Abstract
Glioma tumor suppressor candidate region gene 2 (GLTSCR2/PICT-1) is localized within the well-known 1.4-Mb tumor suppressive region of chromosome 19q, which is frequently altered in various human tumors, including diffuse gliomas. Aside from its localization on the chromosome, several lines of evidence, such as PTEN phosphorylation, support that GLTSCR2 partakes in the suppression of tumor growth and development. However, much remains unknown about the molecular mechanisms of the tumor suppressive activity of GLTSCR2. The purpose of this study was to investigate the molecular mechanisms of GLTSCR2 in cell death pathways in association with its binding partner PTEN. In this work, we show that GLTSCR2 is a nucleus-localized protein with a discrete globular expression pattern. In addition to phosphorylating PTEN, GLTSCR2 induces caspase-independent PTEN-modulated apoptotic cell death when overexpressed. However, the cytotoxic activity of GLTSCR2 is independent of its ability to phosphorylate PTEN, suggesting that the GLTSCR2-induced cell death pathway is divergent from PTEN-induced death pathways. Our results suggest that the induction of PTEN-modulated apoptosis is one of the putative mechanisms of tumor suppressive activity by GLTSCR2.
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Main
Genetic alteration of chromosome 19 is a frequent event encountered in various human tumors, including diffuse gliomas.1, 2 While the putative tumor suppressor gene localized to 19q has been narrowed to the 1.4 Mb between the genetic markers D19S412 and STD, it remains unidentified.3, 4, 5 Glioma tumor suppressor critical region 2 (GLTSCR2/ protein interacting with the carboxyl terminus-1 (PICT-1)), initially identified as a herpes simplex infected cell proteins 22 (ICP22)- and infected cell proteins 0 (ICP0)-interacting protein,6 is one of the candidate genes localized in this critical region. Aside from its localization on the chromosome, several lines of evidence support the participation of GLTSCR2 in the suppression of tumor growth and development. GLTSCR2 physically interacts with phosphatase and tensin homolog deleted on chromosome 10 (PTEN) by phosphorylating the protein,7 which in turn regulates multiple cellular functions including proliferation, growth, differentiation, and apoptosis. While recent reports have shown that the knockdown of GLTSCR2 expression induces anchorage-independent tumor cell growth and decreases susceptibility to apoptosis,8 much remains unknown about the molecular mechanisms behind the tumor suppressive activity of GLTSCR2.
Tumor suppressor genes inhibit the development or growth of cancer cells via a diverse range of pathways such as cell cycle arrest and/or induction of apoptosis. For example, PTEN encodes a dual-specificity protein phosphatase with both substrate specificity and lipid phosphatase activity,9, 10 converting plasma membrane lipid phosphatidylinositol 3,4,5-trisphosphate (PI(3,4,5)P3) to PI(4,5)P2, which antagonizes phosphoinositide 3-kinase (PI3K) and inactivates downstream protein kinases such as Akt and pyruvate dehydrogenase kinase isozyme 1 (PDK1).11, 12, 13 Consequently, the phosphatase activity of PTEN regulates multiple cellular functions including proliferation, growth, and apoptosis. However, it remains unclear whether the inactivation of survival genes, such as Akt, is sufficient for the induction of apoptosis by PTEN in cancer cells. Moreover, neither the molecular mechanisms nor the triggering factors of PTEN-induced apoptosis have yet been clearly identified.
The purpose of this study was to investigate the molecular mechanisms of GLTSCR2 in cell death pathways in association with its binding partner PTEN. In this work, we show that besides phosphorylating PTEN, GLTSCR2 induces caspase-independent apoptotic cell death modulated by PTEN. Our results suggest that the induction of PTEN-modulated cell death is one of the putative mechanisms of tumor suppressive activity by GLTSCR2.
