Activation of the double-stranded RNA (dsRNA)-activated human protein kinase in vivo in the absence of its dsRNA binding domain

The interferon-induced, dsRNA-activated human protein kinase (PKR) exerts antiviral and antiproliferative effects through inhibition of protein synthesis. Studies of structure-function relationships in PKR have shown that two dsRNA binding motifs are important for its autophosphorylation and activation by dsRNA in vitro. To correlate these findings with the activity of PKR in vivo, we examined the function of various PKR deletion mutants in cultured cells by using an inducible expression system. In a reporter gene assay, mutant forms of the kinase lacking amino acids 1-97 (delta 1-97) and 104-157 (delta 104-157), which are required for dsRNA binding in vitro, retained full activity in vivo. Deletion of amino acids 233-271 (delta 233-271), however, abolished the translational inhibitory activity of the kinase and prevented its phosphorylation. Moreover, cells infected with vaccinia virus recombinants expressing wild-type PKR, the mutant delta 104-157, delta 186-222), developed almost complete inhibition of both viral and cellular protein synthesis was upon induction of PKR. This inhibition of viral protein synthesis was not observed in cells infected with a recombinant expressing delta 233-271 mutant PKR. Our findings establish that the region encompassing amino acids 233-271 of PKR is critical for kinase activity in vivo, whereas its dsRNA binding domain is dispensable.

Structural features of adenovirus 2 virus-associated RNA required for binding to the protein kinase DAI

The double-stranded RNA activated protein kinase DAI contains an RNA binding domain consisting of two copies of a double-stranded RNA binding motif. We have investigated the role of RNA structure in the interaction between DAI and the structured single-stranded RNA, adenovirus VA RNAI, which inhibits DAI activation. Mutations in the apical stem, terminal stem, and central domain of the RNA were tested to assess the contribution of these elements to DAI binding in vitro. The data demonstrate that over half a turn of intact apical stem is required for the interaction and that there is a correlation between the binding of apical stem mutants and their ability to function both in vivo and in vitro. There was also evidence of preference for GC-rich sequence in the proximal region of the apical stem. In the central domain the correlation between binding and function of mutant RNAs was poor, suggesting that at least some of this region plays no direct role in binding to DAI, despite its functional importance. Exceptionally, central domain mutations that encroached on the phylogenetically conserved stem 4 of VA RNA disrupted binding, and complementary mutations in this sequence partially restored binding. Measurement of the binding of wild-type VA RNAI to DAI and p20, a truncated form of the protein containing the RNA binding domains alone, under various ionic conditions imply that the major interactions are electrostatic and occur via the protein's RNA binding domain. However, differences between full-length DAI and p20 in their binding to mutants in the conserved stem suggest that regions outside the RNA binding domain also participate in the binding. The additional interactions are likely to be non-ionic, and may be important for preventing DAI activation during virus infection.

Trimeric structure of human proliferating cell nuclear antigen. Implications for enzymatic function and autoantibody recognition

The proliferating cell nuclear Ag (PCNA) is a DNA replication factor postulated to function as a sliding clamp around DNA. PCNA is also a target for autoimmunity in systemic lupus erythematosus. The autoantigenicity of PCNA is highly conformation-dependent, and reaction with most anti-PCNA sera requires a nearly full-length PCNA molecule. Here we describe the use of gel filtration and glycerol gradient sedimentation to analyze the native structure and size of PCNA. PCNA from three sources was studied (PCNA from HeLa cells, PCNA purified after its overexpression in bacteria, and PCNA produced in the wheat germ cell-free translation system) as well as mutant forms of PCNA translated in vitro. In each case, full-length PCNA behaved as a trimer. Analysis of mutant proteins revealed a correlation between the trimeric form and binding to the common type of human anti-PCNA autoantibody, suggesting that the Abs are specific for the active form of the protein. These findings are consistent with the idea that autoantibodies are generated as a response to native Ag and provide experimental support for the hypothesis that PCNA serves its processive function in DNA replication as a trimeric ring structure.

