ADP-Ribosylation Factor/COPI-dependent Events at the Endoplasmic Reticulum-Golgi Interface Are Regulated by the Guanine Nucleotide Exchange Factor GBF1

Rafael García-Mata, Tomasz Szul, Cecilia Alvarez, and Elizabeth Sztul^*

Department of Cell Biology, University of Alabama at Birmingham, Birmingham, Alabama 35924

Submitted November 13, 2002; Revised February 7, 2003; Accepted March 4, 2003
Monitoring Editor: Juan Bonifacino

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

ADP-ribosylation factor (ARF) mediated recruitment of COPI tomembranes plays a central role in transport between the endoplasmicreticulum (ER) and the Golgi. The activation of ARFs is mediatedby guanine nucleotide exchange factors (GEFs). Although severalARF-GEFs have been identified, the transport steps in whichthey function are still poorly understood. Here we report that GBF1, a member of the Sec7-domain family of GEFs, is responsiblefor the regulation of COPI-mediated events at the ER-Golgiinterface. We show that GBF1 is essential for the formation,differentiation, and translocation of pre-Golgi intermediatesand for the maintenance of Golgi integrity. We also show thatthe formation of transport-competent ER-to-Golgi intermediates proceeds in two stages: first, a COPI-independent event leadsto the formation of an unstable compartment, which is rapidlyreabsorbed in the absence of GBF1 activity. Second, the associationof GBF1 with this compartment allows COPI recruitment and leadsto its maturation into transport intermediates. The recruitmentof GBF1 to this compartment is specifically inhibited by brefeldin A. Our findings imply that the continuous recruitment of GBF1to spatially differentiated membrane domains is required forsustained membrane remodeling that underlies membrane trafficand Golgi biogenesis.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Transport between the endoplasmic reticulum (ER) and the Golgiis mediated by transport intermediates generated by three recognizabletraffic stages: the formation of transport intermediates atthe ER, maturation and movement of such intermediates towardthe Golgi, and coalescence at the incoming cis-face of theGolgi. The differentiation of ER-Golgi transport intermediatesrequires the sequential action of two cytosolic coat complexes, COPII and COPI (Aridor et al., 1995; Rowe et al., 1996; Scaleset al., 1997). COPII recruitment is coupled to the differentiationof specialized ER subdomains called endoplasmic reticulum exitsites (ERESs) (Bannykh and Balch, 1997). Protein export fromthe ER seems to occur exclusively from ERESs. Morphologically,ERESs are characterized by COPII-coated tubular ER elements adjacent to a collection of vesicular tubular clusters (VTCs)coated with COPI (Bannykh et al., 1996). VTCs represent asubsequent stage of transport, and one ERES generates multipleVTCs during its existence (Lippincott-Schwartz et al., 1998).Association of COPI with ERESs occurs after these membranes have been first differentiated by the activity of COPII (Roweet al., 1996).

COPI binding seems to be required at multiple stages of ER-Golgitransport. Experimental evidence indicates that the initialrequirement for COPI association is to differentiate VTCs adjacentto ERES. Specifically, when COPI binding to membranes is inhibited,cargo proteins and resident Golgi proteins fail to exit theER and be incorporated into ERESs (Dascher and Balch, 1994; Lippincott-Schwartz et al., 1989; Peters et al., 1995; Roweet al., 1996). Additional COPI function is required after VTCsleave the ERES region and initiate their microtubule-dependentmovement toward the Golgi (Lippincott-Schwartz et al., 1998).

Recent findings indicate that the association of COPI with membranesis likely to result from rapid cycles of COPI binding and dissociation (Presley et al., 2002). The transient nature of COPI associationimplies that COPI must be continuously recruited from the cytosoland suggests that the machinery that recruits COPI must bepresent on all COPI-coated membranes. COPI is recruited tomembranes by a small GTPase of the ARF family (Rothman andWieland, 1996). ARFs cycle between a GDP-bound inactive stateand a GTP-bound active state. Inactive ARF is largely cytosolic,and ARF activation promotes its recruitment to a membrane andallows it to interact with membrane associated downstream effectors(Chavrier and Goud, 1999). ARF binds GDP with high affinityand to become active must interact with a guanine nucleotideexchange factor that stimulates the exchange of GDP for GTP(Chavrier and Goud, 1999; Jackson and Casanova, 2000).

ARF-GEFs share a highly conserved 200 amino acid region, termedthe Sec7 domain, which is sufficient to catalyze the exchangeof GDP for GTP on ARFs in vitro (Jackson and Casanova, 2000).ARF-GEFs are subdivided into two major classes based on sizeand sequence similarities (Jackson and Casanova, 2000). Thesmall GEFs (<100 kDa) have no orthologs in Saccharomycescerevisiae, suggesting a function specific for higher eukaryotes.The large (>100-kDa) ARF-GEFs are conserved from yeast tohumans, suggesting an evolutionary conserved role. Large GEFsinclude the yeast Gea1p, Gea2p, and Sec7p and their mammalianorthologs GBF1 (Gea1/2), BIG-1, and BIG-2 (Sec7). All largeyeast GEFs seem to function at the ER-Golgi system, becausevarious temperature-sensitive alleles of GEA1, GEA2, and SEC7 have defects in ER-Golgi and intra-Golgi transport (Franzusoffet al., 1992; Peyroche et al., 1996, 2001; Spang et al.,2001). In mammals, BIG1 and 2 have been associated with post-Golgitransport (Shinotsuka et al., 2002a,b; Zhao et al., 2002b). In contrast, the function of GBF1 is still poorly understood.The finding that GBF1 overexpression prevents brefeldin A (BFA)-inducedGolgi disassembly and that it cycles between the Golgi andthe ER is consistent with its possible function in ER-Golgitraffic (Claude et al., 1999; Kawamoto et al., 2002; Zhao et al., 2002b).

