H-ras but Not K-ras Traffics to the Plasma Membrane through the Exocytic Pathway

doi:10.1128/MCB.20.7.2475-2487.2000

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Molecular and Cellular Biology, April 2000, p. 2475-2487, Vol. 20, No. 7
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

H-ras but Not K-ras Traffics to the Plasma Membrane through the Exocytic Pathway

Ann Apolloni,¹ Ian A. Prior,¹ Margaret Lindsay,² Robert G. Parton,² and John F. Hancock¹^,^*

Queensland Cancer Fund Laboratory of Experimental Oncology, Department of Pathology, University of Queensland Medical School,¹ and Centre for Microscopy and Microanalysis, Centre for Molecular and Cellular Biology, Department of Physiology and Pharmacology, University of Queensland,² Brisbane 4069, Australia

Received 12 August 1999/Returned for modification 7 October 1999/Accepted 9 January 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Ras proteins must be localized to the inner surface of the plasma membrane to be biologically active. The motifs that effectRas plasma membrane targeting consist of a C-terminal CAAX motifplus a second signal comprising palmitoylation of adjacent cysteineresidues or the presence of a polybasic domain. In this study,we examined how Ras proteins access the cell surface after processingof the CAAX motif is completed in the endoplasmic reticulum (ER).We show that palmitoylated CAAX proteins, in addition to beinglocalized at the plasma membrane, are found throughout the exocyticpathway and accumulate in the Golgi region when cells are incubatedat 15°C. In contrast, polybasic CAAX proteins are found only atthe cell surface and not in the exocytic pathway. CAAX proteinswhich lack a second signal for plasma membrane targeting accumulatein the ER and Golgi. Brefeldin A (BFA) significantly inhibitsthe plasma membrane accumulation of newly synthesized, palmitoylatedCAAX proteins without inhibiting their palmitoylation. BFA hasno effect on the trafficking of polybasic CAAX proteins. We concludethat H-ras and K-ras traffic to the cell surface through differentroutes and that the polybasic domain is a sorting signal divertingK-Ras out of the classical exocytic pathway proximal to the Golgi.Farnesylated Ras proteins that lack a polybasic domain reach theGolgi but require palmitoylation in order to traffic further tothe cell surface. These data also indicate that a Ras palmitoyltransferaseis present in an early compartment of the exocyticpathway.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Ras proteins operate as molecular switches in diverse signaling pathways that regulate cell growth and differentiation (8,26). However, in order to signal, Ras proteins must be localizedto the inner surface of the plasma membrane (58). This requirementreflects the role that Ras plays in recruiting cytosolic effectorsto the cell surface, where they are, in turn, either activatedor juxtaposed with their own specific target proteins. For example,the serine threonine kinase Raf-1 is recruited to the plasma membraneby activated Ras (53), where it is activated by interactionswith membrane lipids, tyrosine kinases, and possibly phosphatases(32, 37). Similarly, the exchange factor RalGDS is relocalizedto the plasma membrane by activated Ras, positioning it in thesame compartment as the Ral GTPase, which it, in turn, activates(29, 57).

The membrane anchors used by the Ras proteins to attach to the plasma membrane have been well characterized. All Ras isoformsterminate in a CAAX motif that is sequentially farnesylated, AAXproteolyzed, and methylesterified (9, 15, 19). The processedCAAX motif then operates with a second signal in the adjacenthypervariable region to target Ras to the plasma membrane. Thissecond signal is cysteines 181 and 184 in H-ras, and cysteine181 in N-ras, and these cysteines undergo palmitoylation (19).In contrast, the second signal in K-ras comprises multiple lysineresidues (175 to 180), which form a polybasic domain (20). Theseminimal C-terminal motifs, amino acids 181 to 189 in H-ras and175 to 188 in K-ras, are sufficient to target heterologous proteinsto the plasma membrane (2, 18, 19). Indeed, targeting ofRaf-1 and phosphoinositol 3-kinase to the plasma membrane usingthese minimal motifs is sufficient to partially activate theseRas effectors (30, 31, 49).

One consequence of each Ras isoform's having a different membrane anchor is that it may be directed to a different microdomainwithin the plasma membrane. In direct support of this concept,we have recently shown that the function of H-ras, but not K-ras,is critically dependent on cholesterol-rich microdomains, or lipidrafts, within the plasma membrane (46). Lipid rafts have beenproposed as important substructures of the plasma membrane whichcan operate as signaling platforms (48), facilitating interactionsbetween diverse signaling proteins, including tyrosine kinases,Src family kinases, G-protein subunits, and Ras (35, 39).The association of palmitoylated H-ras, but not polybasic K-ras,with such lipid rafts (23, 46) may therefore explain biochemical,and hence biological, differences between the various Ras proteins.For example, Ras isoforms vary in the ability to activate Rafand phosphoinositol 3-kinase (16, 59), probably reflectingthe different concentrations of coactivators of these effectorsin the H-, K-, and N-Ras microdomains. In addition, RasGRF1 selectivelyactivates H-Ras (25) and RasGRP1 activates H-, N-, and K-raswith various potencies (52), a likely consequence of differentialcolocalization of these Ras exchange factors with their targetRas isoforms at the plasma membrane. In turn, such biochemicaldifferences can be invoked to rationalize the differential activationof specific Ras isoforms in human tumors (5) and the selectiverequirement for K-ras, but not H- or N-ras, function in mouseembryogenesis (24, 56).

