Epigenetics and the dynamics of chromatin during adenovirus infections

The DNA genome of eukaryotic cells is compacted by histone proteins within the nucleus to form chromatin. Nuclear-replicating viruses such as adenovirus have evolved mechanisms of chromatin manipulation to promote infection and subvert host defenses. Epigenetic factors may also regulate persistent adenovirus infection and reactivation in lymphoid tissues. In this review, we discuss the viral proteins E1A and protein VII that interact with and alter host chromatin, as well as E4orf3, which separates host chromatin from sites of viral replication. We also highlight recent advances in chromatin technologies that offer new insights into virus-directed chromatin manipulation. Beyond the role of chromatin in the viral replication cycle, we discuss the nature of persistent viral genomes in lymphoid tissue and cell lines, and the potential contribution of epigenetic signals in maintaining adenovirus in a quiescent state. By understanding the mechanisms through which adenovirus manipulates host chromatin, we will understand new aspects of this ubiquitous virus and shed light on previously unknown aspects of chromatin biology.

Limited but durable changes to cellular gene expression in a model of latent adenovirus infection are reflected in childhood leukemic cell lines

Mucosal lymphocytes support latent infections of species C adenoviruses. Because infected lymphocytes resist re-infection with adenovirus, we sought to identify changes in cellular gene expression that could inhibit the infectious process. The expression of over 30,000 genes was evaluated by microarray in persistently infected B-and T-lymphocytic cells. BBS9, BNIP3, BTG3, CXADR, SLFN11 and SPARCL1 were the only genes differentially expressed between mock and infected B cells. Most of these genes are associated with oncogenesis or cancer progression. Histone deacetylase and DNA methyltransferase inhibitors released the repression of some of these genes. Cellular and viral gene expression was compared among leukemic cell lines following adenovirus infection. Childhood leukemic B-cell lines resist adenovirus infection and also show reduced expression of CXADR and SPARCL. Thus adenovirus induces limited changes to infected B-cell lines that are similar to changes observed in childhood leukemic cell lines.

Neonatal infection with species C adenoviruses confirmed in viable cord blood lymphocytes

Credible but conflicting reports address the frequency of prenatal infection by species C adenovirus. This question is important because these viruses persist in lymphoid cells and suppress double-stranded DNA-break repair. Consequently, prenatal adenovirus infections may generate the aberrant clones of lymphocytes that precede development of childhood acute lymphoblastic leukemia (ALL). The present study was designed to overcome technical limitations of prior work by processing cord blood lymphocytes within a day of collection, and by analyzing sufficient numbers of lymphocytes to detect adenovirus-containing cells at the lower limits determined by our previous studies of tonsil lymphocytes. By this approach, adenoviral DNA was identified in 19 of 517 (3.7%) samples, providing definitive evidence for the occurrence of prenatal infection with species C adenoviruses in a significant fraction of neonates predominantly of African American and Hispanic ancestry. Cord blood samples were also tested for the presence of the ETV6-RUNX1 translocation, the most common genetic abnormality in childhood ALL. Using a nested PCR assay, the ETV6-RUNX1 transcript was detected in four of 196 adenovirus-negative samples and one of 14 adenovirus-positive cord blood samples. These findings indicate that this method will be suitable for determining concordance between adenovirus infection and the leukemia-associated translocations in newborns.

Adenovirus DNA is detected at increased frequency in Guthrie cards from children who develop acute lymphoblastic leukaemia

Epidemiological evidence suggests that childhood acute lymphoblastic leukaemia (ALL) may be initiated by an in infection in utero. Adenovirus DNA was detected in 13 of 49 neonatal blood spots from ALL patients but only in 3 of 47 controls (P=0.012) suggesting a correlation between prenatal adenovirus infection and the development of ALL

Detection and quantitation of subgroup C adenovirus DNA in human tissue samples by real-time PCR

Advances in amplification techniques have revolutionized the ability to detect viruses both quantitatively and qualitatively and to study viral load. Real-time polymerase chain reaction (PCR) amplification depends on the ability to detect and quantify a fluorescent reporter molecule whose signal increases in proportion to the amount of amplification product generated. Recent advances have been made by using probes, such as TaqMan probes, to detect amplified products. Use of these probes offers confirmation of specificity of the PCR product. Here we describe a sensitive real-time PCR assay to quantify subgroup C adenoviral DNA in human lymphocytes derived from mucosal tissues removed in routine tonsillectomy or adenoidectomy. This chapter will describe in detail the methods used for these analyses.

Postinternalization inhibition of adenovirus gene expression and infectious virus production in human T-cell lines

Detection of adenovirus DNA in human tonsillar T cells in the absence of active virus replication suggests that T cells may be a site of latency or of attenuated virus replication in persistently infected individuals. The lytic replication cycle of Ad5 in permissive epithelial cells (A549) was compared to the behavior of Ad5 in four human T-cell lines, Jurkat, HuT78, CEM, and KE37. All four T-cell lines expressed the integrin coreceptors for Ad2 and Ad5, but only Jurkat and HuT78 express detectable surface levels of the coxsackie adenovirus receptor (CAR). Jurkat and HuT78 cells supported full lytic replication of Ad5, albeit at a level approximately 10% of that of A549, while CAR-transduced CEM and KE37 cells (CEM-CARhi and KE37-CARhi, respectively) produced no detectable virus following infection. All four T-cell lines bind and internalize fluorescently labeled virus. In A549, Jurkat, and HuT78 cells, viral proteins were detected in 95% of cells. In contrast, only a small subpopulation of CEM-CARhi and KE37-CARhi cells contained detectable viral proteins. Interestingly, Jurkat and HuT78 cells synthesize four to six times more copies of viral DNA per cell than did A549 cells, indicating that these cells produce infectious virions with much lower efficiency than A549. Similarly, CEM-CARhi and KE37-CARhi cells, which produce no detectable infectious virus, synthesize three times more viral genomes per cell than A549. The observed blocks to adenovirus gene expression and replication in all four human T-cell lines may contribute to the maintenance of naturally occurring persistent adenovirus infections in human T cells.

The adenovirus e3 promoter is sensitive to activation signals in human T cells

The group C adenoviruses typically cause acute respiratory disease in young children. In addition, a persistent phase of infection has been observed in which virus may be shed for years without producing overt pathology. Our laboratory recently reported that group C adenovirus DNA can be found in tonsil and adenoid T lymphocytes from the majority of pediatric donors (C. T. Garnett, D. Erdman, W. Xu, and L. R. Gooding, J. Virol. 76:10608-10616, 2002). This finding suggests that immune evasion strategies of human adenoviruses may be directed, in part, toward protection of persistently or latently infected T lymphocytes. Many of the adenoviral gene products implicated in prevention of immune destruction of virus-infected cells are encoded within the E3 transcription unit. In this study, the E3 promoter was evaluated for sensitivity to T-cell activation signals by using a promoter reporter plasmid. Indeed, this promoter is extremely sensitive to T-cell activation, with phorbol myristate acetate (PMA) plus ionomycin increasing E3-directed transcription 100-fold. By comparison, in the same cells E1A expression leads to a 5.5-fold increase in transcription from the E3 promoter. In contrast to induction by E1A, activation by PMA plus ionomycin requires the two E3 NF-kappaB binding sites. Interestingly, expression of E1A inhibits induction of the E3 promoter in response to T-cell activation while increasing E3 promoter activity in unactivated cells. Collectively, these data suggest that the E3 promoter may have evolved the capacity to respond to T-cell activation in the absence of E1A expression and may act to upregulate antiapoptotic gene expression in order to promote survival of persistently infected T lymphocytes.

