig. 3A). The wild-type sequence (-61 to -32) contained both of the Sp1-like elements. M1 contained a 4-bp mutation in the distal site (-57 to -49), whereas a 4-bp mutation was introduced into the proximal site (-47 to -39) to generate M2. In addition, M3 contained 4-bp mutations in both elements. The ability of each of these four GSTP1 promoter fragments to bind proteins in nuclear extracts prepared from MCF7, VCREMS, and EJ cells was then tested.
Figure 3: In vitro binding of nuclear proteins to the GSTP1 promoter fragment -61 to -32. A, mutational analysis of the two potential Sp1 binding sites located within the GSTP1 promoter. B, electrophoretic mobility shift assays demonstrating the nuclear complexes (10 µg of nuclear extract per reaction) in MCF7, VCREMS, and EJ cells that bound the GSTP1 promoter fragment -61 to -32 and the mutated fragments M1, M2, and M3. C, electrophoretic mobility shift assays demonstrating the nuclear complexes (10 µg of nuclear extract per reaction) in MCF7, VCREMS, and EJ cells bound to a single Sp1 binding site. The GSTP1 promoter fragment -53 to -32 and the Sp1 consensus sequence from the SV40 early promoter were used as probes. WT, wild type.
Fig. 3B shows that the wild-type sequence bound three major complexes. Interestingly, both the mobility pattern and the relative intensity of these bands were similar in each cell line. Despite the mutations described above, M1 and M2 both gave the same result as the wild-type sequence. This finding suggests that perhaps sequences flanking the Sp1 motifs were responsible for the observed band shift pattern or alternatively that only one of the two Sp1 elements was occupied at one time. The latter explanation seemed more likely because M3, which contained specific mutations in both of the Sp1-like elements, failed to bind any nuclear proteins.
To further emphasize this possibility, a GSTP1 promoter fragment spanning nucleotides -53 to -32 and thus containing only the proximal Sp1 motif and a probe containing a single Sp1 consensus sequence from the SV40 early promoter, produced the same results as the wild-type sequence, which contained two potential Sp1 binding elements (Fig. 3C).
Figure 4: DNA binding specificity of the nuclear complexes bound to the GSTP1 promoter fragment -61 to -32. Double stranded oligonucleotides containing the mutated fragments M1, M2, and M3 (see Fig. 3A) were used at 100-fold molar excess to compete for the nuclear complexes (10 µg of nuclear extract per reaction) bound to the wild-type GSTP1 promoter fragment -61 to -32. Binding specificity was confirmed using 100-fold molar excess of the Sp1 consensus sequence from the SV40 early promoter as a positive control and the AP-1 binding site from the human collagenase promoter as a negative control. WT, wild type.
Furthermore, efficient competition for the three nuclear complexes was observed with the single Sp1 consensus sequence from the SV40 early promoter but not with the nonspecific AP-1 binding site from the human collagenase promoter. As shown for the experiments presented in Fig. 3(B and C), identical results were observed in all three cell lines.
To clarify this matter, nuclear extracts were incubated with a polyclonal Sp1 antibody for 20 min before the -61 to -32 probe was added to the reaction. Fig. 5clearly shows that the Sp1 antibody disrupted binding of the complexes I and II in all three cell lines, although the high mobility complex III was unaffected. Importantly, preimmune sera did not interfere with the DNA binding activity of any of the three complexes. These results conclusively demonstrated that Sp1 was an integral component of complexes I and II in MCF7, VCREMS, and EJ cells. However, the protein composition of complex III remains unknown.
Figure 5: Inhibition of complex formation with Sp1 polyclonal antisera. MCF7, VCREMS, and EJ nuclear extracts (10 µg/reaction) were preincubated with polyclonal antisera (3 µl/reaction) raised against bacterially expressed human Sp1 for 20 min prior to the addition of the GSTP1 promoter fragment -61 to -32. Preimmune serum was used as a negative control.
