Geranylgeranylated, but not farnesylated, RhoB suppresses Ras transformation of NIH-3T3 cells

RhoB is a low molecular weight GTPase that is both farnesylated (RhoB-F) and geranylgeranylated (RhoB-GG) in cells. Based on data from rodent cell models, it has been suggested that RhoB displays differential effects on cell transformation, according to the nature of its prenylation. To test directly this hypothesis, we generated GTPase-deficient RhoB mutants that are exclusively either farnesylated or geranylgeranylated. We show that in Ras-transformed murine NIH-3T3 cells, RhoB-F enhances, whereas RhoB-GG and RhoB (F/GG) suppresses anchorage-dependent and -independent cell growth as well as tumor growth in nude mice. We then demonstrate that Ras constitutive activation of the tumor survival pathways Akt and NF-kappa B are blocked by RhoB-GG, but not by RhoB-F, providing further support for the opposing role of RhoB-F and RhoB-GG in Ras malignant transformation in NIH-3T3 cells. In addition, both RhoB (F/GG) and RhoB-GG induce apoptosis in Ras-transformed NIH-3T3 cells whereas RhoB-F has no effect. Our data demonstrate that RhoB-F and RhoB-GG which differ only by a 5-carbon isoprene behave differently in rodent cells highlighting the important role of prenyl groups in protein function and emphasize the potency of RhoB to regulate negatively the oncogenic signal.     

ROCK I-mediated activation of NF-kappaB by RhoB

RhoB is a short-lived protein whose expression is increased by a variety of extra-cellular stimuli including UV irradiation, epidermal growth factor (EGF) and transforming growth factor beta (TGF-beta). Whereas most Rho proteins are modified by the covalent attachment of a geranylgeranyl group, RhoB is unique in that it can exist in either a geranylgeranylated (RhoB-GG) or a farnesylated (RhoB-F) form. Although each form is proposed to have different cellular functions, the signaling events that underlie these differences are poorly understood. Here we show that RhoB can activate NF-kappaB signaling in multiple cell types. Whereas RhoB-F is a potent activator of NF-kappaB, much weaker activation is observed for RhoB-GG, RhoA, and RhoC. NF-kappaB activation by RhoB is not associated with increased nuclear translocation of RelA/p65, but rather, by modification of the RelA/p65 transactivation domain. Activation of NF-kappaB by RhoB is dependent upon ROCK I but not PRK I. Thus, ROCK I cooperates with RhoB to activate NF-kappaB, and suppression of ROCK I activity by genetic or pharmacological inhibitors blocks NF-kappaB activation. Suppression of RhoB activity by dominant-inhibitory mutants, or siRNA, blocks NF-kappaB activation by Bcr, and TSG101, but not by TNFalpha or oncogenic Ras. Collectively, these observations suggest the existence of an endosome-associated pathway for NF-kappaB activation that is preferentially regulated by the farnesylated form of RhoB.     

Farnesylated RhoB Prevents Cell Cycle Arrest and Actin Cytoskeleton Disruption Caused by the Geranylgeranyltransferase I Inhibitor GGTI-298

Here we demonstrate that the geranylgeranyltransferase-I inhibitor GGTI-298 inhibits the RhoB pathway and disrupts stress fiber and focal adhesion formation in NIH-3T3 cells. Farnesylated V14RhoB-CAIM (resistant to GGTI-298), but not geranylgeranylated V14RhoB (-CLLL), prevented inhibition of actin stress fiber and focal adhesion formation, underlining the critical role of RhoB. In contrast, farnesylated, V14RhoA (-CVLS) was unable to prevent effects of GGTI 298 on cytoskeleton organization. Furthermore, the ability of GGTI-298 to induce p21WAF and to block cells in the G0/G1 phase of the cell cycle was also prevented by farnesylated V14RhoB but not by farnesylated V14RhoA. Moreover, treatment with GGTI-298 of cells expressing farnesylated RhoB results in accumulation of these cells in the G2/M phase. Therefore, the RhoB pathway is a critical target of GGTI-298.     

