A Composite Polyadenylation Signal with TATA Box Function

doi:10.1128/MCB.20.3.834-841.2000

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Molecular and Cellular Biology, February 2000, p. 834-841, Vol. 20, No. 3
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

A Composite Polyadenylation Signal with TATA Box Function

Nir Paran, Assaf Ori, Izhak Haviv, and Yosef Shaul^*

Department of Molecular Genetics, The Weizmann Institute of Science, Rehovot 76100, Israel

Received 15 September 1999/Returned for modification 7 October 1999/Accepted 5 November 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A variant polyadenylation signal, which is conserved and employed by mammalian hepadnaviruses, has a sequence resembling thatof the TATA box. We report here that this composite box manifestsall the promoter characteristics. It binds effectively TATA-bindingprotein with TFIIB and TFIIA in a synergistic manner. This capacity,however, is lost when the box is converted to a canonical andsimple poly(A) signal. Furthermore, we show that it has promoteractivity and supports transcription of reporter genes preferentiallyin liver-derived cells, a characteristic behavior of the hepatitisB virus (HBV) promoters. In addition, we show that the HBV noncanonicalpoly(A) signal supports transcription initiation from the viralgenome, suggesting that it is a genuine promoter, possibly ofthe polymerase/reverse transcriptase gene. Finally, we found thatthis deviant poly(A) signal is crucial for HBV replication sincea viral mutant with a canonical poly(A) box is impaired in replication.Our data, therefore, raise the interesting and novel possibilitythat a composite poly(A) box might have a dual function. At thelevel of DNA it functions as a promoter to initiate transcription,whereas at the level of RNA it serves as a poly(A) signal to processRNA. An interesting outcome of this strategy of gene expressionis that it provides a novel mechanism for the synthesis of anapproximately genome lengthtranscript.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The 3' end of the eukaryotic mRNA is polyadenylated by a reaction that involves site-specific endonucleolytic cleavage. TheAAUAAA sequence, the important polyadenylation signal, is locatedabout 15 to 30 nucleotides upstream of the cleavage site. Somevariation of this signal is tolerated, although it often resultsin diminished processing efficiency (39, 43). Transcriptsthat contain the deviant UAUAAA poly(A) signal are processed muchless efficiently (about 17%). In fact, at the DNA level the deviantsequence (TATAAA) resembles a TATA box more than a canonical poly(A)signal (AATAAA). Interestingly, in spite of its remarkable inefficiencysome viruses tend to prefer this deviant poly(A) signal. Theseinclude all the mammal hepadnaviruses (33), the figwart mosaicvirus (34), and Epstein-Barr virus (40). Particularly puzzlingis the fact that this deviant box is conserved among the differentmembers of mammalian hepadnaviruses, raising an interesting possibilitythat it has a unique but yet-unidentifiedrole.

Hepatitis B virus (HBV) is the prototype of the hepadnaviruses. This enveloped DNA virus has a very small 3.2-kb genome replicatingvia reverse transcription and is primarily hepatotropic. The genomecontains four partially overlapping open reading frames (ORFs),each translated from a specific viral transcript. The largesttwo viral transcripts known are the 3.5-kb precore mRNA (pcRNA)and the 3.4-kb pregenomic mRNA (pgRNA). pgRNA encodes the core(HBcAg) protein and possibly the viral polymerase/reverse transcriptase(Pol). pgRNA has a third function in viral replication, whichis to serve as a template for the reverse transcripts. Two additionalknown transcripts are the 2.3- to 2.1-kb mRNAs, which encode theS, PreS1, and PreS2 viral surface antigens. The last known transcriptis the 0.7-kb mRNA encoding the regulatory X protein (pX). pXhas transcription coactivation activity (14-17, 25) and is aneffector of cellular signaling (3, 9, 23, 26, 28,41).

HBV transcription is regulated by the cellular transcriptional activators that are preferentially found in liver cells (8,12, 20, 29, 30, 38). The viral genome contains multiplepromoters; each regulates the synthesis of a distinct transcript,all of which are processed at a single poly(A) signal. Exceptfor the promoter of the 2.3-kb transcript, none of the viral promoterscontains a classical TATA box (37). The juxtaposed pc- and pgRNApromoters contain a number of AT-rich boxes that bind recombinantTATA-binding protein (TBP) (6). By employing recombinant generaltranscription factors (GTFs), we attempted to characterize thefunctional and cryptic TATA boxes of the different HBV promoters.Unexpectedly, we found that the deviant poly(A) signal of thevirus binds GTFs effectively in a manner characteristic of a promoter.Furthermore, this box has promoter activity and supports the transcriptionof reporter genes. Our data, therefore, describe an interestingcomposite poly(A) box with dual roles. At the level of DNA itfunctions as a promoter to initiate transcription, whereas atthe level of RNA it serves as a poly(A) signal to processRNA.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cell culture. HepG2, SK-Hep1, and Huh7 cells were maintained in Dulbecco's modified Eagle's minimal essential medium (GIBCO Laboratories)containing penicillin (100 U/ml) and streptomycin (100 µg/ml),supplemented with 8% fetal calf serum (GIBCO Laboratories). Transfectionwas carried out by the CaPi method as previously described (16).Cells were seeded 8 to 12 h prior to transfection at about 60%confluence and were transfected as indicated in each figure. Whennecessary, pGEM3 plasmid was added at various concentrations toreach total amounts of 6 and 20 µg of DNA per 6- or 10-cm-diameterplate,respectively.

Plasmid constructions. For construction of simian virus 40 (SV40) enhancer/P(A)S/TATA reporter plasmid, the StyI-BglII DNA fragment from the HBVgenome (subtype adw), containing the HBV poly(A) signal, eitherwild type (wt) or mutant, was cloned via HindIII and BamHI sitesinto the pBluescript plasmid (Stratagene). A KpnI-SacI fragmentof this plasmid harboring this HBV fragment with the flankingpolylinker sequence was cloned to the KpnI-XhoI sites in the pGL2-Enhancervector (Promega). The pGL2 plasmid containing the SV40 enhancerwith the SV40 early promoter served as the positive control; thesame plasmid containing the SV40 enhancer alone served as thenegativecontrol.

For construction of the G5/P(A)S/TATA reporter plasmids, the G5 luciferase plasmid containing five repeats of the UAS^Gal synthetic enhancer element was used. The XbaI fragment of thisplasmid was replaced with an XbaI fragment of pGL3 (Promega) containingthe luciferase gene. The SmaI-BglII DNA fragments from the SV40enhancer/P(A)S/TATA reporter plasmid, containing either the wtor mutant sequence, were cloned downstream of G5 but upstreamof the luciferasegene.