Figure 6: In the absence of the AP-1 element, the Sp1 binding sites alone were insufficient to confer optimal activity to the GSTP1 promoter. The GSTP1 promoter fragments -73 to +36 and -65 to +36 were subcloned into the pCAT.Basic vector to generate p73CAT and p65CAT, respectively. Both of these constructs were transfected into MCF7 (black bars), VCREMS (cross-hatched bars), and EJ (shaded bars) cells, and their relative CAT activities were determined. pCAT.Basic (contains no enhancer/promoter sequences) and pCAT.Control (contains SV40 enhancer and promoter) were used as negative and positive controls, respectively. The results were compared between cell lines by correcting for pCAT.Control activity levels.
However, the role played by the two Sp1 binding sites in contributing to the high level of CAT activity observed for p73CAT was not clear, i.e. could the essential AP-1 element still confer optimal GSTP1 promoter activity in the absence of the Sp1 binding sites?
The mutants described in Fig. 3A were introduced by PCR into the GSTP1 promoter fragment -73 to +36 and subcloned into the pCAT.Basic vector to generate p73Sp1M1CAT, p73Sp1M2CAT, and p73Sp1M3CAT. These mutated constructs were transfected into MCF7, VCREMS, and EJ cells, and their transcriptional activity was compared with that of p73CAT (Fig. 7). The results of these experiments showed that in all three cell lines, mutation of the distal Sp1 site (-57 to -49; p73Sp1M1CAT) reduced GSTP1 promoter activity by 45, 57, and 78% in MCF7, VCREMS, and EJ cells, respectively. In contrast, mutation of the proximal binding motif (-47 to -39; p73Sp1M2CAT) had only a relatively marginal effect on GSTP1 transcription. Consistent with these results, mutation of both Sp1-like elements (p73Sp1M3CAT) produced effects on GSTP1 promoter activity similar to those of mutation of the distal site alone.
Figure 7: The presence of the distal Sp1 binding site was required for optimal activity of the GSTP1 promoter. The mutations, M1, M2, and M3 (see Fig. 3A), were introduced by PCR into the GSTP1 promoter fragment -73 to +36 and subcloned into the pCAT.Basic vector to generate p73Sp1M1CAT, p73Sp1M2CAT, and p73Sp1M3CAT. These constructs were transfected into MCF7, VCREMS, and EJ cells, and their CAT activities were compared with that of p73CAT. The numbers at the top of each lane refer to CAT activities derived from each construct relative to p73CAT, which was given an activity level of 100.
Taken together with the in vitro binding data, these results demonstrated that in MCF7, VCREMS, and EJ cells, Sp1 was preferentially bound to the distal Sp1 recognition sequence and that this interaction was required for optimal activity of the GSTP1 promoter.
These experiments were performed by introducing the mutations M1, M2, and M3 (see Fig. 3A) into the GSTP1 promoter fragment -105 to +36 and subcloning the resultant three mutants into pCAT.Basic. Transient transfection assays were performed in MCF7 cells and the promoter activities of the mutant constructs, p105Sp1M1CAT, p105Sp1M2CAT, and p105Sp1M2CAT were compared with that of p105CAT (Fig. 8).
Figure 8: Loss of Sp1 binding to the GSTP1 promoter did not inhibit GSTP1 transcriptional repressor activity. The mutations, M1, M2 and M3 (see Fig. 3A), were introduced by PCR into the GSTP1 promoter fragment -105 to +36 and subcloned into the pCAT.Basic vector to generate p105Sp1M1CAT, p105Sp1M2CAT, and p105Sp1M3CAT. These constructs were transfected into MCF7 cells, and their CAT activities were compared with those of p105CAT and p73CAT. The numbers at the top of each lane refer to the CAT activities derived from each construct relative to p73CAT, which was given an activity level of 100.
