Processing of alpha -Globin and ICP0 mRNA in Cells Infected with Herpes Simplex Virus Type 1 ICP27 Mutants

doi:10.1128/JVI.74.16.7307-7319.2000

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Journal of Virology, August 2000, p. 7307-7319, Vol. 74, No. 16
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Processing of $alpha$ -Globin and ICP0 mRNA in Cells Infected with Herpes Simplex Virus Type 1 ICP27 Mutants

Kimberly S. Ellison,¹ Stephen A. Rice,² Robert Verity,¹ and James R. Smiley¹^,^*

Department of Medical Microbiology and Immunology, University of Alberta, Edmonton, Alberta, Canada T6G 2H7,¹ and Department of Microbiology, University of Minnesota Medical School, Minneapolis, Minnesota 55455²

Received 2 March 2000/Accepted 17 May 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Herpes simplex virus (HSV) ICP27 is an essential and multifunctional regulator of viral gene expression that modulates RNAsplicing, polyadenylation, and nuclear export. We have previouslyreported that ICP27 causes the cytoplasmic accumulation of unspliced $alpha$ -globin pre-mRNA. Here we examined the effects of a series ofICP27 mutations that alter important functional regions of theprotein on the processing and nuclear transport of $alpha$ -globin andHSV ICP0 RNA. The results demonstrate that ICP27 mutants thatare impaired for growth in noncomplementing cells, including mutantsin the N- and C-terminal regions, are defective in the accumulationof $alpha$ -globin pre-mRNA. Unexpectedly, several mutants that are competentto repress the expression of reporter genes in transient transfectionassays failed to accumulate unspliced RNA, implying that differentmechanisms are responsible for transrepression and pre-mRNA accumulation.Several mutants caused a marked increase in the length and heterogeneityof the $alpha$ -globin mRNA poly(A) tail, suggesting that ICP27 may directlyor indirectly affect the regulation of poly(A) polymerase. ICP27was also required for the accumulation of multiple ICP0 intron-bearingtranscripts, but this effect displayed a mutational sensitivityprofile different from that of accumulation of unspliced $alpha$ -globinRNA. Moreover, unlike spliced and unspliced $alpha$ -globin RNAs, whichwere efficiently exported to the cytoplasm, spliced and intron-containingICP0 transcripts were predominantly nuclear in localization, andICP27 was not required for nuclear retention of the spliced message.We propose that these transcript- and ICP27 allele-specific differencesmay be explained by the presence of a strong cis-acting ICP27response element in the $alpha$ -globintranscript.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Herpes simplex virus (HSV) is the prototypical member of the Herpesviridae, a large group of enveloped nuclear DNA virusesthat infect a wide range of metazoan organisms. Like all herpesviruses,HSV displays both lytic and latent modes of interaction with itsnatural human host (reviewed in reference 46). The HSV lyticcycle involves a complex genetic program encompassing a varietyof transcriptional and posttranscriptional controls (reviewedin references 13, 46, and 63): expression of most cellulargenes is strongly suppressed, and three temporal classes of viralgenes are sequentially activated in a regulatory cascade. Fiveimmediate-early (IE) genes are expressed first, through the transactivationfunction of the virion protein VP16 in combination with cellularfactors. Four of the IE gene products (ICP0, ICP4, ICP22, andICP27) are nuclear regulatory proteins that orchestrate the timelyexpression of the early (E) and late (L)genes.

The IE protein ICP27 is essential for the viability of the virus in cultured cells, and ICP27 homologs are present in allof the mammalian and avian herpesvirus genomes that have beencharacterized to date. ICP27 plays a fundamental and multifunctionalrole in the viral life cycle that has yet to be completely defined.HSV type 1 (HSV-1) ICP27 null mutants display reduced levels ofsome E and most L mRNAs and are defective in viral DNA replication(12, 26, 30, 41, 42, 48, 53, 59). In addition,they fail to efficiently suppress cellular gene expression (16,18, 48). The modes of action of ICP27 in these various processesare not completely clear; however, it is becoming increasinglyapparent that ICP27 functions primarily to modulate the posttranscriptionalprocessing and transport events that are required to convert nuclearprimary transcripts into functional mRNA molecules in the cytoplasm.It has been recognized for some time that ICP27 can activate orrepress the expression of reporter genes driven by HSV promotersin transient cotransfection assays (17, 30, 41, 42, 45,53, 58). Although it was initially thought that the activationand repression was at the transcriptional level, it is now clearthat ICP27 exerts these effects at least in part by modulatingthe processes of polyadenylation and splicing (18, 27, 28,37, 39, 51, 52). Rather than being promoter dependent,activation of gene expression results from the enhancement ofthe selection and cleavage of weak poly(A) sites (27-29, 52).The repression function correlates with the presence of intronsin the reporter genes (52), a finding that led to the view thatICP27 represses expression of intron-bearing genes by inhibitingRNA splicing. A significant amount of data has supported the notionthat ICP27 impairs or modulates splicing: (i) ICP27 colocalizeswith and redistributes snRNPs in HSV-infected cell nuclei (37);(ii) ICP27 coimmunoprecipitates with splicing factors that reactwith anti-Sm antisera and appears to alter the phosphorylationstatus of some of these proteins (50); and (iii) nuclear extractsprepared from cells infected with wild-type HSV carry out in vitrosplicing reactions less efficiently than those prepared from uninfectedcells, and this reduction requires ICP27 (18). It has been suggestedthat inhibition of splicing by ICP27 is responsible for the delayedshutoff of cellular gene expression that occurs during HSV infection(52). This is an appealing idea because unlike cellular genes,the majority of HSV genes do not contain introns, and thus HSVgene expression would be relatively resistant to inhibition. Consistentwith this hypothesis, ICP27 mutants fail to induce the declinein the levels of cellular mRNAs characteristic of infection withwild-type HSV (16, 18).

ICP27 is a nuclear/cytoplasmic shuttling protein (32, 38, 49, 55) and has been shown to bind RNA through a regionrich in arginine and glycine residues, the RGG box (33). A modelhas emerged recently suggesting that these activities mediatethe cytoplasmic accumulation of intronless viral L RNAs in a fashionsimilar to that for the human immunodeficiency virus (HIV) Revprotein (49, 55, 57). ICP27 may also play a role in increasingthe stability of certain RNAs (1).

In keeping with its multifunctional role in viral gene expression, the 512-residue ICP27 protein is composed of multiple functionalregions that confer several possibly independent properties onthe protein. For example, ICP27's nuclear/cytoplasmic shuttlingability is conferred by a leucine-rich nuclear export signal (NES)at the N terminus similar to that of the HIV Rev protein (49),in combination with multiple nuclear localization signals (NLS),including a strong NLS localized to amino acids 110 to 137 (31).The RGG box corresponds to residues 138 to 152 (33). The C-terminalhalf of the molecule has been implicated in the above-mentionedeffects on polyadenylation (the activation function) and splicing(the repression function) (17, 30, 42, 45), although residuesin the N terminus also appear to contribute to activation (45)and repression (44). Not surprisingly in view of the complexfunctions it fulfills, ICP27 has been shown to interact with numerousother viral and cellular proteins. Physical interactions withthe main viral transactivator, ICP4, have been documented (36).Furthermore, it has recently been shown that ICP27 can self-associate(65). Interactions with proteins of the splicing apparatus (50),hnRNP K and casein kinase 2 (61), have also been demonstrated,all of which may contribute in various ways to the functions ofICP27.

We have been investigating how ICP27 affects mRNA processing and nuclear export of the transcript encoded by the cellular $alpha$ -globin gene. Normally silent in cells of nonerythroid lineage,the $alpha$ -globin gene is induced during HSV infection by the actionsof the IE proteins ICP0, ICP4, and ICP22, leading to accumulationof correctly initiated RNAs (6). We have recently reportedthat ICP27, while having little effect on the levels of spliced $alpha$ -globin RNA, causes cytoplasmic accumulation of unspliced $alpha$ -globinpre-mRNA (5). This observation was surprising, for two reasons.First, a large body of evidence demonstrates that transcriptsof most intron-bearing cellular genes must be processed by thesplicing apparatus in order to access the nuclear export machinery(2, 7-9, 14, 19, 20, 22, 25, 35, 47). The processof splicing itself appears to be required, as evidenced by thefinding that cDNA copies of many intron-bearing genes fail todirect the accumulation of stable cytoplasmic RNA, and this defectcan be rescued by placing a heterologous intron in the transcriptionunit (14). Thus, our finding that ICP27 promotes cytoplasmicaccumulation of unspliced $alpha$ -globin RNA suggested that ICP27 providesa novel splicing-independent pathway for RNA export. Second, previousstudies by other investigators have been interpreted to indicatethat ICP27 induces nuclear retention of intron-bearing transcriptsof the HSV genes encoding ICP0 and UL15 (18, 39, 49). Thiseffect, ascribed to a global inhibition of splicing mediated byICP27, was taken to suggest that the RNA transport function ofICP27 distinguishes between transcripts arising from intron-bearingand intronless genes and is capable of transporting only the latter.In contrast, our data were more compatible with the hypothesisthat ICP27 stimulates splicing-independent transport of a specificsubset of RNAs, irrespective of the presence or absence ofintrons.