RNA analysis. Total RNA was extracted from transfected cells by TRI REAGENT (MRC, Inc.) and treated with RNase-free DNase I (Boehringer)for 15 min at 37°C. The RNA quality and quantity were monitoredby measuring UV absorption and by ethidium bromide staining. ForNorthern blot analysis 10 to 20 µg of total RNA per sample wasseparated on a 1% formaldehyde-agarose gel and blotted to a Hybond-Nnylon membrane (Amersham). Radioactive probes were prepared byrandom priming with a full-length HBV DNA and [ $alpha$ -³²P]dCTP (Amersham; 3,000 Ci/mmol). About 10⁶ cpm (10 ng of DNA) of labeled DNA per ml of hybridization bufferwas used. After hybridization the membrane was washed for 60 minat 65°C in a 0.1 × SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodiumcitrate)-0.1% sodium dodecyl sulfate buffer and exposed to anX-ray film for autoradiography. Densitometry was performed bya Fujix Bas 2500 phosphorimager(Fuji).

For the RNase protection assay, total RNA from transfected cells was extracted by TRI REAGENT and analyzed as previously reported(10). For this analysis a single-stranded RNA probe was generatedby using T7 RNA polymerase to transcribe an antisense probe labeledwith [ $alpha$ -³²P]UTP(Amersham).

The primer extension analysis was performed with poly(A)-containing RNA by using as a ³²P-end-labeled primer the single-stranded synthetic oligonucleotide5'-ACTCTAAGGCTTCTCGATAC-3' (nucleotides 2014 to 2034 in the viralgenome considering the unique EcoRI site as 1). The reactionswere conducted as previously described (10).

Preparation of recombinant proteins. Recombinant TBP, TFIIB, and TFIIA proteins were prepared in Escherichia coli as previously reported (17).

Protein-DNA interaction assays. The electrophoretic mobility shift assays (EMSA) were performed as described previously (5, 27). The composition of thebinding buffer was 10 mM HEPES-KOH (pH 7.9), 4 mM MgCl₂, 0.1 mMEDTA, 5 mM (NH₄)₂SO₄, 2% (wt/vol) polyethylene glycol, 8% (vol/vol)glycerol, 10 µM Zn acetate, 0.025% NP-40, 50 to 100 mM KCl, 0.14mg of poly(dC-dG)/ml, bovine serum albumin (100 µg/ml), and 2mM dithiothreitol. As a DNA probe the HBV StyI-BglII 102-bp fragmentcontaining the wt poly(A) signal or the mutated one was used.The fragment was labeled by a fill-in reaction. For each assay5 to 10 ng of DNA (about 5,000 cpm) was used. The binding reactionwas carried out at 30°C for 30 min, and the complexes were separatedthrough nondenaturing 4 to 5% polyacrylamide gels. The runningbuffer contained 25 mM Tris (pH 7.9), 100 mM glycine, 1 mM EDTA,0.025% NP-40, 1 mM $beta$ -mercaptoethanol, 3% glycerol, 1.5 mM MgCl₂,and 10 µMZnOAc.

For DNase I footprinting of the core promoter, a 283-bp (StuI-BglII) DNA fragment was subcloned in pGEM3Z (Promega) and wasdigested and labeled at the unique EcoRI site of the plasmid polylinkerregion. The minus strand of the DNA fragment was labeled by afill-in reaction and used for DNase footprinting according toour published protocols (29). For DNase I footprinting of thepoly(A) signal of HBV the fragment used for EMSA wasemployed.

Virus replication assays. HepG2 cells were transfected with equivalent amounts of plasmid HBV DNA, either wt or mutant, harvested after 5 and 7 days,and analyzed for the presence of replicative HBV DNA intermediatesby a published protocol (31).

To assay for endogenous DNA polymerase activity in viral particles the culture medium of the transfected cells was collectedafter 7 days, virions were harvested and treated, and an endogenousDNA polymerase assay was performed according to the publishedprotocols (21, 42).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Analysis of the HBV pc- and pgRNA promoter region. To characterize the functional HBV pol-II promoters, we took the advantage of the fact that their core box binds GTFs in adefined manner (5, 27). TFIIB and TFIIA are the first GTFsto associate with the TBP during formation of a transcriptioninitiation complex on RNA pol-II promoters. It has been reportedthat both TFIIB and TFIIA have the intrinsic ability to directlyincrease the affinity of TBP to the TATA box (19). Also, TFIIBwas reported to directly interact with DNA immediately upstreamof the TBP binding region (24).

To characterize the structure of the HBV pc- and pgRNA promoter region, we conducted DNase I footprinting assays with recombinantTBP, TFIIA, and TFIIB proteins. An extended protected region atthe expected DNA sequence was obtained, suggesting that the employedrecombinant GTFs bind the pc- and pgRNA promoter(s) at multipleand possibly overlapping sites (Fig. 1, lane 2). This region doesnot contain a canonical TATA box, but three AT-rich regions thatwere reported to bind recombinant TBP were found (6). Unexpectedly,however, an additional footprinted region was detected at theregion that contains the viral poly(A) site. The HBV poly(A) signal[P(A)S] has a deviant TATAAA sequence that resembles that of aTATA box. We refer to this composite box as P(A)S-TATA.

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FIG. 1. DNase I footprinting analysis of the HBV core promoter region. An HBV DNA fragment (StuI-BglII), was end labeled and was incubated either with TBP, TFIIB, and TFIIA in a binding reaction (lane 2) or alone (lanes 1 and 3) and subjected to DNase I footprinting. The sequence of the protected regions, as determined by the comigrated products of the Maxam-Gilbert sequencing reaction, is shown at the left. Also, indicated are the TA-rich boxes that were previously reported to bind recombinant TBP (6). At the right the initiation sites of the pc- and pgRNA are shown; the arrows indicate the transcription direction.

The HBV P(A)S-TATA composite box binds GTFs. To further characterize the capacity of the HBV P(A)S-TATA composite box to bind GTFs in a sequence-specific manner, we introduceda point mutation to convert it from a composite to a simple canonicalpoly(A) signal. Binding of the recombinant TBP, TFIIA, and TFIIBwas analyzed by EMSA (Fig. 2). A suboptimal TBP concentrationwas used to show synergism in DNA-binding activity between TBPand TFIIA and TFIIB (19). Under these conditions P(A)S-TATAdoes not bind TBP efficiently (lane 1) but binds the mixture ofthe three GTF proteins (lane 7). A much weaker complex is seenin the absence of TFIIB (lane 5), but no DNA binding was detectedin the absence of TBP (lanes 2 to 4). Thus, the observed DNA-GTFbinding activity is fully TBP dependent and the joining of TFIIBto the shifted complex (lane 7) seems to be TFIIA dependent. Thisstepwise assembly behavior is in accordance with the reportedGTF binding activity (5, 27). Interestingly, the point mutantwith the simple and canonical poly(A) signal [P(A)S] no longerbinds GTFs (Fig. 2, lanes 8 to 12). We therefore concluded thatthe HBV composite P(A)S-TATA box binds GTFs in a manner characteristicof a genuine TATA box and that this binding activity is completelydependent on the composite nature of this box.

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FIG. 2. wt HBV P(A)S-TATA binds the basal transcription factors in a manner characteristic of a promoter. Two DNA fragments (102 bp) which span from the StyI site to the BglII site, harboring the HBV P(A)S-TATA sequence (TATAAA) (lanes 1 to 7), or the canonical P(A)S sequence (AATAAA; lanes 8 to 12) were subjected to EMSA with purified recombinant basal transcription factors. The amounts of the different basal transcription factors in the reaction mixture were as follows: 125 pg of TBP, 2 ng of TFIIA, and 10 ng of TFIIB. The protein mixtures in the different reactions are indicated.