Intriguing questions invited by these observations are how Ras proteins access the plasma membrane and, more specifically,how they become localized to their correct microdomains. The firststeps in this process must necessarily involve the enzymes whichmodify the CAAX motif. First, farnesyltransferase, a cytosolicenzyme (44), prenylates newly synthesized Ras, generating afarnesylated CAAX sequence that is the recognition sequence forthe prenylcysteine endoprotease which removes the AAX tripeptide(51). The mammalian protease hRce1 has recently been cloned(40) based on its sequence homology with the yeast RCE1 sequence(6). The protease is membrane associated and proteolyzes geranylgeranylatedand farnesylated CAAX motifs of all Ras, Ras-related, and G- $gamma$ subunits tested (28, 40). Moreover, a knockout of Rce1 inmice is late embryonal stage lethal. Fibroblasts derived fromRce1^/ mice show significant mislocalization of Ras proteins to thecytosol (28), a consequence similar to that of RCE1 disruptionin yeast (6). After cleavage of the AAX tripeptide, the nowC-terminal farnesylated cysteine residue of Ras is methylesterifiedby prenylcysteine carboxymethyltransferase (pcCMT), an endoplasmicreticulum (ER)-resident protein (12). The same pcCMT also methylatesthe C-terminal geranylgeranylated cysteine residues of other Ras-relatedproteins (11, 12). No knockout of pcCMT has been reported,but disruption of the homologous STE14 protein in yeast has relativelyminor effects on RAS function and localization (21, 22).

In the Rab and Rho subfamilies of Ras-related proteins, attachment to the correct cellular membrane involves guanine nucleotidedissociation inhibitors (RhoGDI and RabGDI) which extract thecognate GDP-bound prenylated proteins from membranes into cytosoliccomplexes (13, 34, 55). These soluble complexes allow deliveryof the Ras-related protein to the correct cellular membrane throughthe cytosol. Similarly, Rab escort proteins also move geranylgeranylatedRab from Rab geranylgeranyltransferase onto cell membranes (1).Since no analogous GDI has been identified for Ras, we investigatedin this study whether Ras might access the plasma membrane thougha vesicular trafficking pathway. Moreover, given that H- and K-rasoperate in functionally distinct microdomains, we examined whetherthey also traffic to the plasma membrane via differentroutes.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Plasmids. Expression plasmids for green fluorescent protein (GFP)-tH, GFP-tK, and GFP-6QtK were constructed by ligating EcoRI/SalI cDNAfragments from protein A expression plasmids, p381, pA-K, andpA-6Q, respectively (18, 19), into the cloning site of pEGFP-C1.GFP-tH therefore terminates with the sequence CMSCKCVLS, GFP-tKends with KKKKKKSKTKCVIM, and GFP-6QtK ends with QQQQQQSKTKCVIM.pRS $alpha$ -sialylT, the expression plasmid for G-tagged sialyltransferase,has been described previously (43).

Cell culture and confocal microscopy. BHK cells were cultured at 37°C in Dulbecco modified Eagle medium supplemented with 10% bovine calf serum. Cells were platedonto coverslips at 60% confluence and transfected 4 h later, usingLipofectamine (Life Technologies), with 1.6 µg of expression plasmidpEGFP with or without an expression plasmid for G-tagged sialyltransferase.After overnight incubation, cells were fixed with 4% paraformaldehyde,permeabilized in 0.2% Triton X-100, and blocked with 3% bovineserum albumin. Sialyltransferase was visualized using 1:1,000rabbit anti-G tag serum, and the ER was stained using 1:120 rabbitanti-KDDD antibody (raised against the sequence KDDDKDEL and specificfor protein disulfide isomerase (PDI [kindly provided by S. Fuller,EMBL]). Both primary antibodies were followed by 1:250 CY3-coupledanti-rabbit antibody (Zymed). Coverslips were mounted in mowiol.Where indicated, cells were equilibrated at 15°C with medium supplementedwith 25 mM HEPES and incubated for 2 h with or without cycloheximide(50 µg/ml) at the same temperature. Fluorescence images were takenin a Bio-Rad MRC-600 Zeissmicroscope.

Cells to be incubated in brefeldin A (BFA) were returned to Dulbecco modified Eagle medium containing 10% serum 2 h aftertransfection and supplemented with BFA at 5 µg/ml or ethanol (carrier)at 5 µl/ml and incubated for a further 5 h before fixation. Forpalmitic acid labeling, the medium was supplemented with 5 mMsodium pyruvate plus [³H]palmitic acid at 0.25 mCi/ml and cells were incubated for only3 h prior to harvesting to minimize breakdown of the label. Lysateswere prepared in ND buffer (50 mM Tris Cl [pH 7.6], 150 mM NaCl,1% Nonidet P-40, 0.5% deoxycholate plus protease inhibitors),1 mg of cleared lysate was immunoprecipitated with 4 µg of anti-GFPmonoclonal antiserum (Boehringer Mannheim) coupled to proteinG-agarose. After washing in ND buffer, immunoprecipitates wereresolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresisand fluorographed for 24 h at $-$ 70°C using established protocols(19). Where indicated, taxol treatment (3 µM) was commenced2 h prior to lipofection and continued until cells were fixedor harvested 12 h later. Tubulin was visualized using 1:500 anti- $alpha$ -tubulinserum DM1a (Sigma), followed by 1:400 CY3-coupled anti-mouse serum(Zymed).

