(Received for publication, June 20, 1995; and in revised form, September 5, 1995)
From the
The ubiquitous upstream stimulatory factor (USF) transcription factors encoded by two distinct genes (USF1 and USF2) exist under the form of various dimers able to bind E-boxes. We report the molecular cloning and functional characterization of USF2 isoforms, corresponding to a 44-kDa subunit, USF2a, and a new 38-kDa subunit, USF2b, generated by differential splicing. Using specific anti-USF antibodies, we define the different binding complexes in various nuclear extracts. In vivo, the USF1/USF2a heterodimer represents over 66% of the USF binding activity whereas the USF1 and USF2a homodimers represent less than 10%, which strongly suggests an in vivo preferential association in heterodimers. In particular, an USF1/USF2b heterodimer accounted for almost 15% of the USF species in some cells. The preferential heterodimerization of USF subunits was reproduced ex vivo, while the in vitro association of cotranslated subunits, or recombinant USF proteins, appeared to be random. In transiently transfected HeLa or hepatoma cells, USF2a and USF1 homodimers transactivated a minimal promoter with similar efficiency, whereas USF2b, which lacks an internal 67-amino acid domain, was a poor transactivator. Additionally, USF2b was as efficient as USF1 and USF2a homodimers in transactivating the liver-specific pyruvate kinase gene promoter.
Upstream stimulatory factor (USF)()/major late
transcription factor was initially identified from HeLa cell nuclei and
was shown to be necessary to stimulate transcription from the
adenovirus major late promoter (MLP) through the core sequence
CACGTG(1, 2, 3, 4) . Interestingly,
USF proteins, while being ubiquitously expressed, have been involved in
the expression of several tissue-specific or developmentally regulated
genes (reviewed in (5) ) including for the most recent reports:
the
A-crystallin(6) , myosin light-chain 2(7) ,
C/EBP
(8) , and cyclin D1 (9) genes. More
intriguing is the involvement of USF in the signal transduction through
TGF
1 (10) and in the metabolic regulation of two
glucose-controlled genes: the liver type pyruvate kinase (L-PK) and spot 14 genes(11, 12, 13) .
Purification of USF activity from HeLa cells has revealed the presence of an heterogeneous complex composed of two polypeptides with apparent molecular masses of 43 and 44 kDa, referred to as USF1 and USF2, respectively(14, 15) . USF was first cloned as a human cDNA corresponding to the 43-kDa form(16) , and further characterized in Xenopus and sea urchin(17, 18) . Later, the complete murine and partial human USF2 cDNA isoforms were reported(15, 19) . At last, both USF1 and USF2 genes were localized on murine chromosomes and the cloning of USF2 gene was recently reported (5, 20) .
An attractive
biological feature of regulatory proteins such as transcriptional
factors is their ability to mediate protein-protein interactions by a
modular structure through DNA binding/dimerization motifs(21) .
USF proteins belong to the class of b-HLH-ZIP transcription factors
including the nuclear mammalian proteins Myc, Max (22) ,
Mad(23) , Mxi1(24) , AP4(25) ,
TFEB(26) , TFE3(27) , MiTF(28, 29) ,
and ADD1(30) . Some are involved in the balance between cell
proliferation, apoptosis, and/or differentiation such as Max, Mad, and
Mxi regulating Myc functions, or such as MiTF and ADD1 expressed,
respectively, during cell determination of melanocytes and
differentiation of adipose lineage. Indeed, numerous cellular functions
are supported by the interplay of heterodimerization
processes(27, 31) . The HLH proteins generally bind a
cognate DNA sequence termed E-box (CANNTG) as dimers and are referred
to as classes A, B, and C according to the nature of the two variable
NN nucleotides(32) . These transcription factors contain
relatively small domains that mediate DNA binding and dimerization. Two
conserved structural motifs responsible for dimerization have been
characterized (33) and functionally investigated by
three-dimensional structure analysis(34) : the helix-loop-helix
domain (HLH), which consists of two -helices separated by an
extended loop of variable length and sequence, and a leucine zipper
(ZIP), which contains a leucine at every 7th residue forming a coiled
coil with a ZIP in a second monomer. These two motifs are generally
carboxyl-terminal to the stretches of basic amino acids required for
DNA binding.
