(Received for publication, September 19, 1996, and in revised form, December 9, 1996)
From the Institute of Molecular and Cell Biology, National University of Singapore, Singapore 119260
Nuclear factor I (NFI) proteins constitute a family of sequence-specific transcription factors whose functional diversity is generated through transcription from four different genes (NFI-A, NFI-B, NFI-C, and NFI-X), alternative RNA splicing, and protein heterodimerization. Here we describe a naturally truncated isoform, NFI-B3, which is derived from the human NFI-B gene, in addition to characterizing further human NFI-B1 and NFI-B2, two differentially spliced variants previously isolated from hamster and chicken. Although NFI-B1 and NFI-B2 proteins are translated from an 8.7-kilobase message, the mRNA for NFI-B3 has a size of only 1.8 kilobases. The NFI-B3 message originates from the failure to excise the first intron downstream of the exons encoding the DNA binding domain and subsequent processing of this transcript at an intron-internal polyadenylation signal. The translation product includes the proposed DNA binding and dimerization domain and terminates after translation of two additional "intron" encoded codons. In SL-2 cells, which are void of endogenous NFI, NFI-B3 by itself had no effect on transcriptional regulation and failed to bind DNA. Coexpression of NFI-B3 with other isoforms of the NFI-B, -C, and -X family, however, led to a strong reduction of transcriptional activation compared with the expression of these factors alone. Gel shift analysis indicated that NFI-B3 disrupts the function of other NFI proteins by reducing their DNA binding activity by heterodimer formation. The efficiency of NFI-B3 heterodimers to bind to DNA correlated with the degree of transcriptional repression. The abundance of NFI-B transcripts varied significantly between different human cell lines and tissues, suggesting a potential involvement of these factors in the complex mechanisms that generate cell type specificity.
Nuclear factor I (NFI)1 comprises a family of sequence-specific DNA-binding proteins that bind to the palindromic sequence TGGC/A(N)5GCCA or with lower affinity to the half-palindrome. NFI proteins bind their recognition sequence as homo- or heterodimers that are already formed in solution (1, 2). Initially, NFI was identified as a factor required for the replication of adenovirus DNA (3-5) but has since been recognized as a potent transcriptional regulator of many viral (6-9) and cellular genes (10, 11). Molecular cloning and sequence analysis of cDNAs from different animal species (12-18) led to the identification of four different genes: NFI-A, NFI-B, NFI-C, also referred to as NFI/CTF, and NFI-X. The diversity of NFI proteins is increased further by differential RNA splicing (12, 16). The highly conserved 189-amino acid NH2-terminal region of NFI is required for DNA binding and dimerization (1, 2). The COOH-terminal transactivation domain diverges extensively, both among factors derived from different genes as well as between different spliced isoforms derived from the same gene. A high proportion of proline residues is common to all of them, suggesting that transcriptional activation occurs through proline-rich sequences (1). The proline-rich region of NFI/CTF seems dispensable for transcriptional activation in yeast, however (19).
The existence of a number of structurally different NFI proteins and
their differential expression as well as the involvement of NFI binding
sites in cell type-specific gene expression (20-24) suggests that the
individual isoforms may have distinct functions. NFI/CTF isoforms,
first isolated from human HeLa epithelial cells and later from pig
liver, function as transcriptional activators with a broad range of
transactivation potential in different cellular environments (1, 19,
25). We and others have shown recently that differentially spliced
isoforms from the human (24) and mouse (26) NFI-X genes can function as
transcriptional repressors, and some of these isoforms are expressed
differentially in different human tissues (24, 27). A novel repressor
domain, which inhibits DNA binding in vitro, was also
characterized for Xenopus laevis NFI-X isoforms (28). The
underlying mechanism for the varying function of the different isoforms
is not clearly understood. It has been demonstrated that the
transcriptional activation of NFI/CTF-1 in yeast depends on a sequence
motif related to the heptapeptide repeat of the COOH-terminal domain of
RNA polymerase II (29, 30). Another member of the NFI-C family which
lacks this domain was found to be an even more potent activator,
however (25). The activity of individual NFI isoforms may also be
modulated by other factors as observed with the transforming growth
factor- responsive region, located in the proline-rich activation
domain of NFI/CTF-1 (31).
