Human VPS34 is required for internal vesicle formation within multivesicular endosomes

doi:10.1083/jcb.200108152

Published 24 December 2001. doi:10.1083/jcb.200108152

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© The Rockefeller University Press, 0021-9525/2001/12/1251 $5.00
The Journal of Cell Biology, Volume 155, Number 7, December 24, 2001 1251-1264

Article

Human VPS34 is required for internal vesicle formation within multivesicular endosomes

C.E. Futter¹, L.M. Collinson², J.M. Backer³ and C.R. Hopkins²

¹ Institute of Ophthalmology, University College London, London EC1V 9EL, United Kingdom
² Imperial College of Science and Technology, London SW7 2AS, United Kingdom
³ Department of Molecular Pharmacology, Albert Einstein College of Medicine, New York, NY 10461

Address correspondence to Colin Hopkins, Dept. of Biochemistry, Imperial College of Science and Technology, London SW7 2AS, UK. Tel.: 44-207-594-5329. Fax: 44-207-225-0960. E-mail: colinhopkins{at}compuserve.ac.uk

Abstract

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

After internalization from the plasma membrane, activated EGFreceptors (EGFRs) are delivered to multivesicular bodies (MVBs).Within MVBs, EGFRs are removed from the perimeter membrane tointernal vesicles, thereby being sorted from transferrin receptors,which recycle back to the plasma membrane. The phosphatidylinositol(PI) 3'-kinase inhibitor, wortmannin, inhibits internal vesicleformation within MVBs and causes EGFRs to remain in clusterson the perimeter membrane. Microinjection of isotype-specificinhibitory antibodies demonstrates that the PI 3'-kinase requiredfor internal vesicle formation is hVPS34. In the presence ofwortmannin, EGFRs continue to be delivered to lysosomes, showingthat their removal from the recycling pathway and their deliveryto lysosomes does not depend on inward vesiculation. We showedpreviously that tyrosine kinase-negative EGFRs fail to accumulateon internal vesicles of MVBs but are recycled rather than deliveredto lysosomes. Therefore, we conclude that selection of EGFRsfor inclusion on internal vesicles requires tyrosine kinasebut not PI 3'-kinase activity, whereas vesicle formation requiresPI 3'-kinase activity. Finally, in wortmannin-treated cellsthere is increased EGF-stimulated tyrosine phosphorylation whenEGFRs are retained on the perimeter membrane of MVBs. Therefore,we suggest that inward vesiculation is involved directly withattenuating signal transduction.

Key Words: EGF receptor; VPS34; endosome; lysosome; phosphatidylinositol 3'-kinase

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The binding of ligand to growth factor receptors on the cellsurface initiates a series of events including receptor activation,the activation of target proteins, and endocytosis of the activatedligand–receptor complex. Both receptor activation andactivation of target proteins begin on the plasma membrane.However, it has been known for some years that receptor tyrosinekinases remain phosphorylated and are potentially still activein the endosome (Wada et al., 1992; Futter et al., 1993; Burke et al., 2001),suggesting that signaling is not attenuated atthe internalization step. Internalized growth factor receptorsmay be returned to the plasma membrane and can participate infurther signaling, or they may be delivered to lysosomes anddegraded, resulting in signal attenuation.

Recycling receptors, such as transferrin receptors (TRs)^* andreceptors destined for delivery to the lysosome, are initiallyinternalized into the same endocytic compartment where theyare sorted (Trowbridge et al., 1993; Gruenberg and Maxfield, 1995;Mellman, 1996). EM shows that within multivesicular endosomes(multivesicular bodies [MVBs]) recycling TRs are confined tothe perimeter membrane, and from this location they can returnto the plasma membrane, whereas activated EGF receptors (EGFRs)accumulate on the internal vesicles of MVBs (Futter and Hopkins, 1989;Hopkins et al., 1990; Futter et al., 1996). When all therecycling receptors have been removed, the MVB fuses directlywith the lysosome (van Deurs et al., 1995; Futter et al., 1996;Mullock et al., 1998), and EGF–EGFR complexes are rapidlydegraded.

The vesiculation processes which give rise to internal vesicleswithin MVBs are distinctive because, unlike most vesiculationprocesses characterized to date, the vesiculating membrane budsaway from the cytoplasmic matrix. Unlike coatomer- and clathrin-basedmechanisms, the components regulating this kind of vesiculationare poorly understood, but in common with these mechanisms theyare likely to require interactions which select and load cargoand rearrangements within the membrane that lead to the formationof free vesicles. Our previous data would suggest that tyrosinekinase activity of the EGFR is required for selection of EGFRsfor inclusion in the internal vesicle, since mutant EGFRs lackingtyrosine kinase activity fail to accumulate on the internalvesicles and are recycled (Felder et al., 1990). Sequences withinthe cytoplasmic domain of the EGFR, distinct from the kinasedomain (Kornilova et al., 1996; Opresko et al., 1995; Kil et al., 1999),and c-Cbl–mediated ubiquitination of the EGFR(Levkowitz et al., 1998) are also required for efficient lysosomaltargetting of the receptor, although it is not yet known whetherthese are also requirements for sorting within MVBs. However,ubiquitination of carboxypeptidase S was shown recently to berequired for sorting onto internal vesicles of MVBs in yeast(Katzmann et al., 2001; Reggiori and Pelham, 2001). Given thattyrosine phosphorylation of c-Cbl by the EGFR kinase is requiredfor association with and ubiquitination of the EGFR, c-Cbl phosphorylationmay explain at least one requirement for EGFR tyrosine kinaseactivity in sorting of EGFRs within the MVB. Additional proteinsthat may be involved in sorting within the MVB include annexin1, which is phosphorylated by the EGFR kinase on the perimetermembrane of the MVB (Futter et al., 1993), Hrs, which is alsoa substrate of the EGFR kinase (Komada and Kitamura, 1995) andinhibits lysosomal targetting of the EGFR when overexpressed(Chin et al., 2001; Raiborg et al., 2001), and sorting nexin(SNX)1, which associates with the activated EGFR and enhancesthe efficiency of lysosomal targeting of the receptor (Kurten et al., 1996).Hrs contains a domain, which recognizes phosphatidylinositol(PI)(3)P, and several studies suggest a role for lipids in sortingwithin the MVB. Antibodies to lysobisphosphatidic acid (Kobayashi et al., 1998)or mutation of the Niemann-Pick type C gene, whichencodes a protein with a sterol-sensing domain, cause the generationof aberrant MVBs that show defects in protein and cholesterolsorting (Kobayashi et al., 1999). Mutations in the yeast PI(3)P5'-kinase, Fab1, cause defects in sorting within MVBs (Odorizzi et al., 1998),and in mammalian melanoma cells treatment withwortmannin causes the generation of enlarged vacuolar endosomeswith a reduced number of internal vesicles (Fernandez-Borja et al., 1999),suggesting that the inward vesiculation processis likely to be regulated by a PI 3'-kinase.