Prevalence and quantitation of species C adenovirus DNA in human mucosal lymphocytes

The common species C adenoviruses (serotypes Ad1, Ad2, Ad5, and Ad6) infect more than 80% of the human population early in life. Following primary infection, the virus can establish an asymptomatic persistent infection in which infectious virions are shed in feces for several years. The probable source of persistent virus is mucosa-associated lymphoid tissue, although the molecular details of persistence or latency of adenovirus are currently unknown. In this study, a sensitive real-time PCR assay was developed to quantitate species C adenovirus DNA in human tissues removed for routine tonsillectomy or adenoidectomy. Using this assay, species C DNA was detected in Ficoll-purified lymphocytes from 33 of 42 tissue specimens tested (79%). The levels varied from fewer than 10 to greater than 2 x 10(6) copies of the adenovirus genome/10(7) cells, depending on the donor. DNA from serotypes Ad1, Ad2, and Ad5 was detected, while the rarer serotype Ad6 was not. When analyzed as a function of donor age, the highest levels of adenovirus genomes were found among the youngest donors. Antibody-coated magnetic beads were used to purify lymphocytes into subpopulations and determine whether viral DNA could be enriched within any purified subpopulations. Separation of T cells (CD4/8- expressing and/or CD3-expressing cells) enriched viral DNA in each of nine donors tested. In contrast, B-cell purification (CD19-expressing cells) invariably depleted or eliminated viral DNA. Despite the frequent finding of significant quantities of adenovirus DNA in tonsil and adenoid tissues, infectious virus was rarely present, as measured by coculture with permissive cells. These findings suggest that human mucosal T lymphocytes may harbor species C adenoviruses in a quiescent, perhaps latent form.

The adenovirus E3 RID complex protects some cultured human T and B lymphocytes from Fas-induced apoptosis

Human group C adenoviruses cause an acute infection in respiratory epithelia and establish a long-term or persistent infection, possibly in lymphocytes. The mechanism by which this persistence is maintained is unknown; however, it would require that persistently infected lymphocytes not be deleted. The adenovirus genome encodes proteins that prevent the immune system from eliminating the virus-infected cell, including the E3 receptor internalization and degradation (RID) complex. The RID complex prevents death of infected cells by blocking apoptosis initiated through death domain-containing receptors of the tumor necrosis factor receptor (TNFR) superfamily, including TNFR1 (L. R. Gooding, T. S. Ranheim, A. E. Tollefson, L. Aquino, P. Duerksen-Hughes, T. M. Horton, and W. S. Wold, J. Virol. 65:4114-4123, 1991), TNF-related apoptosis-inducing ligand receptors (TRAIL-R1 and -R2) (C. A. Benedict, P. S. Norris, T. I. Prigozy, J. L. Bodmer, J. A. Mahr, C. T. Garnett, F. Martinon, J. Tschopp, L. R. Gooding, and C. F. Ware, J. Biol. Chem. 276:3270-3278, 2001; A. E. Tollefson, K. Toth, K. Doronin, M. Kuppuswamy, O. A. Doronina, D. L. Lichtenstein, T. W. Hermiston, C. A. Smith, and W. S. Wold, J. Virol. 75:8875-8887, 2001), and Fas (J. Shisler, C. Yang, B. Walter, C. F. Ware, and L. R. Gooding, J. Virol. 71:8299-8306, 1997). Here, we test the ability of RID to protect human lymphocytes from apoptosis induced by ligation of Fas, a mechanism important for regulating lymphocyte populations. Using a retrovirus expressing RID to infect six human lymphocyte cell lines, we found that RID functions in the absence of other viral proteins to downregulate surface Fas on some, but not all, cell lines. Total cellular levels of Fas decrease as measured by Western blotting, and this loss of Fas correlates with protection from apoptosis induced by ligation of Fas in every cell line tested. Although in some cases, RID causes loss of only a fraction of surface Fas, the presence of RID completely blocks the immediate events downstream of Fas ligation (i.e., Fas-FADD association and caspase-8 cleavage) in susceptible cell lines. Nonetheless, the ability of RID to block Fas signaling is independent of the Fas signaling pathway used (type I or type II). Interestingly, among the four T-cell lines tested, RID caused loss of Fas in the two T-cell lines bearing a relatively immature phenotype, while having no activity in T cells with mature phenotypes. Collectively, these data suggest that RID functions to prevent apoptosis of some human lymphocytes by internalizing surface Fas receptors. It is possible that the expression of RID facilitates long-term infection by preventing Fas-mediated deletion of persistently infected lymphocytes.

Adenoviral inhibitors of apoptotic cell death

Adenoviruses (Ads) are endemic in the human population and the well-studied group C Ads typically cause an acute infection in the respiratory epithelium. A growing body of evidence suggests that these viruses also establish a persistent infection. The Ad genome encodes several proteins that counteract the host anti-viral mechanisms, which function to limit viral infections. This review describes the adenovirus immuno-regulatory proteins and how they function to block apoptosis of infected cells. In addition to facilitating the successful completion of the viral replication cycle and spread of progeny virus, these functions may help maintain the virus in a persistent state.

Three adenovirus E3 proteins cooperate to evade apoptosis by tumor necrosis factor-related apoptosis-inducing ligand receptor-1 and -2

Adenovirus encodes multiple gene products that regulate proapoptotic cellular responses to viral infection mediated by both the innate and adaptive immune systems. The E3-10.4K and 14.5K gene products are known to modulate the death receptor Fas. In this study, we demonstrate that an additional viral E3 protein, 6.7K, functions in the specific modulation of the two death receptors for tumor necrosis factor-related apoptosis-inducing ligand (TRAIL). The 6.7K protein is expressed on the cell surface and forms a complex with the 10.4K and 14.5K proteins, and this complex is sufficient to induce down-modulation of TRAIL receptor-1 and -2 from the cell surface and reverse the sensitivity of infected cells to TRAIL-mediated apoptosis. Down-modulation of TRAIL-R2 by the E3 complex is dependent on the cytoplasmic tail of the receptor, but the death domain alone is not sufficient. These results identify a mechanism for viral modulation of TRAIL receptor-mediated apoptosis and suggest the E3 protein complex has evolved to regulate the signaling of selected cytokine receptors.

Immune evasion by adenoviruses

Adenovirus is a human pathogen that infects mainly respiratory and gastrointestinal epithelia. While the pathology caused by this virus is generally not life threatening in immunocompetent individuals, there is a large literature describing its ability to establish a persistent infection. These persistent infections typically occur in apparently healthy individuals with no outward signs of disease. Such a long term and benign interaction between virus and immune system requires adenoviruses to dampen host antiviral effector mechanisms that would otherwise eliminate the virus and cause immune-mediated pathology to the host. Adenovirus devotes a significant portion of its genome to gene products whose sole function seems to be the modulation of host immune responses. This review focuses on what is currently understood about how these immunomodulatory mechanisms work and how they might play a role in maintaining the virus in a persistent state.

The adenovirus E3-10.4K/14.5K complex mediates loss of cell surface Fas (CD95) and resistance to Fas-induced apoptosis

Cytotoxic T cells use Fas (CD95), a member of the tumor necrosis factor (TNF) receptor superfamily, to eliminate virus-infected cells by activation of the apoptotic pathway for cell death. The adenovirus E3 region encodes several proteins that modify immune defenses, including TNF-dependent cell death, which may allow this virus to establish a persistent infection. Here we show that, as an early event during infection, the adenovirus E3-10.4K/14.5K complex selectively induces loss of Fas surface expression and blocks Fas-induced apoptosis of virus-infected cells. Loss of surface Fas occurs within the first 4 h postinfection and is not due to decreased production of Fas protein. The decrease in surface Fas is distinct from the 10.4K/14.5K-mediated loss of the epidermal growth factor receptor on the same cells, because intracellular stores of Fas are not affected. Further, 10.4K/14.5K, which was previously shown to protect against TNF cytolysis, does not induce a loss of TNF receptor, indicating that this complex mediates more than one function to block host defense mechanisms. These results suggest yet another mechanism by which adenovirus modulates host cytotoxic responses that may contribute to persistent infection by human adenoviruses.