Farnesylated RhoB prevents cell cycle arrest and actin cytoskeleton disruption caused by the geranylgeranyltransferase I inhibitor GGTI-298

Here we demonstrate that the geranylgeranyltransferase-I inhibitor GGTI-298 inhibits the RhoB pathway and disrupts stress fiber and focal adhesion formation in NIH-3T3 cells. Farnesylated (V14)RhoB-CAIM (resistant to GGTI-298), but not geranylgeranylated (V14)RhoB (-CLLL), prevented inhibition of actin stress fiber and focal adhesion formation, underlining the critical role of RhoB. In contrast, farnesylated, (V14)RhoA (-CVLS) was unable to prevent effects of GGTI 298 on cytoskeleton organization. Furthermore, the ability of GGTI-298 to induce p21(WAF) and to block cells in the G(0)/G(1) phase of the cell cycle was also prevented by farnesylated (V14)RhoB but not by farnesylated (V14)RhoA. Moreover, treatment with GGTI-298 of cells expressing farnesylated RhoB results in accumulation of these cells in the G(2)/M phase. Therefore, the RhoB pathway is a critical target of GGTI-298.     

A Centrosome-autonomous Signal That Involves Centriole Disengagement Permits Centrosome Duplication in G2 Phase after DNA Damage

DNA damage can induce centrosome overduplication in a manner that requires G2-to-M checkpoint function, suggesting that genotoxic stress can decouple the centrosome and chromosome cycles. How this happens is unclear. Using live-cell imaging of cells that express fluorescently tagged NEDD1/GCP-WD and proliferating cell nuclear antigen, we found that ionizing radiation (IR)-induced centrosome amplification can occur outside S phase. Analysis of synchronized populations showed that significantly more centrosome amplification occurred after irradiation of G2-enriched populations compared with G1-enriched or asynchronous cells, consistent with G2 phase centrosome amplification. Irradiated and control populations of G2 cells were then fused to test whether centrosome overduplication is allowed through a diffusible stimulatory signal, or the loss of a duplication-inhibiting signal. Irradiated G2/irradiated G2 cell fusions showed significantly higher centrosome amplification levels than irradiated G2/unirradiated G2 fusions. Chicken–human cell fusions demonstrated that centrosome amplification was limited to the irradiated partner. Our finding that only the irradiated centrosome can duplicate supports a model where a centrosome-autonomous inhibitory signal is lost upon irradiation of G2 cells. We observed centriole disengagement after irradiation. Although overexpression of dominant-negative securin did not affect IR-induced centrosome amplification, Plk1 inhibition reduced radiation-induced amplification. Together, our data support centriole disengagement as a licensing signal for DNA damage-induced centrosome amplification.     

Induction of M-phase arrest and apoptosis after HIV-1 Vpr expression through uncoupling of nuclear and centrosomal cycle in HeLa cells

The human immunodeficiency virus type 1 (HIV-1) accessory protein Vpr induces cell cycle arrest in the G2 phase of the cell cycle followed by apoptosis. The mechanism of the arrest is unknown but the arrest is believed to facilitate viral replication. In the present study, we have established cell lines that allow conditional expression of Vpr, and have examined the mechanism of cell death following Vpr expression. We found that cells expressing Vpr enter M phase after long G2 arrest but formed aberrant multipolar spindles that were incapable of completing karyokinesis or cytokinesis. This abnormality provided the basis for apoptosis, which always followed in these cells. The multipolar spindles formed in response to abnormal centrosomal duplication that occurred during the G2 arrest but did not occur in cells arrested in G2 by irradiation. Thus, the expression of Vpr appears to be responsible for abnormal centrosome duplication, which in turn contributes in part to the rapid cell death following HIV-1 infection.     

