E4orf6 Variants with Separate Abilities To Augment Adenovirus Replication and Direct Nuclear Localization of the E1B 55-Kilodalton Protein

doi:10.1128/JVI.76.3.1475-1487.2002

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Journal of Virology, February 2002, p. 1475-1487, Vol. 76, No. 3
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.76.3.1475-1487.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

E4orf6 Variants with Separate Abilities To Augment Adenovirus Replication and Direct Nuclear Localization of the E1B 55-Kilodalton Protein

Joseph S. Orlando^, and David A. Ornelles^*

Department of Microbiology and Immunology, School of Medicine, Wake Forest University, Winston-Salem, North Carolina 27157-1064

Received 5 April 2001/ Accepted 31 October 2001

ABSTRACT

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

The E4orf6 protein of group C adenovirus is an oncoprotein that,in association with the E1B 55-kDa protein and by E1B-independentmeans, promotes virus replication. An arginine-faced amphipathic ${alpha}$ -helix in the E4orf6 protein is required for the E4orf6 proteinto direct nuclear localization of the E1B 55-kDa protein andto enhance replication of an E4 deletion virus. In this study,E4orf6 protein variants containing arginine substitutions inthe amphipathic ${alpha}$ -helix were analyzed. Two of the six arginineresidues within the ${alpha}$ -helix, arginine-241 and arginine-243, werecritical for directing nuclear localization of the E1B 55-kDaprotein. The four remaining arginine residues appear to providea net positive charge for the E4orf6 protein to direct nuclearlocalization of the E1B 55-kDa protein. The molecular determinantsof the arginine-faced amphipathic ${alpha}$ -helix that were requiredfor the functional interaction between the E4orf6 and E1B 55-kDaproteins seen in the transfected cell differed from those requiredto support a productive infection. Several E4orf6 protein variantswith arginine-to-glutamic acid substitutions that failed todirect nuclear localization of the E1B 55-kDa protein restoredreplication of an E4 deletion virus. Additionally, a variantcontaining an arginine-to-alanine substitution at position 243that directed nuclear localization of the E1B 55-kDa proteinfailed to enhance virus replication. These results indicatethat the ability of the E4orf6 protein to relocalize the E1B55-kDa protein to the nucleus can be separated from the abilityof the E4orf6 protein to support a productive infection.

INTRODUCTION

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Open reading frame 6 of early region 4 (E4orf6) of group C adenovirus(Ad) encodes a multifunctional protein that enhances viral replication(reviewed in reference 34) and acts as an oncoprotein (38, 40,42). Ad mutants that lack the entire E4 region are severelydefective for viral DNA replication and late viral protein synthesis(11, 26, 28). However, expression of the E4orf6 protein in translargely corrects the growth defect of an E4 deletion virus (2,31). The E4orf6 protein promotes the biogenesis and cytoplasmicaccumulation of late viral mRNA, enhances stability of lateviral RNA in the nucleus, and, as part of a complex with theE1B 55-kDa protein, promotes the nucleocytoplasmic transportof processed late viral mRNA to the exclusion of many host mRNAs(reviewed in reference 17).

It has been proposed that the E4orf6-E1B 55-kDa protein complexbinds a component of the host nucleocytoplasmic transport systemto achieve the selective transport of late viral mRNA (46).The E4orf6 protein, in cooperation with the E1A and E1B proteinsof Ad, promotes the oncogenic transformation of baby rat kidney(BRK) cells (40, 42). The E4orf6-mediated transformation ofBRK cells may stem from the ability of the E4orf6 protein tobind and inactivate tumor suppressor proteins such as p53 (16,41) and p73 (27, 52), to bind and inactivate the cyclin A protein(25), or to increase the accumulation of mutations in the hostcell genome (38, 43).

Several structural elements of the E4orf6 protein required forits function have been identified. A protein fragment containingthe amino-terminal 58 amino acids of the E4orf6 protein bindsboth the E1B 55-kDa protein and the tumor suppressor p53 proteinin vitro (16, 48). Additionally, it has been reported that theE4orf6 protein contains a cryptic leucine-rich nuclear exportsignal (15) needed for E4orf6-mediated degradation of p53 (41).However, the role of this cryptic nuclear export signal in lategene expression remains controversial (10, 18, 47, 54). AlthoughE4orf6 proteins lacking the amino terminus or the cryptic nuclearexport signal can cooperate with the E1A and E1B proteins totransform BRK cells, these cells are not as tumorogenic in nudemice as BRK cells transformed with the E1A and E1B proteinsand the wild-type E4orf6 protein (41). E4orf6 variants withsubstitutions among several conserved cysteine and histidineresidues fail to promote late viral gene expression, no longercoimmunoprecipitate with the E1B 55-kDa protein, fail to directnuclear localization of the E1B 55-kDa protein, fail to destabilizethe p53 protein, transform BRK cells with reduced efficiency,and produce transformed cells with diminished oncogenic potentialin nude mice (9, 41). Boyer and Ketner have suggested that theseconserved cysteine and histidine residues coordinate with twoor more zinc ions to establish the proper tertiary structureof the E4orf6 protein (9).

A theoretical model for the structure of the E4orf6 proteinwas derived by Flint and associates (13). This model suggeststhe existence of a binuclear zinc coordination structure, asproposed by Boyer and Ketner (9). The molecular model of Flintand associates is also consistent with the existence of an arginine-facedamphipathic ${alpha}$ -helix at the carboxy terminus of the E4orf6 protein.This structure appears to be required for many of the functionsof the E4orf6 protein. E4orf6 variants that lack this structureor contain proline substitutions within the ${alpha}$ -helix fail to promotevirus replication (45). These E4orf6 variants also fail to directthe E1B 55-kDa protein to the cell nucleus after transfection.

The integrity of the arginine-faced amphipathic ${alpha}$ -helix is requiredfor E4orf6-mediated p53 degradation (41). An intact arginine-facedamphipathic ${alpha}$ -helix is also required for the full oncogenic potentialof the E4orf6 protein, as measured by the ability to transformBRK cells and to elicit an abnormal state of growth termed hypertransformation(41). Although these oncogenic functions may depend, in part,on the E1B 55-kDa protein, it is possible that the arginine-facedamphipathic ${alpha}$ -helix of the E4orf6 protein binds to and altersthe activity of cellular factors that control cell growth. Forexample, a motif within the amphipathic ${alpha}$ -helix was suggestedto mediate binding to cyclin A and augment expression of a transgenepresent on a recombinant adeno-associated virus (rAAV) (25).Because DNA-damaging agents promote transgene expression inrAAV-infected cells (1), it seems possible that the E4orf6 proteinmay promote rAAV transgene expression by disrupting the integrityof cellular DNA or perturbing signaling pathways associatedwith DNA damage (8, 43, 44).

Here we examine the molecular features of the arginine-facedamphipathic ${alpha}$ -helix of the E4orf6 protein that are required tosupport a productive viral infection and to retain the rapidlyshuttling E1B 55-kDa protein (18, 32) in the nucleus, whichwe interpret as a functional interaction between these two proteins.The hydrophilic face of this ${alpha}$ -helix contains six arginine residues.Replacement of these arginine residues with similarly chargedlysine residues had little impact on the ability to direct nuclearlocalization of the E1B 55-kDa protein. Two arginine residues,at positions 241 and 243, were found to be critical for a functionalE4orf6-E1B 55-kDa protein interaction in cells. These residueslie on opposite sides of the ${alpha}$ -helix. The other four arginineresidues establish a positive charge in the central region ofthe ${alpha}$ -helix. A net positive charge in this region appears tobe required for the E4orf6 protein to direct nuclear localizationof the E1B 55-kDa protein.

Strikingly, the features of the arginine-faced amphipathic ${alpha}$ -helixrequired for the functional interaction with the E1B 55-kDaprotein in cells differ from those required for E4orf6 proteinfunction during a productive Ad infection. Some E4orf6 variantsthat failed to retain the E1B 55-kDa protein in the nucleusprovided wild-type function during productive Ad infection.However, an E4orf6 variant that successfully directed nuclearlocalization of the E1B 55-kDa protein expressed either by transfectionor from the viral chromosome failed to supply E4orf6 proteinfunction during Ad infection. These results indicate that theability of the E4orf6 protein to relocalize the E1B 55-kDa proteinto the nucleus can be separated from the ability of the E4orf6protein to support a productive infection. The separation ofthese functions in the mutant proteins described here may reflecta diverse number of interactions that are mediated by the arginine-facedamphipathic ${alpha}$ -helix of the E4orf6 protein for the many activitiesof this protein.