Our earlier studies indicated that NFI plays a crucial role in the epithelial cell type-specific transcription of human papillomaviruses (9, 32, 33). Differences in the gel shift pattern of NFI proteins between human epithelial cells, where the viral enhancer is active, and human fibroblast cells, which do not support viral transcription, suggested that fibroblast cells express a different subset of NFI proteins than do epithelial cells, which express mainly factors of the NFI-C family (9, 12). The screening of a human fibroblast library led to the isolation of NFI-X1, an isoform that represses the activity of NFI/CTF by the formation of heterodimers (24). In addition to different spliced isoforms of the NFI-X family, we also isolated a novel clone of the NFI-B family from human fibroblast cells. Two spliced isoforms of the NFI-B gene, NFI-B1 and NFI-B2, have been isolated before from chicken and hamster liver cells (13, 16), but no human homologs have been characterized so far.
Here we describe a novel NFI-B form, NFI-B3, and its expression pattern and functional characteristics. We show that NFI-B3 is encoded on a 1.8-kb mRNA, which is generated by use of a premature polyadenylation site located in an intron. In contrast, NFI-B1 and NFI-B2 are generated by alternative splicing, leading to an 8.7-kb message. NFI-B3 is a truncated protein that lacks the transcriptional activation domain. It cannot bind to DNA as a homodimer or as a heterodimer with NFI-B2, but it binds in the form of a heterodimer with isoforms of the NFI-C and NFI-X family. For functional analysis we also cloned the human homolog of chicken NFI-B2 and show that the truncated NFI-B3 protein can repress the transcriptional activity of NFI-B,- -C, and -X isoforms containing full-length activation domains.
The chloramphenicol acetyltransferase
(CAT)-reporter construct pCAT3xAd contains the wild-type
-globin
promoter and three consensus NFI binding sites from the adenovirus
origin of replication (1). The NFI expression vectors pXJ-NFI-X1,
pXJ-NFI-X2, and pCGND-CTF-1, pADH-CTF-2, and pADH-CTF-3 have been
described previously (9, 24). To construct the expression vectors
pXJ-NFI-B3 and pXJ-NFI-B2, the cDNA inserts were isolated from the
respective phage clones by polymerase chain reactions (PCRs) using
cDNA insert-flanking primers (cDNA insert-screening amplifiers,
Clontech) and cloned into the EcoRI site of a
cytomegalovirus promoter-driven expression plasmid pXJ40 (34). The
control plasmids pBCAT2 and pPacSp1 are described elsewhere (35).
A commercially available human skin fibroblast cDNA library (Clontech HL 1052a) was screened with a previously isolated 1.2-kb NFI-X cDNA clone, FN6, under hybridization conditions as described (9). From a total of 5 × 105 individual plaques, eight positive clones were purified. The cDNA inserts were amplified by PCR and subcloned into the EcoRI site of pUC19, and both strands of the cDNAs were sequenced.
Reverse Transcriptase-PCR Analysis and Direct DNA SequencingGenomic DNA (SiHa cells) and total RNA (HeLa, MRHF, H4
and HISM cells) for PCRs was prepared using TRIzol Reagent according to
the manufacturer's instruction (Life Technologies, Inc.). First strand
cDNA synthesis and subsequent PCRs were performed as described (9).
Primer pairs YB14-YB15, YB14-YB31, and Do108-Do109 were used for PCR
analysis. YB14 (5-AGTACCGATGGAGAGCG-3
) and YB15 (5
-CCATCTGTGACAGCTCA-3
) are located on the NFI-B3 cDNA; YB31 (5
-GATCATTGTGGCTTGGACT-3
) and YB11 (5
-ATGATGTGGCTGGACAC-3
) on the
NFI-B1 and NFI-B2 cDNAs as shown in Fig.