Role of inducible heat shock protein 70 in radiation-induced cell death

We previously demonstrated the protective effect of inducible heat shock protein 70 (Hsp70) against gamma radiation. Herein, we extend our studies on the possible role of Hsp70 to ionizing radiation-induced cell cycle regulation. The growth rate of inducible hsp70-transfected cells was 2-3 hours slower than that of control cells. Flow cytometric analysis of cells at G1 phase synchronized by serum starvation also showed the growth delay in the Hsp70-overexpressing cells. In addition, reduced cyclin D1 and Cdc2 levels and increased dephosphorylated phosphoretinoblastoma (pRb) were observed in inducible hsp70-transfected cells, which were probably responsible for the reduction of cell growth. To find out if inducible Hsp70-mediated growth delay affected radiation-induced cell cycle regulation, flow cytometric and molecular analyses of cell cycle regulatory proteins and their kinase were performed. The radiation-induced G2/M arrest was found to be inhibited by Hsp70 overexpression and reduced p21Waf induction and its kinase activity by radiation in the Hsp70-transfected cells. In addition, radiation-induced cyclin A or B1 expressions together with their kinase activities were also inhibited by inducible Hsp70, which represented reduced mitotic cell death. Indeed, hsp70 transfectants showed less induction of radiation-induced apoptosis. When treated with nocodazole, radiation-induced mitotic arrest was inhibited by inducible Hsp70. These results strongly suggested that inducible Hsp70 modified growth delay (increased G1 phase) and reduced G2/M phase arrest, subsequently resulting in inhibition of radiation-induced cell death.     

Mitotic catastrophe occurs in the absence of apoptosis in p53-null cells with a defective G1 checkpoint

Cell death occurring during mitosis, or mitotic catastrophe, often takes place in conjunction with apoptosis, but the conditions in which mitotic catastrophe may exhibit features of programmed cell death are still unclear. In the work presented here, we studied mitotic cell death by making use of a UV-inactivated parvovirus (adeno-associated virus; AAV) that has been shown to induce a DNA damage response and subsequent death of p53-defective cells in mitosis, without affecting the integrity of the host genome. Osteosarcoma cells (U2OSp53DD) that are deficient in p53 and lack the G1 cell cycle checkpoint respond to AAV infection through a transient G2 arrest. We found that the infected U2OSp53DD cells died through mitotic catastrophe with no signs of chromosome condensation or DNA fragmentation. Moreover, cell death was independent of caspases, apoptosis-inducing factor (AIF), autophagy and necroptosis. These findings were confirmed by time-lapse microscopy of cellular morphology following AAV infection. The assays used readily revealed apoptosis in other cell types when it was indeed occurring. Taken together the results indicate that in the absence of the G1 checkpoint, mitotic catastrophe occurs in these p53-null cells predominantly as a result of mechanical disruption induced by centrosome overduplication, and not as a consequence of a suicide signal.     

The farnesyltransferase inhibitor FTI-277 suppresses the 24-kDa FGF2-induced radioresistance in HeLa cells expressing wild-type RAS.

In this paper, we describe the effect of the inhibitor of farnesyltransferase (FTI-277) on radioresistance induced by the 24-kDa isoform of FGF2 in human cells expressing wild-type RAS. Treatment with FTI-277 (20 microM) for 48 h prior to irradiation led to a significant decrease in survival of radioresistant cells expressing the 24-kDa isoform (HeLa 3A) but had no effect on the survival of control cells (HeLa PINA). The radiosensitizing effect of FTI-277 is accompanied by a stimulation of postmitotic cell death in HeLa 3A cells and by a reduction in G(2)/M-phase arrest in both cell types. These results clearly demonstrate that at least one farnesylated protein is involved in the regulation of the radioresistance induced by the 24-kDa isoform of FGF2. Furthermore, the radiation-induced G(2)/M-phase arrest is also under the control of farnesylated protein. This work also demonstrates that FTase inhibitors may be effective radiosensitizers of certain human tumors with wild-type RAS.     

RhoA biological activity is dependent on prenylation but independent of specific isoprenoid modification.

Recent studies showed that specific isoprenoid modification may be critical for RhoB subcellular location and function. Therefore, we determined whether the function of the highly related RhoA protein is also critically dependent on specific isoprenoid modification: (a) in contrast to observations with RhoB or Ras proteins, where farnesylated and geranylgeranylated versions showed differences in subcellular location, both prenylated versions of RhoA showed the same plasma membrane and cytosolic location; (b) a farnesylated version of activated RhoA(63L) retained the same diverse functions as the normally geranylgeranylated RhoA(63L) protein, and both proteins show indistinguishable abilities to stimulate gene expression, cause growth transformation of NIH 3T3 mouse fibroblasts, to stimulate the motility of T47D human breast epithelial cells, and to block HIV-1 viral replication and gene expression; and (c) cells expressing farnesylated RhoA retained sensitivity to the growth inhibition caused by inhibition of geranylgeranyltransferase I, indicating that other proteins are critical targets for inhibitors of geranylgeranylation.     

