Subcellular localization of host and viral proteins associated with tobamovirus RNA replication
2003; Springer Nature; Volume: 22; Issue: 2 Linguagem: Inglês
10.1093/emboj/cdg033
ISSN1460-2075
Autores Tópico(s)Insect symbiosis and bacterial influences
ResumoArticle15 January 2003free access Subcellular localization of host and viral proteins associated with tobamovirus RNA replication Yuka Hagiwara Yuka Hagiwara Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Keisuke Komoda Keisuke Komoda Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Takuya Yamanaka Takuya Yamanaka Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Atsushi Tamai Atsushi Tamai Graduate School of Science, Kyoto University, Kyoto, 606-8502 Japan Search for more papers by this author Tetsuo Meshi Tetsuo Meshi Graduate School of Science, Kyoto University, Kyoto, 606-8502 Japan CREST, Japan Science and Technology Corporation, Japan Search for more papers by this author Ryo Funada Ryo Funada Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Tomohiro Tsuchiya Tomohiro Tsuchiya Graduate School of Bioagricultural Sciences, Nagoya University, Nagoya, 464-8601 Japan Search for more papers by this author Satoshi Naito Satoshi Naito Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Masayuki Ishikawa Corresponding Author Masayuki Ishikawa Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan CREST, Japan Science and Technology Corporation, Japan Search for more papers by this author Yuka Hagiwara Yuka Hagiwara Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Keisuke Komoda Keisuke Komoda Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Takuya Yamanaka Takuya Yamanaka Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Atsushi Tamai Atsushi Tamai Graduate School of Science, Kyoto University, Kyoto, 606-8502 Japan Search for more papers by this author Tetsuo Meshi Tetsuo Meshi Graduate School of Science, Kyoto University, Kyoto, 606-8502 Japan CREST, Japan Science and Technology Corporation, Japan Search for more papers by this author Ryo Funada Ryo Funada Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Tomohiro Tsuchiya Tomohiro Tsuchiya Graduate School of Bioagricultural Sciences, Nagoya University, Nagoya, 464-8601 Japan Search for more papers by this author Satoshi Naito Satoshi Naito Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan Search for more papers by this author Masayuki Ishikawa Corresponding Author Masayuki Ishikawa Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan CREST, Japan Science and Technology Corporation, Japan Search for more papers by this author Author Information Yuka Hagiwara1, Keisuke Komoda1, Takuya Yamanaka1, Atsushi Tamai2, Tetsuo Meshi2,3, Ryo Funada1, Tomohiro Tsuchiya4, Satoshi Naito1 and Masayuki Ishikawa 1,3 1Graduate School of Agriculture, Hokkaido University, Sapporo, 060-8589 Japan 2Graduate School of Science, Kyoto University, Kyoto, 606-8502 Japan 3CREST, Japan Science and Technology Corporation, Japan 4Graduate School of Bioagricultural Sciences, Nagoya University, Nagoya, 464-8601 Japan *Corresponding author. E-mail: [email protected] The EMBO Journal (2003)22:344-353https://doi.org/10.1093/emboj/cdg033 PDFDownload PDF of article text and main figures. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info Arabidopsis TOM1 (AtTOM1) and TOM2A (AtTOM2A) are integral membrane proteins genetically identified to be necessary for efficient intracellular multiplication of tobamoviruses. AtTOM1 interacts with the helicase domain polypeptide of tobamovirus-encoded replication proteins and with AtTOM2A, suggesting that both AtTOM1 and AtTOM2A are integral components of the tobamovirus replication complex. We show here that AtTOM1 and AtTOM2A proteins tagged with green fluorescent protein (GFP) are targeted to the vacuolar membrane (tonoplast)-like structures in plant cells. In subcellular fractionation analyses, GFP–AtTOM2A, AtTOM2A and its tobacco homolog NtTOM2A were predominantly fractionated to low-density tonoplast-rich fractions, whereas AtTOM1–GFP, AtTOM1 and its tobacco homolog NtTOM1 were distributed mainly into the tonoplast-rich fractions and partially into higher-buoyant-density