Herein, we report that GBF1 regulates ARF/COPI dynamics at theER-Golgi interface and acts by promoting the recruitment ofCOPI to an unstable post-ERES compartment. GBF1 is essentialfor transport between the ER and the Golgi and for the maintenanceof Golgi integrity.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Antibodies and Cell Reagents
BFA was from Sigma-Aldrich (St. Louis, MO). Polyclonal antibodiesagainst p115 and GM130 were described previously (Nelson etal., 1998). Rabbit polyclonal anti-GBF1 antibodies were generatedby immunization with purified his-tagged construct encodingthe last 107 amino acids of mouse GBF1 and affinity purifiedas described previously (Nelson et al., 1998). Anti-giantinand anti–ERGIC-53 monoclonal antibodies were providedby Dr. Hans-Peter Hauri (University of Basel, Basel, Switzerland).Polyclonal anti-Mann II antibodies were provided by Dr. Marilyn Farquhar (University of California, San Diego, La Jolla, CA).Polyclonal anti-Sec31 antibodies were a kind gift from Dr.Wanjin Hong (Institute of Molecular Biology, Singapore). Thefollowing commercially available antibodies were used: monoclonalanti-myc (Invitrogen, Carlsbad, CA), polyclonal anti-his andmonoclonal anti-HA (Santa Cruz Biotechnology, Santa Cruz, CA),monoclonal anti-p115 and anti-GM130 (Transduction Laboratories,Lexington, KY), polyclonal anti- ${beta}$ -COP (Oncogene Science, Cambridge,MA); polyclonal anti-HA (Zymed Laboratories, South San Francisco,CA). Secondary antibodies conjugated with Texas Red-X, OregonGreen, or Alexa385 were from Molecular Probes (Eugene, OR).

DNA Constructs
A partial human GBF1 cDNA (KIAA0248) was obtained from The KazusaDNA Research Institute (Chiba, Japan). KIAA0248 is 5634 basepairs and lacks 0.5 kb of open reading frame. The missing fragmentwas amplified from a Human lung cDNA library (kindly providedby Dr. Cary Wu, University of Alabama at Birmingham, Birmingham,AL). The polymerase chain reaction product was then subclonedinto the KIAA0248 clone by using the internal EcoRI site at base 1124 and an engineered external XhoI site.

To generate GBFmyc, wtGBF1 was amplified by polymerase chainreaction and subcloned into pcDNA4.0/TO/myc-his (Invitrogen).E794K was generated by a single nucleotide mutation with theQuickChangeXL mutagenesis kit according to manufacturer's instructions(Stratagene, La Jolla, CA). E794K-green fluorescent protein(GFP) was generated by subcloning E794K into pEGFP-C2 (BD BiosciencesClontech, Palo Alto, CA). All constructs were verified by sequencingat the University of Alabama at Birmingham Sequencing Facility.

VSVG ts045-GFP and p58-GFP were kind gifts from Dr. Jennifer Lippincott-Schwartz (National Institutes of Health, Bethesda,MD). ARF1-T31N was a gift from Dr. Julie Donaldson (NationalInstitutes of Health). GFP-GalTase was kindly provided by Dr.Brian Storrie (Virginia Tech, Blacksburg, VA).

Analysis of tsO45 VSV-G Transport
HeLa cells grown on coverslips and transfected with VSV-G-GFP(ts045). Cells were then incubated at 40°C for 16 h toaccumulate the misfolded G protein in the ER. Transport ofG protein was initiated by incubating the cells at 32°C.Cells were fixed at different times and processed for immunofluorescence.

Immunofluorescence Microscopy
Cells grown on coverslips were washed in phosphate-bufferedsaline (PBS), fixed in 3% paraformaldehyde for 10 min, andquenched with 10 mM ammonium chloride. Cells were permeabilizedwith 0.1% Triton X-100 in PBS. The coverslips were then washedwith PBS and blocked in PBS, 2.5% goat serum, 0.2% Tween 20for 5 min followed by blocking in PBS, 0.4% fish skin gelatin,and 0.2% Tween 20. Cells were incubated with primary antibody1 h at room temperature. Coverslips were washed with PBS, 0.2%Tween 20 and incubated with secondary antibodies for 45 min.Coverslips were washed as described above and mounted on slidesin 9:1 glycerol/PBS with 0.1% p-phenylenediamine.

Quantification of Colocalization
Double-labeled images were acquired and analyzed for signaloverlap. Using Adobe Photoshop 6.0, structures were individualizedby drawing a rectangle around it and the percentage of colocalizationwas calculated. A structure is defined by a signal greaterthan 50 (0–255 range) and an area ≥4 pixels² (0.16²µm in the 50x objective).

Time-Lapse Imaging
HeLa cells grown on glass coverslips were sealed into a siliconrubber chamber placed on a glass slide and containing bufferedmedium with 25 mM HEPES, pH 7.5. Images were acquired in anOlympus IX70 inverted epifluorescence microscope, equippedwith a 40x, 1.35 numerical aperture objective and a cooledcharge-coupled device (Photometrics, Tucson, AZ) for 12-bitdetection. IpLab Spectrum software (Signal Analytics, Vienna,VA) was used to control image acquisition and manipulation.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