Protein tyrosine kinase inhibitors modulate radiosensitivity and radiation-induced apoptosis in K562 cells.

We studied the modulating effect of protein tyrosine kinase inhibitors on the response of cells of the human chronic myelogenous leukemia cell line K562 to radiation. The radiosensitivity of the cells was increased by treatment with herbimycin A and decreased by treatment with genistein. This modulating effect of protein tyrosine kinase inhibitors on radiation sensitivity was associated with the alteration of the mode of radiation-induced cell death. After X irradiation, the cells arrested in the G(2) phase of the cell cycle, but these TP53(-/-) cells were unable to sustain cell cycle arrest. This G(2)-phase checkpoint deficit caused cell death. The morphological pattern of cell death was characterized by swelling of the cytoplasmic compartments, cytosolic vacuolation, disruption of the plasma membrane, less evident nuclear condensation, and faint DNA fragmentation, all of which were consistent with oncosis or cytoplasmic apoptosis. The nonreceptor protein tyrosine kinase inhibitor herbimycin A accelerated the induction of typical apoptosis by X irradiation, which was demonstrated by morphological assessments using nuclear staining and electron microscopy as well as oligonucleosomal fragmentation and caspase 3 activity. Herbimycin A is known to be a selective antagonist of the BCR/ABL kinase of Philadelphia chromosome-positive K562 cells; this kinase blocks the induction of apoptosis after X irradiation. Our results showed that the inhibition of protein tyrosine kinase by herbimycin A enhanced radiation-induced apoptosis in K562 cells. This effect was associated with the activation of caspase 3 and rapid abrogation of the G(2)-phase checkpoint with progression out of G(2) into G(1) phase. In contrast, the receptor-type protein tyrosine kinase inhibitor genistein protected K562 cells from all types of radiation-induced cell death through the inhibition of caspase 3 activity and prolonged maintenance of G(2)-phase arrest. Further investigations using this model may give valuable information about the mechanisms of radiation-induced apoptosis and about the radiosensitivity and radioresistance of chronic myelogenous leukemia cells having the Philadelphia chromosome.     

Radiation-induced centrosome overduplication and multiple mitotic spindles in human tumor cells

The centrosome is a highly regulated organelle and its proper duplication is indispensable for the formation of bipolar mitotic spindles and balanced chromosome segregation. To elucidate a possible linkage between centrosome duplication and radiation-induced nuclear damage, we examined centrosome dynamics in U2-OS osteosarcoma cells following gamma-irradiation. Nearly all control cells contained one or two centrosomes, and at mitosis more than 97% of the cells displayed typical bipolar spindles. In contrast, over 20% of cells at 48 h after 10 Gy gamma-irradiation contained more than two centrosomes, and 60% of the mitotic cells showed aberrant spindles organized by multiple poles. Remarkably, the cells with multiple centrosomes frequently exhibited changes in size and/or morphology of the nucleus, including micronuclei formation. We conclude that abnormal centrosome duplication could be one of the key events involved in nuclear fragmentation and perhaps even cell death following irradiation.     

Visualizing the effect of tumor microenvironments on radiation-induced cell kinetics in multicellular spheroids consisting of HeLa cells

In this study, we visualized the effect of tumor microenvironments on radiation-induced tumor cell kinetics. For this purpose, we utilized a multicellular spheroid model, with a diameter of ∼500 μm, consisting of HeLa cells expressing the fluorescent ubiquitination-based cell-cycle indicator (Fucci). In live spheroids, a confocal laser scanning microscope allowed us to clearly monitor cell kinetics at depths of up to 60 μm. Surprisingly, a remarkable prolongation of G2 arrest was observed in the outer region of the spheroid relative to monolayer-cultured cells. Scale, an aqueous reagent that renders tissues optically transparent, allowed visualization deeper inside spheroids. About 16 h after irradiation, a red fluorescent cell fraction, presumably a quiescent G0 cell fraction, became distinct from the outer fraction consisting of proliferating cells, most of which exhibited green fluorescence indicative of G2 arrest. Thereafter, the red cell fraction began to emit green fluorescence and remained in prolonged G2 arrest. Thus, for the first time, we visualized the prolongation of radiation-induced G2 arrest in spheroids and the differences in cell kinetics between the outer and inner fractions.     

