From the
Laboratory of Plant Genomics, Korea Research Institute of Bioscience and Biotechnology, P. O. Box 115, Yusong, Taejon 305-600,
Graduate School of Biotechnology, Korea University, Seoul 136-701, Korea
Received for publication, October 15, 2002
, and in revised form, March 13, 2003.
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ABSTRACT |
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INTRODUCTION |
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As a result of the extensive studies in the past decade, the basic blue print of the molecular control of apoptosis, the most widely studied PCD, has emerged in the animal system (1, 3, 6, 7). The key participants of the apoptotic cell death are the caspases, a family of cysteine proteases, which exist as dormant proenzymes in most cells. During apoptosis, a battery of caspases becomes activated through proteolytic processing at internal aspartic acid residues. The action of the active caspases on their substrates causes apoptotic morphological changes and leads to cell death. Two major pathways to caspase activation have been defined in mammals: the extrinsic death receptor pathway and the intrinsic or mitochondrial pathway (3). The intrinsic pathway is initiated through release of mitochondrial cytochrome c into the cytosol in response to cellular stresses. Cytochrome c release is a major checkpoint in the initiation of apoptosis, because this protein can induce assembly of the caspase-9 activating complex in the cytosol, termed apoptosome. Upon activation within the apoptosome, caspase-9 can propagate a cascade of further caspase activation events by direct processing of effector caspases.
Evidence is accumulating that the ubiquitin/proteasome pathway plays an important role in apoptosis (8, 9). The 26 S proteasome, consisting of two large subcomplexes, the 20 S proteasome and the 19 S regulatory complex, is a major cytoplasmic proteolytic enzyme complex, responsible for degradation of the vast majority of intracellular proteins in eukaryotes (10). In this pathway, ubiquitin becomes covalently attached to cellular proteins by an ATP-dependent reaction cascade, and then the ubiquitinated proteins are targeted for degradation by the proteasome (11). Proteasomal substrates include metabolic key enzymes, transcription factors, cyclins, inhibitors of cyclin-dependent kinases, and apoptotic regulators (11). In plants, the ubiquitin/proteasome pathway has been linked to cell cycle and to various signal transduction pathways including auxin signaling, photomorphogenesis, and jasmonic acid signaling (11). During apoptosis in animal cells, changes in the expression and activity of different components of the ubiquitin-proteasome system occur (9). Furthermore, proteasome inhibitors have been shown to induce apoptosis in most cell types, whereas in some cells, such as thymocytes and neural cells, these compounds were able to block apoptosis, revealing a complex mechanism of proteasome function in apoptosis (12). Proteasome-mediated steps in apoptosis in animal cells is located upstream of mitochondrial changes and caspase activation, and could be related with Bcl-2, Jun N-terminal kinase, heat shock protein, Myc, p53, and polyamines (8).
Studies of the involvement of proteasome in plant PCD lag behind those in animal systems. Among a few examples, application of proteasome inhibitor at the initiation of zinnia mesophyll cell culture completely prevented differentiation of the tracheary element, whereas inhibition of proteasome activity following commitment to differentiation did not prevent formation of the organ but delayed the process (13). Additionally, overexpression of a mutant form of ubiquitin unable to form polyubiquitin chains induced formation of local lesion in response to mild stress, indicating that disruption of the ubiquitin pathway induces a HR-like cell death under certain conditions (14). However, no direct evidence of proteasome involvement in plant cell death has been provided. In this study, we demonstrate that disruption of proteasome function by gene silencing of the proteasome subunits activates programmed cell death in plant cells, revealing that proteasome is critically involved in cell death program in plants. The proteasome-mediated PCD exhibited features of apoptotic cell death, such as involvement of reactive oxygen species (ROS), cytochrome c release from mitochondria, and activation of caspase-like protease activities. Interestingly, the gene expression profile during the PCD in this study was different from that of the HR cell death in response to pathogen infection, indicating that different pathways for PCD regulation might have evolved in plants. Signaling pathways of some plant PCD programs may include modulation of proteasome activities in response to the death signals.
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EXPERIMENTAL PROCEDURES |
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Evans Blue StainingDetached leaves, completely submerged in a 0.1% (w/v) aqueous solution of Evans blue (Sigma), were subjected to two 5-min cycles of vacuum followed by a 20-min maintenance under vacuum. The leaves were then washed by vacuum infiltration of phosphate-buffered saline plus 0.05% (v/v) Tween 20 three times for 15 min each time.