Trimeric structure of human proliferating cell nuclear antigen. Implications for enzymatic function and autoantibody recognition

The proliferating cell nuclear Ag (PCNA) is a DNA replication factor postulated to function as a sliding clamp around DNA. PCNA is also a target for autoimmunity in systemic lupus erythematosus. The autoantigenicity of PCNA is highly conformation-dependent, and reaction with most anti-PCNA sera requires a nearly full-length PCNA molecule. Here we describe the use of gel filtration and glycerol gradient sedimentation to analyze the native structure and size of PCNA. PCNA from three sources was studied (PCNA from HeLa cells, PCNA purified after its overexpression in bacteria, and PCNA produced in the wheat germ cell-free translation system) as well as mutant forms of PCNA translated in vitro. In each case, full-length PCNA behaved as a trimer. Analysis of mutant proteins revealed a correlation between the trimeric form and binding to the common type of human anti-PCNA autoantibody, suggesting that the Abs are specific for the active form of the protein. These findings are consistent with the idea that autoantibodies are generated as a response to native Ag and provide experimental support for the hypothesis that PCNA serves its processive function in DNA replication as a trimeric ring structure.

Autoreactive epitope profiles of the proliferating cell nuclear antigen define two classes of autoantibodies

The proliferating cell nuclear antigen (PCNA) is a conserved protein required for cellular DNA replication. PCNA was first recognized using serum from the autoimmune disease SLE. To analyze the regions on PCNA that confer autoantibody binding, we modified the cDNA encoding full-length PCNA to generate a series of amino terminal, carboxyl terminal and internally deleted constructs, which were transcribed and then translated in vitro using the wheat germ cell-free translation system. An immunoprecipitation assay was used to study the ability of these mutated forms of PCNA to bind anti-PCNA Abs from patients with SLE. Eight of the ten sera studied required a protein of nearly full length for binding: antigenicity was abrogated by removal of 39 amino acids from the amino terminus, by various internal deletions, or by the removal of 15 (but not 11) amino acids from the carboxyl terminus. The remaining two sera exhibited an Ab-binding specificity to the carboxyl-terminally truncated proteins similar to that of the majority of anti-PCNA sera, but their specificity was different in the amino terminus: these sera were able to recognize PCNA lacking over 40% of sequence in the amino terminus, but they did not bind proteins with short internal deletions in that region. Thus, these epitopes appear to be conformational and distinguish two classes of autoimmune sera.

Autoreactive epitope profiles of the proliferating cell nuclear antigen define two classes of autoantibodies

The proliferating cell nuclear antigen (PCNA) is a conserved protein required for cellular DNA replication. PCNA was first recognized using serum from the autoimmune disease SLE. To analyze the regions on PCNA that confer autoantibody binding, we modified the cDNA encoding full-length PCNA to generate a series of amino terminal, carboxyl terminal and internally deleted constructs, which were transcribed and then translated in vitro using the wheat germ cell-free translation system. An immunoprecipitation assay was used to study the ability of these mutated forms of PCNA to bind anti-PCNA Abs from patients with SLE. Eight of the ten sera studied required a protein of nearly full length for binding: antigenicity was abrogated by removal of 39 amino acids from the amino terminus, by various internal deletions, or by the removal of 15 (but not 11) amino acids from the carboxyl terminus. The remaining two sera exhibited an Ab-binding specificity to the carboxyl-terminally truncated proteins similar to that of the majority of anti-PCNA sera, but their specificity was different in the amino terminus: these sera were able to recognize PCNA lacking over 40% of sequence in the amino terminus, but they did not bind proteins with short internal deletions in that region. Thus, these epitopes appear to be conformational and distinguish two classes of autoimmune sera.

Organizational effectiveness: the key to accountability for collegiate schools of nursing

This study describes the organizational effectiveness of collegiate nursing programs in terms of their ability to interact with their external environment. Nursing education administrators from 401 institutions were surveyed concerning their ability to secure resources and the degree of their system's openness and community interaction. Overall, with a response rate of 76.8 per cent, the administrators considered the availability of resources to be adequate and perceived their programs to be moderately successful in procuring resources. A categorical comparison of responses indicated that administrators in specialized/professional institutions identified a greater degree of richness in the availability of resources and perceived their programs to be more successful in procuring resources. However, a second categorical comparison found no statistically significant differences among administrators in their perception of system openness and community interaction. All administrators considered their environments cooperative, accepting, predictable, and stable.

