The vacuolar transport of aleurain-GFP and 2S albumin-GFP fusions is mediated by the same pre-vacuolar compartments in tobacco BY-2 and Arabidopsis suspension cultured cells

Soluble proteins reach vacuoles because they contain vacuolar sorting determinants (VSDs) that are recognized by vacuolar sorting receptor (VSR) proteins. Pre-vacuolar compartments (PVCs), defined by VSRs and GFP-VSR reporters in tobacco BY-2 cells, are membrane-bound intermediate organelles that mediate protein traffic from the Golgi apparatus to the vacuole in plant cells. Multiple pathways have been demonstrated to be responsible for vacuolar transport of lytic enzymes and storage proteins to the lytic vacuole (LV) and the protein storage vacuole (PSV), respectively. However, the nature of PVCs for LV and PSV pathways remains unclear. Here, we used two fluorescent reporters, aleurain-GFP and 2S albumin-GFP, that represent traffic of lytic enzymes and storage proteins to LV and PSV, respectively, to study the PVC-mediated transport pathways via transient expression in suspension cultured cells. We demonstrated that the vacuolar transport of aleurain-GFP and 2S albumin-GFP was mediated by the same PVC populations in both tobacco BY-2 and Arabidopsis suspension cultured cells. These PVCs were defined by the seven GFP-AtVSR reporters. In wortmannin-treated cells, the vacuolated PVCs contained the mRFP-AtVSR reporter in their limiting membranes, whereas the soluble aleurain-GFP or 2S albumin-GFP remained in the lumen of the PVCs, indicating a possible in vivo relationship between receptor and cargo within PVCs.     

Sorting of plant vacuolar proteins is initiated in the ER

Transport of soluble cargo molecules to the lytic vacuole of plants requires vacuolar sorting receptors (VSRs) to divert transport of vacuolar cargo from the default secretory route to the cell surface. Just as important is the trafficking of the VSRs themselves, a process that encompasses anterograde transport of receptor–ligand complexes from a donor compartment, dissociation of these complexes upon arrival at the target compartment, and recycling of the receptor back to the donor compartment for a further round of ligand transport. We have previously shown that retromer‐mediated recycling of the plant VSR BP80 starts at the trans‐Golgi network (TGN). Here we demonstrate that inhibition of retromer function by either RNAi knockdown of sorting nexins (SNXs) or co‐expression of mutants of SNX1/2a specifically inhibits the ER export of VSRs as well as soluble vacuolar cargo molecules, but does not influence cargo molecules destined for the COPII‐mediated transport route. Retention of soluble cargo despite ongoing COPII‐mediated bulk flow can only be explained by an interaction with membrane‐bound proteins. Therefore, we examined whether VSRs are capable of binding their ligands in the lumen of the ER by expressing ER‐anchored VSR derivatives. These experiments resulted in drastic accumulation of soluble vacuolar cargo molecules in the ER. This demonstrates that the ER, rather than the TGN, is the location of the initial VSR–ligand interaction. It also implies that the retromer‐mediated recycling route for the VSRs leads from the TGN back to the ER.     

Arabidopsis mu A-adaptin interacts with the tyrosine motif of the vacuolar sorting receptor VSR-PS1

In receptor‐mediated transport pathways in mammalian cells, clathrin‐coated vesicle (CCV) µ‐adaptins are the main binding partners for the tyrosine sorting/internalization motif (YXXØ). We have analyzed the function of the µA‐adaptin, one of the five µ‐adaptins from Arabidopsis thaliana, by pull‐down assays and plasmon resonance measurements using its receptor‐binding domain (RBD) fused to a histidine tag. We show that this adaptin is able to bind the consensus tyrosine motif YXXØ from the pea vacuolar sorting receptor (VSR)‐PS1, as well as from the mammalian trans‐Golgi network (TGN)38 protein. Moreover, the tyrosine residue was revealed to be crucial for binding of the complete cytoplasmic tail of VSR‐PS1 to the plant µA‐adaptin. The trans‐Golgi localization of the µA‐adaptin strongly suggests its involvement in Golgi‐ to vacuole‐trafficking events.     