RT-PCRTwenty micrograms of total RNA isolated from plant tissues were treated with 1 unit of RNase-free DNase (Promega) and 1 unit of RNase inhibitor (Promega) for 15 min at 37 °C, then purified by phenol/chloroform extraction. The first-strand cDNA was synthesized by using 5 µg of DNase-treated RNA primed by oligo(dT) (50 µM) using 200 units of Superscript II RNase H- reverse transcriptase (Invitrogen), 20 units of RNase inhibitor, 500 µM amounts of each dNTP, and 10 mM dithiothreitol. One-fifth, one-twenty-fifth, and one-hundredth of 1/20 of the reaction mixture were used for PCR amplification with 1 unit of Taq DNA polymerase (Promega), 100 µM amounts of each dNTP, and 100 pmol each of forward and reverse primer. Primers for RT-PCR were made according to the published cDNA sequences (for PR1a, 5'-AATATCCCACTCTTGCCG-3' and 5'-CCTGGAGGATCATAGTTG-3'; for PR1b, 5'-ATCTCACTCTTCTCATGC-3' and 5'-TACCTGGAGGATCATAGT-3'; for PR1c, 5'-CTTGTCTCTACGCTTCTC-3' and 5'-AACACGAACCGAGTTACG-3'; for PR2, 5'-ACCATCAGACCAAGATGT-3' and 5'-TGGCTAAGAGTGGAAGGT-3'; for PR4,5'-ATGGTTGGAACTTCCGGA-3' and 5'-TCCTGATCTCTCTGCTAC-3'; for PR5, 5'-ATGAGAAAGACCCACGTC-3' and 5'-ATGCCTTCTTTGCAGCAG-3'; for S25-PR6, 5'-ATGCCACAATCTCAACCA-3' and 5'-ACCTAATGCAGCCCGAAT-3'; for HSR203J, 5'-TAGCCACGCACATGCAAACC-3' and 5'-GTGACAATCAAGACGGTAC-3'; for 630, 5'-CAAGAAATCCGTCCAGGT-3' and 5'-CTTCTGTATCTGAGGCCT-3'; for SAR8.2a, 5'-CTTTGCCTTTCTTTGGCT-3' and 5'-GACATTTAGGACATTTGCTGC-3'; for HIN1, 5'-GAGCCATGCCGGAATCCAAT-3' and 5'-GCTACCAATCAAGATGGCATCTGG-3'; for NTCP-23,5'-ATGAGAATCCGATCAGAC-3' and 5'-ACATAAGCCATTCTTGCC-3'; for p69d, 5'-ACTTCTCACTGCAATTGG-3' and 5'-TCAGACATGATCAACTCC-3'; for ClpP, 5'-AACCAGGACACAGATCGT-3' and 5'-AGGTACAATTGCTCCTGG-3'; for actin, 5'-TGGACTCTGGTGATGGTGTC-3' and 5'-CCTCCAATCCAAACACTGTA-3'; for NbPBC, 5'-GCAACATCGTTTGTTTCT-3' and 5'-TCAGGCTTCATTTCCCTC-3'; for NbPAF-N,5'-TCAGCGGCAATAGGTTTG-3' and 5'-AAGGTGAGCACCAGACTC-3'; for NbPAF-C,5'-TGCCCTAGTGGTAACTAC-3' and 5'-TTCATCACTACCAGCTTC-3'; and for NbRpn9, 5'-AGCTCTGGCATCAAC-3' and 5'-ACTGAGAAGACACCCAAT-3').
Nuclear Fragmentation AnalysisGenomic DNA was isolated from the fourth leaf above the infiltrated leaf in the virus-induced gene silencing (VIGS) lines using the Genome Isolation Kit (Qiagen) according to the instructions from the manufacturer. Five µg of genomic DNA was separated on a 1.2% agarose gel and transferred to Hybond N+ membrane (Amersham Biosciences). As probes, 100 ng each of the total genomic DNA and chloroplast DNA of N. benthamiana were labeled with a random labeling kit (Bio-Rad). After hybridization, the membranes were washed with 0.2x SSC, 0.1% SDS at 60 °C for 1 h.
In Vivo H2O2 MeasurementProtoplasts isolated from leaves of the VIGS lines were incubated in 2 µM 2',7'-dichlorodihydrofluorescein diacetate (H2DCFDA, Molecular Probes) for 30, 60, 90, 120, and 150 s. Protoplasts were transferred to wells on microscope slides and illuminated using a confocal microscope (Carl Zeiss LSM 510) with optical filters (488-nm excitation, LP 505-nm emission) to visualize the oxidized green fluorescent probe. Quantitative images were captured and data were analyzed using the LSM 510 program (version 2.8).
Measurement of Peroxidase (POD) and Ascorbate Peroxidase (APX) ActivityFor POD activity, 0.2 g of leaves from TRV control and TRV: PAF lines were ground in liquid nitrogen, and suspended in 10 mM potassium phosphate buffer, pH 6.0. After centrifugation at 4 °C, supernatants were taken, and measured for POD activity with 0.5 mM pyrogallol (Sigma) and 0.1 mM H2O2 using a spectrophotometer with 420-nm wavelength. For APX activity, the leaves were homogenized in the homogenization buffer (50 mM HEPES, pH 7.0, 0.1 mM EDTA). After centrifugation at 4 °C, supernatants were measured for the APX activity with 0.03 mM ascorbate and 0.1 mM H2O2 using a spectrophotometer with 290-nm wavelength.
