The adenovirus E1B 19-kilodalton protein stimulates gene expression by increasing DNA levels.

In transient expression assays, the adenovirus E1B 19-kilodalton (19K) tumor antigen increases expression from viral promoters and the promoter for the cellular 70-kilodalton heat shock protein (hsp70). To study the mechanism of this effect, we constructed HeLa cell lines that contain stably integrated copies of the 19K gene. Compared with a 19K- control cell line, 19K+ cells produced a significantly higher level of expression from every promoter introduced into the cells by transfection. The 19K protein also increased expression of an RNA polymerase III-transcribed gene but did not affect the level of expression of the endogenous hsp70 gene. The rate of transcription from transfected promoters, as measured by a nuclear run-on assay, was higher in the 19K+ cells than in the 19K- control cells. Furthermore, the level of plasmid DNA remained higher in the 19K+ cell line, suggesting that the 19K protein stabilizes transfected plasmid DNA. The elevated DNA levels seemed to account in full for the increased transcription. The role of the 19K protein in increasing gene expression during viral infection was found to be due to a replication-dependent increase in viral DNA levels. Thus, the 19K protein activates transcription indirectly by producing a higher level of viral or plasmid DNA. The DNA stabilization function of the 19K protein is probably related to the protective role of the 19K protein during viral infection and represents the first example of a viral oncogene product that modulates gene expression by regulating viral and plasmid DNA levels.

Inhibition of v-Mos kinase activity by protein kinase A.

We investigated the effect of cyclic AMP-dependent protein kinase (PKA ) on v-Mos kinase activity. Increase in PKA activity in vivo brought about either by forskolin treatment or by overexpression of PKA catalytic subunit resulted in a significant inhibition of v-Mos kinase activity. The purified PKA catalytic subunit was able to phosphorylate recombinant p37v-mos in vitro, suggesting that the mechanism of in vivo inhibition of v-Mos kinase involves direct phosphorylation by PKA. Combined tryptic phosphopeptide two-dimensional mapping analysis and in vitro mutagenesis studies indicated that Ser-56 is the major in vivo phosphorylation site on v-Mos. In vivo phosphorylation at Ser-56 correlated with slower migration of the v-Mos protein during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. However, even though Ser-56 was phosphorylated by PKA, this phosphorylation was not involved in the inhibition of v-Mos kinase. The alanine-for-serine substitution at residue 56 did not affect the ability of v-Mos to autophosphorylate in vitro or, more importantly, to activate MEK1 in transformed NIH 3T3 cells. We identified Ser-263 phosphorylation, the Ala-263 mutant of v-Mos was not inhibited by forskolin treatment. From our results, we propose that the known inhibitory role of PKA in the initiation of oocyte maturation in mice could be explained at least in part by its inhibition of Mos kinase.

Response of individual adenovirus promoters to the products of the E1A gene.

Adenovirus E1A genes possess transcriptional activation and repression activities. Three major gene products have been characterized, derived from the 13S, 12S and 9S mRNAs. Using transient expression assays in HeLa cells, we have investigated the effect of these gene products on the activity of the nine major Ad2 (or Ad5) promoters driving the expression of a reporter gene. Based on the results, we could separate the promoters into three classes: (a) E1A, which is active by itself, and is unaffected or slightly stimulated by the E1A 13S product (depending on the HeLa cell line used); (b) the other classical early promoters (E1B, E2e, E3, E4), all of which are active alone and are stimulated by the 13S product and repressed by the 12S product; and (c) the late promoters (IX, IVa2, MLP, E2L) which are not active alone and are substantially unaffected by the 13S or 12S products. Thus the 13S and 12S gene products have antagonistic effects on at least four adenovirus promoters. The 9S product did not influence the activity of any of the adenovirus promoters. Upon transfection into 293 cells, all the early promoters were active and all the late promoters were inactive, except for the major late promoter (MLP). We demonstrate that the combination of the E1A and E1B genes is a potent activator of the MLP in HeLa cells and discuss these results in the context of the infectious cycle.