To further substantiate the above findings and to delineate the GTF-interacting regions, DNase I footprinting was employed.An HBV 102-bp fragment (StyI-BglII) containing the P(A)S-TATAbox was end labeled and incubated with recombinant GTFs. Hereagain, a suboptimal concentration of the recombinant human TBPwas used to minimize its direct DNA interaction (Fig. 3, lane1). The addition of TFIIA resulted in the appearance of a protectedregion over the P(A)S-TATA sequence (lane 2). When TBP was incubatedwith TFIIB, this region was protected to a lesser extent but astrong DNase I-hypersensitive site at the 5' end of the protectedregion was evident (lane 3). This is expected, given the recentfinding that TFIIB directly binds DNA at the 5' end of the TATAbox region (24). Significantly, a fully protected region witha hypersensitive site was detected when all the three proteinswere coincubated (lane 4). Under similar conditions, a mutantDNA fragment bearing the simple and canonical poly(A) box displayedvery poor GTF binding activity (lanes 6 to 10). We concluded thatthe cryptic TATA box embedded within the composite P(A)S-TATAsequence binds the GTFs in a manner genuinely characteristic ofa promoter. Furthermore, the position of the TFIIB-dependent,DNase I-hypersensitive site defined the correct orientation ofthis box. Thus, the deviant and composite poly(A) signal of themammal hepadnaviruses binds GTFs at the level of DNA and, givenits documented function, it must bind the poly(A)-processing proteinsat the RNA level.

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FIG. 3. DNase I footprinting analysis of the novel TATA box in the HBV genome. The examined DNA fragments and the binding conditions are identical to those used for EMSA in Fig. 2, except that 2 ng of TBP, 4 ng of TFIIA, and 10 ng of TFIIB were used. The different probes and the different protein mixtures in each reaction are indicated above the lanes. Lanes 0, no protein added. The sequences of the protected region of the P(A)S-TATA (left) and of the unprotected region of the P(A)S sequence (right) are shown. hTBP, human TBP.

The composite P(A)S-TATA box has promoter activity. To investigate the functional significance of the ability of the composite P(A)S-TATA box to bind GTFs, we employed the luciferasereporter system. Each of the examined HBV DNA fragments was insertedinto a promoterless plasmid at the 5' end of the luciferase reportergene. The reporter plasmid also contained an artificial enhancercomposed of five copies of the yeast GAL4 binding site (UAS^Gal). An empty vector without a TATA box and a vector with the adenovirusE1b TATA box were used as negative and positive controls, respectively.The reporter plasmids were cotransfected together with a plasmidexpressing the VP16 acidic activation domain fused to the GAL4DNA-binding domain. A significant transcription activation wasobtained by the Gal4VP16 activator and the reporter plasmid containingeither the wt HBV fragment (13.7-fold) or the E1b TATA box (55.6-fold),suggesting that the P(A)S-TATA box has intrinsic promoter activity(Fig. 4). In contrast the HBV mutated-DNA fragment with the simplepoly(A) sequence was inactive. We concluded that the embeddedTATA box in the composite HBV P(A)S-TATA signal has promoter activity.The activity of this box, however, is fourfold weaker than thatof the canonical E1b TATA box promoter.

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FIG. 4. The HBV composite P(A)S-TATA box exerts promoter activity in the context of a reporter plasmid. HepG2 cells were transfected with 1 µg of each of the four reporter plasmids schematically described at the bottom and with 50 ng of DNA of the Gal4VP16 activator plasmid per 6-cm-diameter plate. Luciferase activity was measured 48 h posttransfection. To calculate the fold activation, the activity of each reporter was divided by that obtained with reporter 1. The experiments were performed in triplicate, and the average values and standard deviations are shown.

To confirm that the activation of the reporter plasmids is regulated on the level of transcription, we performed RNase mappinganalysis. The Huh7 hepatocytes were transiently cotransfectedwith the reporter and the Gal4VP16 activator plasmids. RNA wasextracted and subjected to an RNase protection reaction. As aprobe an antisense ³²P-RNA containing the sequence of the putative promoter regionwas used. A specific band with an approximate length of 38 nucleotideswas detected with the composite but not with the simple P(A)Sreporter plasmid (Fig. 5). This band is a likely candidate torepresent the 5' ends of the transcripts that are initiated bythe P(A)S-TATA promoter element. The exact 5' end of the protectedband is mapped at the CT sequence (this was also confirmed byprimer extension analysis [see below]). The obtained lower-molecular-weightbands are the products of the RNase digestion at the "breathing"region of five consecutive Ts (see the sequence in Fig. 5). Thesedata, together with the results of the luciferase assays, suggestthat the composite P(A)S-TATA element can function as a promoter,at least in the context of a reporter plasmid.

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FIG. 5. Analysis by RNase mapping of the 5' portion of the RNA molecules produced by the reporter plasmids. Huh7 cells were cotransfected with 0.2 µg of DNA of the activator plasmid Gal4VP16, together with 2 µg of DNA of the luciferase reporter plasmids with either the composite P(A)S-TATA or the simple P(A)S sequence, per 10-cm-diameter plate. Sixty hours posttransfection, total RNA was extracted and RNase mapping was performed with a ³²P-labeled antisense RNA probe. The bands with lower molecular weights are likely to be the products of RNase digestion at the breathing region with five consecutive Ts.

Cell type preference of the P(A)S-TATA promoter element. Previously, we have reported that one of the characteristic features of the HBV promoters is that under the SV40 enhancerthey display greater activity in the liver-derived cell linesthan the SV40 promoter/enhancer unit (18). To determine thepossible cell-specific promoter activity of the composite P(A)S-TATAelement, we constructed a reporter plasmid that contains the SV40enhancer upstream of the composite HBV box and performed transienttransfection experiments. Both highly and poorly differentiatedhepatoma cell lines HepG2 and SK-Hep1, respectively, were transfected.All the reporter plasmids displayed dose-dependent activity regardlessof the cell origin. However, the reporter plasmid containing theP(A)S-TATA promoter under the SV40 enhancer was more active inthe highly differentiated HepG2 cell line (Fig. 6A) than in theSK-Hep1 cell line. In contrast, and in agreement with our previousfindings (18), a reverse picture was seen with the control SV40promoter/enhancer reporter plasmid (Fig. 6B). Thus, similar tothe other HBV promoters, the novel P(A)S-TATA promoter is moreactive in the liver-derived differentiated cells.

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FIG. 6. Preferential promoter activity of the P(A)S-TATA box in highly differentiated hepatocytes. SK-Hep1 cells and HepG2 cells, poorly and highly differentiated hepatocytes, respectively, were transfected with increasing amounts of the luciferase reporter plasmids (0.1 to 1.0 ng of DNA per 2-cm-diameter plate). The SV40 enhancer/HBV P(A)S-TATA (A) and the SV40 enhancer/promoter (B) reporter plasmids were used. Luciferase activity was measured 48 h posttransfection. The experiments were performed in triplicate, and the average values and standard deviations are shown. Conc., concentration.