Electron microscopy. Transfected BHK cells were fixed in 8% paraformaldehyde in 0.1 M phosphate buffer, pH 7.35, for 1 h at room temperature. Theywere then washed with 0.2 M phosphate buffer, scraped from theculture dish, and pelleted in a Microfuge. The cells were thenresuspended in warm gelatin (10% in phosphate buffer) and repelletedat maximum speed in the Microfuge. After cooling, the gelatin-embeddedcells were infiltrated with polyvinylpyrrolidone-sucrose overnightat 4°C and then processed for frozen sectioning as previouslydescribed (41). Ultrathin frozen sections (60 to 80 nm) werelabeled, stained, and viewed (JEOL 1010; Centre for Microscopyand Microanalysis) in accordance with previously published techniques(41) with rabbit polyclonal antibodies to GFP (kindly providedby David James, University ofQueensland).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

A polybasic domain excludes CAAX proteins from the exocytic pathway. Recent work has shown that the mammalian Ras methyltransferase is localized to the ER (12). Since methylesterification isthe final CAAX modification, this suggests that CAAX processingis completed on the cytoplasmic leaflet of the ER membrane. Toinvestigate how Ras proteins access the plasma membrane from theER, the complete targeting signals of H- and K-ras, comprisingthe C-terminal 9 amino acids of H-ras and the C-terminal 17 aminoacids of K-ras, were cloned onto the C terminus of GFP to giveGFP-tH and GFP-tK, respectively. Extensive previous work has shownthat all of the Ras membrane-targeting signals are contained withinthese C-terminal sequences. We elected to use GFP-tH and GFP-tKto investigate Ras trafficking because GFP is biologically inertand the role of the isolated targeting signals can therefore bestudied without the metabolism and architecture of the cell beingaltered by the presence of overexpressed biologically active Ras.The H- and K-ras motifs were compared because although they sharea CAAX motif, the critical second signals within the motifs, palmitoylationin H-ras and a polybasic domain in K-ras, are strikinglydifferent.

First, we evaluated the extent to which GFP-tH and GFP-tK are prenylated when expressed in BHK cells. This was assessed usingthe Triton X-114 partitioning assay, which has been used extensivelyto monitor the posttranslational processing of many Ras and Ras-relatedproteins (15, 17). Wild-type GFP was found to partition completelyinto the aqueous phase of Triton X-114, indicating that it ishighly hydrophilic (Fig. 1). In contrast, both GFP-tH and GFP-tKpartitioned exclusively into the detergent phase of Triton X-114,indicating that all of the expressed protein is hydrophobic. Wetherefore conclude that GFP-tH and GFP-tK are fully prenylatedwhen expressed in BHK cells.

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FIG. 1. Prenylation of GFP-Ras constructs. BHK cells expressing GFP, GFP-tH, or GFP-tK were lysed in Triton X-114. The lysates, normalized for protein content, were warmed to 37°C, and the detergent (D) and aqueous (Aq) phases were separated by centrifugation exactly as previously described (15, 17). Equal proportions of each fraction were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotted using anti-GFP serum. Wild-type GFP is hydrophilic and partitions exclusively into the aqueous phase, whereas prenylation of the CAAX motifs of GFP-tH and GFP-tK imparts sufficient hydrophobicity to partition the proteins into the detergent phase. Prenylation is complete, since all of the expressed GFP-tH and GFP-tK has shifted into the detergent phase.

Next, we used confocal microscopy to compare the subcellular distributions of GFP-tH and GFP-tK when they are expressed atequivalent levels in BHK cells. Figure 2A to C shows that GFP-tKlocalized exclusively to the plasma membrane with no significantlabeling of intracellular structures. In contrast, while GFP-tHwas also on the plasma membrane, a substantial amount was presenton perinuclear structures (Fig. 2D and E). Although there wereno apparent differences between the two targeted GFPs in overallplasma membrane distribution, membrane ruffles and projectionswere more extensively decorated with GFP-tK than with GFP-tH (Fig.2C and F). Cells were then examined using immunoelectron microscopywith antibodies to the GFP tag. In agreement with the immunofluorescenceanalysis, GFP-tH and GFP-tK were both readily detectable on theplasma membrane (Fig. 3A and B and 4A). GFP-tH was also readilydetectable on Golgi membranes (Fig. 3A). In contrast, negligibleGFP-tK labeling was found on Golgi membranes even in cells withsignificant plasma membrane staining (Fig. 4A). These differenceswere not due to different expression levels of the respectiveproteins, because quantitative immunoblotting of cell lysatesshowed that the GFP constructs used in this study were expressedat equivalent levels (Fig. 1).

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FIG. 2. Confocal localization of GFP-Ras constructs. BHK cells were transfected with GFP-tH, GFP-tK, or GFP-6QtK and incubated at 37°C for 18 h prior to fixation for confocal microscopy. Scale bars, 10 µm. (A to F) Panels A, B, D, and E show cuts through cells at the level of the nucleus, whereas those in panels C and F are higher-level cuts showing the cell surface. In cells expressing GFP-tK (A to C), the protein is almost completely localized to the plasma membrane. In cells expressing GFP-tH (D to F), there is staining of the plasma membrane and intracellular structures. The intensity of plasma membrane fluorescence is less with GFP-tH than with GFP-tK. (G to I) Representative cells expressing GFP-6QtK. There is substantial intracellular staining adjacent to and contiguous with the nuclear membrane, with minimal staining of the plasma membrane. (J to L) Cells expressing GFP-6QtK were costained for PDI, an ER marker (red channel), with anti-KDDD antibody (K and L). The overlay (L) shows extensive localization of GFP-6QtK to the ER. (M to O) GFP-6QtK was cotransfected with VSV G-tagged sialyltransferase, a Golgi-resident protein, and the cells were stained for the G epitope tag. The overlay in panel O shows that GFP-6QtK is present in the Golgi, a result confirmed by immunoelectron microscopy.

