Analysis of GTPase-activating proteins: Rab1 and Rab43 are key Rabs required to maintain a functional Golgi complex in human cells

doi:10.1242/jcs.014225

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):

Home Help Feedback Subscriptions Archive Search Table of Contents

First published online 7 August 2007
doi: 10.1242/jcs.014225

Journal of Cell Science 120, 2997-3010 (2007)
Published by The Company of Biologists 2007

This Article

	Summary
	Figures Only
	Full Text (PDF)
	Supplementary Material
	All Versions of this Article: jcs.014225v1 120/17/2997 most recent
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Email this article to a friend
	Related articles in JCS
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager


Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Haas, A. K.
	Articles by Barr, F. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Haas, A. K.
	Articles by Barr, F. A.

Research Article

Analysis of GTPase-activating proteins: Rab1 and Rab43 are key Rabs required to maintain a functional Golgi complex in human cells

Alexander K. Haas¹^,2, Shin-ichiro Yoshimura¹^,2, David J. Stephens³, Christian Preisinger²^,*, Evelyn Fuchs¹ and Francis A. Barr¹^,2^,

¹ Cancer Research Centre, University of Liverpool, 200 London Road, Liverpool, L9 3AT, UK
² Department of Cell Biology, Max-Planck-Institute of Biochemistry, Martinsried 82152, Germany
³ Department of Biochemistry, University of Bristol, Bristol, UK

Author for correspondence (e-mail: fabarr{at}liverpool.ac.uk)

Accepted 1 July 2007

Summary

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

Rab GTPases control vesicle movement and tethering membraneevents in membrane trafficking. We used the 38 human Rab GTPaseactivating proteins (GAPs) to identify which of the 60 Rabsencoded in the human genome function at the Golgi complex. Surprisingly,this screen identified only two GAPs, RN-tre and TBC1D20, disruptingboth Golgi organization and protein transport. RN-tre is theGAP for Rab43, and controls retrograde transport into the Golgifrom the endocytic pathway. TBC1D20 is the ER-localized GAPfor Rab1, and is the only GAP blocking the delivery of secretorycargo from the ER to the cell surface. Strikingly, its expressioncauses the loss of the Golgi complex, highlighting the importanceof Rab1 for Golgi biogenesis. These effects can be antagonizedby reticulon, a binding partner for TBC1D20 in the ER. Together,these findings indicate that Rab1 and Rab43 are key Rabs requiredfor the biogenesis and maintenance of a functional Golgi structure,and suggest that other Rabs acting at the Golgi complex arelikely to be functionally redundant.

Key words: Vesicle transport, Golgi complex, ER-exit site, Rab GTPases, TBC-domain

Introduction

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

Vectorial protein transport between the ER and Golgi complexrequires the coordinated action of many different small GTP-bindingproteins of the Ras superfamily, each controlling distinct aspectsof the cargo sorting, vesicle formation and vesicle fusion processes(Bonifacino and Glick, 2004; Zerial and McBride, 2001). TheseGTP-binding proteins share a common mode of action involvingthe recruitment of cytosolic protein complexes to localizeddomains on membrane surfaces (Munro, 2002; Short et al., 2005).Sar1 and ARF1 recruit COPII and COPI coat complexes to ER andGolgi membranes, respectively, thus promoting vesicle formation(Bonifacino and Glick, 2004). Rabs recruit protein complexesimportant for directed vesicle movement and target recognition(Pfeffer, 1999; Waters and Hughson, 2000). To do this, theseproteins cycle between a GDP bound inactive state, and a GTPbound membrane-associated active state (Pfeffer and Aivazian,2004; Vetter and Wittinghofer, 2001). It is this GTP bound statethat makes specific interactions with so-called effector complexes,and thus promotes their recruitment to membranes. This cycleof activation and inactivation is under the control of GDP-GTPexchange factors (GEFs) and GAPs (Pfeffer and Aivazian, 2004;Zerial and McBride, 2001).

In the case of ER to Golgi trafficking, Rab1 and Rab2 have beenimplicated in the tethering and fusion reactions, and are thoughtto act sequentially (Allan et al., 2000; Alvarez et al., 1999;Segev, 1991; Tisdale and Balch, 1996; Tisdale et al., 1992).First, COPII vesicles, formed from specialized exit sites onthe endoplasmic reticulum (ER exit sites: ERES), are tetheredtogether by the action of Rab1 together with its effector p115to give rise to vesicular-tubular clusters (VTCs) adjacent tothe Golgi (Allan et al., 2000; Alvarez et al., 1999; Bannykhet al., 1996; Cao et al., 1998). TRAPP, the GEF for Rab1, promotestethering of COPII vesicles by activating Rab1 and also servesas a structural component of the tether (Barrowman et al., 2000;Jones et al., 2000; Sacher et al., 2001; Wang et al., 2000).Recent evidence shows that TRAPP is assembled onto forming COPIIvesicles by direct interaction with the coat, thus providinga mechanism to ensure all vesicles can recruit active Rab1 (Caiet al., 2007). Second, Rab2 and its effectors promote the maturationof these VTC structures and their incorporation into the Golgi(Short et al., 2001; Tisdale and Balch, 1996). Finally, in additionto its role in COPII vesicle tethering, Rab1 may also have afunction in regulating the exit of secretory cargo from theER. This idea arose from experiments showing that extractionof Rabs using the Rab chaperone GDI (guanine nucleotide dissociationinhibitor) prevented the exit of the vesicular stomatitus virusG-protein (VSV G) from the ER and that this could be complementedby a complex of Rab1 and GDI (Peter et al., 1994). Later, Ypt1and Uso1, the yeast homologues of Rab1 and p115, respectively,were found to play a role in coupling the sorting of secretorycargo to vesicle formation (Morsomme and Riezman, 2002), providingfurther support for this idea.

To determine which specific Rabs are of general importance forER to Golgi trafficking and Golgi organization in mammaliancells, we have screened 38 human Rab GAPs for their abilityto disrupt the organization of the Golgi complex and proteintransport. Rab GAPs are characterized by a conserved catalyticdomain, the TBC (Tre2/Bub2/Cdc16) domain (Albert and Gallwitz,1999; Albert et al., 1999; Strom et al., 1993), that promotesGTP hydrolysis by a dual arginine-glutamine-finger catalyticmechanism related to the arginine-finger mechanism of Ras GAPs(Ahmadian et al., 1997; Albert et al., 1999; Pan et al., 2006;Rak et al., 2000). As we have shown previously, in the caseof Rab5 (Haas et al., 2005), Rab GAPs can be used to specificallyinactivate the endogenous pool of a Rab and thus interfere withthe process that this Rab is involved in. By mutating the catalyticarginine residue of the TBC domain to alanine, the non-specificeffects of GAP expression can easily be discriminated from thespecific effects of Rab inactivation (Haas et al., 2005).

Results

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

A screen for TBC domain proteins that alter Golgi structure
TBC-domain containing proteins, putative Rab GAPs, were screenedfor their ability to alter Golgi structure when overexpressedin either HeLa or telomerase-immortalized human retinal epithelial(hTERT-RPE1) cells (Fig. 1). Of the 38 TBC domain proteins tested,only three showed any significant effects on Golgi organizationin both HeLa and hTERT-RPE1 cells (Fig. 1A). One of these, TBC1D14was eliminated since the catalytically inactive form showedequivalent or increased effects on the Golgi when compared tothe wild-type protein (Fig. 1A). This left two candidate regulatorsof Golgi-localized Rab GTPases, TBC1D20 and RN-tre, both capableof causing activity dependent fragmentation of both the cis-Golgimarker GM130 and the trans-Golgi marker TGN46 (Fig. 1B,C).

