The zinc finger region of the adenovirus E1A transactivating domain complexes with the TATA box binding protein

The 289R E1A protein of adenovirus transactivates a variety of viral and cellular promoters through protein-protein interactions. In earlier studies, mutational analyses of the E1A transactivating domain identified residues that are critical for transactivation and implied that the zinc finger region of the transactivating domain binds a transcription factor. Also, the E1A activation domain was found to bind to the TATA box binding protein (TBP) in vitro. Here, we tested the significance of the E1A-TBP interaction for E1A transactivation by analyzing the effects of conservative substitutions at each of the 49 residues of the E1A activation domain. Seven of the substitutions significantly diminished TBP binding in vitro. All of these were in the zinc finger region and were defective for transactivation in vivo. The perfect correlation between reduced TBP binding and transactivation argues strongly that a direct interaction between the E1A activation domain and TBP is critical to the mechanism of E1A activation. This genetic analysis leads us to further suggest that another factor, which is limiting, is also necessary for E1A-mediated transactivation.

The E1A products of oncogenic adenovirus serotype 12 include amino-terminally modified forms able to bind the retinoblastoma protein but not p300

The cell growth-regulating properties of the adenovirus type 5 (Ad5) E1A oncogene correlate closely with the binding of the E1A products to specific cellular proteins. These proteins include the products of the retinoblastoma tumor susceptibility gene and a 300-kDa product, p300. pRB binds to E1A sequences that are highly conserved among the E1A products of various serotypes, while p300 binding requires sequences in the E1A amino terminus, a region that is not highly conserved. To help evaluate the roles of the E1A-associated proteins in cell growth control, we have compared the p300-binding abilities of the E1A products of Ad5 and of the more oncogenic Ad12 serotype. We show here that despite encoding a sequence that varies somewhat from the p300-binding sequences of Ad5 E1A, the Ad12 E1A products associate with p300 with an affinity similar to that of the Ad5 E1A products. Both the 12S and 13S splice products of Ad12 E1A, like those of Ad5 E1A, encode proteins able to associate with p300. Interestingly, though, both also give rise to prominent forms that are amino terminally modified and unable to associate with p300. This modification, at least in the 13S product, does not appear to diminish the affinity of this product for the retinoblastoma protein.

Identification of a DNA-binding protein of human herpesvirus 6, a putative DNA polymerase stimulatory factor

A 41K early nuclear antigen (p41), expressed in human herpesvirus type 6 (HHV-6)-infected T cells, was cloned by screening a cDNA expression library with the anti-p41 monoclonal antibody (MAb) C5. When expressed in mammalian cells, the cloned p41 protein comigrated with the authentic p41 protein from HHV-6-infected cells and localized to the nucleus. HHV-6 p41 shares 44% sequence identity with the human cytomegalovirus (HCMV) DNA-binding protein, ICP36 (UL44 gene product); p41 binds to ssDNA with the same apparent affinity as ICP36. Since ICP36 has recently been shown to be an HCMV DNA polymerase-associated stimulatory factor, a similar function is suggested for p41.

Negative regulation of the major histocompatibility complex class I enhancer in adenovirus type 12-transformed cells via a retinoic acid response element

In cells transformed by the highly oncogenic adenovirus type 12 (Ad12), the viral E1A proteins mediate transcriptional repression of the major histocompatibility class I genes. In contrast, class I transcription is not reduced in cells transformed by the nononcogenic Ad5. The decreased rate of class I transcription is, at least in part, the result of a reduced major histocompatibility complex class I enhancer activity in Ad12-transformed cells and correlates with an increase in the levels of a DNA-binding activity to the R2 element of the enhancer (R. Ge, A. Kralli, R. Weinmann, and R. P. Ricciardi, J. Virol. 66:6969-6978, 1992). Employing transient transfection assays, we now provide direct evidence that the R2 element can confer repression in Ad12- but not Ad5-transformed cells. Repression by R2 was observed only in the presence of the positive enhancer element R1 and was dependent on (i) the number of the R2 elements and (ii) the relative arrangement of R2 and R1 elements. The putative R2-binding repressor protein, R2BF, was similar in molecular weight and binding specificity to members of the thyroid hormone/retinoic acid (RA) receptor family. RA treatment abrogated the R2-mediated repression in Ad12-transformed cells and had no effect on the activity of R2/R1-containing promoters in Ad5-transformed cells. These results are consistent with the presence of an R2-binding repressor in Ad12-transformed cells. In the absence of RA, the repressor compromises enhancer activity by interfering with the activity of the positive cis element R1. RA treatment of Ad12-transformed cells may render the repressor inactive.