The composite P(A)S-TATA box is an active promoter in the context of the viral genome. Having demonstrated that the HBV composite P(A)S-TATA box is active in GTF binding and in supporting transcription, we nextinvestigated its possible promoter activity in the context ofthe viral genome. HepG2 permissive cells were transfected withHBV DNA, and RNA was extracted and subjected, along with an end-labeled³²P-labeled oligonucleotide primer, to primer extension reactions.The products were resolved in a denaturing polyacrylamide-ureagel along with that of the dideoxy-sequencing reaction. Interestingly,a band that mapped exactly at the expected site of transcriptioninitiation programmed by the P(A)S-TATA box was detected (Fig.7A). We concluded, therefore, that this composite box has TATAbox activity in the context of the intact viral genome.

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FIG. 7. The composite P(A)S-TATA box is an active promoter in the context of the viral genome, as shown by primer extension analysis. HepG2 cells were transfected with 20 µg of a head-to-tail dimer of HBV DNA, RNA was extracted, and 3 µg of poly(A) RNA was incubated with an end-labeled ³²P-oligonucleotide primer in primer extension reactions. The products were separated in a denaturing polyacrylamide-urea gel along with that of the dideoxy-sequencing reactions (A). The initiation sites are indicated (+1), with an arrow to show the transcription direction. To show that this initiation point is regulated by the composite poly(A) box, wt [P(A)S-TATA] DNA and a point mutant HBV DNA with a simple poly(A) signal [P(A)S] were used to transfect cells. Total RNA (10 µg) of each transfected plate was used for Northern blotting and hybridization with a ³²P-HBV DNA probe (B). The known HBV RNA species and their calculated sizes are indicated. Poly(A) RNA (3 µg) from each of the transfected cells was used for primer extension reactions (C). The 5' ends of the pc- and pgRNA are shown in the upper radiogram, and those of the novel transcript, initiating about 25 bases downstream of the composite poly(A) signal, are shown in the lower radiogram. The upper and lower radiograms were exposed for different times. Note the sharp reduction in the level of this RNA in the HBV mutant, while pc- and pgRNA levels were moderately affected (70% of wt).

The fact that the exact initiation site was also detected in the context of a reporter plasmid (Fig. 5) strongly suggeststhat a common promoter core element, i.e., a P(A)S-TATA box, wasutilized in both cases. To further substantiate this possibility,an HBV DNA mutant that contained a simple poly(A) signal insteadof the composite one was generated. The constructed HBV plasmidswere transfected in the HepG2 cells, and RNA was extracted andanalyzed. Northern blot analysis revealed that the expected HBVtranscripts are produced by both wt and mutant HBV (Fig. 7B),although in the latter case the levels of pc- and pgRNA are lower(about 70%). Thus, under the employed conditions, the gene expressionprogram of the HBV mutant was not dramatically changed. Next theRNA samples were subjected to primer extension analysis. Thisanalysis revealed that both wt and mutant HBV DNA genomes utilizethe same transcription initiation sites for the synthesis of pc-and pgRNA (Fig. 7C, top), but, as expected, the level of the mutant'stranscripts was lower (about 70% of the wt). In sharp contrastthe level of the novel transcript was undetectable when the mutanttemplate was used (Fig. 7C, bottom). The fact that a simple poly(A)box cannot support the production of the novel transcript suggeststhat the composite HBV P(A)S-TATA box is a functional TATAbox.

The deviant poly(A) signal is instrumental in HBV replication. Having demonstrated that an HBV mutant bearing the canonical poly(A) signal is capable of programming the synthesis of themajor viral transcripts, we next asked whether this virus is replicationcompetent. Cells were transfected and analyzed after 5 and 7 daysfor the presence of the replicative HBV DNA intermediates. Bothwt and canonical poly(A)-containing viruses produced equal amountsof HBsAg (data not shown); however, replicative HBV DNA intermediateswere detected only when cells were transfected with wt HBV DNA(Fig. 8A). As has been reported previously (31), HBV DNA isaccumulated after transfection, with the late appearance of therelaxed circular form (Fig. 8A, lane 3). These data clearly suggestthat the composite poly(A) signal with the embedded TATA box isessential for virus replication. A similar conclusion was drawnfrom an experiment whereby the virions in the culture medium wereassayed for DNA polymerase activity (Fig. 8B). Virions with activeDNA polymerase were found only in the culture of wt-transfectedcells, as measured by their capacity to incorporate [ $alpha$ -³²P]dCTP into the viral genome.

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FIG. 8. The composite P(A)S-TATA is instrumental in viral replication. Cells were transfected with the wt and the mutant plasmids as for Fig. 7 and were harvested after 5 and 7 days. The extracted DNA was subjected to 1% agarose gel electrophoresis, Southern blotted, and hybridized with a ³²P-labeled HBV DNA probe to determine the level of relaxed circular (RC) forms and single-stranded (SS) HBV DNA replicative intermediates (A). Viral particles were collected from culture media and assayed for their endogenous polymerase activity by measuring [ $alpha$ -³²P]dATP incorporation into the viral genome (B).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The HBV genome contains multiple promoters, each designed to support the production of a specific transcript. This type ofgene regulation program, which rarely employs splicing to increasethe RNA repertoire, is rather unique considering the small genomeof the virus. In this report we describe the presence of an additionalpromoter that so far was overlooked, perhaps due to its strategicposition. We provide biochemical as well as functional evidencethat the HBV polyadenylation signal sustains a cryptic promoteractivity. The HBV polyadenylation signal differs from the canonicalone (AATAAA) by a single base change and contains the sequenceTATAAA (the changed base is underlined). Such a change in thefirst nucleotide is very uncommon in vertebrate genomes (0.8%contain TATAAA and 98% contain AATAAA), and yet it is found inthe genomes of all the hepadnaviruses that infect mammals. Thisdeviant signal bears a cryptic TATA box and is therefore regardedas a composite element. By employing recombinant GTFs we couldshow that this cryptic TATA box binds TBP, TFIIA, and TFIIB ina manner characteristic of an authentic TATA box (19, 27).At a low TBP concentration no DNA-binding activity was seen, butthis was changed by the addition of TFIIA and TFIIB. The formeris sufficient to increase the DNA-binding activity of TBP (32,45). The addition of TFIIB resulted in the appearance of a strongDNase I-hypersensitive site, as was reported by others (27).Recently, it was shown that TFIIB has a DNA-binding domain thatinteracts with a CG-rich sequence positioned immediately upstreamof the TATA box (24). Interestingly, a similar sequence is foundat the correct position next to the HBV composite P(A)S-TATA box(see Fig. 5 for the sequence). The fact that TFIIB induced theappearance of a strong DNase I-hypersensitive site is a good indicationthat it binds the TATA box upstream region. This behavior of TFIIBnot only provides strong support for the HBV composite P(A)S-TATAbox in sustaining promoter characteristics but also was helpfulfor mapping the orientation of this TATA box (27). It was reportedthat the TATA box can in fact act bidirectionally, and the involvementof auxiliary TFIIA and TFIIB is essential to determine the correctorientation (7). Based on these data we defined the TATA boxorientation to be at the viral positive strand, where all theother viral promoters have beenmapped.