Retromer recycles vacuolar sorting receptors from the trans-Golgi network

Receptor-mediated sorting processes in the secretory pathway of eukaryotic cells rely on mechanisms to recycle the receptors after completion of transport. Based on this principle, plant vacuolar sorting receptors (VSRs) are thought to recycle after dissociating of receptor–ligand complexes in a pre-vacuolar compartment. This recycling is mediated by retromer, a cytosolic coat complex that comprises sorting nexins and a large heterotrimeric subunit. To analyse retromer-mediated VSR recycling, we have used a combination of immunoelectron and fluorescence microscopy to localize the retromer components sorting nexin 1 (SNX1) and sorting nexin 2a (SNX2a) and the vacuolar sorting protein VPS29p. All retromer components localize to the trans -Golgi network (TGN), which is considered to represent the early endosome of plants. In addition, we show that inhibition of retromer function in vivo by expression of SNX1 or SNX2a mutants as well as transient RNAi knockdown of all sorting nexins led to accumulation of the VSR BP80 at the TGN. Quantitative protein transport studies and live-cell imaging using fluorescent vacuolar cargo molecules revealed that arrival of these VSR ligands at the vacuole is not affected under these conditions. Based on these findings, we propose that the TGN is the location of retromer-mediated recycling of VSRs, and that transport towards the lytic vacuole downstream of the TGN is receptor-independent and occurs via maturation, similar to transition of the early endosome into the late endosome in mammalian cells.     

Transport of ricin and 2S albumin precursors to the storage vacuoles of Ricinus communis endosperm involves the Golgi and VSR-like receptors

We have studied the transport of proricin and pro2S albumin to the protein storage vacuoles of developing castor bean (Ricinus communis L.) endosperm. Immunoelectron microscopy and cell fractionation reveal that both proteins travel through the Golgi apparatus and co-localize throughout their route to the storage vacuole. En route to the PSV, the proteins co-localize in large (>200 nm) vesicles, which are likely to represent developing storage vacuoles. We further show that the sequence-specific vacuolar sorting signals of both proricin and pro2SA bind in vitro to proteins that have high sequence similarity to members of the VSR/AtELP/BP-80 vacuolar sorting receptor family, generally associated with clathrin-mediated traffic to the lytic vacuole. The implications of these findings in relation to the current model for protein sorting to storage vacuoles are discussed.     

Peripheral membrane proteins mediate binding of vacuolar storage proteins to membranes of the secretory pathway of developing pea cotyledons

In developing pea cotyledons, storage proteins are sorted viadense vesicles into the protein storage vacuole. Formation ofthese unique transport vesicles is characterized by aggregationof their cargo proteins. Protein sorting into dense vesiclesis pH dependent. In order to gain insight into the molecularbasis of storage protein sorting, a membrane binding assay wasdeveloped which allows for a detailed biochemical analysis ofbinding events. Employing this assay it was possible to showthat storage proteins bind in a pH-dependent manner to the membranesof the secretory pathway with a pH optimum in the range of thelumenal pH of the Golgi cisternae. Through reconstitution experiments,it was possible to demonstrate further that this recruitmentoccurs via the interaction of peripheral rather than intrinsicmembrane proteins. Results of co-immunoprecipitation experimentspoint to interactions between different storage proteins inthe secretory system. These results are discussed in terms ofthe aggregation-mediated sorting of storage proteins into maturingdense vesicles. Key words: Dense vesicles, Golgi apparatus, legumin, pea, receptor, sorting Received 22 January 2008; Revised 22 January 2008 Accepted 23 January 2008     

N‐linked glycosylation of AtVSR1 is important for vacuolar protein sorting in Arabidopsis

Vacuolar sorting receptors (VSRs) in Arabidopsis mediate the sorting of soluble proteins to vacuoles in the secretory pathway. The VSRs are post‐translationally modified by the attachment of N‐glycans, but the functional significance of such a modification remains unknown. Here we have studied the role(s) of glycosylation in the stability, trafficking and vacuolar protein transport of AtVSR1 in Arabidopsis protoplasts. AtVSR1 harbors three complex‐type N‐glycans, which are located in the N‐terminal ‘PA domain’, the central region and the C‐terminal epidermal growth factor repeat domain, respectively. We have demonstrated that: (i) the N‐glycans do not affect the targeting of AtVSR1 to pre‐vacuolar compartments (PVCs) and its vacuolar degradation; and (ii) N‐glycosylation alters the binding affinity of AtVSR1 to cargo proteins and affects the transport of cargo into the vacuole. Hence, N‐glycosylation of AtVSR1 plays a critical role in its function as a VSR in plants.     