Our hypothesis that ICP27 causes the accumulation of $alpha$ -globin pre-mRNA by inducing a splicing-independent RNA transport system(rather than by inhibiting the process of splicing per se) raisedthe possibility that accumulation of unspliced $alpha$ -globin RNA couldbe uncoupled by mutation from the previously described transrepressionfunction of ICP27, which has been attributed to direct inhibitionof splicing. In addition, the contrast between our results andthose previously reported for intron-bearing transcripts of theHSV ICP0 and UL15 genes suggested that ICP27 can discriminatebetween different intron-bearing RNAs. Here we present the resultsof experiments that test these predictions, by examining the effectsof a large panel of ICP27 mutations on the processing and transportof $alpha$ -globin and ICP0RNAs.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cells and viruses. HeLa cells were maintained in Dulbecco's modified Eagle's medium (DMEM) supplemented with 10% fetal bovine serum (FBS). Verocells were propagated in DMEM containing 5% FBS. The HSV-1 wild-typestrain used in this study was KOS1.1 (24). The HSV strains bearingmutated versions of the ICP27 gene are shown in Fig. 1. Mutantsd27-1, n59R, n263R, n406R, and n504R (42, 45), d1-2 (44),d3-4 and d4-5 (31), and M11, M15, and M16 (43) have been describedelsewhere. Construction of the d1-5, d2-3, d5-6, and d6-7 viruses(S. A. Rice, V. Leong, and C. Guy, unpublished data) was analogousto that of the d3-4 and d4-5 viruses (31). The M1X and M2X viruseswere constructed as follows. Plasmid pM1 (43) was modified byinserting an NheI linker having stop codons in all three readingframes into the engineered XhoI site in the ICP27 gene at codons11 and 12. A recombinant HSV bearing this version of ICP27 wasgenerated and designated M1X. This virus produces a truncatedICP27 protein that reacts with monoclonal antibody H1113 (whichrecognizes residues 109 to 137) but not H1119 (which recognizesresidues 1 to 11) (S. A. Rice, unpublished data; 31). Thus,we assume that translation begins at the downstream AUG at codon50 and the truncated ICP27 protein lacks its N-terminal 49 aminoacids. Virus M2X was constructed in a similar fashion except thatthe NheI linker was inserted at the XhoI site of pM2 (43), whichis at codons 63 and 64. This virus does not make any detectableICP27 protein (Rice, unpublished). All ICP27 mutant strains werepropagated in V27 cells, which are derivatives of Vero cells engineeredto express ICP27 upon infection with HSV (42). V27 cells weremaintained in DMEM containing 5% FBS and 100 µg of Geneticin (G418;Gibco-BRL) per ml. Infections of HeLa cells (~80% confluent) werecarried out at a multiplicity of 10 PFU/cell, and in some experimentsphosphonoacetic acid (PAA; 300 µg/ml) was included in the mediumto inhibit viral DNA replication.

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FIG. 1. HSV-1 recombinants encoding altered forms of ICP27. Shown is a schematic diagram of the ICP27 polypeptide and the approximate positions of the NES, N-terminal acidic region, NLS, RGG box and C-terminal region. The positions of 16 XhoI sites engineered in a family of mutant ICP27 plasmids (43) are indicated. Mutants M11, M15, and M16 contain one or two altered amino acids as a consequence of the engineered XhoI sites at positions 11, 15, and 16, respectively. The sites were also used to construct the in-frame deletion mutants shown. The portion of the ICP27 polypeptide that is encoded in each mutant virus is shown by the horizontal lines. The growth characteristics of each mutant virus in Vero cells are indicated by their ability to form plaques and their virus yield relative to the yield of the wild-type (WT) virus. The ability of the ICP27 mutants to carry out the transrepression function of ICP27, as defined by transient transfection assays using reporter genes, is indicated. ND, not determined.

Isolation of RNA and Northern blot analysis. Total RNA was harvested from infected HeLa cells in 100-mm-diameter dishes using the Trizol reagent (Gibco-BRL). Poly(A)⁺ RNA was selected from total RNA using an Oligotex mRNA isolationkit (Qiagen). Nuclear and cytoplasmic RNA fractions were isolatedfrom infected HeLa cells in 60-mm-diameter dishes using an RNeasypurification kit (Qiagen). Briefly, infected cells were trypsinized,pelleted, and lysed in a buffer containing 0.5% NP-40, followedby centrifugation to pellet the nuclei. Cytoplasmic RNA was preparedfrom the supernatant according to the protocol given in the RNeasyhandbook. The pelleted nuclei from the cell fractionation protocolwere processed as described in the RNeasy handbook for whole cells,to give the nuclear RNA fraction. In some experiments, RNA wastreated with RNase H in the presence of oligo(dT) as previouslydescribed (5) to remove the poly(A) tail prior to Northernblot analysis. RNA samples (10 µg of total RNA or the correspondingcell equivalent of nuclear or cytoplasmic RNA) were electrophoresedon a 1 or 1.5% agarose-formaldehyde gel followed by blotting toa Genescreen membrane (NEN). The blot was hybridized to radiolabeledprobes specific for various RNA sequences. The probe used to detect $alpha$ -globin transcripts was a 1.5-kb PstI fragment bearing the entirehuman $alpha$ 2-globin gene purified from pUC $alpha$ 2 (6). All double-strandedICP0 probes were fragments purified from plasmid pSHZ, which bearsthe ICP0 open reading frame and surrounding sequences (34).The ICP0 exon/intron probe was a 1,078-bp NcoI-XhoI fragment;the ICP0 intron probe was a 165-bp PshAI fragment; the ICP0 upstreamprobe was a 160-bp SphI-DrdI fragment (see Fig. 4A). To preparethe ICP0 intron-specific riboprobe, plasmid pBS-9 was constructedby cloning a 165-bp PshAI fragment from pSHZ (blunt ended withthe large fragment of Escherichia coli DNA polymerase I) intothe SmaI site of the vector pBluescript II SK+ (Stratagene). Astrand-specific riboprobe was obtained by transcribing EcoRI-linearizedpBS-9 with T3 RNA polymerase in the presence of [³²P]CTP, followed by purification on a NucTrap column (Stratagene).To detect thymidine kinase (TK) transcripts, a 662-bp SstI/SmaIfragment from plasmid pTK173 (60) was used. All hybridizationswith double-stranded DNA probes or the riboprobe were carriedout in Church buffer (11) at 65°C. To probe for the U3 smallnucleolar RNA (snoRNA), a radiolabeled oligonucleotide specificfor U3 was used as previously described (5); this hybridizationwas done in ExpressHyb (Clontech) according to the usermanual.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

ICP27 mutations that impair virus replication prevent accumulation of unspliced $alpha$ -globin RNA. We previously reported that expression of functional ICP27 is necessary and sufficient for cytoplasmic accumulation of unsplicedpolyadenylated $alpha$ -globin mRNA in HSV-1-infected HeLa cells (5).To investigate which regions of the ICP27 protein mediate pre-mRNAaccumulation, we examined the $alpha$ -globin transcripts in cells infectedwith a panel of HSV-1 recombinants in which each encodes a differentmutated version of ICP27 (Fig. 1). The ICP27 protein can be dividedinto several functional regions. At the amino terminus is theleucine-rich NES (amino acids 5 to 17) (49), which partiallyoverlaps an acidic region extending from amino acids 12 to 63(44). The strong NLS at amino acids 110 to 137 (31) is immediatelyadjacent to the RGG box (residues 138 to 152) (33), which mediatesRNA binding. The C-terminal region (from amino acids 262 to 512),conserved in all mammalian and avian herpesvirus ICP27 homologs(1), is particularly sensitive to mutations, and this halfof the protein is required for the transactivation and transrepressionfunctions of ICP27 (17). However, sequences located in the N-terminalportion of the polypeptide also play a role in these functions(44, 45). The mutations analyzed include a null mutant havinga deletion of most of the ICP27 open reading frame (d27-1), N-terminal(M1X) and C-terminal (n59R, n263R, n406R, n504R, and M2X) deletions,clustered point mutations that alter one or two amino acids inthe C-terminal region (M11, M15, and M16), and in-frame deletionswithin the coding sequence (d1-2, d2-3, d3-4, d4-5, d5-6, d6-7,and d1-5) (Fig. 1). The latter were engineered to precisely removecertain segments of the ICP27 protein; for example, d1-2 deletesthe acidic region, and d3-4 and d4-5 remove the NLS and the RGGbox, respectively. Detailed phenotypic analyses of many of thesemutant viruses have been previously reported (see reference listin Fig. 1). The mutants can be grouped into three categories,based on their ability to replicate in Vero cells: (i) mutantsd27-1, n59R, n263R, n406R, n504R, M11, M15, M16, d1-2, d4-5, d1-5,M1X, and M2X are growth defective, being unable to form plaquesor forming plaques at greatly reduced efficiency; (ii) mutantsd2-3 and d3-4 are growth deficient, being able to form plaquesbut having reduced yields in single-cycle growth assays; and (iii)mutants d5-6 and d6-7 are replication competent, being indistinguishablefrom the wild-typevirus.

