HTLV-1 Tax oncoprotein inhibits the estrogen-induced-ER α-Mediated BRCA1 expression by interaction with CBP/p300 cofactors.

BRCA1 is a multifunctional tumor suppressor, whose expression is activated by the estrogen (E2)-liganded ERα receptor and regulated by certain recruited transcriptional co-activators. Interference with BRCA1 expression and/or functions leads to high risk of breast or/and ovarian cancer. Another multifunctional protein, HTLV-1Tax oncoprotein, is widely regarded as crucial for developing adult T-cell leukemia and other clinical disorders. Tax profile reveals that it can antagonize BRCA1 expression and/or functionality. Therefore, we hypothesize that Tax expression in breast cells can sensitize them to malignant transformation by environmental carcinogens. Here we examined Tax effect on BRCA1 expression by testing its influence on E2-induced expression of BRCA1 promoter-driven luciferase reporter (BRCA1-Luc). We found that E2 strongly stimulated this reporter expression by liganding to ERα, which consequently associated with BRCA1 promoter, while ERα concomitantly recruited CBP/p300 to this complex for co-operative enhancement of BRCA1 expression. Introducing Tax into these cells strongly blocked this E2-ERα-mediated activation of BRCA1 expression. We noted, also, that Tax exerted this inhibition by binding to CBP/p300 without releasing them from their complex with ERα. Chip assay revealed that the binding of Tax to the CBP/p300-ERα complex, prevented its link to AP1 site. Interestingly, we noted that elevating the intracellular pool of CBP or p300 to excessive levels dramatically reduced the Tax-mediated inhibition of BRCA1 expression. Exploring the mechanism of this reduction revealed that the excessive co-factors were sufficient to bind separately the free Tax molecules, thus lowering their amount in the CBP/p300-ERα complex and relieving, thereby, the inhibition of BRCA1 expression.

Differential role of PKC-induced c-Jun in HTLV-1 LTR activation by 12-O-tetradecanoylphorbol-13-acetate in different human T-cell lines.

We have previously shown that TPA activates HTLV-1 LTR in Jurkat T-cells by inducing the binding of Sp1-p53 complex to the Sp1 site residing within the Ets responsive region 1 (ERR-1) of the LTR and that this activation is inhibited by PKCalpha and PKCepsilon. However, in H9 T-cells TPA has been noted to activate the LTR in two consecutive stages. The first stage is activation is mediated by PKCetta and requires the three 21 bp TRE repeats. The second activation mode resembles that of Jurkat cells, except that it is inhibited by PKCdelta. The present study revealed that the first LTR activation in H9 cells resulted from PKCetta-induced elevation of non-phosphorylated c-Jun which bound to the AP-1 site residing within each TRE. In contrast, this TRE-dependent activation did not occur in Jurkat cells, since there was no elevation of non-phosphorylated c-Jun in these cells. However, we found that PKCalpha and PKCepsilon, in Jurkat cells, and PKCetta and PKCdelta, in H9 cells, increased the level of phosphorylated c-Jun that interacted with the Sp1-p53 complex. This interaction prevented the Sp1-p53 binding to ERR-1 and blocked, thereby, the ERR-1-mediated LTR activation. Therefore, this PKC-inhibited LTR activation started in both cell types after depletion of the relevant PKCs by their downregulation. In view of these variable activating mechanisms we assume that there might be additional undiscovered yet modes of HTLV-1 LTR activation which vary in different cell types. Moreover, in line with this presumption we speculate that in HTLV-1 carriers the LTR of the latent provirus may also be reactivated by different mechanisms that vary between its different host T-lymphocyte subclones. Since this reactivation may initiate the ATL process, understanding of these mechanisms is essential for establishing strategies to block the possibility of reactivating the latent virus as preventive means for ATL development in carriers.

Role of caspase 9 in activation of HTLV-1 LTR expression by DNA damaging agents.