1A. Two primers with the sequence
5
-ATGATGTATTCTCCAATCT-3
(Do108) and 5
-CTCAGTTGCTGCTTTCTGCT-3
(Do109) are located at the 5
and the 3
regions of chicken NFI-B1 and
NFI-B2 cDNA. The PCR products were directly sequenced with the PCR
primers using Seqi Therm Cycle Sequencing Kits (Epicentre Technologies).
Northern Blot Analysis
Poly(A)+ RNA was
isolated from total RNA using the Poly(A)Ttract mRNA isolation
system (Promega). Approximately 1.5 µg of mRNA was separated on a
1% agarose gel and blotted to a nylon membrane (Hybond-N, Amersham
Corp.). The multiple tissue Northern blot containing 2 µg of
poly(A)+ RNA of each of various human tissues was obtained
from Clontech. DNA probes containing the 5-untranslated region
(position 76-440 bp) and the novel 3
sequence of NFI-B3 (position
1009-1270 bp) were created by PCR with NFI-B3 cDNA template. The
filters were probed in a hybridization solution containing 0.5 M sodium phosphate, pH 7.9, 7% sodium dodecyl sulfate,
15% formamide, and about 107 cpm/ml of the random primed
labeled novel 3
sequence of NFI-B3 (random primed DNA labeling kit,
Boehringer Mannheim). After a 16-h incubation at 65 °C, filters were
washed in 50 mM sodium phosphate, pH 7.9, 0.1% sodium
dodecyl sulfate for 30 min at room temperature, followed by wahsing
three times for 10 min at 65 °C. The filters were reprobed under the
same conditions with the 5
-untranslated probe, after stripping them in
boiling washing solution, three times for 1 min. After exposing the
filter to an autoradiographic film, the radiographic signals were
quantified on a PhosphorImager and Image Quant program (Molecular
Dynamics).
The human
epithelial cell lines HeLa, SiHa, and Caski as well as the fibroblast
line MRHF were cultured as described before (33). The human smooth
muscle cell line HISM (ATCC, CRL-92) was cultured in Dulbecco's
modified Eagle's medium supplemented with 10% fetal calf serum. The
H4 human neuroglioma line (ATCC, HTB-148) was grown in Dulbecco's
modified Eagle's medium containing 4.5 g glucose/liter and 10%
fetal calf serum. Drosophila Schneider SL-2 cells were grown
in Schneider's insect medium (Life Technologies, Inc.) supplemented
with 10% fetal calf serum at 25 °C. Twenty-four h before
transfection, the cells were seeded at a density of 106
cells/ml and then transfected by calcium phosphate coprecipitation as
described (36). Three µg of an NFI expression vector (pXJ-NFI-B3, -B2, -X2, or pCGND-CTF-1) was cotransfected with 3 µg of the reporter construct pCAT3xAd, and pUC19 plasmid DNA was added as a carrier to
a total of 10 µg of DNA. Cells were harvested 36-38 h after transfection, and 50 µg of protein was used for each CAT assay.
The correct expression of NFI-B3 and NFI-B2 from the pXJ40 vector construct, which contains a T7 promoter upstream of the cloning site, was tested by in vitro transcription and translation. The plasmids (0.5 µg) were added separately to 50 µl of a reaction mix containing T7 RNA polymerase and rabbit reticulocyte lysate (TNT Coupled Reticulocyte Lysate System, Promega). The electrophoretically separated protein products, which had incorporated [35S]methionine, were observed by autoradiography. Nuclear extracts of Drosophila SL-2 cells transfected with 5 µg of pXJ-NFI-B3, pXJ-NFI-B2, pXJ-NFI-X2, and pCGND-CTF-1 were prepared according to Schreiber et al. (37). Gel shift assays were performed with an oligonucleotide representing an Ad-NFI consensus binding site as described previously (9). The DNA-protein complexes were separated on a 4.5% polyacrylamide, 0.25 × TBE gel.