In the current study, we have investigated the role of PI 3'-kinasesin sorting within the MVB in HEp-2 cells and show that the lipidkinase hVPS34 is required for the formation of internal vesicleswithin the MVB but not for removing activated EGFR from therecycling pathway. Since we find enhanced tyrosine phosphorylationwhen EGFRs are retained on the perimeter membrane of MVBs inwortmannin-treated cells, we suggest that the incorporationof activated EGFRs onto the internal vesicles of MVBs is a regulatorystep designed to terminate the EGFR signal more effectivelyand at a prelysosomal stage in the pathway.

Results

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

The effects of wortmannin on delivery of activated EGFRs to the lysosome
We identified lysosomes by incubating cells with a pulse ofHRP followed by a 2–4 h chase. As previously described(Futter et al., 1996), in HEp-2 cells this protocol labels onlylysosomes. After loading lysosomes with HRP, cells were incubatedat 20°C with anti-EGFR antibody conjugated to colloidalgold, which in the presence of EGF follows the normal traffickingroute of the EGFR. At 20°C, EGFRs are retained in the transferrin-containingendosome, but upon transfer to 37°C activated EGFRs moveinto the HRP-loaded lysosome, and after 1 h at 37°C themajority of anti-EGFR gold particles are in the lysosome (Fig. 1a). When wortmannin is included in the 37°C incubation,most MVBs (defined by the presence of anti-EGFR gold but theabsence of HRP) and some lysosomes (defined by the presenceof HRP) become enlarged (Fig. 1, b and c). Both MVBs and lysosomeshave fewer internal vesicles and internal membranes, but itis clear that many of the anti-EGFR gold particles reach HRP-loadedlysosomes in the presence of wortmannin. Counting the numberof anti-EGFR gold particles that reached HRP-filled lysosomesafter 1 h at 37°C showed that delivery of EGFRs to the lysosomewas only slightly inhibited (6%) by wortmannin treatment andthat the majority of EGFRs (81.9%) reached the lysosome in thepresence of wortmannin (Table I). In these experiments, cellswere allowed to take up EGFRs at 20°C in the absence ofwortmannin (to eliminate possible effects of wortmannin on internalizationof EGFRs), and wortmannin was only included in the 37°Cincubation. PI(3)P is likely to be depleted rapidly from cellsafter wortmannin addition, since the PI(3)P binding protein,EEA1, was released from endosomal membranes within 2 min ofwortmannin addition at 37°C (unpublished data). However,to eliminate the possibility that some EGFRs reached the HRP-filledlysosomes before depletion of PI(3)P cells were preincubatedwith wortmannin at 37°C for 30 min before loading with anti-EGFR–gold/EGFat 20°C and chase at 37°C, all in the continued presenceof wortmannin. Under these conditions, there was a 12% reductionin the number of EGFRs reaching the lysosome, but the majority(76.7%) of EGFRs still reached the HRP-filled lysosome.

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Figure 1. The effects of wortmannin on delivery of the EGFR to the lysosome. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with anti-EGFR gold and EGF for 1 h at 20°C, all in the absence of wortmannin. Cells were then chased for 1 h at 37°C in the absence (a) or presence of wortmannin (b and c). Note that in both the absence and the presence of wortmannin, the EGFR have, in many cases, reached the HRP-loaded lysosomes (arrows). In the presence of wortmannin, some MVBs (without HRP) are enlarged with comparatively few internal vesicles, and EGFRs on the perimeter membrane (asterisks) and some lysosomes (with HRP) are also enlarged (crosses). Bar, 0.2 µm.

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Table I. The effects of wortmannin treatment on delivery of EGFRs to HRP-loaded lysosomes

To further investigate the efficiency of delivery of EGF andEGFRs to the lysosome in the presence of wortmannin, the effectsof wortmannin on ¹²⁵I-EGF degradation and EGFR degradation weredetermined. In HEp-2 cells, $~$ 70% of endocytosed ¹²⁵I-EGF is deliveredto the lysosome and degraded to TCA soluble radioactivity, and20% is released into the extracellular medium intact (Fig. 2a). Wortmannin treatment had very little effect on the magnitudeor kinetics of EGF degradation, although EGF recycling was inhibited.We have shown previously that MVB–lysosome fusion is requiredfor EGF degradation to TCA-soluble products (Futter et al., 1996),and so these data together with the EM data describedabove indicate that wortmannin treatment does not inhibit MVB–lysosomefusion. EGFRs are normally delivered to the lysosome primarilyon internal vesicles after MVB–lysosome fusion. In thepresence of wortmannin, a considerable proportion of EGFRs aredelivered to the lysosome on the perimeter membrane, and soEGF and the lumenal domain of the EGFR are exposed to a degradativeenvironment, whereas the COOH terminus of the receptor remainsexposed to the cytoplasm. Therefore, we determined the rateof degradation of the EGFR in the presence and absence of wortmanninby Western blotting with an antibody against the cytoplasmicdomain of the EGFR. Although the rate of EGFR degradation wasreduced in wortmannin-treated cells (Fig. 2 b), no fragmentsof the EGFR indicative of partial degradation were observed.