Results
GLTSCR2 is a nucleus-localized protein
To examine the expression status of GLTSCR2, cell lysates of four glioblastoma cell lines (LN229, LN18, A172, and SNU1105) were subjected to western blotting. GLTSCR2 expression was conspicuously downregulated in SNU1105 cells as compared with other glioblastoma cells (Figure 1a). Next, to ascertain the cellular localization of GLTSCR2, LN229 and SNU1105 cells were fractionated into their nuclear and cytosolic components and subjected to western blotting. As shown in Figure 1b, GLTSCR2 was detected in the nuclear compartment. Consistent with western blot data, expression with a GLTSCR2-expressing plasmid tagged with EGFP (pEGFP-GLT) localized to the nucleus in a discrete globular expression pattern (Figure 1c). These nuclear expression patterns were seen in all of the cell lines tested (data not shown). To map the putative nucleus localization sequence (NLS), we generated a series GLTSCR2 truncation mutants (Figure 2a). A sequential deletion of amino acids 1–346 did not change the globular nuclear localization pattern observed with wild-type GLTSCR2 (Figure 2b). In contrast, deletion mutants of the carboxy-terminus of GLTSCR2 (GLTΔ347–479 and GLTΔ181–479) did not display the globular nuclear localization pattern observed with wild-type GLTSCR2; rather, they were dispersed throughout the nucleus (Figure 2b). Moreover, GLT/181–346 lost nuclear localization and was dispersed throughout the cytoplasm (Figure 2b). These results suggest that GLTSCR2 has two putative NLSs, one at either the amino- or carboxy termini, and that the carboxy-terminal NLS is crucial for the discrete globular localization pattern in the nucleus.
GLTSCR2 induces cell death with apoptotic features
To elucidate the functions of GLTSCR2 in cell growth and survival, we analyzed the effect of GLTSCR2 overexpression on cell viability. LN229 cells were transfected with empty pEGFP or pEGFP-GLT, and the cell viability was subsequently determined by the manual enumeration of dead cells with small, condensed and pyknotic or fragmented nuclei among the transfected cells at the indicated time intervals. As shown in Figure 3a, the number of dead cells was increased by 58% after 48 h of transfection. Morphologically, GLTSCR2-overexpressing cells displayed cytoplasmic condensation with a distorted cytoskeletal architecture and pyknotic nuclei with occasional fragmentation (Figure 3b, left panel). In addition, typical apoptotic changes, such as chromatin condensation and margination along the nuclear membrane, were noted with electron microscopy (Figure 3b, right panel). To further delineate the types of cell death induced by GLTSCR2, the percentage of cells with degraded DNA (hypodiploid DNA content) at the sub-G0/G1 fraction and phosphatidylserine externalization were determined. Flow cytometric analysis of Figure 3c and d depict the increase of sub-G0/G1 fraction and early externalization of phosphatidylserine. Consistent with these data, levels of lactate dehydrogenase (LDH), which are suggestive of the plasma membrane rupture observed in necrotic cell death, were not significantly increased following 36 h of GLTSCR2 overexpression, a time point at which approximately 45% of GLTSCR2-overexpressing cells were dead (Figure 3a and e). Our results suggest that overexpressed GLTSCR2 induced cell death with apoptotic features.
Nuclear localization is not required for the cell-killing activity of GLTSCR2
To gain insight into the molecular mechanisms of GLTSCR2-induced apoptosis, we transfected LN229 cells with each of the truncated mutant plasmid and determined the cell-killing potential of the mutants by a cell death assay in comparison with empty vector-transfected cells. As shown in the upper panel of Figure 4a, the deletion of amino acids 181–346 (GLTΔ1–346 and GLTΔ181–479) resulted in a loss of cell-killing ability, suggesting that this domain is important for the cytotoxic effect of GLTSCR2. In addition, the nuclear localization of GLTSCR2 did not appear to be critical for the induction of cell death, as GLT/181–346, which was localized to the cytoplasm, retained the ability to kill cells (Figures 2b and 4a, upper panel). The mechanism of cell death by overexpression of the truncation mutant was basically the same as that of wild-type GLTSCR2 in that the subG0/G1 fraction (Figure 4a, middle panel) and annexin-positive cells (Figure 4a, lower panel) were increased, and insignificant LDH release (data not shown) was noted. Equalization of mutant protein expression was confirmed by western blotting (Figure 4b). Collectively, our results suggest that when overexpressed, GLTSCR2 retains a pro-death property in both the nucleus and cytoplasm, and amino acids 181–346 are crucial for this cytotoxic effect.