Down-regulation of the major histocompatibility complex class I enhancer in adenovirus type 12-transformed cells is accompanied by an increase in factor binding

In transformed cells, the E1A gene of adenovirus type 12 (Ad12) represses transcription of class I genes of the major histocompatibility complex. The tumorigenic potential of Ad12-transformed cells correlates with this diminished class I expression. In contrast, the E1A gene of the nontumorigenic Ad5 does not affect class I expression. We show here that a transfected reporter chloramphenicol acetyltransferase plasmid driven by an H-2K promoter (-1049 bp) was expressed at much lower levels in Ad12- than in Ad5-transformed mouse cells. Analysis of mutant constructs revealed that only 83 bp of H-2 DNA, consisting of the enhancer juxtaposed to the basal promoter, was sufficient for this differential expression. Whereas the H-2 basal promoter alone was somewhat less active in Ad12-transformed cells, the H-2 TATA box itself did not appear to be important. The H-2 enhancer proved to be the principal element in Ad12 E1A-mediated repression, since (i) substitution of the H-2 enhancer by simian virus 40 enhancers overcame the repression, and (ii) when juxtaposed to either its native or heterologous basal promoters, the H-2 enhancer was functional in Ad5- but not Ad12-transformed cells. Mobility shift assays showed that there is a DNA-binding activity to the 5' site (R2 element) of the enhancer that is significantly higher in Ad12- than in Ad5-transformed cells. These results suggest that decreased class I enhancer activity in Ad12-transformed cells may, at least in part, be due to the higher levels of an enhancer-specific factor, possibly acting as a repressor.

Conversion of the E1A Cys4 zinc finger to a nonfunctional His2,Cys2 zinc finger by a single point mutation

Trans-activation by the adenovirus E1A 289R protein requires a zinc finger defined by Cys-154, Cys-157, Cys-171, and Cys-174. Whereas individually replacing the four cysteine residues with serines resulted in a loss of transactivation, only three of the Cys----Ser mutants (C157S, C171S, and C174S) lost the ability to bind Zn(II). X-ray absorption fine structure analysis revealed that, in the wild-type protein, Zn(II) is coordinated by four cysteine residues whereas in the C154S mutant, Zn(II) is coordinated by two histidines and two cysteines. The mutant protein probably retains, as ligands, two cysteines on the right side of the zinc finger (Cys-171 and Cys-174) and recruits two of the four histidines on the left side (His-149, His-152, His-158, and His-160), despite the presence of Cys-157. This finding may shed light on the general structural requirements of zinc fingers.

trans-dominant mutants of E1A provide genetic evidence that the zinc finger of the trans-activating domain binds a transcription factor

The 289R E1A protein of adenovirus stimulates transcription of early viral and certain cellular genes. trans-Activation requires residues 140 to 188, which encompass a zinc finger. Several studies have indicated that trans-activation by E1A is mediated through cellular transcription factors. In particular, the ability of the trans-dominant E1A point mutant hr5 (Ser-185 to Asn) to inhibit wild-type E1A trans-activation was proposed to result from the sequestration of a cellular factor. Using site-directed mutagenesis, we individually replaced every residue within and flanking the trans-activating domain with a conservative amino acid, revealing 16 critical residues. Six of the individual substitutions lying in a contiguous stretch C terminal to the zinc finger (carboxyl region183-188) imparted a trans-dominant phenotype. trans-Dominance was even produced by deletion of the entire carboxyl region183-188. Conversely, an intact finger region147-177 was absolutely required for trans-dominance, since second-site substitution of every critical residue in this region abrogated the trans-dominant phenotype of the hr5 protein. These data indicate that the finger region147-177 bind a limiting cellular transcription factor and that the carboxyl region183-188 provides a separate and essential function. In addition, we show that four negatively charged residues within the trans-activating domain do not comprise a distinct acidic activating region. We present a model in which the trans-activating domain of E1A binds to two different cellular protein targets through the finger and carboxyl regions.

