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Molecular and Cellular Biology, May 2004, p. 3815-3826, Vol. 24, No. 9
0270-7306/04/$08.00+0     DOI: 10.1128/MCB.24.9.3815-3826.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

The GTPase-Activating Enzyme Gyp1p Is Required for Recycling of Internalized Membrane Material by Inactivation of the Rab/Ypt GTPase Ypt1p

Céline Lafourcade,¹ Jean-Marc Galan,² Yvonne Gloor,^1, Rosine Haguenauer-Tsapis,² and Matthias Peter^1*

Swiss Federal Institute of Technology Zurich (ETH), Institute of Biochemistry, ETH Hoenggerberg, 8093 Zurich, Switzerland,¹ Institut Jacques Monod-CNRS, 75251 Paris Cedex 05, France²

Received 8 September 2003/ Returned for modification 20 October 2003/ Accepted 25 January 2004

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion Appendix References

 
Rab/Ypt GTPases are key regulators of membrane trafficking and together with SNARE proteins mediate selective fusion of vesicles with target compartments. A family of GTPase-activating enzymes (GAPs) specific for Rab/Ypt GTPases has been discovered, but little is known about their function and substrate specificity in vivo. Here we show that the GAP activity of Gyp1p, a yeast member of this family, is specifically required for recycling of the SNARE Snc1p and the membrane dye FM4-64, implying that inactivation of a Rab/Ypt GTPase may be necessary for recycling of membrane material. Interestingly, recycling of GFP-Snc1p in gyp1 cells is partially restored by reducing the activity of Ypt1p. Moreover, GFP-Snc1p accumulated intracellularly in wild-type cells expressing a GTP-locked, mutant form of Ypt1p (Ypt1p-Q67L), suggesting that GTP hydrolysis of Ypt1p is essential for recycling. Ypt6p is known to be required for the fusion of recycling vesicles to the late Golgi compartment. Interestingly, the deletions of GYP1 and YPT6 were synthetic lethal, raising the possibility that at least two distinct pathways are involved in recycling of membrane material.

	INTRODUCTION

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Internalized proteins travel through two morphologically and biochemically distinct organelles called early and late endosomes. After arrival at the endosome, membrane proteins and lipids (solutes) are either directed to the lysosomal or vacuolar compartment where they are degraded or returned to the plasma membrane as in the case of recycling receptors and bulk membrane constituents. Recycling of many signaling receptors back to the plasma membrane allows multiple rounds of ligand binding and internalization. In the yeast Saccharomyces cerevisiae, several endocytosed proteins have been shown to undergo recycling. For example, pheromone-induced internalization of Ste3p results in its recycling back to the plasma membrane (8, 9), while the chitin synthase Chs3p translocates between sites of chitin deposition on the cell surface and an internal structure called the chitosome (42, 47). Moreover, recycling of the exocytic SNARE Snc1p, which is involved in fusion of Golgi compartment-derived secretory vesicles with the plasma membrane, allows reutilization of Snc1p for several round of secretion (22). Despite a detailed morphological analysis of cargo transport through endosomal compartments, the machinery and molecular mechanisms underlying plasma membrane protein sorting and recycling are still largely unknown.

Correct targeting of vesicles to the acceptor compartment by SNAREs and Rab/Ypt GTPases is of fundamental importance to ensure specificity among trafficking pathways (33). Available evidence suggest that Rabs and their recruited effectors function in multiple steps including cargo selection, vesicle budding, movement, docking, and fusion (32, 33, 46). The yeast genome encodes 11 Ypt GTPases compared to more than 60 in mammalian cells, and they are thought to regulate distinct trafficking steps. Rab/Ypt GTPases exist in an active GTP- and an inactive GDP-bound conformation, and this cycle is facilitated by guanine-nucleotide exchange factors that stimulate both GDP loss and GTP uptake as well as GTPase-activating enzymes (GAPs) that catalyze GTP hydrolysis. A family of Rab-specific GAPs termed GYPs (GAP for Ypts) was discovered in yeast, but homologues also exist in other species (1, 12, 37). Most GAPs of the GYP family display broad and overlapping substrate specificity when assayed in vitro. For example, Gyp1p increases GTP hydrolysis of Ypt1p, Sec4p, Ypt51p, and Ypt7p (1, 12, 37). Moreover, Gyp1p, Gyp5p and Gyp8p are all able to inactivate Ypt1p GTP in vitro (1, 11). The substrate specificity of Gyps is less clear in vivo. Thermosensitive growth defect of gyp1 cells is rescued by partial loss of function of YPT1, suggesting that Gyp1p functions as a GAP in early secretion for Ypt1p in vivo (13). Recently, it was shown that the double mutant gyp3/msb3 gyp4/msb4 exhibits secretion defects, most likely because Gyp3p and Gyp4p regulate the Ypt Sec4p (17). However, as yeast cells with deletions of any single GYP-GAPs are viable and exhibit only minor characterized trafficking defects, it is thought that the GYPs are functionally redundant in vivo (11) or, alternatively, that GTP hydrolysis may not be required for Rab/Ypt function (30).