Importance of PTEN in induction of cell death by GLTSCR2
Next, we wanted to know whether PTEN affected the cytotoxic potential of GLTSCR2. Glioblastoma cells with deleted PTEN (A17214 and SNU1105) or wild-type PTEN (LN22915 and LN1816) (Figure 5A) were transfected with pEGFP-GLT, and their pro-death effects were measured 48 h after transfection by a cell death assay and morphological assessment. Interestingly, cell death in PTEN-deleted cells was not significantly increased by GLTSCR2 overexpression as compared with approximate 40% cell death in cells with PTEN expression (Figure 5B, lower panel). The difference in cell death for each cell line was not due to differences in GLTSCR2 expression levels, as the overexpression of GLTSCR2 levels by plasmid transfection were made similar for each cell line (Figure 5B, upper panel). Consistent with the results of the cell death assay, LN229 and LN18 cells displayed cytoplasmic shrinkage with condensed pyknotic nuclei, whereas A172 and SNU1105 cells did not show significant morphological changes (Figure 5C). To further elucidate the effects of PTEN on GLTSCR2-induced cell death, A172PTEN(+) and SNU1105PTEN(+), in which PTEN expression was restored by stably transfecting the PTEN expression plasmid pcDNA-PTEN, were transfected with pEGFP-GLT, and alteration of cell death compared with the respective parent cell line was determined. As shown in Figure 5D, the cytotoxic effects of GLTSCR2 on A172 and SNU1105 were restored by ectopic PTEN expression. Equalization of transfected GLTSCR2 for parent and PTEN-stably transfected cells, as well as the restoration of PTEN expression, is shown in the upper panel of Figure 5D. Likewise, suppression of PTEN expression in LN229 and LN18 cells by small interfering RNA (siRNA) (siPTEN) decreased the sensitivity to GLTSCR2 overexpression (Figure 5E). The knockdown of PTEN by siPTEN and equalization of GLTSCR2 expression were confirmed by western blotting (Figure 5E, upper panel). Our data suggest that PTEN activity is required for the cytotoxic effects of GLTSCR2.
The cytotoxic activity GLTSCR2 is independent of its ability to phosphorylate PTEN
To further elucidate the relationship between the apoptotic activity of GLTSCR2 with PTEN phosphorylation, we transfected a series of GLTSCR2 truncation mutants into LN229 cells and determined the phosphorylation status of PTEN. Consistent with a previous report,7 overexpression of GLTSCR2 phosphorylated PTEN at Ser-380 (Figure 6). In addition, PTEN phosphorylation was not significantly affected by the deletion of the amino-terminal sequence (GLTΔ1–65, GLTΔ1–149, and GLTΔ1–346) (Figure 6). Interestingly, deletions of the GLTSCR2 carboxy-terminus (GLTΔ347–479, GLTΔ181–479, and GLT/181–346) resulted in a decrease of phosphorylation activity (Figure 6), suggesting that the carboxy-terminal domain of GLTSCR2 (amino acids 347–479) is responsible for the phosphorylation of PTEN. Taken with the results shown above, our data suggest that GLTSCR2 exerts its cytotoxic activity independent of PTEN phosphorylation.
Divergence between GLTSCR2- and PTEN-induced apoptotic pathways
It has been well documented that PTEN induces apoptotic cell death via many diverse signaling pathways such as survivin17 or p53.18 We therefore sought to determine whether GLTSCR2 activated PTEN-mediated apoptotic mechanisms or facilitated cell death via divergent pathways independent of PTEN. LN229 cells were transfected with pEGFP-GLT or pEGFP-PTEN, and a caspase-3 substrate cleavage assay was performed at the indicated time points. Figure 7a shows that caspase-3 was not activated during GLTSCR2-induced cell death, while PTEN and a positive Bax control were able to induce activation of caspase-3. In addition, a pan-caspase inhibitor (z-VAD) did not suppress cell death induced by GLTSCR2 whereas it did suppress PTEN-induced cell death (Figure 7b). In further support of caspase independence in GLTSCR2-induced cell death pathways, we were unable to detect the release of cytochrome c from mitochondria (Figure 7c) or the dissipation of the mitochondrial membrane potential (data not shown). Altogether, these results suggest that GLTSCR2 facilitates cell death through a caspase- and mitochondria-independent pathway, divergent from PTEN-mediated pathways.