Adult T-cell leukemia (ATL) is caused by HTLV-I. The viral Tax oncoprotein plays a central role in initiating the process to ATL. However, after infection HTLV-1 enters into latency, during which virus gene expression is very low, so that the level of Tax is likely insufficient for exerting its oncogenic activities. Therefore only 5% of the infected individuals may develop ATL several decades after infection. It is assumed that the transition from latency to ATL development requires at least a temporary activation of the latent virus in order to elevate Tax to its oncogenic threshold. We have previously found that DNA damaging agents, which usually induce apoptosis, can also activate the viral LTR and that the anti apoptosis Bcl-2 protein not only avoid their apoptosis induction but concomitantly prevents their LTR activation effect. Therefore, the present study was designed to identify the factor that while participating in the apoptotic cascade acts also to activate the viral LTR. For this purpose we employed ectopic vectors expressing these apoptotic factors together with potent shRNAs against each of them and anti caspase peptide inhibitors. We have found that in addition to its function as initiator of the mitochondrial apoptotic cascade, caspase 9 can acts also as an executer which among other non-apoptotic functions it forms an Sp1-p53 complex that activates the LTR by binding to an Sp1 recognition site residing in the LTR. This finding can help in designing effective preventing strategies against ATL development in clinically latent HTLV-1 carriers.

The mechanism of HTLV-1 LTR activation by TPA varies in different human T-cell lines: role of specific PKC isoforms.

We demonstrate here that TPA activates HTLV-1 LTR expression in Jurkat and H9 T-cell lines, by strictly different mechanisms. In Jurkat cells this activation is exerted by a PKCalpha- and PKCvarepsilon-antagonized mechanism which operates through an Sp1 binding site residing within the Est responsive region 1 of the LTR. On the other hand, in H9 cells TPA activates the LTR by two consecutive mechanisms; the first depends on PKCeta activity and is exerted through the 21 bp repeats of the LTR, whereas the second is analogous to that observed in Jurkat cells, except that it is antagonized by PKCdelta.

HTLV-1 tax-induced NF-kappaB activation is synergistically enhanced by 12-O-tetradecanoylphorbol-13-acetate: mechanism and implications for Tax oncogenicity.

Nuclear factor kappa B (NF-kappaB) factors regulate a wide range of physiological and oncogenic processes. Normally, these factors are transiently activated by specific external signals which induce their dissociation from inhibitors of kappaB (IkappaB) and subsequent translocation to the nucleus where p65 links to the cyclic adenosine monophosphate response element binding protein (CBP)-p300 and P/CAF coactivators that are essential for its transcriptional activity. The pathogenic potential of human T-cell leukemia virus type 1 (HTLV-1) Tax protein is partly ascribed to its capacity to constitutively activate NF-kappaB factors because constitutive activity of these factors play an important role in the pathophysiology of adult T-cell leukemia (ATL) and tropical spastic paraparesis-HTLV-1 associated myelopathy (TSP-HAM). In assessing the possibility of modulating Tax pathogenic potential by external factors, we focused here on 12-O -tetradecanoylphorbol-13-acetate (TPA) which is a potent protein kinase C (PKC) activator. There are conflicting reports regarding the effect of TPA and PKC on NF-kappaB. Therefore, we reassessed this issue and also investigated their influence on Tax-mediated activation of these factors. We found that TPA promoted NF-kappaB nuclear translocation and the DNA binding of p65 dimers through PKC activation. However, both TPA and ectopically expressed PKC had only a marginal effect on the transcriptional competence of these dimers, indicating that the DNA binding of such dimers is insufficient by itself for gene activation. Notably, however, both TPA and the ectopic PKC displayed strong synergistic enhancement of the Tax-induced activation of the NF-kappaB transcriptional function. In contrast, TPA and the ectopic PKC only slightly elevated the low activation of the NF-kappaB transcriptional capacity by cytoplasmic Tax mutants, indicating that the nuclear translocation of Tax was essential for this synergism. Subsequent experiments suggested that TPA contributed to this synergism by increasing the pool of free p65 which Tax could link to CBP and elevate, thereby, the amount of a p65-Tax-CBP ternary complex that could bind to NF-kappaB-responsive promoters and stimulate their expression. Finally, we demonstrated that this synergism operated also in HTLV-1-infected human T-cells. Earlier reports have shown a close linkage of pathological PKC-activating conditions (e.g., infectious and inflammatory diseases) to certain malignancies. On this ground, the present study suggests that such conditions may enhance the risk for ATL and TSP-HAM in HTLV-1 carriers by increasing the Tax-induced NF-kappaB activation.

Dose-dependent dual effect of HTLV-1 tax oncoprotein on p53-dependent nucleotide excision repair in human T-cells.