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Figure 2. The effects of wortmannin on EGF and EGFR degradation. (a) Cells were incubated with ¹²⁵I-EGF for 1 h at 20°C, surface stripped, and chased at 37°C in the absence or presence of wortmannin (wo) for up to 2 h. Media samples were TCA precipitated to determine the percentage of degradation. (b) Cells were incubated with EGF for 1 h at 20°C and then chased at 37°C for up to 2 h in the absence or presence of wortmannin (wo). Cell lysates were analyzed by SDS-PAGE followed by Western blotting with an antibody against the cytoplasmic domain of the EGFR. Percentage degradation is calculated by comparison with the amount of EGFRs in cells not treated with EGF.

The effects of wortmannin on inward vesiculation in cells where lysosomes have been cross-linked
Incubation of living cells with DAB/H₂O₂ crosslinks HRP-loadedlysosomes, preventing fusion between MVBs and lysosomes, andcauses MVBs to accumulate (Futter et al., 1996). This techniqueallows the development of the MVB to be followed in the absenceof endosome–lysosome fusion and is particularly usefulfor studying inward vesiculation. To quantify the effects ofwortmannin on inward vesiculation, HRP-loaded lysosomes werecross-linked and cells were then incubated with anti-EGFR goldand EGF at 20°C followed by a 1 h chase at 37°C in thepresence or absence of wortmannin. As shown in Fig. 3 a, inthe absence of wortmannin MVBs with many internal vesicles accumulate,and the EGFR gold is primarily on the internal vesicles. Inthe presence of wortmannin enlarged anti-EGFR, gold-containingvacuoles accumulate (Fig. 3, b and c). These vacuoles containvery few internal vesicles, and the majority of the gold-labeledEGFRs is on the perimeter membrane. These EGFRs are not evenlydistributed on the perimeter membrane but are clustered, andwhere an internal vesicle does form it is usually labeled withanti-EGFR gold (Fig. 3 b).

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Figure 3. The effects of wortmannin on inward vesiculation in cells where the lysosomes have been cross-linked. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H₂O₂ at 4°C to crosslink the lysosomes. Cells were then incubated with anti-EGFR gold and EGF at 20°C in the absence of wortmannin and then chased at 37°C in the absence (a) or the presence of wortmannin (b and c). Note that in the absence of wortmannin, MVBs with many internal vesicles and anti-EGFR gold predominantly on the internal vesicles accumulate (asterisks). In the presence of wortmannin, enlarged MVBs with very few internal vesicles accumulate (crosses), and the EGFR are clustered (arrowheads) on the perimeter membrane of the enlarged MVBs. L, lysosome. Bars: (a and b) 0.1 µm; (c) 0.5 µm.

The major change in volume of MVBs induced by wortmannin treatmentmay alter the probability of sectioning through internal vesiclesin any given thin section. To accurately quantitate the numberof internal vesicles per MVB, we therefore analyzed serial sectionsto reconstruct individual MVBs in their entirety. As shown inTable II, MVBs formed in the presence of wortmannin have fivefoldfewer internal vesicles than those formed in the absence ofwortmannin and have approximately twice the diameter. As shownin Fig. 4, the number of internal vesicles per MVB is extremelyvariable, particularly in control cells, but the majority ofMVBs have 10–40 internal vesicles per MVB. In contrast,in wortmannin-treated cells the majority of MVBs have less thanfive internal vesicles. Estimating the total membrane area ofthe MVB, assuming all internal vesicles to have a diameter of50 nm, indicates that wortmannin-treated vacuoles have approximatelytwice as much membrane as control cells (Table II), suggestingthat the vacuolar enlargement cannot be explained solely bya failure to inwardly vesiculate. Inhibition of exit from theMVB as has been suggested by others (Reaves et al., 1996; Kundra and Kornfeld, 1998)may, therefore, also contribute to the vacuolarenlargement. MVBs allowed to accumulate for 1 h in the presenceof wortmannin have up to 50% fewer gold particles than thosethat accumulate in the absence of wortmannin. We can assumethat the entry of EGFRs into the MVBs is not inhibited by wortmannin,since in cells where the lysosomes have not been cross-linkedEGFRs are efficiently delivered to the lysosome (see above).Therefore, it is likely that some loss of EGFRs from the perimetermembrane of the MVB does occur in wortmannin-treated cells whenMVB–lysosome fusion is prevented.

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Table II. The effects of wortmannin on inward vesiculation and membrane area per MVB

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Figure 4. The effects of wortmannin on the number of internal vesicles per MVB. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H₂O₂ at 4°C to crosslink the lysosomes. Cells were then incubated with anti-EGFR gold and EGF at 20°C in the absence of wortmannin and then chased at 37°C in the absence or the presence of wortmannin. The total number of internal vesicles in 13 MVBs per treatment was estimated by analysis of 70-nm serial sections.