HeLa cells were infected with each mutant virus in the presence of PAA, and total RNA was harvested at 6 h postinfection.The RNA samples were either left untreated (Fig. 2A) or treatedwith RNase H in the presence of oligo(dT) to remove the poly(A)tail (Fig. 2B) and then analyzed for the presence of $alpha$ -globintranscripts by Northern blot hybridization. As we have observedpreviously (5), removal of the poly(A) tail resulted in a considerablesharpening of the $alpha$ -globin bands (discussed further below). DeadenylatedRNA extracted from cells infected with the wild-type virus (KOS1.1)displayed three species of $alpha$ -globin RNA (ca. 580, 700, and 840nucleotides [nt]), with the 700-nt RNA being considerably lessabundant than the other two (Fig. 2B). We have previously shownthat these RNAs correspond to fully spliced (576 nt), partiallyspliced (688 and 718 nt), and unspliced (835 nt) $alpha$ -globin transcriptsthat start at the $alpha$ -globin promoter and are processed at the $alpha$ -globinpoly(A) site (5). Cells infected with the ICP27 null virus,d27-1, accumulated only the fully spliced species, confirmingour previous finding that ICP27 is required for the accumulationof unspliced RNA (5). All of the ICP27 mutant viruses inducedaccumulation of the fully spliced mRNA, although we note thatthe signal intensity was somewhat reduced in infections with severalof the mutant viruses (particularly n406R, M11, and d1-2). Wehave not yet determined the basis for this reduction, but it wasseen in multiple experiments. In contrast, only two of the mutants,d5-6 and d6-7, showed accumulation of the unspliced $alpha$ -globin transcript(Fig. 2B); all of the other mutants were as defective as d27-1in this respect. These data demonstrate first that the ICP27 mutantsthat are defective for virus replication in cultured cells failto accumulate unspliced $alpha$ -globin RNA, while those that are replicationcompetent display wild-type levels of unspliced RNA. Second, multiplenonoverlapping segments of ICP27, including the N- and C-terminalregions, are required for accumulation of $alpha$ -globin pre-mRNA. Third,and somewhat surprisingly, several of the mutant forms of ICP27that have been previously shown to retain the ability to repressreporter gene expression in transient transfection experiments(n406R, n504R, M11, M15, M16, and d1-2 [Fig. 1]) neverthelessfail to accumulate unspliced $alpha$ -globin RNA. It has been suggestedthat the transrepression function of ICP27 is a consequence ofimpaired splicing by ICP27, because repression correlates withthe presence of introns in the reporter gene (16, 18, 52).Our findings argue that the accumulation of unspliced transcriptsby ICP27 can be uncoupled by mutation from the repression function.

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FIG. 2. Effect of ICP27 mutants on accumulation of $alpha$ -globin pre-mRNA. HeLa cells were infected with the indicated ICP27 mutant viruses at a multiplicity of 10 in the presence of PAA. Total RNA was harvested 6 h postinfection, and 10 µg was either left untreated (A) or treated with RNase H in the presence of oligo(dT) to remove the poly(A) tails (B). $alpha$ -Globin transcripts were detected by Northern blot analysis. M, RNA markers in kilobases. The $alpha$ -globin transcript in RNA isolated from blood is shown as a control.

Several ICP27 mutations markedly increase the length and heterogeneity of the $alpha$ -globin mRNA poly(A) tail. The poly(A) tails of most mRNAs vary in length from ca. 200 to 250 nt. Spliced $alpha$ -globin mRNA is only ca. 580 nt long [excludingthe poly(A) tail], and the heterogeneity in the poly(A) tail thereforesignificantly influences its electrophoretic mobility, leadingto diffuse bands on a Northern blot. This can be observed quiteclearly with the RNA from KOS1.1-infected cells (Fig. 2A): withoutprior deadenylation, the unspliced, partially spliced, and splicedbands were broad and poorly resolved. Likewise, the spliced mRNAsignal from the d27-1 infection was quite diffuse. In both cases,these relatively diffuse bands collapsed into sharper bands ofthe predicted sizes after the poly(A) tails were removed by treatmentwith RNase H in the presence of oligo(dT) (compare Fig. 2A andB). Remarkably, several of the ICP27 mutants gave rise to exceptionallydiffuse (and more slowly migrating) signals when RNA retainingthe poly(A) tail was examined (Fig. 2A, mutants n406R, M11, M16,d1-2, and to a lesser extent M15). In fact, without removal ofthe poly(A) tail, we were unable to definitively determine whetherthe signals observed corresponded to spliced or unspliced RNAor to a mixture of the two as in the KOS1.1 sample. However, inthe n406R, M11, M15, and M16 samples, the heterogeneity was eliminatedby treatment with RNase H-oligo(dT), giving rise to a single sharpband corresponding to spliced RNA (Fig. 2B). This effect is shownmore clearly in the experiment depicted in Fig. 3A (-RNase H),where RNA from cells infected with M11, M15, M16, n406R, and d1-2were directly compared to the d27-1 sample. The M11, M15, M16,n406R, and d1-2 RNAs all migrated more slowly than the d27-1 sampleand gave rise to a broad indistinct signal. However, with theexception of RNA from cells infected with mutant d1-2, removingthe poly(A) tail resolved the majority of the signal into a discrete580-nt band that comigrated with the spliced mRNA band in KOS1.1-infectedcells and in blood RNA (Fig. 3A, +RNase H +oligo dT). By far themost likely explanation of these data is that the mutations inthe n406R, M11, M15, and M16 viruses greatly increase the lengthand heterogeneity of the poly(A) tail of spliced $alpha$ -globin mRNA.In the case of mutant d1-2, deadenylation of the RNA revealeddetectable quantities of unspliced and partially spliced transcripts,although in lower amounts than in KOS1.1 RNA, which at least partlyaccounts for the broad $alpha$ -globin signal in the untreated sample.The most striking example of the poly(A) extension effect is evidentwith the n406R mutant (Fig. 3B). In cells infected with n406R,the $alpha$ -globin RNA is significantly higher in molecular weight thanthe d27-1 counterpart, and the signal extends almost to the positionof the unspliced transcript present in KOS1.1-infected cells,which is 260 nt longer than the spliced mRNA (Fig. 3B, -RNaseH). We estimate from these data that the poly(A) tail of $alpha$ -globinmRNA in cells infected with this mutant ranges in length from~275 to 520 nt, markedly longer and more heterogeneous than therelatively discrete 200- to 250-nt tail observed in d27-1 infections.This extension phenomenon is clearly a consequence of expressingthe altered ICP27 protein, as the effect was not seen with eitherwild-type or ICP27-null virus. Moreover, a marker-rescued virusin which the n406R ICP27 allele was replaced with the wild-typeallele did not display the extension phenotype (data not shown).Although we do not know the mechanism by which some mutant formsof ICP27 cause extension of the poly(A) tail, these data suggestthat ICP27 may be intimately involved with the polymerizationof the poly(A) tail in addition to its previously documented effectson poly(A) site selection and usage (27-29).