In the past few years, alternative pre-mRNA splicing has emerged as a main mechanism for regulating gene expression and generating isoform diversity(35) . Indeed, hetero-oligomerization of transacting factors also present in various isoforms provided a major regulatory mechanism of gene transcription(36) . A paradigm of this mechanism is the novel diversity of USF proteins family revealed by our present study. Therefore, we wondered about the respective role of the 43- and 44-kDa polypeptides, and eventually of other yet unidentified isoforms, in the USF activity involved in so diverse cellular functions. First, we report here the molecular cloning and functional characterization of the full-length human 44-kDa polypeptide USF2a and a new 38-kDa subunit USF2b. Second, in order to characterize the nature of the USF complexes in various cell lines and tissue extracts, we have developed monospecific polyclonal antibodies against different domains of the USF1 and USF2 proteins. These antibodies revealed to be powerful tools toward the definition of the various USF binding complexes. We have found that USF1/USF2a heterodimer is predominant in all extracts but some variations between the relative proportion of each species is observed in different cells and tissues. In particular, more USF2b-containing species is detected in some erythroid cell extracts. Heterodimerization with USF proteins seems to be strictly restricted to USF family members; however, we have found that, in vivo, subunit association is biased toward heterodimerization, while a pattern of random dimer formation could only be observed in vitro. Finally, we have shown that, while USF1 and USF2a behave similarly on different promoters, USF2b potential transactivity could depend on the promoter context.
Sequences of the oligonucleotides were as follows, for USF2a cloning:
and, for semiquantitative analyses of USF2 isoforms (in Fig. 4),
Figure 4:
Cell-type variations of USF2 message
splicing. A, RT-PCR were conducted with total RNAs from human
cells using primers 1 and 3. The probe fragment used to hybridize the
subsequent blot was amplify using primers 2 and 3 and the plasmid p9
(hUSF2a) as template. To ensure semiquantitative analysis, the
amplification process was maintained in exponential phase. Respective
sizes of predicted RT-PCR products are indicated. B, amplified
fragments were electrophoresed in a polyacrylamide gel. The reaction
specificity was checked using template plasmids p9 and p2 (containing
hUSF2a and hUSF2b cDNAs, respectively) as positive control and a
mixture of all non-reverse-transcribed cellular RNAs as a negative
control (ARN mix). Control of the amount of total cDNA present
in each lane was checked using -actin-specific primers. The gel
was blotted and hybridized with the common USF2 150-bp probe and a
-actin probe. Total RNAs were from rat liver (Li), human
HepG2 hepatoma cells (Hep), HeLa cells (HeLa), human
megakaryoblastic cells (UT7), and human lymphoblastoid
Epstein-Barr virus-transformed cells (Ly).
Figure 1:
Molecular cloning and primary sequences
of human USF2 cDNAs. A, schematic alignment of the three human
USF2 cDNA clones. p9H and p2 clones were isolated from a human
liver library using the rat USF2-specific 267-bp probe. p9 clone was
obtained by RT-PCR strategy using the nucleotide primers indicated by thick horizontal arrows. Similar shading indicates
regions of identical sequence, and rectangular box delimited
the optional domains. Broken and straight (t) vertical arrows are located at initiation
and termination codons, respectively. Protein sizes predicted from the
DNA sequence are written on the right. E/N, EcoRI/NotI adaptator; Nc, NcoI; B, BamHI; S, SacI. B,
nucleotide and deduced amino acid sequences of USF2a (p9) and USF2b
(p2) cDNAs. The internal 201-bp optional sequence is boxed. Brackets delimit the 24-bp fragment encoding the helix 2 of
HLH domain missing in p9
H clone. Numbers on the left indicate nucleodides and those on the right amino acids.
The putative initiating codons and the termination codon are in bold. The putative polyadenylation signal is underlined. Open circles indicate the 7 amino acids
differing between human and mouse proteins.
The USF2a and USF2b cDNA were subcloned in the prokaryotic T7-based expression vector pET-28a (Novagen). Recombinant USF2a and USF2b proteins expressed in BL21(DE3)pLysS cells were purified according to manufacturer's instructions (Novagen). Recombinant USF1 protein expressed in BL21(DE3)pLysS cells from pET3d USF43 vector was purified by ammonium sulfate precipitation(40) .
Heterodimeric complexes between USF proteins were obtained by cotranslation of approximately equal amount of RNA templates or by mixing different amounts of recombinant proteins under denaturing conditions followed by an extensive dialysis.
Electrophoretic mobility shift assays (EMSA)
were performed with either cell-free translation proteins, nuclear
extracts, whole cell extracts or protein extracts used in CAT assays.
The DNA binding reactions were performed as described previously (44) at 4 °C in binding buffer (20 mM Hepes, pH
7.6, 50 mM KCl, 50 mM NaCl, 5 mM
MgCl, 4 mM spermidine, 0.2 mM EDTA, 5
mM dithiothreitol, 4% (w/v) Ficoll) in the presence of
1-2 µg of nuclear extracts or 1-3 µl of
reticulocyte lysate, or 15 µg of whole cell extract and 2.5 µg
of poly(dI-dC) and 0.1-0.5 ng of end-labeled USE/MLP
oligonucleotide(45) . For gel retardation assays with
recombinant proteins, DNA binding reactions were performed in the
presence of 20-40 ng of purified USF proteins, 100 ng of
poly(dI-dC), 1 µl of preimmune rabbit antiserum, and 0.1-0.5
ng of end-labeled MLP oligonucleotide. For competition assays, 5 and 10
ng of USE/MLP probe were used as specific competitor and 10 ng of NF-Y
probe as unrelated competitor (44) and, for supershift assays,
1 µl of polyclonal antisera was included in the binding reactions.