To determine whether there is a general inhibition of exit fromMVBs in wortmannin-treated cells or whether EGFRs are specificallyretained on the perimeter membrane of MVBs, we determined theeffect of wortmannin treatment on removal of TRs from MVBs.Lysosomes were cross-linked in the living cell as describedabove. Cells were then incubated with anti-EGFR gold and EGFat 20°C in the absence of wortmannin to allow EGFR internalizationbut retain EGFRs in the TR-containing endosome. Cells were thenchased for 1 h at 37°C in the presence or absence of wortmannin.In the absence of wortmannin, TRs would be expected to be graduallyremoved from the maturing MVBs. Cells were then permeabilizedand immunogold labeled using an antibody to the cytoplasmicdomain of the TR as described in Materials and methods. As expected,mature MVBs accumulated in the absence of wortmannin for 1 hat 37°C have very few TRs compared with surrounding vesiclesand tubules (Fig. 5, a and b). In wortmannin-treated cells,although the MVBs are enlarged, there are also very few TRson the perimeter membrane compared with surrounding vesiclesand tubules (Fig. 5, b and c). Examining a single time pointdoes not allow the effect of wortmannin on the rate of removalof TRs from the MVBs to be determined. However, counting thenumber of EGFR- and TR-gold particles in random thin sectionsshows that the ratio of EGFRs to TRs in MVBs accumulated inthe presence of wortmannin compared with untreated cells isalmost identical: 57:2 EGFRs to TRs in the absence of wortmanninand 51:2 in the presence of wortmannin (n = 100). Thus, althoughinward vesiculation is inhibited sorting of EGFRs from TRs continues.

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Figure 5. The effects of wortmannin on traffic of EGFRs and TRs through MVBs. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H₂O₂ at 4°C to crosslink the lysosomes. Cells were then incubated with anti-EGFR gold (10 nm) and EGF for 1 h at 20°C in the absence of wortmannin and were then chased at 37°C for 1 h in the absence (a and b) or the presence of wortmannin (c). Cells were then permeabilized, fixed, and labeled with anti-TR antibody (5 nm gold). Note that in both the absence and the presence of wortmannin there are very few TRs on MVBs, but small vesicles labeling strongly for TRs (arrows) are often in close proximity. Bars, 0.1 µm.

The effects of microinjection of anti–PI 3'-kinase antibodies on inward vesiculation
To determine which PI 3'-kinase is involved in inward vesiculation,isotype-specific inhibitory antibodies to the p110 ${alpha}$ and p110ßsubunits of the type 1 kinases and to hVPS 34 (the type IIIkinase) were assessed for their effects on inward vesiculation.These antibodies have been shown to inhibit the respective PI3'-kinase activities when microinjected into cells (Siddhanta et al., 1998).HRP-loaded lysosomes were cross-linked in theliving cell, and then cells were microinjected with anti–PI3'-kinase antibody and with 20 nm gold in order to locate themicroinjected cells. Cells were then allowed to recover fora further 2 h at 37°C before incubation with anti-EGFR goldand EGF at 20°C. Cells were then chased at 37°C for1 h before processing for EM. Control experiments were performedto confirm that the morphology of the cells, and the formationof MVBs was not affected by microinjection with 20 nm gold.The microinjected 20 nm gold was distributed frequently throughoutthe cytoplasm as single particles, although occasionally clustersof gold were observed in the cytoplasm or enclosed within alimiting membrane (Fig. 6 a). Microinjection of anti-p110 ${alpha}$ antibodydid not affect the morphology of the MVB at any dose of antibody(Fig. 6 c). Microinjection of anti-p110ß antibodydid not appear to affect the morphology of the MVB at low doses.However, cells injected with larger doses of antibody had unusuallysmall MVBs with very few internal vesicles, and EGFRs were oftenfound in small vesicles and tubules rather than MVBs (Fig. 6d). This suggests that p110ß is involved in earlyevents in endocytic processing and may be involved in the deliveryof membrane to the MVB. In cells microinjected with anti-hVPS34MVBs had a reduced number of internal vesicles and the EGFRswere primarily on the perimeter membrane (Fig. 6 b). Althoughin some cases these MVBs were enlarged, they were not as largeas those induced by treatment with wortmannin. It is possiblethat this difference in the results of anti–PI 3'-kinaseantibody injection and wortmannin treatment could be explainedby differences in the timing of PI 3'-kinase inhibition. Anti–PI3'-kinase antibodies were injected before the addition of anti-EGFRgold and EGF, whereas wortmannin was added to the cells afterthey had been incubated with anti-EGFR gold and EGF at 20°C.

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Figure 6. The effects of microinjection with anti–PI 3'-kinase antibodies on inward vesiculation in cells where the lysosomes have been cross-linked. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H₂O₂ at 4°C to crosslink the lysosomes. Cells were then microinjected at 37°C with 20 nm BSA gold (arrows) alone (a) or coinjected with anti-hVPS34 antibody (b), anti-p110 ${alpha}$ antibody (c), or anti-p110ß antibody (d). Cells were then incubated with 10 nm anti-EGFR gold (arrowheads) and EGF for 1 h at 20°C and were then chased at 37°C for 1 h. Microinjection with the anti-hVPS34 antibody caused the generation of enlarged MVBs containing few internal vesicles (asterisks). Microinjection with anti-p110 ${alpha}$ had no effect on MVB formation, whereas microinjection with p110ß in some cases caused the generation of MVBs with comparatively few EGFRs, but they were not enlarged. Bars, 0.5 µm.

Therefore, we performed further microinjection experiments tomimic the experiments using wortmannin as closely as possible.HRP-loaded lysosomes were cross-linked in the living cell, andthen cells were loaded with anti-EGFR gold and EGF at 20°C.Cells were then microinjected with antibody and with 20 nm goldparticles and were then incubated for a further 30 min at 20°Cto allow time for the microinjected antibody to bind its antigenwithin the cell. Cells were then chased at 37°C for 1 h.Microinjection of the anti-hVPS34 antibody caused the formationof enlarged MVBs with very few internal vesicles and with EGFRson the perimeter membrane, closely mimicking the effects seenwith wortmannin treatment (Fig. 7 a). This effect appeared tobe dose dependent. In cells with large amounts of injected 20nm gold (indicating a larger volume of microinjected anti–PI3'-kinase antibody), MVBs were large and had very few internalvesicles. Cells containing fewer injected gold particles seemedto have smaller MVBs with a few internal vesicles but stillcontained fewer internal vesicles than MVBs of control cells(unpublished data). Therefore, we conclude that the inhibitionof inward vesiculation within the MVB by wortmannin is due toinhibition of the PI 3'-kinase hVPS34. Large doses of anti-p110ßantibody sometimes led to a decrease in the size of MVBs andsome accumulation of EGFRs in small vesicles and tubules (Fig. 7b). This is an effect not observed with wortmannin treatment.p110ß may be involved in an early step in the maturationof MVBs and is presumably more effectively inhibited by microinjectionthan by wortmannin treatment.