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FIG. 3. Several ICP27 mutants cause an increase in the length and heterogeneity of the $alpha$ -globin 3' poly(A) tail. (A) Total RNA was harvested from HeLa cells infected with the indicated ICP27 mutant viruses in the presence of PAA at 6 h postinfection. The RNA was analyzed for the presence of $alpha$ -globin transcripts before or after removal of the poly(A) tail by treatment with RNase H and oligo(dT). The $alpha$ -globin transcript in RNA isolated from blood is shown as a control. (B) Total RNA was isolated from HeLa cells that were either mock infected or infected with HSV-1 strain KOS1.1, d27-1, or n406R in the presence of PAA. $alpha$ -Globin transcripts were detected by Northern blot hybridization before or after removal of the poly(A) tail by treatment with RNase H and oligo(dT). M, RNA markers in kilobases.

Multiple intron-bearing ICP0 transcripts are present in HSV-infected HeLa cells. It has been suggested in the literature that ICP27 induces the delayed shutoff of host protein synthesis by virtue of itsability to inhibit RNA splicing (16, 18, 52). However, wehave previously shown that although ICP27 induces accumulationof unspliced $alpha$ -globin RNA, it does not detectably inhibit accumulationof the fully spliced globin transcript (5). Moreover, the datapresented in Fig. 2 demonstrate that accumulation of unspliced $alpha$ -globin RNA can be uncoupled from ICP27's repression function(which is thought to reflect inhibition of splicing). The ICP0gene is one of the few HSV-1 genes that contain introns (Fig.4A), and it has been reported that ICP27 causes the accumulationof ICP0 pre-mRNA in infected cells (18, 39, 49). These datahave been interpreted to indicate that ICP27 inhibits the splicingof HSV transcripts as well as cellular RNAs. Given our results,we wished to confirm that ICP27 induces accumulation of unsplicedICP0 RNA in our experimental system and examine the effects ofour panel of ICP27 mutations on this process. In particular, wewished to determine if accumulation of unspliced RNA could beuncoupled from the repression function of ICP27 with this transcriptas well.

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FIG. 4. Northern blot analysis detects more than one ICP0 intron-bearing transcript in KOS1.1-infected HeLa cells, and their accumulation requires ICP27. (A) Schematic diagram of the HSV-1 ICP0 gene. Exon sequences are indicated by filled boxes, and introns are marked by dashed lines. Positions of the mRNA start site, ATG start codon, TAA stop codon, 5' and 3' untranslated regions, and the poly(A) cleavage site are shown. The fragments specific for upstream sequences, intron 1 sequences, and exon plus intron sequences that were used to prepare radiolabeled probes for Northern blot analysis are indicated by hatched bars. (B) Total RNA or poly(A)⁺ RNA was prepared from mock-infected, KOS1.1-infected, or d27-1-infected HeLa cells at 6 h postinfection. Northern blot analysis was conducted using the intron-specific probe (right), and then the membrane was reprobed with the exon/intron probe (left). Transcripts were given the designations a to f for ease of description in the text. M, RNA size markers in kilobases. (C) Northern blot of total RNA from mock-infected, KOS1.1-infected, or d27-1-infected HeLa cells using the ICP0 intron 1 strand-specific riboprobe. (D) Northern blot of total RNA from mock-infected or KOS1.1-infected HeLa cells using the upstream probe (left) and the intron 1 probe (right).

We examined the ICP0 transcripts present in HSV-infected HeLa cells by Northern blot hybridization (Fig. 4B). It should benoted that previous studies used in situ hybridization (39)or RNase protection (16, 18) to detect unspliced ICP0 RNA;although these methods are useful, they do not give an overviewof the number and structures of the transcripts detected. Totaland poly(A)⁺ RNA was isolated from cells infected in the presence of PAA withwild-type KOS1.1 or the ICP27 null d27-1 at 6 h postinfection.We used two probes to analyze the ICP0 transcripts (Fig. 4A).The exon/intron probe extends from the beginning of exon 1 throughthe first intron into the 5' portion of exon 2 and should detectall ICP0 transcripts. In contrast, the intron probe detects onlyunspliced RNAs retaining intron 1. Total RNA extracted from cellsinfected with KOS1.1 contained at least six transcripts that hybridizedto the exon/intron probe (labeled a to f in Fig. 4B). These rangedin size from ca. 800 nt (transcript a) to ca. 7 kb (transcriptf). Transcript a was also detected with the intron-specific probe,and this small RNA was not recovered in the poly(A)⁺ RNA fraction. We therefore conclude that it corresponds to theexcised intron 1 RNA previously observed by other investigators(4). In contrast, transcripts b, c, and e (and possibly d)were all recovered in the poly(A)⁺ fraction. Transcript b (~2,700 to 2,800 nt) is the size predictedfor ICP0 mRNA and did not hybridize to the intron probe. Takentogether, these data indicate that transcript b corresponds tospliced, polyadenylated ICP0 mRNA. The larger transcripts (c tof) all hybridized to the intron probe and thus contain at leasta portion of intron 1. RNA from d27-1-infected cells displayedonly transcripts a and b (free intron 1 and fully spliced mRNA,respectively). Thus, ICP27 was required for the accumulation ofall of the larger intron-bearing transcripts, in accord with theobservations ofothers.

We examined the nature of these intron-bearing RNAs in more detail. Transcript c (~3,500 nt) is the size predicted for RNAthat initiates at the ICP0 gene promoter, bears both introns,and terminates at the designated ICP0 poly(A) site (Fig. 4A).Additional evidence supporting that assignment is presented below.The remaining RNA species (d to f) are all significantly larger,and notably, one of these (transcript e) is considerably moreabundant than transcript c. It is unclear if RNAs d and e areseparate species, since there is some distortion at this positionon the gel due to the presence of the 28S rRNA. All of these transcripts(with the possible exception of d) hybridized to a strand-specificriboprobe derived from intron 1 (Fig. 4C), demonstrating thatthey are transcribed from the same DNA strand as ICP0 mRNA. Inprinciple, these larger intron-bearing transcripts might initiateupstream of the ICP0 mRNA start site and/or terminate downstreamof the poly(A) site. To investigate these possibilities, duplicatesamples of total RNA from KOS1.1-infected cells were run on thesame gel and blotted to a Genescreen membrane. One half of themembrane was probed with a labeled DNA fragment derived from sequenceslocated immediately upstream of the ICP0 mRNA start site (Fig.4A), and the other half was probed with the intron 1 probe (Fig.4D). The upstream probe did not detect band a, b, or c, consistentwith our designation of these RNAs as the excised intron 1, splicedmRNA, and ICP0 pre-mRNA initiating at the ICP0 promoter, respectively.The upstream probe did, however, detect bands d, e, and f, andalso illuminated an additional transcript labeled g. These datademonstrate that the larger intron-containing transcripts (d tof) initiate upstream of the ICP0 promoter and read through atleast a portion of the ICP0 intron 1. The transcriptional polarityof transcript g has not yet been determined. We have not determinedexactly where transcripts d to f initiate orterminate.

Taken together, these data show that several transcripts bearing at least part of ICP0 intron 1 accumulate in HeLa cells infectedwith wild-type HSV-1. The origin of some of these RNAs is notclear, but several initiate upstream of the ICP0 promoter. Importantly,accumulation of all of these intron-containing transcripts requiresthe ICP27 protein, under these conditions of infection. Transcriptc is the most likely candidate for bona fide ICP0 pre-mRNA (i.e.,the pre-mRNA that is spliced to produce translatable ICP0 mRNA).It is worth pointing out that ICP0 transcript c is much less abundantrelative to spliced ICP0 mRNA than the $alpha$ -globin pre-mRNA is relativeto spliced $alpha$ -globin mRNA: the relative band intensity of RNA cis considerably lower than its $alpha$ -globin counterpart; in additionthe ICP0 exon/intron probe used is composed mostly of intron sequences(only 29% of the length of the probe is homologous to the exonsequences), and thus the band intensity of the mRNA species isunderrepresented three- to fourfold relative to the intron-bearingtranscripts. In contrast, the $alpha$ -globin probe used is 70% exonic,and the unspliced $alpha$ -globin signal is often as intense as thatof the fully spliced RNA (Fig. 2, 3, and 6). Thus, compared to $alpha$ -globin pre-mRNA, ICP0 transcript c is a very minor species.These considerations suggest that ICP27 causes the accumulationof $alpha$ -globin pre-mRNA much more efficiently than ICP0 pre-mRNA.