Receptor-mediated transport of vacuolar proteins: a critical analysis and a new model

In this article we challenge the widely accepted view that receptors for soluble vacuolar proteins (VSRs) bind to their ligands at the trans-Golgi network (TGN) and transport this cargo via clathrin-coated vesicles (CCV) to a multivesicular prevacuolar compartment. This notion, which we term the “classical model” for vacuolar protein sorting, further assumes that low pH in the prevacuolar compartment causes VSR–ligand dissociation, resulting in a retromer-mediated retrieval of the VSRs to the TGN. We have carefully evaluated the literature with respect to morphology and function of the compartments involved, localization of key components of the sorting machinery, and conclude that there is little direct evidence in its favour. Firstly, unlike mammalian cells where the sorting receptor for lysosomal hydrolases recognizes its ligand in the TGN, the available data suggests that in plants VSRs interact with vacuolar cargo ligands already in the endoplasmic reticulum. Secondly, the evidence supporting the packaging of VSR–ligand complexes into CCV at the TGN is not conclusive. Thirdly, the prevacuolar compartment appears to have a pH unsuitable for VSR–ligand dissociation and lacks the retromer core and the sorting nexins needed for VSR recycling. We present an alternative model for protein sorting in the TGN that draws attention to the much overlooked role of Ca²⁺ in VSR–ligand interactions and which may possibly also be a factor in the sequestration of secretory proteins.     

Lack of a vacuolar sorting receptor leads to non-specific missorting of soluble vacuolar proteins in Arabidopsis seeds

The plant vacuolar sorting receptor (VSR) binds proteins carrying vacuolar sorting signals (VSS) of the 'sequence-specific' type (ssVSS) but not the C-terminal, hydrophobic sorting signals (ctVSS). Seeds of Arabidopsis mutants lacking the major VSR isoform, AtVSR1, secrete a proportion of the proteins destined to storage vacuoles. The sorting signals for these proteins are not well defined, but they do not seem to be of the ssVSS type. Here, we tested whether absence of VSR1 in seeds leads to secretion of reporter proteins carrying ssVSS but not ctVSS. Our results show that reporters carrying either ssVSS or ctVSS are equally secreted in the absence of VSR1. We discuss our findings in relation to the current model for vacuolar sorting.     

Functional specialization within the vacuolar sorting receptor family: VSR1, VSR3 and VSR4 sort vacuolar storage cargo in seeds and vegetative tissues

Two different gene families have been proposed to act as sorting receptors for vacuolar storage cargo in plants: the vacuolar sorting receptors (VSRs) and the receptor homology‐transmembrane‐RING H2 domain proteins (RMRs). However, functional data on these genes is scarce and the identity of the sorting receptor for storage proteins remains controversial. Through a genetic screen we have identified the mtv2 mutant, which is defective in vacuolar transport of the storage cargo VAC2 in shoot apices. Map‐based cloning revealed that mtv2 is a loss of function allele of the VSR4 gene. We show that VSR1, VSR3 and VSR4, but not the remaining VSRs or RMRs, participate in vacuolar sorting of VAC2 in vegetative tissues, and 12S globulins and 2S albumins in seeds, an activity that is essential for seedling germination vigor. Finally, we demonstrate that the functional diversification in the VSR family results from divergent expression patterns and also from distinct sorting activities of the family members.     

Vacuole biogenesis and protein transport to the plant vacuole: A comparison with the yeast vacuole and the mammalian lysosome

Summary The vacuole is often termed the lytic compartment of the plant cell. The yeast cell also possesses a vacuole containing acid hydrolases. In animal cells these enzymes are localized in the lysosome. Recent research suggests that there is good reason to regard these organelles as homologous in terms of protein transport. Although sorting motifs for the recognition of vacuolar proteins within the endomembrane system differ between the three organelles, there is an underlying similarity in targeting determinants in the cytoplasmic tails of Golgi-based receptors. In all three cases these determinants appear to interact with adaptins of clathrin-coated vesicles which ferry their cargo first of all to an endosomal compartment. The situation in sorting and targeting of plant vacuolar proteins is complicated by the fact that storage and lytic vacuoles may exist together in the same cell. The origin of these two types of vacuole is also a matter of some uncertanity.Abbrevations AP assembly protein - ALP alkaline phosphatase - ARF adenosine diphosphate ribosylation factor - BiP immunoglobulin binding protein - CCV clathrin coated vesicle - CPY carboxypeptidase-Y - DPAP dipeptidyl aminopeptidase - ER endoplasmic reticulum - GApp Golgi apparatus - LAMPs lysosomal associated membrane protein(s) - LAP lysosomal acid phosphatase - LIMPs lysosomal integral membrane protein(s) - MPRs mannosyl 6-phosphate receptors - MVB multivesicular bodies - NSF N-ethylmaleimide sensitive fusion (protein) - PAT phosphinotricine acetyltransferase - PB protein body - PHA phytohemagglutinin - PM plasma membrane - PSV protein storage vacuole - SNAPs soluble NSF attachment protein(s) - SNAREs SNAP receptor(s) - TGN trans Golgi network - TIP tonoplast integral protein - VPS vacuolar protein sorting - ZIO zinc iodide/osmium     