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Figure 7. The effects of microinjection with anti–PI 3'-kinase antibodies after incubation with EGF at 20°C. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H₂O₂ at 4°C to crosslink the lysosomes. Cells were then incubated with 10 nm anti-EGFR gold (arrowheads) and EGF for 1 h at 20°C and were then microinjected with 20 nm BSA gold (arrows) and anti-hVPS34 (a) or anti-p110ß (b) at 20°C before incubation at 20°C for a further 30 min and then chase at 37°C for 1 h. Microinjection of anti-hVPS34 caused the generation of enlarged MVBs with very few internal vesicles and EGFRs on the perimeter membrane. Microinjection of anti-p110ß antibody caused the formation of small MVBs with few internal vesicles and few EGFRs. Bars, 0.2 µm.

The effects of wortmannin on EGF-stimulated tyrosine phosphorylation
The above data suggests that EGFRs carry information that allowsthem to be retained on the perimeter membrane of MVB while TRsare being removed from this location to the recycling pathway,and that retention of EGFRs on the perimeter membrane is sufficientto target them for lysosomal delivery. This raises the questionof the purpose of inward vesiculation. One possible purposecould be the removal of EGFRs from exposure to the cytoplasmicmatrix and hence from substrates for their kinase activity.Therefore, we determined the effects of inhibition of inwardvesiculation on the spectrum of proteins phosphorylated by theEGFR kinase. To enhance potential differences, lysosomes werecross-linked to prevent EGFR degradation, and then cells wereincubated with EGF at 20°C followed by chase at 37°Cin the presence or absence of wortmannin. MVBs with EGFRs onthe perimeter membrane and exposed to the cytoplasm (in thepresence of wortmannin) could be compared with MVBs with EGFRson internal vesicles sequestered from the cytoplasm (in theabsence of wortmannin). Tyrosine-phosphorylated proteins weredetected by Western blotting cell lysates with antiphosphotyrosineantibody. As shown in Fig. 8, the pattern and strength of phosphorylationis increased significantly in wortmannin-treated cells. Sincethere is some loss of EGFRs from the perimeter membrane of MVBsin wortmannin-treated cells in which the lysosomes have beencross-linked, we cannot be sure that all the tyrosine-phosphorylatedproteins are on the perimeter membrane of MVBs in wortmannin-treatedcells. However, these data are consistent with the possibilitythat inward vesiculation within MVBs removes EGFRs from potentialcytoplasmic substrates.

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Figure 8. The effects of wortmannin on EGF-stimulated tyrosine phosphorylation in cells were the lysosomes have been cross-linked. HEp-2 cells were incubated with HRP for 30 min at 37°C, chased for 3 h at 37°C, and then incubated with DAB/H2O2 at 4°C to crosslink the lysosomes. Cells were then incubated in the presence or absence of EGF at 20°C for 1 h and then chased at 37°C in the presence or absence of wortmannin (wo). Cell lysates were analyzed by SDS-PAGE followed by Western blotting with antiphosphotyrosine antibody.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

Wortmannin treatment has multiple effects on both endo- andexocytic pathways, including the stimulation of clathrin-dependentendocytosis (Martys et al., 1996; Spiro et al., 1996), the inhibitionof endosome–endosome fusion in vitro (Jones and Clague, 1995;Li et al., 1995; Spiro et al., 1996), the inhibition ofTR recycling (Martys et al., 1996; Shpetner et al., 1996; Spiro et al., 1996),the formation of enlarged late endosomes (Reaves et al., 1996;Bright et al., 1997; Kundra and Kornfeld, 1998;Fernandez-Borja et al., 1999), and inhibition of the perinuclearclustering and degradation of platelet-derived growth factorreceptors (PDGFRs) (Joly et al., 1995; Shpetner et al., 1996).We have examined the effects of wortmannin on the endocyticpathway followed by activated EGFRs en route to the lysosome.

Wortmannin treatment inhibits inward vesiculation within MVBs but not EGFR delivery to the lysosome
In common with others, we find that wortmannin treatment causesthe formation of enlarged endocytic vacuoles. After 1 h at 37°C,there is a minor enlargement of lysosomes, but the enlargementof vacuoles, recognizable as MVBs because they lack dense contentand usually contain one or more small vesicles, is more marked.The enlarged MVBs frequently have comparatively few internalvesicles, and the EGFRs are found more frequently on the perimetermembrane compared with cells not treated with wortmannin. Wortmannin-inducedenlargement of late endosomes and lysosomes has been proposedto be due to an inhibition of exit of proteins like mannose6-phosphate receptor from these structures (Kundra and Kornfeld, 1998),an inhibition of reformation of lysosomes after endosome–lysosomefusion (Bright et al., 1997), or an inhibition of inward vesiculation(Fernandez-Borja et al., 1999). In the latter study on a humanmelanoma cell line, the authors found that wortmannin treatmentgenerated enlarged vacuoles with few internal vesicles and proposedthat wortmannin inhibited the invagination and/or pinching offof intraluminal vesicles of both MHC class II compartments andof other components of the endocytic pathway. A recent studyfrom Bright et al. (2001) found that prolonged wortmannin treatmentof NRK fibroblasts did not prevent the accumulation of internalvesicles within enlarged endocytic vacuoles and concluded thatvacuolar enlargement was due to inhibition of exit of membranefrom these structures.