In this study we investigated the effect of Tax on nucleotide excision repair (NER) in human T-cell lines by using the host cell repair analysis of UVC-irradiated reporter plasmid. This analysis revealed a p53-dependent NER activity in wild type (w.t.) p53-containing T-cells and p53-independent NER in w.t. p53-lacking T-cells. Notably, in the w.t. p53-containing cells Tax exerted a dose-dependent dual effect on NER. While low Tax doses markedly stimulated this repair, high Tax doses strongly reduced it. Further experiments demonstrated that the low Tax doses enhanced, in these cells, the level and the transcriptional function of their w.t. p53 protein. On the other hand, although the high Tax doses further increased the level of p53, they functionally inactivated its accumulating molecules. Both of these Tax effects on p53 proved to be mediated by Tax-induced NF-kappaB-related mechanisms. Together, these data suggest that by NF-kappaB activation Tax elevates the level of the cellular w.t. p53. However, while at low Tax doses the elevating w.t. p53 molecules are functionally active and capable of stimulating NER, intensifying further the NF-kappaB activation by the high Tax doses concomitantly evokes certain mechanism(s) which functionally inactivates the accumulating p53 protein. In contrast to this dual effect on the p53-dependent NER, Tax displayed only an inhibitory effect on the p53-independent NER by its high doses, whereas its low doses had no effect on this repair. The mechanisms of the NF-kappaB-associated effects on the level and function of the cellular w.t.p53 and of the p53-independent NER noted in our experimental systems are further investigated in our laboratory.

Functional inactivation of p53 by human T-cell leukemia virus type 1 Tax protein: mechanisms and clinical implications.

Human T-cell leukemia virus type 1 (HTLV-I) has been implicated with the etiology of adult T-cell leukemia (ATL) and certain other clinical disorders. Although the leukemogenic mechanism of HTLV-1 is not fully understood yet, the viral Tax protein is widely regarded as a key factor in this mechanism. Tax can modulate the synthesis or function of many regulatory factors which control a wide range of normal and oncogenic cellular processes and therefore, it acts as a potent oncoprotein. In the last few years, special attention has been attracted to Tax interference with the transactivation function of p53, a tumor-suppressor protein that is involved in regulation of the cell-cycle and apoptosis and in maintaining the cellular genome integrity. p53 is mutated in approximately 60% of all human tumors. In contrast, mutant p53 is found in only small percentage of ATL patients. Nevertheless, p53 is inactive in the leukemic cells of most ATL patients and in most HTLV-1 transformed cells. By inactivating p53, Tax can immortalize the HTLV-1-infected cells and destabilize their genome. Consequently, such cells can progress toward the ultimate leukemic state by a stepwise accumulation of oncogenic mutations and other types of chromosomal aberrations. Furthermore, since p53 exists in most ATL patients in its wild-type form, its reactivation by therapeutic drugs might be an effective approach for ATL therapy. Several mechanisms have been proposed so far for Tax-induced p53 inactivation. Understanding the exact mechanism of this Tax effect is essential for designing effective means for this therapeutic approach. In this review article, we discuss the various mechanisms proposed for Tax interference with p53 functions and their clinical and therapeutic implications.

Molecular mechanisms of cellular transformation by HTLV-1 Tax.

The HTLV Tax protein is crucial for viral replication and for initiating malignant transformation leading to the development of adult T-cell leukemia. Tax has been shown to be oncogenic, since it transforms and immortalizes rodent fibroblasts and human T-lymphocytes. Through CREB, NF-kappaB and SRF pathways Tax transactivates cellular promoters including those of cytokines (IL-13, IL-15), cytokine receptors (IL-2Ralpha) and costimulatory surface receptors (OX40/OX40L) leading to upregulated protein expression and activated signaling cascades (e.g. Jak/STAT, PI3Kinase, JNK). Tax also stimulates cell growth by direct binding to cyclin-dependent kinase holenzymes and/or inactivating tumor suppressors (e.g. p53, DLG). Moreover, Tax silences cellular checkpoints, which guard against DNA structural damage and chromosomal missegregation, thereby favoring the manifestation of a mutator phenotype in cells.

High levels of cytoplasmic HTLV-1 Tax mutant proteins retain a Tax-NF-kappaB-CBP ternary complex in the cytoplasm.