View larger version (40K):
[in this window]
[in a new window]

Fig. 1. A screen for TBC domain proteins that alter Golgi structure. (A-C) HeLa and hTERT-RPE1 cells were transfected with the GFP-tagged wild-type and catalytically inactive point mutant TBC-domain proteins listed in the figure. After 24 hours they were fixed, and then stained with antibodies to GM130 or TGN46. (A) The number of cells displaying a fragmented Golgi was then counted (n>100 per condition), expressed as a percentage, and then plotted as a bar graph; grey bars, wild-type (WT) GAPs; open bars, inactive mutants. (B) Cells triply stained for the expressed wild-type (WT) TBC1D20 and RN-tre, TGN46 and GM130 are shown. (C) Cells triply stained for the expressed catalytically inactive mutant (RA) TBC1D20 R105A and RN-tre 150A, TGN46, and GM130 are shown. Bars, 10 µm, in all panels.

To further define the site of action of the different GAPs,the effects of their expression on the ER-Golgi intermediatecompartment (ERGIC) were examined (Fig. 2). In this screen TBC1D20showed catalytic activity dependent ERGIC fragmentation (Fig. 2A,B).Interestingly RN-tre caused only subtle changes to the ERGIC(Fig. 2A,B), suggesting that this GAP is more important forregulating trafficking at other Golgi compartments. This isconsistent with our previous findings that RN-tre, togetherwith its target Rab43, is required for retrograde traffickingto the trans-Golgi, but not anterograde cargo transport throughthe Golgi (Fuchs et al., 2007

) (see supplementary material FigsS1 and S2). Interestingly, TBC1D22B, a potential GAP for Rab33(Pan et al., 2006

) was found to cause ERGIC disruption (Fig. 2A).Other GAPs showed only weak or no effect on the ERGIC. BecauseTBC1D20 had a general effect on Golgi and ERGIC organization,and is a highly conserved protein (see supplementary materialFig. S3), it was studied further.

View larger version (48K):
[in this window]
[in a new window]

Fig. 2. A screen for TBC domain proteins that alter ERGIC structure. (A-C) HeLa cells were transfected with the GFP-tagged wild-type and catalytically inactive point mutant TBC-domain proteins listed in the figure. After 24 hours they were fixed, and then stained with antibodies to ERGIC53. (A) The number of cells displaying a fragmented ERGIC was then counted (n>100 per condition), expressed as a percentage, and then plotted as a bar graph: grey bars, wild-type GAPs; open bars, inactive mutants. (B) Cells stained for the expressed wild-type (WT) TBC1D20 and RN-tre, and ERGIC53 are shown. (C) Cells stained for the expressed catalytically inactive mutant (RA) TBC1D20 R105A and RN-tre R150A and ERGIC53 are shown. Bars, 10 µm, in all panels.

TBC1D20 expression causes a loss of Golgi phenotype
To establish what happens to the Golgi upon TBC1D20 expression,markers for different Golgi sub-compartments were investigated(Fig. 3). TBC1D20 expression results in the loss of recognizableGolgi or punctate vesicular staining for p115, golgin84 andgolgin97, but has no effect on the staining of the endosomalRab5 effector EEA1 (Fig. 3A). TBC1D20, therefore, perturbs allcompartments of the Golgi. None of these effects were seen whencatalytically inactive forms of TBC1D20 were used (Fig. 3B),indicating that these effects are likely to be due to the catalyticinactivation of one or more Rab family GTPases.

View larger version (70K):
[in this window]
[in a new window]

Fig. 3. TBC1D20 causes a `loss of Golgi' phenotype. HeLa cells transfected with GFP-tagged (A) wild-type TBC1D20 (green), or (B) a catalytically inactive R105A point mutant (green) were fixed after 22 hours and then stained with antibodies to p115, golgin84, golgin97, and EEA1 (all in red) as indicated. (C) HeLa cells expressing GFP-tagged NAGT-I (green) were transfected with Myc-tagged wild-type TBC1D20 or the catalytically inactive R105A mutant (blue), fixed after 12 hours, and then stained with antibodies to GM130 (red) and the Myc-epitope tag. (D) To determine the levels of Golgi proteins, cell extracts were prepared from HeLa cells transfected for 24 hours with Myc-tagged wild-type TBC1D20 (WT) or the catalytically inactive R105A mutant (RA). Of these extracts, 20 µg were western blotted for GM130 and p115, the Myc-epitope to control for equal expression of the TBC1D20 constructs, and ${alpha}$ -tubulin as marker for equal loading. The asterisk indicates a GM130 breakdown product. (E) HeLa cells left untreated, expressing Myc-tagged TBC1D20 or the dominant-negative Sar1 H79G mutant for 24 hours, or treated with BFA for 30 minutes were fractionated. Equivalent amounts of the total lysate (T), membrane pellet (P), or soluble cytosolic fraction (S) were western blotted for p115, GM130, golgin84 and the Myc epitope. Bars, 10 µm, in all panels.

These observations raised the question of where the Golgi proteinshave redistributed to in TBC1D20-expressing cells. Peripheralmembrane proteins such as GM130 and p115 can relocate to thecytosol, but integral membrane proteins such as golgin84 andGolgi enzymes must still be present in membrane structures.Alternatively, Golgi proteins could be degraded. To test thesepossibilities a series of experiments was performed. First,the fate of a Golgi enzyme was followed. This revealed thatin TBC1D20-expressing cells, N-acetylglucosaminyl-transferase(NAGT-I) is redistributed to the ER, identified by the markercalnexin (Fig. 3C). When a catalytically inactive mutant ofTBC1D20 was used, NAGT-I remained in the Golgi (Fig. 3C). Second,to test if Golgi proteins were degraded, western blots wereperformed on extracts of cells expressing wild-type or catalyticallyinactive TBC1D20. Despite the high transfection efficiency,which was over 50% as judged by fluorescence microscopy, therewas no change in the levels of either GM130 or p115 in cellsexpressing either form of TBC1D20 (Fig. 3D). Finally, the redistributionof peripheral Golgi membrane proteins to the cytosol was tested.This showed that GM130 behaved like the integral membrane proteingolgin84 and was associated with the membrane pellet to thesame extent in control cells and in cells expressing wild-typeTBC1D20 (Fig. 3E). Interestingly, under the same conditions,the pool of membrane-associated p115 was lost in TBC1D20-expressingcells (Fig. 3E). This effect is not simply due to blocking ER-Golgimembrane trafficking or the disruption of the Golgi complex,since BFA, which specifically inactivates COPI, and the GTP-restrictedform of Sar1, which blocks the COPII pathway by preventing vesicleuncoating, did not cause loss of p115 from the membrane pelletor change the distribution of GM130 (Fig. 3E). Together, theseresults suggest that Golgi proteins are still associated withmembrane structures after TBC1D20 expression, but their fatesmay be different. Similar to BFA treatment, Golgi enzymes arepresent in the ER, whereas Golgi matrix proteins such as GM130are associated with a haze of small vesicular remnants. Significantly,the Rab1 effector p115 was lost from membranes in TBC1D20-expressingcells, indicating that there may be defects in the Rab1-dependentCOPII vesicle-tethering pathway, and suggesting that TBC1D20may be a regulator of Rab1.

TBC1D20 is a GAP for Rab1 and 2 in vitro
To identify candidate target Rabs for TBC1D20, an unbiased two-hybridscreen was performed, based on the use of mutants locking thespecific Rab-GAP interaction (Haas et al., 2005). This approachrevealed that Rabs 1 and 2 are potential candidate targets ofTBC1D20 (A.K.H. and F.A.B., unpublished). To directly test thispossibility, biochemical GTP-hydrolysis assays were performed(Fig. 4). When tested against an extensive selection of Rabs,TBC1D20 strongly stimulated GTP hydrolysis by Rab1 and Rab2(Fig. 4A). Although the majority of Rabs tested were not activatedby TBC1D20, some increased activity of Rab8A, 13 18 and 35 wasobserved (Fig. 4A). These Rabs are closely related members ofthe Rab1-Sec4 subfamily, and this probably explains why a Rab1GAP can activate them in vitro. TBC1D20 activity towards Rab1was dependent on the TBC domain encoded by amino acids 1-317but not other regions of the protein (Fig. 4B). This activitywas abolished when either the catalytic arginine 105 in theTBC domain was mutated to alanine, or the conserved glutamine67 in the GTP-binding site of Rab1 was mutated to leucine (Fig. 4B),in agreement with the catalytic mechanism proposed for Rab GAPs(Pan et al., 2006). Furthermore, TBC1D20 did not display GAPactivity towards Sar1 and ARF1 (Fig. 4A), both non-Rab GTPasesknown to be required for protein trafficking and the maintenanceof normal Golgi structure.

