Sensitization to Apoptosis Underlies KrasD12-Depen
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病菌学杂志 2005年第23期
Department of Surgery, University Medical Center Utrecht, P.O. Box 85500, 3508 GA Utrecht
Virus and Stem Cell Biology Lab, Department of Molecular Cell Biology, Leiden University Medical Center, P.O. Box 9503, 2300 RA Leiden, The Netherlands
ABSTRACT
Reovirus T3D is an oncolytic agent that preferentially targets tumor cells expressing an activated Ras oncogene. Ras signaling interferes with the cellular stress response that inhibits translation of reovirus RNAs. Murine C26 colorectal carcinoma cells express a mutant KrasD12 gene. Reovirus T3D efficiently kills C26 cells, but not C26 cells in which the KrasD12 mRNA is stably repressed by expression of KrasD12-directed short-hairpin RNAs. Surprisingly, neither reovirus T3D protein synthesis nor T3D virus yields were suppressed by deletion of KrasD12. Rather, reovirus-induced tumor cell apoptosis was completely abrogated as a result of Kras knockdown. We conclude that sensitization of C26 tumor cells to reovirus-induced apoptosis underlies the Ras dependency of reovirus T3D oncolysis.
TEXT
Reovirus T3D is a double-stranded RNA-containing virus belonging to the Reoviridae family. Fibroblasts transformed by an activated Hras oncogene are highly sensitive to reovirus oncolysis (7, 17, 23). In untransformed cells, viral RNAs stimulate a cellular defense mechanism by activation of double-stranded RNA-dependent protein kinase (PKR) (23). Activated PKR prevents the translation of transcripts by inactivation of translation initiation factor 2 (eIF2) through phosphorylation on ser51 (6, 10). Ras signaling interferes with this defense mechanism by inhibiting virus-induced PKR activation, thereby allowing reovirus replication (23). Reovirus infections are nonpathogenic in immunocompetent adults, which makes this virus an interesting candidate for exploitation as an oncolytic agent (13-15, 19, 23).
C26 is an aggressive colorectal cancer cell line that contains constitutively activated Kras due to an activating point mutation in codon 12 (G12D) (22). The Nras and Hras genes in this cell line do not contain activating mutations. We previously established cell lines in which the endogenous KrasD12 allele is stably suppressed by mutant-specific RNA interference by using a lentivirus vector (C26-KrasKD). As a control, we established cell lines transduced with the empty lentivirus pLL3.7 vector (C26-pLL). Efficient and specific knockdown of Kras was demonstrated by Western blot analysis for Kras and, as control, Nras (22). These cell lines were used to analyze the effect of Kras on C26 sensitivity to reovirus-induced oncolysis. Tumor cells (5,000/well) were plated in a 96-well plate and immediately infected with reovirus T3D (25 PFU/cell). Tumor cell viability was then analyzed for 6 consecutive days with standard 3-(4,5-dimethylthiazolyl-2)-2,5-diphenyltetrazolium bromide (MTT) assays. After an initial growth phase (1 to 3 days), reovirus-infected C26-pLL cells rapidly lost viability, resulting in near-complete cell death by day 6 (Fig. 1A). In contrast, C26-KrasKD cells were completely refractory to reovirus-induced cell death (Fig. 1A). Evaluation of cellular morphology by light microscopy clearly showed the cytopathic effect of reovirus T3D on C26-pLL cells, but not on C26-KrasKD cells (Fig. 1B).