Human melanoma cells transcribe interleukin 1 genes identical to those of monocytes

Two molecular species of the pleotropic cytokine interleukin 1 (IL-1) are produced as products of two distinct genes transcribed by cells of the monocyte-macrophage lineage. We have shown previously that a significant proportion of human melanoma cell lines express IL-1 biological activity, but it has not been demonstrated that this activity is the same as authentic monocyte IL-1 alpha and -beta. Here we report the cloning and sequencing of IL-1 complementary DNAs from a metastatic melanoma cell line and demonstrate that they encode bona fide IL-1 alpha and IL-1 beta. In addition, IL-1 complementary DNAs encoding a different amino acid at position 145 were revealed.

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.

An adenovirus recombinant that expresses the human cytomegalovirus major envelope glycoprotein and induces neutralizing antibodies

The gene of the human cytomegalovirus (HCMV) major envelope glycoprotein, gB, was cloned from the Towne strain and inserted into adenovirus type 5 downstream of the E3 promoter. The recombinant virus, Ad-gB, expressed antigenically related proteins of 58, 30, 25, and 23 kDa in A549 and MRC-5 cells; the 58-kDa protein had the same mobility as the native gB from HCMV-infected MRC-5 cells and virions. All four proteins were detected by a monospecific polyclonal antiserum and by a monoclonal antibody in immunoblot and immunofluorescence assays. Hamsters infected intranasally with live Ad-gB developed protein-specific and HCMV-neutralizing antibody. This study confirms the importance of gB in the generation of the neutralizing immune response to HCMV and demonstrates the potential of live adenoviruses as vaccine vectors.

Murine cell lines stably expressing the influenza virus hemagglutinin gene introduced by a recombinant retrovirus vector are constitutive targets for MHC class I- and class II-restricted T lymphocytes

A retrovirus vector containing the hemagglutinin (HA) gene of influenza virus was constructed and used to infect murine cell lines of fibroblast, mastocytoma and B cell lineages which are able to present antigens to MHC-restricted T cells. Stable cell lines were selected in which the retrovirus vector integrated as a single copy in almost all of the individual cell clones examined. The HA mRNA was shown to be of the expected length by Northern blot analysis, but the levels varied among the cell clones. Although the HA transcript was difficult to detect in any of the retrovirus-infected cell clones derived from fibroblasts, HA Ag was easily detected on the cell surface by cytofluorographic analysis. Significantly, retrovirus-infected clones derived from each cell type were recognized by HA-specific class I and class II MHC-restricted T lymphocytes. HA produced in these cells was able to be acquired, processed, and presented to class II-restricted T cells by additional, non-HA-expressing APC. This indicates that HA endogenously synthesized within these cell lines is available for Ag processing by an exogenous route.

Murine cell lines stably expressing the influenza virus hemagglutinin gene introduced by a recombinant retrovirus vector are constitutive targets for MHC class I- and class II-restricted T lymphocytes

A retrovirus vector containing the hemagglutinin (HA) gene of influenza virus was constructed and used to infect murine cell lines of fibroblast, mastocytoma and B cell lineages which are able to present antigens to MHC-restricted T cells. Stable cell lines were selected in which the retrovirus vector integrated as a single copy in almost all of the individual cell clones examined. The HA mRNA was shown to be of the expected length by Northern blot analysis, but the levels varied among the cell clones. Although the HA transcript was difficult to detect in any of the retrovirus-infected cell clones derived from fibroblasts, HA Ag was easily detected on the cell surface by cytofluorographic analysis. Significantly, retrovirus-infected clones derived from each cell type were recognized by HA-specific class I and class II MHC-restricted T lymphocytes. HA produced in these cells was able to be acquired, processed, and presented to class II-restricted T cells by additional, non-HA-expressing APC. This indicates that HA endogenously synthesized within these cell lines is available for Ag processing by an exogenous route.

Fusion of adenovirus E1A to the glucocorticoid receptor by high-resolution deletion cloning creates a hormonally inducible viral transactivator