Ion LeakageAfter Agrobacterium infiltration, the fourth leaf above the infiltrated leaf from the TRV control and TRV:PAF lines was collected and analyzed. Fifteen leaf discs (7 mm in diameter) were floated on the 0.4 M sorbitol. The leaf discs were incubated in the darkness for 12 h, and this solution was measured for sample conductivity. Then the leaves were boiled in the same solution for 5 min, and the solution was measured for the subtotal conductivity. Membrane leakage is represented by the relative conductivity, which was calculated as sample conductivity divided by total conductivity (the sum of sample conductivity and subtotal conductivity). Conductivity was measured with a conductivity meter (model 162, Thermo Orion, Beverly, MA).
Callose Staining and Autofluorescence DetectionFor callose staining, leaves from TRV control and VIGS-NbPAF lines were fixed in 3:1 ethanol:acetic acid for 1 h, washed in distilled water for 15 min, and softened in 8 M sodium hydroxide at room temperature overnight. The leaves were then washed twice in distilled water and incubated in 0.1% aniline blue (Sigma) in 0.1 M potassium phosphate buffer, pH 7.0, for 2 h in the darkness. The stained leaves were observed under a fluorescence microscope (Zeiss Axioskop). For autofluorescence detection, intact leaves were observed under a fluorescence microscope (Zeiss Axioskop).
Measurement of Mitochondrial Membrane PotentialTetramethylrhodamine methyl ester (TMRM; Molecular Probes) was added into protoplasts isolated from leaves of the VIGS lines at the final concentration of 200 nM. After incubation for 1015 min at 25 °C, protoplasts were transferred to wells on microscope slides and illuminated using a confocal microscope (Carl Zeiss LSM 510) with optical filters (543-nm excitation, LP 585-nm emission) to visualize the oxidized red fluorescent probe. Quantitative images were captured and data were analyzed using the LSM 510 program (version 2.8).
Measurement of Caspase-like ActivityLeaves were ground and homogenized in caspase extraction buffer (50 mM HEPES, pH 7.5, 1 mM EDTA, 1 mM dithiothreitol, 1% bovine serum albumin, 1 mM phenylmethylsulfonyl fluoride, 20% glycerol). Samples were incubated with shaking on ice for 15 min, centrifuged, and supernatants collected. Samples (50 µl) were mixed with 50 µl of caspase assay buffer (caspase extraction buffer with 150 µM LEHD-AFC (R&D Systems) for caspase 9-like activity and DEVD-AFC (R&D Systems) for caspase 3-like activity, as peptide substrates). After incubation at 37 °C for 1 h, the fluorescence of AFC hydrolyzed from the peptide substrates was quantified in a spectrofluorophotometer (Shimadzu, RF-5000) using 400-nm excitation and 505-nm emission wavelengths. Enzymatic activity was normalized for protein concentration and expressed as percentage of activity present in control extracts. Each measurement was carried out with three independent VIGS plants.
Cellular Fractionation and Detection of Cytochrome c ReleaseTwo grams of leaves from the TRV control and TRV-PAF line were ground in grinding buffer (0.4 M mannitol, 1 mM EGTA, 20 mM 2-merchaptoethanol, 50 mM Tricine, 0.1% bovine serum albumin, pH 7.8) for 1 min at 4 °C. Extracts were filtered through Miracloth, and the filtrates were centrifuged at 15,000 x g for 5 min at 4 °C. The supernatant was centrifuged at 16,000 x g for 15 min at 4 °C. Following this second centrifugation, the supernatants obtained were taken to represent the cytosol fraction, and the pellets were resuspended in grinding buffer to represent the mitochondria fraction. Fifty µg of proteins were electrophoresed on a 12% SDS-PAGE, transferred onto polyvinylidene difluoride membranes, and probed with the monoclonal antibody against cytochrome c (1:1000 dilution; Pharmingen) and the monoclonal antibody (31HL) against human voltage-dependent anion channel (VDAC/porin) (1:1000 dilution; Calbiochem). They were then reacted with secondary antibodies conjugated with horseradish peroxidase and ECL reagent (Amersham Biosciences) for detection.
