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Previous Article | Next Article 
J Virol, February 1998, p. 1504-1515, Vol. 72, No. 2
Microbiology and Tumorbiology Center,
Karolinska Institute, 171 77 Stockholm, Sweden
Received 14 August 1997/Accepted 3 November 1997
Human papillomavirus capsid proteins L1 and L2 are detected only in
terminally differentiated cells, indicating that expression of the L1
and L2 genes is blocked in dividing cells. The results presented here
establish that the human papillomavirus type 16 L2 coding region
contains cis-acting inhibitory sequences. When placed
downstream of a reporter gene, the human papillomavirus type 16 L2
sequence reduced both mRNA and protein levels in an orientation-dependent manner. Deletion analysis revealed that the L2
sequence contains two cis-acting inhibitory RNA regions. We
identified an inhibitory region in the 5'-most 845 nucleotides of L2
that acted by reducing cytoplasmic mRNA stability and a second, weaker
inhibitory region in the 3' end of L2. In contrast, human
papillomavirus type 1 L1 and L2 genes did not encode strong inhibitory
sequences. This result is consistent with observations of high virus
production in human papillomavirus type 1-infected tissue, whereas only
low levels of human papillomavirus type 16 virions are detectable in
infected epithelium. The presence of inhibitory sequences in the L1 and
L2 mRNAs may aid the virus in avoiding the host immunosurveillance and
in establishing persistent infections.
Human papillomaviruses (HPVs) are
nonenveloped DNA tumor viruses that can induce a variety of
proliferative lesions upon infection of epithelial cells (28, 53,
70, 72). To date, more than 70 different HPV types have been
identified (24). Each of these types infects either mucosal
or cutaneous epithelium at distinct anatomical sites. Members of a
subset of the HPV types are etiological agents of cancers, e.g.,
HPV-16, and are referred to as high-risk types, whereas certain HPV
types are rarely or never found in cancers, e.g., HPV-1, and are
referred to as low-risk types (28, 35, 53, 71). HPV-1
infects cutaneous epithelium at the plantar surface of the foot,
whereas HPV-16 shows tropism for mucosal epithelial cells.
The production of HPV virions is strictly linked to the differentiation
stage of the infected epithelial cell, and viral late-gene products, L1
and L2 (Fig. 1), are detected primarily
in the terminally differentiated cells in the upper layers of the
epithelium (11, 23, 32, 33, 53, 56, 61). One reason for the
restriction of HPV late-gene expression to terminally differentiated
cells and for the differences observed in the levels of expression of late-gene products from various HPV types may be the presence of
negative regulatory elements in the HPV late mRNAs. Such elements were originally described by Kennedy et al. (29, 30), who reported the identification of an inhibitory sequence in the HPV-16 late 3' untranslated region (UTR) (Fig. 1) which acted by reducing mRNA
stability in vitro. Other investigators proposed that the activity of
this negative regulatory element required the presence of a 5' splice
site-like sequence (21). In an attempt to produce HPV-16 L1
from eucaryotic expression plasmids encoding L1 cDNAs, we reasoned that
deletion of the negative sequence in the late 3' UTR would allow high
L1 production. However, deletion of the late 3' UTR from an HPV-16 L1
cDNA did not result in the production of detectable levels of L1
(58), indicating that the L1 coding region itself contained
sequences that inhibit L1 production. These sequences acted in
cis and inhibited the expression of a reporter gene to the
extent of several hundredfold (58). Subsequent experiments
demonstrated that inhibitory sequences were located primarily in the 5'
half of the L1 coding region and spanned several hundred nucleotides
(58).
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
mRNA Instability Elements in the Human
Papillomavirus Type 16 L2 Coding Region
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
View larger version (11K):
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FIG. 1.
Genomic map of HPV-16. Numbers indicate nucleotide
positions (51), the shaded box indicates the L2 coding
region, and the white box indicates the L1 coding region. NCR,
noncoding region, containing the late 3' UTR; pA, HPV-16 late
polyadenylation signal.
In the work described here, we investigated if HPV-16 L2 (Fig. 1) contains sequences that negatively affect L2 expression levels. The results presented here demonstrate that the HPV-16 L2 coding region contains cis-acting inhibitory RNA sequences that act by reducing mRNA and protein levels. A sequence in the 5' end of HPV-16 L2 acted as an mRNA instability determinant, and a weaker, posttranscriptionally active sequence was found in the 3' end of L2. We also show that the HPV-1 L1 and L2 coding regions do not contain strong inhibitory sequences. HPV-1 virions are easily detected in vivo, whereas HPV-16 virions are not. Therefore, the presence of inhibitory sequences in L1 and L2 correlates with the amounts of virus produced in vivo.