MATERIALS AND METHODS

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Cell culture and viruses. Cell culture media, cell culture supplements, and serum wereobtained from Invitrogen/Life Technologies (Gaithersburg, Md.)through the Tissue Culture Core Laboratory of the ComprehensiveCancer Center of Wake Forest University. HeLa and W162 cells(55) were maintained in Dulbecco’s modified Eagle’smedium supplemented with 10% newborn calf serum as previouslydescribed (21).

Two strains of adherent HeLa cells were used in this work. The"fast-growing" strain of HeLa cells (CCL2.2) was obtained fromthe American Type Culture Collection in the late 1980s. Thisstrain exhibits the typical morphology and growth rate (doublingtime, ${approx}$ 20 h) of HeLa cells. Another strain of HeLa cells whichhad been propagated in the laboratory of T. Shenk is identifiedas a "slow-growing" strain of HeLa cells. The doubling timeof this strain is approximately 36 h. This slow-growing strainof HeLa cells reaches confluence at a lower cell density thanthe fast-growing strain of HeLa cells, consistent with greaterspread and a less cuboid morphology.

Ad type 5 (Ad5) strain dl309 served as the wild-type Ad5 usedin these studies. dl309 lacks a portion of the E3 region whichhas been shown to be dispensable for growth in culture (29).The E4 deletion virus dl1014 was constructed by Bridge and Ketnerand described previously (12). This virus is able to expressonly the orf4 protein from the E4 region. The wild-type virus,dl309, was propagated in 293 cells (24). and dl1014 was propagatedin W162 cells (55). Virus stocks were prepared by sequentialcentrifugation through CsCl as described previously (21).

The recombinant vaccinia virus used to express the T7 RNA polymerase,vTF7.3, was created by Fuerst et al. (20). Expression of theE1B 55-kDa and E4orf6 genes from the T7 promoter was achievedas described previously (23). Briefly, 10⁵ cells were infectedwith vTF7.3 in reduced-serum medium and transfected with 1 µgof plasmid DNA mixed with 3 µg of Fugene 6 per the manufacturer’s(Roche, Nutley, N.J.) recommendation. Cells were analyzed byimmunofluorescence between 12 and 14 h after infection and transfection.The localizations of the E4orf6 and E1B 55-kDa proteins wereidentical to those observed in cells expressing these proteinsfrom the major immediate-early promoter and enhancer of cytomegalovirusin noninfected cells.

For confocal laser scanning microscopy, HeLa cells were grownon glass cover slips, infected with dl309 (29) or dl1014 (12),and simultaneously transfected with plasmids expressing theE4orf6 variants under control of the cytomegalovirus immediate-earlypromoter. For these experiments, 10⁵ cells were exposed to 1µg of plasmid DNA, 3 µg of Fugene 6, and 10⁶ PFUof Ad in a 2-ml volume of OptiMEM (Invitrogen/Life Technologies).After 6 h at 37°C, the virus and plasmid mixture was replacedwith normal growth medium, and the cells were processed 14 hafter infection.

Plasmids and site-directed mutagenesis. The plasmids carrying the E4orf6 and E1B 55-kDa protein geneswere described previously (23, 45). Most E4orf6 variants werecreated by site-directed mutagenesis using PCR (7, 49). Briefly,arginine codons were changed by performing PCR with a 5' oligonucleotideprimer containing the altered E4orf6 sequences and a 3' primercorresponding to sequences beyond the 3' end of the E4orf6 codingregion. The resulting PCR product of approximately 150 bp wasused with another oligonucleotide corresponding to sequencesbeyond the 5' end of the E4orf6 coding region to perform a secondPCR synthesis. The resulting 1-kbp fragment containing the intendedmutation was subcloned into pGEM11z (Promega, Madison, Wis.)by standard means.

The R4K and R_{241,243,244,248}A E4orf6 variants were created byusing the R₂₄₁P V₂₅₀S variant described previously (45). Restrictiondigestion of R₂₄₁P V₂₅₀S cDNA with NruI and StuI removes a blunt-ended,30-bp DNA fragment encoding amino acids 241 through 250 of theE4orf6 protein. A 30-base oligonucleotide encoding the desiredchanges and its complement were annealed and ligated into thedigested R₂₄₁P V₂₅₀S cDNA to introduce the desired changes.The mutations in the E4orf6 gene were verified by restrictionanalysis and confirmed by automated DNA sequencing of approximately600 to 800 bp of the construct through the DNA Sequencing andGene Analysis Core Laboratory of Wake Forest University. A listof the mutagenic oligonucleotides with the diagnostic restrictionsites used in this study will be provided upon request. Forexpression from an intrinsically active promoter, certain E4orf6variant cDNAs were subcloned into the pCMV Neo-BamHI vector(3) by standard means.

Indirect immunofluorescence. Indirect immunofluorescence and photomicroscopy of whole cellswere conducted as previously described (46). Double-label immunofluorescencewas performed with the mouse monoclonal antibody MAb3 (37),which is specific for the amino terminus of the E4orf6 protein,and rat monoclonal antibody 9C10 (Oncogene Science, Uniondale,N.Y.) (56), which is specific for the Ad5 E1B 55-kDa protein.The secondary antibodies used were multiple-label-qualifiedgoat antibodies conjugated to fluorescein and Rhodamine Red-X(Jackson ImmunoResearch, West Grove, Pa.) or Alexa Fluor 488(Molecular Probes, Eugene, Oreg.).

Samples were examined with a Leitz Dialux 20 EB microscope fittedfor epifluorescent illumination and photographed using TMaxfilm developed to an exposure index of 1600 ASA (Eastman Kodak,Rochester, N.Y.). Some samples were analyzed by a Zeiss LSM510 confocal laser scanning device fitted to an Axioplan 2 microscope.Alexa Fluor 488 and Rhodamine Red-X dyes were excited by kryptonion and helium-neon laser excitation, respectively. Single opticalsections of approximately 1.5-µm depth at the level ofthe cytoplasm were recorded as TIFF files using the LSM 510software.

For the quantitative measurements shown in Fig. 5, a "double-blind"approach was used to quantify the degree of nuclear localizationof the E1B 55-kDa protein. Appropriate mixtures of plasmidswere prepared in randomly encoded tubes. A second investigatorperformed the infection or transfection using randomly labeledcultures of cells. The presence of both E4orf6 and E1B 55-kDaproteins was verified by double-label immunofluorescence asdescribed above, and the localization of the E1B 55-kDa proteinwas scored as either cytoplasmic or nuclear as described inthe text associated with Fig. 5. At least 100 cells were scoredfor each independent transfection.

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FIG. 5. E4orf6 variants bearing arginine replacement mutations within the amphipathic ${alpha}$ -helix retain the E1B 55-kDa protein (55K) in the nucleus less effectively than the wild-type E4orf6 protein. Expression of the E4orf6-related proteins and the E1B 55-kDa protein was established as described in the legend to Fig. 2 but in a double-blind fashion as described in Materials and Methods. Expression of the E4orf6 protein variant (indicated on the left) was established, and the localization of the E1B 55-kDa protein was determined. Approximately 100 cells expressing each E4orf6 variant and the E1B 55-kDa protein were evaluated in each of four independent transfections. The localization of the E1B 55-kDa protein was scored as nuclear or cytoplasmic as indicated in the legend to Fig. 4. Each bar represents the average fraction of cells containing predominantly nuclear E1B 55-kDa protein. The brackets above each bar indicate the minimum and maximum values measured among four experiments. The solid black bar represents the value measured for the wild-type E4orf6 protein, the solid white bar represents the R4K variant, the gray bars represent arginine-to-alanine replacement variants, and the hatched bars represent arginine-to-glutamic acid variants.

Protein expression. Replicate cultures of infected and transfected cells were collected,suspended in urea sample buffer (7.5 M urea, 50 mM Tris [pH6.8], 1% sodium dodecyl sulfate [SDS], 50 mM dithiothreitol,5% ß-mercaptoethanol, 0.05% bromophenol blue), sonicated,and heated for 10 min at 65°C. The proteins were separatedby sodium dodecyl sulfate-polyacrylamide gel electrophoresis(SDS-PAGE) and electrophoretically transferred to nitrocellulose,and the E4orf6-related proteins and the E1B 55-kDa protein werevisualized by immunoblotting with MAb3 (37) and 2A6 (50), respectively,a secondary antibody conjugated to horseradish peroxidase (JacksonImmunoResearch), and chemiluminescence detection (Pierce, Rockford,Ill.).