Transactivation of host and viral genes by the adenovirus E1B 19K tumor antigen.

Adenovirus contains two nuclear oncogenes, the EIA and EIB genes, which cooperatively can transform cells through mechanisms that are not understood. The transcriptional activities of the E1A gene (transactivation and repression) are well studied. Using transient expression assays, we show here that the 19,000-Da E1B gene product can also activate all the adenovirus early promoters (E1A, E1B, E2e, E3 and E4) and a cellular heat shock gene promoter (hsp70), but not the adenovirus late promoters (IX, IVa2, MLP and E2L). The effect is greatest under conditions where cell growth is inhibited, and appears to operate at the transcriptional level. Possible interactions with enhancer elements are discussed. Although the E1B stimulatory effect does not require the presence of E1A gene products, a synergistic effect is obtained in the presence of E1A 13S product. This activity of the E1B gene is also observed during virus infection and is likely to have important consequences in lytically infected and transformed cells.

Wild-type and mutant HIV-1 and HIV-2 Tat proteins expressed in Escherichia coli as fusions with glutathione S-transferase.

Human immunodeficiency virus type 1 (HIV-1) and HIV-2 encode related transcriptional activators known as Tat-1 and Tat-2, respectively, that are required for efficient viral replication. The Tat proteins have been studied extensively, and it appears that their mechanism of action is unique to the primate immunodeficiency viruses or a few distantly related lentiviruses. Here we describe a collection of 24 wild-type and mutant Tat-1 and Tat-2 proteins that are expressed in Escherichia coli as fusions with glutathione S-transferase (GST). The GST-Tat fusions can be used for biochemical studies after simple purification from E. coli lysates in a single step under nondenaturing conditions. The availability of these GST-Tat fusions should be useful to investigators examining biochemical properties of Tat-1 and Tat-2 proteins. E. coli cultures harboring GST-Tat fusions described here are available through the National Institute of Health AIDS Research and Reference Reagent Program.

Construction and characterization of a potent HIV-2 Tat transdominant mutant protein.

The human immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) Tat proteins Tat-1 and Tat-2 stimulate transcription of the viral long terminal repeat (LTR) sequences and are required for efficient viral replication. A class of mutant Tat proteins, termed "transdominant mutants," has been described that possesses relatively low transactivation activity, yet is able to inhibit the function of wild-type Tat. These mutant proteins contain a nonfunctional TAR RNA-binding domain but apparently retain a functional activation domain. A potential limitation for therapeutic use of transdominant mutants described to date is their low but significant basal level of transactivation for the HIV-1 or HIV-2 LTRs. In order to make an improved transdominant mutant, we have constructed Tat-2 proteins that contain mutations in four contiguous arginines at residues 81 to 84 in the RNA-binding domain. Using purified proteins and in vitro RNA-binding assays, we verified that these mutant Tat-2 proteins are defective for TAR RNA binding. We also verified that these mutant Tat-2 proteins bind to a cellular protein kinase in vitro that we have previously shown to bind specifically to the Tat-1 and Tat-2 activation domain. Using plasmid cotransfection assays, we compared the phenotypes of these mutant Tat-2 proteins with the most potent Tat-1 transdominant mutant described to date. One Tat-2 mutant, named "R81-84A," was found to be equivalent to the Tat-1 mutant in ability to inhibit wild-type Tat transactivation of HIV-1 and HIV-2 LTRs. Moreover, the R81-84A mutant possessed a significantly lower basal level of transactivation than the Tat-1 mutant. The R81-84A Tat-2 mutant is therefore a promising reagent for future development as an anti-HIV agent. Additionally, our results suggest that wild-type Tat-2 transactivation of the HIV-2 LTR is especially sensitive to inhibition by transdominant mutants.

