(Received for publication, November 18, 1996, and in revised form, February 14, 1997)
From the Division of Endocrinology and Metabolism,
¶ Howard Hughes Medical Institute, School and Department of
Medicine, University of California at San Diego, La Jolla, California
92037-0648 and the
Departments of Dermatology and Biochemistry
and Molecular Biology, Mayo
Clinic, Rochester, Minnesota 55905-0001
Tissue-restricted POU domain transcription factors, which bind octamer or octamer-like gene sequences, play roles in cellular differentiation and the development of several organs. We have previously identified a POU domain gene, Skn-1a/i, expressed primarily in epidermis, that encodes at least two products through alternative splicing. One of these, Skn-1a, acts as a transcriptional activator, and the other, Skn-1i, contains an inhibitory domain in the NH2 terminus, which prevents DNA-binding in vitro and transcriptional activation in vivo. We now demonstrate that when Skn-1i is expressed in eukaryotic cells it can bind to an octamer site, suggesting that in vivo cellular factors modulate the activity of the inhibitory domain to permit DNA-binding. Yet the inhibitory domain does not allow transactivation by Skn-1i or by a heterologous transactivator containing this domain in cis. Furthermore, we demonstrate that Skn-1a, Tst-1, and Oct-1 are the major octamer-binding proteins in epidermis. Since Skn-1a is primarily expressed in suprabasal cells of the epidermis, we have tested its possible role in the regulation of epidermal papillomaviruses. In transient transfection assays, Skn-1a and Tst-1 can activate the long control region of the epidermis-specific human papillomavirus 1A (HPV-1A). Consistent with these in vivo transcription data, in vitro DNA binding studies identify three octamer-like sites, which are capable of binding Skn-1a, in the HPV-1A long control region. Mutations of all three octamer-like sites prevent transactivation by Skn-1a in transient transfection assays. Taken together, these results provide evidence that Skn-1a and Tst-1 may provide a molecular link between HPV gene expression and epidermal differentiation.
During midgestation in mammals, the embryo is enclosed by a cellular bilayer composed of a basal layer of somatic ectoderm, which is covered by distinct epithelial cells referred to as periderm. While periderm is later shed, somatic ectoderm has several distinct fates in the mature organism. These fates include mammary epithelium, teeth, epidermis, and epidermal appendages such as hair, nails, and sweat glands (1). Epidermis, which forms relatively late in embryogenesis, is made of a single layer of proliferating basal keratinocytes and several layers of postmitotic suprabasal cells. The basal keratinocytes express a pair of keratins, K5 and K14, but, concomitant with departure from the basal layer, they exit the cell cycle, suppress expression of K5 and K14, and induce expression of another keratin pair, K1 and K10. As keratinocytes move outward to the surface of the skin, proteins required for formation of a cornified cell envelope are induced. These cells subsequently undergo programmed cell death to form the cornified layer of the epidermis. This differentiation process, first initiated during embryogenesis, continues throughout life with cell proliferation in the basal layer balanced by cell death and eventual shedding of the stratum corneum (2).
Human papillomaviruses (HPVs)1 are a family of small DNA viruses that selectively infect epithelial tissues and replicate in the nucleus of cells undergoing differentiation (3). Over 70 types of HPVs have been identified, with each type demonstrating a characteristic tissue specificity. HPV-1 and -2 primarily infect epidermal keratinocytes, causing palmoplantar warts and verrucose warts in other regions of the skin, respectively. In contrast, HPV-16 and -18 primarily infect the genitourinary epithelium and have been implicated as the main etiologic factor in cervical cancer (3). The genomic organization of all HPVs is remarkably similar with all open reading frames located on one strand of viral DNA. The approximately 10 expressed viral genes can be divided into early (E) and late (L) genes. The early genes include E1, which is involved in replication, and E2, which regulates transcription, as well as E6 and E7, which are responsible for cellular transformation by means of interactions with p53 and Rb proteins. The late genes L1 and L2 encode for capsid proteins. Between the L2 and E6 genes there is long region in all HPVs, referred to as the long control region (LCR), which contains no open reading frames.
A characteristic feature of all these viruses is the tissue specificity of their infection and the fact that productive infections are dependent on an advanced stage of differentiation of the infected epithelial tissues. In this respect, gene expression and replication of HPV-1 and -2 correlate with expression of markers of epidermal differentiation, such as cytokeratins 1 and 10. In fact, the papillomaviruses may use the same regulatory mechanisms for transcription and replication as the cell uses for differentiation (4).