Generation of cytotoxic T lymphocytes against immunorecessive epitopes after multiple immunizations with adenovirus vectors is dependent on haplotype

Currently, adenovirus (Ad) is being considered as a vector for the treatment of cystic fibrosis as well as other diseases. However, the cytotoxic T lymphocyte (CTL) response to Ad could limit the effectiveness of such approaches. Since the CTL response to virus infection is often focused on one or a few immunodominant epitopes, one approach to circumvent this response is to create vectors that lack these immunodominant epitopes. The effectiveness of this approach was tested by immunizing mice with human group C adenoviruses. Three mouse strains (C57BL/10SnJ [H-2b], C3HeB/FeJ [H-2k], and BALB/cByJ [H-2d]) were immunized with wild-type Ad or Ad vectors lacking the immunodominant antigen(s), and the CTL responses were measured. In C57BL/10 (B10) mice, a single inoculation intraperitoneally (i.p.) led to the recognition of an immunodominant antigen in E1A. When B10 mice were inoculated multiple times either i.p. or intranasally with wild-type Ad or an Ad vector lacking most of the E1 region, subdominant epitopes outside this region were recognized. In contrast, C3H mice inoculated with wild-type Ad recognized an epitope mapping within E1B. When inoculated twice with Ad vectors lacking both E1A and E1B, no immunorecessive epitopes were recognized. The immune response to Ad in BALB/c mice was more complex. CTLs from BALB/c mice inoculated i.p. with wild-type Ad recognized E1B in the context of the major histocompatibility complex (MHC) class I Dd allele and a region outside E1 associated with the Kd allele. When BALB/c mice were inoculated with E1-deleted Ad vectors, only the immunodominant Kd-restricted epitope was recognized, and Dd-restricted CTLs did not develop. This report indicates that the emergence of CTLs against immunorecessive epitopes following multiple administrations of Ad vectors lacking immunodominant antigens is dependent on haplotype and could present an obstacle to gene therapy in an MHC-diverse human population.

Characterization of factors involved in modulating persistence of transgene expression from recombinant adenovirus in the mouse lung

One potential limitation of adenovirus (Ad)-based vectors for the gene therapy of cystic fibrosis (CF) and other genetic diseases is the transience of expression observed in most in vivo systems. In this study, the influence of various factors on persistence of transgene expression in the lung was investigated. In the absence of immune pressure, such as in the nude mouse, the genomic structure of the vector was found to be predominant in determining the persistence of expression; Ad vector constructs with an E1-E3+E4ORF6+ backbone encoding beta-galactosidase (beta-Gal) or the cystic fibrosis transmembrane conductance regulator (CFTR) produced declining levels of expression while an Ad/CMV beta Gal vector with an E1-E3+E4+ backbone gave rise to sustained, long-term reporter gene expression. The ability of the latter vector to persist was in turn limited in part by the presence of cytotoxic T lymphocytes (CTLs). Adoptive transfer experiments indicated that CTLs directed against either viral proteins or the beta-Gal reporter gene product were able to reduce expression in nude C57BL/6 mice stably expressing beta-Gal from the E4+ vector. Finally, the specificity and strength of the CTL response elicited by Ad vector was found to vary considerably depending on mouse strain haplotype. These results indicate that persistence of transgene expression in a given system is determined by the interplay between several factors including genomic structure of the vector, host background, and immune response.

The role of human adenovirus early region 3 proteins (gp19K, 10.4K, 14.5K, and 14.7K) in a murine pneumonia model

Products of human adenovirus (Ad) early region 3 (E3) inhibit both specific (cytotoxic T lymphocytes [CTLs]) and innate (tumor necrosis factor alpha [TNF-alpha]) immune responses in vitro. The E3 gp19K protein prevents CTL recognition of Ad-infected fibroblasts by sequestering major histocompatibility complex class I proteins in the endoplasmic reticulum. E3 proteins 10.4K, 14.5K, and 14.7K function to protect infected cells from TNF-alpha cytolysis. To address the in vivo functions of these proteins, Ad mutants that lack the E3 genes encoding these proteins were inoculated intranasally into C57BL/10SnJ (H-2b) mice. Mutants that lack the gp19K gene failed to alter CTL generation or to affect Ad-induced pulmonary infiltrates. Since gamma interferon (IFN-gamma) is capable of overcoming gp19K suppression of CTL lysis in vitro, mice were depleted of IFN-gamma and inoculated with gp19K mutants. Even when IFN-gamma was depleted, gp19K was incapable of altering pulmonary lesions. These resuls are not in accord with the function of gp19K in vitro and suggest that gp19K does not affect immune recognition in vivo during an acute virus infection, yet they do not exclude the possibility that gp19K blocks immune recognition of Ad during a persistent infection. In contrast, when mice were inoculated with Ad mutants that lack the TNF resistance genes (14.7K and either 10.4K or 14.5K), there was a marked increase in alveolar infiltration and no change in the amounts of perivascular/peribronchiolar infiltration compared with wild-type-Ad-induced pathology. These findings demonstrate the importance of TNF susceptibility and TNF by-products for recruiting inflammatory cells into the lungs during Ad infections.

Induction of susceptibility to tumor necrosis factor by E1A is dependent on binding to either p300 or p105-Rb and induction of DNA synthesis

The introduction of the adenovirus early region 1A (E1A) gene products into normal cells sensitizes these cells to the cytotoxic effects of tumor necrosis factor (TNF). Previous studies have shown that the region of E1A responsible for susceptibility is CR1, a conserved region within E1A which binds the cellular proteins p300 and p105-Rb at nonoverlapping sites. Binding of these and other cellular proteins by E1A results in the induction of E1A-associated activities such as transformation, immortalization, DNA synthesis, and apoptosis. To investigate the mechanism by which E1A induces susceptibility to TNF, the NIH 3T3 mouse fibroblast cell line was infected with viruses containing mutations within E1A which abrogate binding of some or all of the cellular proteins to E1A. The results show that TNF susceptibility is induced by E1A binding to either p300 or p105-Rb. E1A mutants that bind neither p300 nor p105-Rb do not induce susceptibility to TNF. Experiments with stable cell lines created by transfection with either wild-type or mutant E1A lead to these same conclusions. In addition, a correlation between induction of DNA synthesis and induction of TNF sensitivity is seen. Only viruses which induce DNA synthesis can induce TNF sensitivity. Those viruses which do not induce DNA synthesis also do not induce TNF sensitivity. These data suggest that the mechanisms underlying induction of susceptibility to TNF by E1A are intimately connected to E1A's capacity to override cell cycle controls.

Activation of intracellular proteases is an early event in TNF-induced apoptosis

The serine protease inhibitor tosyl-argenine methyl ester inhibits TNF-induced apoptosis, suggesting that proteolysis is necessary for this response. To test this hypothesis, we asked whether protein fragmentation occurs during the death of C3HA fibroblasts, a 3T3-like cell that was rendered sensitive to TNF by cycloheximide. Our results show that the binding of fluorescamine, which binds primary amines, was increased in apoptotic cells by approximately 50%. We also found that 10-15% of the protein in apoptotic cells was no longer precipitable by TCA. Evidence for proteolysis was also revealed by SDS-PAGE analysis and from Western blots. We observed fragmentation and/or degradation of lamin B, topoisomerase I, histone H1, protein kinase C beta 1, and cPLA2, indicating that proteolysis during apoptosis is non-specific. We also found evidence of proteolysis in C3HA cells sensitized to TNF by the adenovirus dl758 (which lacks the E3 14.7-kDa resistance gene) suggesting that protease activation is common in TNF-induced apoptosis. In contrast, the adenovirus E3 14.7-kDa resistance gene prevented proteolysis suggesting that this protein acts at, or upstream of the proteases activated in this response. Finally, because tosyl-argenine methyl ester inhibits the release of [3H]arachidonic acid from apoptotic cells, we tested whether proteolysis of cPLA2 is necessary for enzyme activation. Our results failed, however, to reveal a common proteolytic fragment in different cell types, and when tested in vitro the cytosol from apoptotic cells had less cPLA2 activity. It is unlikely, therefore, that proteolysis is necessary for the activation of this enzyme during TNF-induced apoptosis.