We have reported previously the isolation of a
human NFI-X isoform in a screen of a human fibroblast cDNA library
with an NFI-C probe and the detection of further NFI-X isoforms by
rescreening the same library using this NFI-X clone as a probe (24).
The same study led to the detection of a novel NFI-B cDNA. The 5 region to this cDNA was homologous to the cDNA clones NFI-B1
and NFI-B2 originally isolated from hamster and chicken (13, 16); however, sequences downstream of the DNA binding domain diverged from
those of all known NFI sequences. This clone was termed YL11.
Clone YL11 (GenBankTM accession number U70862[GenBank]) is 1,299 bp long,
starting 457 bp upstream of an ATG initiation codon and terminating in
a poly(A) tail downstream of a putative AATAAA consensus
polyadenylation signal. The 3-untranslated region of YL11 is 267 bp
long. The sequence of 502 bp of the DNA binding domain is 99.8%
similar to a human NFI-B segment amplified by reverse transcriptase-PCR
(18). No homology with other known sequences could be found downstream
of nucleotide 1015. Translation of the cDNA sequence reveals an
open reading frame of 564 bp, coding for a 188-amino acid polypeptide
chain. The NH2-terminal 186 amino acids are conserved among
all known members of the NFI family and comprise the DNA binding
domain. The remaining two amino acids, an alanine and arginine, replace
the whole COOH-terminal transactivation domains observed in hamster
NFI-B1 and chicken NFI-B1 and NFI-B2. Since the sequence similarity
indicated that the COOH-terminal truncated YL-11 clone belonged to the
NFI-B family, it was designated NFI-B3.
To analyze the novel human NFI-B3 isoform and to compare it with other
proteins and cDNAs derived from the NFI-B gene, we attempted to
clone the human homologs of the hamster and chicken NFI-B1 and NFI-B2
isoforms. Reverse transcriptase-PCR was performed with RNA from MRHF
fibroblast cells using a pair of primers, Do108 and Do109, flanking the
full-length coding frames of chicken NFI-B1 and NFI-B2 cDNAs. No
PCR product could be isolated and characterized from MRHF fibroblasts.
We then performed similar PCR analyses with cDNAs generated from
epithelial cells (HeLa and C33A) which resulted in a PCR product of
1.37 kb in both cell lines. The product from HeLa cells was subcloned
and sequenced. Sequence alignment indicated that this cDNA is the
human counterpart of chicken NFI-B2. A partial human NFI-B cDNA was
recently amplified by reverse transcriptase-PCR from human HepG2 cells
(18) which showed sequence identity to our NFI-B2 clone. No product of
1.68 kb, which would account for NFI-B1, could be amplified from the
cDNAs used. To determine if the lack of a NFI-B1 PCR product is the
result of an inefficient amplification of the larger product, PCR
primers overlapping shorter segments were used. Using primer Do108 and
YB11, which are located at the 5 homologous region of the NFI-B
cDNAs, a single band of the predicted size of 505 bp could be
amplified from HeLa cDNA. Primer pair YB14 and Do109 led to the
predicted fragment of 1,252 bp for NFI-B1 and 941 bp for NFI-B2. The
identity of the fragments was verified by sequence analysis. A
schematic diagram of the NFI-B isoforms and the location of the PCR
primers are given in Fig. 1A.
The detection of
a unique NFI-B gene in human genomic DNA by Southern blot hybridization
(18) suggests that all NFI-B isoforms are generated by alternative RNA
processing from the same NFI-B gene. The region where the NFI-B3
cDNA diverges from NFI-B2 contains an AG/GCAAGG sequence similar to
that of a consensus exon-intron junction (38). It is possible that the
novel sequence downstream of nucleotide 1015 bp of the NFI-B3 mRNA
arises from splicing the 5 exon to a new exon with an internal
polyadenylation site. Alternatively, a polyadenylation signal in the
adjacent intron may have been used to terminate the NFI-B3 transcript.