Effect of ICP27 mutations on accumulation of ICP0 intron-bearing transcripts. The foregoing data confirmed that ICP27 is required for accumulation of intron-bearing transcripts of both the $alpha$ -globin andICP0 genes. We next wished to determine if accumulation of theintron-containing ICP0 transcripts exhibits the same mutationalsensitivity spectrum as accumulation of unspliced $alpha$ -globin pre-mRNA.Total RNA harvested from cells infected with the panel of ICP27mutants in the presence of PAA was analyzed by Northern blot hybridizationusing the ICP0 exon/intron (Fig. 5A) and intron 1 (Fig. 5B) probes.Transcripts were given the same designations (a to f) as in Fig.4. Fully spliced ICP0 mRNA was present in all of the samples,as was the excised intron 1 (Fig. 5A, bands b and a, respectively).Several of the mutants (d2-3 and d3-4 in particular) displayedreduced levels of these RNAs; we have not determined the basisfor this reduction. Unlike the results obtained with $alpha$ -globinRNA, we noted several different phenotypes with respect to thetranscripts containing intron 1 sequences (Fig. 5B). First, themajority of the mutant viruses (n59R, n263R, M15, d2-3, d3-4,d4-5, d1-5, M1X, and M2X) behaved like the ICP27-null mutant,d27-1: in these infections, no intron-containing transcripts wereevident. Second, d5-6 and d6-7 displayed the same spectrum ofintron-bearing RNAs as the wild-type virus. d5-6 and d6-7 arethe only mutants analyzed that are not growth impaired in Verocells, and they also efficiently accumulate $alpha$ -globin pre-mRNA.Third, four mutants (n406R, n504R, M11, and M16) accumulated theintron-containing RNAs that initiate upstream of the ICP0 promoter(RNAs d to f) but failed to display the intron-containing transcriptthat likely initiates at the ICP0 promoter (RNA c). Mutant n406Rdisplayed the most striking example of this phenotype, in thattranscripts d to f were overproduced relative to wild-type KOS1.1.Finally, in the d1-2 infection, all of the intron-bearing RNAswere lacking, but a faint new band that migrates slightly higherthan transcript c appeared. We have not investigated the natureof this transcript further. We conclude from these data that theeffects of ICP27 on accumulation of intron-bearing RNAs are bothtranscript and ICP27 allele specific. While d5-6 and d6-7 displaythe wild-type phenotype, several other ICP27 mutants distinguishbetween ICP0 transcript c and $alpha$ -globin pre-mRNA on one hand (noaccumulation) and ICP0 transcripts d to f on the other (accumulation).Possible explanations for these findings are presented below (seeDiscussion).

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FIG. 5. Effect of ICP27 mutants on accumulation of ICP0 intron-bearing transcripts. HeLa cells were infected with the indicated viruses at a multiplicity of 10 in the presence of PAA, and total RNA was harvested 6 h postinfection. Ten micrograms of each RNA was subjected to Northern blot analysis using the ICP0 intron 1 probe (B). The membrane was subsequently reprobed with the ICP0 exon/intron probe (A). Positions of transcripts a to f are indicated. M, RNA size markers in kilobases.

Subcellular localization of $alpha$ -globin and ICP0 transcripts. We previously reported that the unspliced $alpha$ -globin pre-mRNA that accumulates as a consequence of ICP27 expression is efficientlyexported into the cytoplasm (5). This finding was surprisingbecause, as reviewed in the introduction, intron-bearing transcriptsare normally confined to the nucleus, and substantial evidenceindicates that such pre-mRNAs must be processed by the splicingapparatus in order to access the nuclear export machinery. Basedon our data, we proposed that ICP27 induces a splicing-independentpathway for nuclear export, one that transports specific transcriptsirrespective of the presence or absence of introns. However, ithas been previously observed that ICP27 causes the accumulation,preferentially in the nucleus, of intron-bearing transcripts ofthe HSV ICP0 and UL15 genes, an effect that was ascribed to inhibitionof splicing (18, 39, 49). This has led to the suggestionthat the ICP27-induced RNA transport system globally distinguishesbetween transcripts of intronless and intron-bearing genes, transportingthe former and blocking splicing and export of the latter (49).We therefore compared the effects of ICP27 on the subcellularlocalization of $alpha$ -globin and ICP0 pre-mRNA in more detail, inan attempt to resolve the apparent discrepancies between our dataand the interpretations that currently prevail in theliterature.

A major factor that could influence the nuclear/cytoplasmic distribution of mRNA and pre-mRNA is the onset of viral DNA replication.We have routinely blocked viral DNA replication with PAA in allof our previous studies of ICP27's effects on $alpha$ -globin pre-mRNAmetabolism, for two reasons. First, expression of the chromosomal $alpha$ -globin gene declines after 6 h postinfection, like that of viralE genes, and this decline is prevented by blocking viral DNA replication(6). Second, and more important, ICP27-null mutants displaya marked defect in viral DNA replication, and the various ICP27mutants that we have analyzed differ considerably in the abilityto support DNA replication. The onset of DNA replication profoundlyaffects viral gene expression and leads to pronounced changesin nuclear organization. We included PAA to eliminate these potentiallyconfounding secondary effects, which are predicted to vary substantiallybetween the ICP27 mutants. In contrast, the previous study indicatingthat ICP27 causes nuclear retention of ICP0 pre-mRNA did not controlfor the effects of viral DNA replication (39). We thereforeexamined the subcellular localization of $alpha$ -globin and ICP0 RNAs,in the presence or absence of a blockade of viral DNA replicationimposed by PAA (Fig. 6 and 7).

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FIG. 6. Cytoplasmic accumulation of unspliced and spliced $alpha$ -globin RNA is independent of viral DNA replication. HeLa cells were mock infected or infected with HSV-1 strain KOS1.1 in the absence or presence of PAA. At 3, 6, 9, or 12 h postinfection, nuclear (N) or cytoplasmic (C) RNA fractions were prepared. RNA from an equal number of cells was analyzed by Northern blotting for the presence of $alpha$ -globin transcripts (A) or the U3 snoRNA (B).

In the first such experiment, nuclear and cytoplasmic RNA was harvested at various times after infection with wild-type KOS1.1,and deadenylated samples were scored for the presence of splicedand unspliced $alpha$ -globin RNA by Northern blot hybridization (Fig.6A). As a control, the same membrane was probed with an oligonucleotidespecific for the U3 snoRNA, an exclusively nuclear RNA (Fig. 6B).The U3 snoRNA was detected only in the nuclear RNA samples, indicatingthat the cytoplasmic RNA was free of nuclear RNA contamination.As reported previously (6), $alpha$ -globin transcript levels peakedat 6 h postinfection in the absence of PAA, and at this time pointa significant fraction of the pre-mRNA and mRNA was cytoplasmic(lanes 5 and 6). As the infection progressed, the combined pre-mRNAand mRNA signal declined, and both species became increasinglycytoplasmic (lanes 7 to 10). This progressive shift is consistentwith the hypothesis that $alpha$ -globin RNA synthesis declines at latertimes, while nuclear export of the preexisting transcripts continues.The overall decline in the $alpha$ -globin signal likely stems from turnoverin the cytoplasm. Consistent with this interpretation, the declineis largely eliminated by inactivating the virion host shutoffprotein vhs (P. Cheung and J. R. Smiley, unpublished data). Inthe presence of PAA, the levels of $alpha$ -globin RNA increased overtime, and the unspliced and spliced transcripts efficiently gainedaccess to the cytoplasm at all time points (lanes 11 to 18). Thesedata demonstrate that PAA does not greatly influence the nuclearexport of $alpha$ -globin mRNA or pre-mRNA. In particular, the unsplicedRNA is largely cytoplasmic in both the presence and absence ofthedrug.

