IKBKE is induced by STAT3 and tobacco carcinogen and determines chemosensitivity in non-small cell lung cancer

Serine/threonine kinase IKBKE is a newly identified oncogene; however, its regulation remains elusive. Here, we provide evidence that IKBKE is a downstream target of signal transducer and activator of transcription 3 (STAT3) and that tobacco components induce IKBKE expression through STAT3. Ectopic expression of constitutively active STAT3 increased IKBKE mRNA and protein levels, whereas inhibition of STAT3 reduced IKBKE expression. Furthermore, expression levels of IKBKE are significantly associated with STAT3 activation and tobacco use history in non-small cell lung cancer (NSCLC) patients examined. In addition, we show induction of IKBKE by two components of cigarette smoke, nicotine and nicotine-derived nitrosamine ketone (NNK). Upon exposure to nicotine or NNK, cells express high levels of IKBKE protein and mRNA, which are largely abrogated by inhibition of STAT3. Characterization of the IKBKE promoter revealed two STAT3-response elements. The IKBKE promoter directly bound to STAT3 and responded to nicotine and NNK stimulation. Notably, enforcing expression of IKBKE induces chemoresistance, whereas knockdown of IKBKE not only sensitizes NSCLC cells to chemotherapy but also abrogates STAT3- and nicotine-induced cell survival. These data indicate for the first time that IKBKE is a direct target of STAT3 and is induced by tobacco carcinogens through STAT3 pathway. In addition, our study also suggests that IKBKE is an important therapeutic target and could have a pivotal role in tobacco-associated lung carcinogenesis.

Effect of nicotine on chemoresistant phenotype as mediated through Src-dependent Id1 expression in pancreatic adenocarcinoma cells

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Background: The signaling pathways contributing to DNA-binding protein inhibitor Id1 expression and chemoresistance in pancreatic cancer remain unknown. Id1 plays a role in pancreatic tumor progression with tumor-promoting effects of nicotine regulating protein tyrosine kinase Src activation and Id1 expression, both associated with chemoresistance in other systems. We hypothesize Id1 expression regulates chemoresistance in pancreatic cancer through a nicotine-promoting Src-dependent pathway.

Methods: We probed pancreatic cancer cell lines (L3.6pl, PANC-1, Mia-PaCa-2) for innate gemcitabine chemoresistance with cell viability MTT assay and western blot analysis of PARP cleavage programmed cell death. Gemcitabine-sensitive cells were exposed to rising gemcitabine concentrations to establish a resistant subtype, L3.6plGemRes. Protein analysis and mRNA expression were determined by western blot analysis and RT-PCR respectively. Induction of Src phosphorylation or Id1 expression was performed with nicotine (1 μM).

Results: Inhibition of c-Src expression was performed with short-interfering RNA (siRNA). Nicotine-induced Src phosphorylation and Id1 expression. Inhibition of Src by siRNA resulted in decreased nicotine-induced Id1 expression. Inhibition of Src and Id1 expression by siRNA in innate or established gemcitabine resistant pancreatic cancer cells resulted in gemcitabine sensitization. To determine if nicotine contributes to gemcitabine chemoresistance, we exposed gemcitabine-sensitive cells to nicotine with subsequent exposure to gemcitabine IC50, 250 ng/ml, and cell viability assays confirmed a 2-fold increase in cell prolilferation and a 4.5-fold reduction in apoptosis. Further, nicotine induced phosphorylation of key signaling enzymes involved in proliferation and apoptosis, Erk1/2 and Akt respectively.

Conclusions: In summary, we demonstrate that Id1, through a nicotine-promoting Src-dependent pathway, is necessary for establishment of a chemoresistant phenotype in pancreatic cancer cells. Understanding the signaling pathways involved in pancreatic tumor chemoresistance will lead to therapies resulting in improved tumor responses.

No significant financial relationships to disclose.