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MATERIALS AND METHODS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Plasmid constructions. The following plasmids have been described elsewhere: pE55 (59), pNLCATW (58), and pCS1X (58); pC16L1(A) and pC16L1(S) have been described as pCATL1A and pCATL1S (58), respectively, and pT7-16L2 has been described as pT7L2 (25).
pH16L2 was generated by excising a BssHII-KpnI fragment from pT7-16L2, followed by insertion into BssHII- and KpnI-digested pNLCATW (58), thereby replacing the chloramphenicol acetyltransferase (CAT) gene with the HPV-16 L2 open reading frame (ORF). To generate pCMV16L2, the HPV-16 L2 coding region was PCR amplified with oligonucleotides L2START (5'-CAGCGCGCCCTTAACAATGCGACACAAACG-3') and L2STOP (5'-CAGTCGACCGTGGCCTCACTAGGCAGCC-3') and inserted into HpaI-digested, calf intestinal alkaline phosphatase (CIAP)-treated pLNCX (36). pC16L2(S) and pC16L2(A) were produced by subcloning, in the sense and antisense orientations, respectively, an HPV-16 L2 DNA fragment that had been PCR amplified from pT7-16L2 with oligonucleotides L2START and L2STOP into Asp718-digested, Klenow fragment-treated pNLCATW (58). pC16L2-Stop was constructed by annealing oligonucleotide GC-BAMHI (5'-CGCGCGGGGGGGGGGGGGGGGGGGGGGGGATCCCCCCCCCCCCCCCCCCCCCCCCG-3'), followed by subcloning into pC16L2(S) that had been digested with BssHII and treated with CIAP. Digestion of pC16L2(S) with MluI and BssHII, followed by T4 DNA polymerase treatment and religation, generated p16L2
C. pCL2D was generated by
digestion of pC16L2(S) with SalI and SpeI and
religation. To generate pCL2C, pC16L2(S) was digested completely with
SalI and partially with SpeI and religated. A
fragment that had been PCR amplified from pT7-16L2 with
oligonucleotides L2START and L2M (5'-CGTCGACCTGGAGCTATATTAATAC-3') was ligated into pBluescript that had been digested with
EcoRV and treated with CIAP, generating pKSL2B. To generate
pCL2B, a BssHII-SalI fragment from pKSL2B was
ligated to pC16L2(S) that had been digested with MluI and
SalI. pCL2A was constructed by digestion of pC16L2(S) with
SpeI, followed by religation. pCL2R1, pCL2R2, pCL2R4,
pCL2R5, and pCL2R7 were constructed by insertion into
Asp718-digested, Klenow fragment-treated pNLCATW
(58) of HPV-16 L2 DNA fragments that had been PCR amplified
with the following primer pairs: L2D
(5'-CGTCGACGGAATTAATGAAGGAGCTTGG-3') and L2B (5'-CACGCGTCAGTAACTAGTAGCACACCCA-3'), L2C
(5'-CACGCGTAATATAGCTCCAGATCCTGAC-3') and L2STOP, L2B and L2G
(5'-CGTCGACGGATCAATAGTACTTAAA-3'), L2E (5'-CACGCGTCTATTGATCCTGCAGAAG-3') and L2STOP, and L2C and
L2D. To generate pL2HU(S) and pL2HU(A), HPV-16 L2 sequences were PCR amplified with oligonucleotides L2B and L2STOP and inserted in the
sense and antisense orientations, respectively, into
StuI-digested pNLCATW (58).
pC1L1(S) and pC1L1(A) were generated by subcloning into
Asp718-digested, Klenow fragment-treated, CIAP-treated
pNLCATW (58), in the sense and antisense orientations,
respectively, HPV-1 L1 sequences that had been PCR amplified from
pHPV-1 (17) with oligonucleotides H1L1STOP
(5'-GTTATATAGAATTCATACTAAGCC-3') and H1L1START
(5'-AGCGTCGACAAAGAGCTTATGT-3'). pC1L2(S) and pC1L2(A) were
generated by subcloning into Asp718-digested, Klenow
fragment-treated pNLCATW (58), in the sense and antisense
orientations, respectively, HPV-1 L2 sequences that had been PCR
amplified with H1L2S (5'-CGTCGACGTAACAAATGTATCGCCTACG-3') and H1L2A (5'-AGAATTCCATTATACATAAGCTCTTTTACG-3').
pHCMVtat was constructed by subcloning a
SalI-HpaI human immunodeficiency virus type 1 (HIV-1) Tat-encoding fragment from pNL147 (48) into
SalI- and HpaI-digested pCH16pA (58).
pKSNLCAT was generated by ligation of a
HindIII-EcoRI fragment from pNLCATW into
pBluescript (Stratagene) that had been digested with
HindIII and EcoRI.