We have developed a technique that allows the maturation ofMVBs to be followed in the absence of MVB–lysosome fusion(Futter et al., 1996). By preincubation of HRP-loaded lysosomeswith DAB/H₂O₂, which cross-links the lysosome in the livingcell, MVB–lysosome fusion is prevented, but maturationof the MVB, in which inward vesiculation transfers EGFRs tothe inner vesicle, proceeds. By including wortmannin in thisprotocol, we have demonstrated that there is a fivefold reductionin the accumulation of internal vesicles within the MVB andthat EGFRs remain primarily on the perimeter membrane. Estimatingthe amount of membrane per MVB suggests that vacuolar enlargementcannot be explained solely by an inhibition of inward vesiculation.Therefore, it is likely that both inhibition of inward vesiculationand inhibition of exit of proteins, such as MPR, from the MVBcontributes to the vacuolar enlargement. However, wortmannin-inducedinhibition of exit from MVBs is selective, since TRs are efficientlyremoved from the maturing MVBs. This observation needs to bereconciled with several published studies which have reportedthat wortmannin treatment inhibits TR recycling (Martys et al., 1996;Shpetner et al., 1996; Spiro et al., 1996) and our findingthat wortmannin inhibits the recycling of the small proportionof internalized EGF that is normally recycled. EM demonstratesthat the majority of TRs in wortmannin-treated cells is in endosomaltubules, a compartment which is expanded in these cells (unpublisheddata; Shpetner et al., 1996) rather than in MVBs. Therefore,it is probable that it is within tubules rather than in MVBsthat the trafficking of these recycling receptors is being inhibited.

Despite the inhibition of inward vesiculation, EGFRs are stilldelivered to the lysosome in the presence of wortmannin, andEGF degradation is largely unaffected. Although some proteolyticprocessing of EGF has been reported to occur in prelysosomalcompartments (Schaudies et al., 1987; Renfrew and Hubbard, 1991),we have shown previously that MVB–lysosome fusion is requiredfor the degradation of EGF to TCA-soluble products (Futter et al., 1996).Therefore, we conclude that MVB–lysosome fusionis not affected by wortmannin treatment. The EGFR is degradedwith slower kinetics in wortmannin-treated cells. Similarly,the rate but not extent of degradation of Semliki Forest viruswas found to be reduced by wortmannin treatment (Martys et al., 1996).We have been unable to detect degradation products ofthe EGFR indicative of partial degradation of the receptor,suggesting that the EGFR is unstable in the perimeter membraneof the lysosome. There is no indication in our studies of themeans whereby the cytoplasmic domain of the EGFR is degradedin wortmannin-treated cells. Previous studies would supportthe notion that MVB–lysosome fusion can occur in the presenceof wortmannin, since Bright et al. (1997) identified lysosomeswith a pulse of BSA gold and showed that a second pulse of BSAgold could reach the previously internalized gold even in thepresence of wortmannin. These authors have shown that endosome–lysosomefusion results in the generation of a hybrid compartment fromwhich dense core lysosomes must be reformed (Mullock et al., 1998).Wortmannin treatment reduced the number of dense corelysosomes within the cell, suggesting an inhibition of the reformationof dense lysosomes (Bright et al., 1997).

The delivery of PDGFRs to the lysosome has been reported tobe inhibited by wortmannin (Joly et al., 1995; Shpetner et al., 1996).In the latter study, fluid phase markers could reachthe lysosome in the presence of wortmannin, again indicatingthat wortmannin did not prevent endosome–lysosome fusionbut rather that wortmannin inhibited the targetting of PDGFRsto that pathway. In contrast, we found that wortmannin treatmentdid not affect the targetting of EGFRs to the lysosomal pathway.We have proposed previously that movement of EGFRs onto theinternal vesicles of MVBs is critical for removing EGFRs fromthe recycling pathway and targetting them to the lysosome. Inactivationof the tyrosine kinase activity of the EGFR inhibited movementof the EGFR onto the internal vesicles of MVB and, in this case,the EGFR recycled (Felder et al., 1990). In wortmannin-treatedcells, the movement of the EGFR onto the internal vesicles isalso inhibited, but in this case the EGFR is not recycled; itis delivered to the lysosome and degraded. Taken together, theseresults suggest that we have resolved two stages in the inwardvesiculation process: (a) selection of EGFRs for inclusion inthe internal vesicle, which requires tyrosine kinase activitybut not PI 3'-kinase activity and is represented by the clustersof EGFRs on the perimeter membrane of MVBs in wortmannin-treatedcells and (b) vesicle formation, which requires PI 3'-kinaseactivity. EGFR tyrosine kinase activity but not PI 3'-kinaseactivity is, therefore, necessary to retain the EGFR in theMVB and prevent recycling.

The fact that wortmannin treatment inhibits lysosomal targetingof PDGFRs (Shpetner et al., 1996) but not EGFRs (this study)could be because lysosomal targeting of PDGFRs and EGFRs areregulated differently. Alternatively, in our experiments wortmanninwas only added after EGFRs had been internalized at 20°C,and so it is possible that a PI 3'-kinase is involved in anearly step in the processing of EGFRs proximal to the 20°Cblock. Consistent with this possibility is our finding thatwhen cells were treated with wortmannin before addition of EGF,there was a small reduction in the number of EGFRs reachingthe lysosome, and also when anti-PI 3'-kinase antibodies weremicroinjected before addition of EGF, delivery of EGFRs to MVBswas, in some cases, partially inhibited (see below).