While the molecular mechanisms responsible for skin development remain unclear, they probably involve complex interactions between external regulators with convergence on nuclear proteins that ultimately regulate gene transcription. Recent experiments have demonstrated that the HMG domain transcription factor LEF-1 is required for development of several organs requiring inductive epithelial-mesenchymal interactions in somatic ectoderm, including teeth, mammary glands, whiskers, and hair (5, 6). A nuclear zinc finger protein, basonuclein, that is expressed in undifferentiated proliferating keratinocytes is likely to be a transcriptional regulator (7, 8). In addition, several transcription factors with widespread distribution have been implicated in the expression of epidermis-specific genes. These include AP-1 (9-12), AP-2 (13, 14), Mad/Max (15, 16), RARs (17, 18), HNF-4 (19), and several homeobox factors (20).
Identification of the epidermis-restricted POU domain gene Skin-1a/i (Skn-1a/i; also referred to as Epoc and Oct-11) suggested a candidate for a transcription factor involved in epidermal differentiation (21-23). This hypothesis is supported by the fact that other tissue-restricted POU domain genes have been shown to be important for cellular differentiation in other organ systems (24). Although expression has been described in the stromal cell of the thymus and in the antrum of the stomach (23), expression of the Skn-1a/i gene is essentially limited to interfollicular epidermis and cortical cells of the hair. Second, the Skn-1a/i gene is activated in somatic ectoderm at a time that corresponds with formation of epidermis and becomes primarily localized to the differentiating suprabasal layer. Finally, Skn-1a can activate transcription of the differentiation-specific K10 and SPRR2A promoters (22, 25).
Two gene products are encoded by the rat Skn-1a/i gene (22). One, Skn-1i, cloned from an anterior pituitary cDNA library, contains an NH2-terminal sequence that inhibits DNA binding in vitro and prevents transactivation in vivo. The inhibitory domain of Skn-1i is capable of transferring inhibition to unrelated DNA-binding proteins. Furthermore, despite the apparent lack of DNA-binding by Skn-1i, it can interfere with transactivation by Oct-1 and Skn-1a on octamer-containing transcription units. In the other form, Skn-1a, the inhibitory domain is replaced by a distinct sequence; this form binds octamer sites in vitro and acts as a transcriptional activator. While both forms have been found in skin by reverse transcription-polymerase chain reaction, their relative levels are unknown.
In this paper, we demonstrate that the major octamer-binding proteins in skin are Skn-1a, Oct-1, and Tst-1. We show that Skn-1i, which appears to be expressed at a relatively low level in normal skin, can bind octamer sites in eukaryotic cell extracts yet is incapable of transactivation. Both Skn-1a and Tst-1 can activate the E6 promoter of HPV-1A via octamer DNA-binding sites. Thus, the differentiation-related POU domain factors Skn-1a and Tst-1 may provide a molecular link between epidermal differentiation and efficient papillomavirus gene expression.
Nuclear extracts from CV-1 cells were prepared
according to the method described by Schreiber et al. (1989)
(26). Cells were washed two times in phosphate-buffered saline and
scraped from two 35-mm plates in 300 µl of cold buffer A (10 mM Hepes, pH 7.9, 10 mM KCl, 0.1 mM
EDTA, 0.1 mM EGTA, 2 mM dithiothreitol, and
protease inhibitors). After remaining on ice for 5-10 min. 15 µl of
20% Nonidet P-40 was added followed by vortexing for 10 s. The
lysate was centrifuged for 30 s in a microcentrifuge to separate
nuclei from cytosol. After removing the cytoplasmic extract, the
nuclear pellet was resuspended in 50-100 µl of buffer B (10 mM Hepes, pH 7.9, 10 mM KCl, 0.1 mM
EDTA, 0.1 mM EGTA, 2 mM dithiothreitol, 400 mM NaCl, 1% Nonidet P-40, and protease inhibitors. The
sample was gently rotated for 15 min at 4 °C, followed by
centrifugation in a microcentrifuge for 5 min. The supernatant was
frozen in 10% glycerol. Nuclear extracts from neonatal mouse skin were
made using modification of the same method in which 100-500 mg of
tissue were dissected into small pieces followed by homogenization in
buffer A using a Dounce homogenizer. Human adult skin was obtained
using a dermatome set at 0.2-0.4 mm. The sample was cut into small
pieces and incubated in the presence of trypsin for 1 h at
37 °C. After pipetting to dissociate cells, the method described
above was used to isolate nuclear extracts. 0.5-5.0 µl of nuclear
extracts was used in the gel mobility shift assay as described
previously (22). The sequence of oligonucleotide binding sites used in
gel mobility shift assays is as follows: 5-AAGGGGATCCCTGATTTGCATATGAAGGATAC-3
(O+H
; octamer
sequence is underlined);
5
-GATCCTATTTTATGTAAATACATGCCTACTTATACTAATGTAAATCTTA-3
(HPV sites 1 and 2; octamer-like sequences are underlined); and 5
-GATCTGATTGTGTGTTATTTTCCTGCAATATGCAATAAAAGTGAG-3
(HPV site 3; octamer-like sequence is underlined). In
vitro translated and bacterially expressed proteins were prepared
as described previously (22). DNA-binding sites for gel mobility shifts
were labeled using polynucleotide kinase. Footprint assays were
performed as described previously (27).