We expected that C26-KrasKD cells were refractory to reovirus T3D infection due to inhibition of viral protein synthesis and replication (23). To test this, 5 x 104 C26-pLL and C26-KrasKD cells/well were plated in a 24-well plate and infected with reovirus T3D (25 PFU/cell) or treated with a vehicle control and labeled for 4 h with [35S]methionine at 5 days postinfection (dpi). Surprisingly, the production of reovirus proteins could be clearly demonstrated in both C26-pLL and C26-KrasKD cells (Fig. 2A). However, cellular protein synthesis was detectable only in C26-KrasKD cells and had been completely shut off in C26-pLL cells (Fig. 2A). PKR-mediated inhibition of cellular protein synthesis is part of the immediate integrated stress response by which cells respond to virus infections, oxidative stress, endoplasmic reticulum stress, or amino acid deprivation (11, 23). We have not been able to detect an inhibition of cellular or viral protein synthesis in C26 cells or in C26-KrasKD cells at 4, 8, 24, and 48 h postinfection by performing 1-h [35S]methionine-labeling experiments (not shown). Rather, inhibition of cellular protein synthesis in reovirus-infected C26-pLL cells is evident only at 5 and 6 dpi, when primarily viral RNAs are transcribed (Fig. 2A). Total abrogation of protein synthesis (both viral and cellular), reflecting massive cell death, usually occurs 1 to 2 days later. Our study is in apparent contradiction with published studies showing that ectopic expression of exogenous HrasV12 in fibroblasts promotes reovirus protein synthesis (14, 20, 23). A possible explanation for this discrepancy is that the strength and selection of signaling pathways which are activated by endogenous versus overexpressed exogenous Ras genes may be different. Indeed, the expression level of KrasV12 is a highly critical parameter in determining cellular responses to Ras expression (1). In this respect, it is worth mentioning that our results show for the first time that the knockdown of an endogenous Kras oncogene abrogates cellular sensitivity to reovirus T3D.
Recently, it was reported that the facilitation of reovirus replication by overexpressed HrasV12 in fibroblasts depends on the activity of p38 mitogen-activated protein kinase (20). However, several studies show that cancer cell lines harboring an endogenous mutant K-Ras allele display very low to undetectable levels of constitutive p38 activity (2, 21, 25). Furthermore, p38 activity in human colorectal cancer cells was not affected by KrasD13 deletion or by HRasV12 overexpression (2). Therefore, differential signaling to p38 by overexpressed HrasV12 in fibroblasts and by endogenous KrasD12 in tumor cells may explain the differential effects of these Ras genes on reovirus replication.
Next, we assessed whether Kras knockdown affects reovirus T3D propagation in C26 cells. To this end, we infected C26-pLL and C26-KrasKD cells with reovirus T3D (25 PFU/cell) and analyzed reovirus protein synthesis, as well as the number of infectious particles produced by both cell types over time. We made use of a polyclonal antibody raised against UV-inactivated reovirus T3D in rabbits. This antibody primarily recognizes the major structural μ1 protein, with an apparent molecular mass of 76 kDa. Figure 2B shows that both C26-pLL and C26-KrasKD cells synthesize μ1 following infection with T3D. In addition, infectious particles were assayed both in the medium and in freeze-thawed lysates from cell populations. To determine the amount of reovirus released by the cells, the medium was carefully harvested from the cultures. The cell debris was pelleted by low-speed centrifugation (2 min, 250 x g, room temperature). The reovirus in the supernatant was quantified by plaque assays on 911 cells. To determine the quantity of cell-associated reovirus, the medium was carefully removed. Subsequently, the remaining adherent cells were detached in 100 μl fresh medium by tapping the dish and by triturating using a small-volume pipette. The cell suspension was removed from the dish and added to the pellet fraction obtained after centrifugation of the conditioned medium. The cells were resuspended and lysed by three cycles of freeze-thawing. Subsequently, the lysate was added to a new tube and spun at 1,600 x g for 10 min. The amount of infectious T3D particles in the supernatant was then assessed by plaque assays on 911 cells. Figure 2C shows that reovirus T3D is efficiently propagated in and released from C26-pLL, as well as C26-KrasKD, cells. In fact, virus propagation was more pronounced in the T3D-resistant C26-KrasKD cells (Fig. 2B and C). Taken together, the results show that C26-KrasKD cells can support reovirus T3D replication and release without overt cytopathic effects.