Specific interaction of the human immunodeficiency virus Tat proteins with a cellular protein kinase.

The human immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) Tat proteins are related transcriptional activators whose effects are likely to be mediated by a cellular factor. Using an in vitro kinase assay, we have shown that the Tat protein of HIV-2 and the activation domain of the Tat protein of HIV-1 specifically bind to a cellular protein kinase. Mutations in Tat that abolish transactivation activity in vivo abrogate the ability of the mutants to bind to the kinase in vitro. This is the first demonstration of a cellular factor that binds to Tat that is specific for a functional activation domain of Tat and that displays a biochemical activity. Additionally, we show that the Tat protein of HIV-2 serves as a substrate of the kinase in vitro. Consistent with the in vitro results, the Tat protein of HIV-2 interacts with a cellular kinase in HIV-2 Tat-transfected cells and is phosphorylated in vivo. These results suggest that a cellular serine/threonine kinase may act as a mediator of Tat function.

The Cdk9 and cyclin T subunits of TAK/P-TEFb localize to splicing factor-rich nuclear speckle regions.

TAK/P-TEFb is an elongation factor for RNA polymerase II-directed transcription that is thought to function by phosphorylating the C-terminal domain of the largest subunit of RNA polymerase II. TAK/P-TEFb is composed of Cdk9 and cyclin T and serves as the cellular cofactor for the human immunodeficiency virus transactivator Tat protein. In this study, we examined the subcellular distribution of Cdk9 and cyclin T1 using high resolution immunofluorescence microscopy and found that Cdk9 and cyclin T1 localized throughout the non-nucleolar nucleoplasm, with increased signal present at numerous foci. Both Cdk9 and cyclin T1 showed only limited colocalization with different phosphorylated forms of RNA polymerase II. However, significant colocalization with antibodies to several splicing factors that identify nuclear 'speckles' was observed for Cdk9 and especially for cyclin T1. The pattern of Cdk9 and cyclin T1 distribution was altered in cells treated with transcription inhibitors. Transient expression of cyclin T1 deletion mutants indicated that a region in the central portion of cyclin T1 is important for accumulation at speckles. Furthermore, cyclin T1 proteins that accumulated at speckles were capable of recruiting Cdk9 and the HIV Tat protein to this compartment in overexpression experiments. These results suggest that cyclin T1 functions to recruit its binding partners to nuclear speckles and raises the possibility that nuclear speckles are a site of TAK/P-TEFb function.

Lentivirus Tat proteins specifically associate with a cellular protein kinase, TAK, that hyperphosphorylates the carboxyl-terminal domain of the large subunit of RNA polymerase II: candidate for a Tat cofactor.

Efficient replication of human immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) requires the virus transactivator proteins known as Tat. In order to understand the molecular mechanisms involved in Tat transactivation, it is essential to identify the cellular target(s) of the Tat activation domain. Using an in vitro kinase assay, we previously identified a cellular protein kinase activity, Tat-associated kinase (TAK), that specifically binds to the activation domains of Tat proteins. Here it is demonstrated that TAK fulfills the genetic criteria established for a Tat cofactor. TAK binds in vitro to the activation domains of the Tat proteins of HIV-1 and HIV-2 and the distantly related lentivirus equine infectious anemia virus but not to mutant Tat proteins that contain nonfunctional activation domains. In addition, it is shown that TAK is sensitive to dichloro-1-beta-D-ribofuranosylbenzimidazole, a nucleoside analog that inhibits a limited number of kinases and is known to inhibit Tat transactivation in vivo and in vitro. We have further identified an in vitro substrate of TAK, the carboxyl-terminal domain of the large subunit of RNA polymerase II. Phosphorylation of the carboxyl-terminal domain has been proposed to trigger the transition from initiation to active elongation and also to influence later stages during elongation. Taken together, these results imply that TAK is a very promising candidate for a cellular factor that mediates Tat transactivation.

