Rab-interacting lysosomal protein (RILP): the Rab7 effector required for transport to lysosomes
2001; Springer Nature; Volume: 20; Issue: 4 Linguagem: Inglês
10.1093/emboj/20.4.683
ISSN1460-2075
AutoresGiuseppina Cantalupo, Pietro Alifano, Vera Roberti, Carmelo B. Bruni, Cecilia Bucci,
Tópico(s)Lysosomal Storage Disorders Research
ResumoArticle15 February 2001free access Rab-interacting lysosomal protein (RILP): the Rab7 effector required for transport to lysosomes Giuseppina Cantalupo Giuseppina Cantalupo Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Pietro Alifano Pietro Alifano Dipartimento di Biologia, Università degli Studi di Lecce, Via Monteroni, 73100 Lecce, Italy Search for more papers by this author Vera Roberti Vera Roberti Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Carmelo B. Bruni Corresponding Author Carmelo B. Bruni Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Cecilia Bucci Corresponding Author Cecilia Bucci Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Dipartimento di Biologia, Università degli Studi di Lecce, Via Monteroni, 73100 Lecce, Italy Search for more papers by this author Giuseppina Cantalupo Giuseppina Cantalupo Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Pietro Alifano Pietro Alifano Dipartimento di Biologia, Università degli Studi di Lecce, Via Monteroni, 73100 Lecce, Italy Search for more papers by this author Vera Roberti Vera Roberti Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Carmelo B. Bruni Corresponding Author Carmelo B. Bruni Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Search for more papers by this author Cecilia Bucci Corresponding Author Cecilia Bucci Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy Dipartimento di Biologia, Università degli Studi di Lecce, Via Monteroni, 73100 Lecce, Italy Search for more papers by this author Author Information Giuseppina Cantalupo1, Pietro Alifano2, Vera Roberti1, Carmelo B. Bruni 1 and Cecilia Bucci 1,2 1Dipartimento di Biologia e Patologia Cellulare e Molecolare ‘L.Califano’ and Centro di Endocrinologia ed Oncologia Sperimentale ‘G.Salvatore’ del Consiglio Nazionale delle Ricerche, Università degli Studi di Napoli ‘Federico II’, Via S.Pansini 5, 80131 Napoli, Italy 2Dipartimento di Biologia, Università degli Studi di Lecce, Via Monteroni, 73100 Lecce, Italy *Corresponding authors. E-mail: [email protected] or E-mail: [email protected] The EMBO Journal (2001)20:683-693https://doi.org/10.1093/emboj/20.4.683 PDFDownload PDF of article text and main figures. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info Rab7 is a small GTPase that controls transport to endocytic degradative compartments. Here we report the identification of a novel 45 kDa protein that specifically binds Rab7GTP at its C-terminus. This protein contains a domain comprising two coiled-coil regions typical of myosin-like proteins and is found mainly in the cytosol. We named it RILP (Rab-interacting lysosomal protein) since it can be recruited efficiently on late endosomal and lysosomal membranes by Rab7GTP. RILP-C33 (a truncated form of the protein lacking the N-terminal half) strongly inhibits epidermal growth factor and low-density lipoprotein degradation, and causes dispersion of lysosomes similarly to Rab7 dominant-negative mutants. More importantly, expression of RILP reverses/prevents the effects of Rab7 dominant-negative mutants. All these data are consistent with a model in which RILP represents a downstream effector for Rab7 and both proteins act together in the regulation of late endocytic traffic. Introduction In the past few years, studies of various membrane trafficking steps have indicated that the machinery responsible for membrane fusion in each compartment is complex and very carefully regulated (Pfeffer, 1999). The specificity of the reaction seems to be ensured by a number of factors including Rabs, SNAREs and tethering proteins. Tethering proteins appear to act prior to the interaction between t- and v-SNAREs to bring the membranes together. SNARE complexes are responsible later on for the stable attachment of the vesicle to the target membrane. Proteins that could be responsible for tethering have been identified in different steps of transport and, surprisingly, they are not related. The Rab family of Ras-related GTPases appears to be essential for the regulation of intracellular membrane traffic in mammalian cells. Rab proteins are anchored to the cytoplasmic surface of specific intracellular membrane compartments via a geranyl-geranyl group that is added to the C-terminal cysteines post-translationally and is important for their function (Casey, 1995; Rando, 1996). Each Rab