Poly(A)+ RNA was isolated from mouse and rat
skin as described previously (28). After gel electrophoresis, the RNA
was transferred to nitrocellulose filters and hybridized to
32P-labeled DNA fragments. For Northern blots, we used a
Skn-1a probe that is 350 bp long starting at the starting codon and a Skn-1i probe that is 380 bp, containing mainly 5-untranslated sequence. These probes contain 10 bp of common sequence at the 3
-end.
RNase protection assays were performed as described previously (28),
using 3 µg of poly(A)+ RNA from rat neonatal skin. The
cRNA probe for Skn-1a extends from the 5
-end of the Skn-1a cDNA to
the HindIII site in the NH2 terminus, resulting
in a protected fragment of 520 bp; the total length of the probe,
including vector sequences, is 563 bp. The cRNA probe for Skn-1i
extends from the 5
-end of the Skn-1i cDNA to the PstI
site in the NH2 terminus, resulting in a protected fragment
of 370 bp; the total length of the probe is 445 bp. An equivalent
amount of probe and RNA was used for all hybridization reactions.
Three protein preparations, 60
Skn-1i (antiserum 813),
60 NH2 terminus of Skn-1i with
the 5
-part of the POU domain (antiserum 764), and the COOH terminus of
Skn-1a/i (antiserum 812), were used for immunization. Constructs
encoding these proteins were expressed as glutathione
S-transferase fusion proteins in bacteria. After
purification by glutathione-agarose affinity chromatography and size
fractionation on SDS-polyacrylamide gels, gel slices containing these
proteins were injected into rabbits according to standard protocols to
generate antisera. The Tst-1 antisera has been previously described
(29).
Human
papillomavirus 1A DNA was obtained from the American Type Culture
Collection. The LCR, encompassing nucleotides 3395-4370, was isolated
using PCR and cloned directionally into the luciferase reporter plasmid
GeneLight (Promega), using the restriction sites Bgl2 and
HindIII. The sequences of the oligonucleotides used for amplifying the LCR were as follows:
5-ATATAGATCTTAGTATATATTATATATAACTATATTT-3
(5
-end) and
5
-ATATAAGCTTTGTGCAGAGTCTTACCTGTGTATTT-3
(3
-end). The 5
-end of
the LCR was arbitrarily assigned the number
974, and the 3
-end was
assigned +1. The AvrII site at nucleotide 4314 was used to
create the reporter plasmid
56 HPV-1A LCR, which contains the minimal
E6 promoter. The RsaI restriction sites located at
nucleotides 3689, 3957, and 4179, were used to create the fragments of
the LCR used for cloning into reporter plasmids and for DNA-binding studies.
60 K10 luciferase contains the minimal K10 promoter upstream
of luciferase in GeneLight. The following oligonucleotides were used to
mutagenize the Skn-1a binding sites HPV site 1, HPV site 2, and HPV
site 3: 5
-ATACTAATGGGAATCTTACAT-3
,
5
-GACTATTTTATGGGAATACATGCC-3
, and
5
-TCACTTTTATCCCATATTGCAGGA-3
, respectively (altered
nucleotides are underlined). Expression plasmids have been previously
described (22, 28, 30). Transient transfection assays were performed as
described previously, using 6 µg of reporter plasmid and 4 µg of
expression plasmid per duplicate 35-mm tissue culture dish (22).
To identify the
octamer-binding proteins in epidermis, we isolated nuclear extracts
from neonatal mouse skin. This extract was incubated with a
32P-labeled octamer site (O+H) and subjected to
nondenaturing gel electrophoresis in the gel mobility shift assay. Two
major complexes are observed in skin nuclear extracts (Fig.
1A, lanes 10-16), a slow
migrating complex, which is also found in HeLa cell nuclear extracts
(Fig. 1A, lanes 7-9), and a fast migrating
complex, which is unique to skin. The slower complex is consistent with
the ubiquitous POU domain factor Oct-1 and is disrupted by Oct-1
antisera (data not shown). The fast migrating complex is largely
disrupted by two different Skn-1a/i antisera (Fig. 1A,
lanes 11 and 13) and supershifted by a third
Skn-1a/i antiserum, while a Tst-1 antiserum only has a minor effect on
this complex (Fig. 1A, lane 16). The Skn-1a/i and
Tst-1 antisera are specific because they selectively disrupt the
binding of bacterially expressed truncated Skn-1a/i protein (Fig.