Measurement of Proteasome ActivityProteasome activity was assessed in cell extracts using synthetic peptide substrates (Sigma) linked to the fluorescent reporters, 7-amino-4-methylcoumarin (AMC) or -naphthylamide (
NA) in the absence or presence of proteasome inhibitor MG132 (Calbiochem). Homogenized leaf extracts were cleared by centrifugation, and the supernatants used for determination of protein concentration and enzymatic activity. Fifty µl of the extracts were assayed by addition of 50 µl of assay mixture (50 mM Tris-HCl, pH 7.5, 40 mM KCl, 5 mM MgCl2,1mM dithiothreitol, 0.5 mM ATP, 2% glycerol), and incubation for 1 h at 37 °C. MG132 was added to the assay mixture at the final concentration of 100 µM. AMC and
NA hydrolyzed from the peptides were quantified in a spectrofluorophotometer (Shimadzu, RF-5000) using 380-nm excitation/460-nm emission wavelengths, and 342-nm excitation/460-nm emission wavelengths, respectively. Enzymatic activity was normalized for protein concentration and expressed as percentage of activity present in control extracts. Each measurement was carried out with three independent VIGS plants.
Western Blot Analysis of the Levels of SubunitsWestern blot analysis was carried out as described (16). Fifty µg of proteins were electrophoresed on a 10% SDS-PAGE, transferred onto polyvinylidene difluoride membranes, and probed with the monoclonal antibody raised against the mixture of six
subunits (
1,
2,
3,
5,
6, and
7) (1:1000 dilution; Affiniti Research Products Ltd). They were then reacted with secondary antibodies conjugated with horseradish peroxidase and ECL reagent (Amersham Biosciences) for detection.
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RESULTS |
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Suppression of the NbPAF and NbRpn9 Transcripts in the Corresponding VIGS LinesTo confirm gene silencing of NbPAF, we cloned three different fragments of the NbPAF cDNA into the TRV-based VIGS vector pTV00 (15), and infiltrated N. benthamiana plants with Agrobacterium containing each plasmid (Fig. 1A). TRV:PAF(N) and TRV:PAF(C) contains the 0.3-kb N- and 0.3-kb C-terminal regions of the cDNA, whereas TRV:PAF(F) contains the full-length NbPAF cDNA. VIGS with the three constructs all resulted in the same phenotype of severe abnormality in plant development (Fig. 1B). Newly emerged leaves were small, severely curled, and wrinkled, making a cluster near the shoot apex, and the stem growth was completely arrested. Massive cell death soon followed, which resulted in premature death of the whole tissues of newly emerged leaves and flower buds. The effects of gene silencing on the endogenous amounts of the NbPAF mRNA were examined using semiquantitative RT-PCR (Fig. 1C), because the level of the transcript was low in the leaves. Primers for RT-PCR were designed to exclude the cDNA regions used in the VIGS constructs, and the transcript levels of the actin and the 3 subunit of the 20 S proteasome (NbPBC) were measured as controls. RT-PCR using NbPAF-N primers that detect the N-terminal region of the NbPAF cDNA produced significantly reduced amounts of PCR products in the VIGS lines of TRV: PAF(C) compared with the TRV control, indicating that the endogenous level of the NbPAF transcripts is greatly reduced in those plants. The same primers detected high levels of viral genomic transcripts containing the N-terminal region of NbPAF in the TRV:PAF(N) and TRV:PAF(F) lines. In contrast, NbPAF-C primers that recognize the C-terminal region of the cDNA showed suppression of the endogenous NbPAF transcripts in the TRV:PAF(N) lines, whereas they detected the viral genomic transcripts in the TRV:PAF(C) and TRV:PAF(F) lines. The transcript levels of NbPBC and actin remained constant. These results demonstrate that expression of NbPAF was significantly reduced in the VIGS lines.
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The NbRpn9 VIGS lines showed the same phenotypes as that of the NbPAF VIGS lines (Fig. 1D). Silencing of NbRpn9 was examined via semiquantitative RT-PCR using the primers that detect the cDNA region not covered in the VIGS construct. Compared with TRV control, the endogenous level of NbRpn9 transcripts was greatly reduced in the TRV:Rpn9 VIGS lines, whereas the transcript levels of NbPAF, NbPBC, and actin remained constant (Fig. 1E).
Phenotypes of Programmed Cell DeathWe examined nuclear morphology of cells in the abaxial epidermal layer from the leaves of the VIGS lines by DAPI staining (Fig. 2A). In the epidermal cells of the TRV:PAF(N) leaves, condensation and margination of nuclear chromatin were evident, whereas chromatin was evenly distributed within the nucleus in the control lines. Furthermore, DNA laddering was observed in the genomic DNA of TRV:PAF(N) and TRV:Rpn9 lines (Fig. 2B). DNA ladder is formed during PCD because of the activation of cell death-specific endonucleases that cleave the nuclear DNA into oligonucleosomal units. To visualize DNA laddering, the genomic DNA extracts from the VIGS lines were fractionated, transferred to nylon membranes, and hybridized with radiolabeled total genomic DNA and chloroplast DNA of N. benthamiana. DNA laddering was observed with the total genomic DNA probe, whereas the chloroplast DNA probe resulted in DNA degradation but without the laddering pattern, because the chloroplast genomic DNA is not packaged into nucleosomes. Because nuclear condensation and DNA laddering are the hallmark features of PCD, these results demonstrate that reduced expression of these proteasome subunits activates programmed cell death in plants. Interestingly, virus-induced gene silencing of other proteasome subunits (1,
4, and Rpn3) also caused DNA laddering, indicating that inhibition of proteasome function by reduced availability of individual subunits is the reason for the PCD activation (Supplementary Fig. 1, available in the on-line edition of this article; Fig. 3). DNA laddering was also observed by gene silencing of ubiquitin, consistent with the previous report (14). In contrast, virus-induced gene silencing of other presumably essential genes of plants, such as cellulose synthase or glucan synthase, did not induce the PCD phenotypes, despite the fact that it resulted in severe morphological phenotypes including growth arrest and premature death of plants (Supplementary Fig. 1; Fig. 3). Thus, PCD appears to be activated by disrupted function of specific sets of genes such as ubiquitin and proteasome subunits.