GBF1 Localizes to ERES and post-ERES Transport Intermediates
It has been previously shown that GBF1 localizes to the cis-side of the Golgi and that it cycles between the ER and the Golgi (Zhao et al., 2002b). In agreement, we found that GBF1 overlapsextensively with the cis-Golgi protein p115, but only partiallywith giantin and GM130, two proteins concentrated in the moremedial regions of the Golgi (Figure 1A) (Nakamura et al., 1995; Shima et al., 1997). In addition to the Golgi complex,GBF1 also localizes to peripheral punctate structures throughoutthe cells (Figure 1A, arrowheads). As expected for a GEF thatregulates ARF and COPI recruitment, the majority (80 ±6.8%) of GBF1-positive peripheral structures are also positivefor ${beta}$ -COP (Figure 1B, arrowheads), suggesting GBF1 is involvedin COPI recruitment at these sites. To determine the identityof the peripheral structures containing GBF1, we compared thedistribution of GBF1 to those of VTC or ERES markers. As shownin Figure 1C, GBF1 colocalizes significantly with ERGIC53(46.9 ± 6.6%) in peripheral sites shown previously torepresent VTCs (Hauri et al., 2000). Colocalization with ERGIC53is maximal at 15°C (74.0 ± 10.0%), in agreementwith previous results (Figure 1C) (Zhao et al., 2002b). Interestingly,a significant fraction of the peripheral GBF1 also localizesto ERES, as suggested by its overlap with an ERES marker, theCOPII subunit Sec31 (Figure 1D). Quantitative analysis showsthat 66 ± 1.5% of peripheral structures positive for GBF1 also contain Sec31, and another 13% of GBF1-containingstructures are located in proximity to Sec31-positive structures.

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Figure 1. GBF1 localizes to the cis-Golgi, to ERES, and to COPI-coated cargo-containing pre-Golgi intermediates. (A) HeLa cells were stained with antibodies to GBF1 and p115, GM130, or giantin. Insets show higher magnification of boxed areas. GBF1 colocalizes significantly with p115 but only partially with giantin and GM130 (B) GBFmyc-transfected cells were stained with anti-COPI ( ${beta}$ -COP) and anti-myc. Throughout this study we used either endogenous GBF1 or exogenously expressed myc-tagged GBF1, which behaves like wild type at low levels of expression; see supplemental material). (C) Cells were stained with anti-GBF1 and anti-ERGIC53 antibodies in control cells or in cells incubated at 15°C for 2 h. Arrowheads indicate peripheral structures that contain both GBF1 and ERGIC53. (D) GBFmyc-transfected cells were stained with anti-myc antibodies and antibodies to COPII (anti-Sec31). GBFmyc colocalizes significantly with Sec31 (arrowheads). (E) Cells were cotransfected with GBFmyc and VSV-G-GFP, incubated for 16 h at 42°C, and shifted to 32°C for 30 min. Cells were stained with anti-myc antibodies. GBFmyc is detected in pre-Golgi intermediates that contain VSV-G-GFP (arrowheads). The red signal in the merged panels correspond to GBF1 (in all figures). Bars, 10 µm.

Most of the peripheral GBF1-positive structures contain cargoen route from the ER to the Golgi. Cells were cotransfectedwith a myc-tagged GBF1 (GBFmyc) and VSV-G-GFP and incubatedat the restrictive temperature (40°C) for 16 h, and thenshifted to the permissive temperature for 10 min to allow transportof VSV-G protein out of the ER. As shown in Figure 1E, VSV-Gcan be detected in peripheral punctate sites containing GBF1,confirming that, like ${beta}$ -COP, GBF1 is present in peripheral VTCsen route to the Golgi.

It has been shown recently that ARF and COPI are continuouslybinding and dissociating from membranes, suggesting that anARF-GEF must be present in all the compartments in which COPIis present (Presley et al., 2002). Our data demonstrate thatat steady state, GBF1 localizes to the Golgi, to ERES, andto COPI-coated pre-Golgi intermediates containing cargo, suggestinga role for GBF1 in the regulation of ARF/COPI recruitment at these compartments.

Overexpression of Wild-Type GBF1 Arrests COPI-coated Transport Intermediates at a Late pre-Golgi Step
Overexpression of a GEF is likely to increase the concentrationof active GTP-ARF and to promote COPI recruitment to sitesat which the GEF acts. Analysis of various Golgi markers (GalT,giantin, MannII, and GM130) in cells expressing high levelsof GBFmyc shows that the Golgi redistribute from a single perinuclearGolgi complex to relatively large (1.23 ± 0.53-µm)structures found throughout the cell and concentrated aroundthe nucleus (Figure 2A). The severity of the disrupted phenotypeseems to correlate with the level of GBF1 expression. For example,the redistribution of GalT is much more severe in a cell expressinghigh levels of GBFmyc (Figure 2A, arrow) than in a cell expressingmedium levels (Figure 2A, arrowhead). The GBFmyc-induced peripheralstructures are highly enriched in ${beta}$ -COP, suggesting an increasedCOPI recruitment (Figure 2A). The distributions of all examinedmarker proteins, including ${beta}$ -COP, are analogous to that observedin cells expressing a constitutively active ARF1 mutant (ARF1-Q71L) (Dascher and Balch, 1994; Teal et al., 1994; Zhang et al.,1994; Peters et al., 1995).

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Figure 2. Overexpression of GBF1 arrests COPI-coated transport intermediates at a late pre-Golgi step. (A) HeLa cells were transfected with GBFmyc and stained with antibodies to giantin, MannII, GM130, and ${beta}$ -COP. In the GalT-GFP panel, cells were cotransfected with GBFmyc and GalT-GFP and stained with anti-myc antibodies. In cells expressing high levels of GBFmyc (asterisks), the Golgi redistributes to enlarged peripheral clusters. These enlarged elements are coated with COPI ( ${beta}$ -COP panel). In the GalT-GFP panel, the arrowheads indicate a cell expressing medium levels of GBFmyc in which the Golgi is not significantly affected. The arrow shows significant Golgi disruption in a cell expressing higher levels of GBFmyc. (B) Cells were cotransfected with GBFmyc and VSV-G-GFP, incubated for 16 h at 42°C, and then shifted to 32°C for 60 min. Cells were fixed and stained with anti-myc antibodies. VSVG-GFP accumulates at enlarged peripheral and perinuclear elements. (C) GBFmyc-transfected cells were stained with antibodies to myc and antibodies to ERES (anti-Sec31) and to VTCs (anti-p115 and anti-ERGIC53). In transfetecd cells (asterisk), the distribution of ERES is not significantly affected, whereas VTC markers redistribute to peripheral enlarged elements (arrows). Arrowheads indicate the presence of small peripheral elements similar to those found in nontransfected cells. (D) Cells were cotransfected with GBFmyc and GalT-GFP and stained with anti-myc and anti-p115 antibodies. GalT-GFP localization is less affected than that of p115. Bars, 10 µm.