1A, lanes 1-3) and in vitro
translated Tst-1 protein (Fig. 1A, lanes 4-6),
respectively, and none of the antisera recognize the highly related
Oct-1 factor (Fig. 1A, lanes 7-9). Nuclear extracts from human skin also exhibit two major octamer-binding complexes (Fig. 1B). Both complexes are disrupted by
including excess unlabeled octamer DNA-binding site (Fig.
1B, lane 2) and are unaffected by Oct-2 antisera
(Fig. 1B, lane 3). In contrast to the slowly
migrating Oct-1 complex, the faster migrating complex is partially
disrupted by antisera against Skn-1a/i (Fig. 1B, lane
4) and Tst-1 (Fig. 1B, lane 5). Since no
Skn-1a/i or Tst-1 transcripts are found in the dermis (28, 31), these
proteins must originate from the epidermal keratinocytes. We conclude
that Skn-1a and Tst-1 constitute the main octamer binding activity in
epidermis, in addition to the ubiquitous POU domain factor, Oct-1, and
that this pattern of expression is conserved from mice to humans.
Skn-1a Is the Predominant Transcript from the Skn-1a/i Gene in Epidermis
Using specific oligonucleotides in combination with
reverse transcription-polymerase chain reaction, we have demonstrated both Skn-1a and Skn-1i transcripts in skin tissues from rats and mice
(data not shown). To estimate the relative levels of Skn-1a and Skn-1i
transcripts in epidermis, we isolated poly(A)+ RNA from
neonatal mouse and rat skin. 32P-Labeled cRNA probes that
are specific for Skn-1a and Skn-1i were used in RNase protection assays
with 3 µg of poly(A)+ RNA from rat neonatal skin or yeast
tRNA as a negative control (Fig. 2A). While
protected fragments were observed with both probes (indicated with
arrows in Fig. 2A), the Skn-1a transcript is
clearly expressed at a higher level.
To further characterize transcripts from the Skn-1a/i gene, we carried out Northern blotting experiments. After size fractionation and transfer to nitrocellulose, the RNA blots were hybridized with radiolabeled probes directed to the specific NH2 termini of Skn-1a and Skn-1i. Both probes contained a short fragment of common sequence. The Skn-1a fragment hybridized strongly to two major bands, 2.6 and 5.0 kilobase pairs long, (indicated with filled arrows in Fig. 2B) and weakly to several other bands. As expected, given the common sequence included in both probes, the Skn-1i probe hybridized weakly to the same transcripts and preferentially to two other transcripts, 3.8 and 7.5 kilobase pairs long (indicated with open arrows in Fig. 2B). The band in the Skn-1i lane that is over 9.5 kilobase pairs in size is most likely nonspecific because it is very diffuse, and it is not observed in the Skn-1a lane (Fig. 2B). Together, these results suggest that while transcripts corresponding to both Skn-1a and Skn-1i are found in mouse skin, Skn-1a transcripts are the predominant form. This is consistent with Western blot data showing that polyclonal Skn-1a/i antisera identify a predominant band corresponding to Skn-1a in skin nuclear extracts from human keratinocytes (data not shown).
Transcriptional Regulatory Domains of Skn-1a and Skn-1iUsing
deletion mutagenesis, we have demonstrated that a Skn-1a protein
containing only 40 residues of the NH2 terminus immediately adjacent to the POU domain, in addition to the POU domain and the COOH
terminus, is sufficient for transactivation of both the K10 (22) and
the HPV-1A promoters (Fig. 4A) and that the inhibitory domain of Skn-1i interferes with this activity in cis (22). To test whether this activity of the inhibitory domain is transferable, we have linked the inhibitory domain to the transcription factor thyrotrope embryonic factor (TEF). This particular combination was
selected because we have previously shown that the Skn-1i inhibitory
domain can inhibit DNA-binding of TEF in vitro (22). Expression plasmids were co-transfected with the thyroid-stimulating hormone promoter, which is known to be activated by TEF (32), into CV-1
cells (Fig. 3A). TEF activated this promoter
about 10-fold, fusion of the NH2 terminus of Skn-1i
(N-Skn-1i/TEF) interfered with this activation, and deletion of the
inhibitory domain (60 N-Skn-1i/TEF) restored transcriptional
activity. These data suggest that the inhibitory domain is capable of
interfering with heterologous transcription factors in the cell.
