The N-terminal propeptide of the precursor to sporamin acts as a vacuole-targeting signal even at the C terminus of the mature part in tobacco cells.

An asparagine-proline-isoleucine-arginine-leucine (NPIRL) and its related sequences in the N-terminal propeptides (NTPP) of several plant vacuolar proteins, including that of sporamin from sweet potato (SPO) function as vacuole-targeting determinants in a manner that is distinct from the vacuole-targeting determinant in the CTPPs of other plant vacuolar proteins. When the mutant precursor to sporamin, SPO-NTPP (in which NTPP was moved to the C terminus of the mature part), was expressed in tobacco (Nicotiana tabacum) cells, the pro-form was efficiently targeted to the vacuole and the NTPP was cleaved off. Unlike the results obtained with the wild-type precursor, substitution of the NPIRL sequence in the C-terminally located NTPP to asparagine-proline-glycine-arginine-leucine in the SPO-isoleucine-28-to-glycine mutant resulted in missorting of less than 20% of the pro-form to the medium. Unlike the vacuolar transport of SPO-NTPP, the vacuolar transport of SPO-isoleucine-28-to-glycine was strongly inhibited by 33 microM wortmannin, which is similar to the C-terminal propeptide-mediated vacuolar transport. These results suggest that the vacuole-targeting function of the NPIRL sequence is not strictly dependent on its location at the N terminus of a protein and that the C-terminally located mutant NTPP acquired some physicochemical properties of the C-terminal vacuole-targeting sequence.     

Different sensitivity to wortmannin of two vacuolar sorting signals indicates the presence of distinct sorting machineries in tobacco cells

Vacuolar matrix proteins in plant cells are sorted from the secretory pathway to the vacuoles at the Golgi apparatus. Previously, we reported that the NH2-terminal propeptide (NTPP) of the sporamin precursor and the COOH-terminal propeptide (CTPP) of the barley lectin precursor contain information for vacuolar sorting. To analyze whether these propeptides are interchangeable, we expressed constructs consisting of wild-type or mutated NTPP with the mature part of barley lectin and sporamin with CTPP and mutated NTPP in tobacco BY-2 cells. The vacuolar localization of these constructs indicated that the signals were interchangeable. We next analyzed the effect of wortmannin, a specific inhibitor of mammalian phosphatidylinositol (PI) 3-kinase on vacuolar delivery by NTPP and CTPP in tobacco cells. Pulse-chase analysis indicated that 33 microM wortmannin caused almost complete inhibition of CTPP-mediated transport to the vacuoles, while NTPP-mediated transport displayed almost no sensitivity to wortmannin at this concentration. This indicates that there are at least two different mechanisms for vacuolar sorting in tobacco cells, and the CTPP-mediated pathway is sensitive to wortmannin. We compared the dose dependencies of wortmannin on the inhibition of CTPP-mediated vacuolar delivery of proteins and on the inhibition of the synthesis of phospholipids in tobacco cells. Wortmannin inhibited PI 3- and PI 4-kinase activities and phospholipid synthesis. Missorting caused by wortmannin displays a dose dependency that is similar to the dose dependency for the inhibition of synthesis of PI 4-phosphate and major phospholipids. This is different, however, than the inhibition of synthesis of PI 3- phosphate. Thus, the synthesis of phospholipids could be involved in CTPP-mediated vacuolar transport.     

O-glycosylation of a precursor to a sweet potato vacuolar protein, sporamin, expressed in tobacco cells