The quantification of the DNA binding complexes was monitored using a
PhosphorImager and analyzed using ImageQuant (Molecular Dynamics).
As outlined in Fig. 1A, the clone
p9H appeared still as a partial cDNA lacking an initiating
methionine codon. In contrast, p2 clone was probably a full-length
cDNA, containing a 5` untranslated region (109 bp) and an open reading
frame of 279 amino acids starting at a putative ATG initiation codon.
Several lines of evidence indicate that the p9
H and p2 clones
correspond to two different transcripts from the same gene, generated
by differential splicing. (i) p9
H and p2 clones differed from each
other only by their 5` ends and by the length of the poly(A) tail. (ii)
clone p9
H included an internal 201-bp sequence (67 amino acids)
that was absent from p2. From 12 RT-PCR products amplified from human
liver mRNA using two primers located at the two ends of the p2 clone,
four were found identical to p2 and eight contained the expected
complete open reading frame of 346 residues attributed to the complete
p9 sequence (see Fig. 1A). Thus, p2 differs from p9 by
the alternative splicing out of 201 bp (boxed in Fig. 1B). (iii) examination of clone p9
H sequence
pointed out a second splicing pattern. Indeed, a 24-bp fragment
encoding the first 8 residues of the second helix of the HLH domain was
missing. Intriguingly, the remaining reading frame was not modified so
that the putative polypeptide exhibited a partially deleted HLH domain
but did contain an intact leucine zipper domain. This deleted
transcript is naturally generated since RT-PCR strategy allowed us to
amplify helix 2-deleted cDNAs, using sense oligonucleotide primers
overlapping the deletion point and antisense primers derived from the
3` end of the translated region. However, this isoform was very poorly
represented in human cells and was virtually undetectable in rat cells
(data not shown). We termed the cDNA clones p9
H, p9, and p2,
respectively, hUSF2a
H, hUSF2a, and hUSF2b (right side in Fig. 1, A and B). Finally, sequence analysis
of genomic clones of murine USF2 gene indicates that the optional
201-bp region missing in USF2b cDNA lay within the fourth
exon(5, 20) , while the
H isoform is generated by
an additional splicing event within the ninth exon, i.e. the
use of a cryptic splicing acceptor site located 24 bp downstream from
the normal splice site(5) . The in vitro translated
protein hUSF2a
H was unable to bind DNA in band shift assay,
probably reflecting its incapacity to dimerize (data not shown).
Figure 2:
Identification of homodimeric and
heterodimeric USF complexes. A, schematic representation of
the human USF proteins: major late transcription factor/hUSF1, the two
isoforms hUSF2a and hUSF2b, and two truncated USF species termed
mini-USF1 and mini-USF2. The alignment of the conserved COOH-terminal
domains allows us to assign the percentage of identity between
conserved domains visualized as boxes. Amino acids are numbered at the top or at the bottom of each
sequence. Arrows define the sequences encoding specific
domains used to raise rabbit polyclonal antibodies. B, EMSA
was performed by using the radiolabeled MLP oligonucleotide presented
under the figure, in presence of either rat liver nuclear extracts (lanes 4-7 and 12-15) or a programmed
reticulocyte lysate: lanes 2 and 3 correspond to
cotranslation of in vitro transcribed USF2a (U2a) and
USF2b (U2b), or USF1 (U1) and USF2b (U2b). Lanes 8 and 9 correspond to the cotranslation of
mini-USF1 (U1) and either USF1 (U1) or USF2a (U2a); lanes 10 and 11 correspond to the
cotranslation of mini-USF2a (
U2) and either USF1 (U1) or USF2a (U2a); lane 1 corresponds to
unprogrammed lysate. Depletion of the complexes was achieved by adding
1 µl of specific immunesera (IgG) in the reaction mixture.
Identification of the USF/DNA binding complexes is indicated alongside
the figure. Complexes A and B correspond to two
faster migrating minor heterodimers observed with liver nuclear
extracts. A would correspond to USF2a/
U1 and B to USF1/
U2 heterodimers, respectively. The faint complexes
are also indicated as open symbols: circle (U2a/U2a), square (U1/U1), and triangle (U1/U2b) in the
figure.
