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Previous Article | Next Article 
Journal of Virology, March 1999, p. 1918-1930, Vol. 73, No. 3
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Chromatin Structure of the Long Control Region
of Human Papillomavirus Type 16 Represses Viral Oncoprotein
Expression
Walter
Stünkel and
Hans-Ulrich
Bernard*
Institute of Molecular and Cell Biology,
National University of Singapore, Republic of Singapore
Received 2 September 1998/Accepted 20 November 1998
 |
ABSTRACT |
The long control region (LCR) of human papillomavirus type 16 (HPV-16) has a size of 850 bp (about 12% of the viral genome) and
regulates transcription and replication of the viral DNA. The 5'
segment of the LCR contains transcription termination signals and a
nuclear matrix attachment region, the central segment contains an
epithelial cell-specific enhancer, and the 3' segment contains the
replication origin and the E6 promoter. Here we report observations on
the chromatin organization of this part of the HPV-16 genome. Treatment
of the nuclei of CaSki cells, a cell line with 500 intrachromosomal copies of HPV-16, with methidiumpropyl-EDTA-Fe(II) reveals nucleosomes in specific positions on the LCR and the E6 and E7 genes. One of these
nucleosomes, which we termed Ne, overlaps with the center of the viral
enhancer, while a second nucleosome, Np16, overlaps with the
replication origin and the E6 promoter. The two nucleosomes become
positioned on exactly the same segments after in vitro assembly of
chromatin on the cloned HPV-16 LCR. Primer extension mapping of DNase
I-cleaved chromatin revealed Np16 to be positioned centrally over E6
promoter elements, extending into the replication origin. Ne covers the
center of the enhancer but leaves an AP-1 site, one of the strongest
cis-responsive elements of the enhancer, unprotected. Np16,
or a combination of Np16 and Ne, represses the activity of the E6
promoter during in vitro transcription of HPV-16 chromatin. Repression
is relieved by addition of Sp1 and AP-1 transcription factors. Sp1
alters the structure of Np16 in vitro, while no changes can be observed
during the binding of AP-1. HPV-18, which has a similar arrangement of
cis-responsive elements despite its evolutionary divergence
from HPV-16, shows specific assembly in vitro of a nucleosome, Np18,
over the E1 binding site and E6 promoter elements but positioned about
90 bp 5' of the position of Np16 on the homologous HPV-16 sequences. The chromatin organization of the HPV-16 and HPV-18 genomes suggests important regulatory roles of nucleosomes during the viral life cycle.
| |
INTRODUCTION |
Human papillomavirus type 16 (HPV-16) is the clinically most prevalent virus among the approximately
30 HPV types that cause genital cancer or genital warts (32,
85), and due to this significant medical importance, the viral
life cycle and gene expression have been extensively researched.
Despite efforts to study the contributions of known
cis-responsive elements (for a review, see reference
49), some of the most interesting regulatory properties of HPV-16 are not yet understood. These poorly elucidated phenomena include transcriptional changes during the differentiation of
stratified epithelia, the regulation of transcription during latent
infection, genomic copy number control, and partition. Similar
phenomena are regulated in other viruses and some cellular genes by the
organization of DNA into chromatin and by interactions of the DNA with
complex nuclear structures, such as the nuclear matrix (see reference
70 for references). We have begun to study the
intranuclear organization of HPV-16 genomes (70) in the hope
of explaining some of these aspects of the HPV-16 life cycle.
Our research focuses on the long control region (LCR) of
papillomaviruses, which contains most of the cis-responsive
elements regulating papillomavirus biology. The LCR of HPV-16 has a
length of 850 bp and is organized similarly to the LCRs of all other genital HPVs (49). The 3' portion of the LCR contains the
replication origin (8) and the E6 promoter, which has four
cis-responsive elements, namely, one binding site for the
transcription factor Sp1, two binding sites for the viral factor E2,
and a TATA box (16, 19, 23, 24, 71). Two additional E2
binding sites are located approximately 140 and 550 bp 5' of the E6
promoter and flank the central section of the HPV-16 LCR, which
contains the epithelial cell-specific enhancer (17, 18, 26).
The enhancer, the E6 promoter, and the replication origin are
collectively flanked by two nuclear matrix attachment regions (MARs),
one located in the 5' region of the LCR and the other one located in
the E6 gene itself (70). Here, we report on the nucleosomal
organization of the LCR between and overlapping with these two MARs.
The chromosomes of eukaryotes and of double-stranded DNA viruses of
eukaryotes generally do not exist in vivo as naked DNA but rather exist
in form of chromatin, i.e., associated with nucleosomes. Nucleosomes
consist of nucleosomal cores, which are 146-bp lengths of DNA wound
around octameric histone complexes. The internucleosomal stretches of
DNA are called linker DNA and have lengths of 40 to 55 bp. The genomes
of double-stranded DNA viruses, such as simian virus 40 (SV40) and
adenoviruses, are organized in the form of nucleosomes both in the
viral capsids and in the nuclei of infected cells (20, 37, 45,
77). The nucleosomal organization of cellular and viral DNAs has
traditionally been seen as a requirement to store the bulky genomes.
More recently, it has become clear that nucleosomes can be specifically
positioned on regulatory elements, thereby constituting an important
mechanism of gene regulation (for a review and references, see
reference 81).
Most often this nucleosomal organization of eukaryotic genes interferes
negatively with gene expression (for a review, see reference
28), as efficient initiation of transcription
requires binding sites for transcription factors and RNA polymerase II to be free of nucleosomes (36), although elongation through nucleosomes is possible (67). When such sites are
inaccessible, the structure or position of preexisting nucleosomes may
be altered by specific enzymatic chromatin-remodeling activities, such
as the SWI-SNF complex (reference 79 and references
therein), nucleosomal rearrangement factor (75), chromatin
accessibility complex (76), ACF (33), or the
histone acetyltransferase activities associated with some transcription
factors (for a review, see reference 82).
Such regulatory mechanisms have been found to play a role in the life
cycle of viruses. This is particularly well documented for the DNA
genome of the retrovirus mouse mammary tumor virus (MMTV). The long
terminal repeat (LTR) of MMTV is organized in the form of six
nucleosomes. Mutual influences between one of these nucleosomes and
certain transcription factors determine promoter access and
transcriptional activation (2, 72). In another retrovirus,
human immunodeficiency virus type 1 (HIV-1), a nucleosome blocking the
transcriptional start site has to be remodeled for activation of the
virus promoter (63). In the case of SV40, it has been
reported that most of the regulatory region is normally free of
nucleosomes (4, 37). A nucleosome can form, however,
adjacent to this region and overlapping with a late promoter element
(55). In addition, nucleosomes can be assembled in vitro
overlapping with the Sp1 binding sites of the early promoter, with
flanking nucleosomes possibly being positioned due to neighbor effects
(34). Antagonistic interactions between nucleosomes and Sp1
may reduce promoter access of the transcriptional apparatus (36,
41). Access of the replication machinery to the SV40 origin of
replication is also blocked by nucleosomes, and this can be overcome by
nucleosome remodeling in the presence of T antigen (1, 57).