The 289-amino-acid E1A protein of adenovirus type 2 stimulates transcription from early viral and certain cellular promoters. Its mechanism is not known, and there exist no temperature-sensitive mutants of E1A that could help to elucidate the details of E1A transcriptional activation. To create for E1A such a conditional phenotype, we fused portions of E1A to the human glucocorticoid receptor (GR) to make transactivation by E1A dependent on the presence of dexamethasone. Nested subsets of the E1A coding region, centered around the 46-amino-acid transactivating domain, were substituted for the DNA-binding domain of the GR. One of the resulting chimeric proteins (GR/E1A-99), which included the entire E1A transactivating domain, stimulated expression from a viral early promoter (E3) exclusively in the presence of hormone. GR/E1A-99 did not transactivate a GR-responsive promoter. It therefore exhibited the promoter specificity of E1A while possessing the hormone inducibility of the GR. Two smaller chimeras that contained only portions of the E1A transactivating domain failed to transactivate E3. These three chimeras were constructed by a novel strategy, high-resolution deletion cloning. In this procedure, series of unidirectional deletions were made with exonuclease III on each side of the E1A coding region at a resolution of 1 to 2 nucleotides. The large number of in-frame fragments present in the collection of deleted clones facilitated the construction of the GR/E1A chimeras and can be used to create many additional fusions.

An element of the BK virus enhancer required for DNA replication

The human papovavirus BK virus contains three 68-base-pair (bp) repeats that act as transcriptional enhancers. An analysis of plasmids containing the BK virus origin revealed that sequences within the 68-bp enhancer are required for DNA replication as well as transcription of the early promoter in COS-1 cells. Origins with a single 68-bp repeat replicated as efficiently as did those with three repeats when transfected into COS-1 cells. Replication did not occur in the absence of enhancer sequences and could not be restored by distal placement of enhancers to enhancerless origins. However, as with simian virus 40, replication in vitro was not dependent on the presence of any enhancer sequences. Deletion analysis showed that replication of BK virus origins was dependent on the presence of the first 21 bp of the enhancer contiguous with the A-T-rich stretch of the origin. This 21-bp element is referred to as the rep element. Although in combination with rep the remaining 47 bp of the enhancer appear to increase replication by two- to fivefold, they alone are not sufficient to support replication. Deletions or insertions in the enhancer which did not alter the rep element had no major effect on replication. Site-directed mutagenesis of the Sp1-like site within the rep element, the NF1 site present in the enhancer, or the NF1 site in adjacent late-side sequences each reduced transcription by two- to fivefold, but had no effect on replication, suggesting that replication and transcription can be uncoupled.

Modulation of major histocompatibility complex (MHC) class I genes in adenovirus 12 transformed cells: interferon-gamma increases class I expression by a mechanism that circumvents E1A induced-repression and tumor necrosis factor enhances the effect of interferon-gamma

The protein products of the E1A gene of adenovirus type-12 (Ad12) block transcription of major histocompatibility (MHC) class I genes in both rodent and human transformed cells and interferon-gamma (IFN-gamma) is able to override this repression. Although IFN-gamma is known to stimulate class I transcription, we investigated whether its dominance over E1A repression could alternatively result from the ability of this cytokine to induce antiviral mechanisms. We show that this is not so, since the accumulation of Ad12 E1A mRNA and protein are unabated in the presence of IFN-gamma. Also, tumor necrosis factor (TNF) was shown to act synergistically with IFN-gamma to enhance class I antigen levels, although it had little effect alone. These results suggest that the normal pathway by which IFN-gamma acts to enhance the level of class I mRNAs, circumvents the block by which E1A represses class I transcription.

Molecular cloning and characterization of an antigen associated with early stages of melanoma tumor progression

The melanoma-associated antigen ME491 is expressed strongly during the early stages of tumor progression. The ME491 gene was molecularly cloned by means of DNA-mediated gene transfer followed by screening a lambda genomic library with human repetitive Alu sequences as a probe. The cloned DNA, after transfection into mouse L-cells, generated a protein with characteristics that were indistinguishable in Western blot analysis from the ME491 antigen expressed by human melanoma cells. Repeat-free subfragments of the cloned DNA were used for further studies. By Northern blot analysis, the subfragments detected a single 1.2-kilobase mRNA in the transformants and various human melanoma cell lines. ME491 complementary DNA clones were then obtained by probing a melanoma complementary DNA library with the genomic subfragments. Nucleotide sequence analysis of the cloned complementary DNA indicated that the ME491 antigen consists of 237 amino acids (Mr 25,475) with four transmembrane regions and three putative N-glycosylation sites. No significant structural homology was observed with other proteins thus far reported. We observed that the amounts of mRNA varied greatly with different melanoma cell lines. Southern blot analysis revealed no amplification or rearrangement of the ME491 gene in the human melanoma cell lines tested, including both high and low expressors of this antigen. The ME491 gene has been mapped to chromosome region 12p12----12q13 by somatic cell hybrid analysis and more narrowly localized to 12q12----12q14 by in situ hybridization.