Because Golgi proteins undergo continuous cycling through theER, we posited that the observed structures may represent ER-Golgitransport intermediates arrested at a late traffic stage (Lippincott-Schwartzet al., 1998). Analysis of VSV-G transport in cells expressinghigh levels of GBFmyc confirms this prediction (Figure 2B).VSV-G accumulates in enlarged peripheral structures analogous in morphology and distribution to those observed for Golgi markerseven after long (2-h) incubations at the permissive temperature.The fact that VSV-G is able to exit the ER and accumulatesat the peri-Golgi area suggests that early events in VTC formationare not inhibited by GBFmyc overexpression. In agreement, wefound that the overall distribution of ERES (Sec31) is not affected by high levels of GBFmyc (Figure 2C). In contrast,dramatic changes in the distribution of peripheral VTCs (p115and ERGIC53) are apparent in cells overexpressing GBFmyc (Figure 2C).Both p115 and ERGIC53 are present in large perinuclearstructures analogous to those containing marker Golgi proteins(compare Figure 2C to A). We also detect p115 and ERGIC53in smaller peripheral structures analogous in size to normal ERES-associated VTCs (Figure 2C, arrowheads). The data suggestthat ERESs and early VTCs form normally at high levels of GBFmycand that these early steps of ER-Golgi traffic are not significantlyperturbed by GBF1-mediated increase in ARF activation.

Because overexpression of GBFmyc arrests ER-Golgi transportat a late VTC stage, redistribution of rapidly cycling proteins,like ERGIC53 and p115, should be greater than that of Golgienzymes (Ward et al., 2001). In agreement, we found that incells expressing high levels of GBFmyc, the redistributionof p115 is much more severe than that of GalT-GFP (Figure 2D).These results suggest that Golgi-to-ER recycling is not significantlyaffected by overexpression of GBFmyc.

The data suggest that an increase in GBF1 activity has limitedeffect on the structure and function of ERESs and early VTCs.High levels of GBFmyc do not prevent proteins from being sortedinto transport intermediates that exit the ER. However, theability of VTCs to mature and form a functional Golgi is severelycompromised by GBF1-mediated increase in ARF/COPI activity.

Overexpression of Inactive GBF1 Arrests ER-Golgi Transport at an Early Step
The crystal structure of the Sec7 domain has been determinedand consists of 10 ${alpha}$ -helices with a deep hydrophobic groovein the central region (Cherfils et al., 1998; Mossessova et al., 1998). A highly conserved glutamic acid residue at the edge of this groove is critical for the exchange reaction (Figure 3A)(Goldberg, 1998). A change-reversal mutation in this residue(E $->$ K) abolishes completely the nucleotide exchange activityof all ARF-GEFs tested so far (Jackson and Casanova, 2000). It has been previously shown that the corresponding mutationin the ARF-GEF ARNO (E156K) stabilizes the interaction betweenthe mutant GEF and ARF-GDP, suggesting that the sequestrationof the cellular pool of ARF is a possible mechanism for ARFinactivation (Beraud-Dufour et al., 1998). To generate aninactive GBF1, we substituted the critical glutamic acid residueat position 794 by lysine in GBFmyc (E794K). E794K encodesa protein of the appropriate molecular mass ( $~$ 200 kDa) in transfectedcells (Figure 3B).

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Figure 3. Overexpression of an inactive mutant of GBF1 induces disassembly of the Golgi and arrests transport at an early step. (A) Sequence alignment of the F-G loop form seven Sec7 domain GEFs. Identical residues are indicated in blue, and homologous residues are in green. The essential glutamic acid residue is highlighted in yellow and the inactivating substitution is indicated by an asterisk. (B) HeLa lysates from control cells and from cells transfected with E794K were separated by SDS-PAGE, transferred to nitrocellulose membranes, and blotted with anti-GBF1 (endogenous GBF1) or anti-myc antibodies (E794K). (C) E794K-transfected cells were stained with antibodies to MannII, giantin, p115, GM130, and ${beta}$ -COP. (D) Cells were treated with 5 µg/ml BFA for 30 min, and processed as described in C. Both in 794K-transfected cells and in BFA-treated cells, MannII and giantin redistributed to the ER, and p115 and giantin to peripheral punctuate structures, and ${beta}$ -COP to the cytosol. Bars, 10 µm.

E794K expression causes the complete disassembly of the Golgi,as shown by the redistribution of Golgi proteins to the ER(MannII and giantin) or to peripheral punctate structures thatcontain E794K (p115 and GM130) (Figure 3C). The localization of each marker protein resembles its distribution in cells treatedwith BFA (Figure 3D). BFA inhibits the exchange function ofARF-GEFs and induces the dissociation of COPI from membranes(Klausner et al., 1992). In E794K-transfected cells, like inBFA-treated cells, ${beta}$ -COP dissociates from membranes to the cytosol (Figure 3, C and D).