In the case of papillomaviruses, chromatin organization has been
established for bovine papillomavirus type 1 (BPV-1) in situ (59,
78), but it is still unclear whether nucleosomes persist on BPV-1
DNA packaged in viral particles (38). Chromatin packaging interferes with BPV-1 replication (42), although the exact
nucleosomal organization has not been studied. Here we report on the
chromatin organization of the genomes of HPV-16 and HPV-18 and on the
functional consequences of precisely positioned nucleosomes whose
positions overlap with transcription and replication elements of the
viral LCRs.
| |
MATERIALS AND METHODS |
Bacterial strains, plasmid constructs, biochemicals, and cell
lines.
Escherichia coli JM109 (recA) was used for
all DNA cloning experiments as well as for propagation and expression
of the histidine tag vectors pQE31-E2 (71) and pDS-6xHIS:YY1
(64). The transcription factors E2 and YY1 were prepared in
our lab as described below, while AP-1, Sp1, and TATA binding protein
(TBP) were commercially obtained from Promega, Madison, Wis. A segment
of the HPV-16 genome that stretches from the position 7150 to 100 (47) and includes the complete LCR was isolated by PCR and
cloned into the SrfI site of pCR-ScriptT SK(+) (Stratagene,
San Diego, Calif.). To measure the effect on luciferase gene expression
of this HPV-16 segment, the pCR-ScriptT SK(+) construct was cleaved
with SacI and KpnI and the excised HPV-16 DNA was
reinserted into the SacI- and KpnI-cleaved vector
pGL3-basic (Promega) to yield the construct pHPV-16-Luc. For the
analysis of HPV-16 chromatin structures in vivo, we used the cervical
cancer-derived cell line CaSki, which contains about 500 endogenous
HPV-16 genomes (3), under standard conditions in Dulbecco
modified Eagle medium with 10% fetal calf serum.
Expression of recombinant proteins in E. coli.
For the
expression of histidine-tagged HPV-16 E2 and cellular YY1 proteins, 400 ml of Luria-Bertani medium was inoculated with 10 ml of an overnight
culture of JM109 containing pQE31-E2 or pDS-6xHIS:YY1, respectively,
and incubated at room temperature until the bacterial suspension
reached an optical density (600 nm) of 0.6. The culture was induced
with 0.5 mM IPTG (isopropyl-
-D-thiogalactopyranoside), grown for another 4 h, pelleted, and resuspended in 25 ml of lysis buffer (20 mM HEPES [pH 7.2], 100 mM KCl, 5 mM MgCl2,
0.5% Triton X-100, 0.1% Nonidet P-40, 100 U of DNase I per ml, 1 mM
phenylmethylsulfonyl fluoride [PMSF], 1% aprotinin, 5 mg of
leupeptin per ml, and 1 mg of lysozyme per ml). After cell lysis by
sonication, 500 mM NaCl and 20 mM imidazole (Sigma, St. Louis, Mo.)
were added. The lysate was centrifuged and passed over an
Ni2+-nitrilotriacetic acid column (Qiagen,
Düsseldorf, Germany). The column was equilibrated at 4°C with
phosphate-buffered saline (PBS) (137 mM NaCl, 2.7 mM KCl, 18 mM
Na2HPO4, 1.47 mM
KH2PO4) which contained 20 mM imidazole and 1 mM dithiothreitol (DTT). To remove unspecific binding proteins, the
column was washed with PBS containing increasing amounts of imidazole
(30 to 80 mM). The final elution of the fusion protein was performed
with PBS containing 150, 180, and 200 mM imidazole, respectively, in a volume of 5 ml or less. To remove residual imidazole, the fractions containing the fusion protein (examined by sodium dodecyl sulfate [SDS]-polyacrylamide gel electrophoresis) were dialyzed against transcription buffer (60 mM KCl, 6.25 mM MgCl2, 10%
glycerol, 20 mM HEPES [pH 7.8], 0.2 mM PMSF, and 3 mM DTT).
Preparation of transcription extracts.
For in vitro
transcription experiments, nuclear extracts were prepared from HeLa
cells as described previously (21). Briefly, nuclei were
isolated in a buffer containing 20 mM HEPES (pH 7.9), 25% glycerol,
0.42 M NaCl, 1.5 mM MgCl2, 0.2 mM EDTA, and 0.5 mM DTT.
Soluble proteins were precipitated with ammonium sulfate, redissolved
in and dialyzed against transcription buffer, and stored in aliquots in
liquid nitrogen.
In vitro transcription reactions.
Transcription from
pHPV-16-Luc in the form of either naked circular plasmid DNA or in
vitro-assembled chromatin was assayed by primer extension as described
previously (11). Briefly, 250 ng of DNA was incubated with
HeLa cell nuclear extract in the presence of 1 mM ribonucleoside
triphosphates in transcription buffer in a volume of 100 µl. The
reaction was stopped after 1 h at 30°C by proteinase K treatment
followed by incubation with RNase-free DNase I (Boehringer) to destroy
the template DNA. The reaction product was monitored by primer
extension with an oligonucleotide complementary to the luciferase gene
(5'-AGTGATGTCCACCTCGATATGTGCATCTGTAAAAGC-3').
Preparation of Drosophila S190 extract for assembly
of chromatin.
The preparation of the S190 extract was carried out
as described previously (7, 35). Drosophila
strain Canton-S wild-type embryos were harvested during five successive
2-h intervals to ensure that a high fraction of embryos would be in the
preblastodermal stage. To arrest further development, the embryos were
transferred into 0.7% NaCl-0.05% Triton X-100 and kept on ice. After
extensive washing with water, the embryos were dechorionated by
treatment with a 1:1 mixture of bleach and water for 90 s at room
temperature. After being rinsed with water, the embryos were allowed to
settle in 0.7% NaCl-0.05% Triton X-100 on ice for 5 min. This step
was repeated twice. Finally, the embryos were resuspended in 0.7% NaCl, followed by two further washing steps in the same solution. Two
additional washing steps were performed in extract buffer (10 mM HEPES
[pH 7.6], 10 mM KCl, 1.5 mM MgCl2, 0.5 mM EGTA, 10% glycerol, 10 mM -glycerophosphate, 1 mM DTT, and 0.2 mM PMSF). The
embryos in extract buffer were transferred into a 15-ml Dounce homogenizer and allowed to settle, and the supernatant was aspirated. The embryo pellet was homogenized with 10 strokes of pestle B and 10 strokes of pestle A. The homogenate was centrifuged in a 15-ml Falcon
tube at 5,000 rpm in a Sorvall RT600RT B rotor. After the
centrifugation, the cytoplasmic fraction was collected and the
MgCl2 concentration was adjusted from 1.5 to 6.5 mM. The supernatant was clarified by ultracentrifugation in Beckmann 11- by
34-mm tubes in a TLS-55-rotor at 42,000 rpm for 90 min. The yellow
cytoplasmic phase was harvested by puncturing the tube between the
solid pellet and the upper lipid layer and frozen in aliquots in liquid nitrogen.