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FIG. 3. Ultrastructural localization of GFP-tH at 37 and 15°C. BHK cells were transfected with GFP-tH and incubated for 18 h at 37°C (A and B) or for 16 h at 37°C, followed by 2 h at 15°C (C and D). The cells were then labeled with antibodies to GFP, followed by 10-nm protein A-gold particles. Scale bars, 100 nm. (A and B) Specific labeling for GFP-tH is evident on the plasma membrane (P). Despite the high expression level, there is negligible cytosolic labeling. Specific labeling is also apparent on the Golgi complex (G). Putative endosomes (E) show low labeling, whereas small vesicles nearby show higher labeling (arrows). (C and D) At 15°C, GFP-tH accumulates in groups of small vesicular structures (arrowheads) close to the Golgi complex (G), as shown at higher magnification in panel D. Again, note the lack of significant cytosolic labeling and the absence of labeling on the ER surrounding the nucleus (N).

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FIG. 4. Ultrastructural localization of GFP-tK at 37 and 15°C. BHK cells were transfected with GFP-tK and incubated for 18 h at 37°C (A) or for 16 h at 37°C, followed by 2 h at 15°C (B). The cells were then labeled with antibodies to GFP, followed by 10-nm protein A-gold particles. Scale bars, 100 nm. (A) Specific labeling for GFP-tK is evident on the plasma membrane (P). Negligible labeling is apparent on the Golgi complex (G). (B) Again, specific labeling for GFP-tK is evident on the plasma membrane (P). Negligible labeling is apparent on the Golgi complex (G), in contrast to the results obtained with GFP-tH (cf. Fig. 3C and D). N, nucleus.

We have shown previously that an isolated CVIM motif (directing farnesylation) or CCIL motif (directing geranylgeranylation)does not target proteins to the cell surface (18). However,whereas CVIM fusion proteins are largely soluble upon cell fractionation,reflecting the relatively low affinity of farnesylated proteinsfor membranes (47), CCIL fusion proteins associate avidly witha P100 fraction that is not plasma membrane (18). In the lightof the recent data of Dai et al. (12), we investigated whether,in intact cells, these mutant incomplete targeting motifs resultin mislocalization of Ras to the ER or Golgi. The C-terminal sequenceof K-ras-6Q, a mutant protein in which all of the lysines in thepolybasic domain have been replaced with glutamine residues (20),was cloned onto the C terminus of GFP to give GFP-6QtK. The localizationof GFP-6QtK, which therefore has a CVIM motif but no second signal,was examined using confocal and immunoelectron microscopy. Figure2G to I shows that very little GFP-6QtK was present on the plasmamembrane; rather, the majority of the protein was concentratedadjacent to, or associated with, the nuclear membrane. Costainingof cells with an antibody (anti-KDDD) against the ER protein PDIshowed extensive colocalization with GFP-6QtK (Fig. 2J to L).GFP-6QtK appeared more concentrated than the ER marker in theperinuclear area of the cell, which corresponded to the positionof the Golgi complex as marked by vesicular stomatitis virus (VSV)G epitope-tagged sialyltransferase (Fig. 2M to O). Since GFP-6QtK,but not GFP-tK or GFP-tH, was detected on ER membranes, we concludethat the second signal for plasma membrane targeting is requiredto efficiently clear CAAX proteins from the ER. In addition, sinceGFP-tH and GFP-6QtK, but not GFP-tK, were clearly present on Golgimembranes, we conclude that the polybasic domain functions asa sorting signal to exclude CAAX proteins from entering theGolgi.

Palmitoylated, but not polybasic, Ras proteins traffic though the Golgi to the cell surface. The presence of GFP-tH on Golgi membranes (Fig. 3) suggested that this palmitoylated protein passes through the exocytic pathway.To investigate this in more detail, BHK cells expressing GFP-tHand GFP-tK were incubated at 15°C for 2 h before fixation forconfocal or electron microscopy. This temperature block, whichimpairs transport from the ER to the cis-Golgi (42), resultedin striking increases in the amount of GFP-tH that was visibleadjacent to the nucleus (Fig. 5A) but caused no intracellularbuildup of GFP-tK (Fig. 5C). The intracellular accumulation ofGFP-tH was reversible and rapidly dissipated to control levelswhen the cells were returned to 37°C (data not shown). Since thecells were examined 18 h after transfection, a substantial amountof GFP-tH has already been synthesized and trafficked to the cellsurface. To verify that the accumulation of GFP-tH at 15°C consistedof newly synthesized and processed protein rather than proteinthat may have recycled to the Golgi region from the cell surface,the experiment was repeated after cells had been preincubatedwith cycloheximide to block new protein synthesis. Figure 5B showsthat under these experimental conditions, there was no intracellularaccumulation of GFP-tH at 15°C. And consistent with this observation,there was no significant colocalization of intracellular GFP-tHwith Rab11, a marker of the recycling endosome (54) (data notshown).