Cells, transfections, and CAT ELISA. For transfection of adherent cells (HLtat [48], 293, NIH 3T3, BHK-21, and CV-1), 3 × 105 cells were seeded per 60-mm-diameter plate 24 h prior to transfection. Plasmid pHCMVtat, producing HIV-1 Tat, was included in transfections. Transient transfections were carried out by the calcium phosphate coprecipitation technique (22) as described previously (60). For suspended cells (Jurkat and U937), 106 cells were transfected with Lipofectamine (Life Technologies) according to the manufacturer's instructions. The cells were harvested 20 to 48 h posttransfection, and the amount of CAT protein was quantified in a CAT antigen capture enzyme-linked immunosorbent assay (ELISA; Boehringer GmbH). pCS1X (58) was included as an internal control in each transfection experiment, and secreted alkaline phosphatase (SEAP) activity was determined as previously described (58). In transfections executed for downstream RNA analysis, pHCMVtat was included as an internal control. When the vaccinia virus T7 RNA polymerase expression system (20) was used, cells were infected with 0.5 × 106 PFU of recombinant vaccinia virus vTF7-3 (20) expressing T7 RNA polymerase 1 to 2 h prior to transfection. Each experiment was repeated at least three times, and mean values of representative results are shown.
RNA preparation and primer extension. Total cytoplasmic RNA was prepared from transfected HeLa or HLtat cells as previously described (60). For fractionation and preparation of nuclear RNA, the cells were lysed directly in culture dishes with Nonidet P-40 (NP-40) lysis buffer (10 mM Tris-Cl [pH 7.5], 150 mM NaCl, 1.5 mM MgCl2, 0.65% [NP-40 Sigma]). The nuclei were washed three times in NP-40 lysis buffer and then scraped off the culture dishes into 250 µl of NP-40 lysis buffer with a rubber policeman. Nuclei from two 60-mm-diameter culture dishes were pooled. Sodium dodecyl sulfate (SDS) was added to a final concentration of 0.2%, and nuclei were lysed on ice for 5 min, with repeated vortexing. Following freezing-thawing on dry ice and at 37°C, the samples were treated with DNase I for 10 min at 37°C. The samples were extracted twice with an equal volume of phenol-chloroform [at a ratio of 1:1; phenol was equilibrated in 1 M 3-(N-morpholino)propanesulfonic acid (MOPS; pH 6.0)], followed by extraction with chloroform and ethanol precipitation. Pellets were resuspended in water, RNA was quantified by spectrophotometry, and the quality of the RNA was checked on agarose gels.
Primer extension was carried out by coprecipitating 50 µg of nuclear or cytoplasmic RNA with 105 cpm of [
-32P]ATP-labelled oligonucleotides NL-PX2
(5'-GGGCACACACTACTTTGAG-3'), CMV-PX3
(5'-TGGATCGGTCCCGGTGTCTT-3'), and 47S-PX6
(5'-GCCAGAGCCCCGCGCGCATC-3'). Oligonucleotide NL-PX2
hybridizes to the 5' end of mRNA transcribed from the HIV-1 long
terminal repeat (LTR) promoter, oligonucleotide CMV-PX3 hybridizes to
the 5' end of mRNA transcribed from the human cytomegalovirus (CMV)
immediate-early promoter, and oligonucleotide 47S-PX6 hybridizes to the
5' end of the 47S rRNA precursor transcript. Annealing was performed by
resuspending the RNA pellet in 8 µl of 1× RT buffer (50 mM Tris-Cl
[pH 8.3], 75 mM KCl, 3 mM MgCl2, 0.5 mM each
deoxynucleoside triphosphate [dNTP]), followed by incubation at
65°C for 1 min, at 37°C for 1 min, and on ice for 1 min. cDNA
synthesis was carried out by adding 8 µl of 1× RT mixture (50 mM
Tris-Cl [pH 8.3], 75 mM KCl, 3 mM MgCl2, 10 mM dithiothreitol, 0.5 mM each dNTP, 5 U of Molony murine leukemia virus
reverse transcriptase [Life Technologies] per µl, 0.25 U of RNA
Guard [Pharmacia] per µl), followed by incubation at 42°C for 60 min. The reaction was stopped by RNase treatment (1 µg of RNase A and
20 U of RNase T1 [Ambion]) at 37°C for 10 min, followed
by ethanol precipitation. The pellet was resuspended in formamide
loading dye (80% deionized formamide, 1 mM EDTA, 0.1% bromphenol
blue, 0.1% xylene cyanol), and the suspension was boiled for 2 min.
The reaction products were separated on 6% polyacrylamide-urea gels.
Gels were analyzed by autoradiography, and RNA levels were quantified
with a PhosphorImager (Molecular Dynamics). Each experiment was
repeated at least three times, and representative results are shown.
Northern RNA blotting.
Northern RNA blotting was performed
essentially as described previously (58). An antisense
[
-32P]UTP-labelled riboprobe was generated from
HindIII-linearized pKSNLCAT as described previously
(68). The synthetic RNA was complementary to the 5' ends of
mRNAs produced from pNLCATW-derived plasmids and contained 180 nucleotides (nt) of the HIV-1 5' LTR and 213 nt of the 5' end of the
CAT gene.