Sporamin, a vacuolar protein of the sweet potato, is synthesized as a precursor that contains signal peptide and an N-terminal propeptide that functions as a vacuolar targeting determinant. Sporamin, when expressed in tobacco cells, migrated as smeared bands on an SDS-polyacrylamide gel. The smearing was due to O-glycosylation of the precursor to sporamin. The smeared bands were stained by a glycan-specific stain but no N-glycosylation site was found in the amino acid sequence of the precursor to sporamin. The glycan attached to sporamin contained galactose and arabinose as major sugar components. Mutations that altered the Pro³⁶ or Ser³⁹ residue of the precursor to sporamin prevented glycosylation of the protein, and analysis by semiquantitative Edman degradation suggested that a glycan moiety was attached to Pro³⁶ and, possibly, to Ser³⁹. Pulse-labeling and cell-fractionation experiments revealed that the O-glycosylation of the precursor to sporamin occurred in the Golgi apparatus. Thus, this modification serves as a good marker of the transport from the endoplasmic reticulum (ER) to the Golgi apparatus of the precursor to sporamin. Treatment of transformed tobacco cells with brefeldin A (BFA) caused the intracellular accumulation of prosporamin that did not migrate as smeared bands. Thus, it appeared that BFA inhibited the transport of the precursor to sporamin to the Golgi apparatus. This result provides the first biochemical evidence that BFA inhibits transport from the ER to the Golgi apparatus in plant cells.     

Activity of the C-terminal-dependent vacuolar sorting signal of horseradish peroxidase C1a is enhanced by its secondary structure

Plant class III peroxidase (PRX) catalyzes the oxidation and oxidative polymerization of a variety of phenolic compounds while reducing hydrogen peroxide. PRX proteins are classified into apoplast type and vacuole type based on the absence or the presence of C-terminal propeptides, which probably function as vacuolar sorting signals (VSSs). In this study, in order to improve our understanding of vacuole-type PRX, we analyzed regulatory mechanisms of vacuolar sorting of a model vacuole-type PRX, the C1a isozyme of horseradish (Armoracia rusticana) (HRP C1a). Using cultured transgenic tobacco cells and protoplasts derived from horseradish leaves, we characterized HRP C1a's VSS, which is a 15 amino acid C-terminal propeptide (C15). We found that the C-terminal hexapeptide of C15 (C6), which is well conserved among vacuole-type PRX proteins, forms the core of the C-terminal-dependent VSS. We also found that the function of C6 is enhanced by the remaining N-terminal part of C15 which probably folds into an amphiphilic α-helix.     

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.     

Transport of a Sweet Potato Storage Protein, Sporamin, to the Vacuole in Yeast Cells

The propeptide of a precursor to sporamin, a storage proteinof sweet potato, is required for targeting of sporamin to thevacuole in transformed tobacco cells (Matsuoka and Nakamura1991). A fusion gene consisting of an inducible GAL 10 promoterand sporamin cDNA was introduced into Saccharomyces cerevisiaeby use either of a multiple-copy plasmid (YEpSAD16) or of asingle-copy plasmid (YCpSAD16) to control the level of expressionof the precursor. Although we could not detect any sporamin-relatedpolypeptides in cells that harbored YCpSAD16, extracts fromcells that harbored YEpSAD16 contained multiple forms of sporaminrelatedpolypeptides: preprosporamin, prosporamin and several polypeptidesthat were smaller than prosporamin. However, YCpSAD16 directedthe accumulation of prosporamin in pep4 mutant yeast cells thatlack vacuolar proteases, andpep4 mutant cells that harboredYEpSAD16 did not contain any sporamin-related polypeptides smallerthan prosporamin. The vacuole fractions isolated from the wild-typeand pep4 mutant cells contained sporamin-related polypeptidessmaller than prosporamin and prosporamin, respectively. Theseand other results suggest that, at a low level of expressionof the precursor, prosporamin is transported to the vacuoleand degraded by vacuolar proteases. A mutant precursor to sporamin,in which the propeptide and the N-terminal region of maturesporamin were replaced by an unrelated sequence of four aminoacid residues, directed the secretion of sporamin to the culturemedium in transformed tobacco cells. However, this mutationdid not affect the transport of sporamin to the vacuole in yeastcells and none of the sporamin-related polypeptides were secretedto the extracellular space. (Received July 16, 1991; Accepted March 25, 1992)     