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FIG. 5. Newly synthesized GFP-tH accumulates in the Golgi complex at 15°C. BHK cells were transfected with GFP-tH (A, B, and E to G) or GFP-tK (C and D) or cotransfected with GFP-tH and VSV G-tagged sialyltransferase (E to G). After incubation at 37°C for 24 h, cells were incubated for a further 2 h at 15°C prior to fixation. Scale bars, 10 µm. (A and B) GFP-tH accumulates in perinuclear structures after incubation at 15°C (A); this intracellular accumulation of GFP-tH is blocked by incubation of the cells in cycloheximide for 2 h before and during the temperature block (B). (C and D) GFP-tK does not show any evidence of intracellular accumulation at 15°C (C and D). Cells shown in panel D were incubated in cycloheximide. (E to G) All cells were incubated at 15°C prior to fixation. Sialyltransferase (red channel), a Golgi marker, shows extensive colocalization with the intracellular accumulation of GFP-tH.

To identify the compartment in which GFP-tH was localized, cells were cotransfected with sialyltransferase and stained withrabbit antiserum to the VSV G epitope (Fig. 5E to G). The perinuclearaccumulation of GFP-tH colocalized with sialyltransferase, showingthat this treatment caused the protein to accumulate in the Golgiregion (Fig. 5G).

Frozen sections of GFP-tH- and GFP-tK-expressing cells were then examined by immunoelectron microscopy after incubation at15°C. Dense labeling for GFP-tH was observed on tubulovesicularmembranes in close proximity to the Golgi complex (Fig. 3C andD). These tubulovesicular structures represent an intermediatecompartment of the exocytic pathway between the ER and Golgi (33),and the accumulation of GFP-tH in this compartment is thereforeconsistent with a block in transport of GFP-tH from the ER tothe Golgi. In contrast, GFP-tK was readily detectable on the plasmamembrane of transfected cells incubated at 15°C but was not concentratedin the Golgi complex region, even in highly expressing cells (Fig.4B). A quantitative electron microscopic analysis of labelingassociated with the plasma membrane and Golgi apparatus of GFP-tH-and GFP-tK-expressing cells is presented in Fig. 6 and confirmsthe qualitative observations made by immunofluorescence assay.

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FIG. 6. Semiquantitative comparison of the subcellular distribution of GFP-ras constructs. Cells expressing GFP-tK and GFP-tH were fixed after a 2-h incubation at 15°C, cryosectioned, and examined by electron microscopy after immunogold labeling for GFP. Cells positively expressing GFPtH or GFPtK were assayed for the number of gold particles present on randomly chosen fixed-unit lengths of plasma membrane (P.M) or in fixed-unit Golgi complex areas (G.A). These data are, in part, arrayed as two scatter diagrams; note the log difference in the y axis scales. The plasma membrane pool, which represents the largest subcellular pool of Ras, contains similar amounts of labeling for GFPtH and GFPtK, indicating that levels of expression were comparable for the two peptides (means, 13.75 and 13.21 gold particles/µm, respectively). GFP-tH was present on and in the vicinity of the Golgi apparatus (mean, 28.62 gold particles/µm²), whereas GFPtK was almost completely excluded from this region (mean, 0.25 gold particles/µm²).

To extend these observations, we investigated whether an intact Golgi is required to traffic GFP-tH or GFP-tK to the plasmamembrane. BHK cells were treated with BFA 2 h after transfection,and plasma membrane staining was assessed by confocal microscopyafter a further 5 h of incubation. This protocol was used to allowsufficient cells to express the transfected protein to permita quantitative analysis. Coverslips were systematically examined,and the intensity of plasma membrane staining of each cell encounteredwas graded from strong (as in Fig. 2B or E) to weak or none (asin Fig. 2G to I). Examples of cells from the BFA-treated culturesare shown in Fig. 7A to D, and data from a representative experiment,in which a total of >1,000 cells were counted, are presented inFig. 7E. Strikingly, the number of GFP-tH-expressing cells withstrong plasma membrane staining fell by 75% in the presence ofBFA compared with that of untreated control cells, whereas thecorresponding number of GFP-tK-expressing cells with strong plasmamembrane staining was completely unaffected (Fig. 7E). Moreover,greater than 50% of GFP-tH-expressing cells treated with BFA showedstrong perinuclear staining (Fig. 7D), very similar to that shownin Fig. 2G to I. Thus, BFA-induced disruption of the Golgi hadno effect on the delivery of GFP-tK to the plasma membrane butsignificantly inhibited the plasma membrane access of GFP-tH.