To define further transcriptional activation domains in the Skn-1a/i gene products, we have created a series of Skn-1a/i-LexA fusions and transfected with a reporter plasmid containing LexA DNA-binding sites into CV-1 cells (Fig. 3B). The NH2 terminus of Skn-1a shows strong transcriptional activity in this assay, while the Skn-1i NH2 terminus as well as the common POU domain and COOH terminus exhibit little or no activity. These results suggest that a major transactivation domain of Skn-1a resides in the NH2 terminus and that, in this assay, the intact NH2 terminus of Skn-1a is required for transactivation, since constructs containing either proximal or distal part of this sequence show little activity.
DNA Binding by Skn-1iIn previous studies we have noted that
the Skn-1i protein produced by in vitro translation in
rabbit reticulocyte lysates could not bind to octamer DNA sites and
that this inhibitory effect was conferred by a short domain in the
NH2 terminus (22). To test DNA binding in eukaryotic cells,
we transfected CMV expression plasmids encoding variants of Skn-1a
proteins into CV-1 cells. Subsequently, nuclear extracts were isolated
from these cells and used to test binding to an octamer DNA site in gel
mobility shift assays. Nuclear extracts from mock-transfected CV-1
cells contain one major DNA binding activity corresponding to the
ubiquitous Oct-1 (Fig. 3C, lanes 1 and
2). As expected, new binding activity was found in cells
transfected with Skn-1a and with 60 Skn-1i, a construct in which the
inhibitory domain has been deleted from Skn-1i (Fig. 3C,
lanes 3-6). Surprisingly, cells transfected with full-length Skn-1i showed DNA binding activity with migration between
that of Skn-1a and
60 Skn-1i (lanes 7 and 8,
Fig. 3C). These results suggest that the transcriptionally
inactive Skn-1i is modified in vivo, making it capable of
DNA binding.
Together, these data suggest that Skn-1i can bind DNA sites in vivo, presumably dependent upon a specific cellular machinery, but that it fails to act as a transcriptional activator, in contrast to Skn-1a, and further that inhibition can be transferred when the inhibitory domain is placed in cis with other transactivation domains.
Activation of HPV-1A Gene Expression by Skn-1aBased on the
activation properties and expression pattern of Skn-1a, we have tested
whether Skn-1a can regulate the epidermis-specific HPV-1A (33, 34). The
LCR containing the E6 promoter from HPV-1A was used to create a
reporter construct by inserting it in front of the firefly luciferase
gene (HPV-1A LCR luciferase; Fig. 4A). The
isolated LCR region is 974 bp and extends from the end of the L1 gene
to the beginning of the open reading frame for E6 (arbitrarily assigned
the number +1). This region is the only part of the papillomavirus
genome that does not contain open reading frames and is thought to
contain regulatory elements in all papillomaviruses. HPV-1A LCR
luciferase was transiently co-transfected into CV-1 cells along with
CMV expression vectors containing either full-length Skn-1a,
full-length Skn-1i, 60 Skn-1i, Tst-1, Brn-5, or Oct-1 (Fig.
4A). CV-1 cells were selected for these studies because they
lack Skn-1a/i and Tst-1 POU domain factors. Of these expression plasmids, only those expressing Skn-1a,
60 Skn-1i, and Tst-1 activate the HPV-1A LCR luciferase plasmid. Skn-1i, Brn-5, and Oct-1
have no transcriptional effect on the HPV-1A LCR. These results
indicate that Skn-1a and Tst-1 can specifically stimulate HPV-1A E6
promoter activity.
To localize the sequences in the HPV-1A LCR that mediate the Skn-1a
response, we isolated four contiguous fragments from the HPV-1A LCR and
cloned upstream of a minimal E6 promoter that contains 56 bp of
sequence, including the TATA box (HPV-1A LCR 56; Fig. 4B).
These plasmids were co-transfected with a CMV Skn-1a expression vector
into CV-1 cells (Fig. 4B). The HPV-1A LCR
56 luciferase plasmid is unresponsive, whereas reporter plasmids containing either
the region encompassing nucleotides
974 to
681, or nucleotides
681 to
412 are inducible by Skn-1a. CMV Skn-1a has little effect on
reporter plasmids containing fragments encompassing nucleotides
412
to
192 and nucleotides
192 to +1. To test whether the induction by
Skn-1a depends on the E6 promoter or whether the responsiveness could
transferred to a heterologous promoter, we linked the
974/
681,
681/
412, and
412/
192 fragments to the cytokeratin 10 minimal promoter (
60 K10 luciferase; Fig. 4C). These reporter
plasmids were co-transfected with CMV Skn-1a into CV-1 cells (Fig.
4C). The K10 minimal promoter itself is unresponsive to CMV
Skn-1a. Consistent with the previous results, only the
974/
681 and
681/
412 fragments are capable of responding to Skn-1a.
Collectively, these findings suggest that Skn-1a can activate
transcription of the E6 promoter through sequences in at least two
regions of the HPV-1A LCR, one located between nucleotides
974 and
681 and the other located between nucleotides
681 and
412.