To distinguish between these two hypotheses we performed PCR analysis
on cDNA and genomic DNA with PCR primers flanking the potential
splice junction site. If the novel sequence were derived from a intron contiguous to the sequence encoding the DNA binding domain, the PCR
should generate identical fragments in cDNA and genomic DNA; however, if alternative splicing is employed, the PCR product from
genomic DNA should be larger than the cDNA product, or, in case of
very large intron, undetectable. PCR primer YB14 was derived from the
known exon sequence, and primer YB15 from the novel sequence as
indicated in Fig. 1A. A PCR product of 267 bp was amplified from HeLa cDNA (Fig. 1B, lane 1), MRHF
cDNA (lane 2), and SiHa genomic DNA (lane 3).
Sequencing analysis showed that the amplified fragment was identical in
both genomic DNA and cDNAs. The specificity of the reaction was
tested by a PCR performed with the reaction mix, including the primers,
but substituting water for the DNA template. No product was amplified
(data not shown). In control experiments PCRs on the same genomic DNA
and cDNA preparations, primer YB14 was paired with primer YB31,
derived from the known exon sequence of NFI-B1 and NFI-B2 (Fig.
1A). A PCR product of the expected size of 163 bp could be
amplified from the cDNA preparations (lanes 4 and
5) but not from genomic DNA (lane 6), confirming the presence of an intronic sequence between these two exons. These PCR
results show that the NFI-B3 mRNA is generated by using a
polyadenylation site present in the intron adjacent to the intermediary coding sequence, a mechanism thus far not described for any other NFI
isoform.
The expression of human NFI-B isoforms in
epithelial and fibroblast cell lines as well as in different human
tissues was analyzed by Northern blot hybridization. Filters containing
poly(A)+ RNA from HeLa epithelial cells (Fig.
2A, lane 1), MRHF fibroblasts (lane 2), and different human tissue samples (lanes
3-10) were hybridized with the novel 3 sequence of the NFI-B3
cDNA. One mRNA species of about 1.8 kb was detected in both
cell lines in similar amounts and with significant quantitative
variations in different human tissues.
To confirm the identity of the 1.8-kb message the filters were reprobed
with a 5 fragment of NFI-B3. Since the first 550 bp of the coding
region are highly similar among all members of the NFI family, we used
the 5
-untranslated region of NFI-B3, which is conserved within the
NFI-B family but which has no known homology to the NFI-A, -C, and -X
cDNAs. A major mRNA species of about 8.7 kb was detected in
HeLa cells and different tissues (Fig. 2B, lanes
1 and 3-10) but not in MRHF fibroblast cells (Fig. 2B, lane 2). This 8.7-kb mRNA was also
detected by reprobing the filter with the full-length NFI-B2 cDNA
(data not shown), and a message of similar length has been described
previously for NFI-B1 in hamster liver cells (13). The 1.8-kb mRNA
was observed with the 5
probe in all lanes only after longer exposure
of the filter because of the lower expression of this message. In
several human tissues and HeLa cells NFI-B3 mRNA is expressed about
6-fold lower than the 8.7-kb NFI-B1 and NFI-B2 mRNA, whereas it is
the only detectable NFI-B mRNA in MRHF fibroblasts. The absence of the 8.7-kb message in fibroblast cells correlates with our observation from PCR analysis that NFI-B1 and NF1-B2 are not expressed or only at
extremely low levels in human fibroblast cells. Fig.
2C shows the same filter probed with
-actin as control.
DNA Binding and Dimerization Properties of NFI-B3
The truncated NFI-B3 protein lacks a transcriptional activation domain but contains all four cysteine residues essential for DNA binding of full-length NFI proteins (39). To confirm whether the truncated NFI-B3 is able to bind DNA and to examine whether NFI-B3 may interfere with DNA binding of other NFI family members by heterodimerization, we examined these properties by gel shift analysis.
First, we tested the correct expression of the NFI-B3 and NFI-B2 proteins from the newly constructed expression vectors pXJ40-NFI-B3 and pXJ40-NFI-B2 by in vitro translation. A protein of the expected size of about 22 kDa was detected for NFI-B3 (Fig. 3A, lane 1), whereas the predicted open reading frame for NFI-B2 led to the expression of a protein of about 51 kDa (lane 2). The expression of NFI-C and NFI-X proteins from the respective expression vectors has been documented before (24).