Reovirus T3D causes cell death by inducing apoptosis (4). As Ras may control apoptosis signaling either positively or negatively (9), we hypothesized that resistance to reovirus-induced apoptosis may underlie the differential sensitivity of C26-pLL and C26-KrasKD cells to reovirus-induced cell death. To test this, C26-pLL and C26-KrasKD cells were exposed to control vehicle or reovirus T3D (25 PFU/cell) and after 5 days the induction of apoptosis was analyzed by FACScan analysis of propidium iodide-stained cells, as well as by indirect immunofluorescence and Western analysis for activated caspase 3. The fraction of apoptotic C26-pLL cells (with sub-G1 DNA content) increased to 31% at 5 dpi. In contrast, reovirus T3D infection had no effect on the fraction of C26-KrasKD cells with sub-G1 DNA content (Fig. 3A, right side). In addition, immunofluorescence analyses showed that 18.2% of C26-pLL cells were positive for activated caspase 3, whereas only 2.6% of C26-KrasKD cells were positive for activated caspase 3 (Fig. 3A, left side [C92-605; BD Biosciences PharMingen], and B). Furthermore, Western blot analysis showed that activated caspase 3 was readily detected in lysates of C26-pLL cells but not in lysates of C26-KrasKD cells (Fig. 3C). Genomic DNA is cleaved during apoptosis, yielding single- and double-stranded DNA breaks with free 3'-OH termini that can be labeled with the terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling (TUNEL) reaction. Figure 3B shows that at 5 days following infection with reovirus T3D, 21% of the C26-pLL cells were TUNEL positive whereas C26-KrasKD cells remained negative (in situ cell death detection kit; Roche Applied Science). Baculovirus protein p35 inhibits virus-induced apoptosis (5). To determine the contribution of reovirus-induced apoptosis to the cytopathic effect on C26 cells, we transduced C26 cells with a lentivirus vector carrying the p35 coding region, resulting in cell line C26-p35. C26-p35 and, as a control, C26-pLL cells were subsequently infected with reovirus T3D (25 PFU/cell), and 5 days after infection cell viability was assessed by MTT assays. Whereas reovirus T3D infection reduced the viability of C26-pLL cells by 52%, the viability of p35-expressing C26 cells was unaffected (Fig. 3D). Reovirus T3D-induced apoptosis requires virus binding to sialic acid via the 1 protein (8). Type 1 Lang (T1L) reovirus does not bind to sialic acid and does not induce apoptosis (24). A reassortant virus strain carrying the T3D S1 gene in a T1L background (T3SA+) has gained the potential to bind sialic acid and to induce apoptosis (8). In contrast, a reassortant T1L virus carrying a mutated (L204P) T3D S1 gene (T3SA–) fails to do so (8). We compared T3SA+ and T3SA– for the abilities (i) to induce oncolysis and (ii) to replicate in C26 cells. We found that T3SA+ induced oncolysis with kinetics similar to that induced by T3D (Fig. 3E). The apoptosis-defective T3SA– mutant, however, did not induce oncolysis of C26-pLL cells (Fig. 3E). Importantly, the amounts of reovirus μ1 protein produced at the end of the experiment (8 dpi) were similar for both T3SA+ and T3SA–, indicating comparable virus production (Fig. 3E). C26-KrasKD cells were completely resistant to either T3SA+ or T3SA–, as they are to T3D (data not shown and Fig. 1A).
Taken together, our results demonstrate an alternative mechanism for the selective sensitivity of tumor cells carrying a Kras oncogene to reovirus T3D: sensitization to reovirus-induced apoptosis.