G2/M-phase arrest and death by apoptosis of HL60 cells irradiated with exponentially decreasing low-dose-rate gamma radiation.

Cells of the TP53-deficient human leukemia cell line HL60 continue to progress throughout the cell cycle and arrest in the G2/M phase during protracted exposure to exponentially decreasing low-dose-rate radiation. We have hypothesized that G2/M-phase arrest contributes to the extent of radiation-induced cell death by apoptosis as well as to overall cell killing. To test this hypothesis, we used caffeine and nocodazole to alter the duration of G2/M-phase arrest of HL60 cells exposed to exponentially decreasing low-dose-rate irradiation and measured the activity of G2/M-phase checkpoint proteins, redistribution of cells in the phases of the cell cycle, cell death by apoptosis, and overall survival after irradiation. The results from these experiments demonstrate that concomitant exposure of HL60 cells to caffeine (2 mM) during irradiation inhibited radiation-induced tyrosine 15 phosphorylation of the G2/M-phase transition checkpoint protein CDC2/p34 kinase and reduced G2/M-phase arrest by 40-46% compared to cells irradiated without caffeine. Radiation-induced apoptosis also decreased by 36-50% in cells treated with caffeine and radiation compared to cells treated with radiation alone. Radiation survival was significantly increased by exposure to caffeine. In contrast, prolongation of G2/M-phase arrest by pre-incubation with nocodazole enhanced radiation-induced apoptosis and overall radiation-induced cell killing. To further study the role of cell death by apoptosis in the response to exponentially decreasing low-dose-rate irradiation, HL60 cells were transfected with the BCL2 proto-oncogene. The extent of G2/M-phase arrest was similar for parental, neomycin-transfected control and BCL2-transfected cells during and after exponentially decreasing low-dose-rate irradiation. However, there were significant differences (P < 0.01) in the extent of radiation-induced apoptosis of parental and neomycin- and BCL2-transfected cells after irradiation, with significantly less radiation-induced apoptosis and higher overall survival in BCL2-transfected cells than similarly irradiated control cells. These data demonstrate that radiation-induced G2/M-phase arrest and subsequent induction of apoptosis play an important role in the response of HL60 cells to low-dose-rate irradiation and suggest that it may be possible to increase radiation-induced apoptosis by altering the extent of G2/M-phase arrest. These findings are clinically relevant and suggest a novel therapeutic strategy for increasing the efficacy of brachytherapy and radioimmunotherapy.     

Cell cycle age dependence for radiation-induced G2 arrest: evidence for time-dependent repair

Exponentially growing eucaryotic cells, irradiated in interphase, are delayed in progression to mitosis chiefly by arrest in G2. The sensitivity of Chinese hamster ovary cells to G2-arrest induction by X rays increases through the cell cycle, up to the X-ray transition point (TP) in G2. This age response can be explained by cell cycle age-dependent changes in susceptibility of the target(s) for G2 arrest and/or by changes in capability for postirradiation recovery from G2-arrest damage. Discrimination between sensitivity changes and repair phenomena is possible only if the level of G2-arrest-causing damage sustained by a cell at the time of irradiation and the level ultimately expressed as arrest can be determined. The ability of caffeine to ameliorate radiation-induced G2 arrest, while inhibiting repair of G2-arrest-causing damage makes such an analysis possible. CHO cell monolayers were irradiated (1.5 Gy), then exposed to 5 mM caffeine for periods of 0-10 hr. Cell progression was monitored by the mitotic cell selection procedure. In the presence of caffeine, progression of irradiated cells was relatively unperturbed, but on caffeine removal, G2 arrest was expressed. The duration of G2 arrest was independent of the length of the prior caffeine exposure and, since cells of all ages were ultimately examined, the duration of arrest was also independent of cell cycle age at the time of irradiation. This finding indicates that the target for G2-arrest induction is present throughout the cell cycle and that the level of G2-arrest damage incurred is initially constant for all cell cycle phases. The data are consistent with the existence of a time-dependent recovery mechanism to explain the age dependence for radiation induction of G2 arrest.     