fractions containing membranes from several other organelles. The tobamovirus-encoded replication proteins were co-fractionated with both NtTOM1 and viral RNA-dependent RNA polymerase activity. The replication proteins were also found in the fractions containing non-membrane-bound proteins, but neither NtTOM1 nor the polymerase activity was detected there. These observations suggest that the formation of tobamoviral RNA replication complex occurs on TOM1-containing membranes and is facilitated by TOM2A. Introduction The replication of positive-strand RNA viruses occurs via the negative-strand RNAs on the cytoplasmic surface of intracellular membranes. Brome mosaic virus (BMV) forms replication complexes on the endoplasmic reticulum (ER) membranes (Restrepo-Hartwig and Ahlquist, 1996; Restrepo-Hartwig and Ahlquist, 1999; Schwartz et al., 2002). Tobacco etch virus, cowpea mosaic virus and poliovirus induce proliferation or rearrangement of the ER membranes on which replication complexes are localized (Schaad et al., 1997; Carette et al., 2000; Egger et al., 2000; Rust et al., 2001). The replication complex of Semliki Forest virus is associated with the lysosomal or the endosomal membranes (Froshauer et al., 1988; Kujala et al., 2001). The replication of flock house virus, turnip yellow mosaic virus and alfalfa mosaic virus (AMV) occurs in association with the mitochondrial outer membranes, the chloroplast outer membranes and the vacuolar membranes, respectively (Miller et al., 2001; Prod'homme et al., 2001; van der Heijden et al., 2001). Thus the sites of viral RNA synthesis vary depending on the virus, and the replication complexes are tethered on the membranes in their specific manners. At present, the mechanisms by which each viral replication complex is associated with specific membranes or the precise structures of the replication complexes have not been revealed. The tobamovirus group belongs to the alphavirus-like superfamily of positive-strand RNA viruses (Buck, 1996). The genome of a tobamovirus encodes non-structural proteins with an approximate molecular mass of 130 kDa (130K protein), its read-through product with an approximate molecular mass of 180 kDa (180K protein), a 30 kDa non-structural protein known as movement protein (MP), which is required for the cell-to-cell movement of the virus, and the coat protein (CP). The 130K and 180K proteins (the 130K/180K proteins) are both involved in viral RNA replication (Ishikawa et al., 1986), whereas MP and CP are dispensable for replication (Meshi et al., 1987; Takamatsu et al., 1987). The 130K protein harbors domains implicated in RNA capping and helicase functions, and the read-through region of the 180K protein contains an RNA polymerase motif. These domains are conserved among the α-like viruses, implying that these viruses replicate through similar mechanisms. The 130K/180K proteins are known to be contained in a membrane-bound RNA-dependent RNA polymerase (RdRp) complex (Osman and Buck, 1996). Immunofluorescent microscopy of tobamovirus-infected plant cells suggested that these replication proteins are localized on the ER membranes (Heinlein et al., 1998; Más and Beachy, 1999), whereas immunoelectron microscopy suggested that they are localized in the cytoplasmic inclusion bodies induced by tobamovirus infection (Hills et al., 1987; Saito et al., 1987). Arabidopsis thaliana TOM1 (AtTOM1) and TOM2A (AtTOM2A) have been suggested as host factors involved in intracellular multiplication of tobamoviruses, since inactivation of either the AtTOM1 or the AtTOM2A gene results in a decreased multiplication of tobamoviruses (Ishikawa et al., 1993; Ohshima et al., 1998). AtTOM1 and AtTOM2A are predicted to be seven-pass and four-pass transmembrane proteins, respectively, but neither of them possesses well-known sorting signals to specific organelles (Yamanaka et al., 2000; Tsujimoto et al., 2003). AtTOM1 has been shown to interact with the tobamovirus-encoded 130K/180K proteins (Yamanaka et al., 2000). Recent studies have suggested that AtTOM2A interacts both with itself and with AtTOM1 (Tsujimoto et al., 2003). Taking these observations together, we propose that AtTOM1 