Sequence analysis and molecular modeling. Sequence analysis and secondary structure prediction were performedwith the suite of programs available as the Wisconsin Packageversion 10.1 (Genetics Computer Group, Madison, Wis.) Molecularmodels of the amphipathic ${alpha}$ -helix were created and analyzed withthe Sybyl suite of programs (Tripos Associates, Inc., St. Louis,Mo.). The Composer module was used to assemble peptide modelscorresponding to residues 239 through 255 of the E4orf6 proteinand related variants. The amino and carboxy termini of the modelwere blocked with neutral blocking groups, and all hydrogenatoms and unpaired electrons were added. Atomic charges wereassigned from the Amber 95 model provided by Tripos Associates,Inc., and the ${alpha}$ -carbons were constrained to the spacing of astandard ${alpha}$ -helix.

Electrostatic effects were introduced with a dielectric constantthat varied with interatomic distance, and the model was energeticallyminimized by a reiterative process until the energy change perstep was less than 0.02 kcal/mol. The Dynamics module was usedto identify energetically reasonable configurations for theamino acid side chains by simulating exposure to 300 K for 8ps. The initial velocities of the atoms in the model were randomizedbetween repeated simulations to sample the variety of allowableconfigurations. This repeated analysis with different initialconditions confirmed that the simulation parameters allowedall nonconstrained atoms to reach dynamic equilibrium. The resultingstructures were again minimized before using the MOLCAD moduleto project the electrostatic potential onto the solvent-accessiblesurface of the peptide models.

Complementation analysis. HeLa cells were infected with dl309 (29) or dl1014 (12) andsimultaneously transfected with the E4orf6 variant cDNA constructsanalyzed in Fig. 7. For these experiments, 4 x 10⁵ cells ina 65-mm culture dish were exposed to 1 µg of plasmid DNA,3 µg of Fugene 6, and 4 x 10⁶ PFU of virus in a 2-ml volumeof OptiMEM (Invitrogen/Life Technologies). After 6 h at 37°C,the virus and plasmid mixture was replaced with normal growthmedium. Detailed methods for Ad plaque assays have been describedelsewhere (30). In brief, virus was harvested from the infectedand transfected HeLa cells by multiple cycles of freezing andthawing. The cell lysates were clarified by centrifugation andserially diluted for infection of W162 cells (55) grown in six-welltissue culture dishes for plaque assays. Typically, valid datawere collected from three dilutions in each series of dilutions.The virus yield was determined by linear regression and expressedas the number of plaques per milliliter of initial lysate.

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FIG. 7. E4orf6 variants retain the E1B 55-kDa protein (55K) in the nucleus of Ad-infected cells with efficiency similar to that observed in noninfected, transfected cells. HeLa cells were infected with the E4 deletion virus dl1014 at 10 PFU per cell and simultaneously transfected with cDNAs expressing the E4orf6-related constructs indicated on the left. The cells were processed for immunofluorescence after 14 h. Representative confocal laser scanning images of approximately 1.5-µm depth were recorded at a plane of focus that includes the cytoplasm. Staining for the E4orf6 protein is seen in the left column ( ${alpha}$ E4orf6), and staining for the E1B 55-kDa protein is in the center column ( ${alpha}$ E1B-55K). The merged image (right column) shows the superposition of both signals as yellow.

Computer-aided graphics. Film used to record chemiluminescence and immunofluorescencemicrographs was scanned at 300 and 600 dpi, respectively, toproduce a digitized image. Digital images were cropped usingPhotoshop 5.5 (Adobe Systems, Inc., San Jose, Calif.) and assembledwith Canvas 5.1 and 7.0 (Deneba, Miami, Fla.) operating on aMacintosh microcomputer. Images produced by the Sybyl suiteof programs were generated as 16-bit RGB files, transportedto a Macintosh microcomputer as 8-bit RGB files, assigned anew color mapping scheme with Photoshop 5.5, and saved as 8-bitCMYK images.

RESULTS

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Arginine residues in the amphipathic ${alpha}$ -helix between positions 239 and 251 form a positively charged surface-exposed domain. Using circular dichroism spectroscopy, we previously demonstratedthat a peptide corresponding to amino acids 239 through 255of the 294-residue E4orf6 protein can exist as an arginine-facedamphipathic ${alpha}$ -helix (45). Variants of the E4orf6 protein thatlack residues 241 through 250 or contain a proline in this regionwere defective. These mutant proteins failed to retain the E1B55-kDa protein in the nucleus when expressed by transfectionin noninfected cells, and these mutant proteins failed to promotereplication of an E4 deletion virus when expressed by transfectionin Ad-infected cells. These studies suggested that an intact ${alpha}$ -helix in the E4orf6 protein, centered about residue 245, isrequired for a functional interaction between the E4orf6 andE1B 55-kDa proteins in the cell.

To aid in identifying features of this region that underliethe functional interaction between the E4orf6 and E1B 55-kDaproteins, we generated a molecular model of the ${alpha}$ -helix. Thespace-filling model in Fig. 1 illustrates the 4.7 turns of the ${alpha}$ -helix and a potential arrangement of residues 239 through 255of the E4orf6 protein. In this model, the peptide backbone wasconstrained to a standard ${alpha}$ -helix and the side chains were allowedto adopt an energetically favored configuration using moleculardynamics as described in Materials and Methods.

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FIG. 1. Representation of the arginine-faced amphipathic ${alpha}$ -helix. Amino acids 239 through 255 of the E4orf6 protein were modeled as an ${alpha}$ -helix. Side chains were allowed to adopt an energetically reasonable configuration using molecular dynamics as described in Materials and Methods. The identity of each atom is indicated by color: nitrogen, blue; carbon, gray; oxygen, red; sulfur, yellow. Hydrogen atoms are not shown. Atoms in the peptide backbone are rendered in a muted color. The charged residues that are visible are labeled near the side chain. (A) View down the helix axis from N terminus to C terminus. (B) View of the hydrophilic face.

The amphipathic nature of this structure is evident when vieweddown the helix axis (Fig. 1A). Arginine-241 and arginine-243occur at the extreme sides of the hydrophilic face. The onlynonaliphatic residues in the hydrophobic backbone of the ${alpha}$ -helixare threonine-242 and methionine-246. A likely distributionof the charged residues can be seen in the view of the ${alpha}$ -helixshown in Fig. 1B. Arginine-240, arginine-244, and arginine-248align on the hydrophilic face over three turns of the ${alpha}$ -helix(Fig. 1B). In repeated modeling efforts, arginine-251 establisheda bond with the glutamic acid residue at position 255. The theoreticalstructure proposed for the E4orf6 protein by Brown et al. (13)suggests that the protein adopts an ${alpha}$ -helical configuration beyondalanine-249. Thus, the pair of electronegative glutamic acidresidues at positions 255 and 256 may interact with the guanidiniumgroup of arginine-251.

It seems that the remaining five arginines are free to adopta wide variety of configurations. This property would be consistentwith their position on the solvent-exposed face of this amphipathic ${alpha}$ -helix and would permit a significant degree of flexibilityin binding diverse ligands. These arginine residues may forma loosely structured, positively charged region on the surfaceof the E4orf6 protein.

To determine whether the identity of these six arginine residuesor the basic nature of these residues is critical for E4orf6-E1B55-kDa protein interaction, an E4orf6 variant, R4K, bearingfour lysine substitutions, was created and tested for a functionalinteraction with the E1B 55-kDa protein (Fig. 2A). The R4K andwild-type E4orf6 proteins were expressed with the E1B 55-kDaprotein in HeLa cells using the vaccinia virus/T7 RNA polymeraseinfection-transfection expression system, and the localizationof the proteins was determined. As reported previously, theE4orf6 protein is diffusely distributed throughout the nucleusand is excluded from the nucleoli (23, 45). Although the E1B55-kDa protein shuttles between the cytoplasm and nucleus (18,32), when expressed alone, this protein is found primarily inthe cytoplasm (Fig. 2B, second row). However, the subcellularlocalization of the E1B 55-kDa protein is changed when expressedwith the E4orf6 protein (23, 45). The E4orf6 protein retainsthe E1B 55-kDa protein in the cell nucleus. In most cells expressingboth of these adenoviral proteins (Fig. 2B, third row), stainingfor the E1B 55-kDa protein appeared coincident with stainingfor the E4orf6 protein.