In yeast, the Rab family GTPase Ypt6p and its heterodimeric guanine-nucleotide exchange factor Ric1p/Rgp1p appears to play key roles for recycling of Snc1p (34). Ypt6p may be regulated by the GAP Gyp2p (21) and a complex containing Rcy1p and Skp1p (16, 45). Ypt6p mediates fusion of endosomal vesicles with the Golgi compartment by recruiting a multisubunit tethering factor termed VFT (Vps Fifty Three)/GARP complex (34-36). Interestingly, the VFT subunit Vps51p is able to link this VFT complex to the SNARE Tlg1p (10, 36), which is required for recycling of Chs3p and Snc1p (20, 22). These results led those authors to conclude that the recruited VFT tethering factors promote SNARE assembly, and thereby directly link the tethering and fusion events. Finally, retrieval of Snc1p from early endosomes has recently been shown to be dependent on three sorting nexins Snx4p, Snx41p, and Snx42p (19).

In this study, we investigated the role of the known Gyp family members for a potential function in recycling pathways. Interestingly, we found that gyp1 cells are defective for recycling of GFP-Snc1p and FM4-64, most likely because they accumulate activated Ypt1p. Our results thus suggest that hydrolysis of Ypt1p may be important for efficient recycling of membrane material.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion Appendix References

 
Strais constructions and genetic manipulations. Yeast strains are described in Table 1. Standard yeast growth conditions and genetic manipulations were used (18). Strains with deletions of GYP1 were constructed as described (24).

For microscopy, cells were grown at 30°C to early log phase and visualized on a Zeiss Axiophot fluorescence microscope with a Photometrics charge-coupled device camera. GFP-tagged proteins were visualized using a Chroma GFPII filter (excitation wavelength, 440 to 470 nm). For quantification, at least 200 cells were counted. Where indicated, the actin polymerization inhibitor Latrunculin-A (LAT-A) (200 µM final concentration in dimethyl sulfoxide [DMSO]) or the solvent DMSO was added 10 min before crude extract preparation. Aliquots of the culture were treated with rhodamine-phalloidin (Molecular Probes) to check the disruption of actin cytoskeleton upon LAT-A addition. For FM4-64 localization experiments, yeast cells expressing or not expressing GFP-Snc1p were allowed to internalize FM4-64 for 12 min at 24°C and were then washed three times with ice-cold synthetic dextrose (SD) medium (18). The cells were then incubated for 0 to 10 min in SD medium at 30°C, and internalized FM4-64 was visualized using a rhodamine filter (Zeiss FS1). Vacuolar staining was obtained by incubating cells grown to early log phase with 0.1% CMAC (Molecular Probes) at 30°C for 1 h and the cells were then visualized with a DAPI (4',6'-diamidino-2-phenylindole) filter (Zeiss FS20).

Uracil uptake assay and Fur4p degradation. The endocytosis and subsequent vacuolar degradation of Fur4p was measured as described previously (14). At time zero exponentially growing cells transformed with Yep352fF (end-Fur4 on a 2µm/URA3 plasmid) were treated with cycloheximide (CX) (final concentration, 50 µg/ml). The uracil uptake was measured, and crude extracts were prepared each 30 min after addition of CX. Uracil uptake was measured as previously described. Yeast culture (1 ml) were incubated with 5 µM [¹⁴C]uracil (Amersham) for 20 s at 30°C and quickly filtered through Whatman GF/C filters. Filters were washed twice with ice-cold water and then counted for radioactivity. We used a polyclonal antibody raised against the last 10 residues of Fur4p to detect the permease by western immunoblotting.