Figure 5: Oligomerization properties of USF1 and USF2 isoforms in vitro and in vivo. A, recombinant USF proteins were mixed in various ratio under denaturing conditions and the complexes formed after removal of the denaturant by dialysis, were visualized by EMSA using the MLP radiolabeled probe. B, in vitro cotranslated USF protein complexes were analyzed by EMSA using the MLP-radioabeled probe. Cotranslation products were incubated with anti-USF antibodies to discriminate homodimeric and heterodimeric USF complexes. C, EMSA analysis of ectopic USF complexes binding to MLP probe in HeLa cells cotransfected with fixed amounts of pCMV-U2a (4 µg) and pCMV-U1 (6 µg) and increasing amounts of pCMV-U2b. Antibodies anti-USF1, IgG M (pCMV-U2a/U2b cotransfections), or anti-USF2a, IgG O (pCMV-U1/U2b cotransfections), were systematically added in reaction mixtures to deplete the whole cell extracts of endogenous USF binding activity. The percentage of each ectopic USF complex (arrows) is indicated. The percentages corresponding to approximately equal expression of each partner are boxed. Excess of unlabeled MLP oligonucleotide was used in a competition assay in lane C. The asterisk indicates nonspecific protein complex.
Therefore, our different antibodies appeared to be suitable reagents for identifying the nature of the different USF complexes detected in various cells and tissues. Fig. 2B shows that the major complex detected in liver nuclear extract was displaced by both anti-USF1 (IgG M) and anti-USF2 (IgG O and G) antibodies, demonstrating that it corresponds to a USF1/USF2a heterodimer (compare lanes 4-6 to lane 7). After having supershifted this heterodimer, three faint bands, masked by the major species, could be clearly resolved. Indeed, the slow migrating band was displaced by anti-USF2 (IgG G and IgG O) but not anti-USF1 (IgG M) antibodies and could be identified as USF2a homodimer (lane 6). The faster migrating, USF1 homodimer, displaced by IgG M but neither IgG G nor O, was also revealed (lane 5). Finally, as the very faint band slightly below the USF1 homodimer was displaced by IgG M and IgG G, but not IgG O, it could be identified as USF1/USF2b heterodimer (lane 4). These identifications were consistent with the electrophoretic mobility of these different species compared to that of the various dimeric forms resulting from in vitro cotranslation of either USF2a and USF2b mRNAs (lane 2) or USF1 and USF2b mRNAs (lane 3), as shown by the position of USF1 and USF2a homodimers and USF1/USF2b heterodimers indicated on the left of Fig. 2B.
The exact composition of the two
faster migrating complexes A and B was not clear. They could be
considered as heterodimeric complexes between USF1 (complex B) or USF2a
(complex A) full-length subunits and shorter partners. The supershifted
complexes with anti-USF1 ZIP antibodies, IgG [4] (lane
13), and anti-USF2 ZIP antibodies, IgG Z (lane 15), and
the comigration with in vitro cotranslated proteins complexes (lanes 8-11) indicated the presence in these complexes
of NH truncated USF proteins. These latter USF proteins
were described as mini-USF(15) . In vitro treatments
of full-length USFs by the calpain protease, which cleaves the
NH
-terminal ends, gave rise to faster migrating forms (data
not shown). This result strongly suggests that mini-USFs are translated
by the use of internal methionines. Finally, complex A can be defined
as a USF2a/mini-USF1 heterodimer (compare lanes 6 and 9) and B as a USF1/mini-USF2 heterodimer (compare lanes 5 and 10).
Figure 3:
Analysis of cell-specific USF DNA binding
patterns. A, nuclear extracts were from rat tissues (adult
liver and fetal liver), human cells (hepatoma cells (HepG2),
megakaryoblastic cells (UT7), fibroblasts (HeLa)), and mouse hepatoma
cells (AT3F). EMSA were carried out by using the radiolabeled MLP
oligonucleotide. Five and 10 ng of specific unlabeled oligonucleotide
MLP, and 10 ng of unrelated oligonucleotide NF-Y(44) , were
added in competition experiments (lanes MLP and NF-Y). Alongside the figure are indicated the position of the
heterodimeric USF1/USF2a and USF1/USF2b complexes. A and B correspond to USF2a/U1 and USF1/
U2 heterodimers,
respectively. B, representation of the various USF DNA binding
complexes in different tissues and cells. EMSA was performed as
described above and selective depletion of the complexes was realized
by adding specific anti-USF antibodies (IgG) to the binding reactions.
IgG M is specific to USF1 protein, IgG G specific to USF2a and USF2b
proteins, and IgG O specific to USF2a protein. Lanes(-),
naive serum. Complexes revealed are mentioned alongside the figure. The asterisks indicate nonspecific protein
complexes.
