Cell architecture during adenovirus infection

Bromodeoxyuridine Labelling to Determine Viral DNA Localization in Fluorescence and Electron Microscopy: The Case of Adenovirus

The localization of viral nucleic acids in the cell is essential for understanding the infectious cycle. One of the strategies developed for this purpose is the use of nucleotide analogs such as bromodeoxyuridine (BrdU, analog to thymine) or bromouridine (BrU, analog of uridine), which are incorporated into the nucleic acids during replication or transcription. In adenovirus infections, BrdU has been used to localize newly synthesized viral genomes in the nucleus, where it is key to distinguish between host and viral DNA. Here, we describe our experience with methodological variations of BrdU labeling to localize adenovirus genomes in fluorescence and electron microscopy. We illustrate the need to define conditions in which most of the newly synthesized DNA corresponds to the virus and not the host, and the amount of BrdU provided is enough to incorporate to the new DNA molecules without hampering the cell metabolism. We hope that our discussion of problems encountered and solutions implemented will help other researches interested in viral genome localization in infected cells.

Upregulation of the Golgi protein GP73 by adenovirus infection requires the E1A CtBP interaction domain

GP73 is a novel type II Golgi transmembrane protein that is expressed at high levels in the hepatocytes of patients with viral hepatitis (R. D. Kladney, G. A. Bulla, L. Guo, A. L. Mason, A. E. Tollefson, D. J. Simon, Z. Koutoubi, and C. J. Fimmel, 2000, Gene 249, 53-65) and is induced in cultured cells by infection with viruses including adenoviruses. Its biological function and the mechanisms by which its expression may be regulated by viral infection are unknown. Here we report that GP73 is induced at the RNA and protein level in human Hep3B hepatoma cells infected by human Ad5 and Ad2. Hep3B cells were infected with wild-type or mutant adenoviruses. GP73 expression was measured by RNase protection assay, immunoblotting, or immunofluorescence microscopy. GP73 RNA and protein levels were strikingly induced following infection. The rise in GP73 expression coincided with the appearance of the adenovirus E1A and DBP proteins and preceded the expression of the fiber protein, a marker of the late phase of infection. Infection did not affect the expression of giantin, GPP130, or golgin-84, three integral Golgi membrane proteins with structural similarities to GP73. Mapping studies using a panel of mutant adenoviruses demonstrated that the E1A C-terminus, specifically its CtBP interaction domain (CID), is required for GP73 expression. Subsequently, Hep3B cells were transiently transfected with plasmids expressing wild-type or mutant E1A proteins. These studies confirmed that E1A induced GP73 expression via the CID. Our studies establish GP73 as a novel adenovirus-induced cellular protein whose expression is regulated through the CID of the E1A protein.

G-protein-coupled receptor activation induces the membrane translocation and activation of phosphatidylinositol-4-phosphate 5-kinase I alpha by a Rac- and Rho-dependent pathway