protein regulates one (or more) specific step of intracellular membrane traffic in eukaryotic cells, probably by assembling the general tethering/docking/fusion machinery (Olkkonen and Stenmark, 1997; Chavrier and Goud, 1999; Pfeffer, 1999; Waters and Pfeffer, 1999). Moreover, several lines of evidence suggest an involvement of Rab proteins in actin- and microtubule-based processes (Peranen et al., 1996; Echard et al., 1998; Nielsen et al., 1999). To understand the molecular mechanism underlying a step of membrane transport, it is essential to identify all the molecules involved. The early steps of endocytosis (budding of endocytic vesicles from the plasma membrane and delivery to early endosomes) have been studied extensively and are quite well understood (Mukherjee et al., 1997). Indeed, several important factors that function at the level of early endosomes have been isolated (Stenmark et al., 1995; Gournier et al., 1998; Simonsen et al., 1998; Vitale et al., 1998; Christoforidis et al., 1999a,b; McBride et al., 1999; Michaely et al., 1999; Valetti et al., 1999; Nagelkerken et al., 2000). In contrast, relatively little is known about proteins involved in the steps of endocytosis leading to lysosomes. Rab7 is the Rab protein involved in the control of the late steps of endocytosis (Feng et al., 1995; Méresse et al., 1995, 1997; Papini et al., 1997; Vitelli et al., 1997; Press et al., 1998; Bucci et al., 2000). Moreover, it is essential for cellular vacuolation induced by the Helicobacter pylori cytotoxin VacA (Papini et al., 1997) and for the maturation of Salmonella typhimurium-containing vacuoles (Méresse et al., 1999). However, the exact role of Rab7 and its mechanism of action in late endocytic traffic are still not known. Therefore, it is important for understanding the late steps of endocytosis to isolate Rab7-interacting components. The two-hybrid system has been used successfully to identify Rab-interacting proteins. Indeed GDI, Rabaptin4, Rabaptin5, Rabin3, Rabphilin, Rabkinesin6 and PRA1 have been identified using this approach (Brondyk et al., 1995; Janoueix-Lerosey et al., 1995; Stenmark et al., 1995; Echard et al., 1998; Gournier et al., 1998; Bucci et al., 1999; Nagelkerken et al., 2000). We have used a GTPase-deficient mutant (Rab7Q67L) to screen for Rab7-interacting proteins. Here we describe the identification of a novel 45 kDa protein that specifically interacts with the GTP-bound form of Rab7, and demonstrate that this protein, together with Rab7, controls late endocytic transport. Results Identification of a Rab7-binding protein A yeast two-hybrid screen was used to isolate proteins that interact with the Rab7 GTPase. A LexA–Rab7Q67L fusion construct was made in pBTM116 (Bartel et al., 1993) and used in the screen to isolate putative effector proteins. The final three amino acids of Rab7 (Cys-Ser-Cys) were deleted in this construct to prevent C-terminal post-translational prenylation (Farnsworth et al., 1991) since such modification might cause high background in the assay. Expression of the fusion protein was confirmed by western blot analysis of total yeast extracts with an anti-Rab7 antiserum (data not shown). The construct was used to screen a HeLa cell line cDNA library encoding proteins as C-terminal fusions with the transcriptional activation domain of Gal4 (Bartel et al., 1993). From 107 primary transformants, 198 survived the initial selection on medium lacking leucine, tryptophan and histidine, and 120 were also positive for β-galactosidase activity by nitrocellulose filter assay. Of these initial positives, only 12 transformants encoded a true positive that did not activate transcription in the presence of a non-specific test bait (Ras, galectin 1 or lamin C). Ten of these transformants contained a clone coding for the human prenylated Rab acceptor (hPRA1) (Bucci et al., 1999). Two transformants contained a clone encoding part of a novel protein. This clone was 900 bp long and contained only the 3′ portion of a coding sequence, the 3′-untranslated region and the poly(A) tail. We then tested the interaction of this clone (called C33) with different wild-type (wt) and mutant Rab proteins, looking at the growth of the yeast transformants in medium lacking His, and at the development of the blue color due to β-galactosidase activity (data not shown). C33 did not interact with Rab4, Rab5, Rab6, Rab9, Rab17 and Rab22, as shown by the lack of growth on medium lacking His and by the lack of blue color in the yeast colonies. C33 interacted with the Rab7 wt and with the two Rab7 mutant proteins Rab7I41M and Rab7Q67L. These two mutants are active since they have reduced or no