Cis-elements of protein transport to the plant vacuoles

Vacuolar proteins are synthesized and translocated into the endoplasmic reticulum and transported to the vacuoles through the secretory pathway. Three different types of vacuolar sorting signals have been identified, carried by N- or C-terminal propeptides or internal sequences. These signals are needed to target proteins to the different types of vacuoles that can coexist in a single plant cell. A conserved motif (NPIXL or NPIR) was identified within N-terminal propeptides, but can also function in a C-terminal propeptide and targets proteins in a receptor-mediated manner to a lytic vacuole. Binding to a family of putative sorting receptors for sequence-specific vacuolar sorting signals has been used as an assay to identify further peptides with other binding motifs. No motif was found in C-terminal sorting sequences, which need an accessible terminus, suggesting that they are recognized from the end by a still unknown receptor. The phosphatidylinositol kinase inhibitor wortmannin differentially affects sorting mediated by these two sorting sequences, suggesting different sorting mechanisms. Less is known about sorting mediated by internal protein sequences, which do not contain the conserved motif identified in N-terminal propeptides and by function by aggregation, leading to transport by coat-less dense vesicles to protein storage vacuoles. Even less is known about the sorting of tonoplast proteins, for which several sorting systems will also be needed.     

Vacuolar targeting and posttranslational processing of the precursor to the sweet potato tuberous root storage protein in heterologous plant cells

Sporamin, the tuberous root storage protein of the sweet potato, which is localized in vacuoles, is synthesized as a prepro-precursor with an N-terminal sequence of amino acids that includes a signal peptide and an additional pro-segment of 16 amino acids. A full-length cDNA for sporamin was placed downstream of the 35 S promoter of cauliflower mosaic virus and introduced into tobacco and sunflower genomes by Ti plasmid-mediated transformation. A polypeptide of nearly the same size as mature sporamin from the sweet potato was detected in transformed calli of tobacco and sunflower, as well as in the leaves, stems, and roots of regenerated, transgenic tobacco plants. Amino acid sequence analysis of the nearly mature-sized form of sporamin from the transformed tobacco cells revealed that it is actually longer by three amino acids at its N terminus than authentic sporamin purified from the sweet potato. By pulse labeling of suspension-cultured tobacco cells with [35S]methionine, the pro-form of the precursor to sporamin, but not the prepro-precursor, was detected. The 35S-labeled proform was chased to the nearly mature-sized form via an intermediate form which is slightly larger than the nearly mature-sized form. Analysis by Edman degradation of the intermediate form that was labeled in vivo with [3H]histidine suggested that it is longer by two amino acids at its N terminus than the nearly mature-sized form of sporamin. These results suggest that at least two steps of posttranslational processing of the pro-form occurs sequentially in tobacco cells. The posttranslational processing of the pro-form of the precursor to sporamin was inhibited by monensin, suggesting that this step takes place in the acidic compartment, probably in the vacuole. All of the sporamin polypeptides synthesized in transformed tobacco cells were retained inside the cell and sporamin was localized in the vacuole, as judged from results of subcellular fractionation. These results indicate that sporamin is appropriately targeted to the vacuole in tobacco cells.     

Colocalization of barley lectin and sporamin in vacuoles of transgenic tobacco plants.

Various targeting motifs have been identified for plant proteins delivered to the vacuole. For barley (Hordeum vulgare) lectin, a typical Gramineae lectin and defense-related protein, the vacuolar information is contained in a carboxyl-terminal propeptide. In contrast, the vacuolar targeting information of sporamin, a storage protein from the tuberous roots of the sweet potato (Ipomoea batatas), is encoded in an amino-terminal propeptide. Both proteins were expressed simultaneously in transgenic tobacco plants to enable analysis of their posttranslational processing and subcellular localization by pulse-chase labeling and electron-microscopic immunocytochemical methods. The pulse-chase experiments demonstrated that processing and delivery to the vacuole are not impaired by the simultaneous expression of barley lectin and sporamin. Both proteins were targeted quantitatively to the vacuole, indicating that the carboxyl-terminal and amino-terminal propeptides are equally recognized by the vacuolar protein-sorting machinery. Double-labeling experiments showed that barley lectin and sporamin accumulate in the same vacuole of transgenic tobacco (Nicotiana tabacum) leaf and root cells.     