To test this hypothesis, we used a semiquantitative RT-PCR strategy illustrated in Fig. 4A. Analysis of PCR products on cDNAs from different cell lines and tissues showed the two predicted USF2 fragments of similar intensities (Fig. 4B). Northern blot analysis suggested that the USF2 gene was expressed at a similar level in all tested cells (data not shown), even though the ratio between USF2a and USF2b-specific amplified fragments varied significantly. Indeed, USF2b mature messenger seems to be more accumulated in HeLa and UT7 cells than in adult liver, hepatoma HepG2, and lymphoblastic cells. From these data, we infer that different cellular contents in USF1/USF2b complex might occur from a regulation of alternative splicing of USF2 precursor mRNA.
In order to quantify the different USF dimers according to the gel shift patterns, we checked that these complexes exhibited similar binding activity. We therefore compared the patterns using different oligonucleotide probes of decreasing affinity for USF proteins (data not presented). All complexes generated with either crude liver extracts or the three recombinant USF proteins were observed to display similar affinities for each of the probes. Thus, these results indicate that USF homo- and heterodimers shared similar DNA binding properties in vitro, and that binding activities of the various heterodimeric isoforms present in crude nuclear extracts are not significantly different.
As heterodimeric association
seems to be preferred in vivo according to our results, we
then tested this preference in vitro by using recombinant USF
and cell-free translated proteins in EMSA. When recombinant USF
proteins were mixed, dissociated under denaturant conditions, and then
reassociated by removal of the denaturant, we observed that the
USF1/USF2 heterodimers complexes were formed at random (Fig. 5A). A 1:2:1 ratio was observed for the different
complexes formed. When USF proteins were cotranslated in vitro using equimolar ratios of USF1 and USF2a mRNAs, we still obtained
a random dimerization pattern (Fig. 5B). The use of
specific antibodies allowed us to discriminate homodimers from
heterodimers of intermediate electrophoretic mobility. Furthermore, we
did not observe any subunit exchange incubating homodimeric recombinant
USF proteins in ionic strength conditions performed in nuclear extract
preparation (0.42 M NaCl extraction and 50%
(NH)
SO
precipitation). These
results indicate that homo- and heterodimerization of the USF1 and USF2
isoforms are similar in vitro, and suggest that preferential
association between USF1 and USF2 genes products is specific feature of in vivo conditions (Table 1).
To confirm this hypothesis, fixed amounts of USF2a or USF1 expression vectors were cotransfected in HeLa cells with increasing amounts of USF2b. Oligomerization properties of the ectopic USF proteins were analyzed by EMSA, depleting the whole cell extracts from endogenous USFs with anti-USF1 or anti-USF2a antibodies (Fig. 5C), and the different protein complexes visualized were quantified. When ectopic USF2a versus USF2b, and USF1 versus USF2b were produced in comparable amounts (boxed in Fig. 5C), the dimer distribution displayed very different patterns. Indeed, whereas USF2a and USF2b were able to associate in a 1:2:1 distribution, which could be explained considering that each monomer had no preference for a dimerization partner, USF1/USF2b heterodimeric association was clearly favored over homodimerization. It appears from these results that in vitro as well as in vivo, all USF family members are able to form heterodimers with each other. However, in vivo but not in vitro, USF2 isoforms preferentially heterodimerized with USF1.
Figure 6: Analysis of the USF1 and USF2 isoforms transacting potential in HeLa cells. A, schematic representation of the CAT reporter plasmids containing various repeats of the USE-MLP site upstream from the L-type pyruvate kinase minimal promoter and of the USF expression plasmids driven by the CMV promoter. B, transient transfection assays in HeLa cells of the reporter CAT constructs in presence of USF1 and USF2a expression vectors. HeLa cells were cotransfected by calcium phosphate procedure with 5 µg of indicated CAT reporter plasmids and 2 or 0.5 µg of expression plasmids encoding, respectively, USF1 and USF2a (pCMV-U1 and pCMV-U2a) or 2 µg of control plasmid pCMV. C, the transacting effects of the USF1 and USF2 expression vectors are compared. 5 µg of the (MLP)4-54PKCAT plasmid were cotransfected with various amounts of either the empty or the USF-containing expression vectors as indicated (in µg) under the picture. All values represent the means of two or three independent experiments in duplicate. EMSA were performed with the MLP probe and the same whole cell protein extracts used in CAT assays. Anti-USF1 (IgG M) and anti-USF2 (IgG G) antibodies were added in reaction mixtures to deplete the extracts of endogenous USF1/USF2a binding activity. The asterisk indicates nonspecific protein complex.