Functional analysis in the context of a heterologous reporter system revealed that the HBV composite box has promoter activity.At the moment we do not know how this promoter is regulated, butour data tend to suggest that it is a weak one. Based on the primerextension analysis we have estimated that this promoter is about20-fold weaker than the pc- and pgRNA promoters. The presenceof a nearby repressor element could explain the weak activityof the promoter, but it also could be an intrinsic behavior ofthis bifunctional box. The fact that the embedded cryptic TATAbox of the HBV composite P(A)S-TATA element was responsible forthe promoter activity was confirmed by mutagenesis studies. Apoint mutation that changed the TATA sequence to AATA resultedin the lost of GTF binding activity, with concomitant inabilityto supporttranscription.

To show that this promoter is active in the context of the viral genome, we conducted DNA transfection experiments. In theabsence of tissue culture infection this approach is widely usedto study the viral life cycle (1, 36, 44). Under theseconditions, by primer extension analysis we revealed a novel transcriptioninitiation site next to the P(A)S-TATA box. Others have detectedthis very same initiation site in cell lines that stably expresssome of the viral transcripts (35). Thus, it is likely thatthis promoter is active under a wide range of conditions. However,to strengthen the biological significance of this finding, invivo footprinting is required to confirm the occupancy of thisbox inside the cells. Although this is an important experiment,it cannot be performed with plasmid-transfected cells, and wemust await the development of an infectionsystem.

The HBV pgRNA is longer than the genome; therefore, for its synthesis the transcription machinery must ignore the poly(A)signal at the first round of transcription. The deviant natureof the HBV poly(A) signal might be important in this process (33).Indeed, in vitro studies designed to determine the relationshipbetween the sequence of the poly(A) signal and its activity haveclassified the HBV type of poly(A) signal sequence (TATAAA) asa poor one because it supports RNA processing with only 17% efficiency(39). Although this model is appealing, in our experiments wesee only about a twofold reduction in the level of pgRNA synthesisby a viral genome containing a canonical poly(A) signal comparedto the wt level (Fig. 7A). This model is also inconsistent withthe fact that duck HBV DNA, experiencing the same pattern of geneexpression, contains a canonical poly(A) signal. Furthermore,the poly(A) signal of the retroviruses is often positioned atthe R region, which is present at both the 5' and 3' ends. Theformer must be occluded, whereas the latter is efficiently utilized.This differential employment of the poly(A) signal of a givengenome is not achieved by the presence of a deviant poly(A) boxbut rather by other mechanisms (reference 22 and the referencestherein). Therefore, a deviant poly(A) signal is not instrumentalin this process but might have additional roles, such as functioningas apromoter.

A remarkable finding is that HBV DNA with a canonical poly(A) signal is replication defective despite its capacity to program,albeit with lower efficiency, the production of all the viraltranscripts. This might suggest that a very essential activityis missing. The first relevant and functional AUG of the putativenovel transcript is that of the viral Pol ORF. Pol is exceptionalin the sense that it is the only viral protein whose mechanismof production remains obscure. It has been speculated that Polis translated from the polycistronic pgRNA, but the underlyingmolecular mechanism is still unknown (for a review see reference11). The present work raises the possibility that a novel HBVtranscript regulates Pol production. This intriguing possibilitywas in part supported by genetic complementation analysis (datanot shown). Mutation of the HBV P(A)S to a canonical one was accompaniedby a single amino acid change encoded by the overlapping coreORF. The constructed HBV mutant was extremely inefficient in coreprotein accumulation, and, therefore, Pol was insufficient torescue the HBV P(A)S. An optimal complementation, however, wasachieved only when both the core and Pol were supplemented intrans (data not shown), consistent with the possibility that thenovel transcript is responsible for Polproduction.

Primer extension analysis revealed that the novel transcript is present at a much lower level (about 20-fold) than pc- andpgRNA. Also, the activity of its promoter in the context of theP(A)S-TATA reporter plasmids is lower than that of the E1b TATAbox (Fig. 4). The poor activity of this novel promoter is in accordancewith the assumption that only a single Pol polypeptide per virionis encapsidated (2), as opposed to the core protein, for whichabout 240 polypeptides are required (4). The low level of thisputative transcript might be the reason why so far it has escapeddetection by the conventional RNA analysistools.

A composite poly(A) signal with dual functions might be a mechanism exclusively adopted by the viruses that have highly compactgenome structures. However, an interplay between the poly(A) signaland transcription initiation was also found in Saccharomyces cerevisiae(13). It was found that a deletion in the GAL10 poly(A) signalresulted in complete inactivation of the GAL7 promoter, implyinga pivotal role for the poly(A) site in the transcription of adownstream gene. Thus, the poly(A) signal is also involved inthe termination to initiation switching. This documented case,together with our results, suggests the interesting possibilitythat the poly(A) signal may sustain additional functions in generegulation beyond its well-characterized role in supporting correctprocessing of the RNA 3'end.

Finally, the composite poly(A) signal, in the context of an episomal genome, can support the production of an approximatelygenome length transcript. Transcription initiation occurs about20 to 30 bp downstream of the TATA box, and the stretch of A residuesis usually added about 15 to 30 bases downstream of the poly(A)signal, where the initiation took place. At the moment we do notknow what might be the role of a genome length transcript in theHBV life cycle. However, to our knowledge, in animal cells sofar no mechanism for synthesis of such a transcript has been described;therefore, the significance of this finding might be general andrelevant to differentorganisms.

	ACKNOWLEDGMENT

N.P. and A.O. contributed equally to thiswork.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Genetics, The Weizmann Institute of Science, Rehovot 76100,Israel. Phone: 972-8-934-2320. Fax: 972-8-934-4108. E-mail: lvshaul{at}weizmann.weizmann.ac.il.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Acs, G., M. A. Sells, R. H. Purcell, P. Price, R. Engle, M. Shapiro, and H. Popper. 1987. Hepatitis B virus produced by transfected Hep G2 cells causes hepatitis in chimpanzees. Proc. Natl. Acad. Sci. USA 84:4641-4644[Abstract/Free Full Text].

2. Bartenschlager, R., and H. Schaller. 1992. Hepadnaviral assembly is initiated by polymerase binding to the encapsidation signal in the viral RNA genome. EMBO J. 11:3413-3420[Medline].

3. Benn, J., F. Su, M. Doria, and R. J. Schneider. 1996. Hepatitis B virus HBx protein induces transcription factor AP-1 by activation of extracellular signal-regulated and c-Jun N-terminal mitogen-activated protein kinases. J. Virol. 70:4978-4985[Abstract/Free Full Text].

4. Bottcher, B., S. A. Wynne, and R. A. Crowther. 1997. Determination of the fold of the core protein of hepatitis B virus by electron cryomicroscopy. Nature 385:88-91.

5. Buratowski, S., S. Hahn, L. Guarente, and P. A. Sharp. 1989. Five intermediate complexes in transcription initiation by RNA polymerase II. Cell 56:549-561[CrossRef][Medline].