Effect of separase depletion on ionizing radiation-induced cell cycle checkpoints and survival in human lung cancer cell lines

Abstract.   Objectives : This study is to evaluate the effect of separase depletion on cell cycle progression of irradiated and non-irradiated cells through the G₂/M phases and consecutive cell survival. Materials and methods : Separase was depleted with siRNA in two human non-small cell lung carcinoma (NSCLC) cell lines. Cell cycle progression, mitotic fraction, DNA repair, apoptotic and clonogenic cell death were determined. Results : By depletion of endogenous separase with siRNA in NSCLCs, we showed that separase affects progression through the G₂ phase. In non-irradiated exponentially growing cells, separase depletion led to an increased G₂ accumulation from 17.2% to 29.1% in H460 and from 15.7% to 30.9% in A549 cells and a decrease in mitotic cells. Depletion of separase significantly ( P <  0.01) increased the fraction of radiation-induced G₂ arrested cells 30–56 h after irradiation and led to decrease in the mitotic fraction. This was associated with increased double-strand break repair as measured by γ-H2AX foci kinetics in H460 cells and to a lesser extent in A549 cells. In addition, a decrease in the expression of mitotic linked cell death after irradiation was found. Conclusions : These results indicate that separase has additional targets involved in regulation of G₂ to M progression after DNA damage. Prolonged G₂ phase arrest in the absence of separase has consequences on repair of damaged DNA and cell death.     

Cdk2 plays a critical role in hepatocyte cell cycle progression and survival in the setting of cyclin D1 expression in vivo

Cdk2 was once believed to play an essential role in cell cycle progression, but cdk2-/- mice have minimal phenotypic abnormalities. In this study, we examined the role of cdk2 in hepatocyte proliferation, centrosome duplication, and survival. Cdk2-/- hepatocytes underwent mitosis and had normal centrosome content after mitogen stimulation. Unlike wild-type cells, cdk2-/- liver cells failed to undergo centrosome overduplication in response to ectopic cyclin D1 expression. After mitogen stimulation in culture or partial hepatectomy in vivo, cdk2-/- hepatocytes demonstrated diminished proliferation. Cyclin D1 is a key mediator of cell cycle progression in hepatocytes, and transient expression of this protein is sufficient to promote robust proliferation of these cells in vivo. In cdk2-/- mice and animals treated with the cdk2 inhibitor seliciclib, cyclin D1 failed to induce hepatocyte cell cycle progression. Surprisingly, cdk2 ablation or inhibition led to massive hepatocyte and animal death following cyclin D1 transfection. In a transgenic model of chronic hepatic cyclin D1 expression, seliciclib induced hepatocyte injury and animal death, suggesting that cdk2 is required for survival of cyclin D1-expressing cells even in the absence of substantial proliferation. In conclusion, our studies demonstrate that cdk2 plays a role in liver regeneration. Furthermore, it is essential for centrosome overduplication, proliferation, and survival of hepatocytes that aberrantly express cyclin D1 in vivo. These studies suggest that cdk2 may warrant further investigation as a target for therapy of liver tumors with constitutive cyclin D1 expression.     

Influence of environmental pH on G2-phase arrest caused by ionizing radiation

We investigated the effects of an acidic environment on the G2/M-phase arrest, apoptosis, clonogenic death, and changes in cyclin B1-CDC2 kinase activity caused by a 4-Gy irradiation in RKO.C human colorectal cancer cells in vitro. The time to reach peak G2/M-phase arrest after irradiation was delayed in pH 6.6 medium compared to that in pH 7.5 medium. Furthermore, the radiation-induced G2/M-phase arrest decayed more slowly in pH 6.6 medium than in pH 7.5 medium. Finally, there was less radiation-induced apoptosis and clonogenic cell death in pH 6.6 medium than in pH 7.5 medium. It appeared that the prolongation of G2-phase arrest after irradiation in the acidic environment allowed for greater repair of radiation-induced DNA damage, thereby decreasing the radiation-induced cell death. The prolongation of G2-phase arrest after irradiation in the acidic pH environment appeared to be related at least in part to a prolongation of the phosphorylation of CDC2, which inhibited cyclin B1-CDC2 kinase activity.