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FIG. 2. E4orf6 variant bearing arginine-to-lysine substitutions within the amphipathic ${alpha}$ -helix retains the E1B 55-kDa protein (55K) in the nucleus after transfection. (A) The amino acid sequence of the amphipathic ${alpha}$ -helix (residues 239 to 255) and a variant with lysine substitutions at positions 241, 243, 244, and 248. (B) HeLa cells were infected with the recombinant vaccinia virus vTF7.3 to establish expression of the T7 RNA polymerase and then transfected with cDNAs under control of the T7 promoter to express the E4orf6-related protein and the E1B 55-kDa protein. The transfected E4orf6 cDNAs are identified on the left. Ad proteins were visualized by double-label immunofluorescence 12 h after transfection. Representative cells are shown. E4orf6 proteins were visualized with the mouse monoclonal antibody MAb3 (37) (left column, ${alpha}$ E4orf6), E1B 55-kDa protein was visualized with the rat monoclonal antibody 9C10 (56) (center column, ${alpha}$ E1B-55K), and DNA was visualized with 4',6'-diamidino-2-phenylindole (DAPI) (right column, DNA). (C) In parallel with the samples prepared for immunofluorescence, expression of the E4orf6 and E1B 55-kDa proteins was established by transfection of the cDNAs in vTF7.3-infected cells indicated above each lane. Total cell protein was isolated 12 h after transfection, separated by SDS-PAGE, and trans-ferred to a solid support. The E4orf6-related proteins and the E1B 55-kDa protein were visualized by immunoblotting with MAb3 and 2A6 (50), respectively. Only the portion of the membranes containing the E4orf6-related proteins and the E1B 55-kDa proteins is shown.

Like the E4orf6 protein, the R4K variant was found in the nucleusand retained a portion of the E1B 55-kDa protein in the nucleusof cells expressing both proteins. In contrast to the wild-typeE4orf6 protein, the R4K protein appeared to be less efficientat retaining the E1B 55-kDa protein in the nucleus. In the exampleshown (Fig. 2B, fourth row), more cytoplasmic staining is evidentfor E1B 55-kDa protein in the presence of the R4K protein thanin the presence of the wild-type E4orf6 protein (Fig. 2B, thirdrow). Although the R4K protein retained at least a portion ofthe E1B 55-kDa protein in the nucleus of every cell examined,approximately 40% of these cells contained brighter stainingfor the E1B 55-kDa protein in the cytoplasm than in the nucleus.By contrast, a variant bearing alanine replacements at arginine-241,arginine-243, arginine-244, and arginine-248 failed to retainthe E1B 55-kDa protein in the nucleus of cells expressing bothproteins. Nonetheless, since expression of the R4K protein inducednuclear localization of at least a portion of the E1B 55-kDaprotein in each cell and expression of the R_{241,243,244,248}Avariant did not, we conclude that the basic charge of the arginineresidues within the amphipathic ${alpha}$ -helix contributes to the functionalinteraction between the E4orf6 and E1B 55-kDa proteins seenin transfected cells.

The diminished ability of the R4K variant to retain the E1B55-kDa protein in the nucleus is not due to reduced levels ofthe R4K protein. The steady-state level of the E4orf6, R4K,and E1B 55-kDa proteins in HeLa cells was determined by immunoblot.The amount of E4orf6 protein measured in cells expressing theE4orf6 protein alone or with the E1B 55-kDa protein was similarto the amount of R4K protein (Fig. 2C). Neither the E4orf6 proteinnor the R4K variant affected the steady-state level of the E1B55-kDa protein. An equivalent amount of E1B 55-kDa protein wasdetected in lysates derived from cells expressing the E1B 55-kDaprotein alone, the E1B 55-kDa and E4orf6 proteins, or the R4Kand E1B 55-kDa proteins.

Basic nature of arginines 241 and 243 is required for the E4orf6 protein to direct nuclear localization of the E1B 55-kDa protein. A collection of single arginine-to-glutamic acid substitutionvariants were created and tested for the ability to retain theE1B 55-kDa protein in the nucleus. Representative results arepresented in Fig. 3A. In most cells expressing both the E1B55-kDa protein and either the R₂₄₀E, R₂₄₄E, R₂₄₈E, or R₂₅₁Eprotein, a significant portion of the E1B 55-kDa protein wasdetected in the nucleus. However, variants of the E4orf6 proteinwith arginine-to-glutamic acid amino acid replacements at residues241 or 243 failed to retain the E1B 55-kDa protein in the nucleus.Fewer than 1% of transfected cells expressing the E1B 55-kDaand either the R₂₄₁E or R₂₄₃E mutant protein contained the E1B55-kDa protein in the nucleus. Furthermore, in this minorityof cells, the E1B 55-kDa protein was uniformly distributed throughoutthe cell, reinforcing the defective nature of these mutant E4orf6proteins.

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FIG. 3. E4orf6 variants with arginine-to-glutamic acid replacement substitutions at position 241 or 243 do not retain the E1B 55-kDa protein (55K) in the nucleus after transfection. (A) Expression of the E4orf6-related proteins (indicated on the left) and the E1B 55-kDa protein was established, and the localization of the Ad proteins was determined as described in the legend to Fig. 2. Representative images of a single cell from each transfection are presented, with the E4orf6 protein shown in the left column ( ${alpha}$ E4orf6), E1B 55-kDa protein in the center column ( ${alpha}$ E1B-55K), and DNA visualized with DAPI in the right column (DNA). (B) In parallel with the samples prepared for immunofluorescence, expression of the E4orf6 and E1B 55-kDa proteins was established by transfection of the cDNAs indicated above each lane, and the E4orf6-related proteins and the E1B 55-kDa protein were visualized by immunoblotting as described in the legend to Fig. 2.

However, like the R4K variant, the glutamic acid substitutionvariants were not as efficient as the wild-type E4orf6 proteinat retaining the E1B 55-kDa protein in the nucleus. The E1B55-kDa protein was predominantly nuclear in approximately 55%of the cells expressing both the E1B 55-kDa and R₂₄₀E proteins.In cells expressing either the R₂₄₄E, R₂₄₈E, or R₂₅₁E variantand the E1B 55-kDa protein, approximately 85% of the cells containedpredominantly nuclear E1B 55-kDa protein.

The diminished ability of the R₂₄₀E, R₂₄₄E, R₂₄₈E, and R₂₅₁Evariants to retain the E1B 55-kDa protein in the nucleus andthe loss of this ability in the R₂₄₁E and R₂₄₃E variants cannotbe attributed to a gross change in localization or to reducedlevels of the variant E4orf6 proteins. The distribution of eachof these E4orf6 variants in the vaccinia virus-infected cellwas indistinguishable from that of the wild-type E4orf6 protein(compare E4orf6 protein localization in Fig. 2B with that inFig. 3A). However, as noted previously (45), individual cellswith high levels of E4orf6 protein contained some cytoplasmicstaining for the E4orf6 protein. Immunoblot analysis revealedthat these E4orf6-related proteins were expressed to similarlevels (Fig. 3B). Furthermore, expression of these variantsdid not affect the level of E1B 55-kDa protein (Fig. 3B). Thus,the interaction of the E4orf6 and E1B 55-kDa proteins measuredby this colocalization assay is ablated by the R₂₄₁E and R₂₄₃Emutations, reduced by the R₂₄₀E mutation, and only slightlyaffected by the R₂₄₄E, R₂₄₈E, and R₂₅₁E mutations.

All of the E4orf6 variants created in this study directed nuclearlocalization of the E1B 55-kDa protein with varying efficiency.The series of micrographs in Fig. 4 illustrate the various degreesto which the R₂₄₀E mutant protein retained the E1B 55-kDa proteinin the nucleus. More than half of the cells expressing bothE1B 55-kDa and R₂₄₀E proteins showed predominantly nuclear stainingfor the E1B 55-kDa protein (Fig. 4A and 4B). In slightly lessthan half of the cells, the E1B 55-kDa protein appeared to beuniformly distributed (Fig. 4C) or predominantly restrictedto the cytoplasm (Fig. 4D and E). The variable efficiency withwhich the E4orf6 protein variants directed nuclear localizationof the E1B 55-kDa protein formed the basis for the quantitativeassay described below.

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FIG. 4. Extent of E1B 55-kDa nuclear localization in cells expressing the R₂₄₀E protein varies from cell to cell. Expression of the R₂₄₀E E4orf6 variant and the E1B 55-kDa protein was established and the localization of the E1B 55-kDa protein was determined as described in the legend to Fig. 2. The localization represented in A and B was seen in 55% of the cells and scored as nuclear (Nuc). The uniform distribution represented in C was seen in only 2% of the cells; the predominantly cytoplasmic localization seen in D and E was seen in 43% of the cells. Both the uniform and cytoplasmic distributions were scored as cytoplasmic (Cyt).