Similar to results presented in Fig. 7, the CAT activities of p105Sp1M1CAT and p105Sp1M3CAT were significantly reduced, whereas the activity of p105Sp1M2CAT was relatively unaffected compared with the wild-type construct. These results show that loss of Sp1 binding did not inhibit GSTP1 transcriptional repressor activity. Therefore, it appeared unlikely that a protein-protein interaction between Sp1 and the repressor was required to confer the suppressive effects on GSTP1 transcription.
These studies have clearly demonstrated that interaction of Sp1 with the GSTP1 promoter is required for basal transcription of the GSTP1 gene. Indeed, in the absence of Sp1 binding, the GSTP1 promoter exhibited only 17-40% optimal activity in three different cell lines. Moreover, by mutational analysis, we have shown that the distal Sp1 binding motif (-57 to -49) was functionally more important than the proximal element in terms of regulating basal levels of GSTP1 transcription. However, despite the requirement for Sp1, disruption of the adjacent C1 element deemed the GSTP1 promoter inactive. Therefore, the presence of Sp1 binding sites alone were insufficient to support GSTP1 transcription.
In general, sequence-specific
transcription factors can be classified into two main categories;
proximal promoter factors, which only function close to the
transcriptional start site, and enhancer-binding proteins, which can
exert their effects over much larger distances (48) . Due to
the fact that functional Sp1 binding sites are generally found within a
few hundred nucleotides of the transcriptional start site, Sp1 has been
placed in the former category(28) . Moreover, cloning of Sp1
sites far upstream results in a marked decrease in promoter
activity(49) . These findings have led investigators to
conclude that the primary function of Sp1 is to regulate basal levels
of transcription. In this regard, recent advances have established that
Sp1-mediated transcription has been shown to involve an interaction of
the glutamine-rich activation domain of Sp1 with the
TAF110 component of the basal TFIID complex (50, 51, 52) .
However, it has also been
proposed that proximally bound transcription factors mediate the
regulatory effects of enhancer-binding proteins, i.e. the two
classes of control factors activate transcription synergistically. This
idea was originally formulated from observations that Sp1 interactions
with the SV40 early promoter mediated activity of the SV40
enhancer(53, 54) . Interestingly, Sp1 recognition
motifs are often found located near binding sites for other
transcription factors such as CTF/NF-1(55) , AP-1(56) ,
NF-B(57) , and the sterol regulatory element-binding
protein, SREBP(58) . Indeed, synergistic activation of the HIV
promoter by NF-
B and Sp1 (57) and of the low density
lipoprotein receptor gene by SREBP and Sp1 (58) have recently
been demonstrated.
Our results have indicated that a similar mechanism may account for Sp1-mediated activation of the GSTP1 promoter. In the absence of Sp1 binding, the essential C1 element was only able to confer 17-40% optimal activity on the GSTP1 promoter. Conversely, in the presence of the Sp1 binding motifs, disruption of the C1 element rendered the GSTP1 promoter inactive. These data strongly indicate that basal transcriptional activity of the GSTP1 promoter is mediated by a synergistic mechanism requiring both Sp1 and the C1 nuclear complex. Given the critical importance of these two elements, the above conclusion suggests that cooperativity between these two complexes would mediate changes in transcriptional rates of the GSTP1 promoter.
In this regard, it was important to examine the role of Sp1 in controlling GSTP1 transcription in three cell lines, MCF7, VCREMS, and EJ, which exhibited widely different levels of GSTP1 gene expression. However, similar activity of p73CAT in MCF7, VCREMS, and EJ cells suggests that events involving changes in C1 or Sp1 binding do not account for differences in GSTP1 transcriptional rates in these two cell lines. Indeed, despite differences in protein composition, similar DNA binding affinities for the C1 complexes in MCF7 and VCREMS cells have been observed(1) . Furthermore, the data presented here show no significant differences in the GSTP1 promoter binding characteristics of Sp1 in these three cell lines.