Discussion
GLTSCR2 is a putative tumor suppressor gene localized on chromosome 19q and is frequently altered in human brain tumors, including diffuse gliomas.1, 2 An accumulating body of evidence clearly shows that GLTSCR2 retains the tumor suppressive activities, such as phosphorylation and stabilization of PTEN, as well as sensitization to apoptosis;7, 8 however, much remains unknown about the molecular mechanisms and pathways behind the activity of GLTSCR2. We performed this study to investigate the biological function of GLTSCR2 and its mechanisms of tumor suppression.
We first looked at the expression and subcellular localization of GLTSCR2 and found that it was expressed as multiple small discrete globular structures within the nucleus. Truncation mutation analysis revealed the presence of two NLS at both the amino- and carboxy-terminals. Consistent with this finding, computer-assisted NLS analysis (http://cubic.bioc.columbia.edu/) indicated the presence of two NLSs, 34–39 (LRRRRR) and 387–392 (RRRRRR), at the amino- and carboxy-terminus, respectively. However, the two NLSs of GLTSCR2 appeared to have different functions, whereby mutant GLTSCR2, which has a deletion of the carboxy-terminal sequence (GLTΔ347–479), lost the globular localization pattern and was dispersed throughout the nucleoplasm, while the amino-terminal deletion (GLTΔ1–65) retained multiple, small discrete patterns as did the wild-type GLTSCR2. These data suggest that the carboxy-terminal sequence of GLTSCR2 may interact with a target protein within the nucleus. In support of our data, the carboxy-terminal 130 amino acids have been defined as the binding domain for ICP0 of the herpes virus.6 No partner molecules of GLTSCR2 within the nucleus have been identified, although a yeast two-hybrid screen to detect any binding proteins is currently being developed in our laboratory. In contrast to the carboxy-terminal sequence, the amino-terminal sequence was sufficient for the translocation of GLTSCR2 to the nucleus.
We next analyzed the cytotoxic activity of GLTSCR2 to evaluate its potential for tumor suppression. Morphological and biochemical parameters, including fluorescent and electron microscopy, DNA ploidy, and annexin V staining, categorized GLTSCR2 as a member of a group that induces cell death with apoptotic features; however, GLTSCR2 appeared to be different from other proapoptotic proteins. While large parts of pro-death proteins require targeting to a specific organelle for their cytotoxic activity, some execute their functions irrespective of intracellular localization.19, 20 In the case of GLTSCR2, its cytotoxic potentials were retained irrespective of its localization, both in the cytoplasm and nucleus, as GLTSCR2/181–346, which lacked any NLS, retained killing activity. The presence of the death-inducing domain consisting of amino acids 181–346 was important for cytotoxic activity rather than subcellular localization, because the deletion of amino acids 1–347 or 181–479 markedly reduced the cytotoxic potential of GLTSCR2. It remains to be determined whether this region participates in protein–protein interactions with intracellular death-inhibitory or apoptotic-inducing target proteins.