Chromatin assembly of HPV-16 DNA in vitro.
For the assembly
of pHPV-16-Luc into chromatin, we mixed 150 µl of transcription
buffer containing 10 mM -glycerophosphate and 1 mM EDTA with 500 ng
of circular plasmid DNA, 15 µl of Drosophila S190 extract
(corresponding to a protein content of 20 µg/ml), and an
ATP-regenerating system consisting of 40 mM creatine phosphate, 3 mM
ATP, 1.5 ng of creatine kinase, and 3 mM MgCl2. After
assembly of chromatin for 5 h at 30°C, each sample was split for
structural and functional analyses. In contrast to findings reported by
others (63), the S190 extract was sufficient for nucleosomal
organization of the HPV-16 templates (as proven by treatment with
micrococcal nuclease), and it was not necessary to supplement the
reaction mixture with exogenous core or linker histones.
Preparation of nuclei.
For the analysis of the chromatin
organization of the HPV-16 genome in vivo, cultured CaSki cells were
washed twice with ice-cold PBS, harvested with a rubber policeman,
centrifuged in a Sorvall RT600RT B rotor at 3,000 rpm for 5 min, and
resuspended in a buffer containing 15 mM Tris-HCl (pH 7.4), 60 mM KCl,
15 mM NaCl, 3 mM MgCl2, 0.1 mM EGTA, 0.5 mM DTT, and 0.25 M
sucrose. After addition of Nonidet P-40 (final concentration, 0.2%),
the cells were homogenized in a Dounce homogenizer with 10 strokes of a
type S pestle. The nuclei were purified from cellular debris by
centrifugation as described above. The nuclear pellet was resuspended
in the same buffer for the analysis of the chromatin structure.
MPE treatment of CaSki nuclei.
Methidiumpropyl-EDTA-Fe(II)
(MPE) cleavage was by a published protocol (13). Nuclei from
CaSki cells were resuspended in 800 µl of reaction buffer (15 mM
Tris-HCl [pH 7.4], 60 mM KCl, 15 mM NaCl, 1 mM EDTA, 0.25 M sucrose)
supplemented with 2 mM DTT and 2 mM H2O2. The
reaction was initiated with 50 µl of an MPE mixture that was prepared
by mixing equal volumes of 1 mM MPE and 1 mM
Fe(NH4)2(SO4)2 · 6H2O with subsequent 1:10 dilution in reaction buffer.
Aliquots of the reaction were taken when the reaction was stopped after
5, 10, 15, 20, 40, and 60 min with 100 µl of 0.5 mM
bathophenantrolinedisulfonate (Sigma), followed by incubation until the
color of the samples changed. After overnight treatment with proteinase
K, the samples were extracted twice with phenol, precipitated and
washed with ethanol, and treated with 100 µg of RNase A per ml. Next,
the DNA was reextracted with phenol-chloroform-isoamylalcohol (25:24:1)
and precipitated with ethanol. As a control, purified genomic DNA was
treated in a similar way.
Micrococcal nuclease treatment of in vitro-assembled
chromatin.
pHPV-16-Luc DNA (250 ng) was assembled into chromatin
with Drosophila S190 extract, supplemented with 3 mM
CaCl2, and digested with 1 to 5 U of micrococcal nuclease
(Sigma) at room temperature. The reactions were stopped after 1.5 min
by addition of 200 µl of STOP buffer (75 mM EDTA, 900 mM ammonium
acetate), and the products were digested with RNase A (100 µg/ml) for
20 min at 37°C and treated with 500 µg of proteinase K for 3 h.
Micrococcal nuclease digestion of CaSki nuclei.
CaSki nuclei
were isolated and resuspended in 400 µl of reaction buffer containing
15 mM Tris-HCl (pH 7.4), 60 mM KCl, 15 mM NaCl, 1 mM EDTA, 0.25 M
sucrose, and 2 mM DTT, supplemented with 3 mM CaCl2. The
reaction was started with 1 to 5 U of micrococcal nuclease
(Boehringer), allowed to proceed for 5 min, and stopped with 400 µl
of STOP buffer. The samples were treated with 100 µg of RNase A per
ml for 20 min and digested with 500 µg of proteinase K overnight. The
DNA was purified by standard procedures and finally subjected to
indirect end-labelling analysis as described below with the restriction
enzyme NcoI. As a control, purified genomic CaSki DNA was
treated in a similar fashion, except that micrococcal nuclease was used
in a 1:100 dilution.
DNase I treatment of in vitro-assembled HPV-16 chromatin.
The rotational and translational phasing of nucleosomes on
S190-assembled pHPV-16-Luc plasmids was determined by DNase I treatment and subsequent primer extension analysis. Samples from the chromatin assembly reaction mixture were split into two equal aliquots and assayed for transcriptional activity and nucleosomal positioning. Up to
70 ng of DNase I (Boehringer) was added to the samples, and the
reactions were stopped after 1 min of incubation at room temperature
with 100 µl of a buffer containing 450 mM sodium acetate, 0.1% SDS,
and 10 mM EDTA. The DNA was recovered by standard procedures.
Low-resolution analysis of chromatin structure by indirect
end-labelling.
For the in vivo analyses of HPV-16 chromatin
structures, 10 µg of MPE-modified DNA from CaSki cells was digested
with NcoI or EcoRI, purified, and loaded on 1.5%
agarose gels. The gels were run at 50 V for 20 h, blotted on
Hybond-N membranes (Amersham, Buckinghamshire, United Kingdom), and
probed with 32P-labelled fragments of HPV-16 DNA (High
Prime Labelling Kit; Boehringer). For the analysis of chromatin
structures assembled in vitro on pHPV-16-Luc plasmids, the DNA was
digested with micrococcal nuclease, purified, and digested to
completion with ScaI. The DNA fragments were blotted on
Hybond-N membranes and probed with a 32P-end-labelled
oligonucleotide complementary to the luciferase-gene (5'-AGTGATGTCCACCTCGATATGTGCATCTGTAAAAGC-3'). After
hybridization by standard protocols, membranes were washed in 0.1 × SSC (1 × SSC is 0.15 M NaCl plus 0.015 M sodium citrate) with
10% SDS for 20 minutes at 65°C and autoradiographed with
intensifying screens.
Primer extension footprinting of in vitro-assembled
chromatin.
High-resolution DNase I footprinting of nucleosomes
assembled in vitro on pHPV-16-Luc was performed by mapping cleavage
sites with primer extension analysis (DNase I primer extension
footprinting [52]). DNase I-treated DNA was purified
by standard procedures and used as a template for the extension
reaction with Vent (exo-) polymerase (New England Biolabs). The primer
(5'-GATCGCAGATCTCGAGCCCGGGCTAGCACG-3') was derived from the
luciferase vector. A typical reaction mixture contained 100 ng of
template DNA and 105 cpm of labelled oligonucleotide in a
reaction volume of 50 µl. After annealing of the primer at 63°C for
30 min, the enzyme mix containing deoxyribonucleotides triphosphates
was added for a 30-min reaction at 72°C. The reaction was stopped by
phenol-chloroform-isoamylalcohol extraction, and the DNA was purified
by ethanol precipitation. Pellets were dissolved in formamide loading
buffer, and the samples were denatured and loaded onto a denaturing 6%
polyacrylamide gel.