To determine whether the acquisition of a negative charge orthe loss of a positive charge at the position normally occupiedby arginine disrupted the E4orf6-E1B 55-kDa protein interaction,single arginine-to-alanine variants were tested for their abilityto retain the E1B 55-kDa protein in the nucleus. The abilityof these as well as all other mutant E4orf6 proteins to retainthe E1B 55-kDa protein in the nucleus was quantified by a double-blindapproach. Cells expressing both the E4orf6 variant and the E1B55-kDa protein were evaluated for the relative staining intensityof the E1B 55-kDa protein in the nucleus and in the cytoplasm.Cells that contained stronger staining in the nucleus relativeto the cytoplasm were scored as having a predominantly nuclearE1B 55-kDa protein. Each value plotted in Fig. 5 representsthe average of four independent transfection-infections fromtwo independent experiments. The ranges associated with eachpoint indicate the minimum and maximum value of the four measurements.

The R₂₄₀A variant retained the E1B 55-kDa protein in the nucleusof approximately 90% of cells expressing both proteins. Thisvalue was significantly greater than the 55% average measuredfor the related R₂₄₀E variant. Moreover, the lowest percentageof cells containing nuclear E1B 55-kDa protein in the presenceof the R₂₄₀A variant (88%) exceeded the maximum value measuredin the presence of the R₂₄₀E variant (62%). Therefore, it seemslikely that the acquisition of a negative charge at position240 in the R₂₄₀E variant rather than the loss of a positivecharge at this position in the R₂₄₀A variant reduced the strengthof interaction with the E1B 55-kDa protein.

Because E4orf6 variants that contained glutamic acid in position244, 248, or 251 behaved like the wild-type protein with respectto retaining the E1B 55-kDa protein in the nucleus, we expectedthe corresponding arginine-to-alanine variants to also functionlike the wild-type protein. This was indeed observed. Cellsexpressing the E1B 55-kDa protein and either the R₂₄₄A, R₂₄₈A,or R₂₅₁A mutant protein contained predominantly nuclear E1B55-kDa protein in 90 to 98% of the cells. By contrast, the R₂₄₁Aand R₂₄₃A variants relocalized the E1B 55-kDa protein to thenucleus in 73 and 62% of the cells, respectively (Fig. 5). Thisintermediate value, although greater than that measured forthe corresponding glutamic acid variants, is consistent withthe notion that a positive charge at positions 241 and 243 isimportant for this function of the E4orf6 protein.

Further evidence in support of this idea can be derived fromthe ostensibly weaker interaction of the R₂₄₁A and R₂₄₃A proteinswith the E1B 55-kDa protein seen in the slow-growing strainof HeLa cells. In this strain of HeLa cells, the R₂₄₁A and R₂₄₃Amutant proteins directed nuclear localization of the E1B 55-kDaprotein in fewer than 20% of the cells, whereas the other alaninesubstitution mutant proteins did so to the same extent as inthe fast-growing HeLa cell variant (data not shown).

The failure of the R₂₄₁E and R₂₄₃E variants and the diminishedability of the R₂₄₁A and R₂₄₃A variants to retain the E1B 55-kDaprotein in the nucleus shows a requirement for a positivelycharged amino acid at positions 241 and 243 for this propertyof the E4orf6 protein. Since the R₂₄₁A and R₂₄₃A variants canretain at least a portion of the total E1B 55-kDa protein inthe nucleus, it is possible that a neighboring arginine residuemay partially compensate for the loss of arginine-241 or arginine-243.Therefore, double arginine-to-alanine variants were createdand tested for their ability to retain the E1B 55-kDa proteinin the nucleus. An E4orf6 variant bearing arginine-to-alaninesubstitutions at positions 240 and 241 did not relocalize anyE1B 55-kDa protein to the nucleus. Similarly, the R_243,244Avariant was completely defective in its ability to retain theE1B 55-kDa protein in the nucleus. By contrast, two variantsthat preserved arginine-241 and arginine-243, R_240,251A andR_248,251A, retained the E1B 55-kDa protein in the nucleus of70 and 82% of cells expressing both proteins, respectively.The properties of these double alanine substitution variantsprovide further support for the importance of residues 241 and243 for the functional interaction between the E1B 55-kDa andE4orf6 proteins observed in cells.

Net positive charge among residues 240, 244, 248, and 251 is required for the E4orf6 protein to direct nuclear localization of the E1B 55-kDa protein. Under physiological conditions, the arginine residues of theamphipathic ${alpha}$ -helix can form a positively charged surface. Arginine-241and arginine-243 lie on opposite sides of the solvent-exposedface of this ${alpha}$ -helix and are important for the functional interactionof the E4orf6 and E1B 55-kDa proteins observed in cells. Arginine-240,-244, -248, and -251 can form a colinear arrangement over nearlythree turns of the ${alpha}$ -helical segment to present a positivelycharged surface.

Variant E4orf6 proteins with multiple replacements of thesefour amino acids with either glutamic acid or alanine were testedfor their ability to retain the E1B 55-kDa protein in the nucleusof cells transiently expressing both proteins. As discussedpreviously, E4orf6 variants containing two arginine-to-alaninereplacement mutations (R_240,251A and R_248,251A) retained a portionof the E1B 55-kDa protein in the nucleus. By contrast, substitutingglutamic acid for arginine at these positions (R_240,251E andR_248,251E) ablated the E4orf6-E1B 55-kDa protein interaction(Fig. 5). These double glutamic acid replacement variants appearedcompletely defective in their ability to retain the E1B 55-kDaprotein in the nucleus. The distribution of the E1B 55-kDa proteinin cells expressing any of the double arginine-to-glutamic acidE4orf6 variants resembled that observed in cells expressingthe E1B 55-kDa protein alone.

Unlike the double arginine-to-alanine variants, the double arginine-to-glutamicacid variants have a net neutral charge among these four centralresidues. Therefore, to test the possibility that the functionalE4orf6-E1B 55-kDa protein interaction in transfected cells requiresa net positive charge among these amino acids, cDNAs were createdto express E4orf6 proteins containing triple or quadruple arginine-to-alaninereplacement mutations. When coexpressed with the E1B 55-kDaprotein, the R_240,244,251A protein directed the E1B 55-kDa proteinto the nucleus in 60% of the cells. Similar results were observedin cells expressing the R_240,248,251A variant and the E1B 55-kDaprotein. By contrast, the quadruple mutant protein, R_{240,244,248,251}A,failed to retain the E1B 55-kDa protein in the nucleus (Fig.5). The localization of the E1B 55-kDa protein in these cellsresembled that observed in cells expressing the E1B 55-kDa proteinalone (Fig. 2). The quadruple alanine substitution variant R_{240,244,248,251}Aand the double glutamic acid substitution variants R_240,251Eand R_248,251E have a net neutral charge among the four centralresidues. These results lead us to suggest that a positive surfaceon the hydrophilic face of the amphipathic ${alpha}$ -helix is requiredfor E4orf6-E1B 55-kDa protein interaction in transfected cells.

The overall charge of the amphipathic ${alpha}$ -helix appeared to beimportant for the ability of the E4orf6 protein to retain theE1B 55-kDa protein in the cell nucleus. However, variants witha similar net charge differed in their ability to retain theE1B 55-kDa protein in the nucleus. To reveal a possible basisfor these differences, molecular models of the amphipathic ${alpha}$ -helixof the various E4orf6 mutant proteins were created, and thetheoretical charge density of these models was determined (Fig.6). The portion of the E4orf6 protein that was modeled was thesame as that shown in Fig. 1 and included alanine-239 throughglutamic acid-255.

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FIG. 6. Ability to retain the E1B 55-kDa protein in the nucleus is correlated with a more electropositive surface at the amino terminus of the amphipathic ${alpha}$ -helix. Amino acids 239 through 255 of E4orf6 protein variants were modeled as an ${alpha}$ -helix as described in the legend to Fig. 1. The solvent-accessible surface of the model peptide was calculated, and the electropositive potential of the molecule was projected onto this surface. Electropositive regions are mapped to deep blue and electronegative regions are mapped to red, as indicated by the scale (kilocalories per mole electron) on the right. The orientation of the ${alpha}$ -helical peptides is the same as in Fig. 1B, where the amino terminus is at the top and the hydrophilic face is exposed. The models and associated value for nuclear E1B 55-kDa protein retention (from Fig. 5) are (A) wild-type E4orf6 protein, 100%; (B) R₂₅₁A, 99%; (C) R₂₄₄E, 91%; (D) R_248,251A, 80%; (E) R₂₄₁A, 72%; (F) R_240,244,251A, 62%; and (G) R₂₄₁E, 0.8%.