Modulation of transcriptional activation of the proliferating cell nuclear antigen promoter by the adenovirus E1A 243-residue oncoprotein depends on proximal activators

Previous analyses defined a proliferating cell nuclear antigen (PCNA) E1A-responsive element (PERE) in the PCNA promoter that is essential for transactivation by the 243-residue product of the adenovirus type 2 E1A 12S mRNA (E1A 243R). In this report, we show that the PERE activates a heterologous basal promoter and confers susceptibility to transactivation by E1A 243R, indicating that the PERE is both necessary and sufficient for the response of the PCNA promoter to this oncoprotein. Insertion of linker sequences between the PERE and the site of transcription initiation in the PCNA promoter severely impairs the promoter's response to E1A 243R transactivation. GAL4 sites can replace the function of the PERE in the E1A 243R response of the PCNA basal promoter if transcriptional activators of suitable strength are supplied as GAL4 fusion proteins. Weak transcriptional activators render the PCNA basal promoter subject to transactivation by E1A 243R but do not endow the adenovirus E1B basal promoter with a similar response. Strong transcriptional activators do not support transactivation by E1A 243R, however; instead, E1A reduces the ability of the strong activators to activate both the PCNA and E1B basal promoters. Although other mechanistic differences might determine the response, the data imply a relationship between the activation strength of promoter-proximal effectors and the response of the PCNA basal promoter to E1A 243R. These experiments indicate that the PERE can function autonomously in mediating transactivation by E1A 243R and that the PCNA basal promoter is configured in a manner that permits modulation by E1A 243R of transcriptional activation by promoter-proximal effectors.

Two RNA-binding motifs in the double-stranded RNA-activated protein kinase, DAI

The protein kinase DAI, the double-stranded RNA-activated inhibitor of translation, is an essential component of the interferon-induced cellular antiviral response. The enzyme is regulated by the binding of activator and inhibitor RNAs. We synthesized DAI in vitro and located its RNA-binding domain within the amino-terminal 171 residues. This domain contains two copies of an RNA-binding motif characterized by a high density of basic amino acids, by the presence of conserved residues, and by a probable alpha-helical structure. Deletion of either of the two motifs prevents the binding of dsRNA, but their relative positions can be exchanged, suggesting that they cooperate to interact with dsRNA. Clustered point mutations within the RNA-binding motifs and duplications of the individual motifs indicate that the first copy of the motif plays the more important role. Mutations that impair binding have similar effects on the binding of double-stranded RNAs of various lengths and of adenovirus VA RNAI, implying that discrimination between activator and inhibitory RNAs takes place subsequent to RNA binding.

Comparative analysis of the structure and function of adenovirus virus-associated RNAs

The protein kinase DAI is an important component of the interferon-induced cellular defense mechanism. In cells infected by adenovirus type 2 (Ad2), activation of the kinase is prevented by the synthesis of a small, highly ordered virus-associated (VA) RNA, VA RNAI. The inhibitory function of this RNA depends on its structure, which has been partially elucidated by a combination of mutagenesis and RNase sensitivity analysis. To gain further insight into the structure and function of this regulatory RNA, we have compared the primary sequences, secondary structures, and functions of seven VA RNA species from five human and animal adenoviruses. The sequences exhibit variable degrees of homology, with a particularly close relationship between the VA RNAII species of Ad2 and Ad7 and notably divergent sequence for the avian (CELO) virus VA RNA. Apart from two pairs of mutually complementary tetranucleotides which are highly conserved, homologies are limited to transcription signals located within the RNA sequence and at its termini. Secondary structure analysis indicated that all seven RNAs conform to the model in which VA RNA possesses three main structural regions, a terminal stem, an apical stem-loop, and a central domain, although these elements vary in size and other details. The apical stem is implicated in binding to DAI, and the central domain is essential for inhibition of DAI activation. One of the pairs of conserved tetranucleotides (CCGG:C/UCGG) provides further evidence for the existence of the apical stem, but the other conserved pair (GGGU:ACCC) strongly suggests a revised structure for the central domain. In two functional assays conducted in vivo, the VA RNAI species of Ad2 and Ad7 were the most active, their corresponding VA RNAII species displayed little activity, and the single VA RNAs of Ad12 and simian adenovirus type 7 exhibited intermediate activity. Correlation of the structural and functional data suggests that the VA RNAII species adopt a structure different from those of the other VA RNA species and may play a different role in the life cycle of the virus.