Extraction of poly(A)+ mRNA and reverse transcription
(RT)-PCR.
Cytoplasmic poly(A)+ mRNA was isolated with
Dynabeads Oligo (dT)25 (Dynal A. S.) as described
previously (60). Briefly, transfected cells were lysed for 5 min on ice in NP-40 lysis buffer. Cytoplasmic and nuclear fractions
were separated by centrifugation at 8,000 × g for 2 min. Supernatants were incubated with an equal volume of 2× binding
buffer (20 mM Tris-HCl [pH 7.5], 1.0 M LiCl, 2 mM EDTA, 0.5% SDS)
containing 400 µg of Dynabeads Oligo (dT)25. After three
washes in washing buffer (10 mM Tris-HCl [pH 7.5], 0.15 M LiCl, 2 mM
EDTA), poly(A)+ mRNAs were eluted from the beads with
elution buffer (2 mM EDTA [pH 7.5]) at 65°C for 2 to 3 min and
stored at 
70°C until use.
Radioimmunoprecipitation.
Transfected cells were starved for
30 min in Met-free medium containing 0.5% fetal calf serum, followed
by metabolic labelling for 1 h with 200 µCi of
[35S]Met. The cells were washed and lysed in ice-cold
RIPA buffer (25 mM Tris-HCl [pH 7.4], 75 mM NaCl, 0.5% Triton X-100,
0.5% sodium deoxycholate, 0.05% SDS). After three freezing-thawings, the cell extracts were centrifuged, and supernatants were collected, mixed with normal guinea pig serum, and incubated for 30 min at 4°C.
Protein A-Sepharose (Pharmacia) beads were added, and incubation was
continued for 1 h, followed by centrifugation and collection of
supernatants. Normal guinea pig serum or guinea pig anti-HPV-16 L2
peptide antiserum (18) was added, and incubation was
performed at 4°C for 16 h, followed by the addition of protein
A-Sepharose beads and continued incubation for 3 h. The samples
were heated, loaded onto 10% polyacrylamide-SDS gels
(acrylamide/bisacrylamide ratio, 29:1) under reducing conditions, and
electrophoresed at 180 V. The gels were dried and autoradiographed at
70°C.
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The HPV-16 L2 protein can be efficiently produced in HeLa cells by use of the vaccinia virus T7 RNA polymerase-based expression system but not by use of eucaryotic expression plasmids. We first attempted to express HPV-16 L2 (Fig. 1) from plasmids containing the HIV-1 LTR promoter (pH16L2) (Fig. 2A) or the CMV promoter (pCMV16L2) (Fig. 2A), which we have used previously for high expression of other virus genes, e.g., those encoding EIAV and HIV-1 proteins (48, 49, 59). However, the levels of L2 produced from these plasmids were undetectable (Fig. 2). In contrast, transfection of plasmid pT7-16L2, which contains the bacteriophage T7 promoter (Fig. 2A), into HeLa cells infected with a recombinant vaccinia virus producing T7 RNA polymerase (20) yielded high levels of L2 protein (Fig. 2). In the latter case, transcription of the plasmid occurs in the cytoplasm, while in the former case, nuclear factors are required. We do not know if the high L2 expression levels observed in the vaccinia virus T7 RNA polymerase expression system are a result of the bypassing of the nucleus, overall high transcription levels in this expression system, or interactions between vaccinia virus and the infected cell. We obtained similar results previously using the HPV-16 L1 gene (58). Our results indicated that the HPV-16 L2 coding region contains inhibitory sequences.
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The HPV-16 L2 coding region contains cis-acting inhibitory sequences that act in an orientation-dependent manner. To investigate if the HPV-16 L2 coding region contains sequences that inhibit gene expression, the entire HPV-16 L2 coding region was inserted, in sense and antisense orientations, downstream of the CAT reporter gene in plasmid pNLCATW (58), resulting in plasmids pC16L2(S) and pC16L2(A), respectively (Fig. 3). These plasmids were separately transfected in triplicate into HLtat cells (48) in the presence of the SEAP-producing plasmid pCS1X (58), included as an internal control for transfection efficiency. The standard deviation was less than 30% in all experiments shown, and all plasmids were analyzed in a minimum of three independent transfection experiments. Mean values of CAT levels produced after triplicate transfections revealed that pC16L2(S) produced 49-fold-lower levels of CAT than pNLCATW (58), whereas pC16L2(A) and pNLCATW (58) produced similar levels of CAT (Fig. 3). These results demonstrated that the HPV-16 L2 coding region contains cis-acting inhibitory sequences that acted in an orientation-dependent manner to reduce CAT production. For comparison, we analyzed the effect on CAT expression of the HPV-16 L1 coding region. The results demonstrated that pC16L1(S) produced 202-fold-lower CAT levels than pNLCATW (58) and that the presence of L1 in an antisense orientation had a lower inhibitory effect (Fig. 3), as we described previously (58). The HPV-16 L1 sequence had stronger inhibitory activity than the L2 sequence.