Restriction site accessibility assay.
To investigate the
accessibility of a restriction site for the enzyme PinAI at
genomic position 55 within the HPV-16 promoter, chromatin was assembled
with S190 extract in the presence or absence of Sp1 as described above.
The chromatin was purified on S400 Sephacryl mini-gel filtration
columns (600 µl), 10 U of the restriction enzyme PinAI was
added, and the samples were incubated for 1 h at 37°C. The DNA
was purified and subsequently digested to completion with 10 U of the
restriction enzyme ScaI. As a control, pure pHPV-16-Luc DNA
was digested to completion either with ScaI alone or by
subsequent treatment with ScaI and PinAI. After
purification, the DNA fragments were loaded onto a 1% agarose gel and
electrophoresed in 0.5× Tris-borate-EDTA buffer. The DNA was blotted
onto a Hybond N membrane and probed with a 32P-labelled
ScaI-KpnI fragment derived from pGL3. The
membrane was hybridized, washed, and autoradiographed by standard procedures.
| |
RESULTS |
The HPV-16 LCR in CaSki cells is organized in the form of
specifically positioned nucleosomes.
Since details of the
chromatin organization of papillomaviruses have never been studied, we
decided to investigate whether in vivo the LCR of HPV-16 is occupied by
nucleosomes. For these experiments, we chose the cell line CaSki, which
harbors about 500 chromosomally integrated HPV-16 genomes, since an
elevated copy number is a prerequisite to obtain sufficiently strong
signals in an indirect end-labelling analysis to investigate chromatin structures.
Low-resolution analysis of chromatin structure can be achieved by a
combination of treatment of nuclei with micrococcal nuclease or MPE and
subsequent indirect end-labelling analysis. Micrococcal nuclease and
MPE cleave chromatin preferentially in the linker DNA between core
nucleosomes. For many experiments, MPE cleavage is the technique of
choice, as it cleaves naked DNA randomly, while micrococcal nuclease
shows sequence preferences (30, 58).
Figure 1 shows the results of experiments
in which CaSki nuclei were treated either with micrococcal nuclease or
with MPE, followed by purification of the DNA and cleavage with the
restriction enzyme NcoI, which cuts at the end of the E7
gene. The blotted DNA was probed with labelled DNA fragments adjacent
to this restriction site as shown at the right of Fig. 1B. This
analysis revealed that in the case of the micrococcal nuclease, cuts
were centered roughly on genomic positions 7680, 7870, 14, 174, 314, 364, and 514. The cuts obtained with chromatin differed from those
obtained with free DNA and indicated nucleosomal organization, although sequence-preferential cleavage with free DNA confounds an unequivocal interpretation (Fig. 1A). Cleavage with MPE identified cuts centered roughly on genomic positions 7590, 7810, 144, 284, 344, 519, and 679, with the first three cuts falling within the LCR or about 50 bp
downstream (144 bp) and the last four cuts falling within the E6 and E7
genes. The cuts at positions 519 and 679 are less precise than the
other five, and the DNA fragments in this size range form a broader
smear, possibly due to less-conserved nucleosomal positioning in the E6
and E7 genes (Fig. 1B). The cuts obtained with these two techniques
indicated many similar sites, suggesting identical nucleosomal linkers
despite the limitation of this crude mapping technique. We also mapped
MPE cleavage from the 5' side with a probe adjacent to an
EcoRI site at position 7454 for a more precise resolution of
nucleosomal cuts in the regions of the enhancer and promoter, and we
identified preferential cuts at positions 7627, 7827, and 101 (data not
shown). It should be stressed that these experimental data are based on
low-resolution technology, and each of these cuts is identified with a
precision of only 10 to 50 nucleotides, depending on the distance from
the probe.
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FIG. 1.
The LCR and the E6 gene of the HPV-16 genome in CaSki
cells are nucleosomally organized. Nuclei were treated with increasing
amounts of micrococcal nuclease (MNase) for 5 min (A) or of MPE for 10 to 40 min (B), and total genomic DNA was purified, restricted with
NcoI separated by agarose gel electrophoresis, blotted onto
nylon membranes, and processed with a radioactive probe close to the
NcoI site, as indicated on the right of panel B. Arrows mark
fragments with increased accessibility to micrococcal nuclease or MPE.
Their sizes were estimated by comparison with a 100-bp size marker
(lanes M). A scheme on the right of each panel shows the position of
each cleavage site within the LCR of HPV-16.
|
|
Despite these limitations, our results show high accessibility of the
chromatin to micrococcal nuclease and to MPE in two regions of the LCR,
namely, at about bp 7590 to 7680 and 7810 to 7870. The former region
harbors the 5' part of the epithelial cell-specific enhancer, and the
latter harbors the 3' portion, including binding sites for the
transcription factors AP-1 and TEF-1. A third cleavage site, between
positions 101 and 144, lies immediately 3' of the LCR and within the E6
gene. These three cleavage points indicate the precise positioning of
two nucleosomes, one overlapping with the center of the enhancer, and
one upstream of E6, overlapping with the HPV-16 E6 promoter and
replication origin.
Specific positioning of in vitro-assembled nucleosomes on the
HPV-16 LCR.
Precise positions of nucleosomes can be determined by
properties of nucleotide sequences which influence physical properties, such as the curvature of this DNA. To investigate this possibility in
the case of the HPV-16 genome, we asked whether nucleosomes assembled
on the HPV-16 LCR in vitro would occupy positions similar to those
observed on the HPV-16 LCR in CaSki cells. From among the techniques
that are available for the in vitro assembly of chromatin (for a
review, see reference 22), we chose a method based
on cytoplasmic extracts from Drosophila embryos termed S190 (7). In the presence of an ATP-regenerating system, these
extracts establish physiologically spaced nucleosomes irrespective of
the source of the DNA, a consequence of the fact that histone proteins are highly conserved between Drosophila and vertebrates. The
resulting chromatin structure is best analyzed by use of micrococcal
nuclease, which cleaves the linker DNA between adjacent nucleosomes,
followed by restriction cleavage with an enzyme cutting remotely from
the DNA segment of interest and indirect end labelling with a probe that hybridizes close to these restriction cuts.
The outcome of this experiment (Fig. 2)
indicated an approximately 180-bp spacing of nuclesomes assembled on
the HPV-16 LCR in vitro, as apparent by regularly arranged fragments
after micrococcal nuclease treatment. To map the precise positions of
these nucleosomes, the purified DNA fragments were cut with the
restriction enzyme ScaI, which has two cleavage sites in the
vector sequences flanking the HPV-16 LCR. One ScaI site is
at position 254 of the vector, downstream of the HPV-16 LCR, and the
other one is at position 4717, upstream of the insert. As the
micrococcal nuclease cleaves naked DNA in a nonrandom manner
(30), we included in this experiment a direct comparison
between nucleosome-free and chromatin-associated DNA.