Organization of the double-stranded RNA-activated protein kinase DAI and virus-associated VA RNAI in adenovirus-2-infected HeLa cells

We have examined the cellular distribution of the double-stranded RNA-activated protein kinase DAI in adenovirus 2 (Ad2)-infected and uninfected HeLa cells. In uninfected cells DAI was found to be concentrated in the cytoplasm. In addition, DAI was localized in the nucleoli and diffusely distributed throughout the nucleoplasm. Cells treated with alpha-interferon displayed a similar pattern of distribution for DAI. When RNA polymerase I activity was inhibited by the drug actinomycin D, nucleoli segregated and DAI was found to colocalize with the dense fibrillar region of the nucleoli. During mitosis, the distribution of DAI paralleled that of rRNA. In adenovirus-infected cells the localization of DAI was similar to that in uninfected interphase cells. VA RNAI was detected in Ad2-infected cells by 10–14 hours post-infection as fine dots in the nucleoplasm. By 18–24 hours post-infection, VA RNAI appeared in bigger and more abundant dots in the nucleoplasm and the cytoplasm was intensively labeled. Transient expression of the VA RNAI gene in uninfected cells resulted in a similar localization of the RNA. Our results are consistent with a role for DAI and VA RNAI in protein synthesis and suggest that DAI may play an early role in ribosome biogenesis in the nucleolus in addition to its cytoplasmic role in translation.

HIV-1 Tat overcomes inefficient transcriptional elongation in vitro

Tat, the transactivator protein encoded by HIV-1, acts in vivo to increase transcriptional initiation and stabilize elongation. We examined the effects of purified, bacterially-expressed Tat on HIV-1 transcription in a cell-free system. Tat specifically stimulated HIV-directed transcription 12-fold in HeLa cell nuclear extracts and this effect was principally due to increased transcriptional elongation. The degree of transactivation was greatest at later times during the transcription reaction when basal levels of transcription were reduced. At early times, the proportion of basal transcriptional complexes that elongate efficiently was high. Ongoing transcription increased the number of complexes requiring Tat for efficient elongation, possibly due to the activation of a repressor(s). To examine this hypothesis, the effects of the detergent Sarkosyl on HIV transcription were studied. Sarkosyl stimulated HIV-1 transcription to a level similar to that occurring in the presence of Tat alone by improving elongation. Transcription was elevated by Sarkosyl at concentrations inhibitory to reinitiation indicating that inefficient elongation is due to transcriptional pausing. Transcriptional stimulation by Sarkosyl was a general phenomenon as it was also observed with heterologous eukaryotic promoters. Tat was capable of stimulating elongation from a heterologous promoter when Tat binding was provided by a downstream TAR element. We propose that Tat acts as a general transcription factor whose binding at the promoter overcomes inefficient transcriptional elongation.

Mutational analysis of the central domain of adenovirus virus-associated RNA mandates a revision of the proposed secondary structure