Expression vectors for the different NFI proteins were transfected into Drosophila Schneider SL-2 cells, which lack endogenous NFI proteins. Subsequent gel shift analysis of nuclear extracts with a NFI consensus binding site from the adenovirus origin of replication (Ad-NFI) indicates that NFI-B3 is unable to bind DNA on its own (Fig. 3B, lane 1). We then cotransfected NFI-B3 with other members of the NFI-B, -C, and -X family to analyze whether the truncated protein can interfere with DNA binding of different NFI proteins. The gel shift of human NFI-B2 homodimers is shown in Fig. 3B, lane 2. Cotransfection of NFI-B3 significantly decreased the DNA binding activity of NFI-B2 (lane 3). As NFI-B3 presumably cannot compete for DNA binding it possibly disrupts the binding of NFI-B2 by heterodimerization. The binding activity of NFI-X2 (lane 4) was also reduced by NFI-B3, and the appearance of a new band with faster mobility (lane 5) indicates that a heterodimer of NFI-B3 and NFI-X2 proteins can bind to DNA. A similar result was obtained when NFI/CTF-1 was transfected alone or with NFI-B3 (lanes 6 and 7). In separate cotransfection assays, we observed that NFI-B3 could also form a complex of intermediate mobility with other NFI family members such as NFI-X1, NFI/CTF-2, and NFI/CTF-3 (data not shown). Although the DNA binding capacity of NFI-B, NFI-C, and NFI-X homodimers was decreased to a similar extent by NFI-B3, the amount of newly formed DNA binding complexes varied significantly (compare lanes 3, 5, and 7). The migration pattern of the newly formed complexes correlates with the considered sizes of heterodimeric protein moieties as assumed NFI-X2·NFI-B3 complexes migrate with faster mobility than NFI/CTF-1·NFI-B3 complexes (compare lane 5 and lane 7). The specificity of the newly formed complexes was confirmed by competition studies with unlabeled wild-type and mutant NFI binding sites (data not shown).
These experiments show that NFI-B3, which lacks the transcriptional activation domain of other NFI-B family members, cannot bind to DNA on its own; however, it can heterodimerize with other NFI proteins, containing a transcriptional activation domain.
NFI-B3 Inhibits Transactivation by Other NFI Family MembersSince gel shift analysis had shown that NFI-B3 cannot
bind DNA on its own but can interfere with the DNA binding of other members of the NFI family, we tried to determine the functional consequence of these interactions by CAT assays. The reporter construct
pCAT3xAd, which contains the
-globin promoter and three
additional palindromic Ad-NFI binding sites, was cotransfected with
equal amounts of different NFI expression vectors into SL-2 cells.
NFI-B3 alone did not affect the activity of the reporter construct
(Fig. 4A, first two columns).
Another NFI-B family member with a full-length activation domain,
NFI-B2, stimulated CAT activity 23-fold, whereas coexpression of NFI-B2
and NF1-B3 led only to a 13-fold stimulation, a 1.7-fold reduction of
the activation potential of NFI-B2 homodimers (Fig. 4A,
second pair of columns). The activity of the
NFI-X2 homodimers and NFI/CTF-1 homodimers was reduced by the
interference of NFI-B3 to an even greater extent, 3.3- and 2-fold,
respectively (Fig. 4A, third and fourth
pair of columns). All CAT activities given in Fig. 4
were averaged from at least three independent experiments.
Interestingly, the level of transcriptional reduction by the different
heterodimers (NFI-B3·NFI-X2 > NFI-B3·NFI/CTF-1 > NFI-B3·NFI-B2) correlated with the amount of protein complexes bound
to DNA (compare Figs. 3B and 4A).