There has been an increasing awareness that Ras, depending on the cell type and context, can induce either pro- or antiapoptotic signaling (9). Our results clearly show that the presence of KrasD12 facilitates the induction of apoptosis by reovirus T3D. Reovirus-induced apoptosis in human embryonic kidney 293T cells and in HeLa cells is mediated by tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) (3). Furthermore, overexpression of HrasV12 sensitizes normal human fibroblasts and human embryonic kidney cells to TRAIL-induced apoptosis (18). Therefore, Ras-dependent sensitization to TRAIL may underlie the differential susceptibility of C26 and C26-KrasKD cells to reovirus-induced apoptosis. However, treatment of C26-pLL and C26-KrasKD cells with recombinant TRAIL (up to 500 ng/ml, 24 h) did not induce apoptosis in either cell line, whereas HCT 116 cells were efficiently killed (Fig. 4). The TRAIL batch used was highly active, as it induced HCT-116 apoptosis already at 100 ng/ml (not shown). Although TRAIL did not induce apoptosis in C26 or C26-KrasKD cells, it caused a marked increase in the percentage of G1 DNA in both C26 cells (from 40 to 58%) and C26-KrasKD cells (from 52 to 68%). Recently, it was found that TRAIL reduced the proliferation of human T-cell lines, possibly by suppressing cdk4 levels (16). It is unknown whether this is a general phenomenon in TRAIL-resistant tumor cells. In conclusion, the Ras-dependent susceptibility of C26 cells to reovirus-induced apoptosis is not accompanied by susceptibility to TRAIL. This suggests that TRAIL is not the only critical factor in reovirus-induced apoptosis, at least in the C26 cells studied here.
Whether an activated Ras pathway sensitizes transformed cells to reovirus oncolysis by interfering with cellular antiviral stress signaling or by facilitating apoptosis may be cell type dependent. It is even conceivable that these pathways act in concert to allow tumor-specific oncolysis, although this was not observed in the present study. Taken together, our results support the feasibility of using reovirus T3D as an oncolytic agent for tumor cells carrying mutant Kras. Nonetheless, the mechanism underlying oncolytic selectivity may involve Ras-dependent sensitization of tumor cells to reovirus-induced apoptosis, rather than to facilitation of reovirus replication. This may have ramifications for the design of combination therapies involving reovirus T3D.
ACKNOWLEDGMENTS
We thank Terence S. Dermody for the kind gift of the reassortant reovirus strains T3SA– and T3SA+, Fran?oise Carlotti (LUMC, Leiden, The Netherlands) for providing the lentivirus vector pLV-CMV-p35 carrying the baculovirus p35 cDNA, and D. W. Seol for providing the bacterial expression construct encoding His-tagged TRAIL.
N.S. was financially supported by the Wijnand M. Pon Foundation.
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Virus and Stem Cell Biology Lab, Department of Molecular Cell Biology, Leiden University Medical Center, P.O. Box 9503, 2300 RA Leiden, The Netherlands
ABSTRACT
Reovirus T3D is an oncolytic agent that preferentially targets tumor cells expressing an activated Ras oncogene. Ras signaling interferes with the cellular stress response that inhibits translation of reovirus RNAs. Murine C26 colorectal carcinoma cells express a mutant KrasD12 gene. Reovirus T3D efficiently kills C26 cells, but not C26 cells in which the KrasD12 mRNA is stably repressed by expression of KrasD12-directed short-hairpin RNAs. Surprisingly, neither reovirus T3D protein synthesis nor T3D virus yields were suppressed by deletion of KrasD12. Rather, reovirus-induced tumor cell apoptosis was completely abrogated as a result of Kras knockdown. We conclude that sensitization of C26 tumor cells to reovirus-induced apoptosis underlies the Ras dependency of reovirus T3D oncolysis.
TEXT
Reovirus T3D is a double-stranded RNA-containing virus belonging to the Reoviridae family. Fibroblasts transformed by an activated Hras oncogene are highly sensitive to reovirus oncolysis (7, 17, 23). In untransformed cells, viral RNAs stimulate a cellular defense mechanism by activation of double-stranded RNA-dependent protein kinase (PKR) (23). Activated PKR prevents the translation of transcripts by inactivation of translation initiation factor 2 (eIF2) through phosphorylation on ser51 (6, 10). Ras signaling interferes with this defense mechanism by inhibiting virus-induced PKR activation, thereby allowing reovirus replication (23). Reovirus infections are nonpathogenic in immunocompetent adults, which makes this virus an interesting candidate for exploitation as an oncolytic agent (13-15, 19, 23).