and AtTOM2A are constituents of the replication complex of tobamoviruses and play important roles in the formation of the complex on the membranes where they co-localize. Furthermore, we have identified the homologs of AtTOM1 and AtTOM2A in Nicotiana tabacum (NtTOM1 and NtTOM2A, respectively) and found that NtTOM1 also interacts with the tobamovirus-encoded 130K/180K proteins (unpublished data). In this study, the subcellular localizations of At- and NtTOM1 and At- and NtTOM2A were determined by combined analyses of confocal laser scanning microscopy and iodixanol density-gradient centrifugation. These analyses revealed that both TOM1 and TOM2A are mainly localized to the vacuolar membranes (i.e. the tonoplasts). Tobamovirus-encoded membrane-bound 130K/180K proteins were co-fractionated with the activity to synthesize the viral RNA as well as with NtTOM1. Our findings suggest that the replication complex of tobamoviruses is localized at least in part on the tonoplasts and that TOM1 plays a critical role in the formation of the complex on specific membranes. Results Subcellular localization of GFP–tagged TOM proteins To study the intracellular localization of TOM1 and TOM2A in living cells, we used green fluorescent protein (GFP) as a reporter. GFP was fused in frame to either the N- or C-termini of AtTOM1 and AtTOM2A. The resulting constructs, GFP–AtTOM1, AtTOM1–GFP, GFP–AtTOM2A, and AtTOM2A–GFP, were expressed transiently in epidermal cells of A.thaliana leaves by microprojectile bombardment. The GFP fluorescence in the cells was analyzed under a confocal laser scanning microscope. Figure 1A shows a representative image of an epidermal cell transiently expressing free GFP. In addition to its preferential accumulation inside the nucleus, GFP fluorescence was observed in the area lining the plasma membrane. The vacuoles of mature leaf epidermal cells generally occupy most of the intracellular space and press the cytoplasm against the plasma membrane. Therefore the observed fluorescence lining the plasma membrane is likely to represent cytoplasmic localization. Of the two GFP-fused AtTOM1 constructs, only AtTOM1–GFP successfully showed the GFP fluorescence (Figure 1B; data not shown). The fluorescence was found in the area lining the plasma membrane but not in the nucleus. However, it is difficult to specify whether the observed fluorescence is derived from the cytoplasm, tonoplast, plasma membrane or other organelles. Essentially the same fluorescent pattern was observed in cells transiently expressing either GFP–AtTOM2A or AtTOM2A–GFP (Figure 1C; data not shown). AtTOM2A is predicted to possess a putative farnesylation signal (Tsujimoto et al., 2003). This signal functions only at the C-terminus of a protein, so that GFP–AtTOM2A but not AtTOM2A–GFP should preserve the functional signal. Considering the possible importance of AtTOM2A farnesylation, GFP–AtTOM2A was used for further analyses. The distribution patterns of AtTOM1–GFP and GFP–AtTOM2A in epidermal cells of Nicotiana benthamiana and N.tabacum were the same as in A.thaliana cells when transiently expressed (data not shown). Figure 1.Confocal laser scanning micrographs of A.thaliana epidermal cells transiently expressing (A) GFP, (B) AtTOM1–GFP and (C) GFP–AtTOM2A. A single optical section of the cell is shown on the left, and a projection of 10 × 1 μm confocal optical sections through the cell is shown on the right. Note that the leaf epidermal cells have a 'jigsaw-puzzle-like' appearance and possess huge vacuoles that occupy most of the intracellular space. Scale bars, 25 μm. Download figure Download PowerPoint Nicotiana tabacum BY-2 suspension-cultured cells are known to have relatively undeveloped vacuoles compared with mature leaf epidermal cells. Owing to the difficulty in determining the subcellular localization of AtTOM1 and AtTOM2A in epidermal cells, we used BY-2 cells for further investigation. When BY-2 cells stably expressing AtTOM1–GFP and GFP–AtTOM2A were analyzed by confocal laser scanning microscopy, strikingly clear images were obtained compared with those of leaf epidermal cells. In cells expressing AtTOM1–GFP (Figure 2A) and GFP–AtTOM2A (Figure 2B), the GFP fluorescence was targeted to the intracellular membranes of round-shaped structures. These structures were indistinguishable from the fluorescent membrane structures observed in BY-2 cells transiently expressing the GFP-fused AtTOM proteins obtained by microprojectile bombardment (data not shown). Figure 2.Confocal laser scanning micrographs of transgenic BY-2 cells expressing (A) AtTOM1–GFP, (B) GFP–AtTOM2A, (C) GFP–VM23, (D) GmMan1–GFP, (E) GFP–PAQ1 and (F) mGFP5ER. A single optical section through several cells is displayed on the lower left, and its Nomarski image is shown on the upper left. A high-magnification image is shown on the right. Scale bars, 10 μm. Download figure Download PowerPoint To identify the observed membrane structures, we analyzed transgenic BY-2 cells stably expressing GFP-tagged in vivo markers for several major organelles, including a tonoplast protein GFP–VM23 (Maeshima, 1992; T.Tsuchiya, S.Suga and M.Maeshima, unpublished data), a Golgi membrane protein GmMan1–GFP (Nebenführ et al., 1999), a plasma membrane protein GFP–PAQ1 (Suga et al., 2001; T.Tsuchiya, S.Suga and M.Maeshima, unpublished data) and an ER-localized GFP marker protein mGFP5ER (Haseloff and Siemering, 1998). It was found that the round-shaped membrane structures shown in the cells expressing AtTOM1–GFP and GFP–AtTOM2A have a strong resemblance to those observed for GFP–VM23 (Figure 2C). Such structures did not appear in cells expressing GmMan1–GFP (Figure 2D), GFP–PAQ1 (Figure 2E) or mGFP5ER (Figure 2F). Furthermore, cells expressing the GFP-tagged AtTOM proteins did not show the ER-like reticulate structures, the Golgi-like fluorescent spots or a fluorescent line observed between two neighboring GFP–PAQ1-expressing cells. The vital membrane stain FM4-64, which is known as the endocytic tracer, visualizes the vacuolar membranes in yeast (Vida and Emr, 1995) and plant cells (Ueda et al., 2001; Kutsuna and Hasezawa, 2002). In order to verify that AtTOM1–GFP and GFP–AtTOM2A reside on the tonoplast, the transgenic BY-2 cells were pulse-labeled with FM4-64. As shown in Figure 3A, E and I, FM4-64 first labeled the plasma membranes (red signals), which did not overlap the membrane structures visualized by the GFP-fused TOM proteins or the tonoplast marker GFP–VM23 (green signals). Approximately 10 h after labeling, the fluorescence of FM4-64 transported to the tonoplasts by endocytosis overlapped perfectly with the GFP fluorescence in cells expressing AtTOM1–GFP (Figure 3B–D) and GFP–AtTOM2A (Figure 3F–H). The complete overlap of the signals of FM4-64 and GFP–VM23 (Figure 3J–L) confirmed the tonoplast localization of FM4-64. These observations clearly demonstrated that AtTOM1–GFP and GFP–AtTOM2A are both localized mainly to the tonoplasts. This also implies that the fluorescent structures observed in leaf epidermal cells expressing the GFP-fused TOM proteins (see Figure 1B and C) represent the tonoplasts rather than the plasma membranes or appressed cytoplasm. Figure 3.Confocal laser scanning micrographs of FM4-64-treated transgenic BY-2 cells expressing (A–D) AtTOM1–GFP, (E–H) GFP–AtTOM2A and (I–L) GFP–VM23. Cells are shown at ∼20 min (A, E, I) and 10 h (B–D, F–H, J–L) after labeling. The GFP and FM4-64 signals are shown as green and red, respectively. In the merged images (A, D, E, H, I, L), the overlapping signals of GFP and FM4-64 appear as yellow. Scale bars, 10 μm. Download figure Download PowerPoint Subcellular fractionation analysis of TOM proteins For further investigation of the localization of the TOM proteins, we employed membrane flotation analysis using equilibrium iodixanol density-gradient centrifugation. Through iodixanol gradients, membranes and membrane-associated proteins of different intracellular compartments are finely separated according to their buoyant density, as previously reported (see, for example, Tritel and Resh 2000; Kim et al. 2002). First, we analyzed the distribution of the GFP-fused AtTOM proteins and tobacco TOM homologs, NtTOM1 and NtTOM2A, in the gradients to confirm that the localization of the GFP fusions shown by confocal microscopy reflects that of the non-tagged authentic