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Gene Silencing of the Proteasome Subunits Inhibits Proteasome ActivityTo examine functional consequence of gene silencing of the proteasome subunits, we measured proteasome activities in cell extracts from TRV control, TRV:PAF(N), TRV: PAF(C), and TRV:PAF(F) lines using peptide substrates in the absence or presence of proteasome inhibitor MG132 (Fig. 4A). Previously, it has been shown that plant proteasomes possess classical chymotrypsin-like, peptidylglutamylpeptide hydrolyzing-like, and trypsin-like activities against fluorescent synthetic peptide substrates (18, 19). Indeed, compared with the control, reduced expression of the 6 subunit using the three VIGS constructs significantly reduced the hydrolysis of Suc-Leu-Leu-Val-Tyr-AMC, Z-Leu-Leu-Leu-AMC, and Z-Gly-Gly-Arg-
NA, synthetic peptide substrates of the chymotrypsin-like, PGPH-like, and trypsin-like activities of the proteasome, respectively. The degree of reduced activity was comparable with or slightly more than that achieved by lactacystin or RNA interference of the proteasome subunits in animal cells (20, 21). These results demonstrate that VIGS-promoted depletion of the proteasome subunits decreased all three types of proteasome activity. Proteasome inhibitor MG132 significantly reduced all three types of proteasome activity in TRV control, demonstrating that most of the hydrolytic activity indeed comes from proteasome (Fig. 4A). However, the residual peptidase activity, particularly the trypsin-like activity, still remained in the extracts from TRV control as well as from TRV: PAF lines. These inhibitor-resistant residual activities likely represent other proteases besides the 26 S proteasome. The measured peptidase activity of all three types did not differ significantly in the absence or presence of MG132 in the TRV: PAF samples, indicating that VIGS abolished most of active 26 S proteasome complex. The reduced proteasome activity by gene silencing of PAF is likely caused by interference of proteasome assembly resulting from the reduced expression of the subunits. RNA interference of the individual proteasome subunit in Drosophila and trypanosome all resulted in disruption of proteasome assembly, and as a consequence, reduction of proteasome activity (20, 21).
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Depletion of the Proteasome Subunits Leads to Accumulation of Polyubiquitinated Cellular ProteinsMost physiological substrates of the 26 S proteasome are cellular proteins covalently modified with a polyubiquitin chain. To determine the effect of gene silencing of the proteasome subunits on the degradation of such proteins, we carried out Western blotting with cell extracts of TRV control, TRV:PAF(N), TRV:PAF(C), and TRV:PAF(F) lines with a mouse anti-ubiquitin monoclonal antibody (Fig. 4B). It resulted in a smear of high molecular weight immunoreactive materials displaying many cellular proteins modified by polyubiquitin chains. Compared with the TRV control, gene silencing of the 6 subunit using the three different VIGS constructs greatly increased the level of polyubiquitinated proteins. Previously, inhibition of proteasome activity by proteasome inhibitors or by RNA interference of the proteasome subunits also increased the intensity of this smear, displaying accumulation of non-degraded cellular proteins in animal cells (20, 21). In plants, mutants of MCB1 (RPN10) and UBP14 (ubiquitin-specific protease) exhibited increased steady state levels of cellular ubiquitinated proteins (22, 23). These results mirrored corresponding effects of gene silencing on proteasome activity against peptide substrates.
Protein Levels of 6 and Other
Subunits in TRV:PAF LeavesThe protein levels of
6 and other
subunits in TRV: PAF plants were examined by Western blotting with the monoclonal antibody raised against the mixture of six
subunits (
1,
2,
3,
5,
6, and
7) and
-tubulin antibody as a control (Fig. 4C). In three different TRV:PAF lines, the
6 subunit level significantly decreased because of gene silencing, whereas the combined levels of other five
subunits remained constant.