Activation of intracellular proteases is an early event in TNF-induced apoptosis

The serine protease inhibitor tosyl-argenine methyl ester inhibits TNF-induced apoptosis, suggesting that proteolysis is necessary for this response. To test this hypothesis, we asked whether protein fragmentation occurs during the death of C3HA fibroblasts, a 3T3-like cell that was rendered sensitive to TNF by cycloheximide. Our results show that the binding of fluorescamine, which binds primary amines, was increased in apoptotic cells by approximately 50%. We also found that 10-15% of the protein in apoptotic cells was no longer precipitable by TCA. Evidence for proteolysis was also revealed by SDS-PAGE analysis and from Western blots. We observed fragmentation and/or degradation of lamin B, topoisomerase I, histone H1, protein kinase C beta 1, and cPLA2, indicating that proteolysis during apoptosis is non-specific. We also found evidence of proteolysis in C3HA cells sensitized to TNF by the adenovirus dl758 (which lacks the E3 14.7-kDa resistance gene) suggesting that protease activation is common in TNF-induced apoptosis. In contrast, the adenovirus E3 14.7-kDa resistance gene prevented proteolysis suggesting that this protein acts at, or upstream of the proteases activated in this response. Finally, because tosyl-argenine methyl ester inhibits the release of [3H]arachidonic acid from apoptotic cells, we tested whether proteolysis of cPLA2 is necessary for enzyme activation. Our results failed, however, to reveal a common proteolytic fragment in different cell types, and when tested in vitro the cytosol from apoptotic cells had less cPLA2 activity. It is unlikely, therefore, that proteolysis is necessary for the activation of this enzyme during TNF-induced apoptosis.

Cytolysis of adenovirus-infected murine fibroblasts by IFN-gamma-primed macrophages is TNF- and contact-dependent

The effect of interferon-gamma (IFN-gamma) priming on macrophages for cytolysis of adenovirus-infected murine fibroblasts was examined using peritoneal macrophages and the RAW264.7 (RAW) murine macrophage cell line. Adenovirus-infected cells were lysed by IFN-gamma-primed RAW macrophages via a TNF- and contact-dependent mechanism under conditions in which little or no soluble TNF was detected in the supernatant of these effectors. TNF involvement in the lytic mechanism of IFN-gamma-primed macrophages is shown by (a) cytolysis of TNF-sensitive LM and adenovirus E1A-expressing cells, (b) protection from cytolysis by the adenovirus E3-14.7K protein and the E3-10.4/14.5K complex of proteins, and (c) inhibition of cytolysis when neutralizing anti-TNF serum is added to cocultures of macrophages and susceptible adenovirus-infected targets. Physical separation of effectors and targets prevents cytolysis, indicating that cell contact is required. Nonetheless, IFN-gamma-primed RAW macrophages are unable to lyse E8 tumor cells, which are killed by fully activated (triggered) macrophages. These findings indicate that IFN-gamma-primed macrophages are cytolytic for TNF-sensitive targets without soluble TNF release, but they lack the full cytolytic capacity of LPS-triggered macrophages.

Regulation of TNF-mediated cell death and inflammation by human adenoviruses

Human adenoviruses are among a growing number of human, animal, and even plant viruses that encode gene products that interfere with the defense mechanisms of the host. The host mechanisms most often affected by these viral products are the innate and inflammatory responses such as interferon and the proinflammatory cytokines interleukin-1 (IL-1) and tumor necrosis factor (TNF). This review discusses examples of viral anti-immune mechanisms from many different viruses and then focuses on the molecular interactions between adenoviruses and TNF and the effect of these interactions on the ensuing pathogenesis of virus infection.

Deletion mutation analysis of the adenovirus type 2 E3-gp19K protein: identification of sequences within the endoplasmic reticulum lumenal domain that are required for class I antigen binding and protection from adenovirus-specific cytotoxic T lymphocytes

Adenovirus E3-gp19K is a transmembrane glycoprotein, localized in the endoplasmic reticulum (ER), which forms a complex with major histocompatibility complex (MHC) class I antigens and retains them in the ER, thereby preventing cytolysis by cytotoxic T lymphocytes (CTL). The ER lumenal domain of gp19K, residues 1 to 107, is known to be sufficient for binding to class I antigens; the transmembrane and cytoplasmic ER retention domains are located at residues ca. 108 to 127 and 128 to 142, respectively. To identify more precisely which gp19K regions are involved in binding to class I antigens, we constructed 13 in-frame virus deletion mutants (4 to 12 amino acids deleted) in the ER lumenal domain of gp19K, and we analyzed the ability of the mutant proteins to form a complex with class I antigens, retain them in the ER, and prevent cytolysis by adenovirus-specific CTL. All mutant proteins except one (residues 102 to 107 deleted) were defective for these properties, indicating that the ability of gp19K to bind to class I antigens is highly sensitive to mutation. All mutant proteins were stable and were retained in the ER. Sequence comparisons among adenovirus serotypes reveal that the ER lumenal domain of gp19K consists of a variable region (residues 1 to 76) and a conserved region (residues 77 to 98). We show, using the mutant proteins, that the gp19K-specific monoclonal antibody Tw1.3 recognizes a noncontiguous epitope in the variable region and that disruption of the variable region by deletion destroys the epitope. The monoclonal antibody and class I antigen binding results, together with the serotype sequence comparisons, are consistent with the idea that the ER lumenal domain of gp19K has three subdomains that we have termed the ER lumenal variable domain (residues 1 to ca. 77 to 83), the ER lumenal conserved domain (residues ca. 84 to 98), and the ER lumenal spacer domain (residues 99 to 107). We suggest that the ER lumenal variable domain of gp19K has a specific tertiary structure that is important for binding to the polymorphic alpha 1 and alpha 2 domains of class I heavy (alpha) chains. We suggest that the ER lumenal conserved domain of gp19K may interact with some conserved protein, perhaps the highly conserved alpha 3 domain of class I heavy chains. Finally, the ER lumenal spacer domain may allow the ER lumenal variable and conserved domains to extend out from the ER membrane so that they can interact with class I heavy chains.

Characterization of mutants within the gene for the adenovirus E3 14.7-kilodalton protein which prevents cytolysis by tumor necrosis factor

The 14,700-Da protein (14.7K protein) encoded by the E3 region of adenovirus has previously been shown to protect mouse cells from cytolysis by tumor necrosis factor (TNF). Delineating the sequences in the 14.7K protein that are required for this activity may provide insight into the mechanism of protection from TNF by 14.7K as well as the mechanism of TNF cytolysis. In the present study, we examined the ability of 14.7K mutants to protect cells from lysis by TNF. In-frame deletions as well as Cys-to-Ser mutations in the 14.7K gene were generated by site-directed mutagenesis and then built into the genome of a modified adenovirus type 5 (dl7001) that lacks all E3 genes. dl7001, which replicates to the same titers as does adenovirus type 5 in cultured cells, has the largest E3 deletion analyzed to date. 51Cr release was used to assay TNF cytolysis. Our results indicate that most mutations in the 14.7K gene result in a loss of function, suggesting that nearly the entire protein rather than a specific domain functions to prevent TNF cytolysis.