View larger version (54K):
[in this window]
[in a new window]

Fig. 4. TBC1D20 is a GAP for Rab1 and Rab2. Biochemical assays for GTP hydrolysis with the Rabs and GAPs indicated were performed as described previously (Fuchs et al., 2007

; Haas et al., 2005

). All reactions were carried out for 60 minutes. (A) To determine the specific activity towards a range of GTPases, 0.5 pmoles TBC1D20 were tested against 100 pmoles of the Rab GTPases indicated, as well as ARF1 and Sar1. The basal GTP hydrolysis seen with a buffer control was subtracted for each GTPase. (B) 5 pmoles of wild-type and R105A mutant TBC1D20 full-length or the TBC-domain only (amino acids 1-317) were tested against 100 pmoles wild-type Rab1 or the Rab1 Q67L hydrolysis-defective mutant. Basal GTP hydrolysis seen with buffer is plotted as open bars, and GAP-stimulated GTP hydrolysis as grey bars. (C) Buffer (control) or 0.5 pmoles of the GAP indicated were tested against 100 pmoles Rabs 1 and 2. Basal GTP hydrolysis seen with buffer is plotted as open bars, and GAP-stimulated GTP hydrolysis as grey bars.

Rabs1 and Rab2 are important components of the ER-Golgi transportpathway in mammalian cells. Expression of a GAP for either Rab1or Rab2 should inactivate the cognate Rab, and therefore blockprotein transport and disrupt Golgi structure. The screen describedin Figs 1 and 2 revealed that only five TBC-domain proteinscause disruption of the Golgi complex in HeLa cells, and thesewere therefore tested against both Rab1 and Rab2 in biochemicalGTP-hydrolysis assays (Fig. 4C). This revealed that only TBC1D20promotes GTP hydrolysis by Rab1 or Rab2 to a significant extent.Consistent with these observations, target Golgi Rabs are alreadyknown for the TBC1D22 family, proposed to act on Rab33 (Panet al., 2006), RN-tre, reported to act on Rab43 (Fuchs et al.,2007; Haas et al., 2005). TBC1D20 is therefore a specific GAPfor Rab1 and Rab2 in vitro.

TBC1D20 is a Rab1 GAP in vivo
To further narrow down the target of TBC1D20, the effects ofexpressing dominant-negative Rabs were compared (Fig. 5A). Dominant-negativeRab43 T32N was taken as a positive control that caused Golgifragmentation, but did not mimic the TBC1D20 phenotype (Fig. 5A,B).By contrast, dominant-negative Rab1 N121I, but not wild-typeor activated Q67L mutant, caused a loss of Golgi phenotype similarto that caused by TBC1D20 (Fig. 5A,B). Rab2 and the Rabs thatgave weak GTP-hydrolysis signals with TBC1D20 did not causethe loss of Golgi phenotype seen with dominant-negative Rab1(Fig. 5A,B). In addition, whereas Rab2 depletion caused Golgifragmentation, it did not cause the loss of Golgi phenotypeseen with TBC1D20 or in cells expressing dominant-negative Rab1(supplementary material Fig. S4A-C). Together, these findingssupport the idea that TBC1D20 acts as a Rab1 GAP in vivo.

View larger version (46K):
[in this window]
[in a new window]

Fig. 5. Increased p115 staining at the Golgi in TBC1D20-depleted cells. (A) HeLa cells transfected with GFP-tagged dominant-negative Rabs were fixed after 24 hours, and then stained with antibodies to GM130. The number of cells displaying a fragmented Golgi (open bars) or scattered COPII staining (filled bars) was then counted (n>100 per condition), expressed as a percentage, and plotted as a bar graph. (B) HeLa cells transfected with GFP-tagged Rab1, dominant active Rab1^Q67L, and dominant-negative Rab1 N121I or Rab43 T32N were fixed after 24 hours, and then stained with antibodies to GM130 or COPII (red). Rabs were visualized by GFP fluorescence (green), and DNA was stained with DAPI. (C) Cell lysates from HeLa cells expressing GFP-tagged TBC1D20 treated with either control or TBC1D20-specific siRNA duplexes were western blotted for GFP to detect TBC1D20, and ${alpha}$ -tubulin as a loading control. (D) HeLa cells expressing the GFP-tagged R105A inactive form of TBC1D20 (green) as a marker for the efficiency of RNA interference were treated with either control or TBC1D20-specific siRNA duplexes for 72 hours. The cells were then fixed and stained with antibodies to COPII, p115 or GM130 (all in red). DNA was stained with DAPI (blue). Bars, 10 µm.

To test if endogenous TBC1D20 is required for normal Rab1 regulation,HeLa cells were depleted of TBC1D20 using RNA interference (Fig. 5C,D).Western blot analysis showed that TBC1D20 could be efficientlysilenced using specific siRNA duplexes (Fig. 5C). EndogenousTBC1D20 is a low abundance protein spread throughout the ERand hence difficult to detect (A.K.H. and F.A.B., unpublished).For this reason a GFP-tagged, catalytically inactive form ofthe protein was used to monitor the efficiency of RNA interference.Consistent with the idea that TBC1D20 is a negative regulatorof Rab1 and hence its effectors, the intensity of p115 stainingwas increased in TBC1D20-depleted cells compared to the control(Fig. 5D). The typical extended ribbon-like staining patternof GM130 became more compact, but did not increase in intensity(Fig. 5D). In addition, COPII-positive structures defined bySec31 partially lost their perinuclear organization adjacentto the Golgi, and become scattered throughout the cytosol (Fig. 5D).Despite these changes, the transport of VSV G from the ER tothe plasma membrane was not altered (A.K.H. and F.A.B., unpublished).TBC1D20 therefore contributes to the organization of COPII vesiclesand the Golgi complex, but is not an essential component ofthe vesicle transport machinery.

ER exit is blocked by inactivation or depletion of Rab1
If TBC1D20 is a GAP for Rab1, then it should be able to causea block in ER to Golgi transport. To test this, VSV G transportassays were performed using cells expressing wild-type and catalyticallyinactive mutant forms of the TBC-domain proteins causing Golgior ERGIC fragmentation (see Figs 1 and 2). Strikingly, onlyTBC1D20 prevented the appearance of the VSV G at the cell surface(Fig. 6A,B). This effect was dependent on the catalytic arginine,indicating that this is due to specific inactivation of Rab1.Furthermore, depletion of Rab2 did not block anterograde transportof VSV G from the ER to the cell surface (supplementary materialFig. S4D). Therefore, the effect of TBC1D20 expression is mainlydue to the inactivation of Rab1.

View larger version (65K):
[in this window]
[in a new window]

Fig. 6. Rab1 is the only Rab essential for ER to cell surface transport. (A,B) VSV G transport assays were performed as described in the Materials and Methods on HeLa cells expressing the wild-type and catalytically inactive arginine finger point mutant TBC-domain proteins indicated. The cell surface appearance of VSV G was measured for all conditions (A). The bar graph (B) shows the inhibition in transport observed with the various wild-type (grey bars), and catalytically inactive (open bars) TBC-domain proteins. (C) VSV G transport assays were performed in HeLa cells expressing Myc-tagged wild-type (WT) or catalytically inactive arginine finger point mutant (R105A) TBC1D20. After 60 minutes of transport cells were fixed and surface stained for VSV G (red), then permeabilized and stained for the Myc epitope (blue). Total VSV G was observed by GFP fluorescence (green) at all time points. (D) VSV G transport assays were performed in HeLa cells treated with control, Rab1, p115, or GM130 siRNA duplexes for 72 hours. After 60 minutes of transport cells were fixed and surface stained for VSV G (red), and total VSV G was observed by GFP fluorescence (green). (E) VSV G transport assays were performed in HeLa cells expressing Myc-tagged wild-type (WT), dominant-negative (N121I) or constitutive active (Q67L) point mutants of Rab1. After 60 minutes of transport the cells were fixed and surface stained for VSV G (red), then permeabilized and stained for the Myc epitope (blue). Total VSV G was observed by GFP fluorescence (green). Bars, 10 µm.