The orientation of the ${alpha}$ -helices modeled in Fig. 6 is the sameas that in Fig. 1B, where the amino terminus is at the top.These structures represent the solvent-accessible surface ofthe model peptide. The electropositive potential of the moleculewas projected onto this surface and is indicated by the scalebar in Fig. 6, where the most positive regions are mapped todeep blue and the most negative regions are mapped to red. Asexpected, the positive charge of the multiple arginine residuesin the wild-type structure (Fig. 6A) contributes to the overallpositive nature (blue) of the amino-terminal portion of the ${alpha}$ -helix. A possible interaction between arginine-251 and glutamicacid-255 diminishes the contribution of both residues to thepotential, and that portion of the model is predicted to benearly neutral (orange).

The structures in Fig. 6 are arranged in rank order with respectto the ability of the corresponding mutant E4orf6 protein toretain the E1B 55-kDa protein in the nucleus. This ability wasreported in Fig. 5 as the fraction of cells expressing bothproteins with predominantly nuclear E1B 55-kDa protein. Thesevalues are approximately 100, 99, 90, 80, 70, 60 and 1% forthe proteins represented by Fig. 6A through G, respectively.This analysis reveals that the positive charge of the amino-terminalportion of the amphipathic ${alpha}$ -helix is linked to the ability ofthe E4orf6 protein to retain the E1B 55-kDa protein in the nucleus.Although this pattern is not strictly observed, as can be seenby comparing Fig. 6C and D, this trend was noted for all 26of the structures described in this work (data not shown).

We also noted that the resulting electropositive surface ofthe molecular model was not readily predicted from the aminoacid changes. For example, although both R₂₄₄E and R₂₄₁E beara single arginine-to-glutamic acid substitution in the aminoterminus of the ${alpha}$ -helix, the predicted surface charge changedconsiderably more in the R₂₄₁E model (Fig. 6G) than in the R₂₄₄Emodel (Fig. 6C). Collectively, these results suggest that theidentity of the amino acids at positions 241 and 243 as wellas the overall electropositive nature of the amino terminusof the amphipathic ${alpha}$ -helix of the E4orf6 protein govern the functionalinteraction of the E4orf6 and E1B 55-kDa proteins, as definedby colocalization in the nucleus during transient expression.

E4orf6 variants exhibit a similar ability to retain the E1B 55-kDa protein in the nucleus of Ad-infected cells as in transfected cells. Representative E4orf6 protein variants were tested for theirability to retain the E1B 55-kDa protein in the nucleus duringan Ad infection. HeLa cells were infected with the E4 deletionvirus dl1014 and simultaneously transfected with the appropriateE4orf6 expression vector. When the E1B 55-kDa protein was expressedfrom the viral chromosome in the absence of any E4 productsother than orf4, the E1B 55-kDa protein was predominantly cytoplasmic.The limited amount of E1B 55-kDa protein found in the nucleusappeared to occur as irregularly shaped aggregates (Fig. 7,vector).

The E4orf6 variants that retained the E1B 55-kDa protein inthe nucleus of cells after transfection of both Ad genes alsoretained the E1B 55-kDa protein in the nucleus of dl1014-infectedcells. The wild-type and R₂₄₁A E4orf6 proteins were diffuselydistributed through the nucleus and excluded from the nucleoli.In addition, some cells showed an accumulation of E4orf6 andE1B 55-kDa proteins at what appeared to be viral replicationcenters (Fig. 7, R₂₄₁A) (46).

The E4orf6 variants that failed to retain the E1B 55-kDa proteinin the nucleus after transfection largely failed to retain theE1B 55-kDa protein in the Ad-infected cells. The examples shownin Fig. 7 (R₂₄₁E, R₂₄₃E, and R_240,251E) are representative ofcells with no more E1B 55-kDa protein in the nucleus than vector-transfectedcells. However, the extent to which the E1B 55-kDa protein remainedexcluded from the nucleus varied among cells within a sample,as was observed in cells expressing both proteins by transfection(see Fig. 4).

Curiously, whereas both the R₂₄₁E and R₂₄₃E proteins retainedthe E1B 55-kDa protein in the nucleus of fewer than 1% of thevaccinia virus-infected cells, approximately 10% of the dl1014-infectedcells expressing the R₂₄₁E or R₂₄₃E variant showed significantE1B 55-kDa nuclear localization (data not shown). In addition,the intranuclear distribution of the E4orf6 protein variantsthat failed to retain the E1B 55-kDa protein in the nucleusdiffered from that observed in non-Ad-infected cells. In theAd-infected cells, the glutamic acid substitution variants wereconcentrated towards the periphery of the nucleus and were notexcluded from nucleoli (Fig. 7, R₂₄₁E, R₂₄₃E, and R_240,251E).Nonetheless, each E4orf6 variant analyzed in Ad-infected cellsshowed a similar ability to direct E1B 55-kDa protein nuclearlocalization whether the E1B protein was expressed by transfectionor from the viral chromosome.

Ability of the E4orf6 protein to direct nuclear localization of the E1B 55-kDa protein is not strictly linked to its ability to promote virus replication. Several reports have suggested that physical and functionalinteraction of the E4orf6 and E1B 55-kDa proteins is importantfor late viral gene expression (9, 54) and intranuclear localizationof the E1B 55-kDa protein during a viral infection (46) andto correct the growth defect of an E4 deletion virus (45). Todetermine if the limited ability of the mutant E4orf6 proteinsto relocalize the E1B 55-kDa protein correlated with reducedfunction during Ad infection, 11 of the mutant E4orf6 proteinswere tested for their ability to correct the growth defect ofan E4 deletion virus, dl1014. Surprisingly, the results describedbelow demonstrate that the ability of the E4orf6 protein toretain the E1B 55-kDa protein in the nucleus is not strictlycorrelated with the ability of the protein to promote virusgrowth.

To measure the extent to which the mutant E4orf6 proteins correctthe growth of the E4 deletion virus, both the fast- and slow-growingstrain of HeLa cells were infected with dl1014 and simultaneouslytransfected with the appropriate E4orf6 cDNA expression construct.After 2 days, the cells and growth medium were collected, andthe amount of virus produced was quantified by plaque assay.The phenotypically wild-type virus dl309 replicated to levelsapproximately 300-fold (Fig. 8A) or 3,000-fold (Fig. 8B) abovethat of the E4 deletion virus dl1014. Expression of the wild-typeE4orf6 protein did not affect replication of the wild-type virus(Fig. 8).

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FIG. 8. Ability of the E4orf6 protein to retain the E1B 55-kDa protein in the nucleus is neither necessary nor sufficient to correct the growth defect of an E4 deletion virus. A fast-growing strain of HeLa cells (A) and a slow-growing strain of HeLa cells (B) were infected with an E4 deletion virus lacking all E4 open reading frames except orf4 (dl1014) or a phenotypically wild-type virus (dl309) at 10 PFU per cell and simultaneously transfected with cDNAs expressing the E4orf6-related constructs listed below each bar. The E4orf6-related proteins were expressed under the control of the major immediate-early promoter of cytomegalovirus. Progeny virus was harvested after 48 h and quantified by plaque assay. A representative experiment (of three) showing the average amount of virus obtained from two independent infections is shown. The range of virus recovered in the two independent infections is indicated by the brackets on the right.

As reported previously (45), cells infected with dl1014 andsimultaneously transfected with a wild-type E4orf6 expressionvector produced over 200-fold more virus than cells transfectedwith an empty vector or a vector expressing the defective L₂₄₅PE4orf6 mutant protein (Fig. 8 and data not shown). The transfectionefficiency was determined to be 18% ± 2% and 13% ±2% (average of six determinations ± standard deviation[SD]) for the cells analyzed in Fig. 8A and B, respectively.Therefore, the expected virus yield after transfection of aconstruct that fully restored E4 activity was 18 and 13% ofthe wild-type virus yield in the respective cell lines. Thedashed lines in Fig. 8 indicate these values. To within a factorof 3, transfection of the wild-type E4orf6 expression vectorrestored the growth of the mutant virus to these levels.

The virus yield from cells infected with dl1014 and transfectedwith plasmids encoding the glutamic acid substitution variantsR₂₄₁E, R₂₄₃E, R₂₄₄E, R₂₄₈E, and R_240,251E was nearly the same(2- to 3-fold reduced) as that of dl1014-infected cells transfectedwith the wild-type E4orf6 construct (Fig. 8), with one exception.The exception, the R₂₄₁E variant, nonetheless enhanced replicationof the E4 mutant virus by nearly 100-fold in the slow-growingHeLa cell strain (Fig. 8B). We note that the extent to whichthe R₂₄₈E variant supported dl1014 virus growth in this studyis in good agreement with the results of others (47, 54).