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FIG. 7. BFA inhibits the plasma membrane accumulation of GFP-tH but not GFP-tK. BHK cells were transfected with GFP-tH or GFP-tK. At 2 h after transfection, BFA (5 µg/ml) was added to half of the cultures. After 5 h, coverslips were examined by confocal microscopy. Bar, 10 µm. (A to D) Representative cells from control cultures (A and C) and BFA-treated cultures (B and D). The localization of GFP-tK (A and B) is unaffected, while GFP-tH (C and D) is prevented from trafficking to the plasma membrane. (E) Greater than 450 cells (462 to 524) per experimental condition were scored for intensity of plasma membrane fluorescence by an observer blind to the transfection and treatment conditions. The graph shows the percentages cells with clear plasma membrane staining. It is a representative experiment that was repeated three times with similar results. CON, control. (F) BHK cells plated in 10-cm-diameter dishes were transfected with GFP-tH. At 2 h after transfection, cells were switched to labeling medium containing [³H]palmitic acid; simultaneously, BFA (10 µg/ml) was added to half of the cultures (+BFA) and ethanol carrier was added to the remainder ( $-$ BFA). After a further 3 h of incubation, coverslips were quantified as for panel E; the remainder of the cells were harvested into lysis buffer. Lysates were immunoblotted (IB, lanes 1 and 2) or immunoprecipitated (IP, lanes 3 to 6) using monoclonal anti-GFP serum. Radiolabeled proteins in the immunoprecipitates were visualized by fluorography (lanes 3 and 4). Immunoprecipitates were also probed with polyclonal anti-GFP serum to confirm that equal amounts of GFP-tH had been captured (lanes 5 and 6). Note that there is no effect of BFA on GFP-tH expression (lanes 1 and 2) or on palmitic acid incorporation (lanes 3 and 4). BFA did, however, decrease the number of cells with strong plasma membrane staining to 8% from the 48% in the untreated control.

To investigate whether BFA treatment inhibits the palmitoylation of GFP-tH, cells were metabolically labeled with [³H]palmitic acid for 3 h in the presence of BFA and then harvested.Lysates from BFA-treated and control, untreated cultures wereimmunoprecipitated with anti-GFP serum and analyzed by fluorography.Coverslips from the labeled culture plates were also examinedto quantify plasma membrane staining as described above. Figure7F shows that incubation in BFA had no effect on the incorporationof palmitic acid into GFP-tH, even though the number of GFP-tH-expressingcells with strong plasma membrane staining fell by 80% in theBFA-treated culture. We conclude that access of newly synthesizedGFP-tH to palmitoyltransferase does not require an intact Golgi.The simplest interpretation of these data is that palmitoylationof GFP-tH occurs proximal to the Golgi in the exocytic pathwayand that the CAAX palmitoyltransferase is therefore most likelyin theER.

Taxol perturbs the trafficking of polybasic Ras proteins. A mechanistic insight into the nonexocytic pathway utilized by K-ras comes from the work of Casey et al. (50), who reportedthat K-ras binds with high affinity to taxol-stabilized microtubulespolymerized in vitro from monomeric tubulin. This binding of K-rasto microtubules is prenyl dependent and is not seen with any otherRas or Ras-related protein. Moreover, taxol treatment of intactcells results in mislocalization of newly synthesized K-ras buthas no effect on the localization of H-ras (50). We thereforesought to extend these observations by examining the traffickingof GFP-tK and GFP-tH in taxol-treated cells. Consistent with theprevious report, taxol treatment had no detectable effect on theplasma membrane localization of newly synthesized GFP-tH (notshown) but significantly reduced the plasma membrane localizationof GFP-tK (Fig. 8D and G). Importantly, subcellular fractionationof BHK cells revealed that all of the GFP-tK remained associatedwith the P100 membrane fraction in taxol-treated cells (Fig. 8).Confocal sections of cells taken at the level of the nucleus showthat while some GFP-tK in taxol-treated cells is localized atthe plasma membrane, much is found in irregular structures whichdo not show an ER- or Golgi-like staining pattern (Fig. 8D andG). Some of these GFP-tK-decorated structures have a tubular-vesicularappearance (Fig. 8D and G). To examine the relationship betweenGFP-tK and the microtubule network, cells expressing GFP-tK werecostained for tubulin. The thickening and reorganization of microtubulesinduced by taxol are clearly visible when the untreated cellsin Fig. 8B are compared with the treated cells in Fig. 8E andH. The overlays of these confocal images show that there is verylittle colocalization of intracellular GFP-tK and tubulin in thetaxol-treated cells (Fig. 8F and I), although some alignment ofthe tubular-vesicular GFP-tK structures alongside microtubulesis evident in some cells (Fig. 8I). Electron microscopic analysis(Fig. 9) supported these observations. Taxol-treated cells showedabundant microtubule bundles which had negligible labeling forGFP-tK. Labeling was observed on the plasma membrane and withinlarge multivesicular endosomes, which were abundant in the taxol-treatedcells (Fig. 9). Similar multivesicular endosome carrier vesicleshave been shown to accumulate in nocodazole-treated BHK cells(14). In summary, these data show that GFP-tK does not directlyassociate with microtubules in vivo but that taxol treatment resultsin redistribution of GFP-tK away from the plasma membrane intoan endosomal compartment.

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FIG. 8. Taxol causes redistribution of GFP-tK. BHK cells were incubated in taxol for 2 h prior to and 12 h after lipofection and then harvested for subcellular fractionation or fixed for confocal or electron microscopy. The cytosolic (S = S100) and membrane (P = P100) fractions were prepared from cells expressing GFP-tK as previously described (45), normalized for protein content, and immunoblotted with anti-GFP serum (upper panel). GFP-tK remained fully associated with the P100 fraction in taxol-treated cells. The lower panel shows confocal images of BHK cells from identical cultures that have been costained for $alpha$ -tubulin. Cells in panels A to F have been cut at the level of the nucleus. The images in panels G to I show the edge of a cell magnified 2.5× relative to the other images. Bar, 10 µm for panels A to F and 4 µm for panels G to I. (A to C) Untreated control cells showing normal microtubules (red channel) and plasma membrane-localized GFP-tK (green channel). (D to I) Taxol-treated cells show some thickening and disruption of the microtubules, accompanied by accumulation of intracellular GFP-tK and a reduction in the amount of GFP-tK seen at the plasma membrane. GFP-tK is seen decorating vesicular and tubulovesicular structures, but there is very little actual colocalization of GFP-tK with tubulin. Some of the tubulovesicular structures are apparently aligned alongside microtubules; this is seen particularly well in panels G to I.