Interestingly, in TBC1D20-expressing cells, VSV G was apparentlyunable to exit the ER after 60 minutes of transport, and didnot accumulate in punctate structures characteristic of COPIIvesicles or ERES (Fig. 6C). The effects of depleting componentsof ER-Golgi vesicle tethering complexes, Rab1, p115 and GM130,were then compared to those seen with TBC1D20 overexpression(Fig. 6D). Western blotting showed that these proteins werespecifically depleted (see supplementary material Fig. S5A).Similar to TBC1D20, depletion of Rab1 or p115 prevented theappearance of VSV G at the cell surface (Fig. 6D). In contrastto p115 depletion, where VSV G left the ER and accumulated ina collapsed punctate structure reminiscent of GM130 stainingin p115 depleted cells (supplementary material Fig. S5B), VSVG was unable to leave the ER in Rab1-depleted cells (Fig. 6D).Supporting this observation, similar results were obtained incell expressing dominant-negative but not dominant active orwild-type forms of Rab1 (Fig. 6E). GM130 although required fornormal Golgi-ribbon and COPII vesicle organization as expected(Puthenveedu et al., 2006

), was not required for VSV G transport(see supplementary material Fig. S5B and Fig. 6D). The similarityof the TBC1D20 overexpression, Rab1 depletion, and Rab1 dominant-negativephenotypes indicates that TBC1D20 exerts its effects by inactivatingRab1. Although Rab1 binding proteins, such as p115 and GM130,may contribute to this phenotype, for example the loss of COPIIvesicle organization, they cannot explain why secretory cargoproteins are blocked in the ER. However, this would suggestthat TBC1D20 and Rab1 have some function at the level of theER.

COPII function in TBC1D20-expressing cells
The block in cargo exit from the ER on TBC1D20 overexpression,Rab1 depletion and Rab1 dominant-negative N121I expression suggesteda defect in the COPII vesicle transport pathway. Rab1 and itseffector proteins are required for COPII vesicle tethering,and this is an essential step in ER to Golgi transport (Allanet al., 2000). This is most easily visualized by analysis ofCOPII clustering adjacent to the Golgi complex in the perinuclearregion. Low-level expression of TBC1D20 (Fig. 7A) or expressionof dominant-negative Rab1 (Fig. 5B) resulted in a loss of perinuclearCOPII staining, leaving only a scattered peripheral pool ofCOPII. This effect was not seen when the catalytically inactiveR105A mutant of TBC1D20 (Fig. 7A) or dominant active Rab1 wereused, indicating that this effect is likely to be due to inactivationof endogenous Rab1. TBC1D20, therefore, appears to interferewith tethering of COPII vesicles by the Rab1-p115 pathway. However,since depletion of p115 does not mimic the effects of Rab1 inactivation,defective tethering cannot explain the observed requirementfor active Rab1 in cargo exit from the ER (Fig. 6D).

View larger version (47K):
[in this window]
[in a new window]

Fig. 7. Loss of perinuclear ERES in TBC1D20-expressing cells. (A) HeLa cells transfected with GFP-tagged wild-type TBC1D20 or a catalytically inactive R105A point mutant (green) were fixed after 22 hours and then stained with antibodies to the COPII subunit Sec31 (red). DNA was stained with DAPI (blue). The clustering of COPII structures in the perinuclear region, or TBC1D20-induced scattering was counted and the results are show in the bar graph below (100 cells per experiments, n=2). Bar, 10 µm, in all panels. (B) FRAP was performed on cells expressing Myc-TBC1D20 and Venus-Sec16 using a Leica TCS SP3 AOBS scanning confocal microscope with a pinhole size of 2 Airy units, eightfold line averaging, at 1 frame per second, and region-of-interest bleaching with 10 iterations of the 514 nm laser at 100% AOTF power. Cells used for photobleaching were confirmed to express Myc-TBC1D20 by subsequent immunofluorescence; 95% of all cell transfected with Venus-Sec16 were found to be transfected with Myc-TBC1D20. Images taken from the time points indicated were quantified using ImageJ. Plot of the average intensity of individual structures over time, error bars indicate the standard deviation (five cells per experiment, n=3).

One possibility is that Rab1 inactivation is interfering withthe assembly of the COPII vesicle coat, and thus trapping cargoin the ER. However, this is unlikely to be the case for tworeasons. First, TBC1D20 shows no activity towards Sar1 in vitro.Second, fluorescence recovery after photobleaching (FRAP) studies,using previously published methods (Watson et al., 2006

), indicatethat COPII coat turnover is the same in both control and TBC1D20-expressingcells (Fig. 7B).

The other possibility is that cargo selection is defective inTBC1D20-expressing cells. To further investigate this, the behaviourof ERGIC53 and p24, two proteins that cycle between the ER andthe ERGIC, was investigated. In cells expressing wild-type TBC1D20both endogenous ERGIC53 and GFP-tagged p24 were present in largepunctate structures (Fig. 8A). Significantly, p24 was absentfrom the punctate scattered COPII-positive structures seen inwild-type TBC1D20-expressing cells (Fig. 8B, enlargement). Thisis in contrast to the distribution of p24 and ERGIC53 in cellsexpressing catalytically inactive TBC1D20, or in untransfectedcells, where they are present in the perinuclear ERGIC and smallpunctate COPII-positives structures in the cell periphery (Fig. 8B).Rab1 inactivation by TBC1D20 therefore causes a defect in COPIIvesicle tethering, and a transport defect where cargo moleculesare no longer recruited into COPII positive structures, despitenormal COPII turnover.

View larger version (91K):
[in this window]
[in a new window]

Fig. 8. Loss of recycling ERGIC markers from ERES in TBC1D20-expressing cells. HeLa cells expressing GFP-tagged p24 (green) were transfected with wild-type (WT) or catalytically inactive (RA) Myc-tagged TBC1D20 (blue). After 18 hours cells were fixed and then stained with antibodies to either (A) the ERGIC marker ERGIC53 or (B) the Sec31 subunit of the COPII vesicle coat (red), the Myc epitope (blue). GFP was visualized directly (green). The enlargements correspond to 10x10 µm regions of the merged images. Bar indicates 10 µm in all panels.

TBC1D20 is an ER-associated Rab1 GAP
The results described so far indicate that TBC1D20 may controlthe activity of Rab1, and that interfering with this regulationprevents the exit of secretory cargo molecules from the ER.This raises the question of where TBC1D20 acts, and this wastherefore investigated further (Fig. 9). First the topologyof TBC1D20 was examined using a combination of carbonate extractionand proteinase K digestion experiments (Fig. 9A). These showedthat TBC1D20 behaves as an integral membrane protein in carbonateextraction, and is accessible to proteinase K. This was similarto the type II transmembrane golgin, golgin84. This suggeststhat TBC1D20 is a type II membrane protein with the TBC domainoriented towards the cytosol. As expected, mapping experimentsshowed that the first 317 amino acids of TBC1D20 containingthe TBC domain localize to the cytosol and cause disruptionof the Golgi complex, and that deletions into this region resultin a loss of this activity (Fig. 9B). These effects on the Golgimake it difficult to assess where TBC1D20 is localized, andthe catalytically inactive form was therefore used for targetingexperiments (Fig. 9C). This approach showed that full-lengthTBC1D20 was found to target to the ER and nuclear envelope,and that this targeting information was contained in amino acids336-403 (Fig. 9C). Further deletions of the C terminus, aminoacids 364-403, resulted in a slightly altered distribution tothe nuclear envelope and Golgi complex, and a loss of the reticularER staining pattern (Fig. 9C). Inspection of the TBC1D20 sequencerevealed that it has a hydrophobic stretch from 364 to 387 containedwithin the putative ER-targeting region that could form a membrane-anchoringsequence or transmembrane domain (Fig. 9D). These observationsfit with older findings that Ypt1 (yeast Rab1) GAP activityis found in the particulate membrane fraction (Jena et al.,1992