HOG on the promoter: regulation of the osmotic stress response

Members of the mitogen-activated protein (MAP) kinase family regulate transcription through phosphorylation of specific transcription factors. New studies indicate that this process may be more complex than previously anticipated. The yeast Hog1 protein kinase (a homolog of the mammalian p38 MAP kinase) interacts with transcription factors and perhaps with the general transcription machinery at target promoters. Chellappan discusses the recent results and their implications for understanding control of transcription by stress-activated MAP kinases.

Rb dephosphorylation and suppression of E2F activity in human breast tumor cells exposed to a pharmacological concentration of estradiol

This report characterizes the influence of a pharmacological concentration of estradiol on growth arrest and cell death in MCF-7 breast tumor cells, with a focus on elements of the Rb-E2F cell-cycle regulatory pathway. Continuous exposure of MCF-7 breast tumor cells to 100 microM estradiol produces a marked reduction in the G1 and S phase populations and a corresponding increase in the G2/M population within 24 h; after 48 h, accumulation of cells in G1 becomes evident while after 72 h the cells appear to be equally distributed between the G1 and G2/M phases. The accumulation of cells in G1 is temporally associated with dephosphorylation of the Rb protein and suppression of E2F activity. Estradiol also produces an initial burst of cell death with loss of approximately 40% of the tumor cell population within 24 h; however, there is no tangible evidence for the occurrence of apoptosis based on terminal transferase end-labeling of DNA, DNA fragmentation analysis by alkaline unwinding, cell-cycle analysis or cell morphology. In addition to the lack of caspase-3 in MCF-7 cells, the absence of apoptosis could be related, at least in part, to the fact that estradiol promotes a rapid reduction in levels of the E2F-1 and Myc proteins. Overall, these studies are consistent with the concept that alterations in the levels and/or activity of the E2F family of proteins as well as proteins interacting with the E2F family may influence the nature of the antiproliferative and cytotoxic responses of the breast tumor cell.

The cyclin-dependent kinase inhibitor (CDKI) flavopiridol disrupts phorbol 12-myristate 13-acetate-induced differentiation and CDKI expression while enhancing apoptosis in human myeloid leukemia cells

Interactions between the cyclin-dependent kinase inhibitor (CDKI) flavopiridol (FP) and phorbol 12-myristate 13-acetate (PMA) were examined in U937 human leukemia cells in relation to differentiation and apoptosis. Simultaneous, but not sequential, exposure of U937 cells to 100 nM FP and 10 nM PMA significantly increased apoptosis manifested by characteristic morphological features, mitochondrial dysfunction, caspase activation, and poly(ADP-ribose) polymerase cleavage while markedly inhibiting cellular differentiation, as reflected by diminished plastic adherence and CD11b expression. Enhanced apoptosis in U937 cells was associated with an early caspase-independent increase in cytochrome c release and accompanied by a substantial decline in leukemic cell clonogenicity. Moreover, PMA/FP cotreatment significantly increased apoptosis in HL-60 promyelocytic leukemia cells and in U937 cells ectopically expressing the Bcl-2 protein. In U937 cells, coadministration of FP blocked PMA-induced expression and reporter activity of the CDKI p21WAF/CIP1 and triggered caspase-mediated cleavage of the CDKI p27KIP1. Coexposure to FP also resulted in a more pronounced and sustained activation of the mitogen-activated protein kinase kinase/extracellular signal-regulated protein kinase cascade after PMA treatment, although disruption of this pathway by the mitogen-activated protein kinase kinase 1 inhibitor U0126 did not prevent potentiation of apoptosis. FP accelerated PMA-mediated dephosphorylation of the retinoblastoma protein (pRb), an event followed by pRb cleavage culminating in the complete loss of underphosphorylated pRb (approximately Mr 110,000) by 24 h. Finally, gel shift analysis revealed that coadministration of FP with PMA for 8 h led to diminished E2F/pRb binding compared to the effects of PMA alone. Collectively, these findings indicate that FP modulates the expression/activity of multiple signaling and cell cycle regulatory proteins in PMA-treated leukemia cells and that such alterations are associated with mitochondrial damage and apoptosis rather than maturation. These observations also raise the possibility that combining CDKIs and differentiation-inducing agents may represent a novel antileukemic strategy.