Phosphatidylinositol 4,5-bisphosphate (PI4,5P(2)) mediates cell motility and changes in cell shape in response to extracellular stimuli. In platelets, it is synthesized from PI4P by PIP5K in response to stimulation of a G-protein-coupled receptor by an agonist, such as the thrombin. In the present study, we have addressed the pathway that induces PIP5K I alpha activation following the addition of thrombin. Under resting condition expressed PIP5K I alpha was predominantly localized in a perinuclear distribution. After stimulation of the thrombin receptor, PAR1, or overexpression of a constitutively active variant of G alpha(q), PIP5K I alpha translocated to the plasma membrane. Movement of PIP5K I alpha to the cell membrane was dependent on both GTP-bound Rac and Rho, but not Arf, because: 1) inactive GDP-bound variants of either Rac or Rho blocked the translocation induced by constitutively active G alpha(q), 2) constitutively GTP-bound active variants of Rac or Rho induced PIP5K I alpha translocation in the absence of other stimuli, and 3) constitutively active variants of Arf1 or Arf6 failed to induce membrane translocation of PIP5K I alpha. In addition, a dominant negative variant of Rho blocked the PIP5K I alpha membrane translocation induced by constitutively active Rac, whereas dominant negative variants of either Rac or Arf6 failed to block PIP5K I alpha membrane translocation induced by constitutively active Rho. This implies that the effect on PIP5K I alpha by Rac is indirect, and requires the activation of Rho. In contrast to the findings with PIP5K I alpha, the related lipid kinase PIP4K failed to undergo translocation after stimulation by small GTP-binding proteins Rac or Rho. We also tested whether membrane localization of PIP5K I alpha correlated with an increase in its lipid kinase activity and found that co-expressing of PIP5K I alpha with either constitutively active G alpha(q), Rac, or Rho led to a 5- to 7-fold increase in PIP5K I alpha activity. Thus, these findings suggest that stimulation of a G-protein-coupled receptor (PAR1) leads to the sequential activation of G alpha(q), Rac, Rho, and PIP5K I alpha. Once activated and translocated to the cell membrane, PIP5K I alpha becomes available to phosphorylate PI4P to generate PI4,5P(2) on the plasma membrane.

Adenoviral E1B-55kDa protein inhibits yeast mRNA export and perturbs nuclear structure

The mechanisms of export of RNA from the nucleus are poorly understood; however, several viral proteins modulate nucleocytoplasmic transport of mRNA. Among these are the adenoviral proteins E1B-55kDa and E4-34kDa. Late in infection, these proteins inhibit export of host transcripts and promote export of viral mRNA. To investigate the mechanism by which these proteins act, we have expressed them in Saccharomyces cerevisiae. Overexpression of either or both proteins has no obvious effect on cell growth. By contrast, overexpression of E1B-55kDa bearing a nuclear localization signal (NLS) dramatically inhibits cell growth. In this situation, the NLS-E1B-55kDa protein is localized to the nuclear periphery, fibrous material is seen in the nucleoplasm, and poly(A)+ RNA accumulates in the nucleus. Simultaneous overexpression of E4-34kDa bearing or lacking an NLS does not modify these effects. We discuss the mechanisms of selective mRNA transport.

Stabilization of actin filaments at early times after adenovirus infection and in heat-shocked cells

Human cells (HEp-2) infected with adenovirus type 5 (Ad5) at early times (5-7 h) after infection exhibit stabilization of the filamentous actin network against disruption by latrunculin (300-2000 ng), a potent microfilament toxin. This protection is abrogated by pretreatment of infected cells with cycloheximide, suggesting that it is due to a protein induced early after Ad5 infection. Support for a role of HSP70 (heat shock protein of Mr = 70 kDa) in actin stabilization is based on several findings; (i) HSP70 is induced at early times post-infection in Ad5-infected HEp-2 cells, (ii) heat shock treatment (42 degrees C) of uninfected HEp-2 or HeLa cells results in a rearrangement of actin filaments around the nucleus, that is resistant to disruption by latrunculin, (iii) using a DNase I inhibition assay, the percentage of filamentous actin increases from 50 to 65% of total following heat shock of uninfected cells, and (iv) HSP70 induces actin polymerization from monomers in vitro.

Localization of the adenovirus early region 1B 55-kilodalton protein during lytic infection: association with nuclear viral inclusions requires the early region 4 34-kilodalton protein