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FIG. 2.
Nucleosomes assembled in vitro on the LCR and the E6
gene of HPV-16 DNA are found in positions similar to those detected in
CaSki cells. pHPV-16-Luc DNA was assembled into chromatin with
Drosophila S190 extract and treated with 1, 2, 4, and 5 U of
micrococcal nuclease (MNase) (lanes 4 to 7 and 8 to 11 of each panel).
The nuclease-treated DNA was purified and fractionated on agarose gels
without further treatment by restriction endonucleases (lanes 4 to 7 of
each panel) or after digestion with ScaI (lanes 8 to 11).
The DNA was blotted, and the blots were processed either with a
proximal probe (P) (A) or with a distal probe (D) (B). As a control,
lanes 1 to 3 of each panel show the digestion patterns of micrococcal
nuclease-treated and ScaI-restricted free DNAs. The numbers on the left
indicate the sizes of the fragments in base pairs. A schematic
presentation on the right of each panel identifies within the HPV-16
LCR the MAR (M), the enhancer (E), the E6 promoter (P), the genomic
positions of micrococcal nuclease-sensitive sites (arrows), and the
predicted positions of nucleosomes (ovals).
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|
When the micrococcal nuclease treatment of the HPV-16 chromatin was
combined with ScaI cleavage and indirect end labelling with
probes hybridizing close to the upstream or the downstream ScaI site, we observed regularly spaced and precisely
positioned nucleosomes, with the strongest cuts of the micrococcal
nuclease mapping around positions 7840 and 7620 of the HPV-16 LCR.
Neither of these cleavage points appears after micrococcal nuclease
treatment of naked DNA. These data indicate that in vitro-assembled
nucleosomes occupy on the HPV-16 LCR positions very similar or
identical to those observed in CaSki cells in vivo.
A nucleosome is specifically positioned over elements of HPV-16
p97.
To improve the limited resolution of the experiments shown in
Fig. 1 and 2, we footprinted the histone-DNA interactions in the region
of the HPV-16 E6 promoter p97. Chromatin was assembled from the HPV-16
LCR and the Drosophila S190 extract, the samples were
digested with DNase I, and the cleavage sites were identified by primer
extension. Figure 3 shows the outcomes of
two similar footprint experiments. Figure 3A includes a sequence ladder
to map the locations of specific signals with the 3' side of the HPV-16
LCR. The most obvious feature (lanes 2 and 3) is the strong protection
of a segment that contains the binding site of the promoter factor Sp1,
the two E2 binding sites, and the TATA box. The nucleosomal
organization of this DNA is indicated by a 10-bp periodicity of DNase
I-accessible sites due to the rotational phasing within the nucleosome.
This periodicity is particularly clear in Fig. 3B, which, however,
permits less clear mapping of the boundaries of the nucleosome. Such a
10-bp periodicity is not visible when free DNA is treated in a similar
way (Fig. 3A, lane 1, and B, lanes 1 and 2). A particularly strong
DNase I-hypersensitive site overlaps with the promoter-proximal binding
site for the E2 protein. This increased accessibility may indicate the
dyad axis of the nucleosome (73) centered over this E2 site.
With a 5' border approximately at position 7838, the nucleosome also covers the replication origin with the E1 binding site.
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FIG. 3.
A specifically positioned nucleosome covers the promoter
of HPV-16. (A) The HPV-16 LCR cloned in pHPV-16-Luc was assembled into
chromatin with Drosophila S190 extracts and treated with
increasing amounts of DNase I, and the resulting fragments were
purified and assayed by primer extension. Lanes 2 and 3, footprints
originating from two nucleosomes that overlap with the promoter and the
enhancer (large and small oval shapes on the right). Weak 10-bp-spaced
bands (filled stars) indicate DNase I accessibility due to the
rotational phasing of the nucleosomes, and a strong hypersensitive site
(open star) suggests the center of the dyad symmetry of the nucleosome.
As controls, lane 1 shows DNase I treatment of free HPV-16 LCR DNA and
the left side of the panel indicates a sequencing ladder. Lane M, size
marker with bands at 500, 400, 300, 200, and 100 bp. Symbols and
nucleotides on the left identify the four cis-responsive
elements of the E6 promoter, namely, binding sites for Sp1, the viral
factor E2, and TBP. (B) Footprint obtained in a similar experiment and
permitting similar interpretations. It highlights the 10-bp periodicity
but does not permit clear mapping of the extent of nucleosomal
protection.
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Transcriptional repression by a nucleosome positioned over the
HPV-16 promoter is alleviated by the transcription factors AP-1 and
Sp1.
There are numerous examples of strong repressive influences
of chromatin on gene expression (28, 36, 43), while a few genes are also known to be activated by nucleosomes (44, 54, 56,
60, 69). Since accessibility of cis-responsive
elements is a necessary prerequisite for the formation of the
preinitiation complex, we asked whether the occupation of parts of the
LCR of HPV-16 by nucleosomes would have consequences for the activity of the E6 promoter. Figure 4A illustrates
that in vitro transcription starting from the E6 promoter of the free
pHPV-16-Luc DNA is gradually repressed by increasing amounts of
Drosophila S190 extract and chromatin assembly (compare lane
1 with lanes 2 to 6). To ensure that repression of transcriptional
activity was due to chromatin, we added the S190 extract concomitantly
with the transcription extract. The outcome of this experiment is shown
in Fig. 4B (lanes 2 to 4). We conclude that nonhistone components in
the S190 extract do not interfere with accurate transcription from the
HPV-16 promoter. As a further control, we ensured that the factors Sp1
and AP-1 were not limiting in the basic transcriptional system. Lanes 6 to 11 of Fig. 4B confirm that an excess of AP-1 and Sp1 does not superstimulate transcription of nonchromatin templates.
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FIG. 4.
Nucleosomal assembly leads to transcriptional repression
of the HPV-16 promoter. (A) Analyses of in vitro transcription from
free pHPV-16-Luc DNA (lane 1) or the same plasmid assembled into
nucleosomes by increasing amounts of Drosophila S190 extract
(lanes 2 to 6). Lane M, 100-bp ladder serving as size standard. The
specific transcript initiated at the HPV-16 E6 promoter is indicated by
an arrow on the right. (B) The Drosophila S190 extract does
not contain nonhistone components that might inhibit in vitro
transcription, as shown by the addition of 20, 50, and 70 µl of S190
extract (lanes 2 to 4, respectively) at the beginning of an in vitro
transcription reaction with nucleosome-free DNA (lane 1). As a further
control, we ensured that the factors Sp1 and AP-1 are not limiting in
the basic transcriptional system. Lanes 6 to 11 confirm that an excess
of AP-1 and Sp1 does not superstimulate transcription of nonchromatin
templates.