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FIG. 9. Electron microscopic analysis of taxol-treated cells. BHK cells were taxol treated and transfected as described in the legend to Fig. 8. Frozen sections were then labeled with antibodies to GFP, followed by protein A-gold particles. Specific labeling is associated with the plasma membrane and endosomal structures (arrows), but negligible labeling is associated with microtubules (small arrows, bottom panel). N, nucleus; M, mitochondria; bars, 200 nm.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The experiments described in this paper address the intriguing question of how Ras proteins that have been posttranslationallymodified on the cytosolic leaflet of the ER membrane gain accessto the inner surface of the plasma membrane. The results presentedhere are fully consistent with the recent observations of Choyet al. (10), who examined in detail the cellular traffickingof full-length N- and K-Ras proteins coupled to GFP. Here we havefocused on the ability of the isolated H- and K-Ras membrane-targetingmotifs to traffic GFP to the plasma membrane and have made similarobservations. Importantly, when taken together, the two studiesshow that the C-terminal Ras motifs contain all of the relevantsignals for successful Ras trafficking. Moreover, they demonstratethat the palmitoylated Ras proteins H- and N-ras use the sametraffickingpathway.

We found that proteins which have an intact second signal for plasma membrane localization, palmitoylation or a polybasicdomain, are efficiently cleared from the ER, whereas proteinswhich lack a second signal accumulate in the ER and Golgi complex.This led to the important conclusion that palmitoylation or apolybasic domain is an essential part of the trafficking signalfor Ras proteins. Moreover, a particularly fascinating findingof the present study is the observation that palmitoylated H-ras,but not K-ras, traffics to the plasma membrane along the secretorypathway via the Golgi complex. This gives new insights into themanner in which these two proteins, which differ in membrane anchoring,reach their site of action at the plasma membrane. We envisagea scheme in which the H-ras and K-ras polypeptides are synthesizedon cytosolic ribosomes and farnesylated in the cytoplasm. Theproteins then associate with the ER for removal of the AAX tripeptideand methylation of the C-terminal cysteine. The two isoforms arethen differently routed (Fig. 10). If a polybasic domain is present,as in K-ras, the protein does not enter the conventional exocyticpathway. This follows because no GFP-tK was detectable in or nearthe Golgi at 37 or 15°C by either immunofluorescence assay orelectron microscopy. These data therefore suggest that the combinationof a CAAX motif and a polybasic domain comprises a sorting signalthat directs K-ras directly to the cell surface, bypassing theGolgi.

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FIG. 10. Model of Ras trafficking. After the common processing steps of farnesylation, AAX proteolysis, and methylation which are completed on the cytosolic surface of the ER, the trafficking routes of the different Ras proteins diverge. K-ras, by virtue of its C-terminal polybasic domain, is sorted out of the conventional exocytic pathway and takes an undefined pathway to the cell surface that bypasses the Golgi. H- and N-ras are palmitoylated by an ER-localized palmitoyltransferase and enter the exocytic pathway; they traffic to the cell surface via the Golgi. OMe, carboxymethyl; PalmCoA, palmitoyl coenzyme A; SAM, S-adenosyl methionine; PalmTase, palmitoyltransferase; MethTase, methyltransferase; FPTase, farnesyl protein transferase; Farnesyl-PP, farnesyl pyrophosphate.

It is unclear exactly how K-ras accesses the plasma membrane, although several mechanisms are possible. For example, smgGDS,a weak exchange factor for K-ras, could operate as a chaperoneprotein because it has been shown to extract K-ras from cell membranes(27), in a fashion analogous to that of the GDIs of Rho andRab proteins, yet does not interact with H- or N-ras. Alternatively,since farnesylated K-ras has a lower affinity for membranes thanpalmitoylated H-ras, it is possible that this lower avidity ofmembrane binding allows K-ras to dissociate from the ER and binddirectly to the plasma membrane; although this seems less likelybecause GFP-6QtK, which has no polybasic domain and hence haseven lower affinity for membranes than GFP-tK, remained associatedwith the ER and Golgi membranes in intact cells. The completeabsence of GFP-tK from the ER is more consistent with an activeremoval mechanism than a passive, equilibrium-driven diffusionprocess.