As shown at the top of Fig. 6C, cotransfections of (MLP)4-54PKCAT with USF1 or USF2a expression vectors resulted in a very efficient stimulation of CAT activity while USF2b plasmid stimulated poorly. As estimated from EMSA using the same extract than in the CAT assay, the extent of activation essentially depended on the amount of protein produced (Fig. 6C, bottom). The maximum of stimulation occurred at 2, 0.5, and 1 µg of USF1, USF2a, and USF2b expression vectors transfected, respectively. Under these conditions, USF1, USF2a, and USF2b, respectively, resulted in 23-, 18-, and 6-fold transcription stimulation relative to the endogenous USF activity revealed by the empty expression vector. We conclude from these experiments that USF2 gene products have different effects on transcription modulation through the USE-MLP site. USF2a is a transcription activator as efficient as USF1, while the USF2b isoform is at least 3 times less active under the same experimental conditions. This result indicates that the 67-amino acid region of USF2a, missing from USF2b, may be involved in the transcriptional activation.
Next, we compared the respective ability of USF isoforms to modulate the activity of the L-PK promoter that has been shown previously to be dietary controlled via a USF-dependent glucose responsive element, GlRE, consisting in two E-boxes (element L4)(11, 12, 13, 47) . The trans-modulating activity mediated by each USF expression plasmid was tested by transient cotransfections in mouse hepatoma AT3F cells using a CAT reporter gene driven by the -183 L-PK promoter (Fig. 7A). Surprisingly, as shown in Fig. 7B (left side), the ectopic production of all USF isoforms even USF2b resulted in a similar 4-5-fold stimulation of the CAT activity relative to the endogenous activity observed with the empty expression vector. To know whether this unexpected USF2b activity was dependent on the L-PK promoter context or might be assigned to the L4 element itself, we performed cotransfections with a reporter gene carrying four copies of the L4 element placed upstream from the -54PK minimal promoter ((L4)4-54PK, Fig. 7A). As shown in Fig. 7B (right side), overexpression of USF1 or USF2a stimulated transcription about 60-fold while USF2b resulted in a 18-fold stimulation relative to the endogenous activity for equivalent DNA binding activity checked by EMSA. These results obtained with the (L4)4-54PK promoter in hepatoma cells confirm those obtained with (MLP)4-54PK promoter in HeLa cells, namely that USF2b is at least 3 times less active than USF1 and USF2a on a minimal promoter depending on oligomerized USF binding sites. However, in the context of the natural -183 L-PK promoter in which the USF binding site L4 is contiguous to an HNF4 binding site(45, 47) , USF2b exhibited a transactivating potential similar to USF1 and USF2a.
Figure 7: Transacting effects of USF1 and USF2 isoforms on the glucose-responsive element (GIRE) of the L-type pyruvate kinase promoter in mouse AT3F hepatoma cells cultured without glucose. A, schematic representation of the CAT reporter plasmids containing either the -183 L-PK promoter or four copies of the L4 element located upstream from the L-type pyruvate kinase minimal promoter, and of the USF expression plasmids driven by the CMV promoter. Boxes L1-L3 bind HNF1, NF1, and HNF4 proteins respectively(45) . B, transient transfection assays in AT3F cells of the reporter CAT constructs in the presence of USFs expression vectors. Comparison between the transacting effects of the USF1 and USF2 expression vectors. 5 µg of the -183PKCAT or of the (L4)4-54PKCAT plasmids were cotransfected with indicated amounts of either the empty or the USF-containing expression vectors. All values represent the means of at least three independent experiments in duplicate. EMSA were performed with the MLP probe and the same whole cell protein extracts used in CAT assays. Anti-USF1 (IgG M) and anti-USF2 (IgG G) antibodies were added in reaction mixtures to deplete the extracts of endogenous USF1/USF2a binding activity. The asterisk indicates nonspecific protein complex.
USF proteins are ubiquitous transcription factors that were initially considered playing a probable role in housekeeping functions (51) . Furthermore, these USF proteins have also been recognized as important players in the regulation of tissue-specific genes(52, 53, 54, 55) and recently in the specific response of genes to external modulators (10) , as glucose(11, 12, 13) . So far, how such a type of ubiquitous factor can be involved in highly regulated transcriptional phenomena remains unknown. Therefore, it seems of prime interest to be able to accurately identify and quantify the various USF isoforms in different tissues or cells, and to determine their transacting potential.
USF DNA binding activity in HeLa cells was
initially described as a complex consisting of two polypeptides of 43
and 44 kDa(4) . Various alternatively spliced USF transcripts
were previously described resulting in non-coding
RNAs(14, 15, 16) . In this paper, an
additional level of complexity is described since we show that the
human USF2 gene generates, by differential splicing, different mRNAs
encoding polypeptides with respective apparent molecular masses of 44
kDa (USF2a) and 38 kDa (USF2b). These two isoforms share perfect
identity in an extended COOH-terminal region of 203 amino acids,
encompassing the b-HLH-ZIP motifs, but vary in the organization of
their NH-terminal domains (Fig. 2A).