We expected the R₂₄₄E and R₂₄₈E variants to promote virus growthbecause these E4orf6 variants behaved like the wild-type proteinwith respect to altering E1B 55-kDa protein localization. However,three of the glutamic acid substitution variants, R₂₄₁E, R₂₄₃E,and R_240,251E, failed to retain the E1B 55-kDa protein in thenucleus, and their nearly wild-type function in this complementationassay was unexpected. Thus, it appears that ability to promotevirus growth can be dissociated from the property of directingE1B 55-kDa protein to the nucleus.

The alanine substitution variants R₂₅₁A, R_248,251A, and R_240,244,251Abehaved as expected, based on their ability to direct nuclearlocalization of the E1B 55-kDa protein. Each of these variantsretained the E1B 55-kDa protein in a majority of cells transientlyexpressing both proteins (Fig. 5), and each of these variantscorrected the growth defect of dl1014 nearly as well as thewild-type E4orf6 protein (Fig. 8).

However, the behavior of other alanine substitution variantsprovided further support for the idea that virus growth enhancementcan be dissociated from the property of E1B 55-kDa protein relocalization.The quadruple alanine substitution variant R_{240,244,248,251}Afailed to retain any E1B 55-kDa protein in the nucleus of over400 cells evaluated that transiently expressed both proteins(Fig. 5). This E4orf6 variant restored the growth of dl1014to 7 to 10% of the level associated with the wild-type E4orf6protein. These values represent as much as a 300-fold increaseover the yield of virus from infected cells transfected withthe empty vector (Fig. 8B). Therefore, this E4orf6 variant hasan intermediate ability to correct the growth defect of dl1014.

Cells infected with dl1014 and simultaneously transfected withthe R₂₄₁A expression construct produced approximately the sameamount of virus as dl1014-infected cells transfected with thewild-type E4orf6 construct. This was measured in both the fast-growingHeLa cell strain (Fig. 8A), in which the R₂₄₁A protein directednuclear retention of the E1B 55-kDa protein in 73% of the cells(Fig. 5), and the slow-growing HeLa cell strain (Fig. 8B), inwhich only 16% of transfected cells contained predominantlynuclear E1B 55-kDa protein (data not shown). Thus, for thesealanine substitution variants, the inability or reduced abilityto direct nuclear retention of the E1B 55-kDa protein aftertransfection was not reflected in the ability of this variantto correct the growth defect of an E4 deletion virus.

In contrast to the nearly wild-type function of the R₂₄₁A proteinduring a virus infection, the R₂₄₃A protein was defective withrespect to virus growth even though, by morphological criteria,the R₂₄₃A variant resembled the R₂₄₁A variant. The R₂₄₃A variantdirected nuclear retention of the E1B 55-kDa protein in 62%of the fast-growing HeLa cells (Fig. 5) and in 17% of the slow-growingHeLa cells (data not shown). However, both strains of HeLa cellsinfected with dl1014 and simultaneously transfected with theR₂₄₃A expression construct failed to produce significantly morevirus than dl1014-infected cells transfected with an empty plasmidvector (Fig. 8A and 8B). Thus, although preserving some abilityto retain the E1B 55-kDa protein in the nucleus after transfection,the R₂₄₃A protein appears to be unable to correct the growthdefect of an E4 deletion virus. Together, these results leadus to conclude that the ability to direct nuclear localizationof the E1B 55-kDa protein is neither sufficient nor necessaryto complement the growth of the E4 deletion virus, dl1014, underthe conditions of these assays.

Key features of the E4orf6 amphipathic ${alpha}$ -helix are conserved among adenoviruses. To determine if the critical features of the arginine-facedamphipathic ${alpha}$ -helix of the E4orf6 protein are conserved amongdifferent adenoviruses, we compared the predicted sequencesof five human Ad E4orf6 proteins and three nonhuman Ad E4 proteinsthat are similar to the human Ad E4orf6 protein. The secondary-structureprediction algorithm of Chou and Fasman (14) confirmed thateach protein could adopt an ${alpha}$ -helical conformation at the carboxyterminus. These proteins exhibited overall identity to the Ad2and Ad5 E4orf6 protein ranging from 62% (human Ad17) through24% (bovine Ad3). The fraction of identical amino acids in thepredicted ${alpha}$ -helix region (Ad2 and Ad5 residues 239 through 255)also varied in a similar manner, from 88% (human Ad17) to 6%(bovine Ad3).

Alignment of these sequences reveals that the critical featuresof the amphipathic ${alpha}$ -helix identified in this study may be conservedamong this group of adenoviruses. In the alignment shown inFig. 9, conserved arginine residues are shaded black. Basicamino acids found at the same position are shaded gray, anddivergent amino acids are not shaded. With the exception ofthe canine Ad3 protein, each of these E4orf6 homologues containsa positively charged amino acid at the position equivalent toarginine-241 and arginine-243. All of these proteins preservea net positive charge on the residues (240, 244, 248, and 251)that comprise the central face of the ${alpha}$ -helix. Thus, the keyfeatures of the arginine-faced amphipathic ${alpha}$ -helix required forE1B 55-kDa protein nuclear localization are conserved amongthese viruses. The conservation of a positively charged aminoacid at the position corresponding to arginine-243 may reflecta more general requirement for a charged amino acid at position243 for a productive Ad infection.

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FIG. 9. Key features of the amphipathic ${alpha}$ -helix are conserved among different adenoviruses. The predicted amino acid sequence of five human Ad E4orf6 proteins and three nonhuman Ad E4 proteins that are similar to the human Ad E4orf6 protein were aligned at the region corresponding to the amphipathic ${alpha}$ -helix. The arginine residues in the Ad2 and Ad5 proteins are identified at the top of the alignment. Arginines that occur at the same position in the other proteins are shaded black, basic amino acids in these positions are shaded gray, and divergent amino acids are not shaded.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We previously demonstrated that an arginine-faced amphipathic ${alpha}$ -helix centered at amino acid 245 is essential for the functionof the E4orf6 protein during a productive Ad5 infection (45).The integrity of this amphipathic ${alpha}$ -helix is also required forthe E4orf6 protein to retain the predominantly cytoplasmic E1B55-kDa protein in the nucleus of primate cells when both proteinsare expressed by transfection (23, 45). We interpret the changesin cellular localization of the E1B 55-kDa protein attributedto the E4orf6 protein to reflect a functional interaction betweenthese proteins in the cell. We and others have suggested thatthis functional interaction between the E4orf6 and E1B 55-kDaproteins may be correlated with the ability of E4orf6 proteinto correct the growth defect of an E4 deletion virus (9, 45,54). However, the properties of E4orf6 variants created in thisstudy lead us to conclude that the ability to retain the E1B55-kDa protein in the nucleus is neither necessary nor sufficientto correct the growth defect of an E4 deletion virus.

In this work, we found that arginine-241 and arginine-243 ofthe E4orf6 protein were critical for the E4orf6 protein to directnuclear localization of the E1B 55-kDa protein in transfectedcells (Fig. 4 and 5). The remaining four arginine residues ofthe ${alpha}$ -helix contribute a net positive charge that is needed topreserve the functional interaction of the E4orf6 and E1B 55-kDaproteins in cells. Notably, homologous proteins of other humanand nonhuman Ad serotypes also contain arginine or lysine residuesat positions corresponding to 241 and 243 and also maintaina net positive charge among the residues corresponding to theother four arginines (Fig. 9).

Surprisingly, these determinants may not be the same as thoserequired for E4orf6 protein function during productive Ad infection.Four E4orf6 variants that failed to relocalize the E1B 55-kDaprotein to the nucleus in transfected cells, R₂₄₁E, R₂₄₃E, R_240,251E,and, to a limited extent, R_{240,244,248,251}A, corrected the growthdefect of an E4 deletion virus that expressed only the orf4protein of E4 (Fig. 8). If redistribution of the E1B 55-kDaprotein to the nucleus reflects a functional interaction withthe E4orf6 protein, then these mutant E4orf6 proteins appearto be less dependent on an interaction with the E1B 55-kDa proteinto support a productive Ad infection. Additionally, anotherE4orf6 variant, R₂₄₃A, retained the E1B 55-kDa protein in thenucleus in transfected cells and during an Ad infection (datanot shown) but failed to correct the growth defect of the E4deletion virus. Thus, the ability to direct nuclear localizationof the E1B 55-kDa protein may not be sufficient for E4orf6 proteinfunction during a productive Ad infection.

The E4orf6 variants described here demonstrate that, for theE4orf6 protein, the ability to direct nuclear localization ofthe E1B 55-kDa protein can be separated from the ability tosupport a productive infection. Why might some of the mutantE4orf6 proteins support virus growth in the apparent absenceof a functional interaction with the E1B 55-kDa protein?