hVPS34 is the PI 3-kinase required for inward vesiculation
There are three classes of mammalian PI 3'-kinases, which differboth in their regulation and their substrate specificities (Rameh and Cantley, 1999).Class I and class III PI 3'-kinases havedistinct roles in endocytic traffic. Microinjection of inhibitoryanti-p110 ${alpha}$ antibody inhibits TR recycling, whereas microinjectionof anti-hVPS34 but not anti-p110 ${alpha}$ inhibits transit of internalizedPDGFRs to a perinuclear compartment (Siddhanta et al., 1998).Here, we show that microinjection with inhibitory anti-hVPS34but not anti-p110 ${alpha}$ or anti-p110ß causes the generationof enlarged MVBs. These MVBs contain reduced numbers of internalvesicles, and EGFRs remain on the perimeter membrane. Therefore,we conclude that hVPS34 is the PI 3'-kinase required for inwardvesiculation within MVBs. Some reduction in size of MVBs wasobserved in cells microinjected with anti-p110ß (andhVPS34 when microinjected before the addition of EGF), suggestinga possible role of these PI 3'kinases in an early step in thesorting of EGFRs, which would be consistent with their recruitmentby rab5 to early endosomes (Christoforidis et al., 1999). PDGFRmutants that fail to bind PI 3'-kinases are unable to enterthe lysosomal pathway, suggesting a role of the class I PI 3'-kinasesin this effect (Joly et al., 1995). On the other hand, microinjectionof anti-hVPS34 inhibited accumulation of PDGFRs in the perinucleararea, indicating a role for this PI 3'-kinase in sorting ofPDGFRs (Siddhanta et al., 1998). It is not possible to determinethe roles of PI 3'-kinases in early events in the sorting ofEGFRs from the results of our experiments, but both p110ßand hVPS34 may have roles in addition to that demonstrated herefor hVPS34 in inward vesiculation.

The product of hVPS34, PI(3)P, is specifically recognized byproteins containing a cysteine-rich zinc finger domain, termedthe FYVE domain. FYVE domains are found in several proteinsimplicated in membrane trafficking, including EEA1, Fab1, Vac1,Hrs (Stenmark and Aasland, 1999), and rabenosyn 5 (Nielsen et al., 2000).Association of EEA1 and rabenosyn 5 with endosomesinvolves binding to both PI(3)P and rab5-GTP (Patki et al., 1998;Simonsen et al., 1998; Nielsen et al., 2000). EEA1 isrequired for endosome–endosome fusion in vitro (Mills et al., 1998;Simonsen et al., 1998) and may act as a tetheringfactor (Pfeffer, 1999), mediating endosome–endosome docking(Christoforidis et al., 1999). Fab1 is a PI(3)P 5-kinase andtherefore phosphorylates the product of VPS34. Mutations inyeast Fab1 cause expansion of the vacuole and retention of carboxypeptidaseS, which is normally degraded within the lumen of the vacuole,on the perimeter membrane (Odorizzi et al., 1998). This showsa striking similarity with the phenotype observed for EGFRsin wortmannin-treated cells. Hrs has been localized to endosomes(Komada et al., 1997) where it can recruit clathrin (Raiborg et al., 2001),becomes tyrosine phosphorylated in response toseveral growth factors, including EGF, (Komada and Kitamura, 1995;Komada et al., 1997), and tyrosine phosphorylation causesthe release of Hrs from endocytic vacuoles (Urbe et al., 2000).In addition to the FYVE domain, the PX domain contained in SNX3has been shown recently to bind PI(3)P, and this domain is foundin a family of proteins termed SNXs (Xu et al., 2001). SNX1binds to the EGFR and can also interact with Hrs (Chin et al., 2001).Overexpression of SNX1 enhances EGFR degradation (Kurten et al., 1996),whereas overexpression of Hrs or the SNX1 bindingdomain of Hrs inhibits EGFR degradation, suggesting that Hrsmay regulate the traffic of EGFRs through SNX1 (Komada and Soriano, 1999;Chin et al., 2001). Thus, there are multiple proteinscontaining domains which specifically recognize PI(3)P. Someof these proteins have been implicated in the regulation ofthe traffic of the EGFRs, but as yet no role of any of theseproteins in either selection of cargo for inclusion in internalvesicles or in vesicle formation has been demonstrated directly.Our data suggest that the generation of PI(3)P-rich domainson the perimeter membrane of the MVB is required for vesicleformation but not for lysosomal targetting of EGFRs. Given thatHrs and SNX1 have been implicated in lysosomal targetting ofthe EGFR, it is possible that these proteins play a role atan early step in the sorting of endocytosed EGFRs before thegeneration of internal vesicles within MVBs and that other PI(3)Pbinding proteins, such as Fab1, are required for inward vesiculation.

The generation of PI(3)P-rich domains on the perimeter membraneof the MVB requires the localization of hVPS34 to that domain.hVPS34 localization within the endosomal membrane may be regulatedby rab5, since rab5 is localized to the endosomal membrane andhVPS34 interacts indirectly with activated rab5 (Christoforidis et al., 1999).Unlike the class I PI 3'-kinases, hVPS34 hasnot been shown to be regulated directly by growth factors. However,EGFR activation has been shown recently to induce activationof rab5a (Barbieri et al., 2000), and so EGF stimulation ofrab5 may play a role in the localization of hVPS34. A recentstudy localizing PI(3)P at the light and EM level found thislipid to be highly enriched on early endosomes and on the internalvesicles of MVBs (Gillooly et al., 2000). This would be in keepingwith the generation of patches of PI(3)P on the perimeter membrane,leading to inward vesiculation. Yeast studies suggest that PI(3)Pmust be transported to the vacuole/lysosome for turnover (Wurmser and Emr, 1998),and so PI(3)P would be expected to remain onthe internal vesicles of MVBs until MVB–lysosome fusion.

Taken together, a model emerges whereby the rab5-dependent recruitmentof hVPS34 results in the generation of microdomains rich inPI(3)P that recruit effector proteins, leading to inward vesiculation.

