In vivo bioluminescent monitoring of chemical toxicity using heme oxygenase-luciferase transgenic mice.

Transgenic mice expressing the luciferase (luc) gene under the control of the heme oxygenase-1 promoter (Ho1) were used to measure the induction of heme oxygenase in response to known toxicants. Transgenic Ho1-luc expression was visualized in vivo using a low-light imaging system (IVIS). Ho1-luc activation was compared to Ho1-luc expression, HO1 protein levels, standard markers of toxicity, and histology. Male and female Ho1-luc transgenic mice were exposed to acute doses of cadmium chloride (CdCl2, 3.7 mg/kg), doxorubicin (15 mg/kg), and thioacetamide (300 mg/kg). These agents induced the expression of Ho1-luc in the liver and other tissues to varying degrees. The greatest increase in Ho1-luc activity was observed in the liver in response to CdCl2; intermediate responses were observed for doxorubicin and thioacetamide. Induction of the Ho1-luc transgene by these agents was similar to endogenous protein levels of heme oxygenase as assessed by Western blotting, and generally correlated with plasma levels of circulating enzymes reflecting hepatic or general tissue damage. Histopathology confirmed the toxic effects of CdCl2 on liver and kidney; doxorubicin on kidney, liver, and intestine; and thioacetamide on the liver. Tissue damage was much more pronounced than the luciferase expression following thioacetamide treatment when compared with tissue damage and bioluminescence of the other toxicants. Nevertheless, the induction of Ho1-luc expression following exposure to these agents suggests that the Ho1-luc transgenic mouse may prove useful as a model for in vivo screening of compounds that induce luciferase expression as a marker of toxicity.

The characterization and hormonal regulation of kidney androgen-regulated protein (Kap)-luciferase transgenic mice.

The androgen-dependent regulation for the gene encoding the kidney androgen regulated protein (Kap) was examined in transgenic mice expressing luciferase (luc) under the control of the murine Kap promoter. Biophotonic imaging was used to visualize luciferase expression from the kidneys and various organs that was confirmed using luminometer assays. Kap-luc expression was observed at high levels in kidneys, epididymides, testes, and seminal vesicles in male mice, and in kidneys, ovaries, and uterus in female mice. Kap-luc expression was modulated by androgen and anti-androgen treatment in both male and female mice. Male mice were treated daily with the anti-androgenic compounds, cyproterone acetate (50 and 100 mg/kg/day) and flutamide (50 and 100 mg/kg/day), or vehicle for 16 days. Endpoints evaluated included in vivo biophotonic imaging, body weights, organ weights (liver, kidney, testes, epididymides, preputial gland, and seminal vesicles), protein luciferase assays and Western blot analysis. Biophotonic imaging was used to follow Kap-luc expression from each animal throughout the experiment using a sensitive imaging system. These imaging results correlated well with Western blot analysis and traditional endpoints of body and organ weights. Following treatment with anti-androgens, the luciferase signal was found to significantly decrease in the intact male mouse using in vivo biophotonic imaging and correlated with measurements of luciferase activity in homogenized organ extracts. The decrease in epididymal and seminal vesicle weight confirmed the action of the anti-androgens. In vivo imaging documented significant changes in luciferase expression within the first few days of the experiment indicative of the anti-androgenic activity of the drugs. Testosterone treatment significantly increased the Kap-luc bioluminescent signal in female mice. This increased luciferase induction was shown to be inhibited by coadministration of cyproterone (100 mg/kg/day). Our results indicate that biophotonic imaging may provide a useful approach for noninvasively tracking the effects of endocrine disruptors in specific tissues.

Tumor induction by an Lck-MyrAkt transgene is delayed by mechanisms controlling the size of the thymus.

Transgenic mice expressing MyrAkt from a proximal Lck promoter construct develop thymomas at an early age, whereas transgenic mice expressing constitutively active Lck-AktE40K develop primarily tumors of the peripheral lymphoid organs later in life. The thymus of 6- to 8-week-old MyrAkt transgenic mice is normal in size but contains fewer, larger cells than the thymus of nontransgenic control and AktE40K transgenic mice. Earlier studies had shown that cell size and cell cycle are coordinately regulated. On the basis of this finding, and our observations that the oncogenic potential of Akt correlates with its effect on cell size, we hypothesized that mechanisms aimed at maintaining the size of the thymus dissociate cell size and cell cycle regulation by blocking MyrAkt-promoted G(1) progression and that failure of these mechanisms may promote cell proliferation resulting in an enlarged neoplastic thymus. To address this hypothesis, we examined the cell cycle distribution of freshly isolated and cultured thymocytes from transgenic and nontransgenic control mice. The results showed that although neither transgene alters cell cycle distribution in situ, the MyrAkt transgene promotes G(1) progression in culture. Freshly isolated MyrAkt thymocytes express high levels of cyclins D2 and E and cdk4 but lower than normal levels of cyclin D3 and cdk2. Cultured thymocytes from MyrAkt transgenic mice, on the other hand, express high levels of cyclin D3, suggesting that the hypothesized organ size control mechanisms may down-regulate the expression of this molecule. Primary tumor cells, similar to MyrAkt thymocytes in culture, express high levels of cyclin D3. These findings support the hypothesis that tumor induction is caused by the failure of organ size control mechanisms to down-regulate cyclin D3 and to block MyrAkt-promoted G(1) progression.