View larger version (52K):
[in this window]
[in a new window]

Fig. 9. TBC1D20 is an ER membrane protein. (A) A schematic showing the proposed topology of TBC1D20. Carbonate extraction experiments were performed as described in the Materials and Methods to investigate the membrane association of TBC1D20. Golgin84 and GM130 were taken as representative integral and peripheral membrane proteins, respectively. The topology of TBC1D20 was investigated using proteinase K (PK) digestion experiments in the presence or absence of Triton X-100 (TX). TGN46 and Golgin84 were taken as controls for proteins with large lumenal or cytosolic domains, respectively. (B) HeLa cells transfected with Myc-tagged TBC1D20 and a series of C-terminal deletions were fixed after 24 hours, and then stained with antibodies to GM130 (green) and the Myc epitope (red). The reticular or cytosolic nature of TBC1D20 constructs is more clearly visible in the enlargements. (C) HeLa cells expressing the GFP-tagged R105A mutant of TBC1D20, or a series of N-terminal deletions were fixed after 24 hours, and then stained with antibodies to GM130 (red). TBC1D20 constructs were visualized by GFP fluorescence (green). DNA was stained with DAPI (blue). Bars, 10 µm in all panels. (D) A summary of the TBC1D20 constructs used and results obtained in B and C. Activity refers to the ability to cause the `loss of Golgi' phenotype; localization of the different constructs is scored as ER, including nuclear envelope, and Golgi. The TBC domain is marked in red, and the putative transmembrane domain in green.

Reticulon interacts with and modulates TBC1D20 function
To identify partners for TBC1D20 that could explain its localizationto the ER, or possibly act as regulators of its activity, atwo-hybrid screen was performed using full-length TBC1D20 asa bait. This screen identified the C-terminal region of reticulon1 variant 2 (reticulon) as an interaction partner of TBC1D20(Fig. 10A; A.K.H. and F.A.B., unpublished). Mapping experimentsrevealed that the minimal region of TBC1D20 able to interactwith reticulon was the C-terminal fragment from amino acids336-403 that shows the same ER targeting as full-length TBC1D20(Fig. 10A). However, the shorter fragment from amino acids 364-403showing nuclear envelope and Golgi targeting, could not interactwith reticulon. These results could be confirmed at the proteinlevel using immune precipitation, where full-length TBC1D20,irrespective of its catalytic activity, was found to interactwith reticulon (Fig. 10A). The first 337 amino acids of TBC1D20,lacking the ER-targeting region did not show any significantbinding to reticulon under the same conditions (Fig. 10A). Finally,reticulon, like other family members, was found to localizepredominantly to the ER (Fig. 10B). TBC1D20 therefore containsa specific ER-targeting motif that interacts with a known ERprotein. Reticulon is particularly interesting in this regard,since reticulons have previously been shown to be excluded fromthe nuclear envelope and to play a role in the organizationof the tubuloreticular ER (Voeltz et al., 2006

View larger version (56K):
[in this window]
[in a new window]

Fig. 10. Reticulon interacts with and modulates TBC1D20 function at the ER. (A) A schematic of reticulon 1 variant 2 (reticulon 1v2) showing the two hydrophobic regions (HR), which by analogy with other reticulons may form transmembrane or membrane anchoring sequences (Voeltz et al., 2006

). The minimal binding fragment identified by yeast two-hybrid (Y2H) screening is shown in blue. Directed Y2H analysis was performed using reticulon 1v2 as the prey and full-length TBC1D20 and the various deletion constructs indicated. All combinations grow on non-selective media (–LW), whereas only a subset can grow on the selective media (QDO). GFP-immunoprecipitations were performed from HeLa S3 cells cotransfected with Myc-tagged reticulon, and the GFP-tagged TBC1D20 constructs indicated, using a published method (Voeltz et al., 2006

). The immunoprecipitates were blotted with GFP and Myc antibodies to detect TBC1D20 and reticulon, respectively. (B) HeLa cells transfected with reticulon 1v2 (reticulon; green) were fixed after 24 hours, and then stained with antibodies to calnexin or GM130 (red). (C,D) HeLa cells expressing Myc-tagged wild-type, R105A catalytically inactive mutant TBC1D20, or the minimal TBC domain (amino acids 1-317) in the absence or presence of GFP-tagged reticulon 1v2 (reticulon) were fixed, and then stained for GM130 and antibodies to the Myc epitope. In some panels DNA was stained with DAPI. Bars, 10 µm. (D) Quantification of the cells showing intact Golgi, the `loss of Golgi' phenotype, or Golgi fragmentation in cells expressing TBC1D20 constructs and reticulon as indicated. (E) Western blots were performed to control for the expression levels of TBC1D20 and reticulon, with tubulin as a loading control.

These results suggested that reticulon might be important forcontrolling TBC1D20 function. As shown previously, wild-typeTBC1D20 causes the apparent loss of GM130 when expressed alone(Fig. 10C,D). This effect can be antagonized by the expressionof reticulon, judged by the recovery of GM130 staining intoa fragmented perinuclear ribbon structure in cells expressingboth TBC1D20 and reticulon (Fig. 10C,D). When co-expressed witha catalytically inactive form of TBC1D20, reticulon and TBC1D20were both found in the ER, and GM130 showed a normal Golgi staining(Fig. 10C). If this effect of reticulon is specific, it shouldrequire the ER-targeting properties of TBC1D20. As predicted,amino acids 1-337, a TBC-domain containing fragment of TBC1D20capable of causing Golgi fragmentation but lacking the ER-targetingdomain, was resistant to the effects of reticulon (Fig. 10C,D).Importantly, the effect of reticulon was not mediated throughalterations in the expression levels of the various TBC1D20constructs tested, since these were equal under all conditions(Fig. 10E). Together these finding support the idea that reticulonshelp to functionally compartmentalize the ER, in this case bycontrolling the activity of TBC1D20, the GAP for Rab1.

Discussion

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

We have identified functions at the Golgi complex for a subsetof the large family of TBC domain proteins encoded in the humangenome. One of the most interesting of these is TBC1D20, whichis unique amongst the TBC-domain proteins in that it possessesa predicted transmembrane anchor that targets it to the ER andwhen overexpressed causes a complete disruption of the Golgicomplex. TBC1D20 shows specific GAP activity towards Rab1 andRab2, unlike the other GAPs tested. This agrees with previousstudies on budding yeast Gyp8, the homologue of human TBC1D20,which was previously reported to have Ypt1 GAP activity, andto suppress the cold-sensitive defect in strains expressingthe Ypt1 Q67L activated mutant (De Antoni et al., 2002). Furtherinvestigation revealed that TBC1D20 blocks protein transportat the level of ER exit, by inactivating Rab1. As expected,this phenotype was also observed in cells depleted of Rab1.This is consistent with older observations that extraction ofRab1 using the Rab chaperone GDI prevents the ER exit of VSVG (Peter et al., 1994). The common factor in these situationsis that the activated GTP form of Rab1 is absent. Depletionof the Rab1 effector p115 did not cause the same effect, andas expected secretory cargo could exit the ER, but accumulatedin a punctate cluster adjacent to the nucleus and did not reachthe plasma membrane. Importantly, p115 depletion is not expectedto alter the amount of activated Rab1, suggesting this is thedifference between TBC1D20 expression and Rab1 depletion. Thesefindings suggested that TBC1D20 and Rab1 have p115-independentfunctions in controlling the exit of secretory cargo and Golgienzymes from the ER. Interestingly, a similar role has alreadybeen proposed for Ypt1 in budding yeast, which has been shownto play a role in the sorting of some cargo molecules exitingthe ER (Morsomme and Riezman, 2002). Since neither TBC1D20 inhuman cells nor Gyp8 in yeast is essential for secretion, regulationof GTP hydrolysis by GAPs appears not to be critical for Rab1or Ypt1 function under laboratory conditions (De Antoni et al.,2002; Richardson et al., 1998). However, this may be a simplificationof what is required to maintain secretory pathway function undermore physiological conditions.