The distribution of the adenovirus early region 1B 55-kDa protein (E1B-55kDa) in lytically infected HeLa cells was determined. At the time of infection, when the E1B-55kDa protein facilitates the cytoplasmic accumulation of viral mRNA while simultaneously restricting the accumulation of most cellular mRNA, five distinct intracellular localizations of the protein were observed. Only one of these was disrupted when cells were infected with a mutant virus that fails to produce a second viral protein encoded by early region 4 (E4-34kDa). This protein normally forms a complex with the E1B-55kDa polypeptide, enabling it to influence RNA metabolism. This key localization of the E1B protein was within and about the periphery of nuclear viral inclusion bodies believed to be the site of viral DNA replication and transcription. In the absence of the E4-34kDa protein, the coincidence of E1B-55kDa-specific immunofluorescence and phase-dense viral inclusions was reduced compared with that in a wild-type infection. Similarly, by immunoelectron microscopy, the relative number of E1B-55kDa-specific immunogold particles associated with the clear fibrillar inclusion bodies was reduced. However, the E4-34kDa protein was not required for the close association of the early region 2A DNA binding protein with the viral inclusions. We propose that the viral 55-kDa-34-kDa protein complex interacts with a cellular factor required for cytoplasmic accumulation of mRNAs and directs it to the periphery of the transcriptionally active viral inclusion bodies. This model provides an explanation for the ability of these viral proteins to simultaneously enhance accumulation of viral mRNAs and inhibit accumulation of cellular mRNAs.

Intranuclear location of the adenovirus type 5 E1B 55-kilodalton protein

The intracellular location of the adenovirus type 5 E1B 55-kilodalton (kDa) protein, particularly the question of whether it is associated with nuclear pore complexes, was examined. Fractionation of adenovirus type 5-infected HeLa cell nuclei by an established procedure (N. Dwyer and G. Blobel, J. Cell. Biol. 70:581-591, 1976) yielded one population of E1B 55-kDa protein molecules released by digestion of nuclei with RNase A and a second population recovered in the pore complex-lamina fraction. Free and E1B 55-kDa protein-bound forms of the E4 34-kDa protein (P. Sarnow, C. A. Sullivan, and A. J. Levine, Virology 120:387-394, 1982) were largely recovered in the pore complex-lamina fraction. Nevertheless, the association of E1B 55-kDa protein molecules with this nuclear envelope fraction did not depend on interaction of the E1B 55-kDa protein with the E4 34-kDa protein. Comparison of the immunofluorescence patterns observed with antibodies recognizing the E1B 55-kDa protein or cellular pore complex proteins and of the behavior of these viral and cellular proteins during in situ fractionation suggests that the E1B 55-kDa protein does not become intimately or stably associated with pore complexes in adenovirus-infected cells.

Estramustine phosphate reversibly inhibits an early stage during adenovirus replication

Estramustine phosphate, an estradiol-mustard conjugate, was shown to reversibly inhibit a stage during the first hour of productive adenovirus 2 infection of HeLa cells. This drug, employed in the therapy of advanced prostatic cancer, specifically interacts with microtubule-associated proteins (MAPs) of the cytoskeleton. The results obtained under physiological conditions in vivo suggest a MAPs-interference with the microtubule-mediated vectorial migration of the virus inoculum to the nucleus. Virus attachment, uncoating kinetics and the appearance of established uncoating intermediates were not affected.

Nontranslated cellular mRNAs are associated with the cytoskeletal framework in influenza virus or adenovirus infected cells