GTPase activity. The deletion of the last three amino acids in the Rab7 wt and Rab7Q67L mutant did not abolish the interaction. In contrast, there was no interaction of C33 with the dominant-negative mutant Rab7T22N locked in the GDP-bound form. To quantify the interaction, we used a liquid β-galactosidase assay (Figure 1). No interaction was detected with Ras or with other Rab proteins. A very strong interaction was instead observed with Rab7 wt and Rab7Q67L. The reaction was weaker (three to five times less) if the last three amino acids were removed from the Rab7 wt or Rab7Q67L protein, demonstrating that prenylation is important for the interaction. A very weak interaction was detected with the Rab7T22N mutant (∼40 times less compared with Rab7 wt). Figure 1.Specific interaction between Rab7 and C33. The β-galactosidase activity of double transformants was measured using o-nitrophenyl-β-D-galactoside as substrate. Activities are measured as arbitrary relative units and represent mean values ± SEM of four independent transformants. Download figure Download PowerPoint Altogether, these results indicate that clone C33 encodes part of a protein that, at its C-terminus, specifically binds the GTP-bound and geranyl-geranylated form of the Rab7 protein. The C33 cDNA encodes a novel protein A search of the EMBL nucleotide database revealed no significant homology with any known human protein, but identified several expressed sequence tag (EST) sequences virtually identical to parts of the C33 cDNA. None of these sequences extended further at the 5′ end compared with clone C33. We then screened a HeLa cDNA library and isolated a full-length clone. The complete nucleotide sequence of the clone with the deduced amino acid sequence is shown in Figure 2A. The cDNA is 1814 bp long and contains a coding sequence of 401 amino acids with a predicted mol. wt of 45 kDa. A histogram of the probability of the formation of an α-helical coiled-coil structure in the protein was determined using the Lupas algorithm (Lupas et al., 1991) with a window size of 28 residues. This histogram (Figure 2B) shows that there are two regions in the protein that are likely to be in the coiled-coil conformation: the first between amino acids 140 and 180, and the second between amino acids 245 and 280. We called this protein RILP (Rab-interacting lysosomal protein). Figure 2.Primary structure of RILP. (A) Nucleotide and deduced amino acid sequence of RILP. The predicted amino acid sequence is shown below the nucleotide sequence in single-letter code. (B) Histogram indicating the probability of forming an α-helical coiled coil in RILP as determined by the Lupas algorithm. The x-axis indicates the amino acid number while the y-axis shows the probability (0–1). Download figure Download PowerPoint When the amino acid sequence of RILP was challenged against a protein domain database (ProDom), homology was found only with two hypothetical gene products from Drosophila melanogaster (EG:132E8.4; accession No. AE003420) and Caenorhabditis elegans (C32A3.3; accession No. Z81449). The two products have similar sizes (443 and 433 amino acids, respectively), very close to that of RILP (401 amino acids). The homology between the three proteins was more significant at the level of the N-terminal region, where a protein domain of ∼40 amino acids, cataloged as PD154241 in the database, was mapped. The results of the ProDom database and research tools analysis confirmed that RILP, EG:132E8.4 and C32A3.3 had a similar architecture; in fact, the region encompassing the α-helical coiled-coil structure(s) in the three proteins appeared to belong to a single protein domain, consisting of ∼200 amino acids, cataloged as PD000002. The presence of RILP in the mouse was documented by extensive homology of our cDNA full-length clone with regions of mouse chromosome 11. Significant homology was also found with a hypothetical murine protein (AB041584) of similar length (406 amino acids) belonging to the ezrin–radixin–moesin (ERM) family. However, homology was restricted to three definite regions encompassing amino acids 28–66 (identities 43.6%, positives 64.1%), 109–134 (identities 61.5%, positives 88.5%) and 308–327 (identities 80%, positives 100%). No extensive homology was found with any known yeast protein. In vitro interaction of Rab7 with RILP We decided to reconstruct the interaction with RILP in vitro using recombinant Rab7 mutant proteins. For this purpose, we expressed the Rab7T22N and Rab7Q67L proteins in Escherichia coli as glutathione S-transferase (GST) fusions and bound them to glutathione resin. They were loaded with GDP or GTP, and incubated in the