One possible explanation for the behavior reported here is thatthe E4orf6 protein variants were overexpressed under controlof the cytomegalovirus immediate-early promoter for the viruscomplementation experiments. Under these conditions, the amountof E4orf6 protein in each cell was 20- to 50-fold greater thanthat present during a normal Ad infection. Perhaps a partialdefect in the protein was masked at such nonphysiologicallyhigh concentrations. Indeed, when the E1B 55-kDa protein wasexpressed from the viral chromosome, some of the E4orf6 variantsthat failed to direct nuclear localization of the E1B 55-kDaprotein after transfection did so in a fraction of the Ad-infectedcells (Fig. 7 and data not shown).

Another possible explanation for the apparent separation ofE4orf6-E1B 55-kDa protein interaction and virus complementationamong the mutant E4orf6 proteins is that the mutant E4orf6 proteinsmay bind different cellular factors to perform various functions.It seems plausible that the R₂₄₃A variant could bind cellularfactors needed for E4orf6-E1B 55-kDa protein interaction incells, but not those factors required for a productive Ad infection.Conversely, it would have to be argued that the R₂₄₁E, R₂₄₃E,and R_240,251E variants bind cellular factors required for virusgrowth but not those required for interaction with the E1B 55-kDaprotein. Note that this hypothesis requires that the glutamicacid substitution E4orf6 variants have the ability to bind thecellular factors independently of the E1B 55-kDa protein. Perhaps,for example, the negative charge on the hydrophilic face ofthe glutamic acid replacement E4orf6 protein somehow mimickeda change brought about by association with the E1B 55-kDa protein.

A third possible explanation for the behavior of the R₂₄₁E,R₂₄₃E, and R_240,251E variants is that their function duringan Ad infection is less dependent on the E1B 55-kDa proteinthan the wild-type E4orf6 protein. Perhaps, for example, onerole for the E4orf6-E1B 55-kDa protein complex is to promoteproper folding and presentation of the C-terminal amphipathic ${alpha}$ -helix in the E4orf6 protein. Therefore, changes to the E4orf6protein that stabilize this amphipathic ${alpha}$ -helix without destroyingkey contacts for other interactions may diminish the need fora physical interaction with the E1B 55-kDa protein. We suggestthat this admittedly helix-centric view is not entirely withoutmerit. Indeed, the charge substitutions in R₂₄₁E, R₂₄₃E, andR_240,251E are predicted to enhance the intrinsic stability ofthe ${alpha}$ -helix through electrostatic interactions between oppositelycharged residues separated by three or four positions on the ${alpha}$ -helix (33, 39). Thus, if the ability of the E4orf6 amphipathic ${alpha}$ -helix to form properly is a limiting step for E4orf6 proteinfunction during Ad infection, the role of the E1B 55-kDa proteinin the E4orf6-E1B 55-kDa complex may be to establish or stabilizethe C-terminal amphipathic ${alpha}$ -helix in the E4orf6 protein.

This hypothesis may also provide an explanation for the cold-sensitivephenotype of E1B mutant viruses (see, for example, reference22). Proper formation of the amphipathic ${alpha}$ -helix in the E4orf6protein probably depends on hydrophobic interactions withinthe E4orf6 protein. If the proper configuration of the E4orf6protein is promoted by an interaction with the E1B 55-kDa protein,then this configuration might be cold-labile in the absenceof the E1B 55-kDa protein. At low temperatures, at which hydrophobicinteractions are weaker, the E4orf6 protein would fold ineffectively,and the yield of an E1B mutant virus would be reduced comparedto the yield at 37°C. Conversely, at higher temperatures,at which hydrophobic interactions are stronger, the E4orf6 proteinmay fold independently of the E1B 55-kDa protein, allowing theE1B mutant virus to replicate to nearly wild-type levels.

Recently, Shen and associates described variant E1B 55-kDa proteinsthat failed to bind the E4orf6 protein in a coimmunoprecipitationassay but still supported late viral gene expression and hostcell shutoff in Ad-infected A549 cells (51). This finding suggeststhat mutant E1B 55-kDa proteins exist that may support virusgrowth in the absence of a functional interaction with the E4orf6protein. Additionally, these investigators described one E1B55-kDa protein variant that bound the E4orf6 protein less effectivelythan the wild-type E1B 55-kDa protein. Intriguingly, the correspondingmutant virus displayed a cold-sensitive phenotype intermediatebetween that of the E1B 55-kDa protein-null virus and wild-typevirus (51).

Although clearly speculative, these hypotheses provide readilytested implications, the pursuit of which should increase ourunderstanding of the relationship between the E1B 55-kDa andE4orf6 proteins. One immediate goal is to determine the functionof these mutant E4orf6 proteins when they are expressed fromthe viral chromosome. Some of these mutant genes are being introducedinto both the wild-type Ad background and viruses bearing additionalmutations for this purpose.

Arginine-rich, amphipathic ${alpha}$ -helices have been implicated inprotein-protein interaction in at least three other proteins.First, the Nef protein of human immunodeficiency virus containsan amino-terminal arginine-rich amphipathic ${alpha}$ -helix that bindsto the Lck kinase and a serine kinase that phosphorylates bothNef and Lck (5). The interaction between the Nef amphipathic ${alpha}$ -helix and the two kinases appears to be necessary for maximumvirion infectivity. Second, the NS-1 protein of influenza Avirus is a dimeric, helix-rich protein that binds RNA (36).Helix 3 of NS-1 is an amphipathic ${alpha}$ -helix that appears to contributeto dimer formation (53). Third, the 14-3-3 proteins are ubiquitousproteins involved in a number of processes, including mitogenicsignal transduction, cell cycle progression, and oncogenesis(reviewed in references 4 and 19).

The 14-3-3 proteins bind a wide variety of protein ligands,including the cellular Raf-1 kinase and a bacterial ADP-ribosyltransferase.The three-dimensional crystal structure of the 14-3-3 ${zeta}$ -isoformshows that the ligand-binding surface, which is present in all14-3-3 proteins, is lined by amphipathic ${alpha}$ -helices rich in basicamino acids (35). Changes to the conserved basic residues onthe hydrophilic face selectively disrupted the interaction withsome ligands but not with others (57). Perhaps the E4orf6 proteincan also bind multiple and diverse ligands through similar interactionsvia the C-terminal arginine-faced amphipathic ${alpha}$ -helix.

In conclusion, we have elucidated some of the requirements ofthe arginine-faced amphipathic ${alpha}$ -helix of the E4orf6 proteinfor a functional interaction with the E1B 55-kDa protein andfor E4orf6 protein function during Ad infection. We suggestthat the requirements for these two properties are not identical.Perhaps one role for the arginine-faced amphipathic ${alpha}$ -helix ofthe E4orf6 protein is to mediate protein-protein interactionswith multiple cellular factors through different arginine residueson the hydrophilic face. Clearly, however, additional work isneeded to confirm the structure proposed by Flint and associates(13), to identify the cellular factors used by the E4orf6 proteinto promote virus growth (6), and to understand the relationshipbetween the E1B 55-kDa and E4orf6 proteins that contributesto the multiple activities of the E4orf6 oncoprotein.

ACKNOWLEDGMENTS

This work was supported by Public Health Service grants AI35589from the National Institute of Allergy and Infectious Diseasesand CA77342 from the National Cancer Institute. J.S.O. was supportedin part by NIH training grant T32 AI07401 to the Departmentof Microbiology and Immunology. Tissue culture reagents andservices were provided by the Tissue Culture Core Laboratory,and DNA sequencing was performed by the DNA Synthesis Core Laboratory,both of the Comprehensive Cancer Center of Wake Forest University,supported in part by NIH grant CA12197.

We gratefully acknowledge Al Claiborne, Mark Lively, Maria McGee,and Leslie Poole for help with molecular modeling and proteinstructure analysis and Ken Grant of the Micromed facility forassistance with confocal laser scanning microscopy. We thankSusan Sun and Jeff Childers for technical assistance and AmyChastain, Felicia Goodrum, Roy Hantgan, Doug Lyles, Griff Parks,and Robin Shepard for providing valuable advice on the workin progress and on manuscript preparation.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, Wake Forest University School of Medicine, Winston-Salem, NC 27157-1064. Phone: (336) 716-9332. Fax: (336) 716-9928. E-mail: ornelles{at}wfubmc.edu.

Present address: Departments of Medicine, Microbiology and MolecularGenetics, Harvard Medical School and Beth Israel Deaconess MedicalCenter, Boston, MA 02215.

REFERENCES

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

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