C26 is an aggressive colorectal cancer cell line that contains constitutively activated Kras due to an activating point mutation in codon 12 (G12D) (22). The Nras and Hras genes in this cell line do not contain activating mutations. We previously established cell lines in which the endogenous KrasD12 allele is stably suppressed by mutant-specific RNA interference by using a lentivirus vector (C26-KrasKD). As a control, we established cell lines transduced with the empty lentivirus pLL3.7 vector (C26-pLL). Efficient and specific knockdown of Kras was demonstrated by Western blot analysis for Kras and, as control, Nras (22). These cell lines were used to analyze the effect of Kras on C26 sensitivity to reovirus-induced oncolysis. Tumor cells (5,000/well) were plated in a 96-well plate and immediately infected with reovirus T3D (25 PFU/cell). Tumor cell viability was then analyzed for 6 consecutive days with standard 3-(4,5-dimethylthiazolyl-2)-2,5-diphenyltetrazolium bromide (MTT) assays. After an initial growth phase (1 to 3 days), reovirus-infected C26-pLL cells rapidly lost viability, resulting in near-complete cell death by day 6 (Fig. 1A). In contrast, C26-KrasKD cells were completely refractory to reovirus-induced cell death (Fig. 1A). Evaluation of cellular morphology by light microscopy clearly showed the cytopathic effect of reovirus T3D on C26-pLL cells, but not on C26-KrasKD cells (Fig. 1B).
We expected that C26-KrasKD cells were refractory to reovirus T3D infection due to inhibition of viral protein synthesis and replication (23). To test this, 5 x 104 C26-pLL and C26-KrasKD cells/well were plated in a 24-well plate and infected with reovirus T3D (25 PFU/cell) or treated with a vehicle control and labeled for 4 h with [35S]methionine at 5 days postinfection (dpi). Surprisingly, the production of reovirus proteins could be clearly demonstrated in both C26-pLL and C26-KrasKD cells (Fig. 2A). However, cellular protein synthesis was detectable only in C26-KrasKD cells and had been completely shut off in C26-pLL cells (Fig. 2A). PKR-mediated inhibition of cellular protein synthesis is part of the immediate integrated stress response by which cells respond to virus infections, oxidative stress, endoplasmic reticulum stress, or amino acid deprivation (11, 23). We have not been able to detect an inhibition of cellular or viral protein synthesis in C26 cells or in C26-KrasKD cells at 4, 8, 24, and 48 h postinfection by performing 1-h [35S]methionine-labeling experiments (not shown). Rather, inhibition of cellular protein synthesis in reovirus-infected C26-pLL cells is evident only at 5 and 6 dpi, when primarily viral RNAs are transcribed (Fig. 2A). Total abrogation of protein synthesis (both viral and cellular), reflecting massive cell death, usually occurs 1 to 2 days later. Our study is in apparent contradiction with published studies showing that ectopic expression of exogenous HrasV12 in fibroblasts promotes reovirus protein synthesis (14, 20, 23). A possible explanation for this discrepancy is that the strength and selection of signaling pathways which are activated by endogenous versus overexpressed exogenous Ras genes may be different. Indeed, the expression level of KrasV12 is a highly critical parameter in determining cellular responses to Ras expression (1). In this respect, it is worth mentioning that our results show for the first time that the knockdown of an endogenous Kras oncogene abrogates cellular sensitivity to reovirus T3D.
Recently, it was reported that the facilitation of reovirus replication by overexpressed HrasV12 in fibroblasts depends on the activity of p38 mitogen-activated protein kinase (20). However, several studies show that cancer cell lines harboring an endogenous mutant K-Ras allele display very low to undetectable levels of constitutive p38 activity (2, 21, 25). Furthermore, p38 activity in human colorectal cancer cells was not affected by KrasD13 deletion or by HRasV12 overexpression (2). Therefore, differential signaling to p38 by overexpressed HrasV12 in fibroblasts and by endogenous KrasD12 in tumor cells may explain the differential effects of these Ras genes on reovirus replication.