The phosphatase activity of PTEN, which antagonizes the PI3 kinase and thus dephosphorylates downstream protein kinase Akt and PDK1, modulates a diverse range of signaling cascades including cell growth, survival, or death.12, 13 Our data obtained from the truncation mutants revealed that the amino-terminus of GLTSCR2 participates in the phosphorylation of PTEN, whereas amino acids 181–346, which lack the phosphorylation domain for PTEN, are responsible for the cytotoxic activity of GLTSCR2. The apparent separation of the PTEN phosphorylation domain from the cytotoxic domain suggests that GLTSCR2 facilitates cell death independent of the PTEN-Akt signaling cascades. In support of this assumption, the cell death pathway of GLTSCR2 is completely different from that of PTEN. Data obtained from our caspase assay, cell fractionation assay, and determination of mitochondrial parameters showed that GLTSCR2 induced caspase-independent cell death without mitochondrial perturbation or mitochondrial release of death proteins. These findings contradict established PTEN-induced cell death mechanisms, as PTEN regulates cell death via a caspase- and mitochondria-dependent pathway.21 Nevertheless, insensitivity of PTEN-deleted A172 and SNU444 cells to GLTSCR2 overexpression and restoration of sensitivity to GLTSCR2 by ectopic PTEN expression indicated that normal PTEN activity was required for cell death induced by GLTSCR2. Further studies demonstrating the molecular triggering mechanisms for GLTSCR2 cytotoxicity by PTEN will be needed in order to understand the tumor suppressive function of GLTSCR2.
In summary, we showed that GLTSCR2 not only affected PTEN activity by phosphorylation but also triggered caspase- and mitochondria-independent cell death mechanisms modulated by PTEN. These results suggest that the tumor suppressive function of GLTSCR2 and PTEN are tightly interconnected.
Materials and Methods
Antibodies and reagents
Anti-GLTSCR2 polyclonal antibody was produced by immunizing a rabbit with keyhole limpet hemocyanin-conjugated amino-acid residues 178–193 (CTRAKPGPQDTVERPF) of human GLTSCR2; antibody was purified from the immune serum by affinity chromatography. Anti-PTEN, -phosphoPTEN, and -cytochrome c antibodies were purchased from Abcam (Cambridge, UK). Anti-lamin antibody was purchased from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA, USA). Unless otherwise specified, all other reagents were obtained from Sigma-Aldrich, Inc. (St Louis, MO, USA).
Cell culture, cell viability, and cell death assay
The human LN229, LN18, and A172 glioblastoma cell lines were obtained from the American Type Culture Collection (Rockville, MD, USA). The SNU1105 cell line was purchased from the Korean Bank of Cancer Cells (Seoul, Korea). All cells were cultured in RPMI 1640 medium (Gibco BRL, CA, USA) containing 10% fetal bovine serum under a 5% CO2 atmosphere at 37°C. Cells stably expressing PTEN were generated by transfecting A172 and SNU1105 cells with a PTEN-expressing plasmid (pcDNA-PTEN) and selection with G418. The cell death assay was performed as follows: dead cells exhibiting altered nuclear morphology, such as fragmentation or a condensed pyknotic chromatin pattern among transfected cells, were enumerated manually under a fluorescence microscope following 4′,6′-diamidino-2-phenylindole (DAPI) staining. For quantitative determination of the sub-G0/G1 fraction, cells were stained with propidium iodide (PI) and analyzed using flow cytometry (FC500, Beckerman-Coulter) 48 h after transfection. Annexin V staining was performed according to the manufacturer's instructions (Calbiochem, CA, USA) 12 h after transfection. Lactate dehydrogenase (LDH) released into culture medium was measured using an LDH assay kit (Calbiochem).
Plasmid construction and transient transfection
DNAs encoding full-length GLTSCR2 (Accession no. NM_015710) and Bax (Accession no. L22473) were amplified by polymerase chain reaction (PCR) from a human kidney cDNA library and cloned into pcDNA3.1/V5 (Invitrogen Corp., CA, USA) or pEGFP (Clontech Laboratories, Inc., CA, USA) vectors. Various deletion mutants of GLTSCR2 were constructed by PCR and subcloned into the pcDNA3.1/V5 or pEGFP vectors. Glioblastoma cells (3 × 105/10 cm culture dish) were transiently transfected with each plasmid using Magnetofection according to the manufacturer's protocol (Chemicell, Berlin, Germany).
Determination of mitochondrial membrane potential
Transfected glioblastoma cells were cultured under the indicated conditions, and Mitotracker Red CMXRos (Molecular Probes, Inc.) was added to the medium at a final concentration of 400 nM. After 20 min of incubation, the cells were harvested and washed three times with phosphate-buffered saline (PBS). The fluorescence intensity was measured by flow cytometry (FC 500, Beckmann-Coulter).