It has been shown that in contrast to its effects on COPI, BFAdoes not inhibit the recruitment of COPII components to ERES (Orci et al., 1993; Ward et al., 2001). Furthermore, BFA allowsthe formation of an adjacent tubular compartment that is devoidof COPII elements but contains ERGIC53 (and other proteins) (Lippincott-Schwartz et al., 1990; Nakamura et al., 1995;Klumperman et al., 1998; Nelson et al., 1998; Ward et al.,2001). In the absence of COPI, this post-ERES compartment doesnot differentiate into transport-competent VTCs. Expression of E794K also allows the formation of ERES and the adjacentpost-ERES compartment. In E794K-expressing cells the distributionof ERES (Sec31) seems normal, and the pattern is similar tothat observed in BFA-treated cells (Figure 4, A and B). Similarly, the redistribution of ERGIC53 induced by E794K is analogousto that obtained after BFA treatment (Figure 4, A and B),when ERGIC53 localizes to the tubular compartment adjacent to ERES (Lippincott-Schwartz et al., 1990; Ward et al., 2001).

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Figure 4. E794K localizes to a post-ER exit sites compartment. (A) HeLa cells were transfected with E794K and stained with anti-Sec31 or anti-ERGIC53 antibodies. (B) Cells were treated with 5 µg/ml BFA and stained as described in A. (C) Insets show a higher magnification of the boxed areas in A. The arrow marks a Sec31-positive structure adjacent to an E794K-positive structure. Arrowheads show two Sec31-positive structures associated to a single E794K positive structure. (D) Fluorescence intensity of the boxed area in C was plotted against pixel position (E) Double-labeled images were acquired, analyzed for signal overlap, and plotted. Bars, 10 µm.

E794K localizes preferentially to the post-ERES compartment.We examined the level of colocalization between E794K and Sec31,and between E794K and ERGIC53, and found that although thepatterns of E794K and ERGIC53 overlap almost completely, E794K-positivestructures are either completely separate or only partiallyoverlap with Sec31-containing structures (Figures 4, C and D).Sometimes two or more Sec31 structures are associated witha single E794K structure. Quantitation analysis indicates that>85% of E794K colocalizes with ERGIC53 and <50% colocalizeswith Sec31 (Figure 4E). Our results indicate that expressionof E794K disassembles the Golgi and arrest transport at earlyVTCs that localize adjacent to ERES. It seems that furtherdifferentiation of the post-ERES compartment to VTCs is haltedby E794K-induced inhibition of COPI recruitment.

Dynamics of E794K-GFP in Live Cells
To investigate the dynamics of the post-ERES compartment inliving cells, we generated a GFP-tagged construct of E794K.E794K-GFP causes Golgi disassembly and arrests transport ina manner analogous to that of E794K (our unpublished data).Time-lapse imaging shows that E794K-GFP labeled structures are relatively immobile and do not seem to change their overalldistribution. Figure 5A shows a representative series of imagesspanning 12:30 min (see accompanying movie). Tracing of sixdifferent particles over a period of 45 min shows that most particles are practically immobile, or move over a short distance(<2.5 µm) with no particular direction (Figure 5B).Significantly, most of the structures labeled with E794K-GFP are relatively short lived and disappear with a half-life of<10 min. Quantitative analysis indicates that 86% of thestructures disappear within 10 min (Figure 5C). E794K disappearanceevents resemble the blink-out events described after BFA treatment,suggesting E794K-GFP containing structures fuse with the ER (Sciaky et al., 1997). Alternatively, E794K-GFP may be dissociatingfrom membranes to the cytosol. A series of images showing ablink out of a single E794K-GFP–labeled structure isshown in Figure 5D (blink-out panels). We have imaged manyE794K-labeled structures in different cells and have observedblink out consistently, even when adjacent structures do notfade, suggesting that there are no major changes in the focalplane of the image (Figure 5D, blink-out panel and accompanyingmovie). We also show that most of the particles move very little or do not move at all, suggesting that movement out of the focalplane is a rare event. Often, we observed E794K-GFP–labeledstructures forming de novo at the same place or in proximityto a blink out. As shown in Figure 5D (build-up panels), twoadjacent structures undergo subsequent blink outs, and a newstructure occurs in the vicinity. Fluorescence buildup of thenew particle is gradual but relatively rapid, and maximal labelingof the structure is achieved within 4 min. In some cases, weobserved fusion between two separate structures (Figure 5D,fusion panels). Two distinct particles $~$ 1.2 µm apart seemto coalesce into a single structure in $~$ 1.5 min and behave asa single entity until they blink out after 27 min (see accompanyingmovie).

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Figure 5. Dynamics of E794K-GFP in live cells. (A) Cells expressing E794K-GFP were imaged at 15-s intervals for 45 min. Images shown cover a period of 12:30 min. Bar, 10 µm. (B) Overlaid in the first frame of the accompanying movie are the tracings of six randomly chosen structures over a period of 45 min. (C) Population analysis of post-ER exit site structures' half-life. The half-life of individual particles (n = 78) was measured, grouped into 5-min intervals, and plotted. More than 50% of the initial structures disappeared during the first 10 min. (D) Analysis of post-ER exit sites' compartment behavior. (Blink out) The series show two particles, one disappearing in $~$ 1 min (arrowheads), whereas the other remains stable throughout. (buildup) The series shows a particle occurring in the vicinity of a blink-out event after the sequential disappearing of two particles. The series show two particles that come into proximity and fuse with each other (fusion). Bar, 1 µm.

Our results indicate that the post-ERES compartment is unstableand constantly undergoes cycles of de novo formation and disappearance.Functional GBF1 is required to stabilize this compartment andallow traffic to the Golgi.