presence of HeLa cell lysates as described in Materials and methods. The result of this experiment is shown in Figure 3A. Lane 1 contains extracts of HeLa cells overexpressing RILP as the immunoblotting control. RILP binds efficiently to GST–Rab7Q67L (GTP-bound) (Figure 3A, lane 4) and only weakly to GST–Rab7T22N (GDP-bound) (Figure 3A, lane 3), consistent with the data obtained with the two-hybrid assay. No binding was detected to the GST protein alone (Figure 3A, lane 2). Figure 3.Direct interaction between RILP and Rab7 in vitro. (A) GST and GST-tagged Rab7T22N and Rab7Q67L were expressed in BL21 E.coli cells, purified and immobilized on a glutathione resin. They were incubated with 100 μM GDP (Rab7T22N) or GTP (Rab7Q67L) and then with extracts of HeLa cells. Samples were then loaded on an SDS–polyacrylamide gel and subjected to western blot analysis using anti-RILP polyclonal antibodies. (B) One (lanes 1 and 3) or 2 (lanes 2 and 4) μg of GST-tagged RILP expressed in BL21 E.coli cells were loaded onto an SDS–polyacrylamide gel and transferred to nitrocellulose. The blot was then renatured as described in Materials and methods. A 10 μg aliquot of GST–Rab9 (lanes 1 and 2) or GST–Rab7 (lanes 3 and 4) loaded with [α-32P]GTP was applied to the renatured blot. Download figure Download PowerPoint To demonstrate a direct interaction between Rab7 and RILP, we performed a protein overlay assay. RILP was expressed in E.coli as GST fusions, loaded onto an SDS–polyacrylamide gel and transferred to nitrocellulose. The blot was then renatured as described in Materials and methods. GST–Rab7 and GST–Rab9 were loaded with [α-32P]GTP and then applied to the renatured blot. No binding of [α-32P]GTP-Rab9 to RILP was detected (Figure 3B, lanes 1 and 2). In contrast, [α-32P]GTP-Rab7 bound to RILP in a dose-dependent fashion (Figure 3B, lanes 3 and 4). These experiments demonstrate that RILP interacts specifically and directly with Rab7. Expression analysis of RILP To determine the expression of RILP in different tissues, we used a 1800 bp SalI fragment as a probe in a northern blot of poly(A)+ RNA from three different human tissues (Figure 4A). This analysis showed the presence of two mRNAs of 1.8 and 1.2 kb in the three tissues examined. In order to follow the expression of the protein, we produced a rabbit antiserum against a bacterially produced recombinant RILP protein. This antibody was probed against total extracts of HeLa (human uterus carcinoma), CaCo2 (human colon carcinoma), MKN28 (human gastric tubular adenocarcinoma), FEUN (human skin fibroblast), 293 cells and peripheral blood lymphocytes (Jones et al., 1975; Knowles et al., 1980; Pinto et al., 1983; Romano et al., 1988; Burkhardt et al., 1993). While no bands were detected with the pre-immune serum in any extract (data not shown), a protein of ∼50 kDa was detected in all the extracts tested (Figure 4B). The protein was more abundant in CaCo2 cells. To determine whether the protein was cytosolic or membrane associated, we fractionated the post-nuclear supernatant (PNS) of HeLa cells into a high speed pellet (P100) and a supernatant (S100), and analyzed the distribution of the protein using western blot analysis (Figure 4C). The protein was mainly cytosolic, but a fraction of it (∼5%) was membrane associated. Figure 4.Expression analysis of RILP and recruitment on membranes upon expression of Rab7Q67L. (A) Northern blot analysis. Human poly(A)+ RNA (10 μg) from lung, spleen and stomach was electrophoresed, transferred to a nylon membrane, hybridized to a 32P-labeled 1800 bp SalI fragment, washed and autoradiographed as described in Materials and methods. The relative migration of the RNA markers is indicated on the left of the panel. (B) Western blot analysis. Total extracts from FEUN (human embryonic fibroblast), PBL (peripheral blood lymphocytes), MKN28, CaCo2, 293 and HeLa cells were run on an SDS–polyacrylamide gel and analyzed by western blotting using affinity-purified anti-RILP polyclonal antibodies. The molecular weight of the immunoreactive protein is shown. (C) The PNS of HeLa cells, transfected with Rab7T22N or Rab7Q67L or not transfected, was fractionated into a high speed pellet (P100) and supernatant (S100). Proportional amounts of supernatant, pellet and PNS were analyzed by western blotting using affinity-purified anti-RILP polyclonal antibodies. (D) The same experiment as in (C) was performed using HeLa cells transfected with RILP-C33. Download figure Download PowerPoint Recruitment of RILP on late endosomal/lysosomal membranes by Rab7GTP To determine whether the expression of Rab7 affected the distribution of the RILP protein, we looked at the