6. Chen, I. H., C. J. Huang, and L. P. Ting. 1995. Overlapping initiator and TATA box functions in the basal core promoter of hepatitis B virus. J. Virol. 69:3647-3657[Abstract].

7. Cox, J. M., M. M. Hayward, J. F. Sanchez, L. D. Gegnas, S. van der Zee, J. H. Dennis, P. B. Sigler, and A. Schepartz. 1997. Bidirectional binding of the TATA box binding protein to the TATA box. Proc. Natl. Acad. Sci. USA 94:13475-13480[Abstract/Free Full Text].

8. Dikstein, R., O. Faktor, R. Ben-Levy, and Y. Shaul. 1990. Functional organization of the hepatitis B virus enhancer. Mol. Cell. Biol. 10:3682-3689.

9. Doria, M., N. Klein, R. Lucito, and R. J. Schneider. 1995. The hepatitis B virus HBx protein is a dual specificity cytoplasmic activator of Ras and nuclear activator of transcription factors. EMBO J. 14:4747-4757[Medline].

10. Faktor, O., T. De-Medina, and Y. Shaul. 1988. Regulation of hepatitis B virus S gene promoter in transfected cell lines. Virology 162:362-368[CrossRef][Medline].

11. Ganem, D. 1996. Hepadnaviridae and their replication, p. 2703-2737. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.

12. Garcia, A. D., P. Ostapchuk, and P. Hearing. 1993. Functional interaction of nuclear factors EF-C, HNF-4, and RXR $alpha$ with hepatitis B virus enhancer I. J. Virol. 67:3940-3950[Abstract/Free Full Text].

13. Greger, I. H., and N. J. Proudfoot. 1998. Poly(A) signals control both transcriptional termination and initiation between the tandem GAL10 and GAL7 genes of Saccharomyces cerevisiae. EMBO J. 17:4771-4779[CrossRef][Medline].

14. Haviv, I., Y. Matza, and Y. Shaul. 1998. pX, the HBV-encoded coactivator, suppresses the phenotypes of TBP and TAFII250 mutants. Genes Dev. 12:1217-1226[Abstract/Free Full Text].

15. Haviv, I., M. Shamay, G. Doitsh, and Y. Shaul. 1998. Hepatitis B virus pX targets TFIIB in transcription coactivation. Mol. Cell. Biol. 18:1562-1569[Abstract/Free Full Text].

16. Haviv, I., D. Vaizel, and Y. Shaul. 1995. The X protein of the hepatitis B virus coactivates acidic activation domains. Mol. Cell. Biol. 15:1079-1085[Abstract].

17. Haviv, I., D. Vaizel, and Y. Shaul. 1996. pX, the HBV-encoded coactivator, interacts with components of the transcription machinery and stimulates transcription in a TAF-independent manner. EMBO J. 15:3413-3420[Medline].

18. Honigwachs, J., O. Faktor, R. Dikstein, Y. Shaul, and O. Laub. 1989. Liver-specific expression of hepatitis B virus is determined by the combined action of the core gene promoter and the enhancer. J. Virol. 63:919-924[Abstract/Free Full Text].

19. Imbalzano, A. N., K. S. Zaret, and R. E. Kingston. 1994. Transcription factor (TF) IIB and TFIIA can independently increase the affinity of the TATA-binding protein for DNA. J. Biol. Chem. 269:8280-8286[Abstract/Free Full Text].

20. Johnson, P. F., W. H. Landschulz, B. J. Graves, and S. L. McKnight. 1987. Identification of a rat liver nuclear protein that binds to the enhancer core element of three animal viruses. Genes Dev. 1:133-146[Abstract/Free Full Text].

21. Junker, M., P. Galle, and H. Schaller. 1987. Expression and replication of the hepatitis B virus genome under foreign promoter control. Nucleic Acids Res. 15:10117-10132[Abstract/Free Full Text].

22. Klasens, B. I., A. T. Das, and B. Berkhout. 1998. Inhibition of polyadenylation by stable RNA secondary structure. Nucleic Acids Res. 26:1870-1876[Abstract/Free Full Text].

23. Klein, N. P., and R. J. Schneider. 1997. Activation of Src family kinases by hepatitis B virus HBx protein and coupled signaling to Ras. Mol. Cell. Biol. 17:6427-6436[Abstract].

24. Lagrange, T., A. N. Kapanidis, H. Tang, D. Reinberg, and R. H. Ebright. 1998. New core promoter element in RNA polymerase II-dependent transcription: sequence-specific DNA binding by transcription factor IIB. Genes Dev. 12:34-44[Abstract/Free Full Text].

25. Lin, Y., H. Tang, T. Nomura, D. Dorjsuren, N. Hayashi, W. Wei, T. Ohta, R. Roeder, and S. Murakami. 1998. The hepatitis B virus X protein is a co-activator of activated transcription that modulates the transcription machinery and distal binding activators. J. Biol. Chem. 273:27097-27103[Abstract/Free Full Text].

26. Luber, B., U. Lauer, L. Weiss, M. Hohne, P. H. Hofschneider, and A. S. Kekule. 1993. The hepatitis B virus transactivator HBx causes elevation of diacylglycerol and activation of protein kinase C. Res. Virol. 144:311-321[Medline].

27. Maldonado, E., I. Ha, P. Cortes, L. Weis, and D. Reinberg. 1990. Factors involved in specific transcription by mammalian RNA polymerase II: role of transcription factors IIA, IID, and IIB during formation of a transcription-competent complex. Mol. Cell. Biol. 10:6335-6347[Abstract/Free Full Text].

28. Natoli, G., M. L. Avantaggiati, P. Chirillo, P. L. Puri, A. Ianni, C. Balsano, and M. Levrero. 1994. Ras- and Raf-dependent activation of c-jun transcriptional activity by the hepatitis B virus transactivator pX. Oncogene 9:2837-2843[Medline].

29. Ori, A., and Y. Shaul. 1995. Hepatitis B virus enhancer binds and is activated by the hepatocyte nuclear factor 3. Virology 207:98-106[CrossRef][Medline].

30. Patel, N. U., S. Jameel, H. Isom, and A. Siddiqui. 1989. Interactions between nuclear factors and the hepatitis B virus enhancer. J. Virol 63:5293-5301[Abstract/Free Full Text].

31. Pugh, J. C., K. Yaginuma, K. Koike, and J. Summers. 1988. Duck hepatitis B virus (DHBV) particles produced by transient expression of DHBV DNA in a human hepatoma cell line are infectious in vitro. J. Virol. 62:3513-3516[Abstract/Free Full Text].

32. Roeder, R. G. 1996. The role of general initiation factors in transcription by RNA polymerase II. Trends Biochem. Sci. 21:327-335[CrossRef][Medline].

33. Russnak, R., and D. Ganem. 1990. Sequences 5' to the polyadenylation signal mediate differential poly(A) site use in hepatitis B viruses. Genes Dev. 4:764-776[Abstract/Free Full Text].

34. Sanfacon, H. 1994. Analysis of figwort mosaic virus (plant pararetrovirus) polyadenylation signal. Virology 198:39-49[CrossRef][Medline].