Protein synthesis in adenovirus-infected cells is regulated during the late phase of infection. The rate of initiation is maintained by a small viral RNA, virus-associated (VA) RNAI, which prevents the phosphorylation of eukaryotic initiation factor eIF-2 by a double-stranded RNA-activated protein kinase, DAI. On the basis of nuclease sensitivity analysis, a secondary-structure model was proposed for VA RNA. The model predicts a complex stem-loop structure in the central part of the molecule, the central domain, joining two duplexed stems. The central domain is required for the inhibition of DAI activation and participates in the binding of VA RNA to DAI. To assess the significance of the postulated stem-loop structure in the central domain, we generated compensating, deletion, and substitution mutations. A substitution mutation which disrupts the structure in the central domain abolishes VA RNA function in vitro and in vivo. Base-compensating mutations failed to restore the function or structure of the mutant, implying that the stem-loop structure may not exist. To confirm this observation, we tested mutants with alterations in the hypothetical loop and short stem that constitute the main features of the wild-type model structure. The upper part of the hypothetical loop could be deleted without abolishing the ability of the RNA to block DAI activation in vitro, whereas other loop mutations were deleterious for function and caused major rearrangements in the molecule. Base-compensating mutations in the stem did not restore the expected base pairing, even though the mutant RNAs were still functional in vitro. Surprisingly, a mutant with a noncompensating substitution mutation in the stem was more effective than wild-type VA RNAI in DAI inhibition assays but was ineffective in vivo. The structural and functional consequences of these mutations do not support the proposed model structure for the central domain, and we therefore suggest an alternative structure in which tertiary interactions may play a significant role in shaping the specificity of VA RNA function in the infected cell. Discrepancies between the functionality of mutant forms of VA RNA in vivo and in vitro are consistent with the existence of additional roles for VA RNA in the cell.

Transcription by SP6 RNA polymerase exhibits an ATP dependence that is influenced by promoter topology

Transcription of linearized DNA templates by SP6 RNA polymerase requires a higher concentration of ATP than of the other three nucleotides. This requirement is not shared by T7 RNA polymerase. The ATP requirement is partially relieved when the SP6 template is supercoiled but not when it is relaxed circular DNA. The effect of supercoiling is eliminated by replacement of the A.T rich sequence downstream from the SP6 promoter with a G.C rich sequence. Examination of the reaction products indicates that the ATP dependence of transcription from a linear template is not due to an ATPase activity or to the premature termination of transcription at low ATP concentration. These data suggest that the initiation of transcription by SP6 RNA polymerase requires partial denaturation of the template in the promoter-proximal region, and that this requirement can be satisfied by negative supercoiling or by increasing the ATP concentration. ATP also reduces, but does not eliminate, the abortive transcription that leads to the production of short, prematurely terminated transcripts by SP6 polymerase from supercoiled templates.

A complex promoter element mediates transactivation of the human proliferating cell nuclear antigen promoter by the 243-residue adenovirus E1A oncoprotein

The adenovirus E1A oncoproteins interfere with the normal regulation of cellular proliferation through interactions with cell cycle regulatory proteins. In view of the essential role of proliferating-cell nuclear antigen (PCNA) in DNA replication, we performed a mutational analysis of the minimal human PCNA promoter (nucleotides -87 to +62) to define sequence elements which mediate transactivation by the 243-residue E1A protein (E1A 243R). Linker-scanning and site-directed mutants were examined for basal and E1A-induced expression of chloramphenicol acetyltransferase (CAT) from PCNA promoter-CAT reporter constructs transiently expressed in HeLa cells. The results define the cis-acting element required for induction of PCNA by E1A 243R as a region between -59 and -45 relative to the transcription initiation site. This PCNA E1A-responsive element (PERE), which is protected from DNase I digestion by nuclear extracts from 293 cells, includes the sequence AGCGTGG immediately upstream of the ATF binding site previously shown to be important for activation of PCNA by E1A 243R (G. F. Morris and M. B. Mathews, J. Virol. 65:6397-6406, 1991). Mutation of either the upstream component or the ATF site within the PERE diminishes basal promoter activity and abrogates transactivation by E1A 243R. This novel cis-acting element is also essential for both basal and E1A-induced expression in the context of the full-length PCNA promoter.

Tat-responsive region RNA of human immunodeficiency virus type 1 stimulates protein synthesis in vivo and in vitro: relationship between structure and function

The Tat-responsive region (TAR) sequence is present at the 5' end of human immunodeficiency virus 1 mRNAs and as a cytoplasmic form of 58-66 nucleotides. TAR RNA blocks the activation and autophosphorylation of the double-stranded RNA-activated protein kinase in vitro. We show here that TAR RNA also prevents the double-stranded RNA-mediated inhibition of translation in a cell-free system. Mutagenic and structural analyses of TAR RNA indicate that a stem of at least 14 base pairs is required for this activity, whereas the loop and bulge required for transactivation by Tat are dispensable. Truncation of the RNA to 68 nucleotides results in the loss of translational rescue ability, suggesting that the short cytoplasmic TAR RNA produced by viral transcription in vivo may not have the capability to suppress activation of the kinase. However, because longer TAR transcripts stimulate expression in a transient assay in vivo, the TAR structure at the 5' end of viral mRNAs could still exert this function in cis.