Next, we assessed whether Kras knockdown affects reovirus T3D propagation in C26 cells. To this end, we infected C26-pLL and C26-KrasKD cells with reovirus T3D (25 PFU/cell) and analyzed reovirus protein synthesis, as well as the number of infectious particles produced by both cell types over time. We made use of a polyclonal antibody raised against UV-inactivated reovirus T3D in rabbits. This antibody primarily recognizes the major structural μ1 protein, with an apparent molecular mass of 76 kDa. Figure 2B shows that both C26-pLL and C26-KrasKD cells synthesize μ1 following infection with T3D. In addition, infectious particles were assayed both in the medium and in freeze-thawed lysates from cell populations. To determine the amount of reovirus released by the cells, the medium was carefully harvested from the cultures. The cell debris was pelleted by low-speed centrifugation (2 min, 250 x g, room temperature). The reovirus in the supernatant was quantified by plaque assays on 911 cells. To determine the quantity of cell-associated reovirus, the medium was carefully removed. Subsequently, the remaining adherent cells were detached in 100 μl fresh medium by tapping the dish and by triturating using a small-volume pipette. The cell suspension was removed from the dish and added to the pellet fraction obtained after centrifugation of the conditioned medium. The cells were resuspended and lysed by three cycles of freeze-thawing. Subsequently, the lysate was added to a new tube and spun at 1,600 x g for 10 min. The amount of infectious T3D particles in the supernatant was then assessed by plaque assays on 911 cells. Figure 2C shows that reovirus T3D is efficiently propagated in and released from C26-pLL, as well as C26-KrasKD, cells. In fact, virus propagation was more pronounced in the T3D-resistant C26-KrasKD cells (Fig. 2B and C). Taken together, the results show that C26-KrasKD cells can support reovirus T3D replication and release without overt cytopathic effects.
Reovirus T3D causes cell death by inducing apoptosis (4). As Ras may control apoptosis signaling either positively or negatively (9), we hypothesized that resistance to reovirus-induced apoptosis may underlie the differential sensitivity of C26-pLL and C26-KrasKD cells to reovirus-induced cell death. To test this, C26-pLL and C26-KrasKD cells were exposed to control vehicle or reovirus T3D (25 PFU/cell) and after 5 days the induction of apoptosis was analyzed by FACScan analysis of propidium iodide-stained cells, as well as by indirect immunofluorescence and Western analysis for activated caspase 3. The fraction of apoptotic C26-pLL cells (with sub-G1 DNA content) increased to 31% at 5 dpi. In contrast, reovirus T3D infection had no effect on the fraction of C26-KrasKD cells with sub-G1 DNA content (Fig. 3A, right side). In addition, immunofluorescence analyses showed that 18.2% of C26-pLL cells were positive for activated caspase 3, whereas only 2.6% of C26-KrasKD cells were positive for activated caspase 3 (Fig. 3A, left side [C92-605; BD Biosciences PharMingen], and B). Furthermore, Western blot analysis showed that activated caspase 3 was readily detected in lysates of C26-pLL cells but not in lysates of C26-KrasKD cells (Fig. 3C). Genomic DNA is cleaved during apoptosis, yielding single- and double-stranded DNA breaks with free 3'-OH termini that can be labeled with the terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling (TUNEL) reaction. Figure 3B shows that at 5 days following infection with reovirus T3D, 21% of the C26-pLL cells were TUNEL positive whereas C26-KrasKD cells remained negative (in situ cell death detection kit; Roche Applied Science). Baculovirus protein p35 inhibits virus-induced apoptosis (5). To determine the contribution of reovirus-induced apoptosis to the cytopathic effect on C26 cells, we transduced C26 cells with a lentivirus vector carrying the p35 coding region, resulting in cell line C26-p35. C26-p35 and, as a control, C26-pLL cells were subsequently infected with reovirus T3D (25 PFU/cell), and 5 days after infection cell viability was assessed by MTT assays. Whereas reovirus T3D infection reduced the viability of C26-pLL cells by 52%, the viability of p35-expressing C26 cells was unaffected (Fig. 3D). Reovirus T3D-induced apoptosis requires virus binding to sialic acid via the 1 protein (8). Type 1 Lang (T1L) reovirus does not bind to sialic acid and does not induce apoptosis (24). A reassortant virus strain carrying the T3D S1 gene in a T1L background (T3SA+) has gained the potential to bind sialic acid and to induce apoptosis (8). In contrast, a reassortant T1L virus carrying a mutated (L204P) T3D S1 gene (T3SA–) fails to do so (8). We compared T3SA+ and T3SA– for the abilities (i) to induce oncolysis and (ii) to replicate in C26 cells. We found that T3SA+ induced oncolysis with kinetics similar to that induced by T3D (Fig. 3E). The apoptosis-defective T3SA– mutant, however, did not induce oncolysis of C26-pLL cells (Fig. 3E). Importantly, the amounts of reovirus μ1 protein produced at the end of the experiment (8 dpi) were similar for both T3SA+ and T3SA–, indicating comparable virus production (Fig. 3E). C26-KrasKD cells were completely resistant to either T3SA+ or T3SA–, as they are to T3D (data not shown and Fig. 1A).