Both tumor necrosis factor and nitric oxide participate in lysis of simian virus 40-transformed cells by activated macrophages

SV40 transformation of rodent fibroblasts generally produces cells that are highly sensitive to killing by activated macrophages. The cell line SV-COL-E8 (E8) is typical of SV40-transformed mouse fibroblasts in that it is readily lysed when exposed to activated macrophages. This killing is not due solely to TNF, because soluble TNF alone is incapable of lysing these cells. TNF is, however, necessary for lysis since antibodies to TNF will prevent macrophage-mediated lysis. Similarly, E8 is not sensitive to nitric oxide (NO); however, NO is also necessary for lysis since inhibition of NO generation (by coincubation with the arginine analogue NG-monomethyl-1-arginine) with Fe(II)) blocks lysis of E8 by activated macrophages. Cytolysis by macrophages is contact dependent, suggesting that the cell-associated TNF precursor may be involved in mediating cytolysis. However, transfected cell lines bearing cell-associated TNF precursor do not mediate killing of E8. Thus, killing of E8 either involves both TNF and NO in addition to a third, as yet unidentified, lytic mechanism, or killing requires the contact-dependent delivery of TNF and NO from the macrophage to its target.

Both tumor necrosis factor and nitric oxide participate in lysis of simian virus 40-transformed cells by activated macrophages

SV40 transformation of rodent fibroblasts generally produces cells that are highly sensitive to killing by activated macrophages. The cell line SV-COL-E8 (E8) is typical of SV40-transformed mouse fibroblasts in that it is readily lysed when exposed to activated macrophages. This killing is not due solely to TNF, because soluble TNF alone is incapable of lysing these cells. TNF is, however, necessary for lysis since antibodies to TNF will prevent macrophage-mediated lysis. Similarly, E8 is not sensitive to nitric oxide (NO); however, NO is also necessary for lysis since inhibition of NO generation (by coincubation with the arginine analogue NG-monomethyl-1-arginine) with Fe(II)) blocks lysis of E8 by activated macrophages. Cytolysis by macrophages is contact dependent, suggesting that the cell-associated TNF precursor may be involved in mediating cytolysis. However, transfected cell lines bearing cell-associated TNF precursor do not mediate killing of E8. Thus, killing of E8 either involves both TNF and NO in addition to a third, as yet unidentified, lytic mechanism, or killing requires the contact-dependent delivery of TNF and NO from the macrophage to its target.

The 19-kilodalton adenovirus E1B transforming protein inhibits programmed cell death and prevents cytolysis by tumor necrosis factor alpha

The adenovirus E1A and E1B proteins are required for transformation of primary rodent cells. When expressed in the absence of the 19,000-dalton (19K) E1B protein, however, the E1A proteins are acutely cytotoxic and induce host cell chromosomal DNA fragmentation and cytolysis, analogous to cells undergoing programmed cell death (apoptosis). E1A alone can efficiently initiate the formation of foci which subsequently undergo abortive transformation whereby stimulation of cell growth is counteracted by continual cell death. Cell lines with an immortalized growth potential eventually arise with low frequency. Coexpression of the E1B 19K protein with E1A is sufficient to overcome abortive transformation to produce high-frequency transformation. Like E1A, the tumoricidal cytokine tumor necrosis factor alpha (TNF-alpha) evokes a programmed cell death response in many tumor cell lines by inducing DNA fragmentation and cytolysis. Expression of the E1B 19K protein by viral infection, by transient expression, or in transformed cells completely and specifically blocks this TNF-alpha-induced DNA fragmentation and cell death. Cosegregation of 19K protein transforming activity with protection from TNF-alpha-mediated cytolysis demonstrates that both activities are likely the consequence of the same function of the protein. Therefore, we propose that by suppressing an intrinsic cell death mechanism activated by TNF-alpha or E1A, the E1B 19K protein enhances the transforming activity of E1A and enables adenovirus to evade TNF-alpha-dependent immune surveillance.

T-cell responsiveness to an oncogenic peripheral protein and spontaneous autoimmunity in transgenic mice

Why T cells develop autoimmune reactivity to some antigens and tolerance to others is unknown. Various mechanisms can provide for T-cell tolerance. These include deletion in the thymus, exhaustive differentiation in the periphery, T-cell receptor and coreceptor downregulation, and anergy. Which mechanisms normally provide for tolerance to antigens expressed on specific tissues and why they sometimes fail is unclear. To understand this, we analyzed how a tissue-specific protein with defined timing and location of expression is recognized by T cells so as to induce tolerance or autoimmunity. We crossed mice expressing the simian virus 40 large tumor antigen on pancreatic acini beginning 4-25 days after birth with mice transgenic for a rearranged T-cell receptor that recognizes this antigen presented by the class I major histocompatibility complex molecule H-2Kk. No T-cell tolerance was found; rather, T-cell reactivity accompanied lymphocytic infiltration and pancreatic acinar destruction. This result argues that T cells may become spontaneously autoreactive to certain postnatally expressed peripheral proteins and that this reactivity may lead to autoimmune disease.

The 10,400- and 14,500-dalton proteins encoded by region E3 of adenovirus function together to protect many but not all mouse cell lines against lysis by tumor necrosis factor

We have reported that the E3 14,700-dalton protein (E3 14.7K protein) protects adenovirus-infected mouse C3HA fibroblasts against lysis by tumor necrosis factor (TNF) (L. R. Gooding, L. W. Elmore, A. E. Tollefson, H. A. Brady, and W. S. M. Wold, Cell 53:341-346, 1988). We have also observed that the E1B 19K protein protects adenovirus-infected human but not mouse cells against TNF lysis (L. R. Gooding, L. Aquino, P. J. Duerksen-Hughes, D. Day, T. M. Horton, S. Yei, and W. S. M. Wold, J. Virol. 65:3083-3094, 1991). We now report that, in the absence of E3 14.7K, the E3 10.4K and E3 14.5K proteins are both required to protect C127 as well as several other mouse cell lines against TNF lysis. The 14.7K protein can also protect these cells from TNF in the absence of the 10.4K and 14.5K proteins. This protection by the 10.4K and 14.5K proteins was not observed in the C3HA cell line. These conclusions are based on 51Cr release assays of cells infected with virus E3 mutants that express the 14.7K protein alone, that express both the 10.4K and 14.5K proteins, and that delete the 14.7K in combination with either the 10.4K or 14.5K protein. The 10.4K protein was efficiently coimmunoprecipitated together with the 14.5K protein by using an antiserum to the 14.5K protein, suggesting that the 10.4K and 14.5K proteins exist as a complex in the infected mouse cells and consistent with the notion that they function in concert. Considering that three sets of proteins (E3 14.7K, E1B 19K, and E3 10.4K/14.5K proteins) exist in adenovirus to prevent TNF cytolysis of different cell types, it would appear that TNF is a major antiadenovirus defense of the host.

Sensitivity to tumour necrosis factor-mediated cytolysis is unrelated to manganous superoxide dismutase messenger RNA levels among transformed mouse fibroblasts

The ability of cells to resist the cytolytic actions of tumour necrosis factor (TNF) has been shown to require TNF-induced gene expression. It has been shown in some human cells that the gene encoding manganese superoxide dismutase (MnSOD), a TNF-induced gene, can provide resistance to TNF killing. Variation in the sensitivity to TNF was observed during subcloning of mouse SV40-transformed cell lines. This variation fell into three phenotypic classes. Cells were found that were either always resistant to TNF, always sensitive to TNF, and sensitive to TNF if inhibitors of transcription or translation were present. To determine if the regulation of MnSOD was responsible for the TNF sensitivity, Northern blot analysis was carried out. These experiments showed no correlation between expression and/or induction of the MnSOD mRNA and sensitivity or resistance to TNF. These data suggest that other pathways and gene products must therefore play a role for cells to resist TNF-mediated cellular lysis.