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Next, we asked whether transcription factors that are known to activate
HPV-16 expression would be able to relieve this repression when they
are added shortly after initiation of the assembly process. For this we
chose the transcription factor AP-1, which binds fp9e (27),
a site 3' of the enhancer, at a position about 70 bp upstream of the
nucleosome that occupies the HPV-16 promoter in vitro and between the
two nucleosomes mapped on the LCR in vivo. Similarly, we measured the
effects of the factors Sp1, E2, YY1, and TBP, whose binding sites
overlap with the promoter proximal nucleosome. There was an activation
of transcription from the chromatin templates by AP-1 and Sp1 (Fig.
5A, lanes 3 to 5 and 8 to 10), whereas
YY1 (Fig. 5B, lanes 8 to 11) and E2 (data not shown) did not relieve the nucleosomal repression. In addition, there was weak activation by
TBP, which was visible only after exposure of the autoradiograph for 2 days (Fig. 5B, lanes 3 to 6).
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FIG. 5.
Relief of nucleosomal transcriptional repression by
trans-acting factors. (A) AP-1 (lanes 3 to 5) and Sp1 (lanes
8 to 10), added 15 min after initiation of chromatin assembly on
pHPV-16-Luc, activate in vitro transcription from the E6 promoter.
Specific transcripts were detected by primer extension (arrow). The
same transcript is generated from free DNA in the absence of chromatin
and an excess of any additional factor (lanes 1 and 6) but is repressed
by chromatin alone (lanes 2 and 7). (B) Under the same conditions as
used for panel A, TBP (lanes 3 to 6) marginally induces a nucleosomally
organized E6 LCR, while YY1 (lanes 8 to 11) fails to do so. Lane 1, transcription of nucleosome-free DNA; lanes 2 and 7, repression of
transcription by nucleosomes. To detect the weak signals of the
transcriptional induction by TBP, this blot was exposed five times
longer than the blot shown in panel A. YY1 has a strong binding site
within the promoter sequence covered by the nucleosome, which does not
lead to transcriptional repression in transfection experiments, while
additional YY1 sites remote from the promoter and possibly protected by
the upstream nucleosome may negatively interfere with transcription
independent from the chromatin state of the HPV-16 LCR (50).
(C) AP-1 (lanes 3 to 5) and Sp1 (lanes 7 to 9) can activate in vitro
transcription from the E6 promoter even when added at a late stage of
chromatin assembly. The conditions of this experiment resembled those
for panel A, but the transcription factors were added 3.5 h after
initiation of chromatin assembly. Lane 1, transcription from naked DNA,
lanes 2 and 6, transcription from chromatin in the absence of
additional factors. (D) Schematic diagram of the experiments in panels
A and C. NTP, nucleoside triphosphate.
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The experiments shown in Fig. 5A were performed under conditions in
which formation of chromatin and transcription factor binding could
each occur, mimicking conditions in which competition for transcription
factor binding sites and nucleosomal positioning may take place. To
investigate whether these factors may also counteract nucleosomal
repression after a more stable establishment of chromatin, we took a
similar experimental approach but added the transcription factors
3.5 h after initiating the assembly of chromatin, such that the
establishment of chromatin is nearly complete (Fig. 5D). Figure 5C
shows that AP-1 and Sp1 maintained the ability to activate repressed
transcription under these circumstances (lanes 3 to 5 and 7 to 9),
while the basal transcription factor TBP had lost its ability to do so
(data not shown).
Rearrangement of the promoter-bound nucleosome by Sp1.
We next
asked by which mechanisms AP-1 and Sp1 may relieve nucleosomal
repression of p97. It is unlikely that both transcription factors act
by the same mechanism, as the principal AP-1 binding site of HPV-16
(fp9e [27]) does not overlap with either of the nucleosomes attached to the enhancer or to p97 sequences, while Sp1
binds this promoter at nucleotide sequences fully protected by the
nucleosome. Figure 6A shows that an
increase in the concentration of Sp1 even at a late stage of the
chromatin assembly process led to a change of the nucleosomal footprint
as well as the hypersensitivity around the E2 binding site. In
addition, the nucleosomal 10-bp pattern became less pronounced (lanes 5 and 6). These changes became even more pronounced when the
transcription extract was added to the prebound Sp1 (data not shown).
In contrast to Sp1, AP-1 did not affect the structure of the
nucleosomal footprint (Fig. 6A, lanes 7 and 8).
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FIG. 6.
Sp1 can rearrange the structure of the E6 promoter-bound
nucleosome. (A) pHPV-16-Luc DNA was assembled into chromatin, subjected
to DNase I treatment, and processed as described for Fig. 3 to
visualize the nucleosomal footprints overlapping with the HPV-16 E6
promoter (lanes 4 to 8) and enhancer (large and small oval shapes,
respectively, on the right). Weak 10-bp-spaced bands (filled stars)
indicate DNase I accessibility due to the rotational phasing of the
nucleosomal core, and a strong hypersensitive site (open star) is most
likely the center of the dyad symmetry of the nucleosome. As controls,
lanes 1 to 3 show DNase I treatment of free HPV-16 LCR DNA. A
nucleosome (Np16) protects four cis-responsive elements of
the E6 promoter, namely, binding sites for Sp1, the viral factor E2,
TBP, and a YY1 site (brackets on the right of the oval shape). Sp1
(lanes 5 and 6) or AP-1 (lanes 7 and 8) was added 3.5 h after
start of the chromatin assembly and in the case of Sp1 resulted in the
reemergence of the cleavage pattern of the free DNA and the
disappearance of nucleosome-specific DNase I-hypersensitive sites. Lane
M, markers. (B) Schematic representation of an HPV-16 LCR clone from
position 7150 to 100 in the vector pGI3. The enzyme ScaI
cleaves in vector sequences on both sides of the cloned segment;
PinAI cleaves at position 55 in the promoter sequences of
HPV-16. (C) Southern blot of a ScaI digest (lane 1) and a
ScaI-PinAI double digest (lane 2). The
ScaI-PinAI fragment is released inefficiently in
the presence of chromatin (lanes 3 and 4) but efficiently with
increasing Sp1 concentrations (lanes 5 and 6). This blot was processed
with a radioactive probe specific for the
ScaI-PinAI fragment.
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As an additional control for the rearrangement of this nucleosome by
Sp1, we monitored the accessibility of a restriction site in the
nucleosomally protected region in the absence and presence of Sp1. The
restriction enzyme PinAI cleaves the hexanucleotide ACCGGT,
which occurs in the HPV-16 promoter at the genomic position 55 and
forms the 3' part of the promoter-proximal E2 binding site. Two
ScaI sites in the vector pGL3 (Fig. 6B) permit excision of the cloned HPV-16 LCR segment, which can be further cleaved with PinAI (Fig. 6C, lanes 1 and 2). This cleavage occurs very
inefficiently when the HPV-16 DNA is organized as chromatin (Fig. 6C,
lanes 3 and 4, lower band) but efficiently in the presence of Sp1
(lanes 5 and 6). We conclude that the PinAI site becomes
more accessible by binding of Sp1 to a site 30 bp 5' of the
PinAI site with concomitant rearrangement or displacement of
the nucleosome positioned over both sequence elements.