HLA class I-mediated induction of cell proliferation involves cyclin E-mediated inactivation of Rb function and induction of E2F activity

Chronic rejection of transplanted organs is manifested as atherosclerosis of the blood vessels of the allograft. HLA class I Ags have been implicated to play a major role in this process, since signaling via HLA class I molecules can induce the proliferation of aortic endothelial as well as smooth muscle cells. In this study, we show that HLA class I-mediated induction of cell proliferation correlates with inactivation of the Rb protein in the T cell line Jurkat as well as human aortic endothelial cells. HLA class I-mediated inactivation of Rb can be inhibited specifically by neutralizing Abs to basic fibroblast growth factor (bFGF), suggesting a role for FGF receptors in the signaling process. Signaling through HLA class I molecules induced cyclin E-associated kinase activity within 4 h in quiescent endothelial cells, and appeared to mediate the inactivation of Rb. A cdk2 inhibitor, Olomoucine, as well as a dominant-negative cdk2 construct prevented HLA class I-mediated inactivation of Rb; in contrast, dominant-negative cdk4 and cdk6 constructs had no effect. Furthermore, there was no increase in cyclin D-associated kinase activity upon HLA class I ligation, suggesting that cyclin E-dependent kinase activity mediates Rb inactivation, leading to E2F activation and cell proliferation.

Raf-1 physically interacts with Rb and regulates its function: a link between mitogenic signaling and cell cycle regulation

Cells initiate proliferation in response to growth factor stimulation, but the biochemical mechanisms linking signals received at the cell surface receptors to the cell cycle regulatory molecules are not yet clear. In this study, we show that the signaling molecule Raf-1 can physically interact with Rb and p130 proteins in vitro and in vivo and that this interaction can be detected in mammalian cells without overexpressing any component. The binding of Raf-1 to Rb occurs subsequent to mitogen stimulation, and this interaction can be detected only in proliferating cells. Raf-1 can inactivate Rb function and can reverse Rb-mediated repression of E2F1 transcription and cell proliferation efficiently. The region of Raf-1 involved in Rb binding spanned residues 1 to 28 at the N terminus, and functional inactivation of Rb required a direct interaction. Serum stimulation of quiescent human fibroblast HSF8 cells led to a partial translocation of Raf-1 into the nucleus, where it colocalized with Rb. Further, Raf-1 was able to phosphorylate Rb in vitro quite efficiently. We believe that the physical interaction of Raf-1 with Rb is a vital step in the growth factor-mediated induction of cell proliferation and that Raf-1 acts as a direct link between cell surface signaling cascades and the cell cycle machinery.

Divergent effects of bryostatin 1 and phorbol myristate acetate on cell cycle arrest and maturation in human myelomonocytic leukemia cells (U937)