Specificity of the mouse cytotoxic T lymphocyte response to adenovirus 5. E1A is immunodominant in H-2b, but not in H-2d or H-2k mice

The Ag specificity and MHC restriction of the CTL response to adenovirus 5 (Ad5) in three strains of mice, C57BL/10 (H-2b), BALB/c (H-2d), and C3H/HeJ (H-2k), were tested. Polyclonal Ad5-specific CTL were prepared by priming mice in vivo with live Ad5 virus followed by secondary in vitro stimulation of the spleen cells with virus-infected syngeneic cells. The Ad5-specific CTL were Db restricted in C57BL/10 and Kk restricted in C3H/HeJ. In BALB/c mice both Kd- and Dd/Ld-restricted CTL were detected. The polyclonal Ad5-specific CTL response in C57BL/10 mice is directed exclusively against the products of the E1A region, which comprises only 5% of the Ad5 genome. In BALB/c mice E1A is at best a very minor target Ag and in C3H/HeJ mice E1A is not recognized at all. Using the H-2 congenic mouse strains B10.BR (H-2k) and C3H.SW (H-2b) it was shown that the immunodominance of E1A is H-2 dependent. The 19-kDa glycoprotein encoded in the E3 region of Ad5, which binds to class I MHC in the endoplasmic reticulum and prevents its translocation to the cell surface, does not affect the specificity of the CTL response in C57BL/10 mice toward E1A. However, it affects the MHC restriction of the Ad5-specific response in BALB/c mice, selectively inhibiting generation of Kd-restricted CTL.

Specificity of the mouse cytotoxic T lymphocyte response to adenovirus 5. E1A is immunodominant in H-2b, but not in H-2d or H-2k mice

The Ag specificity and MHC restriction of the CTL response to adenovirus 5 (Ad5) in three strains of mice, C57BL/10 (H-2b), BALB/c (H-2d), and C3H/HeJ (H-2k), were tested. Polyclonal Ad5-specific CTL were prepared by priming mice in vivo with live Ad5 virus followed by secondary in vitro stimulation of the spleen cells with virus-infected syngeneic cells. The Ad5-specific CTL were Db restricted in C57BL/10 and Kk restricted in C3H/HeJ. In BALB/c mice both Kd- and Dd/Ld-restricted CTL were detected. The polyclonal Ad5-specific CTL response in C57BL/10 mice is directed exclusively against the products of the E1A region, which comprises only 5% of the Ad5 genome. In BALB/c mice E1A is at best a very minor target Ag and in C3H/HeJ mice E1A is not recognized at all. Using the H-2 congenic mouse strains B10.BR (H-2k) and C3H.SW (H-2b) it was shown that the immunodominance of E1A is H-2 dependent. The 19-kDa glycoprotein encoded in the E3 region of Ad5, which binds to class I MHC in the endoplasmic reticulum and prevents its translocation to the cell surface, does not affect the specificity of the CTL response in C57BL/10 mice toward E1A. However, it affects the MHC restriction of the Ad5-specific response in BALB/c mice, selectively inhibiting generation of Kd-restricted CTL.

The E1B 19,000-molecular-weight protein of group C adenoviruses prevents tumor necrosis factor cytolysis of human cells but not of mouse cells

Tumor necrosis factor (TNF) is a multifunctional immunoregulatory protein that is secreted by activated macrophages and is believed to have antiviral activities. We reported earlier that when mouse C3HA fibroblasts are infected with human adenoviruses, the 289R and 243R proteins encoded by region E1A render the cells susceptible to lysis by TNF, and a 14,700-molecular-weight protein (14.7K protein) encoded by region E3 protects the cells against lysis by TNF. We now report that the 19,000-molecular-weight (19K) (176R) protein encoded by the E1B transcription unit can protect human HEL-299 fibroblasts and human ME-180 cervical carcinoma cells against lysis by TNF. This was determined by infecting cells with adenovirus double mutants that lack region E3 and do or do not express the E1B-19K protein and by measuring cytolysis by using a short-term (18-h) 51Cr-release assay. Under these assay conditions, the 51Cr release was specific to TNF and was not a consequence of the cyt phenotype associated with E1B-19K protein-negative mutants. Also, by using virus double mutants that lack E3 in combination with other early regions, we found that E1A, the E1B-55K protein-encoding gene, E3, and E4 are not required to protect HEL-299 cells against TNF cytolysis. Three additional human cancer cell lines (HeLa, HCT8, and RC29) and a simian virus 40-transformed WI38 cell line (VA-13) also required E1B for protection against TNF cytolysis, indicating that the E1B-19K protein is required to protect many if not all human cell types against lysis by TNF when infected by adenovirus. The E1B-19K protein was not able to protect six different adenovirus-infected mouse cell lines against TNF lysis, even though the protein was shown to be efficiently expressed in one of the cell lines. HEL-299 or ME-180 cells infected by a mutant that lacks the E1B-19K protein but retains region E3 were not lysed by TNF, indicating that one or more of the E3 proteins can protect these cells against TNF lysis in the absence of the E1B-19K protein. Thus, the E3-14.7K but not the E1B-19K protein can protect adenovirus-infected mouse cells against TNF cytolysis, whereas the E1B-19K protein as well as one or more of the E3 proteins can protect adenovirus-infected human cells against TNF cytolysis.

Adenovirus E3 14.7K protein functions in the absence of other adenovirus proteins to protect transfected cells from tumor necrosis factor cytolysis

A 14,700-kDa protein (14.7K) encoded by the E3 region of adenovirus has been shown to protect adenovirus-infected mouse C3HA cells from lysis by tumor necrosis factor (TNF) (L. R. Gooding, L. W. Elmore, A. E. Tollefson, H. A. Brady, and W. S. M. Wold, Cell 53:341-346, 1988). These infected cells are sensitized to TNF by expression of the adenovirus E1A proteins (P. Duerksen-Hughes, W. S. M. Wold, and L. R. Gooding, J. Immunol. 143:4193-4200, 1989). In this study we show that 14.7K suppresses TNF cytolysis independently of adenovirus infection. Mouse C3HA and C127 cells were transfected with the 14.7K gene controlled by the mouse metallothionein promoter, and permanent 14.7K-expressing cell lines were tested for sensitivity to TNF cytolysis. Transfected cells which were sensitized to TNF either by inhibitors of protein synthesis, microfilament-destabilizing agents, or adenovirus infection were found to be resistant to TNF cytolysis. Two monoclonal antibodies were isolated and used to quantitate 14.7K in transfected and infected cells. Enzyme-linked immunosorbent assay (ELISA) analysis with these monoclonal antibodies and 14.7K immunoblots showed that 14.7K expression can be induced with cadmium in C3HA and C127 transfectants. The 14.7K induction correlated with a dose-dependent decrease in sensitivity to TNF cytotoxicity. The 14.7K protein does not substantially alter cell surface TNF receptor numbers or affinity on C3HA mouse fibroblasts, as determined by Scatchard analysis of 125I-TNF binding. The 14.7K protein also does not alter TNF signal transduction in general, because TNF induction of cell surface class I major histocompatibility complex molecules on 14.7K transfectants was unmodified. Our findings indicate that the adenovirus 14.7K protein functions as a specific inhibitor of TNF cytolysis in the absence of other adenovirus proteins and thus is a unique tool to study the mechanism of TNF cytotoxicity.

The amino-terminal portion of CD1 of the adenovirus E1A proteins is required to induce susceptibility to tumor necrosis factor cytolysis in adenovirus-infected mouse cells

Previous work by our laboratory and others has shown that mouse cells normally resistant to tumor necrosis factor can be made sensitive to the cytokine by the expression of adenovirus E1A. The E1A gene can be introduced by either infection or transfection, and either of the two major E1A proteins, 289R or 243R, can induce this sensitivity. The E1A proteins are multifunctional and modular, with specific domains associated with specific functions. Here, we report that the CD1 domain of E1A is required to induce susceptibility to tumor necrosis factor cytolysis in adenovirus-infected mouse C3HA fibroblasts. Amino acids C terminal to residue 60 and N terminal to residue 36 are not necessary for this function. This conclusion is based on 51Cr-release assays for cytolysis in cells infected with adenovirus mutants with deletions in various portions of E1A. These E1A mutants are all in an H5dl309 background and therefore they lack the tumor necrosis factor protection function provided by the 14.7-kilodalton (14.7K) protein encoded by region E3. Western blot (immunoblot) analysis indicated that most of the mutant E1A proteins were stable in infected C3HA cells, although with certain large deletions the E1A proteins were unstable. The region between residues 36 and 60 is included within but does not precisely correlate with domains in E1A that have been implicated in nuclear localization, enhancer repression, cellular immortalization, cell transformation in cooperation with ras, induction of cellular DNA synthesis and proliferation, induction of DNA degradation, and binding to the 300K protein and the 105K retinoblastoma protein.