Neither of these potential trafficking mechanisms can account for the intriguing observations that taxol treatment significantlyreduces the plasma membrane accumulation of newly synthesizedK-ras. This result strongly suggests that a functional microtubulenetwork is necessary for K-ras to transit the cell. We show here,however, that there is no obvious colocalization of GFP-tK withtubulin in taxol-treated cells, as might have been predicted fromthe study of Casey et al. (50). Rather, we found that GFP-tKaccumulates in intracellular multivesicular and univesicular endosomalstructures that are only infrequently arrayed alongside taxol-stabilizedmicrotubules. There are two possible interpretations of thesefindings. First, GFP-tK traffics from the ER to the plasma membraneusing microtubule-dependent vesicular transport and taxol treatmentresults in a build up of GFP-tK in transport vesicles. An importantcaveat is that K-ras must traffic to the plasma membrane veryquickly, because the GFP-tK taxol-sensitive compartment was notvisible in untreated cells. In this context, it is worth notingthat kinetic analysis does suggest that newly synthesized K-rasaccesses the cell surface more rapidly than does N-ras (10).A second interpretation is that forward transport of GFP-tK fromthe ER to the plasma membrane is unaffected by taxol but thatmaintenance of the plasma membrane pool requires functioning microtubules.In this case, in taxol-poisoned cells, some of the plasma membrane-localizedGFP-tK enters and accumulates in a bulk flow endosomal compartment,possibly due to disruption of early-to-late endosomal transport(14). Both interpretations have important yet clearly differentimplications for the potential clinical manipulation of K-rasplasma membraneassociation.

In the absence of a polybasic domain, CAAX proteins are delivered to the Golgi complex and, if palmitoylated, are traffickedto the plasma membrane (Fig. 10). Since palmitoylated GFP-tH wascleared from the ER much more efficiently than nonpalmitoylatedGFP-6QtK, it is most likely that the Ras palmitoyltransferase,like the pcCMT, is present in the ER. This conclusion is supportedby the observation that disruption of the Golgi by BFA did notinhibit GFP-tH palmitoylation but dramatically reduced GFP-tHtrafficking to the plasma membrane. Since some GFP-6QtK was detectedin the Golgi, palmitoylation cannot be absolutely required forER-to-Golgi transport but palmitoylation and an intact Golgi areclearly essential for trafficking of H-ras from the ER throughthe Golgi to the plasma membrane. The role of palmitoylation maysimply be to allow a more stable membrane association of H-ras,which is required for further transport to the plasma membrane.However, it is also possible that the requirement for palmitoylationto escape from the Golgi indicates that the palmitoyl group isrequired for sorting of H-ras into specific carrier vesicles exitingthe Golgi. These roles are not mutually exclusive. Either way,H-ras behaves like a membrane protein, being transported to thecell surface via the Golgi complex while associated with the cytoplasmicface of the transported membrane. H-ras is therefore a cytoplasmiccargo protein of the exocytic pathway, and its delivery to theplasma membrane is reliant on membrane traffic. Interestingly,a recent study reached similar conclusions with respect to Lck,proposing palmitoylation early in the exocytic pathway and vesiculartransport to the cell surface through the Golgi (3).

There appear to be two outcomes for CAAX proteins with an incomplete trafficking signal: farnesylated Ras proteins with relativelylow affinity for membranes probably have a high rate of dissociationfrom the ER and Golgi, which is why they are recovered predominantlyin the cytosol on cell fractionation (19). In contrast, geranylgeranylatedRas proteins with an incomplete trafficking signal have a higheraffinity for membranes (47) and remain associated with the ER.Similarly, Ras proteins engineered to be N terminally myristoylatedand C terminally farnesylated, but which lack a polybasic domainor palmitoylation sites, fail to localize to the cell surfaceand extensively decorate the nuclear membrane (7), implyingthat these dually lipidated Ras proteins, with a high affinityfor membranes and no second signal, cannot exit and remain boundto the ER. Other studies also emphasize the importance of thesecond signal for plasma membrane targeting. N-terminally myristoylatedRas proteins lacking a CAAX motif but with an intact polybasicdomain or palmitoylation sites localize predominantly to the plasmamembrane. Thus, the second signal specifies targeting to the plasmamembrane if the Ras protein has a hydrophobic N or C terminus.Even more strikingly, in the case of H-Ras, additional hydrophobicityother than that provided by the acyl chain is also unnecessaryfor plasma membrane binding: H-ras proteins with a C-terminalpolybasic extension in place of the CAAX motif undergo palmitoylation,localize to the plasma membrane, and have biological activity(4, 36).

Finally, different trafficking mechanisms for the Ras isoforms can be rationalized in the light of recent data showing thatH-ras, but not K-ras, functionally associates with cholesterol-richsurface domains (46). An attractive hypothesis is that theselipid rafts, which can ultimately coalesce into caveolae in thepresence of caveolin, are assembled in the trans-Golgi networkand that H-ras needs to associate with the rafts at this stage.In contrast, K-ras, which does not show reliance on cholesterol-enricheddomains for Raf activation, might show a more random distributionover the cell surface (38) and therefore does not need sucha specific traffickingpathway.

	ACKNOWLEDGMENTS

We thank Bill Balch for helpful advice, Tommy Nilsson for the pRS $alpha$ -sialylT plasmid, Steven Fuller for the anti-KDDD antibody,and Annette Lane and Colin McQueen for excellent technicalassistance.

This work was supported by grants to J.F.H. and R.G.P. from the NHMRC, Australia. J.F.H. is also supported by the Royal Children'sHospital Foundation,Queensland.

	FOOTNOTES

^* Corresponding author. Mailing address: Queensland Cancer Fund Laboratory of Experimental Oncology, Department of Pathology,University of Queensland Medical School, Herston Rd., Brisbane4069, Australia. Phone: 617 3365 5288. Fax: 617 3365 5511. E-mail:j.hancock{at}mailbox.uq.edu.au.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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