Bryostatin 1 and the phorbol ester, phorbol myristate acetate (PMA), both bind to and activate protein kinase C (PKC) but exhibit divergent biological actions. Bryostatin 1 exerts variable effects on leukemic cell differentiation, and has been reported by some investigators to inhibit the proliferation of the monocytic leukemic cell line U937. In this study, we have compared the efficacy of bryostatin 1 and PMA with respect to U937 cell maturation, with a major emphasis on differential actions on the cell cycle arrest machinery. At equimolar concentrations (10 nM), PMA, in contrast to bryostatin 1, induced cellular differentiation of U937 cells, reflected by growth inhibition, increased plastic adhesion, and expression of the monocytic differentiation marker, CD11b. Consistent with these results, bryostatin 1 was less effective in inducing G0/G1 arrest and inhibiting cyclin-dependent kinase 2 (CDK2) activity. Bryostatin 1, unlike PMA, failed to induce expression of the cyclin-dependent kinase inhibitor (CDKI), p21CIP1/WAF1, and blocked the ability of PMA to induce this protein. Bryostatin 1 exposure resulted in increased expression of the CDKI p27KIP1 in these cells, although the kinetics differed from PMA. In addition, bryostatin 1 was less effective than PMA in dephosphorylating pRb, modifying E2F complexes, and downregulating c-Myc. Co-administration of bryostatin 1 with PMA antagonized the latter's differentiation-inducing capacity and anti-proliferative effects, actions that were accompanied by a reduction in PMA-mediated p21CIP1/WAF1 induction, CDK2 inhibition, pRb dephosphorylation, and c-Myc downregulation. Antagonistic effects of bryostatin 1 on PMA-related cell cycle events were mimicked by the specific PKC inhibitor GF109203X. Together, these studies indicate that bryostatin 1 is a considerably weaker stimulus than PMA for U937 cell differentiation, and raise the possibility that this deficiency arises from its failure to induce p21CIP1/WAF1 and trigger cell cycle arrest.

Effects of antisense p21 (WAF1/CIP1/MDA6) expression on the induction of differentiation and drug-mediated apoptosis in human myeloid leukemia cells (HL-60)

The p21MDA6 gene product induces cell cycle arrest in p53-null human leukemic cells exposed to differentiation stimuli. We employed an HL-60 cell line stably transfected with a p21MDA6 antisense construct to compare the effects of p21MDA6 dysregulation on the response of myeloid leukemia cells to differentiating and cytotoxic agents. Antisense-expressing cells (HL-60/AS5) treated with 5 nM PMA for 24 h exhibited attenuated induction of p21MDA6 compared to empty vector controls (HL-60/V2). This phenomenon was accompanied by a reduction in the percentage of cells undergoing G1 arrest (67.6 +/- 4.7 vs 82.9 +/- 1.3; P < or = 0.01) and expressing the monocytic maturation marker cd11b (35.5 +/- 2.8 vs 50.5 +/- 2.4; P < or = 0.005). Although HL-AS5 and HL-60/V2 cells did not exhibit obvious differences in the phosphorylation status of the retinoblastoma protein (pRB), in E2F complex formation, or in p27klp1 induction following PMA exposure, inhibition of activity of cyclin-dependent kinase-2 was attenuated in the antisense-expressing line. A 24-h exposure to 5 nM PMA also reduced the cloning efficiency of HL-60/V2 cells to a significantly greater extent than HL-60/AS5 cells (ie to 30.1 +/- 7.0 vs 57.2 +/- 5.6 of controls; P < or = 0.01). In contrast to the disparate responses to PMA, HL-60/AS5 and HL-60/V2 cells treated with the antimetabolite 1-beta-D-arabinofurano-sylcytosine (Ara-C; 10 microM for 6 h) displayed equal susceptibility to G1 arrest, apoptosis, and inhibition of clonogenicity, phenomena unaccompanied by p21MDA6 and p27klp1 induction, or pRB dephosphorylation. These observations indicate that dysregulation of p21MDA6 in p53-null human myeloid leukemia cells interferes with PMA-related G1 arrest, CDK-2 inhibition, differentiation, and loss of clonogenic survival in the absence of obvious alterations in pRB phosphorylation status or E2F complex formation. They also provide functional evidence that p21MDA6 induction does not appear to be required for Ara-C-induced apoptosis, G1 arrest, or the resulting reduction in the self-renewal capacity of HL-60 cells.