Taken together, our results demonstrate an alternative mechanism for the selective sensitivity of tumor cells carrying a Kras oncogene to reovirus T3D: sensitization to reovirus-induced apoptosis.
There has been an increasing awareness that Ras, depending on the cell type and context, can induce either pro- or antiapoptotic signaling (9). Our results clearly show that the presence of KrasD12 facilitates the induction of apoptosis by reovirus T3D. Reovirus-induced apoptosis in human embryonic kidney 293T cells and in HeLa cells is mediated by tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) (3). Furthermore, overexpression of HrasV12 sensitizes normal human fibroblasts and human embryonic kidney cells to TRAIL-induced apoptosis (18). Therefore, Ras-dependent sensitization to TRAIL may underlie the differential susceptibility of C26 and C26-KrasKD cells to reovirus-induced apoptosis. However, treatment of C26-pLL and C26-KrasKD cells with recombinant TRAIL (up to 500 ng/ml, 24 h) did not induce apoptosis in either cell line, whereas HCT 116 cells were efficiently killed (Fig. 4). The TRAIL batch used was highly active, as it induced HCT-116 apoptosis already at 100 ng/ml (not shown). Although TRAIL did not induce apoptosis in C26 or C26-KrasKD cells, it caused a marked increase in the percentage of G1 DNA in both C26 cells (from 40 to 58%) and C26-KrasKD cells (from 52 to 68%). Recently, it was found that TRAIL reduced the proliferation of human T-cell lines, possibly by suppressing cdk4 levels (16). It is unknown whether this is a general phenomenon in TRAIL-resistant tumor cells. In conclusion, the Ras-dependent susceptibility of C26 cells to reovirus-induced apoptosis is not accompanied by susceptibility to TRAIL. This suggests that TRAIL is not the only critical factor in reovirus-induced apoptosis, at least in the C26 cells studied here.
Whether an activated Ras pathway sensitizes transformed cells to reovirus oncolysis by interfering with cellular antiviral stress signaling or by facilitating apoptosis may be cell type dependent. It is even conceivable that these pathways act in concert to allow tumor-specific oncolysis, although this was not observed in the present study. Taken together, our results support the feasibility of using reovirus T3D as an oncolytic agent for tumor cells carrying mutant Kras. Nonetheless, the mechanism underlying oncolytic selectivity may involve Ras-dependent sensitization of tumor cells to reovirus-induced apoptosis, rather than to facilitation of reovirus replication. This may have ramifications for the design of combination therapies involving reovirus T3D.
ACKNOWLEDGMENTS
We thank Terence S. Dermody for the kind gift of the reassortant reovirus strains T3SA– and T3SA+, Fran?oise Carlotti (LUMC, Leiden, The Netherlands) for providing the lentivirus vector pLV-CMV-p35 carrying the baculovirus p35 cDNA, and D. W. Seol for providing the bacterial expression construct encoding His-tagged TRAIL.
N.S. was financially supported by the Wijnand M. Pon Foundation.
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