In an effort to understand the molecular mechanisms underlying the selective shutoff of host protein synthesis in influenza virus and adenovirus infected cells, we analyzed the subcellular location of representative cellular and viral mRNAs. Earlier work has shown that the majority of cellular mRNAs remain polysome associated after infection by either virus and that both the initiation and elongation steps of host protein synthesis were blocked in infected cells (M. G. Katze, D. DeCorato, and R. M. Krug, J. Virol., 60, 1027-1039, 1986). The present study was undertaken to test whether these cellular mRNAs were rendered nontranslatable during infection as a result of their dissociation from the cytoskeleton framework. HeLa cells were fractionated into subcellular components by first gently disrupting the cells with Triton X-100 yielding the soluble fraction (SOL); the cytoskeleton (CSK) fraction was obtained from the Triton insoluble material by the double detergent treatment of Tween-40 and sodium deoxycholate. In uninfected cells the majority of host mRNAs were associated with polysomes which were exclusively bound to the CSK as would be expected of actively translated mRNAs. The cellular mRNAs also remained almost totally associated with the cytoskeleton in adenovirus and influenza virus infected cells despite the fact that these mRNAs are not translated during infection. Indeed, the host mRNAs and the efficiently translated viral mRNAs were CSK associated to the same extent. In contrast to the adenovirus and influenza systems, significant amounts of cellular mRNAs were dissociated from the CSK and found in the SOL fraction of poliovirus infected cells as others have reported. In accordance with the biochemical analysis, morphological studies utilizing electron microscopy revealed that the cytoskeleton remained relatively intact during adenovirus and influenza infection but was substantially reorganized in poliovirus infected cells. We conclude that translational regulatory events are likely different in the poliovirus system and that cytoskeletal association of mRNAs may be required but is not sufficient for efficient mRNA translation during adenovirus or influenza virus infection.

Alterations in nuclear matrix structure after adenovirus infection

Infection of HeLa cells with adenovirus serotype 2 causes rearrangements in nuclear matrix morphology which can best be seen by gentle cell extraction and embedment-free section electron microscopy. We used these techniques to examine the nuclear matrices and cytoskeletons of cells at 6, 13, 28, and 44 h after infection. As infection progressed, chromatin condensed onto the nucleoli and the nuclear lamina. Virus-related inclusions appeared in the nucleus, where they partitioned with the nuclear matrix. These virus centers consisted of at least three distinguishable areas: amorphously dense regions, granular regions whose granulations appeared to be viral capsids, and filaments connecting these regions to each other and to the nuclear lamina. The filaments became decorated with viral capsids of two different densities, which may be empty capsid shells and capsids with DNA-protein cores. The interaction of some capsids with the filaments persisted even after lysis of the cell. We propose that granulated virus-related structures are sites of capsid assembly and storage and that the filaments may be involved in the transport of capsids and capsid intermediates. The nuclear lamina became increasingly crenated after infection, with some extensions appearing to bud off and form blebs of nuclear material in the cytoplasm. The perinuclear cytoskeleton became rearranged after infection, forming a corona of decreased filament number around the nucleus. In summary, we propose that adenovirus rearranges the nuclear matrix and cytoskeleton to support its own replication.

Identification of the trans-acting Rep proteins of adeno-associated virus by antibodies to a synthetic oligopeptide

Prior genetic analysis provided evidence for trans-acting regulatory proteins (Rep) coded by the left-hand open reading frame (orf-1) of adeno-associated virus (AAV). We have used immunoblotting analysis to identify four protein products of orf-1. Antibodies elicited against an oligopeptide encoded by orf-1 were reacted with extracts of cells that were infected with AAV or transfected with AAV recombinant vectors in the presence or absence of helper adenovirus. The antibody recognized four polypeptides with apparent molecular weights of 78,000, 68,000, 52,000, and 40,000. The 78,000-dalton (78K) (Rep78) and 68K (Rep68) proteins appear to be encoded by the unspliced 4.2-kilobase (kb) and spliced 3.9-kb mRNAs, respectively, transcribed from the p5 promoter. The 52K (Rep52) and 40K (Rep40) proteins appear to be the products of the unspliced 3.6-kb and the spliced 3.3-kb mRNAs, respectively, transcribed from the p19 promoter. Rigorous identification of Rep68 as an AAV-coded protein is compromised by a cross-reacting cellular protein of similar size. All four proteins were expressed in the human cell lines 293, HeLa, HT29, and A549 infected with AAV together with adenovirus. Rep78 and Rep52 were detected at lower levels in cells infected with AAV at high multiplicity in the absence of adenovirus. Human 293 cells transfected with a recombinant AAV vector (pAV2) also expressed Rep proteins in the presence or absence of adenovirus. Mutations introduced into the Rep region of pAV2 further identified the Rep proteins. The amount of each Rep protein varied between nuclear and cytoplasmic extracts, but all four proteins accumulated during the lytic cycle of the viral infection. Other studies have indicated that the Rep proteins have independent trans-acting functions in viral DNA replication and negative and positive regulation of gene expression. Correlation of each trans-acting function with individual Rep proteins will be facilitated with the antibodies described herein.