The oncogenic potential of HTLV-1 Tax protein is partially ascribed to its capacity to activate NF-kappaB. The current view is that Tax acts first in the cytoplasm to dissociate NF-kappaB factors from the IkappaB proteins and enable their nuclear translocation, then Tax links p65(RelA), within the nucleus, to CBP/p300 and P/CAF, which are essential for its optimal transcriptional activity. Our present study challenges the paradigm that Tax-p65(RelA)-CBP/p300 assembly occurs in the nucleus. Using Tax mutants defective for nuclear localization we show that at low levels these mutants induce the nuclear translocation of NF-kappaB factors but not their transcriptional activity, whereas at high levels they trap CBP and free p65(RelA) in the cytoplasm and block, thereby, their transcriptional function. In contrast, wild-type (w.t.) Tax strongly stimulated NF-kappaB-dependent gene expression in all tested experimental settings. These data suggest that the Tax-p65(RelA)-CBP ternary complex is established in the cytoplasm rather than in the nucleus. When this complex is formed with w.t. Tax, the entire moiety translocates into the nucleus and exerts high transcriptional activity. However, if the complex is formed with the cytoplasmic Tax mutants, the resulting moiety is retained in the cytoplasm and is, therefore, devoid of transcriptional activity.

Implications of the evolution pattern of human T-cell leukemia retroviruses on their pathogenic virulence (Review).

Simian retroviruses pose a serious threat to public health, as two human pathogenic retroviruses, HIV and HTLV, have been already proved to originate from such non-human viruses. Therefore, studying their natural prevalence among wild non-human primates is important for planning strategies to prevent the emergence of additional human retroviral pathogens. This article is focused on tracing the origin and evolution of the human T-cell leukemia viruses HTLV-I and HTLV-II in comparison to that of the simian lymphotropic viruses STLV-I, STLV-II and STLV-L, which are phylo-genically classified into a common group called primate T-lymphotropic viruses (PTLV). Thus, HTLV-I and STLV-I are referred to as PTLV-I and HTLV-II and STLV-II as PTLV-II, whereas STLV-L, which is highly divergent from both HTLV types, comprises a third subgroup called PTLV-L. The phylogeny of PTLV indicates that both, HTLV-I and HTLV-II emerged from a simian origin, but their subsequent evolution continued in different patterns. HTLV-I includes 6 subtypes which evolved from STLV-I through several times of different geographic interspecies transmission between simian and human hosts. These repeated invasions to new primate species are likely to give rise to viral strains with increasing pathogenic potential. On the other hand, HTLV-II includes 4 subtypes which appear to originate from a common human ancestor virus that emerged from only one simian to human transmission, whereas the subsequent evolution of HTLV-II and STLV-II strains continued separately only within the Homo sapiens and Pan paniscus species respectively, without repeated interspecies jumps. Such evolution pattern likely involves less genetic changes and selection of viral strains with low pathogenic virulence that could co-exist with their hosts for long time. These different evolution patterns can explain the much wider implication of HTLV-I with human clinical disorders than HTLV-II. Of note, however, more recently HTLV-II started spreading much more rapidly through intravenous drug users to many geographical regions, with a 150-350 fold higher mutation rate than that of its previous strictly endemic strains. This change in the mode of the virus spread creates a serious risk for emergence of HTLV-II strains with higher virulence.

Role of Tax protein in human T-cell leukemia virus type-I leukemogenicity.

HTLV-1 is the etiological agent of adult T-cell leukemia (ATL), the neurological syndrome TSP/HAM and certain other clinical disorders. The viral Tax protein is considered to play a central role in the process leading to ATL. Tax modulates the expression of many viral and cellular genes through the CREB/ATF-, SRF- and NF-kappaB-associated pathways. In addition, Tax employs the CBP/p300 and p/CAF co-activators for implementing the full transcriptional activation competence of each of these pathways. Tax also affects the function of various other regulatory proteins by direct protein-protein interaction. Through these activities Tax sets the infected T-cells into continuous uncontrolled replication and destabilizes their genome by interfering with the function of telomerase and topoisomerase-I and by inhibiting DNA repair. Furthermore, Tax prevents cell cycle arrest and apoptosis that would otherwise be induced by the unrepaired DNA damage and enables, thereby, accumulation of mutations that can contribute to the leukemogenic process. Together, these capacities render Tax highly oncogenic as reflected by its ability to transform rodent fibroblasts and primary human T-cells and to induce tumors in transgenic mice. In this article we discuss these effects of Tax and their apparent contribution to the HTLV-1 associated leukemogenic process. Notably, however, shortly after infection the virus enters into a latent state, in which viral gene expression is low in most of the HTLV-1 carriers' infected T-cells and so is the level of Tax protein, although rare infected cells may still display high viral RNA. This low Tax level is evidently insufficient for exerting its multiple oncogenic effects. Therefore, we propose that the latent virus must be activated, at least temporarily, in order to elevate Tax to its effective level and that during this transient activation state the infected cells may acquire some oncogenic mutations which can enable them to further progress towards ATL even if the activated virus is re-suppressed after a while. We conclude this review by outlining an hypothetical flow of events from the initial virus infection up to the ultimate ATL development and comment on the risk factors leading to ATL development in some people and to TSP/HAM in others.