Limiting Rab1 activity under stress conditions
A recent study on the mechanism of ${alpha}$ -synuclein toxicity showsthat this creates a stress situation resulting in a block ofER to Golgi trafficking (Cooper et al., 2006). This genomicscreen in yeast revealed Ypt1 but not other Rabs can suppress ${alpha}$ -synuclein toxicity and recover ER to Golgi trafficking, andthat the TBC1D20 homologue Gyp8 significantly enhanced ${alpha}$ -synucleintoxicity (Cooper et al., 2006). Interestingly, COPII vesiclecomponents and the Ypt1 effector Uso1 were not recovered, suggestingthat general enhancement of COPII vesicle formation and tetheringis not the mechanism by which Ypt1 is acting. The explanationthat we favour is that the activity of Ypt1, and Rab1, becomeslimiting for the exit of secretory proteins from the ER understress conditions, and this may be mediated through the actionof the Gyp8/TBC1D20 family of Rab GAPs.

Does reticulon restrict TBC1D20 to subdomains of the ER?
Recent work has uncovered a role for the reticulon family oftransmembrane proteins in the organization and shaping of theER, and the regulation of ER to Golgi transport (De Craene etal., 2006; Voeltz et al., 2006; Wakana et al., 2005). It istherefore interesting that the ER targeting region of TBC1D20interacts with at least one member of the reticulon family,and that this interaction exerts a negative effect on the abilityof TBC1D20 to disrupt the Golgi complex. These findings raisethe question of why is ER exit defective in cells where Rab1has been inactivated? One possible reason is that it may beimportant to couple the sorting of cargo and Rab1 into COPIIvesicles to ensure that they will recruit the correct tetheringfactors and therefore dock with the correct destination. HowRab1 could exert such effects is less clear, and will requirefurther investigation of its interaction partners, for examplethe TRAPP Rab1 GEF complex (Barrowman et al., 2000; Jones etal., 2000; Wang et al., 2000), and in mammalian cells the MICALfamily of proteins (Weide et al., 2003). Interestingly, TRAPPhas recently been shown to bind the COPII coat and may thereforebe recruited to ER exit sites as COPII vesicles form (Cai etal., 2007; Yu et al., 2006). Thus, TRAPP might provide a meansto ensure loading of Rab1 into the vesicle as it forms. A secondexplanation may relate to the proposed function of reticulonsin the compartmentalization of the ER (De Craene et al., 2006;Voeltz et al., 2006), and the fact that vesicle formation fromthe ER is a highly controlled process restricted to specificER exit sites. It is therefore conceivable that reticulon togetherwith TBC1D20 may be important for defining these sites, or perhapsrestricting them to subdomains of the ER.

Rab1 and Golgi biogenesis
One striking aspect of TBC1D20 expression is that unlike anyof the other 38 Rab GAPs tested, it causes the apparent lossof cis-, medial and trans-Golgi markers. This effect is notsimply due to blocking vesicle trafficking, since treatmentsthat do this, such as the GTP-restricted form of Sar1, BFA ordepletion of the vesicle tether p115, block ER to Golgi traffic,yet only cause partial fragmentation of the Golgi complex. Asdiscussed, this may be due to the fact that these treatmentswill not directly alter the levels of activated Rab1, whereasTBC1D20 expression will. Why then, should blocking Rab1 functionat the ER cause such extreme changes in Golgi structure?

Although debated for many years, most recent findings supportthe view that the Golgi complex is not formed of static cisternaebut rather that it is made up of highly dynamic and continuouslymaturing cisternae that receive and exchange material throughvesicle trafficking pathways (Bonfanti et al., 1998; Losev etal., 2006; Matsuura-Tokita et al., 2006; Mironov et al., 1997).Exactly how new Golgi cisternae form is equally hotly debated,and under some conditions Golgi may form by division of pre-existingstructures (Pelletier et al., 2002; Shima et al., 1997). However,there is also good evidence that the Golgi can arise directlyfrom the ER (Bevis et al., 2002; Glick, 2002; Mironov et al.,2003), and that availability of cargo such as Golgi enzymesis a key factor in determining the size of the resulting Golgicisternae (Guo and Linstedt, 2006). Furthermore, the organizationof ERES and the COPII vesicle trafficking pathway is of keyimportance for normal Golgi biogenesis and function (Connerlyet al., 2005). Our findings that ER exit of secretory cargo,ERGIC markers such as p24 and Golgi enzymes is blocked in cellswhere Rab1 is inactivated may be significant in this context.Interestingly, these cargo molecules fail to accumulate at ERESeven though COPII turnover, as measured by FRAP experimentsappears normal. By interfering with the sorting of Golgi enzymesand directly preventing the formation of Golgi precursors, Rab1inactivation may therefore cause a much more serious defectin Golgi biogenesis than depleting individual tethering factorsor Golgi matrix proteins.

Yeast and mammalian Golgi – not so different after all
The results presented here suggest that despite its greatersize and morphological complexity the mammalian Golgi complexis more similar to its budding yeast counterpart in terms ofRab function than previously thought. In budding yeast, althoughadditional Rabs are needed for transport from the Golgi to thecell surface, Ypt1 appears to be the sole Rab required for ERto Golgi transport, and transport though the Golgi (Brennwaldand Novick, 1993). Surprisingly, the results presented herereveal a similar picture in mammalian cells. Rab1 depletion,inactivation by expression of TBC1D20, or expression of dominant-negativeRab1 all cause a block in ER to Golgi protein transport, andthe collapse of the Golgi. Inactivation of other Rabs by expressionof other TBC-domain proteins had no effect on secretion, despitethe fact that a number of these caused Golgi fragmentation.This might indicate that other Rabs functioning at the Golgiare redundant, or not required for general anterograde cargotransport. These ideas and others discussed here, provide manyavenues for further investigation.

Materials and Methods

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

Antibody reagents
Antibodies reagents were as follows: mouse anti-GM130, Sec31and EEA1 (Becton Dickinson, Heidelberg, Germany); sheep anti-TGN46(Serotec, Düsseldorf, Germany); sheep anti-GM130, p115and GRASP55 (Barr et al., 2001; Shorter et al., 1999). Donkeysecondary antibodies conjugated to HRP, AMCA, CY2 and CY3 wereobtained from Jackson ImmunoResearch Labs (West Grove, PA).

Molecular biology and protein expression
Human Rab GAPs were identified by searching the GenBank databaseusing the TBC-domain signature motifs defined by Goody and co-workers(Rak et al., 2000). The 38 human Rab GAPs identified by thismethod and expression constructs have been described previously(Fuchs et al., 2007). Yeast two-hybrid assays, protein expressionand purification were performed as described previously (Haaset al., 2005).

Cell culture and RNA interference
hTERT-RPE1 cells (Clontech Laboratories) were grown at 37°Cand 5% CO₂ in a 1:1 mixture of DMEM and HAMS F12 containing10% calf serum, 2.5 mM L-glutamine, and 1.2 g/l sodium bicarbonate.HeLa cells were cultured at 37°C and 5% CO₂ in DME containing10% FCS. HeLa or hTERT-RPE1 cells plated on glass coverslipsat a density of 50,000 cells/well of a 6-well plate were usedfor plasmid transfection and RNA interference. All siRNA duplexeswere obtained from Dharmacon Inc, Lafayette, CO and are describedin Table SI in supplementary material. Where multiple siRNAduplexes are indicated the same results were obtained with all.For western blotting, cells from three wells of the six-wellplate were washed in 2 ml PBS, then lysed in 70-80 µl50 mM Tris-HCl pH 7.4, 150 mM NaCl, 0.1% (wt/vol) Triton X-100.For each lane of a minigel 10 µg of the protein lysatewas loaded.