35. Schranz, P., H. Zentgraf, and C. H. Schroder. 1990. Integrated defective replication units of hepatitis B virus. Virus Genes 4:367-374[CrossRef][Medline].

36. Sells, M. A., M. L. Chen, and G. Acs. 1987. Production of hepatitis B virus particles in Hep G2 cells transfected with cloned hepatitis B virus DNA. Proc. Natl. Acad. Sci. USA 84:1005-1009[Abstract/Free Full Text].

37. Shaul, Y. 1991. Regulation of HBV transcription, p. 193-211. In A. McLachlan (ed.), Molecular biology of the hepatitis B virus. CRC Press, Boca Raton, Fla.

38. Shaul, Y., and R. Ben-Levy. 1987. Multiple nuclear proteins in liver cells are bound to hepatitis B virus enhancer element and its upstream sequences. EMBO J. 6:1913-1920[Medline].

39. Sheets, M. D., S. C. Ogg, and M. P. Wickens. 1990. Point mutations in AAUAAA and the poly (A) addition site: effects on the accuracy and efficiency of cleavage and polyadenylation in vitro. Nucleic Acids Res. 18:5799-5805[Abstract/Free Full Text].

40. Silver-Key, S. C., and J. S. Pagano. 1997. A noncanonical poly(A) signal, UAUAAA, and flanking elements in Epstein-Barr virus DNA polymerase mRNA function in cleavage and polyadenylation assays. Virology 234:147-159[CrossRef][Medline].

41. Su, F., and R. J. Schneider. 1996. Hepatitis B virus HBx protein activates transcription factor NF- $kappa$ B by acting on multiple cytoplasmic inhibitors of rel-related proteins. J. Virol. 70:4558-4566[Abstract].

42. Tuttleman, J. S., J. C. Pugh, and J. W. Summers. 1986. In vitro experimental infection of primary duck hepatocyte cultures with duck hepatitis B virus. J. Virol. 58:17-25[Abstract/Free Full Text].

43. Wilusz, J., S. M. Pettine, and T. Shenk. 1989. Functional analysis of point mutations in the AAUAAA motif of the SV40 late polyadenylation signal. Nucleic Acids Res. 17:3899-3908[Abstract/Free Full Text].

44. Yaginuma, K., Y. Shirakata, M. Kobayashi, and K. Koike. 1987. Hepatitis B virus (HBV) particles are produced in a cell culture system by transient expression of transfected HBV DNA. Proc. Natl. Acad. Sci. USA 84:2678-2682[Abstract/Free Full Text].

45. Yokomori, K., M. P. Zeidler, J. L. Chen, C. P. Verrijzer, M. Mlodzik, and R. Tjian. 1994. Drosophila TFIIA directs cooperative DNA binding with TBP and mediates transcriptional activation. Genes Dev. 8:2313-2323[Abstract/Free Full Text].