Therefore, in terms of constitutively elevated expression of the GSTP1 gene, a change in the relative binding affinities of the Sp1 and C1 complexes for the GSTP1 promoter does not appear to be the primary mechanism responsible for increasing GSTP1 mRNA levels. Indeed, these data strongly indicate that Sp1 is principally involved in maintaining basal levels of GSTP1 transcription but not cell-specific differences in GSTP1 gene expression, because changes in steady state GSTP1 mRNA levels do not correlate with changes in association of Sp1 with the GSTP1 promoter.
The lack of Sp1 involvement in regulating cell-specific expression of GSTP1 is particularly interesting with respect to the multidrug-resistant VCREMS cell line. As shown for a number of other cell lines selected for resistance to anticancer drugs(10, 59, 60) , development of resistance in VCREMS cells correlated with an increase in GSTP1 gene expression levels(1, 36) . Moreover, we have reported that transcriptional activation of the GSTP1 promoter in VCREMS cells accounts for the elevated GSTP1 mRNA and protein levels relative to the parental MCF7 cell line (1) .
In this regard, Borellini et al.(61) have previously shown an increase in Sp1 levels and DNA binding activity in HL60 leukemia cells made resistant to adriamycin. Indeed, these authors speculated that augmented expression and DNA binding activity of Sp1 may account for the increased transcription of genes associated with the multidrug resistance phenotype such as P-glycoprotein, whose promoter contains potential Sp1 binding sites.
VCREMS cells, which were selected for resistance to vincristine but are also cross-resistant to adriamycin, exhibit increased expression of P-glycoprotein as well as GSTP1(36) . Clearly, in these cells, the DNA binding activity of Sp1 was not increased relative to the parental MCF7 cells and cannot therefore explain the observed changes in gene expression.
All evidence to date suggests that the negative regulatory element located between nucleotides -105 and -86 (1) is the critically important control region for defining cell-specific differences in the constitutive level of GSTP1 transcription. In this regard, these present data have clearly shown that repressor activity in MCF7 cells was retained even in the absence of Sp1 binding. Therefore, Sp1 does not appear to be involved in regulating the suppressive effects of the GSTP1 transcriptional repressor. This evidence supports the hypothesis that Sp1 is primarily involved in regulating basal activity of the GSTP1 promoter.
Although these studies have indicated that Sp1 is not involved in determining cell-specific differences in the constitutive level of GSTP1 gene expression, our data do not exclude the possibility that changes in Sp1 binding to the GSTP1 promoter may be important in mediating transient alterations in GSTP1 transcription. In this regard, our studies have indicated that only one of the two potential Sp1 binding sites was preferentially utilized in three different cell lines. However, occupation of multiple GC boxes has been shown to synergistically activate transcription(62) . As stated above, the major function of GSTP1 inside the cell is to provide a detoxification mechanism in its role as an important drug metabolizing enzyme. Therefore, it is intriguing to perceive an involvement for the proximal Sp1 element in the transient induction of GSTP1 transcription in response to xenobiotics.
In summary, the data presented in this report have highlighted an absolute requirement for Sp1 in maintaining activity of the GSTP1 promoter. Moreover, our results have provided strong evidence that Sp1 is principally involved in regulating basal transcription of the GSTP1 gene but does not appear to mediate directly the different steady state levels of GSTP1 mRNA in MCF7, VCREMS, and EJ cells.
However, it is interesting to note that recent developments have characterized several other transcription factors that can bind to the GC-rich Sp1 binding motif. Evidence suggests that these regulatory proteins can compete for this promoter element to either potentiate (e.g. EGR-1(63) ) or repress (e.g. Sp3(64) ) Sp1-mediated transcriptional activation. Therefore, further work is required to determine whether similar control mechanisms can modulate GSTP1 gene expression in a coordinated stress response to dramatic but transient changes in the intracellular environment.