Involvement of ROSTo test whether ROS are produced in the cells undergoing PCD in the VIGS lines, we prepared protoplasts from leaves from TRV or the mixture of TRV:PAF(N), TRV:PAF(C), and TRV:PAF(F) lines, and incubated the protoplasts with H2DCFDA to visualize the green fluorescent signal of which activation depends on the presence of H2O2 (Fig. 5A). H2DCFDA is a cell-permeant indicator for ROS that is nonfluorescent until the acetate groups are removed by intracellular esterases and oxidation occurs within the cell (24). The rate of the accumulation of fluorescent H2DCFDA in protoplasts from the TRV:PAF VIGS lines was significantly higher than that of the TRV control; the mean fluorescence for the protoplasts from the TRV:PAF lines reached 10-fold higher level than that of the TRV control (Fig. 5B). These results demonstrate that reactive oxygen species are involved in this cell death program. The overall activity of POD and APX, the enzymes hydrolyzing H2O2 to water and oxygen, was measured using leaf extracts of the control TRV and the mixture of TRV:PAF VIGS lines. The relative activity of POD was similar in both control and TRV:PAF leaves (Fig. 5C), whereas the APX activity was approximately 1.7-fold lower in the TRV:PAF leaves than control (Fig. 5D). Plant cell death is associated with an increase in cellular membrane leakage (25), which can be measured by ion leakage. The TRV:PAF leaves exhibited 3-fold higher levels of relative ion leakage than leaves from the TRV control (Fig. 5E).
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Disrupted Membrane Potential of Mitochondria and Release of Cytochrome cDuring apoptosis in animal cells, modification of the mitochondrial membrane permeability initiates the death execution pathway. Mitochondrial membrane potential of the protoplasts isolated from leaves of TRV control and the mixture of TRV:PAF VIGS lines was monitored by TMRM fluorescent probes (Fig. 6A). TMRM is a lipophilic cation that is accumulated in mitochondria in proportion to the mitochondrial membrane potential (26). A drop in the membrane potential leads to a decrease in fluorescence caused by the diminished capacity of mitochondria to retain the probe. The average fluorescence of protoplasts from TRV:PAF leaves was approximately 4-fold lower than TRV control, indicating disruption of mitochondrial membrane potential. During apoptosis in animal cells, the release of cytochrome c occurs before visible morphological changes. We investigated cytochrome c relocation during the PCD. Leaves of the VIGS lines were homogenized, and the mitochondria were separated from the cytosol by differential centrifugation. The proteins in each fraction were analyzed by Western blot analysis using a monoclonal cytochrome c antibody and a monoclonal antibody against VDAC as a control for fractionation (Fig. 6B). VDAC is localized in the outer membrane of mitochondria and forms a channel through which metabolites pass (27). The Western blot revealed that cytochrome c was mainly detected in the mitochondria in the TRV control, whereas it was detected only in the cytosol fraction in the TRV:PAF lines. VDAC was detected only in the mitochondria fraction. This result shows that cytochrome c is released from mitochondria to cytosol, an early event of apoptosis in animal cells, during PCD in the VIGS lines.
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Activation of Caspase-like ActivityDuring apoptosis in animal cells, relocated cytochrome c induces assembly of the caspase-9 activating complex, which in turn propagates a cascade of further caspase activation, including caspase-3. Using synthetic fluorogenic substrates for animal caspase-9 (LEHD-AFC) and caspase-3 (DEVD-AFC), we found that extracts from TRV:PAF(N), TRV:PAF(C), and TRV:PAF(F) leaves all exhibited both caspases 9-like and caspase 3-like proteolytic activities (Fig. 7). Activation of caspase-like protease activity could not be detected in TRV control leaves compared with the leaves of no treatment.
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Markers Associated with HR Cell DeathPlant cells undergoing hypersensitive cell death deposit autofluorescing secondary metabolites and cell wall materials such as callose and aromatic polymers at infection sites. We examined the presence of the autofluorescent material and callose in the leaves of the TRV:PAF(N) and TRV:Rpn9 VIGS lines that undergo PCD. Fig. 8A demonstrates that leaves of both VIGS lines accumulated substantial amounts of autofluorescent products and callose. TRV control showed only small patches of those materials, primarily along the vein. Both TRV:PAF and TRV:Rpn9 VIGS lines also exhibited intense staining on the leaves with Evans blue indicating localized cell death, whereas TRV control showed no staining (Fig. 8A). These results demonstrate that some features of HR cell death are conserved in the PCD program induced by disruption of proteasome function.