Adenovirus E1A is associated with a serine/threonine protein kinase.

The adenovirus E1A proteins form stable protein complexes with a number of cellular proteins, including cyclin A and the product of the retinoblastoma susceptibility gene. We have been interested in learning about the function of proteins associated with E1A and therefore looked for an enzymatic activity present in E1A complexes. We found a serine/threonine kinase activity that phosphorylates two proteins bound to E1A, the 107- and 130-kDa (107K and 130K) proteins. The kinase also phosphorylates histone H1 added as an exogenous substrate. The kinase activity is cell cycle regulated, being most active in S and G2/M-phase cells. The timing of phosphorylation of the 107K protein in vitro correlates with the phosphorylation pattern of the 107K protein in vivo. A variety of genetic and immunochemical approaches indicate that the activity is probably not due to the E1A-associated 300K, 130K, 107K, or pRB protein. Although we have not established the identity of the kinase, we present evidence that the kinase activity is consistent with phosphorylation by p34cdc2 or a related kinase.

The human immunodeficiency virus Tat proteins specifically associate with TAK in vivo and require the carboxyl-terminal domain of RNA polymerase II for function.

Human immunodeficiency virus types 1 and 2 encode closely related proteins, Tat-1 and Tat-2, that stimulate viral transcription. Previously, we showed that the activation domains of these proteins specifically interact in vitro with a cellular protein kinase named TAK. In vitro, TAK phosphorylates the Tat-2 but not the Tat-1 protein, a 42-kDa polypeptide of unknown identity, and the carboxyl-terminal domain (CTD) of RNA polymerase II (RNAP II). We now show that the 42-kDa substrate of TAK cochromatographs with TAK activity, suggesting that this 42-kDa polypeptide is a subunit of TAK. We also show that the Tat proteins specifically associate with TAK in vivo, since wild-type Tat-1 and Tat-2 proteins expressed in mammalian cells, but not mutant Tat proteins containing a nonfunctional activation domain, can be coimmunoprecipitated with TAK. We also mapped the in vivo phosphorylation sites of Tat-2 to the carboxyl terminus of the protein, but analysis of proteins with mutations at these sites suggests that phosphorylation is not essential for Tat-2 transactivation function. We further investigated whether the CTD of RNAP II is required for Tat function in vivo. Using plasmid constructs that express an alpha-amanitin-resistant RNAP II subunit with a truncated or full-length CTD, we found that an intact CTD is required for Tat function. These observations strengthen the proposal that the mechanism of action of Tat involves the recruitment or activation of TAK, resulting in activated transcription through phosphorylation of the CTD.

Viral transactivators specifically target distinct cellular protein kinases that phosphorylate the RNA polymerase II C-terminal domain.

Phosphorylation of the carboxyl-terminal domain (CTD) of the largest subunit of RNA polymerase II has been implicated as an important step in transcriptional regulation. Previously, we reported that a cellular CTD kinase, TAK, is targeted by the human immunodeficiency virus transactivator Tat. In the present study, we analyzed several other transactivators for the ability to interact with CTD kinases in vitro. The adenovirus E1A and herpes simplex virus VP16 proteins, but not other transactivators tested, were found to associate with a cellular kinase activity that hyperphosphorylates the CTD. The interaction is dependent upon a functional activation domain of E1A or VP16, suggesting that the interaction with a CTD kinase is relevant for the transactivation function of these proteins. The CTD kinase activities that interact with E1A and VP16 are related to each other but distinct from TAK. The Tat-, E1A- and VP16-associated CTD kinase activities detected in our assay also appear unrelated to MO15, the catalytic component of the CTD kinase activity of the general transcription factor TFIIH. Thus, this study has identified a novel interaction between viral transactivators and a cellular CTD kinase and suggests that at least two CTD kinases may mediate responses to viral transactivators.

Induction of TAK (cyclin T1/P-TEFb) in purified resting CD4(+) T lymphocytes by combination of cytokines.