Cell fractionation and membrane topology
For fractionation experiments HeLa cells were grown on 15 cmdishes to 70% confluence. Cells were either transfected using15 µg of each plasmid DNA and left for 24 hours to expressthe protein of interest, or incubated for 30 minutes in growthmedium containing 5 µg/ml BFA. The cells were then harvestedand washed twice in ice cold PBS. The cell pellet was resuspendedin 1 ml of 25 mM Tris-HCl pH 7.4, 130 mM KCl, 5 mM MgCl₂ containinga protease inhibitor cocktail (Roche Diagnostics). Cells werethen broken open by passing them 40 times through a 27G needleusing a 1 ml syringe. Nuclei and cell debris were removed bycentrifugation for 5 minutes at 1000 g and 4°C. This post-nuclearsupernatant was split into two aliquots, one was kept on iceand represented to the total material. The other half was centrifugedfor 30 minutes at 100,000 g and 4°C. The supernatant, whichwas the soluble cytosolic fraction, was transferred to a freshtube. The pellet, which was the membrane fraction, was resuspendedin 100 µl sample buffer. Aliquots of the supernatant andtotal of each sample were precipitated by adding 0.5 µlof 10% (wt/vol) sodium deoxycholate and 30 µl of 100%(wt/vol) TCA. After 30 minutes incubation on ice, precipitatedprotein was collected by centrifugation at 20,000 g and 4°C.Pellets were washed with ice cold acetone, and then resuspendedin 100 µl of sample buffer.

For proteinase K digestion experiments, HeLa S3 cells from two70% confluent 15 cm dishes and one 10 cm dish transfected withGFP-tagged TBC1D20 constructs for 24 hours were washed twicein cold PBS, then scraped off the dishes, and pooled. The cellpellets were resuspended using six passes through a 21G needlein 50 mM Hepes pH 7.5, 200 mM sucrose, 1 mM MgCl₂, 1 mM EDTA,to give a final volume of 1 ml. This cell suspension was passedthough an EMBL cell cracker (European Molecular Biology Laboratories,Heidelberg, Germany) fitted with an 8.002 mm diameter ball.The broken cell suspension was centrifuged twice at 1000 g and4°C for 5 minutes to remove cell debris and leave a postnuclear supernatant. Proteinase K (New England Biolabs) wasincubated at 37°C for 30 minutes prior to use to inactivateany contaminating lipase activity. The post nuclear supernatantwas then adjusted to 10 mM CaCl₂, and 100 µl aliquotstreated with 2 µg proteinase K, 0.5% (vol/vol) TritonX-100, or both proteinase K and Triton X-100 for 30 minuteson ice. To stop the reaction, a half volume of 100% (wt/vol)TCA was added, samples were then vortexed and incubated on icefor 30 minutes. Proteins were recovered by centrifugation at20,000 g for 15 minutes, the pellets washed in 1 ml of –20°Cacetone, resuspended in 100 µl of sample buffer, and 20µl analysed by western blotting.

For carbonate extraction experiments, 100 µl aliquotsof the post nuclear supernatant was centrifuged at 100,000 gfor 30 minutes at 4°C to generate a membrane pellet. Thepellet was resuspended in 100 mM Na₂CO₃ and incubated on icefor 30 minutes. To recover the membrane the sample was centrifugedat 100,000 g for 30 minutes at 4°C. The supernatant wasprecipitated using 25% (wt/vol) TCA, and equal amounts of thetotal, carbonate-extracted supernatant and membrane pellet fractionsanalysed by western blotting.

Protein transport assays and microscopy
VSV G ts045 protein transport assays were carried out usingan adaptation of a published protocol. HeLa cells plated onglass coverslips were treated with specific RNA duplexes for56 hours at 37°C, then transfected with a plasmid encodinggreen fluorescent protein (GFP)-tagged VSV G protein for 2 hoursat 37°C, then for 12 hours at 39.5°C. The cells werethen incubated at 4°C to promote VSV G protein folding,and afterwards the growth medium was replaced with pre-warmedmedium at 31.5°C. After the required chase period cellswere fixed with 3% (wt/vol) paraformaldehyde in PBS. Cell surfaceVSV G was detected with a monoclonal antibody to the VSV G lumenaldomain and a donkey anti-mouse secondary coupled to CY3, andtotal VSV G by GFP fluorescence. The ratio of surface to totalmeasured fluorescence was used to calculate the extent of VSVG transport. Shiga toxin transport assays were performed usinga published method (Fuchs et al., 2007). Cells were processedfor immunofluorescence and images collected as described previously(Fuchs et al., 2007).

Footnotes

Supplementary material available online at http://jcs.biologists.org/cgi/content/full/120/17/2997/DC1

^* Present address: Beatson Institute of Cancer Research, Glasgow,UK

References

Top
Summary
Introduction
Results
Discussion
Materials and Methods
References

Ahmadian, M. R., Stege, P., Scheffzek, K. and Wittinghofer, A. (1997). Confirmation of the arginine-finger hypothesis for the GAP-stimulated GTP-hydrolysis reaction of Ras. Nat. Struct. Biol. 4, 686-689.[CrossRef][Medline]

Albert, S. and Gallwitz, D. (1999). Two new members of a family of Ypt/Rab GTPase activating proteins. Promiscuity of substrate recognition. J. Biol. Chem. 274, 33186-33189.[Abstract/Free Full Text]

Albert, S., Will, E. and Gallwitz, D. (1999). Identification of the catalytic domains and their functionally critical arginine residues of two yeast GTPase-activating proteins specific for Ypt/Rab transport GTPases. EMBO J. 18, 5216-5225.[CrossRef][Medline]

Allan, B. B., Moyer, B. D. and Balch, W. E. (2000). Rab1 recruitment of p115 into a cis-SNARE complex: programming budding COPII vesicles for fusion. Science 289, 444-448.[Abstract/Free Full Text]

Alvarez, C., Fujita, H., Hubbard, A. and Sztul, E. (1999). ER to Golgi transport: requirement for p115 at a pre-Golgi VTC stage. J. Cell Biol. 147, 1205-1222.[Abstract/Free Full Text]

Bannykh, S. I., Rowe, T. and Balch, W. E. (1996). The organization of endoplasmic reticulum export complexes. J. Cell Biol. 135, 19-35.[Abstract/Free Full Text]

Barr, F. A., Preisinger, C., Kopajtich, R. and Korner, R. (2001). Golgi matrix proteins interact with p24 cargo receptors and aid their efficient retention in the Golgi apparatus. J. Cell Biol. 155, 885-891.[Abstract/Free Full Text]

Barrowman, J., Sacher, M. and Ferro-Novick, S. (2000). TRAPP stably associates with the Golgi and is required for vesicle docking. EMBO J. 19, 862-869.[CrossRef][Medline]

Bevis, B. J., Hammond, A. T., Reinke, C. A. and Glick, B. S. (2002). De novo formation of transitional ER sites and Golgi structures in Pichia pastoris. Nat. Cell Biol. 4, 750-756.[CrossRef][Medline]

Bonfanti, L., Mironov, A. A., Jr, Martinez-Menarguez, J. A., Martella, O., Fusella, A., Baldassarre, M., Buccione, R., Geuze, H. J., Mironov, A. A. and Luini, A. (1998). Procollagen traverses the Golgi stack without leaving the lumen of cisternae: evidence for cisternal maturation. Cell 95, 993-1003.[CrossRef][Medline]

Bonifacino, J. S. and Glick, B. S. (2004). The mechanisms of vesicle budding and fusion. Cell 116, 153-166.[CrossRef][Medline]

Brennwald, P. and Novick, P. (1993). Interactions of three domains distinguishing the Ras-related GTP-binding proteins Ypt1 and Sec4. Nature 362, 560-563.[CrossRef][Medline]

Cai, H., Yu, S., Menon, S., Cai, Y., Lazarova, D., Fu, C., Reinisch, K., Hay, J. C. and Ferro-Novick, S. (2007). TRAPPI tethers COPII vesicles by binding the coat subunit Sec23. Nature 445, 941-944.[CrossRef][Medline]