Determination of Vps10p half-life. Cultures were grown to early log phase in rich medium at 30°C, at which time CX (Sigma) was added to a final concentration of 50 µg/ml. Aliquots were collected at the times indicated, and protein levels were analyzed by immunoblotting with specific antibodies.

Detection of secreted CPY. For the detection of secreted CPY, 10 µl of exponentially growing cells were spotted onto yeast-peptone-dextrose (YPD) medium and grown for 2 days in contact with a 0.45-mm-pore-size nitrocellulose membrane. The filter was removed and washed with distilled water, and CPY was immunologically detected as previously described (31).

FM4-64 recycling assays. FM4-64 recycling assays were performed as described previously (45). Briefly, yeast cells were allowed to internalize FM4-64 for 12 min at 24°C, and washed three times with ice-cold SD medium. After the last wash, the cells are resuspended in 10 µl of SD medium and kept on ice. Prewarmed SD medium at 30°C was added to the cells and fluorescence was recorded during 600 s.

SGA analysis of GYP1. Synthetic genetic array (SGA) analysis was performed with gyp1 cells essentially as described by Tong et al. (39) using a Beckman Biomek FX robot. All identified mutants were confirmed by random sporulation or tetrad analysis (39). Representation of the interactors was performed with the Osprey program (7). Classification of the interactors and additional interactions between them were added based on data from GRID (6) and were manually refined with published data.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion Appendix References

 
The GAP Gyp1p is required for efficient recycling of the SNARE Snc1p and FM4-64. The localization and phosphorylation state of GFP-Snc1p provide a convenient marker of recycling. In wild-type cells GFP-Snc1p is mostly localized at the plasma membrane in a phosphorylated state, while it accumulates in internal structures in an underphosphorylated state in cells deficient for recycling (16, 22). Recycling can also be quantified by measuring the secretion of previously internalized fluorescent dye FM4-64 (45). We used these two assays to investigate possible functions of the known Rab/Ypt-GAPs for recycling of membrane material. Interestingly, GFP-Snc1p was predominantly intracellular and accumulated in its underphosphorylated form in gyp1 cells (Fig. 1A), while it was found mostly located at the plasma membrane in wild-type cells and strains with deletions of GYP2 to GYP8 (Fig. 1B and data not shown). In addition, gyp1 cells also exhibited a recycling defect of the fluorescent dye FM4-64 (Fig. 1C), suggesting a general role of Gyp1p in recycling. While in wild-type cells internalized FM4-64 was rapidly recycled, it accumulated in punctate structures in gyp1 cells (Fig. 1C, right panels), which could correspond to either endosomes or fragmented vacuoles (see below). After longer exposure, the remaining FM4-64 prominently stained the vacuolar membrane of wild-type cells (inset). Interestingly, GFP-Snc1p colocalized at least partially with FM4-64 at the beginning of the time course (Fig. 1D), suggesting that GFP-Snc1p is likely to accumulate in endosomes in gyp1 cells.

View larger version (29K): [in this window] [in a new window]   FIG. 1. Gyp1p is required for recycling of the SNARE Snc1p and FM4-64. (A) Wild-type (BY4741) and gyp1 (YCL248) cells transformed with GFP-Snc1p were grown at 30°C in selective SD medium to early log phase and analyzed by fluorescence microscopy (left panels) and immunoblotting with GFP-antibodies (right panel). Note that GFP-Snc1p is intracellular and underphosphorylated in gyp1 cells, characteristic of a recycling defect. (B) The phosphorylation state of GFP-Snc1p was examined by immunoblotting with GFP-antibodies in the indicated strains grown at 30°C to early log phase in selective SD medium. The following strains were analyzed: gyp1 (YCL248), gyp2 (YCL246), msb3/gyp3 (YCL250), msb4/gyp4 (YCL252), gyp5 (YCL281), gyp6 (YCL254), gyp7 (YCL282), and gyp8 (YCL283). (C) Wild-type (BY4741) and gyp1 (YCL248) cells were analyzed for their ability to recycle the membrane dye FM4-64 as described in Materials and Methods. Fluorescence microscopy pictures were taken at the beginning and the end of the time course (right panels). The cell shown in the inset was exposed longer to visualize staining of FM4-64 at the vacuolar membrane. (D) gyp1 cells expressing GFP-Snc1p were incubated with FM4-64 for 12 min, washed and analyzed by fluorescence microscopy. Note that GFP-Snc1p partially colocalizes with structures stained by FM4-64.