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1.	Acs, G., M. A. Sells, R. H. Purcell, P. Price, R. Engle, M. Shapiro, and H. Popper. 1987. Hepatitis B virus produced by transfected Hep G2 cells causes hepatitis in chimpanzees. Proc. Natl. Acad. Sci. USA 84:4641-4644[Abstract/Free Full Text].
2.	Bartenschlager, R., and H. Schaller. 1992. Hepadnaviral assembly is initiated by polymerase binding to the encapsidation signal in the viral RNA genome. EMBO J. 11:3413-3420[Medline].
3.	Benn, J., F. Su, M. Doria, and R. J. Schneider. 1996. Hepatitis B virus HBx protein induces transcription factor AP-1 by activation of extracellular signal-regulated and c-Jun N-terminal mitogen-activated protein kinases. J. Virol. 70:4978-4985[Abstract/Free Full Text].
4.	Bottcher, B., S. A. Wynne, and R. A. Crowther. 1997. Determination of the fold of the core protein of hepatitis B virus by electron cryomicroscopy. Nature 385:88-91.
5.	Buratowski, S., S. Hahn, L. Guarente, and P. A. Sharp. 1989. Five intermediate complexes in transcription initiation by RNA polymerase II. Cell 56:549-561[CrossRef][Medline].
6.	Chen, I. H., C. J. Huang, and L. P. Ting. 1995. Overlapping initiator and TATA box functions in the basal core promoter of hepatitis B virus. J. Virol. 69:3647-3657[Abstract].
7.	Cox, J. M., M. M. Hayward, J. F. Sanchez, L. D. Gegnas, S. van der Zee, J. H. Dennis, P. B. Sigler, and A. Schepartz. 1997. Bidirectional binding of the TATA box binding protein to the TATA box. Proc. Natl. Acad. Sci. USA 94:13475-13480[Abstract/Free Full Text].
8.	Dikstein, R., O. Faktor, R. Ben-Levy, and Y. Shaul. 1990. Functional organization of the hepatitis B virus enhancer. Mol. Cell. Biol. 10:3682-3689.
9.	Doria, M., N. Klein, R. Lucito, and R. J. Schneider. 1995. The hepatitis B virus HBx protein is a dual specificity cytoplasmic activator of Ras and nuclear activator of transcription factors. EMBO J. 14:4747-4757[Medline].
10.	Faktor, O., T. De-Medina, and Y. Shaul. 1988. Regulation of hepatitis B virus S gene promoter in transfected cell lines. Virology 162:362-368[CrossRef][Medline].
11.	Ganem, D. 1996. Hepadnaviridae and their replication, p. 2703-2737. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.
12.	Garcia, A. D., P. Ostapchuk, and P. Hearing. 1993. Functional interaction of nuclear factors EF-C, HNF-4, and RXR $alpha$ with hepatitis B virus enhancer I. J. Virol. 67:3940-3950[Abstract/Free Full Text].
13.	Greger, I. H., and N. J. Proudfoot. 1998. Poly(A) signals control both transcriptional termination and initiation between the tandem GAL10 and GAL7 genes of Saccharomyces cerevisiae. EMBO J. 17:4771-4779[CrossRef][Medline].
14.	Haviv, I., Y. Matza, and Y. Shaul. 1998. pX, the HBV-encoded coactivator, suppresses the phenotypes of TBP and TAFII250 mutants. Genes Dev. 12:1217-1226[Abstract/Free Full Text].
15.	Haviv, I., M. Shamay, G. Doitsh, and Y. Shaul. 1998. Hepatitis B virus pX targets TFIIB in transcription coactivation. Mol. Cell. Biol. 18:1562-1569[Abstract/Free Full Text].
16.	Haviv, I., D. Vaizel, and Y. Shaul. 1995. The X protein of the hepatitis B virus coactivates acidic activation domains. Mol. Cell. Biol. 15:1079-1085[Abstract].
17.	Haviv, I., D. Vaizel, and Y. Shaul. 1996. pX, the HBV-encoded coactivator, interacts with components of the transcription machinery and stimulates transcription in a TAF-independent manner. EMBO J. 15:3413-3420[Medline].
18.	Honigwachs, J., O. Faktor, R. Dikstein, Y. Shaul, and O. Laub. 1989. Liver-specific expression of hepatitis B virus is determined by the combined action of the core gene promoter and the enhancer. J. Virol. 63:919-924[Abstract/Free Full Text].
19.	Imbalzano, A. N., K. S. Zaret, and R. E. Kingston. 1994. Transcription factor (TF) IIB and TFIIA can independently increase the affinity of the TATA-binding protein for DNA. J. Biol. Chem. 269:8280-8286[Abstract/Free Full Text].
20.	Johnson, P. F., W. H. Landschulz, B. J. Graves, and S. L. McKnight. 1987. Identification of a rat liver nuclear protein that binds to the enhancer core element of three animal viruses. Genes Dev. 1:133-146[Abstract/Free Full Text].
21.	Junker, M., P. Galle, and H. Schaller. 1987. Expression and replication of the hepatitis B virus genome under foreign promoter control. Nucleic Acids Res. 15:10117-10132[Abstract/Free Full Text].
22.	Klasens, B. I., A. T. Das, and B. Berkhout. 1998. Inhibition of polyadenylation by stable RNA secondary structure. Nucleic Acids Res. 26:1870-1876[Abstract/Free Full Text].
23.	Klein, N. P., and R. J. Schneider. 1997. Activation of Src family kinases by hepatitis B virus HBx protein and coupled signaling to Ras. Mol. Cell. Biol. 17:6427-6436[Abstract].
24.	Lagrange, T., A. N. Kapanidis, H. Tang, D. Reinberg, and R. H. Ebright. 1998. New core promoter element in RNA polymerase II-dependent transcription: sequence-specific DNA binding by transcription factor IIB. Genes Dev. 12:34-44[Abstract/Free Full Text].
25.	Lin, Y., H. Tang, T. Nomura, D. Dorjsuren, N. Hayashi, W. Wei, T. Ohta, R. Roeder, and S. Murakami. 1998. The hepatitis B virus X protein is a co-activator of activated transcription that modulates the transcription machinery and distal binding activators. J. Biol. Chem. 273:27097-27103[Abstract/Free Full Text].
26.	Luber, B., U. Lauer, L. Weiss, M. Hohne, P. H. Hofschneider, and A. S. Kekule. 1993. The hepatitis B virus transactivator HBx causes elevation of diacylglycerol and activation of protein kinase C. Res. Virol. 144:311-321[Medline].
27.	Maldonado, E., I. Ha, P. Cortes, L. Weis, and D. Reinberg. 1990. Factors involved in specific transcription by mammalian RNA polymerase II: role of transcription factors IIA, IID, and IIB during formation of a transcription-competent complex. Mol. Cell. Biol. 10:6335-6347[Abstract/Free Full Text].
28.	Natoli, G., M. L. Avantaggiati, P. Chirillo, P. L. Puri, A. Ianni, C. Balsano, and M. Levrero. 1994. Ras- and Raf-dependent activation of c-jun transcriptional activity by the hepatitis B virus transactivator pX. Oncogene 9:2837-2843[Medline].
29.	Ori, A., and Y. Shaul. 1995. Hepatitis B virus enhancer binds and is activated by the hepatocyte nuclear factor 3. Virology 207:98-106[CrossRef][Medline].
30.	Patel, N. U., S. Jameel, H. Isom, and A. Siddiqui. 1989. Interactions between nuclear factors and the hepatitis B virus enhancer. J. Virol 63:5293-5301[Abstract/Free Full Text].
31.	Pugh, J. C., K. Yaginuma, K. Koike, and J. Summers. 1988. Duck hepatitis B virus (DHBV) particles produced by transient expression of DHBV DNA in a human hepatoma cell line are infectious in vitro. J. Virol. 62:3513-3516[Abstract/Free Full Text].
32.	Roeder, R. G. 1996. The role of general initiation factors in transcription by RNA polymerase II. Trends Biochem. Sci. 21:327-335[CrossRef][Medline].
33.	Russnak, R., and D. Ganem. 1990. Sequences 5' to the polyadenylation signal mediate differential poly(A) site use in hepatitis B viruses. Genes Dev. 4:764-776[Abstract/Free Full Text].
34.	Sanfacon, H. 1994. Analysis of figwort mosaic virus (plant pararetrovirus) polyadenylation signal. Virology 198:39-49[CrossRef][Medline].
35.	Schranz, P., H. Zentgraf, and C. H. Schroder. 1990. Integrated defective replication units of hepatitis B virus. Virus Genes 4:367-374[CrossRef][Medline].
36.	Sells, M. A., M. L. Chen, and G. Acs. 1987. Production of hepatitis B virus particles in Hep G2 cells transfected with cloned hepatitis B virus DNA. Proc. Natl. Acad. Sci. USA 84:1005-1009[Abstract/Free Full Text].
37.	Shaul, Y. 1991. Regulation of HBV transcription, p. 193-211. In A. McLachlan (ed.), Molecular biology of the hepatitis B virus. CRC Press, Boca Raton, Fla.
38.	Shaul, Y., and R. Ben-Levy. 1987. Multiple nuclear proteins in liver cells are bound to hepatitis B virus enhancer element and its upstream sequences. EMBO J. 6:1913-1920[Medline].
39.	Sheets, M. D., S. C. Ogg, and M. P. Wickens. 1990. Point mutations in AAUAAA and the poly (A) addition site: effects on the accuracy and efficiency of cleavage and polyadenylation in vitro. Nucleic Acids Res. 18:5799-5805[Abstract/Free Full Text].
40.	Silver-Key, S. C., and J. S. Pagano. 1997. A noncanonical poly(A) signal, UAUAAA, and flanking elements in Epstein-Barr virus DNA polymerase mRNA function in cleavage and polyadenylation assays. Virology 234:147-159[CrossRef][Medline].
41.	Su, F., and R. J. Schneider. 1996. Hepatitis B virus HBx protein activates transcription factor NF- $kappa$ B by acting on multiple cytoplasmic inhibitors of rel-related proteins. J. Virol. 70:4558-4566[Abstract].
42.	Tuttleman, J. S., J. C. Pugh, and J. W. Summers. 1986. In vitro experimental infection of primary duck hepatocyte cultures with duck hepatitis B virus. J. Virol. 58:17-25[Abstract/Free Full Text].
43.	Wilusz, J., S. M. Pettine, and T. Shenk. 1989. Functional analysis of point mutations in the AAUAAA motif of the SV40 late polyadenylation signal. Nucleic Acids Res. 17:3899-3908[Abstract/Free Full Text].
44.	Yaginuma, K., Y. Shirakata, M. Kobayashi, and K. Koike. 1987. Hepatitis B virus (HBV) particles are produced in a cell culture system by transient expression of transfected HBV DNA. Proc. Natl. Acad. Sci. USA 84:2678-2682[Abstract/Free Full Text].
45.	Yokomori, K., M. P. Zeidler, J. L. Chen, C. P. Verrijzer, M. Mlodzik, and R. Tjian. 1994. Drosophila TFIIA directs cooperative DNA binding with TBP and mediates transcriptional activation. Genes Dev. 8:2313-2323[Abstract/Free Full Text].