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The HPV-1 L1 and L2 coding regions do not contain strong inhibitory sequences. We next investigated if the presence of inhibitory sequences in the L1 and L2 coding regions is a general property of HPVs. The L1 and L2 coding sequences from HPV-1 were separately inserted in the sense and antisense orientations downstream of the CAT gene in pNLCATW (58), resulting in pC1L1(S), pC1L1(A), pC1L2(S), and pC1L2(A) (Fig. 3). These plasmids were transfected into HLtat cells (48), and the levels of CAT were determined. The results showed that HPV-1 L1 and L2 inhibited CAT expression 13- and 3-fold, respectively (Fig. 3), demonstrating that the HPV-1 L1 and L2 coding sequences encode only low inhibitory activity. The ratios between CAT levels produced from each plasmid containing HPV sequences in the sense orientation and CAT levels produced from the corresponding plasmid containing HPV sequences in the antisense orientation were 0.32 and 1.1 for the HPV-1 L1 [pC1L1(S)/pC1L1(A)] and L2 [pC1L2(S)/pC1L2(A)] plasmids, respectively, whereas the corresponding ratios for the HPV-16 L1 [pC16L1(S)/pC16L1(A)] and L2 [pC16L2(S)/pC16L2(A)] plasmids were 0.05 and 0.03, respectively. We concluded that the HPV-16 L1 and L2 coding regions contain strong inhibitory sequences located on the coding strand; the HPV-1 L2 sequence appeared to lack significant inhibitory activity, whereas the HPV-1 L1 sequence had weak inhibitory activity.
The inhibitory sequences in HPV-16 L2 are active in cells of different origins. We transfected pC16L2(A) or pC16L2(S) (Fig. 2A) into cell lines of different origins (Table 1) to test if the inhibitory activity of the L2 sequences was restricted to epithelial cells. Table 1 shows a 14- to 126-fold difference in CAT production between pC16L2(A) and pC16L2(S) in the cell lines, indicating that the inhibitory sequences were functional in different cell types and in cells from different species. However, the inhibitory element in HPV-16 L2 acted most efficiently in human epithelial cells. The results indicated that the regulatory mechanism involving the HPV-16 L2 sequences is evolutionarily conserved and is not cell type specific.
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The HPV-16 L2 coding region contains cis-acting sequences that reduce cytoplasmic and nuclear mRNA levels. To further investigate the inhibitory effect of the HPV-16 L2 coding sequence, plasmids pC16L2(S), pC16L2(A), and pNLCATW were separately transfected into HLtat cells in the presence of the internal control plasmid pHCMVtat (see Materials and Methods), and cytoplasmic mRNA levels were monitored by primer extension. The results revealed that pNLCATW and pC16L2(A) produced similar mRNA and protein levels, whereas pC16L2(S) produced significantly lower mRNA and protein levels than pC16L2(A) and pNLCATW (Fig. 4A), respectively. The differences were 20- to 13-fold at the mRNA level and 133- to 147-fold at the protein level. Quantitation of mRNA and protein levels in cells transfected with serially diluted pNLCATW verified that the analysis was performed in the linear range of the assays (Fig. 4B). In addition, we analyzed cytoplasmic poly(A)+ mRNA by RT-PCR with fourfold serially diluted mRNA. The results demonstrated that the mRNA levels produced from pC16L2(S) were approximately 30- to 60-fold lower than those produced from pNLCATW (Fig. 4C). The levels of internal control EIAV gag mRNA did not vary significantly between the two transfections. The CAT protein levels produced from pC16L2(S) were 140-fold lower than those produced from pNLCATW in the same transfection experiment (Fig. 4C).