Genomic cloning and chromosomal assignment of the E2F dimerization partner TFDP gene family

The TFDP genes encode a family of transcription factors that can form heterodimers with E2F family proteins in vivo. The E2F-TFDP transcription factors are major regulators of genes that are required for the progression of S-phase, such as DHFR and DNA polymerase alpha, and they play a critical role in cell cycle regulation and differentiation. The retinoblastoma tumor suppressor protein has been shown to induce growth arrest by binding to E2F-TFDP and repressing its activity. Two human TFDP genes have been cloned, namely TFDP1 and TFDP2 (or DP1 and DP2). In the present study, we identified genomic clones of TFDP1, its pseudogene TFDP1P and TFDP2, and we mapped them to chromosome 13q34, 1q32.3, and 3q23, respectively. Chromosomal abnormalities involving regions 13q34 and 3q23 have been reported in certain lymphomas and other diseases associated with loss of cell cycle regulation, and the involvement of the TFDP transcription factors remains to be elucidated.

Cell cycle gene expression and E2F transcription factor complexes in human melanoma cells induced to terminally differentiate

Defects in cellular differentiation are a common occurrence in human cancers. The combination of recombinant human fibroblast interferon (IFN-beta) and the antileukemic compound mezerein (MEZ) results in an irreversible loss of proliferative capacity and terminal cell differentiation in H0-1 human melanoma cells. In contrast, either agent alone induces reversible growth arrest and/or specific components of the differentiation process without inducing terminal differentiation. The current study investigates changes in cell cycle, cell cycle gene expression and E2F transcription factor complex formation during the processes of reversible and irreversible (terminal) differentiation. Induction of both terminal differentiation and reversible differentiation (MEZ treatment) results in a temporal decrease in DNA synthesis and the percentage of cells in S phase and a decrease in the expression of cell cycle and growth regulated genes, including cdc2, cyclin A, cyclin B, histone H1, histone H4, nm23-H1, p53 and c-myc. Persistent gene expression changes occur in terminally differentiated cells, but not in reversibly differentiated cells. H0-1 cells contain several E2F binding activities, including uncomplexed E2F, an E2F-p107-cyclin A-cdk2 kinase complex and an Rb-E2F complex. Induction of growth arrest by MEZ results in a slow migrating gelshift band that contains E2F associated with the pRb2/p130 protein. There is also a loss of the Rb-E2F complex. Induction of terminal differentiation after treatment with IFN-beta + MEZ generates a second pRb2/p130-E2F complex that migrates considerably faster than the pRb2/p130-E2F complex resulting from growth arrest. The slower migrating complex may contribute to growth arrest, whereas the faster migrating complex may play a role in terminal differentiation. Our results demonstrate that terminal cell differentiation involves a co-ordinate and continuous suppression of a number of cell cycle and growth related genes and results in the development of a novel E2F transcription factor complex not apparent in growth arrested and reversibly differentiated human melanoma cells.

Cloning and characterization of human DP2, a novel dimerization partner of E2F

The transcription factor E2F consists of a family of proteins that bind to the sequence TTTCGCGC and regulate the expression of various cellular and viral promoters. E2F binds to DNA as homodimers or as heterodimers in association with a protein, DP1 (for dimerization partner 1). E2F-DP1 heterodimers bind more efficiently than homodimers to DNA, retinoblastoma gene product as well as the adenovirus E4 protein and DP1 can stimulate transcription from E2F sites in a synergistic fashion. Here we describe the cloning and characterization of a novel human DP gene, DP2, whose product dimerizes efficiently with E2F. Unlike DP1, there appear to be multiple transcripts for DP2 and their distribution appears to vary in different tissues and cell lines. DP2 binds to E2F as detected by in vitro reconstitution assays and an E2F-DP2 heterodimer can bind to DNA in gel-retardation assays. We believe that DP2 also plays a major role in modulating the function of E2F in cell cycle regulation and oncogenesis.