To determine whether the
transcriptional regulation of the HPV-1A LCR by Skn-1a is through
direct binding of Skn-1a, we performed electrophoretic gel mobility
shift assays, using radioactively labeled fragments of the LCR and
bacterially expressed 60Skn-1i protein. The
974/
681 (Fig.
5A, lanes 1-5),
681/
412 (lanes 6-10),
412/
192 (lanes 11-15), and
192/+1
(lanes 16-20) fragments were incubated with increasing
concentrations of bacterially expressed
60Skn-1i protein. These
reactions were then run on a nondenaturing polyacrylamide gel to
separate bound from free complexes. The
974/
681 fragment binds
60Skn-1i with high affinity and the
681/
412 fragment with
somewhat lower affinity, whereas both
412/
192 and
192/+1
fragments required high
60Skn-1i concentrations for DNA binding
(Fig. 5A). The formation of two complexes with the
974/
681 fragment at relatively low protein concentrations suggests
that this fragment contains two high affinity binding sites for Skn-1a.
An antiserum specific for Skn-1a/i causes a supershift of the complex
(Fig. 5A, lane 22). We quantified the free and
bound complexes shown in Fig. 5A to assess the relative affinity of
60Skn-1i for the fragments tested in this experiment. The relative amount of protein required for binding a half-molar amount
of each fragment is an approximate guide for the relative affinity of
these fragments for
60Skn-1i. These binding curves (Fig.
5B) confirm that the
974/
681 fragment contains the
highest affinity sites, whereas the
681/
412 fragment binds with
approximately 5-10-fold lower affinity. The other two fragments bind
with much lower affinity.
To localize these elements more precisely, we first performed DNase I
protection assays with the 974/
681 fragment and a purified
60Skn-1iGST fusion protein. We readily observed a footprint that
corresponds to nucleotides
874 to
829 over both the + strand (data
not shown) and the
strand (Fig. 5C). Inspection of
the sequence of this region shows two binding sites that are perfect octamer motifs (ATGCAAAT) except for a change of 1 nucleotide (Fig.
5C). These sites are referred to as HPV sites 1 and 2 (Fig. 5E). To confirm that this region contained two binding
sites, we synthesized an oligonucleotide corresponding to this
region and tested it in the gel mobility shift assay (Fig.
5D). With low concentrations of
60Skn-1i protein, a
single fast migrating complex is observed (B1). When the
60Skn-1i
concentration is increased, a second complex (B2) with slower mobility
is observed. These findings are consistent with sequential filling of
the two octamer-like elements. The affinity of
60Skn-1i for
these sites is similar to that of the affinity of
60Skn-1i to a
classic octamer element (data not shown).
Mapping the Skn-1a binding site(s) in the 681/
412 fragment with
DNase I protection assays was unsuccessful, perhaps due to the relative
lower affinity of Skn-1a binding to this fragment. Therefore, we used
an alternative approach in which we isolated the
681/
412 fragment
and generated overlapping fragments, using different restriction
endonucleases. These fragments were radioactively labeled, and their
binding to
60Skn-1i was analyzed in the gel mobility shift assay
(data not shown). Inspection of the sequence of the region mapped by
this method reveals a putative binding site that contains only two
nucleotide differences from a classic octamer site. Binding to this
octamer-like site, referred to as HPV site 3 (Fig. 5E), was
confirmed using a synthesized oligonucleotide binding site
corresponding to this region (data not shown).
In summary, these results indicate that the sequences that respond transcriptionally to Skn-1a also bind Skn-1a with the highest affinity, suggesting that Skn-1a regulates the HPV-1A E6 promoter via a direct mechanism by binding to regulatory sites in the LCR.
Mutations of Octamer-like Sequences in HPV-1A LCR Prevent Transactivation by Skn-1aTo test the transcriptional effect of
the Skn-1a binding sites directly, each site was mutated in the HPV-1A
LCR luciferase plasmid. These reporter plasmids were transfected into
CV-1 cells, and their ability to respond to Skn-1a was assessed by
co-transfecting a control CMV vector or CMV Skn-1a (Fig.
6). While Skin-1a transactivates HPV-1A LCR luciferase,
no transactivation was observed in a similar plasmid with all three
octamer-like sites mutated (M123). Single mutations in site 2 (M2) or a
double mutation in sites 1 and 3 (M13) had little effect on Skn-1a
activation, suggesting redundancy between these sites.
Collectively, the in vitro DNA binding studies and the transient transfection analyses indicate that the Skn-1a binding sites identified in this study are both necessary and sufficient for transactivation of the HPV-1A LCR by Skn-1a.