The adenovirus E1A 12S product displays functional redundancy in activating the human proliferating cell nuclear antigen promoter

The adenovirus E1A 243R oncoprotein stimulates expression from the promoter of the human proliferating cell nuclear antigen (PCNA). To gain insight into the mechanism of activation, we analyzed deletion and point mutations of the 243R protein for their abilities to activate PCNA promoter-directed reporter gene expression upon cotransfection into HeLa cells. Large deletions that in combination span the entire protein severely impaired the ability of E1A 243R to induce PCNA expression. Smaller deletions and specific point mutations that target specific E1A-binding proteins were less deleterious to PCNA induction. The data suggest that E1A activates transcription of the PCNA gene by multiple mechanisms and that, of the known 243R-associated proteins, p300 and p107-cyclin A can mediate the response while p105-RB does not appear to participate. Presumably, the functional redundancy ensures that 243R can activate expression of this essential DNA replication protein regardless of cell type and physiological conditions.

Interactions between double-stranded RNA regulators and the protein kinase DAI

The interferon-induced protein kinase DAI, the double-stranded RNA (dsRNA)-activated inhibitor of translation, plays a key role in regulating protein synthesis in higher cells. Once activated, in a process that involves autophosphorylation, it phosphorylates the initiation factor eIF-2, leading to inhibition of polypeptide chain initiation. The activity of DAI is controlled by RNA regulators, including dsRNA activators and highly structured single-stranded RNAs which block activation by dsRNA. To elucidate the mechanism of activation, we studied the interaction of DAI with RNA duplexes of discrete sizes. Molecules shorter than 30 bp fail to bind stably and do not activate the enzyme, but at high concentrations they prevent activation by long dsRNA. Molecules longer than 30 bp bind and activate the enzyme, with an efficiency that increases with increasing chain length, reaching a maximum at about 85 bp. These dsRNAs fail to activate at high concentrations and also prevent activation by long dsRNA. Analysis of complexes between dsRNA and DAI suggests that at maximal packing the enzyme interacts with as little as a single helical turn of dsRNA (11 bp) but under conditions that allow activation the binding site protects about 80 bp of duplex. When the RNA-binding site is fully occupied with an RNA activator, the complex appears to undergo a conformational change.

Premature termination and processing of human immunodeficiency virus type 1-promoted transcripts

We have used transient expression assays to study transcription directed by the human immunodeficiency virus (HIV) type 1 promoter. A plasmid containing an HIV-reporter gene fusion and a simian virus 40 origin of DNA replication was transfected into COS-1 cells in the presence or absence of a Tat expression vector. HIV-promoted RNA was analyzed by in vivo labeling, by RNase protection mapping, and in run-on transcription assays. As observed previously, two populations of HIV RNA accumulate in vivo: short, attenuated transcripts and long, polyadenylated mRNA. The short transcripts labeled in vivo were longer and more heterogeneous than expected from RNase protection assays. Moreover, comparison of transcripts labeled in vivo with run-on transcription products revealed that similar, if not identical, short RNAs accumulate in vitro. Utilizing the run-on assay, we show that following transcriptional termination, the attenuated transcripts undergo processing to generate one species of RNA. We also provide evidence that Tat does not act as an antiterminator to relieve a discrete elongation block but instead modifies transcriptional complexes, enabling them to overcome putative pause sites and continue transcription of the template.

Role of the apical stem in maintaining the structure and function of adenovirus virus-associated RNA

Adenovirus virus-associated (VA) RNAI maintains efficient protein synthesis during the late phase of infection by preventing the activation of the double-stranded-RNA-dependent protein kinase, DAI. A secondary structure model for VA RNAI predicts the existence of two stems joined by a complex stem-loop structure, the central domain. The structural consequences of mutations and compensating mutations introduced into the apical stem lend support to this model. In transient expression assays for VA RNA function, foreign sequences inserted into the apical stem were fully tolerated provided that the stem remained intact. Mutants in which the base of the apical stem was disrupted retained partial activity, but truncation of the apical stem abolished the ability of the RNA to block DAI activation in vitro, suggesting that the length and position of the stem are both important for VA RNA function. These results imply that VA RNAI activity depends on secondary structure at the top of the apical stem as well as in the central domain and are consistent with a two-step mechanism involving DAI interactions with both the apical stem and the central domain.