An adenovirus mRNA which encodes a 14,700-Mr protein that maps to the last open reading frame of region E3 is expressed during infection

The E3 regions of adenovirus types 2 and 5, respectively, are known to synthesize proteins of 19,000 Mr (19K) and 11.6K, but information regarding the identity and characterization of other potential E3 proteins encoded by the six remaining open reading frames (ORFs) is lacking. In this study, we show that the last ORF of region E3, which encodes a 14.7K protein, is expressed in adenovirus-infected cells. This information was largely derived from analysis of an E3 deletion mutant (H2dl801) in which an extensive deletion (1,939 base pairs) was found to eliminate all ORFs except for two proteins of 12.5K and 14.7K. The 14.7K protein was translated from RNA isolated from H2dl801-infected cells that had been hybridization selected to E3 DNA; hybridization-selected RNA from wild-type adenovirus type 5-infected cells translated both the 19K and the 14.7K proteins. Moreover, an antiserum directed against a bacterial 14.7K fusion protein (A. E. Tollefson and W. S. M. Wold, J. Virol. 62:33-39, 1988) immunoprecipitated the 14.7K translation product synthesized by wild-type and mutant H2dl801 adenovirus mRNAs.

Expression of hepatitis B surface antigen in human cells by a recombinant BK virus DNA vector

The construction of the first stable human cell lines that express and secrete authentic hepatitis B virus surface antigen (HBsAg), using a BK virus (BKV) episomal plasmid vector, is described. The amount of HBsAg produced by BKV vectors (up to 600 ng/10(7) cells) was comparable to other eukaryotic vector systems. The level of HBsAg expression remained the same regardless of the orientation of the HBsAg gene, substitution of the HBsAg gene promoter with the mouse metallothionein I gene promoter or the tissue origin of the human cell lines used to establish stable cellular transformants. Northern blot analysis also indicated synthesis of normal HBsAg transcripts. Surprisingly, however, the vectors were maintained at far lower than expected copy number (one to five copies/cell). Reasons for this are discussed.

CTL recognition of adenovirus-transformed cells infected with influenza virus: lysis by anti-influenza CTL parallels adenovirus-12-induced suppression of class I MHC molecules

We examined the ability of influenza-specific cytotoxic T lymphocytes to lyse adenovirus-transformed cells infected with influenza virus. Cytotoxic T lymphocyte lysis of Ad12-transformed cells was greatly reduced relative to that of Ad5-transformed cells. Lysability of adenovirus-12-transformed cells was restored in parallel with interferon-gamma induced increases in major histocompatibility complex class I gene products. These findings establish that recognition of foreign molecules by self-restricted cytotoxic T lymphocytes is reduced in adenovirus-12-transformed cells. This provides further evidence that Ad12 tumorigenicity is related to its ability to suppress class I major histocompatability complex molecule expression thereby avoiding recognition by the host immune system.

Detailed kinetics of adenovirus type-5 steady-state transcripts during early infection

The appearance and steady-state accumulation of specific viral RNAs during the early phase of adenovirus type 5 (Ad5) infection was examined. HeLa cells were synchronously infected and harvested at 30 min intervals throughout the first 12 h of infection. Total cytoplasmic RNA was extracted from infected cells and analyzed by hybridization-selection and translation to identify the viral mRNAs from each early region on the basis of the protein products they encode. The same RNA samples were used for S-1 nuclease and Northern blot analyses to quantitatively compare the levels of individual viral RNAs that accumulate within each early transcription region (E1A, E1B, L1, E2A, E3 and E4). The salient features of this analysis show that RNA accumulation occurs first from E1A followed by E2A, E3 and E4, E1B and lastly, L1. Although the profile of RNA accumulation was unique for each early region, overlapping RNAs within E1A, E3, and E4, respectively, remained generally parallel to one another throughout early infection, in contrast to RNAs from E1B and L1, respectively. Since both the appearance and quantitative accumulation of specific early viral mRNAs were examined at many time points, a number of subtleties associated with the complex dynamics of early Ad5 gene expression were revealed. In particular, the L1 region was shown to transcribe from the major late promoter two early RNAs of 3.81 Kb and 3.5 Kb, either or both of which encode the 52,55 kDa proteins; the auxiliary i leader sequence was found on the 3.81 Kb RNA but not on the 3.5 Kb RNA.