POU domain factors, which bind octamer DNA sequences, have been shown to be important for cellular differentiation and development in several organs (24, 35). In this study, we demonstrate that three major octamer-binding proteins, Oct-1, Skn-1a, and Tst-1, are expressed in normal skin. Skn-1i transcripts and protein are expressed at a much lower level in normal skin than the alternatively spliced Skn-1a. We also find that Skn-1i, when expressed in eukaryotic cells, is capable of DNA binding, suggesting that in vivo its inhibitory domain acts by interfering with transactivation rather than DNA binding. Finally, we show that an epidermis-specific DNA virus, HPV-1A, contains Skn-1a-binding sites in its regulatory region that mediate transcriptional activation by Skn-1a, suggesting the possibility that Skn-1a may contribute to the tissue-specific expression of HPV-1A.
Octamer-binding Factors in SkinThe octamer (ATGCAAAT) and related sequences are found in regulatory regions of several cellular genes. These sequences are bound by nuclear factors, collectively referred to as octamer-binding proteins. Cloning of three such factors in mammals, Oct-1, which is ubiquitously expressed, Oct-2, which is prominently expressed in B-lymphocytes, and the pituitary-specific Pit-1, revealed that all three contained a DNA-binding motif similar to that of a cell-determining factor in Caenorhabditis elegans, unc-86 (36). The bipartite DNA-binding motif, referred to as the POU domain, is composed of a divergent homeodomain linked to another conserved region referred to as the POU-specific domain, with both domains making major groove contacts in DNA (37). Subsequently, several additional POU domain genes have been discovered in mammals and other species, many with prominent neuronal expression (38).
The interfollicular epidermis is a classic example of a tissue that is renewed by unipotent stem cells located in the basal cell layer (39). Recently, several transcription factors have been implicated in formation of both hair and teeth (5, 6), but tissue-restricted factors involved in differentiation of interfollicular epidermis remain unknown. The identification of a class II POU domain gene, Skn-1a/i, that is expressed at high levels in skin provides a candidate factor (21-23). This hypothesis is supported by the relatively restricted expression in epidermis but not other stratified epithelia, with the possible exception of stomach; expression has also been described in stromal cells of the thymus. Also consistent with a role for this gene in differentiation is the observation that in transient transfections, Skn-1a stimulates expression of a reporter that is under the control the K10 promoter (22). Interestingly, K10 is expressed in the epidermis and in stomach epithelium, the only two stratified epithelia in which Skn-1a/i expression has been described. Furthermore, Skn-1a has been shown to activate the epidermis-specific human SPRR2A gene (25). Skn-1a and Skn-1i have also been shown to inhibit the involucrin promoter, which contains an octamer DNA-binding site in its promoter. The inhibition, however, is also seen with several other POU domain factors and is independent of the involucrin octamer sites, suggesting that protein-protein interactions may be involved in this regulation (40).
In addition to Skn-1a/i, the expression of two other POU domain genes has been previously described in epidermis. One of these, Oct-1, is a class II POU domain gene that is ubiquitously expressed and has been implicated in regulation of housekeeping genes such as those encoding small nuclear RNA (41) and histone H2B (42). The other, Tst-1 (Oct-6/SCIP), is an intronless POU domain gene of class IV that exhibits predominantly neuronal and glial expression, but is also expressed in stratified epithelia throughout the body, including skin (31, 43). In transient transfection assays, Tst-1 suppressed expression of K5 and K14 reporter genes, suggesting that the this factor might be involved in the restriction of K5/K14 gene expression (31). While the mRNA expression of Oct-1, Skn-1a/i, and Tst-1 has been previously described, the extent to which these protein products are expressed in epidermis was unclear.
In this study, we have shown that in Skn-1a, in addition to Oct-1, represents the major octamer binding activity in epidermal keratinocytes. Studies by Faus et al. (31) indicate that Tst-1 is the major octamer binding activity in epidermal keratinocytes. This discrepancy is likely due to the unanticipated co-migration of Skn-1a and Tst-1 by gel mobility shift and the failure of these investigators to identify the protein-DNA complexes by antisera. While the class II POU domain factors Oct-1 and Skn-1 clearly bind preferentially to classic octamer sites, other POU domain factors may bind preferentially to sites that are divergent from a classical octamer site (44). Therefore, our study does not preclude the expression of yet more such factors in epidermis. The low levels of Skn-1i transcripts coupled with the failure to observe DNA-binding complex corresponding to this factor in gel mobility shift assays suggests that Skn-1i is expressed at a very low level in normal skin.