Homology of adenoviral E3 glycoprotein with HLA-DR heavy chain

The Mr 19,000 adenovirus glycoproteins coded by the E3 region that is expressed on the cell membrane and presumably binds to HLA class I antigen shows sequence homology to the alpha-chain of human HLA-DR and to the kappa-chain of human IgM. The homology extends to a conserved domain present in all of the major histocompatibility complex antigens, beta 2-microglobulins, and immunoglobulins. Predicted beta-sheet secondary structures are similar between the Mr 19,000 adenovirus protein and these immune system proteins. Evolutionary and functional implications of the homology are discussed.

Intracellular localization of adenovirus type 5 tumor antigens in productively infected cells

The intracellular localization of tumor antigens of human adenovirus type 5 (Ad5) during lytic infection of KB cells has been studied. The cells were pulse labeled with [35S]methionine early after infection and early proteins of 58,000 D (58K), 44K, 19K, 18.5K, and 14K detectable by immunoprecipitation with hamster antitumor serum were assayed for association with cytoplasm, nucleoplasm, chromatin, cytosol, cytoskeleton, and membranes. The 44,000 D (44K) tumor antigen encoded in early region 1A (E1A: 0-4.4%) was recovered in approximately equal amounts from cytoplasmic and nucleoplasmic fractions of pulse-labeled cells and within the cytoplasmic compartment was found in the cytosol as well as associated with the cytoskeleton. The E1B-58K (E1B: 4.5-11.2%) antigen was also found to be associated with the cytoplasmic and nucleoplasmic fractions in approximately equal amounts but unlike the E1A-44K showed no affinity for cytoskeletons. Pulse-chase and immunofluorescence experiments suggested the 58K antigen accumulated in the nucleus late in infection. The E1B-19K antigen was found almost exclusively associated with the membrane fraction of infected KB cells and was resolved in polyacrylamide gels into two related species of 18.5K and 19K. Immunofluorescence studies on the E1B 18.5-19K doublet suggested that within a population of infected HeLa cells a small minority seemed to be expressing copious amounts of stainable antigen. Cell fractionation and immunofluorescence studies showed that the E4-14K antigen was a nuclear protein and the only antigen in this study which showed a significant association with a nuclear subfraction composed almost entirely of histones. The implications of these findings for the roles of the Ad5 tumor antigens in lytic infection and transformation are discussed.

Heterogeneic autoantibody against neurofilament protein in the sera of animals with experimental kuru and Creutzfeldt-Jakob disease and natural scrapie infection

Heterogeneic autoantibodies against axonal neurofilament proteins of mature mouse neurons grown in vitro were detected by the indirect immunofluorescence technique in 12.7% (9 of 71) of the sera from nonhuman primates infected with kuru, in 14.5% (17 of 117) and 4% (1 of 25), respectively, of the sera from nonhuman primates and laboratory rodents infected with Creutzfeldt-Jakob disease, and in 35% (7 of 20) of the sera from sheep naturally infected with scrapie. Autoantibody titers ranged from 1:16 to 1:512 in Creutzfeldt-Jakob disease-infected animals, 1:32 to 1:512 in kuru-infected animals, and 1:64 to 1:1,024 in sheep with natural scrapie. The sera from 11 monkeys and 17 hamsters infected with scrapie and from 19 chimpanzees inoculated with brain tissues from humans with other neurological diseases did not contain autoantibodies. Of the 41 chimpanzees with Creutzfeldt-Jakob disease, 6 had autoantibodies against neurofilament proteins before experimental inoculation, whereas 6 others developed autoantibodies after inoculation, 4 developed autoantibodies during the asymptomatic phase, and 2 developed autoantibodies during the terminal clinical phase. Of the 48 chimpanzees with kuru, 2 had autoantibodies before inoculation, 6 developed autoantibodies after inoculation, 3 developed autoantibodies during the asymptomatic phase, and 3 developed autoantibodies during the terminal clinical phase. Among the normal nonhuman primate controls, 4.6% (9 of 195) had autoantibodies. In contrast, no autoantibodies were detected in 49 control rodents and 13 control sheep. The increased incidence of autoantibodies against neurofilament proteins in animals with kuru, Creutzfeldt-Jakob disease, and scrapie constitutes the first evidence of an immunological reaction in this group of atypical infections caused by unconventional viruses and suggests that neurofilaments may be involved in pathogenesis.