TOM proteins. The transgenic BY-2 cells expressing AtTOM1–GFP or GFP–AtTOM2A and the non-transgenic BY-2 cells were disrupted and centrifuged at a low speed to pellet and remove cell debris. The lysates were loaded into the bottom of the gradients and centrifuged at 114 000 g for 16 h. The gradients were then fractionated and analyzed by immunoblotting. An antibody against GFP was used to detect AtTOM1–GFP and GFP–AtTOM2A. NtTOM1 and NtTOM2A were detected using antisera against AtTOM1 and AtTOM2A, respectively, and the fractionation patterns were compared. Figure 4A and B illustrates representative fractionation patterns of AtTOM1–GFP and NtTOM1, respectively. The anti-GFP antibody detected bands migrating around a position corresponding to a molecular mass of 43 kDa, which was smaller than the expected value (∼50 kDa). These bands were also detected by anti-AtTOM1 antiserum (data not shown). Both AtTOM1–GFP and NtTOM1 were detected as double bands, suggesting that TOM1 may undergo modifications. The fractionation pattern of AtTOM1–GFP was similar to that of NtTOM1. Both proteins predominantly floated to the top fraction of the gradient (fraction 1, referred to as Fraction T), while they were also detected in fractions 2–15 with relatively strong signals in the middle part of the gradient (fractions 9–11, referred to as Fraction M). The bands were almost undetectable in the bottom part where the cell lysates were originally loaded (fractions 16–18, referred to as Fraction L). Fraction L contains most of the cytoplasmic non-membrane-bound proteins (data not shown), indicating that TOM1 is exclusively a membrane-bound protein. Figure 4.Equilibrium iodixanol density-gradient analysis of the TOM proteins in BY-2 cells. Lysates from non-transgenic BY-2 cells (B, D, E and G) and transgenic BY-2 cells expressing (A) AtTOM1–GFP, (C) GFP–AtTOM2A, (F) GFP–VM23, (H) mGFP5ER, (I) GmMan1–GFP and (J) GFP–PAQ1 were subjected to density gradient centrifugation. Fractions (1–18, from top to bottom of a gradient) were analyzed by SDS–PAGE and immunoblotting. An anti-GFP antibody was used to detect the GFP-fused proteins. NtTOM1 (B), NtTOM2A (D), V-PPase (E) and Sec61p (G) were detected with the corresponding antibodies. The top (fraction 1), middle (fractions 9–11) and sample-loaded (fractions 16–18) parts are referred to as Fraction T, Fraction M and Fraction L, respectively, as shown below the panels. The positions of molecular mass markers (kDa) are indicated on the right. Download figure Download PowerPoint The fractionation patterns of GFP–AtTOM2A and NtTOM2A are shown in Figure 4C and D, respectively. Both proteins showed strong signals in Fraction T. They were weakly detected in all other membrane fractions (fractions 2–15) when overexposed (data not shown) but were absent in Fraction L, again indicating that they were completely membrane-bound. In GFP–AtTOM2A, the size of the fusion protein detected by the anti-GFP antibody (∼34 kDa) was smaller than the expected value (∼50 kDa). Nevertheless, the fractionation pattern resembled that of NtTOM2A, indicating that cleavage of GFP–AtTOM2A, if it occurred, did not affect its localization. Similar distribution profiles between AtTOM1–GFP and NtTOM1 and between GFP–AtTOM2A and NtTOM2A suggest that tagging with the GFP reporter did not alter the subcellular localization of AtTOM1 and AtTOM2A. In addition, these results indicate that TOM1 and TOM2A are mainly associated with the membranes that floated to the top part of the iodixanol gradients, while TOM1 is also localized to the membranes contained in Fraction M. Next, fractionation patterns of marker proteins for the tonoplasts, the ER, and the Golgi and plasma membranes were analyzed. As illustrated in Figure 4E and F, two typical tonoplast proteins, H+-translocating inorganic pyrophosphatase (V-PPase) and GFP-tagged VM23 (see Figure 2C), were mainly detected in Fraction T. Thus, both TOM1 and TOM2A are predominantly distributed to the tonoplast-rich fractions. On the other hand, an ER membrane protein Sec61p was found to be fractionated mainly to Fraction M (Figure 4G), although it was faintly detected in Fraction T when