A specifically positioned nucleosome binds the HPV-18 replication
origin after assembly of chromatin in vitro.
The nucleotide
sequences of the LCRs of HPV-16 and HPV-18 show little similarity but
conserve most cis-responsive elements. On the 3' side within
the LCR, there are three binding sites for the E2 protein, one of the
replication factor E1, and one each for Sp1 and TBP (31,
49). It is of interest to ask whether the chromatin organization
in both viruses may also be conserved. We addressed this question by
assembling chromatin in vitro on the HPV-18 LCR and examining by primer
extension footprinting the position of a potential nucleosome forming
on this segment. Figure 7 (lanes 3 to 7)
shows that a nucleosome occupies a highly specific position in the 3'
segment of the HPV-18 LCR. This nucleosome is positioned about 90 bp 5' from the equivalent position of the HPV-16 promoter, with the
center of symmetry apparently overlapping with the third E2 binding
site upstream of the HPV-18 E6 promoter. The downstream end of the
nucleosome occupies the E1 binding site and extends to the Sp1 binding
site, leaving the two promoter-proximal E2 binding sites and the TATA
box unprotected.
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FIG. 7.
A specifically positioned nucleosome covers the
replication origin of HPV-18 and extends into E6 promoter sequences.
The cloned HPV-18 LCR was assembled into chromatin with
Drosophila S190 extracts and treated with increasing amounts
of DNase I, and the resulting fragments were assayed by primer
extension. Lanes 3 to 7 show, with increasing DNase I treatment, the
footprint of a nucleosome overlapping the replication origin (distal E2
and E1 binding site), indicated by a large hatched oval on the right.
Weak 10-bp-spaced bands (filled stars) indicate DNase I accessibility
due to the rotational phasing of the nucleosomal organization, and a
strong hypersensitivity site (open star) suggests the center of the
dyad symmetry of the nucleosome. As controls, lanes 1 and 2 show DNase
I treatment of free HPV-18 LCR DNA, and the left side shows a
sequencing ladder of this sequence. Lane M, size marker with bands at
500, 400, 300, 200, and 100 bp. Symbols and nucleotides on the right
identify the third E2 binding site from the E6 promoter, the E1 binding
site, and one of the four cis-responsive elements of the E6
promoter, namely, the binding site for Sp1.
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DISCUSSION |
Nucleosomal organization of the L1-LCR-E6-E7 segment of
HPV-16.
Figure 8 summarizes the
positions of nucleosomes on a 1.5-kb segment of HPV-16 (about 20% of
the viral genome) from the end of the L1 gene to the center of the E7
gene. In CaSki cells (Fig. 8B and C), three nucleosomes are located
overlapping with the LCR. MPE cleavage in vivo suggests the presence of
three additional nucleosomes within the E6 gene and the 5' part of E7.
Multiple cleavage sites in the nucleosomal linker DNA suggest loose
positioning of some of these nucleosomes. Nucleosomal positioning is
not precise in the 5' segment of the LCR, since a nucleosome
overlapping with the MAR and the 5' side of the enhancer protects an
unusually long DNA segment, as to be expected from nucleosomes forming
on nuclear MARs (10). One nucleosome (Ne) overlaps with the
center of the enhancer, and another (Np16) overlaps with the
replication origin and the E6 promoter. The position of at least one of
these nucleosomes, Np16, seems to be determined by intrinsic properties of the HPV-16 DNA sequences, as micrococcal nuclease mapping of in
vitro-assembled nucleosomes indicates a position of Np16 similar or
identical to that determined by MPE mapping of CaSki chromatin (Fig.
8D).
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FIG. 8.
Nucleosomal organization of the LCR of HPV-16. (A)
Genomic segment of HPV-16 with a size of approximately 1.5 kb. The LCR
has a size of 850 bp and includes an MAR, the epithelial cell-specific
enhancer, the replication origin (repl. origin), and the E6 promoter
(arrow) and is flanked by the L1 and E6 genes. The bar below the 3'
side of the enhancer, the replication origin, and the promoter
highlights the genomic fragment that has been studied in both HPV-16
and HPV-18 by footprint analysis to map specifically positioned
nucleosomes. (B) MPE-hypersensitive sites in HPV-16 chromatin in CaSki
cells permit the mapping of the positions of six nucleosomes relative
to an NcoI site, which is positioned downstream of this
segment. A double-headed arrow above the leftmost nucleosome, which
overlaps with the MAR, indicates a region of protection whose size
exceeds that for the normal protection by a nucleosome, possibly due to
alternative positions of a nucleosome. The nucleosome (Ne) between the
MPE cuts at position 7590 and 7810 overlaps with the epithelial
cell-specific enhancer, and the third nucleosome (Np), between
positions 7810 and 144, overlaps with the replication origin and the E6
promoter. Three additional nucleosomes are positioned within the E6
gene and at the 5' end of the E7 gene, respectively. (C and D) The
positions of four nucleosomes on the HPV-16 LCR in CaSki cells mapped
with an upstream probe (hybridizing close to the EcoRI site
at position 7456) are in agreement with the data obtianed with the
NcoI probe, and at least two of these nucleosomes are
positioned identically after assembly of chromatin in vitro (data not
shown). (E and F) One of these nucleosomes was footprinted, and its
center apparently overlaps with two E2 binding sites at the E6
promoter. The protection of this nucleosome includes the TBP binding
site, the Sp1 binding site, and the binding site for the replication
factor E1. (G) In HPV-18, which has a similar arrangement of elements
of the replication origin and the E6 promoter, a nucleosome (Np18) it
positioned about 90 bp further upstream from the E6 promoter, extending
to and partially protecting the promoter elements. The HPV-16 DNA, and
possibly also the DNA of HPV-18, may position in vitro the Ne
nucleosome, which overlaps with the core of the epithelial
cell-specific enhancer, but leave the 3' side of the enhancer with a
strong AP-1 site unprotected.
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Most nucleosomes that exist in eukaryotic and viral chromatin are
probably not specifically positioned (65) and most often assume random positions by sliding freely along any particular DNA
segment (46, 53). It is well known, however, that the sequences of particular nucleotide segments can affect physical properties, like their curvature, and these properties may determine the precise position of nucleosomes (25, 29). Surprisingly, in the case of the majority of the few carefully studied genes, nucleosomes were found to occupy specific positions relative to regulatory DNA sequences (for reviews, see references
6 and 80). Paradigms for this
scenario have been the promoter on the LTR of MMTV (2, 14, 58, 72,
73) and the promoters of the Xenopus 5S rRNA genes
(reference 61 and references therein). Additional
examples include the promoters for the Xenopus vitellogenin B1 gene (60), the human U6 gene (69), rat
tyrosine aminotransferase (12), Drosophila hsp26
and hsp27 (44), Xenopus TFIIIA (54), and HIV-1 (52, 62) and the late promoter of SV40
(55). For some of these genes it has been proposed that only
one or a few nucleosomes are specifically positioned, due to underlying
structural properties of the DNA, while neighboring nucleosomes may be
arranged in a regular array relative to a specifically positioned
nucleosome, thereby also binding a constant segment.