Transport between the ER and the Golgi is BFA sensitive, andit has been shown that the GEF operational at this stage isa target for BFA (Donaldson et al., 1992). In agreement, bothGBF1 and E794K relocate to the ER in BFA-treated cells (Figure 6A).However, this posed a paradox. On the one hand, neitherwild-type GBF1 nor E794K is sorted into the post-ERES compartmentupon inhibition of COPI recruitment by BFA. On the other hand,E794K can be sorted into the post-ERES compartment even whenE794K inhibits COPI recruitment (Figure 3C). These results suggest that the effects of BFA on GBF1 sorting are not dueby the lack of COPI recruitment but are probably the resultof BFA directly interfering with GBF1 sorting. To provide experimentalevidence to support our model, we inhibited COPI recruitmentwithout the use of BFA and analyzed the sorting of endogenousGBF1. Expression of a dominant inactive ARF1 mutant (ARF1-T31N) causes COPI release into the cytosol, and leads to Golgi disassembly,an effect similar to that of BFA (Dascher and Balch, 1994;Ward et al., 2001). We expressed ARF1-T31N in cells and analyzedits effects on ${beta}$ -COP and GBF1 localization. As shown in Figure 6B, ${beta}$ -COP is released into the cytosol in ARF-T31N–transfectedcells. Significantly, GBF1 localizes to punctate structuresanalogous in morphology to those induced by overexpressionof E794K. This finding indicates that GBF1 is sorted into thepost-ERES compartment in a COPI-independent manner and thatBFA directly interferes with its sorting. In agreement, analysisof the dynamics of E794K disappearance from the post-ERES compartmentafter BFA addition shows rapid redistribution to the ER (Figure 6Cand accompanying movie). More than 90% of E794K particles disappear within the first 10 min (Figure 6D). Importantly,E794K remains in the ER and no de novo buildup of E794K isobserved. It must be stressed that BFA specifically inhibitsthe sorting of E794K into the post-ERES compartment, but doesnot prevent the sorting of other proteins into this compartment.Live imaging of p58-GFP after BFA treatment confirms that afunctional post-ERES compartment is maintained during BFA treatment(see supplemental movie). p58 is the rat homolog of ERGIC53and localizes to the post-ERES compartment in BFA-treated cells (Ward et al., 2001; this study). Our results indicate thatBFA allows the formation and the sorting of several proteinsinto a post-ERES compartment but specifically blocks the recruitmentof GBF1 to this compartment.

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Figure 6. BFA directly influences E794K localization. (A) Control cells and E794K-transfected cells were incubated with 5 µg/ml BFA for 30 min and stained with anti-GBF1 and anti-myc antibodies. Sorting of E794K into the post-ERES compartment is inhibited by BFA. (B) Cells expressing a constitutively inactive mutant of ARF1 (T31N) (HA-tagged) were stained with anti-HA and anti ${beta}$ -COP or anti GBF1 antibodies. Although COPI recruitment to membranes is completely abolished in T31N-transfected cells, GBF1 is still recruited to post-ERES structures. (C) Dynamics of E794K-GFP in BFA-treated cells. Cells expressing E794K-GFP were treated with 5 µg/ml BFA and imaged at 20-s intervals for 45 min. Images begin 2 min after BFA addition and extent to 14 min. BFA causes redistribution of E794K to the ER and prevents reappearance. (D) Population analysis of post-ERES structures' half-life in BFA-treated cells (n = 62). The half-life of individual particles was measured, grouped into 5-min intervals, and plotted. Bar, 10 µm.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Molecular and biochemical dissection of ER-Golgi transport hasrevealed a crucial role for the ARF/COPI system. Assembly ofa functional COPI coat is required for the formation and maturationof pre-Golgi intermediates into Golgi elements and is essentialfor the maintenance of a functional Golgi complex (Lippincott-Schwartzet al., 1998). COPI coats are recruited to membranes throughthe action of activated ARFs, which in turn are activated byGEFs. Herein, we report the identification of GBF1 as the GEFresponsible for the regulation of ARF/COPI dynamics at theER-Golgi interface. GBF1-mediated ARF activation is requiredfor the formation of VTCs at ERESs, as well as their maturationinto Golgi. GBF1 function also plays a key role in the maintenanceof Golgi integrity.

Localization of GBF1
At least three GEFs have been shown to be important for transportbetween the ER and the Golgi in yeast: Sec7p, Gea1p, and Gea2p (Achstetter et al., 1988; Peyroche et al., 1996, 1999, 2001; Spang et al., 2001). The corresponding mammalian orthologs,BIG1/2 (Sec7p) and GBF1 (Gea1/2p), have been localized to distinctregions of the Golgi, and are likely to perform distinct functions(Claude et al., 1999; Mansour et al., 1999; Togawa et al., 1999; Kawamoto et al., 2002; Yamaji et al., 2000; Zhao et al., 2002b). BIG1 and BIG2 localize to the TGN and are involvedin regulating the recruitment of the clathrin adaptor complexesAP-1 and GGA1 (Shinotsuka et al., 2002a,b; Zhao et al., 2002b). They do not seem to be involved in COPI events because theydo not redistribute to VTCs at 15°C, and remain associatedwith TGN membranes in the peri-microtubule organizing centerregion after BFA treatment (Zhao et al., 2002b). In contrast,GBF1 is found at the cis-Golgi and in tubular structures likelyto be VTCs, cycles between the Golgi and the ER, and redistributesto the ER in cells treated with BFA (Claude et al., 1999; Kawamoto et al., 2002; Zhao et al., 2002b; this study). Herein,we show that in addition to its cis-Golgi localization, GBF1is present at peripheral COPI-coated structures that representERESs and VTCs, suggesting a role for GBF1 in COPI recruitmentat several steps between the ER and the Golgi.