Activation of simian virus 40 promoter by HTLV-I Tax protein: role of NF-kappaB and CBP.

HTLV-I is implicated with adult T-cell leukemia and certain other clinical disorders. The viral Tax protein is regarded as a key element in HTLV-I pathogenicity due to its ability to activate a wide variety of cellular regulatory factors. As such, Tax may likely activate also latent infection of certain other pathogenic viruses whose expression is modulated by cellular transcription factors. Therefore, investigation of Tax effect on the expression of these viruses is of particular clinical importance, since HTLV-I infection of carriers harboring such latent viruses may trigger their related diseases. In this study we focused on simian virus 40 and demonstrated that Tax activates the promoter of this virus through NF-kappaB-associated pathway. Furthermore, we show that this activation requires an interaction of the NF-kappaB factor p65(RelA) with CBP, which depends on PKA-mediated phosphorylation of p65(RelA). Finally, the present study proves that the nuclear Tax plays a critical role in Tax-induced NF-kappaB-mediated SV40 activation.

Role of protein kinase C and the Sp1-p53 complex in activation of p21(WAF-1) expression by 12-O-tetradecanoylphorbol-13-acetate in human T cells.

Previous reports have shown that, in certain cell types, p21(WAF-1), which plays a central role in cell proliferation, can be activated by HTLV-I Tax protein and by TPA. Tax and TPA are also known to stimulate HTLV-I gene expression. Since cell proliferation has a major impact on HTLV-I replication, it was of interest to investigate their effect on p21(WAF-1) in human T cells, which are the main target of HTLV-I in human infection. This study demonstrates that p21(WAF-1) is activated in such cells by both factors, each acting through a different mechanism that does not influence the other. The effect of TPA is shown to require PKC activity. Notably, however, examination of different PKC isoforms revealed that PKC-alpha and PKC-epsilon stimulated p21(WAF-1) expression, whereas PKC-eta was rather inhibitory and PKC-beta1 and beta2 were ineffective. All these isoforms were found to be activated by TPA in the employed T cells, but this apparent paradox was resolved by the observation that when coexpressed together in these cells, the stimulatory PKCs override the inhibitory isoform. Further experiments demonstrated that the PKC-induced p21(WAF-1) activation was mediated by binding of Sp1-p53 complex to the second most upstream of the six Sp1 recognition sites present in its promoter and that this effect did not require the cooperation of an p53-binding site.

Activation of HTLV-I long terminal repeat by apoptosis inducing agents: mechanism and implications for HTLV-I pathogenicity (review).

HTLV-I is the etiological agent of adult T-cell leukemia (ATL), tropical spastic paraparesis/HTLV-I associated myelopathy (TSP/HAM) and certain other clinical disorders. After infection in human the virus enters into a latent state, in which very low viral gene expression can be detected. On the other hand several major characteristics of ATL and TSP/HAM indicate that their genesis requires activation of the dormant virus. TSP/HAM is characterized by high virus expression, which accounts for most of its immunopathological manifestations, whereas the process leading to ATL is believed to be initiated by the viral Tax protein, implying that it requires, at least, a temporary activation of the latent virus. Data from our and other laboratories suggest that this activation may likely be induced by environmental or/and intrinsic apoptosis-inducing factors. Moreover, we have demonstrated a mechanistic linkage between the activation of the viral promoter and the early stage of the apoptotic cascade. However, we have also shown that Tax rescues virus-expressing T-cells from apoptotic death. This suggests that Tax protein, emerging after activation of the latent virus, can rescue the host cells of the activated virus from the ultimate apoptotic death. Since the development of both TSP/HAM and ATL seems to depend on the viral Tax protein, we describe a possible system for anti Tax gene-therapy approach based on a negative transdominant mutant Tax gene.