Monoclonal antibodies to barley aleurain and homologs from other plants

Barley aleurain is contained within a specific type of vacuole characterized by acidic pH and the presence of other hydrolytic enzymes. The aleurain-containing vacuole is distinct from protein storage vacuoles, and anti-aleurain antibodies serve as markers for this organelle in barley cells. Aleurain is a unique type of cysteine protease, and other plant species have genes for homologs whose sequences are highly conserved, but little is known about these homologs at the protein level. Seven monoclonal antibodies to barley aleurain were isolated, which bind to and define aleurain homologues in Arabidopsis, Petunia , and tobacco cell extracts. Interestingly, in addition to 29–32 kDa aleurain homologs, Petunia extracts contain a protein of ∼50 kDa and tobacco extracts a protein of ∼40 kDa that are recognized by multiple different mono-clonal antibodies, indicating an unexpected diversity to the aleurain protein family. Among the group of antibodies are some that efficiently immunoprecipitate metabolically labeled aleurain from barley cell extracts, and some that efficiently label aleurain in immunofluorescence assays using root tip cells. These antibodies should be useful for plant cell biologists who study vacuole biogenesis and function and sorting of proteins to specific vacuolar compartments, in barley as well as other plant species.     

The plant vacuolar sorting receptor AtELP is involved in transport of NH(2)-terminal propeptide-containing vacuolar proteins in Arabidopsis thaliana

Many soluble plant vacuolar proteins are sorted away from secreted proteins into small vesicles at the trans-Golgi network by transmembrane cargo receptors. Cleavable vacuolar sorting signals include the NH(2)-terminal propeptide (NTPP) present in sweet potato sporamin (Spo) and the COOH-terminal propeptide (CTPP) present in barley lectin (BL). These two proteins have been found to be transported by different mechanisms to the vacuole. We examined the ability of the vacuolar cargo receptor AtELP to interact with the sorting signals of heterologous and endogenous plant vacuolar proteins in mediating vacuolar transport in Arabidopsis thaliana. AtELP extracted from microsomes was found to interact with the NTPPs of barley aleurain and Spo, but not with the CTPPs of BL or tobacco chitinase, in a pH-dependent and sequence-specific manner. In addition, EM studies revealed the colocalization of AtELP with NTPP-Spo at the Golgi apparatus, but not with BL-CTPP in roots of transgenic Arabidopsis plants. Further, we found that AtELP interacts in a similar manner with the NTPP of the endogenous vacuolar protein AtALEU (Arabidopsis thaliana Aleu), a protein highly homologous to barley aleurain. We hypothesize that AtELP functions as a vacuolar sorting receptor involved in the targeting of NTPP-, but not CTPP-containing proteins in Arabidopsis.     

Plant RMR proteins: unique vacuolar sorting receptors that couple ligand sorting with membrane internalization

In receptor-mediated sorting of soluble protein ligands in the endomembrane system of eukaryotic cells, three completely different receptor proteins for mammalian (mannose 6-phosphate receptor), yeast (Vps10p) and plant cells (vacuolar sorting receptor; VSR) have in common the features of pH-dependent ligand binding and receptor recycling. In striking contrast, the plant receptor homology-transmembrane-RING-H2 (RMR) proteins serve as sorting receptors to a separate type of vacuole, the protein storage vacuole, but do not recycle, and their trafficking pathway results in their internalization into the destination vacuole. Even though plant RMR proteins share high sequence similarity with the best-characterized mammalian PA-TM-RING family proteins, these two families of proteins appear to play distinctly different roles in plant and animal cells. Thus, this minireview focuses on this unique sorting mechanism and traffic of RMR proteins via dense vesicles in various plant cell types.     