Indeed, USF2b lacks an internal 67-amino acid domain present in USF2a.
Analysis of murine genomic clones showed that the USF2b messenger
occurs by the splicing out of the fourth exon in primary transcripts (5, 20) . In addition, USF2a
H, an additional
spliced form, although containing an intact leucine zipper domain,
lacks the second helix of the HLH motif due to a 24-bp in-frame
deletion occurring by the use of a cryptic splicing site within the
ninth exon(5) . As suggested by RT-PCR analysis (data not
shown), this latest splicing event is poorly efficient in human and
virtually undetectable in rat cells. The biological relevance of the
H isoform also remains unclear.
As an effort to characterize
the various USF DNA-binding complexes, we have developed various
polyclonal antibodies against different regions of the USF1 and USF2
proteins. Our immunochemical analyses in nuclear extracts from various
cell lines and tissues revealed that the major USF species detected was
a USF1/USF2a heterodimer, corresponding to the species composed of the
43- and 44-kDa subunits. In addition, minor forms whose abundance
varies in different cell types and tissues could be detected. A
heterodimer between USF1 and USF2b subunits was especially abundant in
some cultured erythroid cell lines, where it reached 15% of the total
binding activity. Consistent with ubiquitous distribution, RT-PCR and
EMSA analyses showed that USF2a and USF2b isoforms are coexpressed in
every cell types tested with slight cell type preferences concerning
USF2b expression. Indeed, we observed a modulation in the amount of
USF1/USF2b binding complex, which is well correlated to the relative
USF2b mRNAs accumulation observed by RT-PCR. Interestingly, the greater
expression of USF2b isoform in UT7 cells and fetal liver seems to be a
common feature of the erythroid cell type. It was previously observed
that relative abundance of USF1 (43 kDa) and USF2 (44 kDa) homo- and
heterodimers seemed to vary among different cell types(15) . We
report here the presence of a novel USF binding complex occurring by a
quantitative modulation of the USF2 pre-mRNA splicing. Whether this
modulation corresponds to possible tissue-specific regulatory functions
remains to be carefully investigated. Two low molecular weight
complexes were also detected in liver-specific cells, i.e. nuclear extracts from liver and cultured mouse hepatoma AT3F
cells, which could be identified as heterodimers between full-length
USF1 or USF2a proteins on the one hand, mini-USF2a or -USF1 on
the other. Mini-USF proteins are deleted from their NH termini containing the transactivation domains and are likely to
result from the use of internal translation initiators as proposed by
Sirito et al.(15) . Indeed, we observed that similar
NH
-truncated forms resulting from calpain digestion (56) migrated faster than these mini-USFs (data not shown).
In rat liver nuclear extracts as in all cells tested, USF binding activity corresponds mainly to four different complexes as presented by our gel shift experiments. In vivo, most USF species are heterodimers between USF1 and USF2a isoforms, with an obvious under-representation of homodimers. The fact that USF1 and USF2 gene products preferentially heterodimerize was quite surprising. In fact, the specificity of association between USF subunits is probably allowed by the dimerization domain itself, which should then dictate the compatibility between the different family members as this is observed with the b-ZIP protein Fos, unable to dimerize with itself, while it forms stable dimers with Jun(57) . The dimerization interfaces of the coiled-coil motif is supposed to play a critical role in the dimerization specificity of b-HLH-ZIP proteins(33) . Interhelical electrostatic interactions between opposite charged residues located in the leucine zippers of b-ZIP and b-HLH-ZIP factors are needed to design specific dimerization partners(57, 58, 59) . However, this mechanism seems unlikely to explain USF1/USF2 preferential dimerization since USF1 and USF2 species cotranslated in a cell-free system or associated after denaturation of recombinant proteins, dimerized randomly to give the exact 1:2:1 dimer distribution. These results indicate that the HLH-ZIP dimerization domains of USF proteins exhibit no particular preference for partners in vitro. However, the in vivo preferential association may be experimentally reconstituted and visualized in EMSA using HeLa whole cell extracts with high levels of USF1 and USF2 obtained by cotransfection, indicating that this phenomenon is strictly dependent on a cellular context. Therefore, the reason why the in vivo association pattern is biased toward USF1/USF2 heterodimers remains rather obscure. A preferential stability of the heterodimers in the intracellular conditions could be a first explanation. In any case, such a stabilization could not be ascribed to an intrinsic higher affinity of the heterodimers for DNA since, at least in vitro, homo- and heterodimers appeared to have the same affinity for the various types of USF binding sites we tested (data not shown). In vivo preferential isoform associations might also be governed by post-translational control mechanisms. Recently, the redox state of b-HLH proteins has been shown to control dimerization and DNA-binding of E2A proteins(60) . A redox control of transcription factor activity has also been demonstrated for Fos and Jun(61) . In the case of USF1 protein, non-reducing conditions were shown to decrease the affinity for DNA recognition motif(62) .