Oncogenic transformation induced by membrane-targeted Akt2 and Akt3.

The kinases Akt2, Akt3 and their myristylated variants, Myr-Akt2 and Myr-Akt3 were expressed by the RCAS vector in chicken embryo fibroblasts (CEF). Myr-Akt2 and Myr-Akt3 were strongly oncogenic, inducing multilayered foci of transformed cells. In contrast, wild-type Akt2 and Akt3 were only poorly transforming, their efficiencies of focus formation were more than 100-fold lower; foci appeared later and showed less multilayering. Addition of the myristylation signal not only enhanced oncogenic potential but also increased kinase activities. Myr-Akt2 and Myr-Akt3 also induced hemangiosarcomas in the animal, whereas wild type Akt2 and Akt3 were not oncogenic in vivo. Furthermore, Akt2, driven by the lck (lymphocyte specific kinase) promoter in transgenic mice, induced lymphomas. The oncogenic effects of Akt2 and Akt3 described here are indistinguishable from those of Akt1. The downstream targets relevant to oncogenic transformation are therefore probably shared by the three Akt kinases.

Tcl1 enhances Akt kinase activity and mediates its nuclear translocation.

The TCL1 oncogene at 14q32.1 is involved in the development of human mature T-cell leukemia. The mechanism of action of Tcl1 is unknown. Because the virus containing the v-akt oncogene causes T-cell lymphoma in mice and Akt is a key player in transduction of antiapoptotic and proliferative signals in T-cells, we investigated whether Akt and Tcl1 function in the same pathway. Coimmunoprecipitation experiments showed that endogenous Akt1 and Tcl1 physically interact in the T-cell leukemia cell line SupT11; both proteins also interact when cotransfected into 293 cells. Using several AKT1 constructs in cotransfection experiments, we determined that this interaction occurs through the pleckstrin homology domain of the Akt1 protein. We further demonstrated that, in 293 cells transfected with TCL1, the endogenous Akt1 bound to Tcl1 is 5-10 times more active compared with Akt1 not bound to Tcl1. The intracellular localization of Tcl1 and Akt1 in mouse fibroblasts was investigated by immunofluorescence. When transfected alone, Akt1 was found only in cytoplasm whereas Tcl1 was localized in the cytoplasm and in the nucleus. Interestingly, Akt1 was also found in the nucleus when AKT1 was cotransfected with TCL1, suggesting that Tcl1 promotes the transport of Akt1 to the nucleus. These findings were supported by the intracellular localization of Akt1 or Tcl1 when Tcl1 or Akt1, respectively, were confined to the specific cellular compartments. Thus, we demonstrate that Tcl1 is a cofactor of Akt1 that enhances Akt1 kinase activity and promotes its nuclear transport.

Cyclin D expression is controlled post-transcriptionally via a phosphatidylinositol 3-kinase/Akt-dependent pathway.

Cyclin D expression is regulated by growth factors and is necessary for the induction of mitogenesis. Herbimycin A, a drug that binds to Hsp90, induces the destruction of tyrosine kinases and causes the down-regulation of cyclin D and an Rb-dependent growth arrest in the G1 phase of the cell cycle. We find that the induction of D-cyclin expression by serum and its repression by herbimycin A are regulated at the level of mRNA translation. Induction of cyclin D by serum occurs prior to the induction of its mRNA and does not require transcription. Herbimycin A repression is characterized by a decrease in the synthetic rate of D-cyclins prior to changes in mRNA expression and in the absence of changes in the half-life of the protein. This effect on D-cyclin translation is mediated via a phosphatidylinositol 3-kinase (PI 3-kinase)-dependent pathway. PI 3-kinase inhibitors such as wortmannin and LY294002, and rapamycin, an inhibitor of FRAP/TOR, cause a decline in the level of D-cyclins, whereas inhibitors of mitogen-activated protein kinase kinase and farnesyltransferase do not. Cells expressing the activated, myristoylated form of Akt kinase, a target of PI 3-kinase, are refractory to the effects of herbimycin A or serum starvation on D-cyclin expression. These data suggest that serum induction of cyclin D expression results from enhanced translation of its mRNA and that this results from activation of a pathway that is dependent upon PI 3-kinase and Akt kinase.

Akt activation by growth factors is a multiple-step process: the role of the PH domain.