Ultrastructure of the pea cotyledon Golgi apparatus: Origin of dense vesicles and the action of brefeldin A

Summary We have followed the action of brefeldin A (BFA) on the Golgi apparatus of developing pea cotyledons, the cells of which are actively engaged in the synthesis and deposition of storage proteins. The Golgi apparatus of normal cells is characterized by the presence of three different types of vesicle: smooth-surfaced secretory vesicles, dense vesicles which carry the storage proteins, and clathrin-coated vesicles (CCV). The dense vesicles originate at the cis cisternae and undergo a maturation as they pass through the Golgi stack, presumably as a result of cisternal progression. CCV bud off from dense and smooth vesicles, which may be attached to one another, at the trans pole of the Golgi apparatus. BFA eliminates the CCV and leads, initially, to an increase in the number and length of the cisternae. Dense vesicles are still to be seen, and many show an increase in diameter. Longer BFA treatments result in a trans-driven vesiculation and an accumulation of vesicles within the vicinity of single cisternae. The vesicles were sometimes seen to be connected to one another via a network of tubules. As judged by immunocytochemistry with gold-coupled legumin and vicilin antisera, some of the dilated vesicles originate directly from dense vesicles by swelling whereas others probably arise by dilation of Golgi cisternae since they possess a layer of flocculent storage proteins at their periphery. By contrast the centre of the dilated vesicles labels positively with antibodies against complex glycans, indicating that the ability to segregate storage proteins from cell wall or lytic vacuole glycoproteins is lost during extended BFA treatment. The effects of BFA are reversible when cotyledons are further incubated on Gamborg's medium for 5 h without the inhibitor.Dedicated to Professor R. Kollmann on the occasion of his 65th birthday.     

pH Regulation by NHX-Type Antiporters Is Required for Receptor-Mediated Protein Trafficking to the Vacuole in Arabidopsis

Protein trafficking requires proper ion and pH homeostasis of the endomembrane system. The NHX-type Na⁺/H⁺ antiporters NHX5 and NHX6 localize to the Golgi, trans-Golgi network, and prevacuolar compartments and are required for growth and trafficking to the vacuole. In the nhx5 nhx6 T-DNA insertional knockouts, the precursors of the 2S albumin and 12S globulin storage proteins accumulated and were missorted to the apoplast. Immunoelectron microscopy revealed the presence of vesicle clusters containing storage protein precursors and vacuolar sorting receptors (VSRs). Isolation and identification of complexes of VSRs with unprocessed 12S globulin by 2D blue-native PAGE/SDS-PAGE indicated that the nhx5 nhx6 knockouts showed compromised receptor-cargo association. In vivo interaction studies using bimolecular fluorescence complementation between VSR2;1, aleurain, and 12S globulin suggested that nhx5 nhx6 knockouts showed a significant reduction of VSR binding to both cargoes. In vivo pH measurements indicated that the lumens of VSR compartments containing aleurain, as well as the trans-Golgi network and prevacuolar compartments, were significantly more acidic in nhx5 nhx6 knockouts. This work demonstrates the importance of NHX5 and NHX6 in maintaining endomembrane luminal pH and supports the notion that proper vacuolar trafficking and proteolytic processing of storage proteins require endomembrane pH homeostasis.     

Vacuolar storage proteins are sorted in the cis-cisternae of the pea cotyledon Golgi apparatus

Developing pea cotyledons contain functionally different vacuoles, a protein storage vacuole and a lytic vacuole. Lumenal as well as membrane proteins of the protein storage vacuole exit the Golgi apparatus in dense vesicles rather than in clathrin-coated vesicles (CCVs). Although the sorting receptor for vacuolar hydrolases BP-80 is present in CCVs, it is not detectable in dense vesicles. To localize these different vacuolar sorting events in the Golgi, we have compared the distribution of vacuolar storage proteins and of alpha-TIP, a membrane protein of the protein storage vacuole, with the distribution of the vacuolar sorting receptor BP-80 across the Golgi stack. Analysis of immunogold labeling from cryosections and from high pressure frozen samples has revealed a steep gradient in the distribution of the storage proteins within the Golgi stack. Intense labeling for storage proteins was registered for the cis-cisternae, contrasting with very low labeling for these antigens in the trans-cisternae. The distribution of BP-80 was the reverse, showing a peak in the trans-Golgi network with very low labeling of the cis-cisternae. These results indicate a spatial separation of different vacuolar sorting events in the Golgi apparatus of developing pea cotyledons.     