View larger version (25K): [in this window] [in a new window]   FIG. 2. The GAP activity of Gyp1p is required for its recycling function. gyp1 (YCL248) cells expressing GFP-Snc1p (pJMG118) were transformed with plasmids encoding either wild-type or Gyp1p mutant proteins. The tested mutants are schematically indicated on the left. The cells were grown at 30°C in selective SD medium to early log phase, and analyzed by GFP microscopy. The ability of wild-type and the indicated Gyp1p-mutants to restore recycling of GFP-Snc1p was compared to their previously reported growth at 37°C and GAP activity in vitro (2, 13). ND, not determined. Symbols: +, wild-type activity; –, no activity.

Endocytosis and secretion are not affected in gyp1 cells.

View larger version (49K): [in this window] [in a new window]   FIG. 3. Secretion and endocytosis are not altered in gyp1 cells. (A) Wild-type (BY4741) and gyp1 (YCL248) cells transformed with a plasmid expressing internalization-defective GFP-Snc1p-pem (pJMG122) were grown at 30°C in selective SD medium to early log phase and analyzed by GFP microscopy. (B) The subcellular localization of GFP-Snc1p (pJMG118) was analyzed in wild-type (BY4741) and gyp1 (YCL248) cells, treated for 10 min with 200 µM LAT-A (+LAT-A) or DMSO (+SOLV). Note that GFP-Snc1p relocated to the plasma membrane in gyp1 cells treated with LAT-A. (C) Wild-type (BY4741) and gyp1 (YCL248) cells transformed with a multicopy plasmid encoding Fur4p under its own promoter (Yep352fF) were grown to early log phase. CX was added to a final concentration of 50 µg/ml, and the uracil uptake (left graph) and Fur4p degradation (right panel) were followed over time as described in Materials and Methods. For a loading control we used the marked unspecific band (*). (D) The morphology of the vacuole was examined by fluorescence microscopy in wild-type (BY4741) and gyp1 (YCL248) cells incubated with CMAC for 1 h. The corresponding DIC images are shown below.

gyp1 cells are impaired in retrograde traffic from endosomes to the Golgi compartment. To test whether Gyp1p may be involved in trafficking to the Golgi compartment, we analyzed the sorting of the vacuolar CPY, which undergoes N glycosylation in the Golgi compartment before being transported to the vacuole. In cells defective for anterograde Golgi compartment-to-endosome or retrograde endosome-to-Golgi compartment trafficking, part of CPY is secreted in a nonmaturated form. Consistent with previous results (5, 13), CPY was secreted in gyp1 and ypt6 cells, although the effect was less pronounced compared to the retromer mutant vps5 (Fig. 4A). This observation could be explained by a defect in retrograde transport from the prevacuolar compartment (PVC) to the Golgi compartment, which leads to a mislocalization of Vps10p, the receptor of CPY. To test this possibility, we followed degradation of Vps10p after the addition of the translation inhibitor CX to the culture medium. As shown in Fig. 4B, the half-life of Vps10p was significantly reduced in gyp1, ypt6 and vps5 cells. Quantification of these results revealed that the half-life of Vps10p was less than two hours (lower graph) in these mutant cells, while Vps10p remained almost stable over the entire time course in wild-type cells. Moreover, the cleaved form of Vps10p slightly accumulated in gyp1, ypt6, and vps5 cells compared to wild-type cells (expressed as a percentage of the total amount of Vps10p), a characteristic feature for increased vacuolar targeting (28). Based on these results, we conclude that the trafficking route from the Golgi compartment to the PVC and the retrograde transport from the PVC to the Golgi compartment are partially impaired in gyp1 and ypt6 cells.