The adenovirus E3-14.7K protein is a general inhibitor of tumor necrosis factor-mediated cytolysis

We have previously described a 14,700 m.w. protein (14.7K) encoded by the E3 region of adenovirus that prevents TNF-mediated cytolysis of adenovirus-infected C3HA mouse fibroblasts. In the studies described here we have extended our analysis of TNF cytolysis of C3HA cells and the circumstances under which 14.7K protects these cells from cytolysis. C3HA cells were killed by TNF in the presence of inhibitors of protein synthesis, in the presence of cytochalasin E (which disrupts the microfilaments), and when adenovirus E1A was expressed. As described for other cell types, pretreatment of C3HA cells with TNF prevented cytolysis by TNF plus cycloheximide or TNF plus cytochalasin E, indicating that TNF induces a response that protects against these treatments. Remarkably, when 14.7K was expressed in virus-infected cells, it also prevented TNF-induced lysis whether sensitivity to TNF was induced by inhibition of protein synthesis, disruption of the cytoskeleton by cytochalasin E, or expression of adenovirus E1A. The 14.7K protein also prevented TNF lysis of cells that are spontaneously sensitive to TNF lysis. Thus, 14.7K appears to be a general inhibitor of TNF cytolysis, and as such should be an important tool in unraveling the mechanism of TNF cytolysis. There was one exception; NCTC-929 cells were spontaneously sensitive to TNF lysis and that lysis was not affected by 14.7K even though the protein was made in large quantities and was metabolically stable in these cells. This suggests that there is heterogeneity among TNF-sensitive cell lines. The 14.7K protein was found in both the nuclear and cytosol fractions of TNF resistant as well as all spontaneously sensitive cells suggesting that 14.7K may have more than one site of action within the cell.

Induction of the heat shock response protects cells from lysis by tumor necrosis factor

A minority of transformed cell lines are directly susceptible to lysis by TNF, whereas many cells can be made sensitive to TNF by treatment with inhibitors of protein synthesis. Other groups have shown that exposure to TNF induces in many cells a transcription/translation dependent response that protects the cell from TNF lysis. Heat shock proteins are involved in protecting cells from the lethal affects of heat and other metabolic poisons. In this report, we test the possibility that heat shock proteins are also involved in protecting cells from lysis by TNF. We find that after induction of the cellular heat shock response by either heat or arsenite treatment, both spontaneously TNF-sensitive cells and those cells made sensitive by inhibition of protein synthesis are nearly completely protected from TNF cytolysis. The heat-treated cells retained most of their capacity to bind TNF, suggesting that heat shock functions at a postreceptor binding phase of the lytic process. Mouse C3HA fibroblasts are also made sensitive to TNF lysis by treatment with cytochalasin E. We have previously found that elicitation of the cell's TNF-protective response by exposure to TNF suppresses killing of C3HA by subsequent treatment with TNF plus cytochalasin E. In contrast, we report here that induction of the heat shock response did not provide significant protection to C3HA from killing by TNF in the presence of cytochalasin E. Thus, although induction of heat shock proteins does protect cells from TNF, they appear to act by a mechanism distinct from that elicited by TNF itself.

Induction of the heat shock response protects cells from lysis by tumor necrosis factor

A minority of transformed cell lines are directly susceptible to lysis by TNF, whereas many cells can be made sensitive to TNF by treatment with inhibitors of protein synthesis. Other groups have shown that exposure to TNF induces in many cells a transcription/translation dependent response that protects the cell from TNF lysis. Heat shock proteins are involved in protecting cells from the lethal affects of heat and other metabolic poisons. In this report, we test the possibility that heat shock proteins are also involved in protecting cells from lysis by TNF. We find that after induction of the cellular heat shock response by either heat or arsenite treatment, both spontaneously TNF-sensitive cells and those cells made sensitive by inhibition of protein synthesis are nearly completely protected from TNF cytolysis. The heat-treated cells retained most of their capacity to bind TNF, suggesting that heat shock functions at a postreceptor binding phase of the lytic process. Mouse C3HA fibroblasts are also made sensitive to TNF lysis by treatment with cytochalasin E. We have previously found that elicitation of the cell's TNF-protective response by exposure to TNF suppresses killing of C3HA by subsequent treatment with TNF plus cytochalasin E. In contrast, we report here that induction of the heat shock response did not provide significant protection to C3HA from killing by TNF in the presence of cytochalasin E. Thus, although induction of heat shock proteins does protect cells from TNF, they appear to act by a mechanism distinct from that elicited by TNF itself.

The adenovirus E3-14.7K protein is a general inhibitor of tumor necrosis factor-mediated cytolysis

We have previously described a 14,700 m.w. protein (14.7K) encoded by the E3 region of adenovirus that prevents TNF-mediated cytolysis of adenovirus-infected C3HA mouse fibroblasts. In the studies described here we have extended our analysis of TNF cytolysis of C3HA cells and the circumstances under which 14.7K protects these cells from cytolysis. C3HA cells were killed by TNF in the presence of inhibitors of protein synthesis, in the presence of cytochalasin E (which disrupts the microfilaments), and when adenovirus E1A was expressed. As described for other cell types, pretreatment of C3HA cells with TNF prevented cytolysis by TNF plus cycloheximide or TNF plus cytochalasin E, indicating that TNF induces a response that protects against these treatments. Remarkably, when 14.7K was expressed in virus-infected cells, it also prevented TNF-induced lysis whether sensitivity to TNF was induced by inhibition of protein synthesis, disruption of the cytoskeleton by cytochalasin E, or expression of adenovirus E1A. The 14.7K protein also prevented TNF lysis of cells that are spontaneously sensitive to TNF lysis. Thus, 14.7K appears to be a general inhibitor of TNF cytolysis, and as such should be an important tool in unraveling the mechanism of TNF cytolysis. There was one exception; NCTC-929 cells were spontaneously sensitive to TNF lysis and that lysis was not affected by 14.7K even though the protein was made in large quantities and was metabolically stable in these cells. This suggests that there is heterogeneity among TNF-sensitive cell lines. The 14.7K protein was found in both the nuclear and cytosol fractions of TNF resistant as well as all spontaneously sensitive cells suggesting that 14.7K may have more than one site of action within the cell.

A 6700 MW membrane protein is encoded by region E3 of adenovirus type 2

There is an open reading frame between ATG1022 and TGA1205 in the E3 transcription unit of adenovirus 2 that could encode a protein of MW 6700 (6.7K) (61 amino acids). To address whether this protein is expressed, we prepared an antiserum against a synthetic peptide corresponding to residues 47-61 in the 6.7K protein. This antiserum immunoprecipitated two series of protein bands, a 7K-8K doublet and a 15K-16K doublet or triplet, as observed by electrophoresis on 10-18% gradient SDS-polyacrylamide gels. These bands were not obtained from cells infected with mutants that lack the 6.7K gene. Most, if not all, of the 7K-8K and 15K-16K bands were detected by immunoblot, indicating that they are modified versions of the 6.7K protein. Only an 8K band was observed after cell-free translation of hybridization-purified mRNA, suggesting that this may be the primary translation product. As judged by DNA sequence, the 6.7K protein has a hydrophobic domain of at least 22 residues (residues 16-37), suggesting that 6.7K may be a membrane protein. Consistent with this, the 7K-8K and 15K-16K bands were observed in the crude membrane but not the cytosol or nuclear fractions of biochemically fractionated cells. The 6.7K protein was underproduced by mutants which underproduce E3 mRNAs a and c, indicating that 6.7K is translated from these mRNAs. Since the E3-gp 19K protein is also translated from mRNAs a and c, these mRNAs are bicistronic. The 6.7K protein is well-conserved in Ad5 (Ad2 and Ad5 are group C adenoviruses), and appears to be marginally conserved in Ad3 (group B).