Function of GBF1 in ER-Golgi Traffic
To explore the cellular function of GBF1, we used wild-typeand inactive GBF1 mutant in vivo. High levels of GBF1 activityincrease the rate of ARF and COPI recruitment to VTCs and arresttransport at a pre-Golgi stage. The rate-limiting step fordissociation of ARF seems to be GTP hydrolysis, and it is likelythat at high levels of GBF1, the amount of active ARF exceedsthe capacity of GAPs (GTPase activating protein) to inactivateit (Vasudevan et al., 1998). GBF1 overexpression does notaffect function of ERES. VTCs can differentiate and relocateat least partially in the presence of high levels of GBF1,because they concentrate in the peri-microtubule organizing center region but they cannot assemble a Golgi. Our data suggestthat high levels of GBF1 create a kinetic delay in the maturationof VTCs, causing a block at a late pre-Golgi stage. This findingsuggests that maturation of late VTCs is probably the stepmost sensitive to perturbations of COPI dynamics. Our resultsare consistent with those obtained when COPI recruitment is stabilized by other means, such as expression of a constitutivelyactive from of ARF1, or microinjection of anti- ${beta}$ -COP antibodies (Pepperkok et al., 1993; Dascher and Balch, 1994; Teal etal., 1994; Zhang et al., 1994). It is not clear what ARF isoformsGBF1 activates. In vitro observations suggest that GBF1 preferentiallyuses class II ARFs (ARF5) as substrate (Claude et al., 1999).However, in vivo data suggest that GBF1 can also act on ARF1and ARF3 (Kawamoto et al., 2002). ARF1 and ARF3 belong to classI and are thought to be the main ARFs responsible for regulatingER-to-Golgi transport. It is possible that GBF1 is acting ondifferent ARF isoforms that regulate different transport steps.Alternatively, the different ARFs might be involved in the transport of specific components or pathways. Characterizationof the specificity of GBF1 will be fundamental for understandingARF function in cells.

That GBF1 activity is essential for COPI recruitment and forthe formation of VTCs is most clearly shown with the inactiveE794K mutant. Expression of E794K leads to COPI dissociationfrom membranes and the disassembly of the Golgi. It also arrestscargo transport at the level of early VTCs that localize adjacentto ERESs. The compartment arrested by inactivating GBF1 seemsanalogous to that observed in cells treated with BFA. BFA bindsto and stabilizes an ARF-GDP-Sec7 domain complex, trappingthe exchange factor and blocking the activation of ARF molecules (Peyroche et al., 1999). In the presence of BFA, ARF activityis inhibited and COPI is not recruited to membranes. Analysisof the compartment generated by E794K (or BFA treatment) suggeststhat it represents the earliest defined stage in VTCs formation.We propose the term pre-COPI VTC, to define this stage in VTC maturation because it differentiates from ER exit sites in aCOPI-independent manner.

Pre-COPI VTCs differentiate by the action of the COPII coat,because they do not form when COPII recruitment is inhibitedby a constitutively inactive Sar1p mutant (Ward et al., 2001).Pre-COPI VTC membranes are distinct from ERESs because they do not contain COPII markers, and contain proteins, such asERGIC53, p115, GM130, GRASP65, syntaxin5, and membrin (Lippincott-Schwartzet al., 1990; Nakamura et al., 1995; Klumperman et al., 1998;Nelson et al., 1998; Chao et al., 1999; Ward et al., 2001).The differentiation and recruitment of specific proteins topre-COPI VTC provides the framework for subsequent steps inVTC differentiation. Specifically, the recruitment of GBF1 topre-COPI VTC is required to locally activate ARF and inducethe spatially defined assembly of COPI coat. Association ofCOPI with pre-COPI VTC is required for stabilization of thesestructures (see below) and sorting of proteins such as MannII,Gal-T, or VSV-G into these differentiated subdomains. The COPI-mediateddifferentiation of pre-COPI VTC into VTCs is essential for subsequent transport to the Golgi. This model of early eventsin ER-Golgi traffic is diagramed in Figure 7.

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Figure 7. GBF1 regulates COPI coating at the ER-Golgi interface and defines a novel functional stage in the progressive maturation of VTCs. Expression of an inactive GBF1 mutant arrests transport, blocks COPI recruitment to membranes, and induces the collapse of the Golgi into the ER. The effect of expressing an inactive GBF1 is analogous to that of BFA. GBF1 inactivation allows the formation of an abortive post-ER exit sites compartment (pre-COPI VTCs capable of selectively sorting some transport components. In the absence of COPI recruitment, pre-COPI VTCs continuously form and disappear, presumably by fusing with the ER (red arrow). COPII-mediated differentiation of pre-COPI VTCs represents the first step in VTC formation. GBF1 regulates the subsequent association of COPI with pre-COPI VTCs, which is required for stabilization of these structures and sorting of others proteins. The COPI-mediated differentiation of pre-COPI VTCs into VTCs is essential for subsequent transport to the Golgi. Increased expression of GBF1 causes Golgi disassembly and leads to the accumulation of enlarged COPI-coated elements in a peri-Golgi region. High levels of GBF1 promote COPI recruitment and result in the stabilization of the peri-Golgi compartment, preventing its maturation into Golgi.

It is not clear whether pre-COPI VTCs are a specialized subdomainof an ER exit site or an independent compartment that formsfrom COPII vesicles budded from ER exit sites. Electron microscopicanalysis of pre-COPI VTC structure in BFA-treated cells showsthat they are morphologically similar to VTCs in nontreatedcells, suggesting they may represent a separate compartment (Ward et al., 2001). However, photobleaching experiments withGFP-tagged p58 (the rat homolog of ERGIC53) show that pre-COPIVTC-localized p58-GFP exchanges rapidly with the ER pool ofp58-GFP (Ward et al., 2001). Because p58 is a transmembraneprotein, these data suggest that ER and pre-COPI VTC mightbe connected. Alternatively, it is possible that p58 rapidlymoves between ER and pre-COPI VTCs via vesicles.