View larger version (30K): [in this window] [in a new window]   FIG. 4. gyp1 cells are impaired in endosome-to-Golgi compartment retrograde traffic. (A) Wild-type (BY4741) and gyp1 (YCL248) cells were spotted on a nitrocellulose membrane on YPD plates (105 cells/spot). After 48 h at 30°C, secreted CPY was detected with a monoclonal CPY antibody as described in Materials and Methods. (B) The half-life of Vps10p was determined by CX (CHX) chase in wild-type (BY4741), gyp1 (YCL248), vps5 (YCL267), and ypt6 (YCL154) cells. Cells were grown in YPD medium to mid-log phase, and CX was added (time zero) to a final concentration of 50 µg/ml. Proteins extracts were prepared at the indicated times after CX addition and analyzed by SDS-PAGE and immunoblotting with a monoclonal antibody directed against Vps10p. The arrow marks the position of full-length Vps10p, while the arrowhead points to the truncated form of Vps10p, which is cleaved in the vacuole. The bands were quantified, and the level of the lower band was expressed as a percentage of the total Vps10p signal. The decrease of full-length Vps10p was quantified and plotted as the ratio of residual intensity compared to the initial one expressed in percentage over time (in hours).

The ypt1-2 mutant allele partially rescues the recycling defect of gyp1 cells.

View larger version (52K): [in this window] [in a new window]   FIG. 5. The ypt1-2 mutant allele partially rescues the recycling defect of gyp1 cells. (A) gyp1 (YCL248), gyp1 ypt7 (YCL222), gyp1 ypt10 (YCL223), gyp1 ypt11 (YCL230), gyp1 ypt51 (YCL224), gyp1 ypt52 (YCL225), gyp1 ypt53 (YCL226), and wild-type (BY4741) cells were transformed with a plasmid expressing GFP-Snc1p (pJMG118), grown in selective SD medium to early log phase, and the phosphorylation state of GFP-Snc1p was examined by Western blot using an antibody raised against GFP. Note that GFP-Snc1p is hyperphosphorylated only in wild-type cells. Pgk1p was used as a loading control. (B) Wild-type (YCL192), ypt1-2 (YCL193), gyp1 ypt1-2 (YCL209), and gyp1 (YCL210) cells expressing GFP-Snc1p (pJMG118), were analyzed by GFP-fluorescence microscopy and by Western blotting. For each strains, the cells were quantified by microscopy and expressed as percentage of the total number of cells according to their complete (+), partial (±), or absent (–) GFP-Snc1p recycling. Moreover, the bands obtained by Western blot were quantified, and the level of the upper band was expressed as a percentage of the total GFP-Snc1p signal. Note that the plasma membrane localization of GFP-Snc1p is partially recovered in gyp1 ypt1-2 compared to gyp1 cells.

View larger version (47K): [in this window] [in a new window]   FIG. 6. Ypt1pQ67L expressing cells exhibit a recycling defect. (A and B) The subcellular localization (panel A) and phosphorylation state (panel B) of GFP-Snc1p (pJMG118) and GFP-Snc1p-pem (pJMG122) was analyzed in wild-type (YCL262) and ypt1Q67L (YCL263) cells, grown in selective SD medium to early log phase. (C) Wild-type (YCL262) and ypt1Q67L (YCL263) cells were analyzed for their ability to recycle the membrane dye FM4-64. (D) Wild-type (YCL262) and ypt1Q67L (YCL263) cells were grown on YPD plates (105 cells by spot) for 48 h in contact with nitrocellulose membrane. Secreted CPY was detected on the membrane by probing with a monoclonal antibody directed against CPY.

View larger version (32K): [in this window] [in a new window]   FIG. 7. Synthetic lethal interactions with GYP1. (A) Dissection of tetrads from heterozygous diploids revealed synthetic-lethal interactions between GYP1 and YPT6 or RIC1 deletions. The genotype of the germinating spores was determined by plating them on media containing Nourseothricin (Nat) or Geneticin (G418). (B) Genetic interaction network of the synthetic-lethal interactions identified by the SGA analysis. The genes that were identified as synthetic lethal with GYP1 are represented as nodes. Analysis and representation of the interactors was performed with the use of the Osprey program.