Cell fractionation and western blotting
Cell fractionation was performed as previously described.22 Extracts from total cells or cell fractions were suspended in lysis buffer (10 mM Tris-HCl (pH 7.4), 1% Triton X-100, 0.1% sodium deoxycholate, 0.1% SDS, 150 mM NaCl, 1 mM EDTA, 1 mM EGTA, 0.5 mM phenylmethylsulfonyl fluoride, 1.1 mM Na3VO4, and 10 mM NaF). Extracted proteins were separated by SDS-PAGE on 12% polyacrylamide gels and electrophoretically transferred onto nylon membranes. The membranes were probed with primary antibody, followed by incubation with horseradish peroxidase-coupled secondary antibody. Detection was performed with a chemiluminescence-based detection kit (Amersham Pharmacia Biotech).
Caspase assays
Caspase-3 activities were measured with the colorimetric caspase-3 assay kit (Calbiochem) according to the manufacturer's instructions.
Immunocytochemistry and electron microscopy
Glioblastoma cells were fixed with 4% paraformaldehyde in PBS and permeabilized with 0.1% Triton X-100. After blocking with 3% bovine serum albumin in PBS, the cells were incubated with anti-cytochrome c, anti-apoptosis-inducing factor (AIF), anti-smac/DIABLO, anti-HtrA2/Omi, or anti-endonuclease G, and anti-tubulin antibody for 1.5 h at room temperature. Afterwards, the cells were stained with secondary antibody conjugated with fluorescein isothiocyanate or Texas Red and viewed after DAPI staining under a confocal microscope (META 510, Zeiss). For ultrastructural studies, cells were fixed with 2.5% glutaldehyde in 0.1 M phosphate buffer, pH 7.3, treated with osmium tetroxide in 0.1 M phosphate buffer, and then embedded in Epon (Poly/Bed 812® embedding media/DMP-30 kit, PolyScience, Germany). The cells were then observed under an electron microscope (H7100, Hitachi, Japan).
Suppression of endogenous GLTSCR2 expression by siRNA
Pairs of 19-nucleotide sense and antisense RNA oligomers were chemically synthesized independently and annealed by Bioneer Corp. (Daejeon, Korea). The oligonucleotides for GLTSCR2 were as follows: sense, 5′-GCA CAG GCU GCG GGU ACA G-3′, and antisense, 5′-CUG UAC CCG CAG CCU GUG C-3′, which corresponded to human GLTSCR2 coding nucleotides 1455–1475. The selected sequence (siA11) was subjected to a BLAST search to ensure that no other part of the human genome sequence other than GLTSCR2 was targeted. The introduction of siRNA was carried out using Lipofectamine 2000 (Invitrogen) according to the manufacturer's instructions.
Abbreviations
- AIF:
-
apoptosis-inducing factor
- DAPI:
-
4′-6′-diamidino-2-phenylindole
- GLTSCR2:
-
glioma tumor suppressor candidate region 2
- ICP0:
-
infected cell proteins 0
- ICP22:
-
infected cell proteins 22
- LDH:
-
lactate dehydrogenase
- NLS:
-
nuclear localization signal
- PDK1:
-
pyruvate dehydrogenase kinase isozyme 1
- PI3K:
-
phosphoinositide 3-kinase
- PICT-1:
-
protein interacting with the carboxyl terminus-1
- siRNA:
-
small interfering RNA
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Acknowledgements
This work was supported by the Korea Science & Engineering Foundation through the Medical Research Center for Bioreaction to Reactive Oxygen Species at Kyung Hee University (no. R13-2002-020-01002-0) and the Neurobiology Research Program.
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Yim, JH., Kim, YJ., Ko, JH. et al. The putative tumor suppressor gene GLTSCR2 induces PTEN-modulated cell death. Cell Death Differ 14, 1872–1879 (2007). https://doi.org/10.1038/sj.cdd.4402204
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DOI: https://doi.org/10.1038/sj.cdd.4402204
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