Initially, COPI was proposed to mediate the formation of transportvesicles carrying anterograde cargo (Lippincott-Schwartz etal., 1998; Chavrier and Goud, 1999). An alternative hypothesisproposed a role for COPI in the formation of retrograde transportvesicles that would recycle proteins from the Golgi back tothe ER. However, experimental results over the last several years led to the proposal of an alternative model in which COPIplays a role in sorting proteins into membrane subdomains thatsubsequently bud off as anterograde or retrograde transportintermediates (Presley et al., 2002). Our data are most consistentwith and extend the last model of COPI function. Our resultssuggest that GBF1 associates with partially differentiatedmembranes and through its action of recruiting COPI, further matures the membrane. The association of COPI and the continualfunction of GBF1 to sustain COPI association defines a spatiallylimited subdomain that allows the sorting and recruitment ofadditional proteins. Together, GBF1 and COPI facilitate theconversion of transport arrested intermediates into transport-competentintermediates. Recruitment of GBF1 to membranes represents the most proximal event in the COPI cascade. It remains to bedetermined whether GBF1, like ARF and COPI, is continuouslycycling on and off the membrane and to define the mechanismsthat target GBF1 to specific membrane sites. Time-lapse imaginganalysis of wild-type GFP-GBF1 suggest that GBF1 cycles veryrapidly between the cytosol and membranes, both at the Golgi region and at the ERES/VTC region (Zhao et al., 2002a).

Dynamics of pre-COPI VTCs
In cells, pre-COPI VTCs are likely to be transient structuresthat rapidly acquire COPI and mature into VTCs. In E794K-transfectedcells, pre-COPI VTCs are relatively short lived with half-livesthat are usually <10 min. This is distinct from ERESs visualizedby imaging GFP-tagged Sec13 showing that ERESs are long livedand rarely form de novo (Stephens et al., 2000). Pre-COPIVTCs are continuously disappearing, presumably by fusing withthe ER. After the collapse of a pre-COPI VTCs, the adjacentERES generally gives rise to a new pre-COPI VTC. It is likelythat E794K forms an abortive pre-COPI VTC that cannot matureand is reabsorbed. It seems that GBF1 function defines thetransition from pre-COPI VTC to VTC and allows the stable entryof cargo and Golgi proteins.

Is GBF1 the Target of BFA in ER-Golgi Traffic?
Because transport between the ER and the Golgi is BFA sensitive,the GEF-regulating COPI events in this pathway should be BFAsensitive. GBF1 has been originally identified as BFA-resistantGEF by its ability to confer BFA resistance to cells (Klausneret al., 1992; Claude et al., 1999; Kawamoto et al., 2002;Zhao et al., 2002b). However, it is possible that the observed resistance is a product of overexpression and not of a BFA-resistantactivity. This is strongly supported by recent results showingthat overexpression of BIG2, a BFA-sensitive GEF, blocks BFA-inducedredistribution from membranes of ARF1 and the AP-1 complexat the TGN (Shinotsuka et al., 2002a,b). In addition, structuralanalyses of the residues that determine BFA resistance/sensitivityin other GEFs suggest that GBF1 could be BFA sensitive. Mutagenesisstudies have shown that a critical pair of phenylalanine and alanine (FA) residues conserved in all BFA-resistant GEFs isrequired to confer BFA-resistant GEF activity (Peyroche etal., 1999) In contrast, BFA-sensitive GEFs contain a conservedpair of tyrosine and serine (YS) residues. Substitution ofthe FA pair to the YS pair converts a resistant GEF into asensitive GEF, and vice versa (Peyroche et al., 1999). Interestingly,GBF1 contains a mixed sensitive/resistant (Y/A) sequence inthat region. When the residues in the resistant FA pair were substituted individually, only the phenylalanine residue butnot the alanine residue could confer BFA resistance (Peyrocheet al., 1999). Because GBF1 does not contain the phenylalanineresidue, it is likely a BFA-sensitive GEF. Furthermore, theyeast orthologs of GBF1 (Gea1p and Gea2p) are the major targetsof BFA in the yeast secretory pathway (Peyroche et al., 1999).Our data also suggest that GBF1 might be the target for BFA at the early secretory pathway. We show that GBF1 distributionis BFA sensitive and that this is due to a direct interferenceof BFA in GBF1 sorting. BFA binds to a complex between a GEFand GDP-ARF, and the effect of BFA on GBF1 localization ismost likely due to direct binding of BFA to the ARF-GDP-GBF1complex. Furthermore, BFA also causes the redistribution ofE794K and prevents its sorting into post-ERES compartment.

Together, our data identify GBF1 as a key molecule involvedin membrane differentiation that underlies the ability of thesecretory pathway to sort resident, recycling, and cargo proteins.The process involves the selective sorting of molecules intoorganized membrane subdomains that are defined by the recruitmentof cytosolic coat proteins. The primary site of GBF1 function is at a post-ER exit site compartment that represents the firstCOPI assembly site. This initial ARF/COPI event defines a differentiationstep required for the maturation of the unstable compartmentinto mobile intermediates capable of translocating to the Golgi.GBF1 activity is also required in subsequent stages of transport,indicating that GBF1 is likely to be the sole ARF-GEF regulatingCOPI dynamics at the ER-Golgi interface.

ACKNOWLEDGMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We thank J. Lippincott-Schwartz, J. Donaldson, and B. Storriefor DNA constructs; H.P. Hauri, W. Hong, B. Glick, and M. Farquahrfor antibodies; and C. Jackson and J. Lippincott-Schwartz forhelpful discussion.

Footnotes

Abbreviations used: ARF, ADP-ribosylation factor; BFA, brefeldinA; ERES, endoplasmic reticulum exit site; GEF, guanine nucleotideexchange factor; VTC, vesicular tubular cluster.

Online version of this article contains video material for somefigures. Online version available at www.molbiolcell.com.

^* Corresponding author. E-mail address: esztul{at}uab.edu.

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ABSTRACT
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DISCUSSION
ACKNOWLEDGMENTS
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