View larger version (57K): [in this window] [in a new window]   FIG. 8. GFP-Tlg1p and GFP-Tlg2p are correctly localized in gyp1 cells. The subcellular localization of GFP-Tlg1p and GFP-Tlg2p was analyzed by fluorescence microscopy in wild-type (BY4741), gyp1 (YCL248), and gos1 (YCL316) cells. Note the punctate staining of Tlg1p and Tlg2p in gyp1 and wild-type cells compared to the hazy staining observed in gos1 cells.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion Appendix References

The role of Gyps for trafficking. Surprisingly, the major trafficking routes are normal in cells lacking any single GAP of the Gyp family. The absence of dramatic trafficking phenotypes has been explained by the fact that the Gyps function in a redundant manner. Indeed, only cells with deletions of MSB3 and MSB4 exhibit a strong secretion defect, probably because of the accumulation of Sec4p GTP (17). Consistent with overlapping functions, Gyp1p, Gyp5p, and Gyp8p are all able to stimulate GTP hydrolysis of Ypt1p in vitro (11, 12). However, the results presented here demonstrate that the GAP activity of Gyp1p is specifically required for recycling of membrane material in vivo. Moreover, previous findings suggest a specific role of Gyp2p as a negative regulator of Ypt6p (21), indicating that the Gyps may be more specific in vivo than in vitro. Gyp1p localizes predominantly to the Golgi compartment (11, 13), while Gyp5p is cytosolic and Gyp8p localizes to few large structures that do not colocalize with Gyp1p (11). It is thus possible that subcellular compartmentalization of Gyp GAPs may contribute to their substrate specificity in vivo. Given that GAPs of the Gyp family remained highly conserved during evolution (see Fig. A1), it will be interesting to test whether human Gyp1p homologues are also required for recycling.

View larger version (71K): [in this window] [in a new window]   FIG. A1. Sequence alignment of Gyp1p with its closest homologues in other species. Sequence homology between Gyp1p from S. cerevisiae (Sc) and putative orthologs in S. pombe, SPBC530.01 (Sp); C. elegans, F32B6.8 (Ce); mouse, MGC61359 (Mm); and human, C22orf4 (Hs). Sequences were aligned with ClustalW and displayed using Boxshade. Residues are shaded if identical (black) or conserved (grey) in at least three proteins. The bracket indicates the GAP domain; the catalytic arginine (arginine finger) is also marked (R*).

What is the function of Ypt1p during recycling? In addition to the well established role of Ypt1p for trafficking of secretory vesicles from the ER to the Golgi compartment (25, 33), and a possible function at a late step during secretion (26), our results implicate Ypt1p in recycling of membrane proteins. At least two possibilities may account for these observations. First, it remains possible that deletion of GYP1 or expression of GTP-locked Ypt1p-Q67L may indirectly disturb recycling by delocalizing essential recycling factors. For example, gos1 cells fail to recycle GFP-Snc1p because the SNAREs Tlg1p/Tlg2p are mislocalized from the late Golgi compartment to transport vesicles (35). Although Tlg1p and Tlg2p were correctly localized to the Golgi compartment in gyp1 cells (Fig. 8), we cannot exclude that other recycling components may be mislocalized.

Alternatively, Ypt1p may function in the Golgi compartment to promote fusion of endosomal vesicles. Interestingly, the COG or Sec34p/35p complex has been described as an effector of Ypt1p (38). This complex exerts several functions together with Ypt1p, and has been proposed to function in ER sorting and as a tethering factor at the Golgi compartment for both anterograde transport from ER-to-Golgi compartment and retrograde intra-Golgi compartment transport (25, 38, 43, 44). Moreover, the COG complex could be involved in tethering endosomal vesicles to the Golgi compartment, since dor1/cog8 cells are defective for recycling of GFP-Snc1p (43). We propose that Gyp1p-catalyzed GTP hydrolysis of Ypt1p is essential for tethering endosome-derived recycling vesicles to the Golgi compartment.