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We also examined whether the proteasome-mediated PCD induces expression of defense-related genes using semiquantitative RT-PCR (Fig. 8B). PR1a, PR1b, PR1c, PR2, PR4, PR5, S25-PR6, SAR8.2a, HSR203J, HIN1, and 630 genes are all highly induced during HR cell death (28). NTCP-23 (cysteine protease) and p69d (serine protease) have been shown to be involved in pathogen-induced cell death (29), whereas the chloroplastic ClpP protease plays a role in chloroplast development but not in senescence or HR cell death (29). Among these genes, only PR2, PR5, HIN1, ClpP, and NTCP-23 genes were transcriptionally induced in both the TRV:PAF(N) and TRV:Rpn9 VIGS lines. Expression of SGT1, RAR1, and SKP1, recently identified signaling genes in plant defense (30, 31, 32), remained constant. Thus the proteasome-mediated PCD process promotes expression of only a subset of PR genes. Taken together, some features of HR cell death are conserved in the proteasome-mediated PCD program, but its gene expression profile is significantly different from the HR, indicating a possibility of differential regulation of each PCD pathway.
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DISCUSSION |
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Recent findings suggest diverse action mechanisms of ubiquitin/proteasome pathway in the regulation of PCD (8). Important regulators of apoptosis, including the Bcl-2 family of proteins and the inhibitor of apoptosis proteins (34), have been newly identified as substrates of the proteasome. Furthermore, the tumor suppressor p53 and other cell cycle proteins that are already known to be substrates of the proteasome, and inhibitor of apoptosis proteins, which are critically involved in the negative regulation of apoptosis, have been shown to play an active role in the proteolytic inactivation of death executors (8, 9). The evidence of possible involvement of proteasome in PCD in plants has only begun to emerge. Recently, ubiquitin ligase-associated protein SGT1 has been found to be essential for R gene-mediated disease resistance (30, 35) and HR cell death elicited by multiple resistance interactions (35). Furthermore, SGT1 and RAR1 (SGT1-interacting protein) are co-immunoprecipitated with COP9 signalosome, demonstrating a direct interaction between COP9 signalosome and ubiquitin ligases (31). These results suggest that the ubiquitin protein degradation pathway regulate at least a subset of R-mediated defense responses and HR cell death (36).
Compared with animal system, relatively little information is available on the detailed mechanism of PCD in plants. However, some aspects of the molecular machinery of PCD seem to be conserved between plants and animals. Numerous mediators of disease resistance signaling in plants share conserved motifs with proteins that have similar roles in the defense response of animals (7). Furthermore, overexpression of Bax, which encodes a mammalian proapoptotic protein, induces PCD in plants and yeast (37, 38). In animal cells, mitochondria-mediated PCD acts through Bax family of proteins, which associates with the mitochondria membrane and forms an ion-conduction channel through which macromolecules and metabolites can pass (39). Although Bax plays a critical role in mitochondrion-mediated PCD in mammals, plants and yeast lack these proteins and many other regulators of mammalian PCD. Nevertheless, Bax-induced PCD in plant cells indicates common underlying mechanisms between animal and plant cell death programs.
In this study, we have demonstrated that proteasome-mediated cell death in plants involves the common components of apoptosis in animal cells, including decreased mitochondrial membrane integrity, ROS production, cytochrome c release, and activation of caspase-like protease activities. Although plant genome lacks direct homologues of caspase genes, caspase-like protease activities have been detected in the HR cell death and in PCD associated with other nonpathogenic responses, such as heat, menadione, and isopentenyladenosine treatment (40, 41, 42). Interestingly, HR cell death and the caspase-like activities were specifically inhibited by caspase inhibitors but not by other types of inhibitor including those targeting serine proteases, metalloproteases, calpain, and aspartate proteases (40, 43). The caspase 3-like activity found in barley embryonic cells also could be inhibited by the specific caspase 3 inhibitors, but not by general cysteine protease inhibitors (44). Recently, a family of caspase-related proteases (the metacaspases) has been identified in Arabidopsis based on homology searches (45). It remains to be seen whether the metacaspases are functionally equivalent to mammalian caspases in controlling cell-death activation. Several reports point to the importance of the mitochondria in the expression of HR cell death in plants, although it is not clear whether cytochrome c leakage occurs during the HR. Cytochrome c leakage and activation of caspase-like proteases was detected in our study, and during isopentenyladenosine- and heat-induced PCD, but not during petal senescence-associated PCD (41, 42, 46, 47). It remains to be investigated whether the released cytochrome c promotes assembly of the caspase-activating complex in the cytosol, as in the case of animal cells.
Disruption of two different proteasome subunits both induced transcription of defense genes, such as PR2, PR5, Hin1, and NTCP-23 (cysteine protease), and ClpP protease (Fig. 7B). However, expression of other genes that are also highly induced during the HR cell death, including PR1, PR4, HSR203J, SAR8.2, and p69d (serine protease), was not stimulated. No induction of PR1a and SAR8.2 indicates that the level of salicylic acid, a positive regulator of the HR cell death, is not elevated during the proteasome-mediated PCD. Hin1 and HSR203J, which showed opposite expression patterns in this study, have been shown to be associated in HR cell death, but not with senescence-related cell death (28). HSR203J encoding a serine hydrolase is believed to play a role in the limitation of cell death during HR (48). In addition, the chloroplastic ClpP protease is involved in chloroplast development but not in senescence or HR cell death (29). These different gene expression profiles indicate that PCD pathway activated by the two different means, i.e. proteasome inhibition and pathogen, may be differentially regulated, at least partly, with possible involvement of distinct downstream components. A microarray analysis of gene expression of 100 selected genes demonstrated that heat- and senescence-induced PCD each caused stimulated expression of a distinctive set of genes, whereas there is some overlap in the differential gene expression between the two system (49). Particularly, certain oxidative stress-related genes and cysteine proteases, and several genes involved in the HR cell death, appeared to be commonly involved during PCD induced by the two different means (49). Functions of these genes in programmed cell death remain to be tested.