We next examined the effects of ICP27 and PAA on the subcellular distribution of ICP0 transcripts at 6 and 12 h postinfection(Fig. 7A). We also probed the same samples for HSV TK mRNA (Fig.7B), which is derived from an intronless viral gene. Previousstudies have indicated that TK mRNA contains multiple cis-actingelements that mediate its nuclear export, likely via interactionswith the cellular protein hnRNP L (25). Controls confirmed that,as expected, U3 snoRNA was recovered exclusively in the nuclearfraction (Fig. 7C). The profiles of ICP0 transcripts at 6 h postinfectionwere similar in the presence and absence of PAA (Fig. 7A): transcriptsa to e, as defined in Fig. 4, were readily discernible in theKOS1.1 samples, and only transcripts a and b were evident in d27-1RNA (the faint higher-molecular-weight band in the d27-1 lanes5 and 13 was not detected with the intron 1 probe [data not shown]).It is interesting that transcript c, the presumed bona fide ICP0pre-mRNA, was not apparent in KOS1.1-infected cells at 12 h postinfection,in either the absence or presence of PAA (lanes 8, 15, and 16).The d27-1 RNA harvested 12 h postinfection from cells infectedin the absence of PAA (lane 9) displayed the intron-bearing transcriptsd and e, in addition to the intron 1 RNA and the spliced message(RNAs a and b, respectively). Thus, unlike at early times of infection,the accumulation of these intron-bearing transcripts was not strictlydependent on ICP27 expression at late times under replication-competentconditions. The significance of this observation is unknown atpresent. Significant quantities of each of the ICP0 transcriptscould be detected in the cytoplasm in cells infected with KOS1.1in the absence of PAA, as has been observed previously (18,49); however, the majority of RNAs b to e was recovered in thenucleus (Fig. 7A, lanes 3, 4, 7, and 8). This nuclear retentionwas greatly exaggerated at 12 h postinfection. Notably, retentionwas not confined to the intron-bearing RNAs but was exhibitedby the spliced mRNA as well (transcript b). Furthermore, a similardegree of nuclear retention of the spliced mRNA was observed ind27-1 infections (Fig. 7A, lanes 5, 6, 9, and 10). Interestingly,the exception to the nuclear retention phenotype was band a, whichcorresponds to excised intron 1. A significantly greater proportionof this RNA than of the other transcripts was cytoplasmic, independentof the presence or absence of ICP27. Cytoplasmic accumulationof ICP0 intron 1, by unknown mechanisms, has been described previously(4). ICP0 transcript levels were considerably reduced in thepresence of PAA (lanes 11 to 18), especially at 12 h postinfection,and modest levels of nuclear retention were observed. These resultsindicate that in HeLa cells, ICP0 transcripts are predominantlynuclear regardless of the presence or absence of intron sequences.This retention is not obviously mediated by ICP27, since the splicedmRNA is preferentially located in the nucleus even in the absenceof functional ICP27.

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FIG. 7. Nuclear retention of all ICP0 transcripts is dramatically enhanced by viral DNA replication but is independent of ICP27. HeLa cells were mock infected or infected with HSV-1 strain KOS1.1 or d27-1 in the absence or presence of PAA. At 6 or 12 h postinfection, nuclear (N) or cytoplasmic (C) RNA fractions were prepared. RNA from an equal number of cells was analyzed by Northern blotting for the presence of ICP0 transcripts using the ICP0 exon/intron probe (A), TK transcripts (B), or the U3 snoRNA (C). M, RNA size markers in kilobases.

The membrane shown in Fig. 7A was then stripped and reprobed for TK sequences (Fig. 7B). In KOS1.1-infected cells, TK RNAwas distributed approximately equally between the nucleus andcytoplasm at all time points (lanes 3, 4, 7, 8, 11, 12, 15, and16). However, in the d27-1 infection, the RNA was preferentiallycytoplasmic (lanes 5, 6, 9, 10, 13, 14, 17, and 18), an effectthat was especially pronounced when viral DNA replication wasdisabled by PAA. In addition, the amount of TK RNA was substantiallyreduced in d27-1 infections. One explanation of these resultsis that the previously described cellular export pathway for theTK transcript is saturated in cells infected with the wild-typevirus. However, these data raise the possibility that ICP27 mayparticipate in regulating the nuclear/cytoplasmic distributionof TKtranscripts.

Taken together, the data presented above demonstrate that in HSV-infected HeLa cells, $alpha$ -globin transcripts are exported tothe cytoplasm irrespective of the presence or absence of an intron,while conversely both spliced and unspliced ICP0 RNAs are preferentiallyrecovered in the nuclear fraction. Moreover, retention of splicedICP0 mRNA does not requireICP27.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Effects of ICP27 mutations on accumulation of unspliced $alpha$ -globin and ICP0 pre-mRNA. We have used a panel of HSV-1 recombinants bearing altered versions of the ICP27 gene to examine which regions of ICP27 areimportant for the accumulation of unspliced transcripts of twointron-bearing genes, $alpha$ -globin and ICP0. Our results revealeda striking correlation between the ability of the various mutantforms of ICP27 to support virus replication on noncomplementingcells and accumulation of unspliced $alpha$ -globin RNA (compare Fig.1 and 2). Mutations that inactivate or delete the NES, the N-terminalacidic region, the NLS, the RGG box, and the conserved C-terminalhalf of the protein all eliminated pre-mRNA accumulation. Thisfinding argues that all of these regions, which are essentialfor ICP27 function, participate in the accumulation of $alpha$ -globinpre-mRNA. Surprisingly, accumulation of $alpha$ -globin pre-mRNA didnot correlate with the previously described transrepression functionof ICP27, that is, its ability to inhibit expression of intron-bearingreporter genes in cotransfection assays. Several mutants thatare fully competent for repressing reporter genes (Fig. 1) neverthelessfail to accumulate detectable levels of unspliced $alpha$ -globin pre-mRNA.Previous studies utilizing a more limited set of ICP27 mutationssuggested that accumulation of unspliced RNA and transrepressionare operationally equivalent consequences of a global inhibitionof splicing by ICP27 (18, 52). Our data provide new and significantinformation, by demonstrating that these effects can be separatedby mutation. One possible explanation to reconcile these observationsis the following. Although the repression function of wild-typeICP27 appears to be intron dependent (52), it has not been determinedif this is also the case for the repression-competent ICP27 mutantsthat have been analyzed in our study. Indeed, Sandri-Goldin andMendoza have reported intron-independent inhibition of reportergene expression by an ICP27 mutant, S23, that is defective ingene activation (52). This mutant, as well as several othermutants in the activation domain, is transdominant to the wild-typeprotein, reducing late gene expression and viral yields duringcoinfection with wild-type virus (54). This suggests the mutantprotein is dysfunctional rather than nonfunctional, interferingwith normal RNA processing possibly by the formation of inactiveheterodimers with wild-type ICP27 or by competing with the wild-typeprotein for substrates or interacting proteins. Repression-competentdysfunctional proteins such as S23 may thus cause decreased geneexpression by mechanisms that are quite distinct from those usedby the native ICP27 protein. In this context, it is interestingthat several of the ICP27 mutants that are repression competent(n406R, M11, M15, and M16) display the poly(A) tail extensioneffect, a phenotype not exhibited by the wild-type virus or bythe ICP27-null virus (discussed further below). It is possiblethat this aberrant polyadenylation could lead to reduced expressionof certain reporter genes (i.e., repression). Further studiesare required to test thishypothesis.

Does ICP27 induce accumulation of $alpha$ -globin pre-mRNA simply by interfering with RNA splicing? If the accumulation of unsplicedRNA were due solely to a decrease in the efficiency of splicing,then one would expect KOS1.1 to induce lower levels of splicedmRNA than d27-1, accompanied by a concomitant increase in theamounts of unspliced RNA. However, we have consistently observedapproximately equal band intensities for the fully spliced mRNAin KOS1.1 and d27-1 infections, and indeed KOS1.1 often showsslightly higher levels of the spliced product than d27-1 (Fig.2; see also reference 5). Recent studies of the Epstein-Barrvirus homolog of ICP27, EB2, have produced similar observations(3): EB2 promotes cytoplasmic accumulation of unspliced transcriptsof at least one intron-bearing reporter construct without reducingthe levels of fully spliced mRNA. To account for these data, wehave suggested that ICP27 acts to rescue a subset of $alpha$ -globinpre-mRNAs that would normally be degraded, rather than inhibitingsplicing per se (5). We speculated that ICP27 accomplishesthis by dissociating transcripts from nonproductive interactionswith the spliceosome, thereby preventing their degradation andpromoting their polyadenylation and nuclear export (5) (seebelow). We further hypothesized that these activities are keyto ICP27's ability to promote splicing-independent export of HSVL mRNAs (5). It is interesting that HIV Rev appears to actin a similar fashion to promote nuclear export of unspliced HIVmRNAs (40). If ICP27 indeed functions in this or a similar manner,then it seems likely that multiple properties of the protein (forexample, RNA binding, interactions with the spliceosome, interactionswith the polyadenylation machinery, nuclear export of RNA cargo,and reimportation of ICP27 into the nucleus) would be required.Inactivating any one of these functions could prevent accumulationof unspliced $alpha$ -globin RNA. Considered in this light, it is notsurprising that the integrity of most of the protein is requiredfor thiseffect.