Yeast cells may use two distinct recycling routes. In mammalian cells, several pathways of recycling to the plasma membrane have been described, including a direct pathway from early endosomes and a slower route through early and recycling endosomes (46). In yeast, the only well characterized recycling route is the one followed by the SNARE Snc1p which travels from early endosomes to the Golgi compartment and back to the plasma membrane (22). In this pathway, activated Ypt6p recruits the VFT tethering complex, which in turn interacts with the SNAREs Tlg1p and Tlg2p, thereby promoting fusion of vesicles derived from early endosomes to the Golgi compartment (34-36). Cells with deletions of YPT6 or its regulators RIC1/RGP1 exhibit a recycling defect of GFP-Snc1p (34), and accumulate vesicles thought to be on their way to the Golgi compartment (41). However, ypt6, ric1, or rgp1 cells are viable, implying that either recycling is not essential for cell viability, or that recycling is an essential process but ensured by at least two redundant pathways. Interestingly, we found that GYP1 deletion is synthetic-lethal with YPT6, RIC1, ARL1 and ARL3 deletions. Arl1p functions in the Golgi compartment and was previously shown to interact with the VFT complex through Vps53p (27). In addition to known components of the Ypt6p pathway, gyp1 was also found to be synthetic-lethal with deletions of genes encoding multiple components of the COG complex including COG5, -6, -7, and -8, and other proteins previously implicated in trafficking (Fig. 7B). Similarly, ric1 has recently been found to be synthetic-lethal with cog8 (43). Interestingly, these four COG components are not crucial for the association of the core proteins, suggesting that these four subunits may be peripheral components of the COG complex (29). One hypothesis to explain their synthetic lethality with gyp1 would be that the remaining COG complex is still partially functional, but requires correct regulation of Ypt1p to perform its role during recycling. Although the molecular basis of the observed synthetic-lethal interactions are not clear, it is tempting to speculate that GFP-Snc1p can recycle by two distinct routes: first, from early endosomes using the Ypt6p-VFT pathway for fusion of the vesicles with the late Golgi compartment, and second, using the Ypt1p-pathway for fusion of endosomal vesicles with the cis-Golgi compartment. Consistent with this hypothesis, it was previously shown that overexpression of Ypt1p is able to suppress the growth defect of temperature-sensitive ypt6 mutants (23). Based on the observations reported here, it may be worthwhile to analyze recycling and other trafficking pathways in the mutants that are synthetic-lethal with GYP1, which previously have not been functionally connected to trafficking (Fig. 7B). Taken together, our results suggest that recycling of membrane proteins may be an essential process regulated by at least two distinct trafficking routes.

	Appendix

Top Abstract Introduction Materials and Methods Results Discussion Appendix References

 
Sequence comparisons between various GAPs of the GYP family revealed that Gyp1p is conserved among species (Fig. A1).

	ACKNOWLEDGMENTS

 
We thank P. Novick, N. Segev, H. Pelham, H. Riezman, and S. Alberts for plasmids and yeast strains. We are grateful to Monika Gersbach for expert technical assistance, C. Boone's laboratory for help in the synthetic-lethal analysis, Nicolas Pagé for robot expertise, members of the Haguenauer-Tsapis and Peter groups for stimulating discussion, and Marc Sohrmann for critical reading of the manuscript.

J.-M.G. is supported by the CNRS, and work in the M.P. laboratory is supported by the Swiss National Science Foundation, the Functional Genome Center Zurich, and the ETH/Zurich.

	FOOTNOTES

 
* Corresponding author. Mailing address: Swiss Federal Institute of Technology Zurich (ETH), Institute of Biochemistry, ETH Hoenggerberg HPM G 6.2, 8093 Zurich, Switzerland. Phone: 41 1 632-3134. Fax: 41 1 632-1269. E-mail: matthias.peter{at}bc.biol.ethz.ch.

Present address: Max Planck Institute for Molecular Cell Biology and Genetics, Dresden D-01307, Germany.

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Top Abstract Introduction Materials and Methods Results Discussion Appendix References

 
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