overexposed (data not shown). Similarly, the ER marker protein mGFP5ER (see Figure 2F) was also predominantly fractionated into Fraction M (Figure 4H). This lumenal soluble protein was also detected in Fraction L, probably due to a leak upon disruption of the ER membranes. The fractionation pattern of the Golgi marker GmMan1–GFP (see Figure 2D) is shown in Figure 4I. The anti-GFP antibody detected two bands around the position of the expected molecular mass, but both bands showed a similar fractionation profile. They were predominantly found in Fraction M, although they were also weakly detected in Fraction T. The overall fractionation pattern of the Golgi membranes was found to be similar to that of the ER membranes. The plasma membrane marker GFP–PAQ1 (see Figure 2E) was distributed in a wide range of the membrane fractions and showed relatively strong signals in Fractions T and M (Figure 4J). Taken together, Fraction T, where both TOM1 and TOM2A were mainly detected, was abundant in the tonoplasts, while Fraction M, in which TOM1 but not TOM2A was detected at a significant level, contained membranes from several different organelles. To rule out the possibility that the buoyant densities of intracellular membranes in BY-2 cells differ from those in A.thaliana cells, we examined the fractionation patterns of AtTOM1, AtTOM2A, V-PPase and Sec61p using A.thaliana Col-0 suspension-cultured cells. The fractionation patterns of these proteins were identical with their respective patterns obtained using BY-2 cells (data not shown). All these findings suggest that both NtTOM1 (AtTOM1) and NtTOM2A (AtTOM2A) are localized predominantly to the tonoplasts. This is consistent with the confocal images illustrating the subcellular localization of AtTOM1–GFP and GFP–AtTOM2A (see Figure 2A and B). The TOM1-bearing membrane(s) in Fraction M remains to be determined. Co-fractionation of NtTOM proteins and tobamovirus-encoded replication proteins Previously, we have detected the interaction between membrane-associated AtTOM1 and the helicase domain polypeptides of the 130K/180K proteins of two tobamoviruses, TMV-Cg and TMV-L, using the yeast Sos recruitment system (Yamanaka et al., 2000, 2002). Recently, we have found that AtTOM2A interacts with AtTOM1 in yeast split ubiquitin system (Tsujimoto et al., 2003). Based on these observations, we have proposed that the TOM proteins and tobamovirus 130K/180K proteins are integral parts of the tobamoviral RNA replication complex on membranes. To test this possibility, we investigated subcellular distribution of the 130K/180K proteins of TMV-L and compared their localization with that of the TOM proteins. Protoplasts isolated from BY-2 cells were inoculated with TMV-L RNA. Cells at 6 h post-inoculation (h.p.i.) were disrupted and subjected to iodixanol gradient flotation analysis. The antibody against the helicase domain polypeptide of TMV-L was used to detect both 130K and 180K proteins. In mock-inoculated protoplasts (Figure 5A), Sec61p, V-PPase, NtTOM1 and NtTOM2A showed similar fractionation patterns to those described for BY-2 cells (see Figure 4). In TMV-L-inoculated protoplasts, two different types of fractionation patterns were obtained. Representative patterns of four out of seven independent inoculations are shown in Figure 5B ('Infect 1'), while those of the other three inoculations are shown in Figure 5C ('Infect 2'). Figure 5.Equilibrium iodixanol density-gradient analysis of the 130K/180K proteins and the viral RdRp activity of TMV-L-inoculated BY-2 protoplasts. Lysates from mock- or TMV-L-inoculated protoplasts harvested at 6 h.p.i. were subjected to density-gradient centrifugation. Fractions were collected and analyzed by SDS–PAGE and immunoblotting. (A) Immunoblot analysis of Sec61p, V-PPase and the TOM proteins in mock-inoculated protoplasts. (B and C) Immunoblot analysis of Sec61p, V-PPase, TOM proteins, and the 180K and 130K replication proteins in TMV-L-inoculated protoplasts (see text for definition of 'Infect 1' and 'Infect 2'). The RF RNA synthesized in the RdRp assay of each fraction is shown in the bottom panel of (B) and (C). The band intensity for NtTOM1, the 130K protein