distribution of RILP in HeLa cells after transfection with a dominant-negative (Rab7T22N) or a constitutively active mutant (Rab7Q67L) of Rab7 (Figure 4C). Similar to what happens in the case of Rabaptin5, which is recruited on the membrane by active Rab5, the amount of membrane-associated RILP increased when Rab7 wt (not shown) or Rab7Q67L, but not Rab7T22N, was transfected. In a similar manner, the transfected RILP-C33 truncated construct was recruited on membranes by the Rab7 wt (not shown) or Rab7Q67L mutant protein (Figure 4D). These data indicate that active Rab7 is able to recruit RILP as well as its truncated form, RILP-C33, on membranes. RILP localizes to late endosomal/lysosomal membranes We next examined the intracellular localization of this protein. Antibodies made against this protein and affinity purified gave a diffuse cytosolic staining on HeLa, BHK and CaCo2 cells, confirming that the protein is mainly cytosolic (data not shown). We then performed immunofluorescence, permeabilizing the cells with saponin before fixation to wash out excess cytosolic proteins. Under these conditions, we were able to analyze the membrane-associated fraction of endogenous RILP. We found a high degree of co-localization of RILP and the late endosomal/lysosomal marker Lamp1 in CaCo2 cells where the protein is expressed at higher levels (Figure 5A). Similar results were obtained with Lamp2 and CathD (data not shown), demonstrating that RILP localizes to a Lamp-, CathD-positive compartment. In contrast, no co-localization was detected with adaptin γ (Figure 5B), human transferrin receptor (hTfR; Figure 5C), early endosomal autoantigen 1 (EEA1; data not shown) and protein disulfide isomerase (PDI; data not shown). These data demonstrate that RILP specifically localizes to late endosomal/lysosomal membranes. As expected, overexpressed RILP in HeLa cells (Figure 5D) or RILP-C33 (Figure 5E) co-localized mostly with Lamp1 and not with other cellular markers such as adaptin γ, hTfR, EEA1 and PDI (data not shown). In addition, the late endosomal/lysosomal compartment seems to be strongly affected by the expression of these proteins. Indeed, overexpression of RILP causes a high degree of aggregation of the late endosomal/lysosomal compartment in the perinuclear region, as documented by the Lamp1 staining (Figure 5D), while expression of RILP-C33 seems to cause a dispersion of the compartment (Figure 5E). Indeed, the normal perinuclear accumulation of Lamp-positive vesicles is not observed (Figure 5E). However, in cells transfected with RILP-C33, in some cases individual late endosomal/lysosomal vesicles actually appear enlarged compared with control. The striking perinuclear clustering of the late endosomal/lysosomal compartment caused by overexpression of RILP can be reversed by treatment with nocodazole, demonstrating that this process is microtubule dependent (Figure 5F). Figure 5.Confocal immunofluorescence analysis of cells expressing endogenous or high levels of RILP. Low magnification fields of several CaCo2 cells stained with anti-RILP at a dilution of 1:10 (A′, B′ and C′; red) and anti-Lamp1 (A; green), anti-adaptin γ (B; green) or anti-hTfR (C; green). HeLa cells transfected for 5 h with RILP (D and F) or RILP-C33 (E) and stained with anti-RILP at a dilution of 1:1000 (D′, E′ and F′; red) and with anti-Lamp1 (D–F; green). In (F), cells were treated for 30 min with 10 μM nocodazole after transfection. A few cells are shown in each field. The overlays of the two colors are in (A′′–F′′). Coverslips were viewed with a Leica confocal microscope. Bars = 10 μm. Download figure Download PowerPoint These data together demonstrate that RILP specifically localizes to the late endosomal/lysosomal membranes and that its overexpression affects the normal distribution of these compartments in the cell. RILP is able to overcome the morphological effects of the Rab7T22N dominant-negative mutant on the late endosomal/lysosomal compartment We have demonstrated previously that expression of Rab7 dominant-negative mutants causes selective dispersal of perinuclear lysosomes while expression of Rab7 wt or Rab7Q67L increases the degree of aggregation. In addition, the dispersed lysosomes obtained after expression of Rab7 dominant-negative mutants are no longer acidic and they can not be reached by endocytic markers (Bucci et al., 2000). Interestingly, while overexpressed RILP causes perinuclear aggregation of late endosomes and lysosomes, similar to what occurs in the case of Rab7Q67L expression (Figure 5D), expression of RILP-C33, the truncated form of RILP, causes the dispersal of the perinuclear late endosomal/lysosomal