The protein kinase encoded by the Akt proto-oncogene is activated by phospholipid binding, membrane translocation and phosphorylation. To address the relative roles of these mechanisms of Akt activation, we have employed a combination of genetic and pharmacological approaches. Transient transfection of NIH3T3 cells with wild-type Akt, pleckstrin homology (PH) domain mutants, generated on the basis of a PH domain structural model, and phosphorylation site Akt mutants provided evidence for a model of Akt activation consisting of three sequential steps: (1) a PH domain-dependent, growth factor-independent step, marked by constitutive phosphorylation of threonine 450 (T450) and perhaps serine 124 (S124), that renders the protein responsive to subsequent activation events; (2) a growth factor-induced, PI3-K-dependent membrane-translocation step; and (3) a PI3-K-dependent step, characterized by phosphorylation at T308 and S473, that occurs in the cell membrane and is required for activation. When forced to translocate to the membrane, wild-type Akt and PH domain Akt mutants that are defective in the first step become constitutively active, suggesting that the purpose of this step is to prepare the protein for membrane translocation. Both growth factor stimulation and forced membrane translocation, however, failed to activate a T308A mutant. This, combined with the finding that T308D/S473D double mutant is constitutively active, suggests that the purpose of the three-step process of Akt activation is the phosphorylation of the protein at T308 and S473. The proposed model provides a framework for a comprehensive understanding of the temporal and spatial requirements for Akt activation by growth factors.

Activation of the c-fos serum response element by phosphatidyl inositol 3-kinase and rho pathways in HeLa cells.

Many growth factors rapidly induce transcription of the c-fos proto-oncogene. We have investigated the pathways for induction of the c-fos promoter by serum and epidermal growth factor (EGF) in HeLa cells. Induction of the serum response element (SRE) of the c-fos promoter could be split into two parts, one involving the serum response factor-associated ternary complex factor (TCF) factors and the second mediated by core SRE sequences. Serum induction was mediated primarily by the core SRE, whereas EGF used both the TCF and core SRE pathways. Using activated and inhibitory signaling proteins, we found that phosphatidyl inositol 3-kinase (PI3K) and rho family members could mediate activation by serum. Activation by PI3K was mediated by core SRE sequences and was dependent upon rac and rho, suggesting a PI3K-to-rac-to-rho pathway for core SRE activation. The PI3K target Akt was also capable of activating the SRE but functioned through the TCF pathway, suggesting that Akt does not mediate the primary PI3K pathway to the SRE and that Akt is capable of activating TCF family members. Serum and EGF induction of the core SRE was partially inhibited by rho and PI3K inhibitors. The use of these inhibitors demonstrates the complexity of signaling pathways to the SRE and suggests that serum activates rho by PI3K-dependent and -independent pathways.

Bik, a novel death-inducing protein shares a distinct sequence motif with Bcl-2 family proteins and interacts with viral and cellular survival-promoting proteins.

The survival-promoting activity of the Bcl-2 family of proteins appears to be modulated by interactions between various cellular proteins. We have identified a novel cellular protein, Bik, that interacts with the cellular survival-promoting proteins, Bcl-2 and Bcl-xL, as well as the viral survival-promoting proteins, Epstein Barr virus-BHRF1 and adenovirus E1B-19 kDa. In transient transfection assays, Bik promotes cell death in a manner similar to the death-promoting members of the Bcl-2 family, Bax and Bak. This death-promoting activity of Bik can be suppressed by coexpression of Bcl-2, Bcl-XL, EBV-BHRF1 and E1B-19 kDa proteins suggesting that Bik may be a common target for both cellular and viral anti-apoptotic proteins. While Bik does not show overt homology to the BH1 and BH2 conserved domains characteristic of the Bcl-2 family, it does share a 9 amino acid domain (BH3) with Bax and Bak which may be a critical determinant for the death-promoting activity of these proteins.

Adenovirus E1B 19 kDa and Bcl-2 proteins interact with a common set of cellular proteins.

Adenovirus E1B 19 kDa protein protects against cell death induced by viral infection and certain external stimuli. The Bcl-2 protein can functionally substitute for the E1B 19 kDa protein. To identify cellular targets for the 19 kDa protein, we used the two-hybrid screen in yeast. We have isolated cDNAs for three different proteins, designated Nip1, Nip2, and Nip3, that interact with the 19 kDa protein. Mutational analysis indicates that these proteins do not associate with 19 kDa mutants defective in suppression of cell death, suggesting a correlation between interaction of these proteins and suppression of cell death. These proteins also associate with discrete sequence motifs in the Bcl-2 protein that are homologous to motifs of the 19 kDa protein. Our results suggest that two diverse proteins, the E1B 19 kDa and the Bcl-2 proteins, promote cell survival through interaction with a common set of cellular proteins.

Requirement of the C-terminal region of adenovirus E1a for cell transformation in cooperation with E1b.

We have previously reported that adenovirus E1a mutants lacking the C-terminal 61 or 67 amino acids were severely defective in immortalization, but cooperated more efficiently (than wt E1a) with activated T24 ras oncogene in transformation of primary rat kidney (BRK) cells (Subramanian et al., 1989; Oncogene, 4:415-420). Here, we show that in contrast to these previous results, transformation of BRK cells in cooperation with the Ad2 E1b region is dependent on the C-terminal region of E1a. Mutational analysis of the C-terminal region has revealed that a region located between residues 266 and 276 may be important for E1a/E1b cooperative transformation. Like E1a/T24 ras cooperative transformation, E1a/E1b cooperative transformation also requires two essential domains involved in the binding of two cellular proteins (300K and 105K) within the N-terminal half of E1a. E1a/E1b cooperative transformation therefore requires an additional E1a activity encoded within the C-terminal region of E1a.