An adenovirus type 5 E1A protein with a single amino acid substitution blocks wild-type E1A transactivation

The E1A gene of adenovirus type 5 encodes a 289-amino-acid (289R) protein that transactivates early adenovirus promoters. We showed that the 289R protein of the E1A missense mutant gene hr5 is novel in that it inhibits the wild-type (wt) E1A protein from stimulating transcription from each of the early viral promoters E2, E3, and E4. Since both the hr5 and wt genes produced similar levels of E1A proteins, the ability of hr5 E1A to block transactivation was attributed to the replacement of serine by asparagine as position 185. We confirmed that this single amino acid substitution was responsible for blocking transactivation by showing equal inhibition with an hr5-wt hybrid E1A gene containing this missense mutation as the only alteration. The smaller 243R E1A protein of hr5 was not necessary for inhibition. Transcriptional activity from each early promoter was inhibited by at least 50% when the hr5 and wt E1A genes were present in equimolar amounts; complete inhibition occurred with a fivefold molar excess of the hr5 gene. Two other E1A missense mutant genes (hr3 and hr4) with amino acid substitutions in close proximity to that of hr5 failed to block wt E1A-induced transcription when similarly tested. Also, the hr5 E1A gene failed to impede the pseudorabies immediate early gene from transactivating the adenovirus E3 promoter, demonstrating that hr5 E1A inhibits wt E1A activation at the transcriptional, rather than the posttranscriptional, level. Although several possibilities were considered to account for this inhibition, the most likely is that the nonfunctional hr5 E1A protein competes with the wt 289R protein for a cellular transcription factor required for transactivation.

Transactivation of BKV and SV40 early promoters by BKV and SV40 T-antigens

The early promoters of BKV and SV40 plasmids were transactivated in both BKV and SV40-transformed cells which failed to support replication of these plasmids. This suggests that the T-antigen of either virus can transactivate BKV and SV40 early promoters by either increasing the availability of cellular transcription factors or by directly interacting with specific sequences which comprise the transcriptional control region of the early promoters. We also observed that removal of 8-bp on the early side of T-antigen binding site I of BKV does not alter viral-plasmid replication.

Cellular protein differences between nontumorigenic Ad5 and tumorigenic Ad12 transformed mouse cells

Murine fibroblasts transformed by adenovirus 12 (Ad12) show reduced class I major histocompatibility complex (MHC) antigen synthesis and form tumors in syngeneic mice whereas those transformed by adenovirus 5 (Ad5) show no alteration in class I antigen synthesis and do not form tumors (K. B. Eager, J. Williams, D. Breiding, S. Pan, B. Knowles, E. Appella, and R. P. Ricciardi (1985) Proc. Natl. Acad. Sci. USA 82, 5525-5529). Nearly 1500 metabolically labeled polypeptides from the Ad5 and Ad12 transformed cell lines as well as polypeptides from a nontransformed murine line of the same haplotype were compared by two-dimensional gel electrophoresis. In addition to the reduction of the class I H-2 transplantation antigens seen in the Ad12-transformed lines, we detect few but reproducible polypeptide differences between the tumorigenic and nontumorigenic cell lines.

Adenovirus type 12 early region 1A proteins repress class I HLA expression in transformed human cells

The adenovirus type 12 (Ad12) early region 1A (E1A) gene is thought to play a major role in repressing class I major histocompatibility complex expression in transformed rodent cells. However, since transformation by adenovirus requires both E1A and E1B genes, it has not been demonstrated whether the Ad12 E1A gene acts alone or synergistically with the E1B gene to accomplish this effect. Moreover, it is not known whether the repression of class I antigen synthesis by Ad12-transforming gene products occurs only in rodent cells. We show that the Ad12 E1A gene, in the absence of the E1B gene, is capable of greatly reducing the levels of class I HLA antigens and mRNAs in primary human cells transformed by the E1A gene of Ad12 and the large tumor antigen (T-antigen) gene of BK virus; control cells transformed by BK virus T-antigen gene alone or the highly related simian virus 40 T-antigen gene showed no apparent alteration in class I HLA expression. Human recombinant interferon gamma was able to restore synthesis of class I HLA antigens in transformed cells that produced Ad12 E1A proteins, indicating that these cells were not deficient for class I genes. These results strongly indicate that the Ad12 E1A proteins modulate class I gene expression by similar mechanisms in both transformed rodent and human cells.