The cargo in vacuolar storage protein transport vesicles is stratified

Developing pea seeds contain two functionally distinct vacuoles--lytic vacuoles and protein storage vacuoles (PSV). The Golgi apparatus of these cells has to discriminate between proteins destined for these vacuolar compartments. Whereas it is known that sorting into the lytic vacuole is performed via the conserved clathrin-coated vesicle pathway, sorting of proteins into the protein storage vacuole remains enigmatic. In developing pea cotyledons, the major storage proteins are sorted via 'dense vesicles'. In this report we examined the sorting of a minor protein of the protein storage vacuole, the sucrose-binding-protein homolog (SBP), along the secretory pathway employing immunoelectron microscopy on cryosectioned pea cotyledons. SBP follows the same vesicular route into the PSV as the main storage proteins legumin and vicilin, via the dense-vesicles. Furthermore, legumin and SBP are sorted together into the same dense vesicle population at the stack. Although soluble cargo proteins of the dense vesicles, they show a stratified distribution in the lumen of the dense vesicles. Whereas the legumin label is equally distributed across the lumen, the SBP label is concentrated at the membrane of the vesicle. This observation is discussed with respect to a putative receptor-mediated sorting of the proteins into the dense vesicles.     

Protein mobilization in germinating mung bean seeds involves vacuolar sorting receptors and multivesicular bodies

Plants accumulate and store proteins in protein storage vacuoles (PSVs) during seed development and maturation. Upon seed germination, these storage proteins are mobilized to provide nutrients for seedling growth. However, little is known about the molecular mechanisms of protein degradation during seed germination. Here we test the hypothesis that vacuolar sorting receptor (VSR) proteins play a role in mediating protein degradation in germinating seeds. We demonstrate that both VSR proteins and hydrolytic enzymes are synthesized de novo during mung bean (Vigna radiata) seed germination. Immunogold electron microscopy with VSR antibodies demonstrate that VSRs mainly locate to the peripheral membrane of multivesicular bodies (MVBs), presumably as recycling receptors in day 1 germinating seeds, but become internalized to the MVB lumen, presumably for degradation at day 3 germination. Chemical cross-linking and immunoprecipitation with VSR antibodies have identified the cysteine protease aleurain as a specific VSR-interacting protein in germinating seeds. Further confocal immunofluorescence and immunogold electron microscopy studies demonstrate that VSR and aleurain colocalize to MVBs as well as PSVs in germinating seeds. Thus, MVBs in germinating seeds exercise dual functions: as a storage compartment for proteases that are physically separated from PSVs in the mature seed and as an intermediate compartment for VSR-mediated delivery of proteases from the Golgi apparatus to the PSV for protein degradation during seed germination.     

Cardosin A contains two vacuolar sorting signals using different vacuolar routes in tobacco epidermal cells

Several vacuolar sorting determinants (VSDs) have been described for protein trafficking to the vacuoles in plant cells. Because of the variety in plant models, cell types and experimental approaches used to decipher vacuolar targeting processes, it is not clear whether the three well‐known groups of VSDs identified so far exhaust all the targeting mechanisms, nor if they reflect certain protein types or families. The vacuolar targeting mechanisms of the aspartic proteinases family, for instance, are not yet fully understood. In previous studies, cardosin A has proven to be a good reporter for studying the vacuolar sorting of aspartic proteinases. We therefore propose to explore the roles of two different cardosin A domains, common to several aspartic proteinases [i.e. the plant‐specific insert (PSI) and the C–terminal peptide VGFAEAA] in vacuolar sorting. Several truncated versions of the protein conjugated with fluorescent protein were made, with and without these putative sorting determinants. These domains were also tested independently, for their ability to sort other proteins, rather than cardosin A, to the vacuole. Fluorescent chimaeras were tracked in vivo, by confocal laser scanning microscopy, in Nicotiana tabacum cells. Results demonstrate that either the PSI or the C terminal was necessary and sufficient to direct fluorescent proteins to the vacuole, confirming that they are indeed vacuolar sorting determinants. Further analysis using blockage experiments of the secretory pathway revealed that these two VSDs mediate two different trafficking pathways.