The specificity of the transcriptional repression by NFI-B3 was determined by cotransfection of the transcription factor Sp1 with NFI-B3 and a reporter construct, pBCAT2, which contains two Sp1 binding sites. The activity of Sp1 was not affected by NFI-B3 (Fig. 4A), indicating that NFI-B3 specifically inhibited the transactivation potential of NFI proteins.
NFI-B3 Inhibits the Activation Potential of Full-length NFI Proteins in a Concentration-dependent MannerTo study
the function of heterodimers between the truncated NFI-B3 and
full-length NFI we cotransfected equal amounts of the expression
vectors (see above), which gave rise to similar amounts of the
DNA-bound proteins (see Fig. 3). Northern blot data shown in Fig. 2 had
indicated, however, that NFI-B3 is expressed in vivo in
lower amounts than the other NFI proteins in most human tissues. To
examine whether NFI-B3 can repress the activity of other NFI proteins
at low concentrations we performed a titration experiment. A constant
amount of NFI/CTF-1 expression vector (1.5 µg) and increasing amounts
(0.1-1.5 µg) of NFI-B3 expression vector were cotransfected with 2 µg of the pCAT3xAd construct into SL-2 cells, followed by the
determination of CAT activity. Fig. 4B, first
column, shows the background activity of the CAT reporter construct alone, the effect of cotransfected NFI-B3 (second
column), and NFI/CTF-1 alone (third column) or
increasing amounts of NFI-B3 with constant amounts of NFI/CTF-1
(fourth through eighth columns). These data show that
although 1.5 µg of cotransfected NFI-B3 plasmid reduced the CAT
activity almost to background levels, there was still a significant
suppression of the NFI-C-stimulated CAT activity with 15-fold less (0.1 µg) NFI-B3 vector.
Our previous studies had
shown that human epithelial cells express NFI proteins of the NFI-C
family, whereas human fibroblasts express NFI-C and NF-X isoforms. To
confirm that NFI-B3 also interferes with the endogenous NFI proteins in
their natural environment, we overexpressed NFI-B3 in HeLa epithelial
and MRHF fibroblast cell. The CAT activity of the reporter construct
pCAT3xAd in Hela cells (Fig. 5, lane 1)
was down-regulated by exogenous NFI-B3 expression 2.4-fold (lane
2), and in MRHF cells 3.3-fold (lanes 3 and
4). The expression of high levels of NFI-X proteins in MRHF cells (24) may account for the stronger effect of NFI-B3 in these cells
since NFI-X2·NFI-B3 heterodimers also showed the strongest level of
repression in SL-2 cells.
Transcriptional control plays a central role in determining the level of gene expression in various tissues during development and differentiation. Fundamental to such intricately controlled processes are the interactions of protein factors with specific sequence motifs in the promoter region and the interplay of these factors with components of the general transcriptional machinery. Specific sequence motifs often may be bound by related proteins with varying activation and repressing potentials, increasing the flexibility of transcriptional regulation to disparate cellular cues. Several mechanisms have been described which generate proteins with similar DNA binding specificity but different functions. Discrete isoforms can be transcribed from different, but related genes. Alternatively, a single gene can give rise to several distinct proteins by alternative RNA splicing or differential use of initiation codons (for review, see Ref. 40).
NFI constitutes such a family of transcription factors comprised of multiple subtypes. The variation among all NFI proteins isolated so far is the result of transcription from four different genes as well as alternative RNA splicing within the subfamilies. All differentially spliced RNA products characterized so far were produced by alternative exon usage affecting the transcriptional activation domain. We have identified a new member of the NFI family, designated NFI-B3, which is generated by an alternative mechanism of RNA processing. The first intron after the proposed DNA binding domain, which is conserved among all NFI proteins, is maintained, and a polyadenylation site in the internal intron is used to terminate the transcript. This mechanism has been not been described for NFI proteins before but is also used to generate functionally different isoforms of the hepatocyte nuclear factor I family (41). Transcripts generated by this mechanism have not been described so far from the NFI family. The nucleotide sequence of the exon/intron junction in NFI-B3 which leads to the alternative transcripts is not conserved among the different NFI genes. A splice junction has, however, also been documented for the NFI-C (15) and NFI-A (42) genes in a similar position separating the conserved DNA binding domain from the divergent transactivation domains. A truncated human NFI-C cDNA (hCTF4), previously isolated from HeLa cells, contains 10 amino acids divergent from all known exon sequences of the NFI-C gene (15) in a position comparable to the novel sequences of NFI-B3, which possibly represents a NFI-B3 equivalent in the NFI-C family.