The 20 S proteasome consists of two copies each of seven distinctive - and seven distinctive
-type subunits (50). In Saccharomyces cerevisiae, gene disruption of the individual genes encoding the 14 subunits of the 20 S proteasome was carried out. The results indicated that 13 of the 14 subunits are essential to the viability of yeast cells; the only subunit that turned out to be nonessential is
3 (51) The deletion mutant of the
3 subunit gene has a longer generation time than the wild-type cells and showed altered chymotryptic activities (51). Finley and co-workers (52) tested the functional effects of mutations in the ATP-binding motif of each of the six RPT genes in S. cerevisiae; four were lethal, and two conferred a strong growth defect, implying that these ATPases are not functionally redundant. Recently, using RNA interference, effects of reduced expression of individual proteasome subunits of the 19 S regulatory complex were examined in Drosophila and trypanosome (20, 21). In both cases, reduced expression of individual proteasome subunits disrupted proteasome complex formation and resulted in increased apoptosis, accumulation of ubiquitinated cellular proteins, and decreased cell proliferation. Among 11 Rpn subunits of the 19 S regulatory complex, Rpn9 and Rpn10 are not essential for the viability of S. cerevisiae (50, 53), whereas only Rpn10 is not essential in Drosophila (20, 21). In trypanosome, each of the 11 Rpn subunits was found indispensable for the viability (20). Yeast
rpn9 cells grow normally at the permissive temperature but displayed strong growth defect at nonpermissive temperature and became arrested at the G2/M phase of cell cycle (50). These cells contained 26 S proteasome that was shifted to lighter fractions in a glycerol density gradient. However, this incomplete proteasome complex, which also misses Rpn10, is functionally adequate in maintaining cell viability (50). In this study, we found that reduced expression of the
6,
1,
4, Rpn3, and Rpn9 subunits all activated the PCD pathway; thus, all of these subunits are essential for survival of plant cells.
Our results demonstrated the involvement of the ubiquitin/proteasome pathway in the regulation of PCD in plant cells. The proteasome is expected to play a role in regulation of plant cell death in multilevels, including proteolytic inactivation of unidentified apoptosis regulators and death executers. Stability of an individual proteasome subunit may be a target of regulation for controlling the PCD program. It will be important to investigate whether various developmentally or environmentally activated cell death programs of plants involve modulation of proteasome function. In this scenario, some PCD pathways of plants may include signaling molecules that modify proteasome activity to activate the cell demolition process when death signals are perceived. To identify the important players in cell death activation in plants, reverse genetic approaches such as virus-induced gene silencing, coupled with bioinformatics approaches, will be useful to screen a large number of candidate regulators. Probing functional roles of the proteasome in PCD activation may give insight into how death signals, including developmental or pathogen-related signals, are perceived and translated into a cascade of changes leading to plant cell death. These efforts may reveal unique mechanisms of PCD program in plant cells, in addition to the conserved mechanisms between animals and plants. Finally, from an applied perspective, the ability to induce cell death by gene silencing of proteasome subunits may have useful applications in agriculture by providing a tool to selectively kill certain cells and tissues.
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* This work was supported by grants from the National Research Laboratory Program and Plant Diversity Research Center of 21st Century Frontier Research Program, funded by the Korean Ministry of Science and Technology. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
The on-line version of this article (available at http://www.jbc.org) contains Supplemental Fig. 1 and legend.
¶ To whom correspondence should be addressed. Tel.: 82-42-860-4195; Fax: 82-42-860-4608; E-mail: hyunsook{at}kribb.re.kr.
1 The abbreviations used are: PCD, programmed cell death; HR, hypersensitive response; ROS, reactive oxygen species; Tricine, N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; RT, reverse transcription; VIGS, virus-induced gene silencing; H2DCFDA, 2',7'-dichlorodihydrofluorescein diacetate; POD, peroxidase; APX, ascorbate peroxidase; AFC, 7-amino-4-trifluoromethylcoumarin; AMC, 7-amino-4-methylcoumarin; NA,
-naphthylamide; TMRM, tetramethylrhodamine methyl ester; VDAC, voltage-dependent anion channel; TRV, tobacco rattle virus.
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