Sequestration of activated EGFRs within the lumen of MVBs removes the receptor from potential phosphotyrosine substrates
Retention on the perimeter membrane of MVBs is sufficient forthe lysosomal targetting and degradation of activated EGFRs,raising the question of the purpose of the inward vesiculationprocess. Several studies suggest that EGFRs can continue tosignal while they remain on the perimeter membranes of the endocyticpathway. Thus, it has been shown that EGFRs remain phosphorylatedin the endosome (Wada et al., 1992) but become inactivated beforedegradation (Burke et al., 2001). Although some substrates ofthe EGFR kinase are phosphorylated on the plasma membrane, others,such as annexin 1 (Futter et al., 1993) and Eps8 (Burke et al., 2001),appear to be phosphorylated by the endosomal but notthe plasma membrane EGFR kinase. Inhibition of endocytosis ofEGFRs by expression of mutant dynamin inhibits Erk1/2 MAP kinasesignaling (Vieira et al., 1996) and Erk2 activation can be initiatedfrom the endosomal EGFR kinase in a cell-free system (Xue and Lucocq, 1998).Activated Raf-1 and Mek have been localized toendosomes after EGF stimulation (Pol et al., 1998). Therefore,it is likely that endocytosed EGFRs, which continue to be exposedto the cytoplasm, continue to signal. When they become sequesteredon internal vesicles of MVBs, their access to cytosolic substratesis presumably lost. We have addressed this question directlyby comparing the activity of the EGFR kinase in cells in whichEGFRs are retained on, with those in which they are removedfrom, the perimeter membrane. When EGFRs were retained on theperimeter membrane, tyrosine phosphorylation of a large numberof proteins was enhanced, demonstrating that there are a largenumber of potential substrates of the EGFR kinase availableto the cytoplasmically exposed EGFR. Therefore, a likely purposeof inward vesiculation is to sequester the activated EGFR awayfrom cytoplasmic substrates and thereby attenuate its signaltransduction.

Materials and methods

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Reagents
Monoclonal antibody to the extracellular domain of the EGFR(108) and the cytoplasmic domain of the TR were gifts from J.Schlessinger (New York University Medical Center, New York,NY) and I. Trowbridge (The Salk Research Institute, San Diego,CA), respectively. Rabbit polyclonal antibodies against hVPS34,p110 ${alpha}$ , and p110ß were as previously described (Siddhanta et al., 1998;Christoforidis et al., 1999). Rabbit polyclonalantibody against the cytoplasmic domain of the EGFR was raisedby immunization with the peptide Cys-DVVDADEYLIPQ coupled toKLH. Monoclonal antiphosphotyrosine antibody (PY20) was fromICN Biomedicals. HRP (type II) and wortmannin were from Sigma-Aldrich.Radiolabeled EGF and colloidal gold sols were made as describedpreviously (Slot and Geuze, 1985; Futter et al., 1996).

Cell culture and incubation conditions
HEp-2 cells were maintained in DME containing 10% FCS in a 5%CO₂ atmosphere. Lysosomes were loaded with HRP and cross-linkedin living cells as described in Futter et al. (1996). EGF wasused at a concentration of 200 ng/ml, and wortmannin was usedat a concentration of 200 nM.

EM
For conventional EM, cells grown on glass coverslips were incubatedwith HRP and gold probes under different conditions as describedin the text and were then fixed, processed, and treated withtannic acid as described previously (Stinchcombe et al., 1995).Coverslips were embedded on Epon stubbs, and the coverslipswere then removed by immersion in liquid nitrogen. Cells weresectioned en face, stained with lead citrate, and viewed inPhilips 400 or CM12 electron microscopes.

For morphometry, serial 70-nm sections were cut, the diameterof the MVB was measured, and the number of internal vesiclesper MVB were counted. An MVB was defined as a vacuole that containedanti-EGFR gold particles and had a diameter of greater than200 nm. The total membrane area per MVB was estimated by assumingthe diameter of internal vesicles to be 50 nm.

To quantitate the numbers of TRs and EGFRs/MVBs, lysosomes werecross-linked and cells were incubated with anti-EGFR gold, EGF,and wortmannin as described above. Cells were then permeabilizedand labeled with an antibody to the cytoplasmic domain of theTR as described in Futter et al. (1998). The number of anti-EGFRgold particles and anti-TR gold particles per MVB in randomthin sections were counted.

Microinjection of anti–PI 3'-kinase antibodies
HEp-2 cells were grown on Cellocate glass-gridded coverslips(Eppendorf). Microinjection was performed using an Eppendorfsemiautomated transjection system, and the needles were pulledusing a Sutter p-97 micropipette puller. 1.5-µl aliquotsof anti-hVPS34, anti-p110 ${alpha}$ , and anti-p110ß antibodies(3–4 mg/ml in PBS) were mixed with equal volumes of BSA-stabilized20 nm gold and microinjected into the cytoplasm of cells. Afterembedding in Epon, ultrathin sections were cut from the appropriategrid area containing the microinjected cells and examined byEM.

Measurement of EGF degradation
The intracellular degradation of ¹²⁵I-EGF results in the generationof TCA-soluble products of degradation that diffuse rapidlyout of the cell and can be collected in the extracellular medium.After incubation of cells with ¹²⁵I-EGF, the extracellular mediumwas collected and precipitated with 10% TCA at 4°C for 2h. TCA precipitable proteins were pelleted by centrifugationat 14,000 g at 4°C, and pellet and supernatant were counted.By also counting the radioactivity remaining associated withthe cells, the percentage degradation of EGF could be determined.

Measurement of EGFR degradation
After incubation of cells with EGF, cell lysates were subjectedto SDS-PAGE and Western blotted using a rabbit polyclonal antibodyagainst the cytoplasmic domain of the EGFR. Western blots werevisualized using ECL-Plus (Amersham Pharmacia Biotech) and quantitatedusing a Fuji PhosphorImager.

Footnotes

^* Abbreviations used in this paper: EGFR, epidermal growth factorreceptor; MVB, multivesicular body; PDGFR, platelet-derivedgrowth factor receptor; PI, phosphatidylinositol; SNX, sortingnexin; TR, transferrin receptor.

Acknowledgments

This work was funded by an Medical Research Council programgrant awarded to C. Hopkins.

Submitted: 31 August 2001

Revised: 26 October 2001

Accepted: 29 October 2001

References

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