Combinations of cytokines are known to reactivate transcription and replication of latent human immunodeficiency virus type 1 (HIV-1) proviruses in resting CD4(+) T lymphocytes isolated from infected individuals. Transcription of the HIV-1 provirus by RNA polymerase II is strongly stimulated by the viral Tat protein. Tat function is mediated by a cellular protein kinase known as TAK (cyclin T1/P-TEFb) that is composed of Cdk9 and cyclin T1. We have found that treatment of peripheral blood lymphocytes and purified resting CD4(+) T lymphocytes with the combination of interleukin-2 (IL-2), IL-6, and tumor necrosis factor alpha resulted in an increase in Cdk9 and cyclin T1 protein levels and an increase in TAK enzymatic activity. The cytokine induction of TAK in resting CD4(+) T lymphocytes did not appear to require proliferation of lymphocytes. These results suggest that induction of TAK by cytokines secreted in the microenvironment of lymphoid tissue may be involved in the reactivation of HIV-1 in CD4(+) T lymphocytes harboring a latent provirus.

PITALRE, the catalytic subunit of TAK, is required for human immunodeficiency virus Tat transactivation in vivo.

The human cdc2-related kinase PITALRE is the catalytic component of TAK, the Tat-associated kinase. Previously, we have proposed that TAK is a cellular factor that mediates Tat transactivation function. Here we demonstrate that transient overexpression of PITALRE specifically squelches Tat-1 activation of both a transfected and an integrated human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR), suggesting that PITALRE mediates Tat function as a multiprotein complex. A catalytic mutant of PITALRE, D167N, was found to be more efficient than wild-type PITALRE in squelching Tat transactivation. Neither wild-type PITALRE nor D167N was able to squelch transactivation of the human T-cell leukemia type 1 LTR by the Tax protein. Additionally, we show that artificial targeting of PITALRE to a nascent RNA element, in the absence of Tat, activated HIV-1 LTR expression. These results indicate that a PITALRE-containing complex mediates transactivation by Tat and suggest that Tat proteins function by localizing such a PITALRE-containing complex to the site of the transcribing provirus.

Tat-associated kinase, TAK, activity is regulated by distinct mechanisms in peripheral blood lymphocytes and promonocytic cell lines.

TAK, a multisubunit cellular protein kinase that specifically associates with the human immunodeficiency virus Tat proteins and hyperphosphorylates the carboxyl-terminal domain of RNA polymerase II, is a cofactor for Tat and mediates its transactivation function. The catalytic subunit of TAK has been identified as cyclin-dependent kinase Cdk9, and its regulatory partner has been identified as cyclin T1; these proteins are also components of positive transcription elongation factor P-TEFb. TAK activity is up-regulated upon activation of peripheral blood lymphocytes and following macrophage differentiation of promonocytic cell lines. We have found that activation of peripheral blood lymphocytes results in increased mRNA and protein levels of both Cdk9 and cyclin T1. Cdk9 and cyclin T1 induction occurred in purified CD4(+) primary T cells activated by a variety of stimuli. In contrast, phorbol ester-induced differentiation of promonocytic cell lines into macrophage-like cells produced a large induction of cyclin T1 protein expression from nearly undetectable levels, while Cdk9 protein levels remained at a constant high level. Measurements of cyclin T1 mRNA levels in a promonocytic cell line suggested that regulation of cyclin T1 occurs at a posttranscriptional level. These results suggest that cyclin T1 and TAK function may be required in differentiated monocytes and further show that TAK activity can be regulated by distinct mechanisms in different cell types.

Viral transactivators E1A and VP16 interact with a large complex that is associated with CTD kinase activity and contains CDK8.