Transcriptional Regulatory Domains in Skn-1a and Skn-1iWe previously identified a short domain in the NH2 terminus of Skn-1i that interferes with DNA binding by the POU domain in vitro (22). Intriguingly, this domain retains its activity when transferred to a distinct DNA-binding domain. Furthermore, in transient transfection assays, this domain prevents transactivation by Skn-1a/i transactivation domains, an ability we have now shown can also be transferred to a heterologous transactivation domain. The correlation between inhibition of DNA binding and lack of transactivation led to a model suggesting that Skn-1i is transcriptionally inactive because it fails to bind to DNA in vivo. The current study has led us to reevaluate this model, since we have shown that Skn-1i expressed in eukaryotic cells can bind octamer elements. It is therefore more likely that the inhibitory domain interferes with transcriptional activation function, perhaps by interacting with a transcriptional repressor(s) or by directly interfering with a transactivation domain (45). The observation that the inhibitory domain can act both on the NH2-terminal transactivation domains of Skn-1a/i and the transactivation domain of TEF suggests that protein-protein interactions may be involved. This result is also consistent with our earlier observation showing that Skn-1i can interfere with octamer-dependent transactivation by Oct-1 and Skn-1a. It is plausible that Skn-1i can occupy octamer sites, thus preventing activation by positive transactivators that bind to octamer sites. The LIM domain found in certain transcription factors may behave in an analogous fashion to the inhibitory domain of Skn-1i because it interferes with DNA-binding in vitro, yet DNA binding can be restored via protein-protein interactions (46, 47). However, we find that adding nuclear extracts to binding reactions containing in vitro translated Skn-1i protein does not restore binding, suggesting that the protein must be processed in the cell for binding (data not shown).
The requirement of the whole NH2 terminus of Skn-1a for transfer of efficient transactivation to the LexA DNA binding domain suggests that several subdomains interact for full transcriptional activity similar to the transactivation domains of the related POU domain factor Oct-2 (48). Interestingly, similar to Skn-1i, the Oct-2 NH2 terminus has also been shown to contain inhibitory domains (49). Combinations of inhibitory and activation domains, each interacting with distinct or common co-regulators, may be a common regulatory mechanism for transactivators.
Skn-1a and PapillomavirusesExpression of the viral genes is thought to be under control of an enhancer that is part of the LCR. Although at least one viral product, E2, can bind to and regulate the enhancer (50-52), the enhancer is thought to be primarily controlled by cellular trans-acting factors. While investigations of the HPV-16 and HPV-18 enhancers have implicated several ubiquitous transcription factors in regulation of these viruses, including AP-1, Sp1, and Tef-1, their differentiation- and cervix-specific activity has not been explained. Octamer DNA-binding sites have been demonstrated in the regulatory region of both HPV-16 and HPV-18. Several octamer-binding proteins have been shown to bind to and regulate these viruses, including Oct-1 (53-55), Oct-2 (56), Skn-1a (57), and several unknown octamer-binding proteins, some of which may be specific to the cervical epithelium (58).
HPVs infect the proliferating basal layer, yet their replication and efficient gene expression is carried out in the differentiating suprabasal cells; in fact, the differentiation program is required for expression of early and late genes (4, 59, 60). It is therefore plausible that gene expression from the LCR might depend on transcription factors that are expressed in the suprabasal cells and that the virus might depend on the same machinery that is responsible for differentiation-specific expression of cellular genes in the epidermis. Several of our experiments indicate that Skn-1a may provide a potential molecular link between epidermal differentiation and HPV-1A gene expression. First, Skn-1a is highly expressed in suprabasal cells of the epidermis, and its expression in cultured keratinocytes correlates with differentiation. Second, the HPV-1A LCR contains three distinct octamer-like binding sites for Skn-1a. Third, Skn-1a stimulates transcription from the E6 promoter through these sites. While Oct-1 appears to be inactive on the HPV-1A E6 promoter, Tst-1 can stimulate this promoter to an extent similar to that of Skn-1a. Therefore, regulation of HPV-1A may be complex and may involve redundancy in function between Skn-1a and Tst-1 in epidermis.
Emerging data suggest that regulation of viral gene expression by POU domain factors may be a common mechanism. Oct-1 in association with VP-16 stimulates immediate early gene expression in the herpes simplex virus (61, 62), while Oct-2 may inhibit expression of the same genes (63). Other neuronally expressed POU domain genes, including Brn-2 and Brn-3, have been implicated in herpes simplex virus gene expression (64, 65). In addition, in vitro studies have demonstrated that several POU domains can regulate replication of adenoviruses (66). Finally, Tst-1 regulates transcription of the JC virus, a papovavirus that selectively infects glial cells (30).
We thank Richard Pearse, Charles Nelson, and Karen Squillace for contributions to this work; Michael Wegner for providing Tst-1 antisera; Wei Zhang for help with figures; and Richard Pearse and Bernd Gloss for reviewing the manuscript.