Adeno-associated virus RNA transcription in vivo

We have studied RNA transcripts of the defective parvovirus, adeno-associated virus (AAV) present in poly(A)rich and poly-(A)free fractions of nuclear and cytoplasmic RNA prepared from cells infected together with a helper adenovirus. Cytoplasmic poly-(A)rich RNA contains three overlapping spliced AAV RNAs having sizes of 3.9 X 10(3), 3.3 X 10(3) and 2.3 X 10(3) bases respectively. The nuclear precursors of these RNAs appear to be the coterminal unspliced poly(A)-rich RNAs containing 4.2 X 10(3), 3.6 X 10(3) and 2.6 X 10(3) bases respectively. These unspliced RNAs were also found in the cytoplasm. The nuclear poly(A)-free RNA contained a heterogenous population of AAV RNAs that were generally smaller than 2.3 X 10(3) bases. In addition, the Hirt pellet fraction of the nuclear RNA contained two discrete AAV poly(A)-free RNAs having sizes of 2.5 X 10(3) and 2.8 X 10(3) bases. The 4.2 X 10(3) and 3.6 X 10(3)-base unspliced RNAs are more abundant than the coterminal 3.9 X 10(3) and 3.3 X 10(3)-base spliced RNAs whereas the 2.3 X 10(3)-base spliced RNA is much more abundant than the 2.6 X 10(3)-base unspliced RNA. Thus, the cytoplasmic abundance of the AAV spliced RNAs appears to be controlled in part by the post-transcriptional events of splicing or message stability. We also analysed the effects of AAV defective-interfering genomes upon AAV transcription. These studies showed that when synthesis of standard AAV genomes was inhibited more than 10-fold by defective-interfering genomes there was no significant effect on the types or amounts of AAV RNA transcripts which accumulated. These observations indicate that interference by defective-interfering genomes occurs mostly at the level of DNA replication rather than transcription.

Microtubules and microfilaments in HSV-Infected rabbit-kidney cells

In rabbit kidney cells infected with strains of Herpes simplex virus producing either cell-rounding or polycaryocytosis. Vinblastine induced paracrystals. This could be shown by phase-contrast- and electron-microscopy. Infections were done under one-step-growth conditions or at low MOI. 90 per cent noninfected cells contained stress fibers as detected by Servablue R250-staining. Shortly after recruitment into polycaryocytes, stress fibres of normal length appearing in criss-cross arrangement can be seen in the periphery of these cells. Later they polymerize to very long fibers and finally they are partially destroyed. The time of destruction depends on the MOI employed. By using Actinomycin D and/or Cycloheximide as blocking agents, it could be shown that polymerization of microfilaments correlates in time with giant cell formation. In view of the fact that the virus synthesis is accompanied in parallel by a special rearrangement of microfilaments as well as polycaryocytosis, both these processes have to be considered as caused by early (and late ?) protein-synthesis (beta-/gamma-proteins) but not as induced by "very-early" proteins (alpha-proteins).