Replication origin and E6 promoter sequences of HPV-16 and HPV-18
are occupied by specifically positioned nucleosomes.
The
nucleosome Np16, and Np18 in the equivalent genomic segment of HPV-18,
could be mapped with reasonable precision by primer extension
footprinting experiments in vitro (Fig. 3 and 7). It is technically
challenging to determine the precise borders of a nucleosomal footprint
in the manner of a footprint generated by a DNA-bound transcription
factor, but a 10-bp spacing of DNA fragments reveals the extent of a
nucleosomal organization, and several bands originating from strong
DNase I hypersensitivity within Np16 and Np18 most likely identify the
center of dyad symmetry of each nucleosome. Interestingly, both DNase
I-hypersensitive sites overlap with E2 binding motifs: in the case of
Np16 with the promoter-proximal E2 binding site (Fig. 8E and F) and in
the case of Np18 with the third E2 binding site, 90 bp upstream and within the homologous elements of HPV-18. While the exact positions of
these nucleosomes differ for the two viruses in vitro, similar cis-responsive elements, namely, the E1 binding site
necessary for replication and the Sp1 binding site that activates the
E6 promoter, fall in the 146-bp segment protected by the nucleosomal core. These overlaps suggest a nucleosomal effect on replication as
well as transcription in both viruses, but knowledge of details of
these functional consequences beyond the repression of HPV-16 transcription studied here has to await future investigations.
Nucleosomal repression of the HPV-16 E6 promoter and derepression
by AP-1 and Sp1.
Our in vitro transcription experiments document
that usage of the E6 promoter is impeded as a consequence of the
nucleosomal organization of the HPV-16 LCR, most likely due to impaired
accessibility of the promoter sequences by Sp1 and the basic
transcription machinery. This explanation is strengthened by the
observation that an excess of Sp1 can functionally overcome this
repression, apparently by altering or displacing the promoter
nucleosome Np16. At this time we can offer only this very general
explanation, as research on the interaction between nucleosomes and
transcription factors on other promoters has shown that physical
displacement or competitive binding applies to only some of these
promoters (68), while other factor-nucleosome interactions
are governed by more complex mechanisms (74). For example,
in the case of a nucleosome blocking the MMTV LTR promoter, a complex
interaction between the glucocorticoid receptor and other transcription
factors with the nucleosomal remodeling activity of the SWI-SNF complex
is required to permit access to cognate binding sites (66).
In another case, a nucleosome on the promoter of the Xenopus
oocyte 5S rRNA gene can slide freely, but it is forced into a specific
position by interacting with histone H1, which recognizes a specific
nucleotide sequence of this promoter. As a consequence, H1
overexpression represses this promoter (61).
There is a viral precedent for repression due to interference between
nucleosomes and Sp1. Sp1 has six binding sites at the SV40 early
promoter; however, nucleosomally organized SV40 DNA is bound by Sp1
with 10- to 20-fold-lower affinity than naked DNA. Access to these
sites by Sp1 involves formation of a ternary Sp1-nucleosome-DNA
complex. It was observed that activation by Sp1 involves stepwise
nucleosomal disassembly, particularly when aided by the addition of
nucleosplasmin, and removal of H2A-H2B dimers by the SWI-SNF complex
enables transcription factors to bind (15, 41).
Some aspects of the abolition of nucleosomal repression by AP-1 have
become clear with the detection of histone acetyltransferase activity
of CREB binding protein, a transcriptional cofactor of AP-1.
Acetylation destabilizes the interaction between histones and DNA,
alters the shape of the octamer (5), and can open the way
for increased accessibility by transcription factors (48, 83,
84).
There is also evidence for a change of chromatin under the influence of
the papillomavirus transcription factor E2 (40). As this
factor represses the HPV E6 promoter due to displacement of Sp1 and TBP
(19, 71) irrespective of nucleosomal biology, we did not
investigate whether its presence alters the chromatin structures of the
HPV-16 and HPV-18 LCRs.
Potential consequences of the HPV chromatin organization for
replication, transcription, and the viral life cycle.
The
presently available technology does not permit studies of in which
parts of the HPV life cycle transcriptional control by nucleosomes may
take place, as this would require information about the HPV chromatin
state in very small cell populations, such as basal, suprabasal, or
differentiated layers of squamous epithelia, which even epithelial raft
cultures (51) may not provide. We suggest, however, that
chromatin actually does repress HPV-16 transcription in CaSki cells, as
the signals that we observed after MPE cleavage suggest that the
majority of the 500 HPV-16 genomes exhibit specifically positioned Ne
and Np16 nucleosomes on the HPV-16 enhancer and promoter. This may
explain the well-discussed enigma that SiHa and CaSki cells, which
contain 1 and 500 HPV-16 genomes, respectively, show similar viral
transcription levels (3, 9). It is tempting to speculate
about whether the single integrated HPV-16 genome in SiHa cells may
show the same or a different nucleosomal positioning. We have attempted
to answer this question but have found that the analysis of a single
genomic copy exceeded the sensitivity of the available technology.
HPV-16 shows analogies with HIV-1 as to the transcriptional regulation
by chromatin. The DNA genome of HIV-1 has one nucleosome specifically
positioned overlapping with the transcription start and another one in
a remote upstream position. Remodeling of HIV-1 chromatin occurs in
response to mitogenic signals and is mechanistically influenced by
multiple transcription factors, but it apparently results in only a
small fraction of all viral templates being active in any round of
transcription. It is likely that chromatin represses transcription
during latency in vivo, although details of these mechanisms were
gleaned from in vitro studies (39, 62, 63).
Our research did not address the possibility of HPV-16 and HPV-18
replication being modulated by chromatin. This is quite likely, because
Np16 and Np18 overlap with the respective E1 binding sites. Without
knowledge of nucleosomal positioning, it has been reported that
nucleosomes can repress BPV-1 replication and that this repression can
be relieved by E2 and acidic transcription factors (42). A
careful mechanistic study of replication control by chromatin has shown
that the exact distance between a nucleosome and the yeast replication
origin ARS1 determines accessibility to the replication machinery
(65), and in vitro studies of SV40 replication pointed to
the ability of the chromatin accessibility complex to stimulate
nucleosomally repressed replication (1).
| |
ACKNOWLEDGMENT |
We are grateful to Robin M. Watts for discussions and critical
reading of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular and Cell Biology, National University of Singapore, 30 Medical Dr., Singapore 117609. Phone: 65-874-3755. Fax: 65-779-1117. E-mail: mcbhub{at}mcbsgs1.imcb.nus.edu.sg.
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Top
Abstract
Introduction