We obtained a substantially more complex picture when we examined the effects of the various mutant forms of ICP27 on accumulationof transcripts that retain ICP0 intron 1. The complexity stemsin large part from the rather surprising multiplicity of intron-bearingtranscripts that were observed. Multiple ICP0 transcripts bearingthe intron 1 sequence have not been reported previously, and althoughit is possible that they are HeLa cell specific, it is more probablethat the Northern blot analysis gives a more precise view of thenumber and sizes of transcripts than do RNase protection or insitu hybridization experiments. Although ICP27 was required foraccumulation of all these RNAs early in infection, only one (transcriptc) appears to represent unspliced ICP0 pre-mRNA initiated at theICP0 promoter and processed at the ICP0 poly(A) site. The remainderof the RNAs (transcripts d to f) initiate somewhere upstream ofthe ICP0 promoter, and we have yet to map their 3' ends. Thus,although accumulation of these RNAs requires ICP27, it is notyet clear that this effect is due to inhibition of splicing orrescue of the intron-containing transcript from the spliceosome.It is possible that another function of ICP27 could result inaccumulation of these RNAs. For example, some or all of theseRNAs might initiate at the promoter of the upstream ICP34.5 gene(or another upstream promoter) and read through upstream poly(A)sites in an ICP27-dependent manner into ICP0 sequences. In keepingwith this notion, ICP27 has clearly documented effects on regulatinggene expression by modulating the choice between alternative poly(A)sites (15, 27-29). In a particularly relevant example, most transcriptsof the UL24 gene ordinarily read through the UL24 poly(A) siteand are instead processed at the poly(A) site of the downstreamUL26 gene; however, when ICP27 is inactivated, virtually all ofthe UL24 transcripts utilize the promoter-proximal UL24 poly(A)site (15). An analogous mechanism might explain the ICP27-dependentaccumulation of transcripts d to f. Other possibilities are thattranscripts d to f arise from an upstream promoter that is activatedby ICP27, or that ICP27 mediates some form of alternative splicing.Thus, some or all of ICP0 transcripts d to f may arise as a consequenceof functions of ICP27 that are not equivalent to transcript rescueor inhibition of constitutivesplicing.

As was the case for $alpha$ -globin, the only ICP27 mutants that exhibited a wild-type phenotype with respect to the accumulationof ICP0 intron-bearing RNAs were d5-6 and d6-7, which are notgrowth impaired in Vero cells. However, in marked contrast tothe findings with $alpha$ -globin, several of the growth-defective mutants(n406R, n504R, M11, and M16) also accumulated ICP0 intron-containingRNAs. It is interesting and probably significant that these mutantsaccumulated only those intron-bearing transcripts that initiateupstream of the ICP0 promoter and failed to display transcriptc, which is likely the precursor of ICP0 mRNA. A possible explanationfor this finding is based on the notion, described above, thatthe intron-bearing transcripts d to f arise through another functionof ICP27. Perhaps only transcript c accumulates via the transcriptrescue function proposed above for $alpha$ -globin pre-mRNA. Supportingthis hypothesis, only this transcript displayed the same mutationalsensitivity spectrum as $alpha$ -globin pre-mRNA. If this interpretationis correct, then the implication is that the transcript rescuefunction likely operates to some degree on the ICP0 precursorRNA as well as $alpha$ -globin. However, as noted in Results, accumulationand transport of transcript c are very inefficient compared tothe response of $alpha$ -globin pre-mRNA. One interpretation is thatICP27 acts through specific cis-acting sequence elements and thatthose present in ICP0 RNA fail to mediate an efficient response(discussed further below). This is in keeping with the findingthat ICP27 did not detectably bind ICP0 spliced or unspliced RNAin the nucleus or cytoplasm as measured by in vivo UV cross-linkingof HSV-1-infected cells (49).

Poly(A) tail extension by certain mutant forms of ICP27. The observation that certain mutant forms of ICP27 cause a significant change in the heterogeneity in length of the $alpha$ -globinmRNA poly(A) tail was surprising and points to a previously unappreciatedattribute of ICP27. It has long been recognized that ICP27 increasesthe efficiency of poly(A) site selection at weak poly(A) sites(27-29). This enhancement of 3' processing has been correlatedwith the transactivation function of ICP27, i.e., its abilityto stimulate reporter genes in cotransfection assays, and seemsto participate in stimulating late gene expression (52). Toour knowledge, however, this is the first report of effects ofICP27 on the length of the poly(A) tail. The fact that these effectsare not observed in wild-type or ICP27-null infections suggeststhat the phenotype is manifest as a consequence of expressingan altered protein that interferes with a normal pathway. Manymutants of this kind are dominant to the function of the wild-typeprotein; in fact, Smith et al. have identified several activation-defectiveICP27 mutants that exhibit transdominance to the wild-type protein(54). Preliminary data indicate that n406R, which displays themost striking poly(A) extension phenotype, may be partially dominantnegative (K. S. Ellison, S. A. Rice, and J. R. Smiley, unpublisheddata). The poly(A) tail length of mammalian mRNAs is normallylimited to approximately 250 nt, by a mechanism that involvesthe switching of poly(A) polymerase (PAP) from a processive modeof polymerization to a distributive mode (62; see reference64 for a recent review). This switch is regulated by interactionsbetween PAP, the RNA molecule, the cleavage and polyadenylationspecificity factor, and poly(A) binding protein II. The poly(A)chain is elongated processively only when PAP is stimulated byboth the cleavage and polyadenylation specificity factor and poly(A)binding protein II bound to short poly(A) tails: disruption ofthese interactions ensues at a chain length of ~250 nt by a mechanismthat is as yet unclear (62). Our findings imply that this lengthcontrol mechanism is fundamentally subverted by the presence ofsome mutated versions of ICP27. One possibility is that PAP retainsits processivity throughout the course of the reaction, perhapsthrough direct interactions with the altered form ofICP27.

It is interesting that four of the five mutant forms of ICP27 that display the poly(A) tail extension effect (excluding d1-2[47]) have been previously shown to be defective in ICP27'sactivation function, and that the activation function has beencorrelated with enhanced usage of some, but not all, poly(A) sites.We have so far failed to detect a convincing effect of the n406Rmutation on the length of the poly(A) tails of HSV ICP0 and TKmRNAs, although the data are not yet definitive (K. S. Ellison,R. Verity, and J. R. Smiley, unpublished data). It will thereforebe interesting to determine which, if any, additional viral andcellular RNAs display this effect and to learn whether all ofthese are substrates for ICP27-induced nuclearexport.

Subcellular localization of $alpha$ -globin and ICP0 transcripts. We have previously suggested that there are two modes for nuclear export of $alpha$ -globin transcripts in HSV-infected cells: asplicing-dependent pathway for the spliced mRNA (presumably thesame as that utilized for transport of transcripts derived frommost intron-bearing cellular genes), and an alternative, splicing-independentpathway that requires ICP27 for the egress of unspliced pre-mRNA(5). This hypothesis was based on the observations that (i)ICP27 induces the cytoplasmic accumulation of unspliced $alpha$ -globinRNA, while efficient export of the spliced mRNA is ICP27 independent,and (ii) ICP27 does not detectably alter the levels or rate ofproduction of fully spliced mRNA (5). Here we demonstrate thatcytoplasmic accumulation of spliced and unspliced $alpha$ -globin transcriptsoccurs throughout the course of infection and in the presenceor absence of viral DNAreplication.

The ICP27-dependent accumulation of unspliced transcripts of two intron-containing HSV genes, ICP0 and UL15, has been attributedto splicing inhibition by ICP27 (18, 39, 49), and one studyhas suggested that ICP27 causes the retention of these unsplicedtranscripts in the nucleus (39). We observed both unspliced(intron-bearing) and spliced ICP0 transcripts in the cytoplasm,as has been previously reported (18, 49), but the bulk ofthe ICP0 transcripts were retained in the nucleus, an effect thatwas significantly enhanced when viral DNA replication was allowedto proceed. However, the spliced mRNA was retained as well asthe intron-bearing RNAs (Fig. 7A). Furthermore, the nuclear/cytoplasmicdistribution of the spliced ICP0 mRNA was not substantially alteredin the absence of ICP27 (Fig. 7A), particularly when one takesinto account the fact that DNA replication is impaired duringinfection with d27-1. Thus, although we confirm that ICP0 transcriptsdisplay enhanced nuclear retention relative to $alpha$ -globin, thiswas not caused by the presence of introns in the retained RNAor by expression of ICP27. In keeping with our results, Clementsand colleagues found by in situ hybridization that ICP0 transcriptswere predominantly nuclear, using an exon-specific probe thatwould not distinguish between mRNA and pre-mRNA, and suggestedthat nuclear retention was conferred by ICP0 exon sequences (39).The indirect negative effects of deleting ICP27 on DNA replicationwere not taken into account in this and other earlier studies,however, which may account for the discrepancies in our interpretationsregarding the requirement forICP27.