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HPV-16 L2 contains cytoplasmic mRNA instability determinants. To investigate if the decreased levels of L2-containing mRNAs could be explained by a reduced mRNA half-life, HLtat cells were transfected with pC16L2(S) or pNLCATW and treated with actinomycin D for 0, 30, and 60 min. Cytoplasmic RNA was extracted, and mRNA levels were quantified by primer extension. Figure 6A shows that the mRNAs produced from pC16L2(S) were less stable than those produced from pNLCATW, a result which explains, at least in part, the reduced steady-state levels of L2-containing mRNAs. The cytoplasmic half-life of pC16L2(S) mRNAs was 61 min, whereas the pNLCATW-derived mRNAs had a half-life of 161 min (Fig. 6B). The mRNA half-life was reduced approximately threefold when the L2 sequence was present on the mRNA. The pC16L2(S)-derived mRNAs were more stable in the nucleus than in the cytoplasm (data not shown), and we therefore focused on cytoplasmic L2 mRNA. The stability of several cellular mRNAs is affected by translation inhibitors (reviewed in reference 41). To test if CAT-L2 mRNA levels could be induced by translation inhibitors, we treated pC16L2(S)-transfected cells with cycloheximide for 0, 1, 2, and 3 h. Levels of cytoplasmic mRNAs produced from pC16L2(S) continuously increased during the cycloheximide treatment time course (Fig. 7A), indicating that the effect on cytoplasmic mRNA stability was dependent on protein synthesis. There was an approximate fivefold induction after 3 h of cycloheximide treatment (Fig. 7A), while the difference in steady-state mRNA levels between pC16L2(S) and pNLCATW was 10- to 30-fold, indicating that inhibition of translation did not entirely prevent premature cytoplasmic degradation of CAT-L2 mRNAs. To test if specific inhibition of translation of the mRNA produced by pC16L2(S) resulted in increased cytoplasmic mRNA levels, a stable GC-rich hairpin loop that blocks translation of the mRNA was inserted at the 5' end of pC16L2(S), generating pC16L2-Stop (Fig. 7B). This plasmid did not produce detectable levels of CAT protein. The mRNA levels produced from pC16L2-Stop were twofold lower than those produced from pC16L2(S) (Fig. 7C). The reason for this may be that the introduction of a stable RNA structure may have effects on the mRNA other than inhibiting translation. These results indicated that the reduction of the cytoplasmic mRNA levels by the L2 sequence was not dependent on translation of the L2-CAT mRNAs. The results presented here also demonstrate that HPV-16 L2 contains a rapid mRNA degradation determinant and suggest that a labile factor targets HPV-16 L2 mRNAs for premature degradation in the cytoplasm.
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C (Fig. 7B), designed to express the L2 gene from
the HIV-1 LTR promoter in the absence of the CAT gene, with those
produced from pC16L2(S). The two plasmids produced similar low
cytoplasmic mRNA levels (Fig. 7C), and L2 protein could not be
detected in cells transfected with p16L2C (data not shown). In
conclusion, the presence of the HPV-16 L2 sequence in the mRNA resulted in decreased mRNA levels, caused by rapid mRNA
degradation.
The cytoplasmic mRNA instability sequence is contained in the 5'-most 845 nt of HPV-16 L2. To map the negative sequences in HPV-16 L2, we introduced deletions in the L2 sequence contained in pC16L2(S), resulting in plasmids pCL2D, pCL2C, pCL2B, and pCL2A (Fig. 8A). The L2 sequences present in pCL2A, pCL2B, and pCL2C inhibited CAT expression when compared to pNLCATW but less so than did the entire L2 sequence present in pC16L2(S) (Fig. 8A). pCL2D produced CAT levels similar to those produced from pNLCATW (Fig. 8A), demonstrating that the inhibitory sequences had been destroyed. Therefore, sequences in the 5' and 3' ends of the L2 coding region contributed to the inhibitory activity. Alternatively, inhibitory sequences were located in the 5' end and in the middle portion of the L2 coding region.
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Identification of inhibitory sequences in the 3' end of L2. To confirm the presence of inhibitory sequences in the 3' end of L2, sequences spanning various parts of the 3'-most 800 nt of HPV-16 L2 (nt 4865 to nt 5665) were inserted downstream of CAT in pNLCATW. Analysis of the CAT levels produced from pCL2R1 and pCL2R2 (Fig. 9A) revealed that the L2 sequences present in these two plasmids inhibited CAT production to similar extents (Fig. 9A), suggesting that an inhibitory region was located in the middle of these two overlapping sequences. The borders of this region should be nt 5060 and nt 5520. However, the presence of this fragment downstream of CAT, as in pCL2R7, did not result in strong inhibition (Fig. 9A), indicating that additional sequences in the 5' and 3' ends were required for efficient inhibition. This suggestion was consistent with larger deletions of 5' and 3' sequences, as in pCL2R5 and pCL2R4, respectively, resulting in a loss of inhibition (Fig. 9A). We concluded that an inhibitory region was located downstream of nt 4860 in the L2 coding sequence and that efficient inhibition required the presence of 500 to 600 nt of the L2 3' end.
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Here we show that the HPV-16 L2 coding region contains cis-acting inhibitory sequences that act in an orientation-dependent manner to reduce cytoplasmic and nuclear mRNA levels. The low cytoplasmic mRNA steady-state levels were a result of the reduced stability of mRNAs containing L2. Mapping experiments demonstrated that the 5' end of the L2 coding region contained an mRNA destabilization sequence and that the 3' end of L2 contained a weaker inhibitory sequence that acted posttranscriptionally to reduce protein levels. Furthermore, we showed that strong inhibitory sequences in the L1 and L2 coding regions are found in HPV-16 but not in HPV-1, suggesting that late-gene expression is differently regulated by these two HPV types.