Large T antigens of many polyomaviruses are able to form complexes with the retinoblastoma protein

Stable protein complexes between the large T antigens of mouse, monkey, baboon, or human polyomaviruses and the retinoblastoma protein were detected by an in vitro coimmunoprecipitation assay. All of the large T antigens tested were able to bind to both human and mouse retinoblastoma polypeptides, showing that these interactions have been conserved during evolution.

A protein serologically and functionally related to the group C E3 14,700-kilodalton protein is found in multiple adenovirus serotypes

A 14.7-kilodalton protein (14.7K protein) encoded by the E3 region of group C adenoviruses has been shown to protect virus-infected fibroblasts from lysis by tumor necrosis factor (TNF) (L.R. Gooding, L.W. Elmore, A.E. Tollefson, H.A. Brady, and W.S.M. Wold, Cell 53:341-346, 1988). In this study we show that adenoviruses of other groups are also protected from TNF-induced cytolysis. Representative serotypes of groups A, B, D, and E produce a protein analogous to the 14.7K protein found in human group C adenoviruses. Deletion of this protein in group C viruses permits virus infection to induce cellular susceptibility to TNF killing. As with group C adenoviruses, cells infected with wild-type adenoviruses of other serotypes are not killed by TNF and are protected from lysis induced by TNF plus cycloheximide. However, cells are susceptible to TNF-induced lysis when infected with adenovirus type 4 mutants from which the 14.7K gene has been deleted. Although all known adenovirus serotypes infect epithelial cells, adenoviruses cause several diseases with various degrees of pathogenesis. Our findings suggest that the 14.7K protein provides a function required for the in vivo cytotoxicity of many adenoviruses independent of the site of infection or degree of pathogenesis.

A 14,500 MW protein is coded by region E3 of group C human adenoviruses

There is an ORF in the early region E3 transcription unit of human adenovirus 5 (Ad5) which could encode a protein of 14,500 MW (14.5K). This ORF is conserved in Ad5 and Ad2, both group C adenoviruses, and also in Ad3 and Ad7, both group B adenoviruses. To address whether the 14.5K protein is synthesized, we prepared antisera against synthetic peptides corresponding to residues 19-34 or 118-132 in the Ad5 version of 14.5K, and also against a TrpE-14.5K fusion protein expressed in Escherichia coli. These antisera immunoprecipitated the [35S]Met-labeled 14.5K protein from KB cells infected with rec700 (an Ad5-Ad2-Ad5 recombinant), Ad2, and a variety of E3 mutants. Mutants in the 14.5K ORF did not produce the 14.5K protein. The 14.5K is coded in large part, although probably not exclusively, by E3 mRNA f, as indicated by immunoprecipitation of 14.5K from cells infected with mutants that overproduce or underproduce mRNA f. The 14.5K migrated as five to six bands on SDS-PAGE after immunoprecipitation or Western blot, suggesting that it undergoes post-translational modification. Two bands of 14.5K were obtained by cell-free translation of 14.5K from mRNA purified by hybridization from infected cells.

Evidence that a target-derived soluble factor is necessary for the selective lysis of SV40-transformed fibroblasts by activated mouse macrophages

Our laboratory is investigating the basis for the selective recognition of transformed cells by activated mouse macrophages. As targets we are using a panel of SV40-transformed, C3H.OL fibroblast cell lines (SV-COL) that display widely different levels of sensitivity to lysis, from highly sensitive to completely resistant. Our results show that adding conditioned medium from the macrophage-sensitive target SV-COL-E8 (CM(E8] to a cytolysis assay with the macrophage-resistant target SV-COL-F5f causes the macrophages to kill the resistant targets in a contact dependent fashion. We have termed this activity "macrophage cell lysis factor" (MCLF). MCLF activity was not detected in conditioned media from cells not killed by activated macrophages (i.e., 3T3-like cell lines or embryo fibroblasts) but was present in conditioned media from six other SV-COL cell lines at levels that were directly proportional to the sensitivity of those targets (r = 0.98). These data suggest that MCLF plays a key role in determining the lytic sensitivity of SV40-transformed fibroblasts. Finally, to ask whether the production of MCLF is sufficient to explain the selective recognition of SV40-transformed fibroblasts by activated macrophages we have tested whether CM(E8) will cause macrophages to kill normal cells. Our results show that in the presence of CM(E8) macrophages will kill immortalized, 3T3-like fibroblasts but will not kill normal embryo fibroblasts. These results suggest that the production of MCLF, or a similar activity, is necessary but not sufficient for macrophage cytolysis to occur and that a change in target cell phenotype that occurs during the process of immortalization is also required.

Evidence that a target-derived soluble factor is necessary for the selective lysis of SV40-transformed fibroblasts by activated mouse macrophages

Our laboratory is investigating the basis for the selective recognition of transformed cells by activated mouse macrophages. As targets we are using a panel of SV40-transformed, C3H.OL fibroblast cell lines (SV-COL) that display widely different levels of sensitivity to lysis, from highly sensitive to completely resistant. Our results show that adding conditioned medium from the macrophage-sensitive target SV-COL-E8 (CM(E8] to a cytolysis assay with the macrophage-resistant target SV-COL-F5f causes the macrophages to kill the resistant targets in a contact dependent fashion. We have termed this activity "macrophage cell lysis factor" (MCLF). MCLF activity was not detected in conditioned media from cells not killed by activated macrophages (i.e., 3T3-like cell lines or embryo fibroblasts) but was present in conditioned media from six other SV-COL cell lines at levels that were directly proportional to the sensitivity of those targets (r = 0.98). These data suggest that MCLF plays a key role in determining the lytic sensitivity of SV40-transformed fibroblasts. Finally, to ask whether the production of MCLF is sufficient to explain the selective recognition of SV40-transformed fibroblasts by activated macrophages we have tested whether CM(E8) will cause macrophages to kill normal cells. Our results show that in the presence of CM(E8) macrophages will kill immortalized, 3T3-like fibroblasts but will not kill normal embryo fibroblasts. These results suggest that the production of MCLF, or a similar activity, is necessary but not sufficient for macrophage cytolysis to occur and that a change in target cell phenotype that occurs during the process of immortalization is also required.

Adenovirus E1A renders infected cells sensitive to cytolysis by tumor necrosis factor

TNF is a multifunctional protein that is secreted by activated macrophages and is believed to have antiviral properties. We reported previously that certain murine fibroblasts infected with group C human adenoviruses become sensitive to cytolysis by TNF, and that a 14,700 m.w. (14.7K) protein encoded by the E3 transcription unit protects the cells from TNF cytolysis. We now report the mapping of the adenovirus genes that induce sensitivity to TNF cytolysis. Experiments using hydroxyurea or 1-beta-D-arabinofuranosylcytosine showed that sensitivity is conferred by an early gene. Further mapping was done by infecting cells with double mutants that lack both the TNF protection function of the E3-14.7K protein and various other early genes and testing infected cells for TNF sensitivity. Using this method we found that none of the genes in regions E1B, E3, E4, or VA1-RNA are involved in creating the TNF-sensitive cellular phenotype. However, TNF did not lyse cells infected with dl312, an adenovirus mutant that lacks the 14.7K gene plus region E1A, suggesting that the E1A proteins are required to induce sensitivity to TNF. Mutants dl237 and 13SWT, which produce only the 12S (243R) or 13S (289R) E1A proteins, respectively, do render infected cells sensitive to TNF, indicating that both proteins provide this function. Finally, E1A-transfected cells, which are sensitive to TNF killing, do not become more sensitive when infected with dl312, thus indicating that E1A alone among adenovirus genes is responsible for the TNF susceptibility of infected cells.