NFI-B3 contains the sequences thought to be sufficient for DNA binding and dimerization but lacks the proline-rich activation domain. Proteins with similar characteristics from other transcription factor families have been found to function as transcriptional repressors either by competing with activators for a common binding site or by forming heterodimers with activators and thereby reducing their binding activity or their ability to activate transcription (43, 44). Expression of NFI-B3 in SL-2 cells, which are void of endogenous NFI proteins, had no effect on the activity of a NFI binding site-containing reporter construct. NFI-B3 repressed, however, the activity of other NFI transcriptional activators when coexpressed in SL-2 cells, as well as the activity of endogenous NFI proteins when overexpressed in HeLa and MRHF cells.
Gel shift analysis showed that the interference with the activity of the transcriptional activators occurs in two different ways. NFI-B3 reduces the binding activity of an activator protein from the NFI-B subgroup, possibly because of the formation of heterodimers that cannot bind DNA. The activation potential of NFI-C and NFI-X proteins, however, is apparently reduced by the formation of heterodimers with NFI-B3 which retain the capacity to bind DNA. The potential for heterodimer formation among different NFI family members has been demonstrated recently in vitro (45). NFI-B3 contains 186 amino acids of the highly conserved NH2-terminal portion of NFI as well as two novel residues. Studies with deletion mutants of the NFI-C and NFI-A gene (1, 2) have demonstrated earlier that the regions essential for DNA binding and dimerization lie within the NH2-terminal 220 amino acids. The minimum region may have to be redefined, however, because amino acids 178-202 can be spliced to yield NFI/CTF-3, which can still form dimers and bind to DNA (1). A protein from a deletion mutant of the NFI-A gene which encodes only the first 186 amino acids of NFI, similar to NFI-B3, could neither bind to DNA nor form heterodimers with the wild-type protein containing the activation domain (4), suggesting that such a truncated protein has no functional role at all. The naturally occurring NFI-B3, which contains only two additional amino acids, similarly cannot bind to DNA probably because of a failure to form homodimers. In contrast to the NFI-A deletion mutant, NFI-B3 apparently forms heterodimers with other NFI proteins thereby interfering with their function. Our observation that the heterodimers of NFI-B3 with other proteins derived from the NFI-B, NFI-C, and NFI-X genes have different DNA binding affinities, indicates a potential contribution of the COOH-terminal region to DNA binding. Functional data furthermore suggest that a single activation domain in a heterodimer may not be sufficient for transcriptional activation.
The expression of all NFI-B isoforms, as examined by Northern blot analysis, varies significantly among different human tissues, with the highest levels of both the 8.7-kb message for NFI-B1 and NFI-B2 and the 1.8-kb message for NFI-B3 being observed in heart and skeletal muscle. No 8.7-kb mRNA could be detected in human fibroblast cells. This differential expression pattern suggests NFI-B factors to be one out of several sources for cell type-specific transcriptional differences observed with promoters and enhancers with NFI binding sites. It has been shown recently that NFI-B and NFI-C genes are up-regulated by thyroid hormones during metamorphic transition in X. laevis development (46), suggesting that these factors are important for postembryonic organ development. As both genes can potentially give rise to truncated proteins with repressing functions (see above) it would be interesting to examine the possible contribution of NFI-B3 and any potential counterpart of the NFI-C family in organ development.
We thank Robin Watts and Mark O'Connor for helpful discussions and critically reading this manuscript and Guntram Suske for providing the plasmid constructs pBCAT2 and pPacSp1.