Regulation of mRNA stability is a common mechanism of
posttranscriptional gene regulation in eucaryotes (reviewed in
references 2, 3, 9, and 40 to
42). Mammalian c-fos, c-myc, and 
-tubulin mRNAs have been shown to encode mRNA instability
determinants in their coding regions (4, 6, 27, 45, 54, 55,
62-64, 66, 67). Interestingly, c-fos and
c-myc mRNAs also contain mRNA instability
determinants in their 3' UTRs (9, 41), a property that they
share with late HPV-16 L1 and L2 mRNAs (21, 29, 30, 58).
The mRNA instability determinants in the c-fos, c-myc, and -tubulin coding regions are located in the
middle, 3', and 5' regions and span approximately 320 (54,
55), 320 (63), and 40 (8, 13-15, 38) nt,
respectively. The HPV-16 L2 coding region mRNA destabilizing
determinant is contained within the first 845 nt (Fig. 8). Mapping of
the 5' end of the L2 sequence will show if the size of the functional
element is smaller. The L2 coding region does not contain AUUUA or
UUUUU motifs, which are commonly found in AU-rich mRNA instability
elements (9, 41), but does have a 60% A+U content, similar
to that of an mRNA instability sequence located in the HIV-1
gag ORF (50). The human insulinlike growth factor
II mRNA contains an RNA cleavage-promoting sequence in the 3' UTR,
consisting of two elements located approximately 2,000 nt apart
(44). These RNA elements hybridize to form the functionally
active stem-loop structure (44). It remains to be
investigated if it is the RNA primary or secondary structure that is
the major determinant of the activity of the HPV-16 L2 mRNA
instability determinant.
It was previously concluded that translation of the c-myc
and c-fos mRNAs specifically was required for
deadenylation and rapid degradation (27, 45, 64). The
function of the negative element in the -tubulin coding region is
dependent on the production of the first amino acids of the -tubulin
protein (66, 67). Furthermore, the yeast MAT1
mRNA is rapidly degraded as a result of the presence in the
mRNA coding region of rare codons (7, 26). Similarly, we
showed that treatment of cells with the translation elongation
inhibitor cycloheximide rendered the CAT-L2 hybrid mRNAs more
stable in the cytoplasm (Fig. 7A). However, the function of the
mRNA instability sequence in the CAT-L2 hybrid mRNAs was not
dependent on translation of these mRNAs specifically (Fig. 7B and
C), suggesting that a labile factor targets the L2 mRNA for rapid
degradation. This suggestion is not without precedent, since premature
degradation of a c-fos 3' UTR-containing mRNA was shown
to be inhibited by cycloheximide but not by insertion into the mRNA
of sequences that blocked the translation of c-fos (31). This idea is consistent with our observations of
reduced CAT-L2 mRNA levels in both the cytoplasmic and the nuclear
compartments (Fig. 5), suggesting that mRNA destabilization occurs
in the nucleus and the cytoplasm. Alternatively, inhibition of
translation by cycloheximide affects the stability of the mRNA only
in the cytoplasm. The c-fos coding region instability
determinant interacts with cellular factors (10), and the
c-myc mRNA instability determinant binds a 70-kDa
protein which protects against degradation of the c-myc
mRNA (39). A recent report indicates that the HPV-16 L2 protein interacts nonspecifically with nucleic acids (69).
However, production of the HPV-16 L2 protein is most likely not
required for the inhibitory activity of the L2 mRNA. It remains to
be investigated by what mechanism L2-containing mRNAs are degraded
in the cytoplasm and the nucleus and if cellular proteins bind to them.
We cannot exclude the possibility that L2-containing mRNAs are
retained in the nucleus, where they are prematurely degraded.
HPVs infect dividing cells in the basal cell layer of the stratified epithelium. As the infected cell moves toward the upper cell layers and differentiates, HPV late-gene expression is activated (11, 23, 28, 32, 33, 56). This differentiation-dependent HPV late-gene expression pattern has been observed for several different HPV types, illustrating that the expression of late genes is suppressed in the lower cell layers, while in the upper strata, with differentiated cells, this block is relieved. Interestingly, the expression of c-fos in squamous cell epithelium also is differentiation dependent, with higher c-fos mRNA and protein levels in the upper strata (19). Therefore, the inhibitory activity of the c-fos and HPV-16 L2 coding region determinants must be relieved as the cell differentiates. Interestingly, c-myc production decreases as myoblasts differentiate. A recent report indicated that this effect is attributable to the c-myc coding region mRNA instability determinant (65), demonstrating an inverse correlation between the inhibitory activity of the RNA sequence and cell differentiation for c-fos and HPV-16 late mRNAs. It remains to be investigated if the inhibitory sequences in HPV-16 L1 and L2 are as active in terminally differentiated cells as in dividing cells.