Interactions of the p107 and Rb proteins with E2F during the cell proliferation response

The E2F transcription factor is found in complexes with a variety of cellular proteins including the retinoblastoma tumor suppressor protein. Various assays have demonstrated a tight correlation between the functional capacity of Rb as a growth suppressor and its ability to bind to E2F. Moreover, only the underphosphorylated form of Rb, which appears to be the active species, interacts with E2F. Despite the fact that the majority of Rb becomes hyperphosphorylated at the end of G1, we now show that the E2F-Rb interaction persists through the G1/S transition and into S phase. A distinct E2F complex does appear to be regulated in relation to the transition from G1 to S phase. We now demonstrate that this complex contains the Rb-related p107 protein. Moreover, like the Rb protein, p107 inhibits E2F-dependent transcription in a co-transfection assay. This result, together with the observation that free, uncomplexed E2F accumulates as cells leave G1 and enter S phase, suggests that the p107 protein may regulate E2F-dependent transcription during G1. In contrast, although Rb does regulate the transcriptional activity of E2F, this association does not coincide with the G1 to S phase transition.

The interaction of RB with E2F coincides with an inhibition of the transcriptional activity of E2F

Recent experiments have shown that the E2F transcription factor is in a complex with the RB1 gene product. The E2F-pRB complex can be reconstituted in an in vitro assay using a GST-RB fusion protein isolated from Escherichia coli. This interaction is dependent on pRB sequences involved in E1A/T-antigen binding as well as carboxy-terminal pRB sequences that are not necessary for E1A/T binding. Moreover, reconstitution assays reveal a requirement for an accessory factor, in addition to E2F and pRB, for formation of the E2F-pRB complex. Assays of transcription from the adenovirus E2 promoter in transfection experiments demonstrate that formation of the complex containing pRB and E2F coincides with an inhibition of E2F-dependent transcriptional activity. A mutant pRB protein that does not associate with E2F does not inhibit transcription. We conclude that as a consequence of its interaction with E2F, pRB may regulate the transcriptional function of the E2F factor.

The E2F transcription factor is a cellular target for the RB protein

Although it is generally believed that the product of the retinoblastoma susceptibility gene (RB1) is an important regulator of cell proliferation, the biochemical mechanism for its action is unclear. We now show that the RB protein is found in a complex with the E2F transcription factor and that only the under phosphorylated form of RB is in the E2F complex. Moreover, the adenovirus E1A protein can dissociate the E2F-RB complex, dependent on E1A sequence also critical for E1A to bind to RB. These sequences are also critical for E1A to immortalize primary cell cultures and to transform in conjunction with other oncogenes. Taken together, these results suggest that the interaction of RB with E2F is an important event in the control of cellular proliferation and that the dissociation of the complex is part of the mechanism by which E1A inactivates RB function.

DNA octamer element can confer E1A trans-activation, and adenovirus infection results in a stimulation of the DNA-binding activity of OTF-1/NFIII factor

Adenovirus E1A-dependent trans-activation of viral transcription involves the utilization and alteration of multiple sequence-specific transcription factors. Cellular genes are also activated by E1A, one example being the immunoglobulin heavy-chain locus when assayed by transfection into fibroblast cells. We have explored the basis for the E1A-dependent activation of this cellular transcription unit. We demonstrate that the ATTTGCAT ("octamer") element found in the heavy-chain enhancer and promoter is a target for E1A trans-activation since this sequence can confer inducibility to the normally unresponsive simian virus 40 early promoter. In addition, adenovirus infection stimulates the DNA-binding activity of the ubiquitous octamer-specific factor, OTF-1, and we presume that this is the basis for the stimulation of transcription. Although there are no octamer elements in the adenovirus genome that are known to be important for transcription, there are octamer elements in the viral terminal repeat sequences. These elements bind the NFIII factor and are important for the initiation of DNA replication. Since the NFIII factor has been shown to be identical to OTF-1, we suggest that the stimulation of OTF-1/NFIII activity during an adenovirus infection may be important for efficient initiation of adenovirus DNA synthesis.