aggregate, similar to the case of cells expressing Rab7 dominant-negative mutants (Figure 5E). To analyze better the effects of RILP and RILP-C33 on the late endosomal/lysosomal compartment, we expressed these proteins in HeLa cells together with the Rab7 dominant-negative or constitutively active mutants (Figure 6). As expected, co-expression of Rab7T22N and RILP-C33 resulted in the dispersion of the Lamp-positive compartment (Figure 6A), which remained well separated from the early endosomal compartment labeled by hTfR (Figure 6F). In contrast, co-expression of Rab7Q67L and RILP resulted in the perinuclear aggregation of these structures, which were even more compact as compared with cells transfected with the active Rab7 active mutant (Figure 6C; Bucci et al., 2000). The perinuclear clustering caused by RILP and Rab7 involves only the late endosomal/lysosomal compartment since the distribution of other compartments was not affected. Indeed, adaptin γ-, PDI-, EEA1- and TfR-labeled vesicles maintained their normal distribution, clearly distinct from the perinuclear cluster of late endosomes and lysosomes (data not shown and Figure 6G). Interestingly, in cells co-expressing Rab7T22N and RILP, lysosomes are not dispersed but clustered in the perinuclear region as documented by the Lamp1 staining, indicating that RILP is able to prevent/reverse the action of the Rab7 dominant-negative mutant (Figure 6D and E). In contrast, dispersed lysosomes caused by expression of RILP-C33 are present even in the presence of the Rab7Q67L constitutively active mutants (Figure 6B). Figure 6.Dispersal of lysosomes in Rab7 dominant-negative mutant-expressing cells is prevented/reversed by expression of the RILP protein but not of the RILP-C33 protein. HeLa cells were transfected with RILP-C33 and EGFP–Rab7T22N (A and F), with RILP-C33 and EGFP–Rab7Q67L (B), with RILP and EGFP–Rab7Q67L (C and G), or with RILP and EGFP–Rab7T22N (D and E). Cells were stained with anti-RILP (A′–G′; red) and with anti-Lamp1 (A′′–E′′; blue) or anti-hTfR (F′′–G′′; blue), while EGFP–Rab7 mutants were green. Overlays of the three colors are shown in (A′′′–G′′′). Coverslips were viewed with a Leica confocal microscope. Bars = 10 μm. Download figure Download PowerPoint Altogether, these data demonstrate that RILP together with Rab7 plays a fundamental role in the organization of the late endosomal/lysosomal compartment, and suggest that RILP could act as a downstream effector of Rab7 since its expression is able to bypass the effects on the lysosomal compartment caused by the Rab7 dominant-negative mutants. RILP controls transport to lysosomes We next investigated the function of RILP in the endocytic pathway by analyzing the effect on uptake and degradation of [125I]low-density lipoprotein (LDL) and [125I]epidermal growth factor (EGF) in HeLa cells expressing RILP and its truncated form RILP-C33. No effect on [125I]LDL or [125I]EGF kinetics of internalization was observed when RILP or RILP-C33 were expressed, indicating that RILP, like Rab7, does not affect the early stages of the endocytic pathway (data not shown). In contrast, a strong inhibition of [125I]LDL and [125I]EGF degradation was detected when RILP-C33, but not RILP, was expressed (Figure 7). This inhibition was comparable with that obtained when expressing the Rab7 dominant-negative mutants and indicated that RILP plays an important role in the regulation of the transport to degradative compartments of the endocytic pathway. We next investigated whether expression of functional RILP was able also to reverse/prevent the inhibitory effect of the dominant-negative mutants of Rab7 on LDL or EGF degradation. We therefore measured the degradation in cells doubly transfected with a Rab7 dominant-negative mutant, Rab7T22N (Figure 7), and the full-length or truncated form (RILP-C33) of RILP. Degradation was normal in cells co-expressing Rab7 dominant-negative mutants and RILP, while it was inhibited if Rab7 dominant-negative mutants were expressed with RILP-C33. In addition, expression of the Rab7-activating mutant was not able to reverse/prevent the inhibitory effect caused by the RILP-C33 protein. Co-expression of RILP and Rab7Q67L did not result in a statistically significant increase in degradation compared with control. All these data together indicate that Rab7 and RILP work sequentially in the regulation of the late endocytic pathway, and suggest that RILP could represent the downstream effector of Rab7. Figure 7.Inhibition of EGF and LDL degradation by expression of RILP-C33 and rescue of the inhibition caused by the Rab7 dominant-negative
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