An attempt to classify HPVs into different groups based on the amount of virus present in benign lesions has been made and has suggested that HPVs can be divided into three groups: productive, weakly productive, and nonproductive (57). It is of interest to note that HPV-1 categorically falls into the productive group, characterized by the detection of moderate to large amounts of virus in lesions, whereas HPV-16 belongs to the weakly productive group, where only minute amounts of virus can be detected. Since we have identified strong negative sequences in HPV-16 L1 and L2 (58; this study) but not in HPV-1 L1 and L2, it is reasonable to speculate that the negative sequences present in the coding regions may explain the different amounts of virions present in lesions caused by HPV-1 and HPV-16. In contrast, both HPV-1 and HPV-16 show strict cell differentiation-dependent expression of late genes. This property correlates with the presence of a negative element in the 3' UTRs of the late mRNAs of both HPV types (29, 30, 58, 60), suggesting that the block in late-gene expression caused by the 3' UTR element is alleviated as the cell differentiates. It would be of interest to determine the effect of cell differentiation on the activity of the 3' UTR and coding region inhibitory sequences.
The regulation of viral late-gene expression caused by the presence of negative regulatory sequences on the mRNAs coding for structural proteins appears to be a common strategy used by many viruses. Although such inhibitory RNA sequences have not yet been characterized in detail, several reports on negative sequences on viral late mRNAs have been presented. For example, HIV-1 contains inhibitory sequences in the Gag, Pol, and Env coding regions (16, 34, 37, 46, 47, 50) and human T-cell leukemia virus type 1 contains inhibitory sequences in the 5' UTR (52) and in the Pol and Env coding regions (43). An mRNA instability sequence previously identified in the HIV-1 gag ORF was shown to reduce mRNA levels in both cytoplasmic and nuclear compartments (50), similar to the data presented here for HPV-16 L2 (Fig. 5). The HIV-1 gag mRNA inhibitory element interacted specifically with poly(A)-binding protein 1 (1), but in preliminary experiments we did not detect binding to the L2 sequences of proteins with an affinity for poly(A).
The presence of multiple inhibitory sequences on viral late mRNAs encoding structural proteins appears to be a common property of HIV-1, HTLV-1, and HPV-16. For example, HIV-1 contains inhibitory sequences in the Env coding region (12, 37) that would be present on the Env-producing and Gag-Pol-producing mRNAs as well as inhibitory sequences in the Gag and Pol coding regions (16, 34, 47, 50). A similar arrangement is observed for HPV-16, where the HPV-16 L1 coding region contains inhibitory elements (58) that would be present on both the L1 mRNAs and the L2-L1 mRNAs (5). In addition to these negative elements, the L2-L1 mRNAs would contain the L2 coding region inhibitory sequences described here. Therefore, the inhibitory sequences in HPV-16 L2 would allow independent regulation of L1 and L2 production. Perhaps the presence of inhibitory sequences in the L2 coding region allows a balanced production of L1 and L2 and reflects a requirement for the production of a certain ratio between L1 and L2 molecules to generate correctly assembled virions. Alternatively, perhaps the posttranscriptional processing and regulation of expression of a polycistronic mRNA are different from those of a monocistronic mRNA and therefore require more complex cis-acting signals. In conclusion, the presence of negative elements on viral late mRNAs allows the virus to regulate late-gene expression and virus production. This ability may be of critical importance for the virus in avoiding host immune system surveillance and in establishing persistent infections. Subgenomic virus expression plasmids encoding late genes lacking negative sequences may be valuable tools for the development of DNA vaccines.
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ACKNOWLEDGMENTS |
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We thank M. Yaniv, F. Thierry, H. zur Hausen, G. N. Pavlakis, and B. K. Felber for plasmids, J. Dillner for guinea pig anti-HPV-16 L2 peptide antiserum, S. Leonov for help with electrotransfer equipment, and S. Izadi for participating in some experiments.
Part of this work was performed at the Department of Medical Immunology and Microbiology, Biomedical Center, Uppsala University. This work was supported by the Swedish Cancer Society, the Swedish Medical Research Council, the Swedish Society for Medical Research, the Swedish Society of Medicine, Anders Otto Swärds Stiftelse, Stiftelsen Lars Hiertas Minne, Jeanssonska Stiftelserna, Magnus Bergvalls Stiftelse, and Åke Wibergs Stiftelse.
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FOOTNOTES |
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* Corresponding author. Present address: Department of Medical Immunology and Microbiology, Biomedical Center, Uppsala University, P.O. Box 582, 751 23 Uppsala, Sweden. Phone: 4618 471 4928. Fax: 4618 509 876. E-mail: Stefan.Schwartz{at}imim.uu.se.
Present address: Department of Medical Immunology and Microbiology,
BMC, Uppsala University, 751 23 Uppsala, Sweden.
Present address: The John P. Robarts Research Institute, London,
Ontario N6A 5K8, Canada.
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REFERENCES |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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) and antisense (
)
orientations. The depicted plasmids were transfected in triplicate into
HLtat cells, and CAT levels were monitored in a CAT ELISA and
normalized to SEAP levels produced from the internal control plasmid
pCS1X (