Cao, X., Ballew, N. and Barlowe, C. (1998). Initial docking of ER-derived vesicles requires Uso1p and Ypt1p but is independent of SNARE proteins. EMBO J. 17, 2156-2165.[CrossRef][Medline]

Connerly, P. L., Esaki, M., Montegna, E. A., Strongin, D. E., Levi, S., Soderholm, J. and Glick, B. S. (2005). Sec16 is a determinant of transitional ER organization. Curr. Biol. 15, 1439-1447.[CrossRef][Medline]

Cooper, A. A., Gitler, A. D., Cashikar, A., Haynes, C. M., Hill, K. J., Bhullar, B., Liu, K., Xu, K., Strathearn, K. E., Liu, F. et al. (2006). Alpha-synuclein blocks ER-Golgi traffic and Rab1 rescues neuron loss in Parkinson's models. Science 313, 324-328.[Abstract/Free Full Text]

De Antoni, A., Schmitzova, J., Trepte, H. H., Gallwitz, D. and Albert, S. (2002). Significance of GTP hydrolysis in Ypt1p-regulated endoplasmic reticulum to Golgi transport revealed by the analysis of two novel Ypt1-GAPs. J. Biol. Chem. 277, 41023-41031.[Abstract/Free Full Text]

De Craene, J. O., Coleman, J., Estrada de Martin, P., Pypaert, M., Anderson, S., Yates, J. R., 3rd, Ferro-Novick, S. and Novick, P. (2006). Rtn1p is involved in structuring the cortical endoplasmic reticulum. Mol. Biol. Cell 17, 3009-3020.[Abstract/Free Full Text]

Fuchs, E., Haas, A. K., Spooner, R. A., Yoshimura, S., Lord, J. M. and Barr, F. A. (2007). Specific Rab GTPase-activating proteins define the Shiga toxin and epidermal growth factor uptake pathways. J. Cell Biol. 177, 1133-1143.[Abstract/Free Full Text]

Glick, B. S. (2002). Can the Golgi form de novo? Nat. Rev. Mol. Cell Biol. 3, 615-619.[CrossRef][Medline]

Guo, Y. and Linstedt, A. D. (2006). COPII-Golgi protein interactions regulate COPII coat assembly and Golgi size. J. Cell Biol. 174, 53-63.[Abstract/Free Full Text]

Haas, A. K., Fuchs, E., Kopajtich, R. and Barr, F. A. (2005). A GTPase-activating protein controls Rab5 function in endocytic trafficking. Nat. Cell Biol. 7, 887-893.[CrossRef][Medline]

Jena, B. P., Brennwald, P., Garrett, M. D., Novick, P. and Jamieson, J. D. (1992). Distinct and specific GAP activities in rat pancreas act on the yeast GTP-binding proteins Ypt1 and Sec4. FEBS Lett. 309, 5-9.[CrossRef][Medline]

Jones, S., Newman, C., Liu, F. and Segev, N. (2000). The TRAPP complex is a nucleotide exchanger for Ypt1 and Ypt31/32. Mol. Biol. Cell 11, 4403-4411.[Abstract/Free Full Text]

Losev, E., Reinke, C. A., Jellen, J., Strongin, D. E., Bevis, B. J. and Glick, B. S. (2006). Golgi maturation visualized in living yeast. Nature 441, 1002-1006.[CrossRef][Medline]

Matsuura-Tokita, K., Takeuchi, M., Ichihara, A., Mikuriya, K. and Nakano, A. (2006). Live imaging of yeast Golgi cisternal maturation. Nature 441, 1007-1010.[CrossRef][Medline]

Mironov, A. A., Weidman, P. and Luini, A. (1997). Variations on the intracellular transport theme: maturing cisternae and trafficking tubules. J. Cell Biol. 138, 481-484.[Free Full Text]

Mironov, A. A., Mironov, A. A., Jr, Beznoussenko, G. V., Trucco, A., Lupetti, P., Smith, J. D., Geerts, W. J., Koster, A. J., Burger, K. N., Martone, M. E. et al. (2003). ER-to-Golgi carriers arise through direct en bloc protrusion and multistage maturation of specialized ER exit domains. Dev. Cell 5, 583-594.[CrossRef][Medline]

Morsomme, P. and Riezman, H. (2002). The Rab GTPase Ypt1p and tethering factors couple protein sorting at the ER to vesicle targeting to the Golgi apparatus. Dev. Cell 2, 307-317.[CrossRef][Medline]

Munro, S. (2002). Organelle identity and the targeting of peripheral membrane proteins. Curr. Opin. Cell Biol. 14, 506-514.[CrossRef][Medline]

Pan, X., Eathiraj, S., Munson, M. and Lambright, D. G. (2006). TBC-domain GAPs for Rab GTPases accelerate GTP hydrolysis by a dual-finger mechanism. Nature 442, 303-306.[CrossRef][Medline]

Pelletier, L., Stern, C. A., Pypaert, M., Sheff, D., Ngo, H. M., Roper, N., He, C. Y., Hu, K., Toomre, D., Coppens, I. et al. (2002). Golgi biogenesis in Toxoplasma gondii. Nature 418, 548-552.[CrossRef][Medline]

Peter, F., Nuoffer, C., Pind, S. N. and Balch, W. E. (1994). Guanine nucleotide dissociation inhibitor is essential for Rab1 function in budding from the endoplasmic reticulum and transport through the Golgi stack. J. Cell Biol. 126, 1393-1406.[Abstract/Free Full Text]

Pfeffer, S. R. (1999). Transport-vesicle targeting: tethers before SNAREs. Nat. Cell Biol. 1, E17-E22.[CrossRef][Medline]

Pfeffer, S. and Aivazian, D. (2004). Targeting Rab GTPases to distinct membrane compartments. Nat. Rev. Mol. Cell Biol. 5, 886-896.[CrossRef][Medline]

Puthenveedu, M. A., Bachert, C., Puri, S., Lanni, F. and Linstedt, A. D. (2006). GM130 and GRASP65-dependent lateral cisternal fusion allows uniform Golgi-enzyme distribution. Nat. Cell Biol. 8, 238-248.[CrossRef][Medline]

Rak, A., Fedorov, R., Alexandrov, K., Albert, S., Goody, R. S., Gallwitz, D. and Scheidig, A. J. (2000). Crystal structure of the GAP domain of Gyp1p: first insights into interaction with Ypt/Rab proteins. EMBO J. 19, 5105-5113.[CrossRef][Medline]

Richardson, C. J., Jones, S., Litt, R. J. and Segev, N. (1998). GTP hydrolysis is not important for Ypt1 GTPase function in vesicular transport. Mol. Cell. Biol. 18, 827-838.[Abstract/Free Full Text]

Sacher, M., Barrowman, J., Wang, W., Horecka, J., Zhang, Y., Pypaert, M. and Ferro-Novick, S. (2001). TRAPP I implicated in the specificity of tethering in ER-to-Golgi transport. Mol. Cell 7, 433-442.[CrossRef][Medline]

Segev, N. (1991). Mediation of the attachment or fusion step in vesicular transport by the GTP-binding Ypt1 protein. Science 252, 1553-1556.[Abstract/Free Full Text]

Shima, D. T., Haldar, K., Pepperkok, R., Watson, R. and Warren, G. (1997). Partitioning of the Golgi apparatus during mitosis in living HeLa cells. J. Cell Biol. 137, 1211-1228.[Abstract/Free Full Text]

Short, B., Preisinger, C., Korner, R., Kopajtich, R., Byron, O. and Barr, F. A. (2001). A GRASP55-rab2 effector complex linking Golgi structure to membrane traffic. J. Cell Biol. 155, 877-883.[Abstract/Free Full Text]

Short, B., Haas, A. and Barr, F. A. (2005). Golgins and GTPases, giving identity and structure to the Golgi apparatus. Biochim. Biophys. Acta 1744, 383-395.[Medline]

Shorter, J., Watson, R., Giannakou, M. E., Clarke, M., Warren, G. and Barr, F. A. (1999). GRASP55, a second mammalian GRASP protein involved in the stacking of Golgi cisternae in a cell-free system. EMBO J. 18, 4949-4960.