and the RF RNA was quantitated and represented graphically. Download figure Download PowerPoint In 'Infect 1', the patterns of Sec61p, V-PPase and the TOM proteins were similar to those in mock-inoculated protoplasts. While most of the 130K/180K proteins of TMV-L remained in Fraction L, they also floated up to the membrane fractions (fractions 1–15). Among these fractions, strong signals of the 130K/180K proteins were detected in Fractions T and M, resembling the fractionation pattern of NtTOM1. In 'Infect 2', distinctive fractionation patterns of NtTOM1, NtTOM2A, V-PPase and the 130K/180K proteins were observed (Figure 5C). In addition to the signals observed in 'Infect 1', strong signals for NtTOM1, NtTOM2A and V-PPase, but not Sec61p, were detected in fractions 4 and 5. Since these proteins were not detected, or detected at only a very low level, in the corresponding fractions of mock-inoculated protoplasts, it appeared that the buoyant density of part of the tonoplasts was altered upon infection. Remarkably, relatively large amounts of the 130K/180K proteins were also detected in fractions 4 and 5, indicating that the 130K/180K proteins are tethered to the tonoplast-derived membranes found in these fractions. Subcellular distribution of RNA-dependent RNA polymerase activity We found that the membrane-associated 130K/180K proteins of TMV-L were abundant in Fractions T and M. In addition, large amounts of the 130K/180K proteins also existed in Fraction L, where non-membrane-bound proteins remained. To investigate whether each fraction contained the functional TMV-L replication complex to synthesize the viral RNA, the fractions shown in Figure 5B ('Infect 1') and C ('Infect 2') were subjected to an RdRp assay to detect the incorporation of ribonucleotides into the double-stranded replicative form (RF) RNA of TMV-L. The bottom panels (marked 'RdRp') of Figure 5B and C show the 32P-labeled RF RNA produced in each fraction. No RF RNA bands were detected in mock-inoculated protoplast samples (data not shown), indicating that the bands were TMV-L infection-specific. In both 'Infect 1' and 'Infect 2', the viral RdRp activity (represented by the amount of [32P]RF RNA) was mainly present in Fractions T and M. Furthermore, fractions 4 and 5 in 'Infect 2' showed higher RdRp activity than those in 'Infect 1' (Figure 5B and C). The RdRp activity was not detected in Fraction L in either case despite the abundance of the 130K/180K proteins. The quantification of the signal intensity of the RF RNA and the protein bands clearly demonstrated that the peaks for the viral RdRp activity, NtTOM1 and the membrane-associated 130K replication protein were located in the same fractions (see the quantification graphs in Figure 5B and C). These observations suggest that the active tobamovirus replication complex is localized on the TOM1-bearing membranes. Discussion AtTOM1 and AtTOM2A, encoding putative integral membrane proteins, are required for efficient multiplication of tobamoviruses (Yamanaka et al., 2000; Tsujimoto et al., 2003). In this study, we performed confocal microscopic analyses of the GFP-tagged TOM proteins and subcellular fractionation analyses of the TOM proteins to investigate the subcellular localization of these host factors and their relevance to the localization of the tobamovirus 130K/180K proteins and the viral RdRp activity. The combined results demonstrated that TOM1 and TOM2A were pre dominantly targeted to the vacuolar membranes, although TOM1 was also localized on other uncharacterized membranes (Figure 4A and B, Fraction M). Importantly, the subcellular fractionation pattern of the viral RdRp activity coincided well with that of both NtTOM1 and the membrane-bound 130K/180K proteins. These findings support the hypothesis that the replication complex of tobamoviruses is tethered to the membranes in association with TOM1. TOM proteins are localized to the tonoplasts The GFP-tagged AtTOM proteins were localized to the tonoplast-like structures in tobacco BY-2 cells (Figure 2), and probably in leaf epidermal cells of A.thaliana, N.tabacum and N.benthamiana (Fig
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