Taken in combination, the data presented in this report suggest that ICP27 has different effects on ICP0 and $alpha$ -globin transcriptswith respect to both nuclear export and pre-mRNA accumulation.Unspliced $alpha$ -globin RNA accumulates to relatively high levels andis transported very efficiently, while ICP0 transcript c accumulatesinefficiently and remains largely nuclear. We have previouslynoted that the proposed transcript rescue function of ICP27 isakin to the mechanism of action of the HIV Rev protein. Rev enhancesthe intranuclear stability of unspliced and partially splicedHIV transcripts and promotes their nuclear export by binding toa specific cis-acting sequence, the Rev response element (seerecent reviews in references 10, 40, and 57). Several naturallyintronless genes require cis-acting sequences for splicing independentnuclear export (21, 23, 25). These considerations lead usto speculate that ICP27-dependent nuclear export of RNAs relieson the presence of specific cis-acting RNA sequences. Accordingto this model, RNA molecules containing one or more optimal ICP27response elements would be rescued and transported more efficiently( $alpha$ -globin and some viral L RNAs) than those with weak or nonconsensuselements (ICP0 RNA). If such is the case, we may be able to identifythe putative transport element by its ability to confer ICP27responsiveness on a nonresponsive gene. It is interesting thatthe TK transcript, which has been shown to possess multiple cis-actingtransport elements that bind the cellular hnRNP L protein (25),exhibits some ICP27-dependent nuclear retention (Fig. 7B). Thiscould reflect competition by ICP27 for a factor that is commonto both exportpathways.

While this paper was under review, Soliman and Silverstein published a study indicating that nucleocytoplasmic shuttling ofICP27 is prevented when viral DNA replication is blocked by PAAor mutations in components of the viral DNA replication machinery(56). At first glance, this observation seems to conflict withour proposal that ICP27 mediates cytoplasmic accumulation of unspliced $alpha$ -globin RNA through its shuttling activity (because this globinpre-mRNA accumulates in the cytoplasm in the absence of viralDNA replication). However, Soliman et al. previously reportedthat ICP27 requires an RNA cofactor to shuttle (55) and suggestedthat ICP27 must bind to HSV L RNAs in order to efficiently moveinto the cytoplasm (55, 56). According to this view, DNA replicationstimulates shuttling indirectly, by allowing accumulation of therequisite L mRNAs. If this model is correct, then it seems likelythat ICP27 would be capable of shuttling in the absence of viralDNA replication, provided that a suitable RNA cargo (such as $alpha$ -globinRNA) was available. In this context, it should be noted that othershave observed shuttling of ICP27 in the absence of viral L RNAs(32, 49), and ICP27 shuttles in interspecies heterokaryonassays under conditions that almost certainly preclude viral DNAreplication (32).

Interrelationship between splicing, polyadenylation, RNA nuclear export, and ICP27. As more of the biochemical details of mRNA synthesis, processing, and transport become elucidated, it is becoming increasinglyevident that the various steps in these processes (transcription,5' capping, splicing, polyadenylation, and nuclear export) arenot independent but rather are tightly interwoven and functionallyinterconnected (see reviews in references 57 and 64). Mountingevidence suggests that splicing greatly stimulates polyadenylationand vice versa, and that polyadenylation in turn is required fornuclear export (64). It seems likely that ICP27 is intimatelyinvolved with many of these processes. Our finding that certainmutant forms of ICP27 apparently alter some of these pathwayssuggests that these mutants may be invaluable tools for probingboth the mechanisms of ICP27 action in HSV gene regulation andthe basic operation of the cellular RNA processing and transportmachinery.

	ACKNOWLEDGMENTS

We thank Rob Maranchuk and Holly Saffran for excellent technicalassistance.

This research was supported by an Establishment Grant from the Alberta Heritage Foundation for Medical Research (AHFMR) toJ.R.S. and a grant from the National Institutes of Health (AI42737)to S.A.R. J.R.S. was a Terry Fox Senior Scientist of the NCI(C).S.A.R. was an AHFMR SeniorScholar.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Medical Microbiology & Immunology, 1-41 Medical Sciences Bldg., Universityof Alberta, Edmonton, Alberta, Canada T6G 2H7. Phone: (403) 492-2308.Fax: (403) 492-7521. E-mail: jim.smiley{at}ualberta.ca.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Brown, C. R., M. S. Nakamura, J. D. Mosca, G. S. Hayward, S. E. Straus, and L. P. Perera. 1995. Herpes simplex virus trans-regulatory protein ICP27 stabilizes and binds to 3' ends of labile mRNA. J. Virol. 69:7187-7195[Abstract].
2.	Buchman, A. R., and P. Berg. 1988. Comparison of intron-dependent and intron-independent gene expression. Mol. Cell. Biol. 8:4395-4405[Abstract/Free Full Text].
3.	Buisson, M., F. Hans, I. Kusters, N. Duran, and A. Sergeant. 1999. The C-terminal region but not the Arg-X-Pro repeat of Epstein-Barr virus protein EB2 is required for its effect on RNA splicing and transport. J. Virol. 73:4090-4100[Abstract/Free Full Text].
4.	Carter, K. L., and B. Roizman. 1996. Alternatively spliced mRNAs predicted to yield frame-shift proteins and stable intron 1 RNAs of the herpes simplex virus 1 regulatory gene alpha 0 accumulate in the cytoplasm of infected cells. Proc. Natl. Acad. Sci. USA 93:12535-12540[Abstract/Free Full Text].
5.	Cheung, P., K. S. Ellison, R. Verity, and J. R. Smiley. 2000. Herpes simplex virus ICP27 induces cytoplasmic accumulation of unspliced polyadenylated alpha-globin pre-mRNA in infected HeLa cells. J. Virol. 74:2913-2919[Abstract/Free Full Text].
6.	Cheung, P., B. Panning, and J. R. Smiley. 1997. Herpes simplex virus immediate-early proteins ICP0 and ICP4 activate the endogenous human $alpha$ -globin gene in nonerythroid cells. J. Virol. 71:1748-1793.
7.	Chiou, H. C., C. Dabrowski, and J. C. Alwine. 1991. Simian virus 40 late mRNA leader sequences involved in augmenting mRNA accumulation via multiple mechanisms, including increased polyadenylation efficiency. J. Virol. 65:6677-6685[Abstract/Free Full Text].
8.	Cooke, C., and J. C. Alwine. 1996. The cap and the 3' splice site similarly affect polyadenylation efficiency. Mol. Cell. Biol. 16:2579-2584[Abstract].
9.	Cooke, C., H. Hans, and J. C. Alwine. 1999. Utilization of splicing elements and polyadenylation signal elements in the coupling of polyadenylation and last-intron removal. Mol. Cell. Biol. 19:4971-4979[Abstract/Free Full Text].
10.	Cullen, B. R. 1998. Retroviruses as model systems for the study of nuclear RNA export pathways. Virology 249:203-210[CrossRef][Medline].
11.	Elgadi, M. M., and J. R. Smiley. 1999. Picornavirus internal ribosome entry site elements target RNA cleavage events induced by the herpes simplex virus virion host shutoff protein. J. Virol. 73:9222-9231[Abstract/Free Full Text].
12.	Everett, R. D. 1986. The products of herpes simplex virus type 1 (HSV-1) immediate early genes 1, 2, and 3 can activate HSV-1 gene expression in trans. J. Gen. Virol. 67:2507-2513[Abstract/Free Full Text].
13.	Everett, R. D. 1987. The regulation of transcription of viral and cellular genes by herpesvirus immediate-early gene products. Anticancer Res. 7:589-604[Medline].
14.	Hamer, D. H., and P. Leder. 1979. Splicing and the formation of stable RNA. Cell 18:1299-1302[CrossRef][Medline].
15.	Hann, L. E., W. J. Cook, S. L. Uprichard, D. M. Knipe, and D. M. Coen. 1998. The role of herpes simplex virus ICP27 in the regulation of UL24 gene expression by differential polyadenylation. J. Virol. 72:7709-7714[Abstract/Free Full Text].
16.	Hardwicke, M. A., and R. M. Sandri-Goldin. 1994. The herpes simplex virus regulatory protein ICP27 contributes to the decrease in cellular mRNA levels during infection. J. Virol. 68:4797-4810[Abstract/Free Full Text].
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Processing of -Globin and ICP0 mRNA in Cells Infected with Herpes Simplex Virus Type 1 ICP27 Mutants

Processing of $alpha$ -Globin and ICP0 mRNA in Cells Infected with Herpes Simplex Virus Type 1 ICP27 Mutants