The adenovirus E1A transforming protein activates the proliferating cell nuclear antigen promoter via an activating transcription factor site

The transforming region of adenovirus (E1) stimulates expression of a reporter construct linked to the promoter for the human proliferating cell nuclear antigen (PCNA) gene in a cotransfection assay (G. F. Morris and M. B. Mathews, J. Biol. Chem. 264:13856-13864, 1989). The major products of the E1 region were assessed individually for their contribution to transactivation of the PCNA promoter. The E1A 13S and 12S products and the E1B 19-kDa product elevated expression from the PCNA promoter, whereas the E1B 55-kDa product did not. Induction of the PCNA promoter by E1A differed from transcriptional activation of the adenovirus E3 promoter in that the PCNA promoter is activated by the E1A 12S product whereas the E3 promoter is repressed; furthermore, the PCNA promoter is activated upon E1A overexpression, whereas the E3 promoter responds less well to high amounts of E1A. A site for the activating transcription factor ATF located approximately 50 nucleotides upstream from the transcription initiation site in the PCNA promoter mediates a positive response to the E1A 12S and 13S products.

Tat transactivation of the human immunodeficiency virus type 1 promoter is influenced by basal promoter activity and the simian virus 40 origin of DNA replication

We examined the activation of transcription from the human immunodeficiency virus type 1 (HIV-1) promoter by the viral Tat protein in a transient expression system. Plasmids contained a HIV-reporter gene cassette and a simian virus 40 origin of DNA replication. Run-on assays of transcription complex distribution and analysis of cytoplasmic RNA accumulation confirmed that Tat is able to activate transcription by two mechanisms: by increasing the rate of transcriptional initiation and the efficiency of transcriptional elongation. The degree to which Tat stimulated initiation is determined by the basal level of HIV-directed transcription, which is influenced by the presence [corrected] of the simian virus 40 replication origin. Tat functions primarily to increase the efficiency of elongation when the origin is present and the basal level of transcription is high [corrected]. On the other hand, Tat functions primarily to increase the rate of initiation when the origin is absent [corrected] and the basal level of transcription is 10-fold lower. These studies suggest that the site of integration of the virus into the cellular genome may significantly affect the level of expression from the HIV promoter and consequently the pathobiology of the virus.

Synergy between HIV-1 Tat and adenovirus E1A is principally due to stabilization of transcriptional elongation

We studied the combined effects of Tat and general trans-activators, such as E1A and phorbol esters, on human immunodeficiency virus-1 (HIV-1) gene expression. Interaction between these two types of trans-activators may be involved in the transition from transcriptional quiesence during viral latency to active gene expression during productive infection. E1A cooperated with Tat to produce a fourfold greater increase in accumulation of full-length, cytoplasmic HIV-1-directed RNA than is expected if they were acting additively to increase RNA accumulation. Similarly, phorbol 12-myristate 13-acetate (PMA) also cooperated with Tat to elevate HIV RNA levels synergistically. Analysis of transcription rates across the HIV-1-directed transcription unit indicated, unexpectedly, that synergy between Tat and E1A could not be accounted for by increased promoter proximal transcription rates that were merely additive. However, Tat and E1A produced a greater than additive increase in transcription rates in the 3' end of the gene. These findings imply that synergy between Tat and E1A (or other general transcriptional activators) is due principally to stabilization of transcriptional elongation. Furthermore, the observation that Tat elicits only a small increase in promoter proximal transcription in the presence of E1A suggests that the magnitude of the effect of Tat on initiation is decreased when the basal level of transcription is increased. These findings underscore the importance of the ability of Tat to stabilize elongation, as well as to stimulate initiation, in an HIV-1-directed transcription unit.