Previously, we showed that the viral transactivator proteins E1A and VP16 specifically interact with a cellular CTD kinase activity in vitro. We now report that E1A and VP16 complexes contain human CDK8, a newly identified member of the cyclin-dependent kinase family that has been shown to be a component of the RNA polymerase II (RNAP II) holoenzyme complex. The presence of CDK8 in the E1A- and VP16-containing complexes is specific for a functional activation domain of these viral transactivators, strongly suggesting that this association is relevant for the transactivation function of E1A and VP16. We show that CDK8 is associated with CTD kinase activity and that CDK8 co-fractionates with E1A- and VP16-associated CTD kinase activity over several chromatography columns. Therefore, CDK8 is likely responsible for the E1A- and VP16-associated CTD kinase activity. Gel filtration chromatography indicates that the E1A- and VP16-associated CTD kinase activity has a molecular size of approximately 1.5 MDa and contains cyclin C and the human homolog of SRB7 in addition to CDK8. This implies that E1A and VP16 associate with the RNAP II holoenyzme. We also looked at the transcriptional activity of CDK8 and found that CDK8 can function as a transcriptional activator when fused to the DNA binding domain of GAL4. Surprisingly, the ability of GAL4-CDK8 to activate transcription in this assay was not dependent on the kinase activity of CDK8, since a kinase-deficient mutant of CDK8 stimulated transcription nearly as well as wild-type GAL4-CDK8. This suggests that CDK8 may play a role in transcription that is distinct from its ability to function as a CTD kinase.

TAK, an HIV Tat-associated kinase, is a member of the cyclin-dependent family of protein kinases and is induced by activation of peripheral blood lymphocytes and differentiation of promonocytic cell lines.

We have previously identified a cellular protein kinase activity termed TAK that specifically associates with the HIV types 1 and 2 Tat proteins. TAK hyperphosphorylates the carboxyl-terminal domain of the large subunit of RNA polymerase II in vitro in a manner believed to activate transcription [Herrmann, C. H. & Rice, A. P. (1995) J. Virol. 69, 1612-1620]. We show here that the catalytic subunit of TAK is a known human kinase previously named PITALRE, which is a member of the cyclin-dependent family of proteins. We also show that TAK activity is elevated upon activation of peripheral blood mononuclear cells and peripheral blood lymphocytes and upon differentiation of U1 and U937 promonocytic cell lines to macrophages. Therefore, in HIV-infected individuals TAK may be induced in T cells following activation and in macrophages following differentiation, thus contributing to high levels of viral transcription and the escape from latency of transcriptionally silent proviruses.

The interaction between HIV-1 Tat and human cyclin T1 requires zinc and a critical cysteine residue that is not conserved in the murine CycT1 protein.

HIV-1 Tat activates transcription through binding to human cyclin T1, a regulatory subunit of the TAK/P-TEFb CTD kinase complex. Here we show that the cyclin domain of hCycT1 is necessary and sufficient to interact with Tat and promote cooperative binding to TAR RNA in vitro, as well as mediate Tat transactivation in vivo. A Tat:TAR recognition motif (TRM) was identified at the carboxy-terminal edge of the cyclin domain, and we show that hCycT1 can interact simultaneously with Tat and CDK9 on TAR RNA in vitro. Alanine-scanning mutagenesis of the hCycT1 TRM identified residues that are critical for the interaction with Tat and others that are required specifically for binding of the complex to TAR RNA. Interestingly, we find that the interaction between Tat and hCycT1 requires zinc as well as essential cysteine residues in both proteins. Cloning and characterization of the murine CycT1 protein revealed that it lacks a critical cysteine residue (C261) and forms a weak, zinc-independent complex with HIV-1 Tat that greatly reduces binding to TAR RNA. A point mutation in mCycT1 (Y261C) restores high-affinity, zinc-dependent binding to Tat and TAR in vitro, and rescues Tat transactivation in vivo. Although overexpression of hCycT1 in NIH3T3 cells strongly enhances transcription from an integrated proviral promoter, we find that this fails to overcome all blocks to productive HIV-1 infection in murine cells.