According to earlier in vitro and in vivo studies, the 43-kDa USF1 gene product was supposed to account for all of the transcription stimulation activity present in the 43/44-kDa USF complex purified from Hela cells(49, 50) . Using transfection assays, we demonstrated that the 44-kDa USF2a component is able to activate transcription of a reporter gene driven by either minimal promoters containing four copies of USF binding sites or by a natural USF-dependent promoter, e.g. the -183 L-PK promoter(13) , as efficiently as USF1. However, the 38-kDa USF2b alternative spliced form revealed a promoter-dependent activity. Indeed, in experiments using minimal promoters ((MLP)4-54PK or (L4)4-54PK), we showed that USF2b was a poor transactivator, 3-4 times less active through identical binding sites than USF1 or USF2a, while it stimulated -183 L-PK promoter as efficiently as USF1 or USF2a homodimers. In experiments using minimal promoters, the transacting potential of the three USF variants was not cell type-dependent (HeLa cells or hepatoma cells) and occurred through multimerized high affinity binding sites (MLP-USE of adenovirus, core sequence: CACGTG) as well as through multimerized low affinity binding sites (L4 element of the L-PK gene, core sequence: CACGGGGCACTCCCGTG).
In agreement with a modular
composition of activation domains among USF proteins, previous deletion
experiments had allowed the identification of two activation domains
(one NH-terminal spanning residues 26-39 and a second
spanning residues 105-130) that cooperate in vitro for
full transcriptional activity of USF1 (63) . Consistent with
its stronger activation potential, the NH
-terminal domain
was particularly well conserved among vertebrate USFs (70% homology).
The second is not conserved between USF1 and USF2 proteins, suggesting
that the USF1 and USF2 gene products could interact with different
accessory factors or components of the transcription machinery.
Although further investigations are required to identify USF2
transactivation domains, our findings suggest that the activation
potential of USF2a requires the 67-amino acid insert deleted in USF2b.
Noticeably, the transactivating potential of this alternatively spliced
domain of USF2a seems to depend upon the promoter context. Indeed, its
excision from USF2a, resulting in a USF2b protein that conserves the
putative NH
-terminal transactivating domain, leads to a
strong reduction of the transactivation potential through minimal
promoters ((MLP)4-54PK or (L4)4-54PK) but has little or no
effect in the L-PK promoter context. The involvement of multiple
domains that cooperate to allow fine-tuning of transactivating ability,
has been found in several transcription factors. For instance, three
activator elements (TEI-TEIII) are required for full C/EBP
transcriptional activity and one of them, TEIII, is shown to contain a
negative subdomain, the function of which is controlled depending on
the promoter context(64) . An alternative explanation may be
that the transactivation potential of USF2b isoform mediated through
the L4 motif (18-fold stimulation of (L4)4-54PK construct, Fig. 7B) should be enough to allow the full stimulation
of the -183 L-PK promoter (maximum 5-fold).
There is
increasing evidence that ubiquitously expressed factors can also play
an important role in tissue-restricted expression as well as in highly
controlled cellular functions, as for instance hormonal and dietary
regulations(11, 12, 13) . The mechanisms by
which USF proteins contribute to these specific functions are yet
unclear and may overlay several phenomena. The NH activation domains of USF1 and USF2a are different and therefore
could interact with different transcription factors bound at proximity,
auxiliary factors, co-activators, or general transcription
factors(1, 51, 65, 66, 67) .
Therefore, the various USF dimers could have slightly different
specificities for a number of genes. In particular, diverse proportions
of activatory and inhibitory USF dimers in different tissues and stages
of development could allow a fine tuning of gene expression during
differentiation and transcriptional response to external effectors.
Moreover, a high proportion of USF2b-containing dimers could result in
a down-regulation of USF transactivating activity in some tissues.
Since mini-USF proteins behave as transdominant
inhibitors(13) , their accumulation at a sufficient level in
some cells could also be expected to down-regulate USF activity.
However, although the abundance of USF2b and mini-USF species depends
clearly on the cell types, whether their involvement in total USF
activity is sufficient to play this putative negative regulatory role
remains to be studied. The structural and functional diversities of the
USF family, here defined, should enlighten the way of investigating the
physiological roles of USF proteins.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBank(TM)/EMBL Data Bank with accession number(s) X90823[GenBank]-X90826[GenBank].