Cloning and sequence analysis of the ces10 gene encoding a Sphingomonas paucimobilis esterase

Peroxidases (PRX, EC 1.11.1.7) are widely distributed across microorganisms, plants, and animals; and, in plants, they have been implicated in a variety of secondary metabolic reactions. In particular, horseradish (Armoracia rusticana) root represents the main source of commercial PRX production. The prxC1a gene, which encodes horseradish PRX (HRP) C, is expressed mainly in the roots and stems of the horseradish plant. HRP C1a protein is shown to be synthesized as a preprotein with both a N-terminal (NTPP) and a C-terminal propeptide (CTPP). These propeptides, which might be responsible for intracellular localization or secretion, are removed before or concomitant with production of the mature protein. We investigated the functional role of HRP C1a NTPP and CTPP in the determination of the vesicular transport route, using an analytical system of transgenically cultured tobacco cells (Nicotiana tabacum, BY2). Here, we report that NTPP and CTPP are necessary and sufficient for accurate localization of mature HRP C1a protein to vacuoles of the vesicular transport system. We also demonstrate that HRP C1a derived from a preprotein lacking CTPP is shunted into the secretory pathway.     

Soybean peroxidase propeptides are functional signal peptides and increase the yield of a foreign protein

Elements that contribute to the high, stable yield of soybean peroxidase (SBP) in soybean seed coats can be exploited in the development of this tissue as a protein production platform. SBP contains an N-terminal and a C-terminal propeptide that are predicted to direct vacuolar targeting; this may be one factor that contributes to its high yield and stability. We characterized the function of the SBP propeptides and investigated their ability to increase the yield of a foreign protein in a heterologous plant system. SBP propeptides are functional signal peptides capable of directing vacuolar transport in Arabidopsis. The use of these propeptides as well as an endoplasmic reticulum (ER)-retention signal to direct a foreign protein to the apoplast, ER, or vacuole can significantly increase yield and will therefore be useful for the development of the seed coat as a protein production platform. We also demonstrate that growth conditions may have a significant impact on the yield of a foreign protein and that this may be subcellular compartment-specific.     

Localization of a flavonoid biosynthetic polyphenol oxidase in vacuoles

Aureusidin synthase, a polyphenol oxidase (PPO), specifically catalyzes the oxidative formation of aurones from chalcones, which are plant flavonoids, and is responsible for the yellow coloration of snapdragon (Antirrhinum majus) flowers. All known PPOs have been found to be localized in plastids, whereas flavonoid biosynthesis is thought to take place in the cytoplasm [or on the cytoplasmic surface of the endoplasmic reticulum (ER)]. However, the primary structural characteristics of aureusidin synthase and some of its molecular properties argue against localization of the enzyme in plastids and the cytoplasm. In this study, the subcellular localization of the enzyme in petal cells of the yellow snapdragon was investigated. Sucrose-density gradient and differential centrifugation analyses suggested that the enzyme (the 39-kDa mature form) is not located in plastids or on the ER. Transient assays using a green fluorescent protein (GFP) chimera fused with the putative propeptide of the PPO precursor suggested that the enzyme was localized within the vacuole lumen. We also found that the necessary information for vacuolar targeting of the PPO was encoded within the 53-residue N-terminal sequence (NTPP), but not in the C-terminal sequence of the precursor. NTPP-mediated ER-to-Golgi trafficking to vacuoles was confirmed by means of the co-expression of an NTPP-GFP chimera with a dominant negative mutant of the Arabidopsis GTPase Sar1 or with a monomeric red fluorescent protein (mRFP)-fused Golgi marker (an H+-translocating inorganic pyrophosphatase of Arabidopsis). We identified a sequence-specific vacuolar sorting determinant in the NTPP of the precursor. We have demonstrated the biosynthesis of a flavonoid skeleton in vacuoles. The findings of this metabolic compartmentation may provide a strategy for overcoming the biochemical instability of the precursor chalcones in the cytoplasm, thus leading to the efficient accumulation of aurones in the flower.     

Efficient developmental mis-targeting by the sporamin NTPP vacuolar signal to plastids in young leaves of sugarcane and <Emphasis Type="Italic">Arabidopsis</Emphasis>

Plant vacuoles are multi-functional, developmentally varied and can occupy up to 90% of plant cells. The N-terminal propeptide (NTPP) of sweet potato sporamin and the C-terminal propeptide (CTPP) of tobacco chitinase have been developed as models to target some heterologous proteins to vacuoles but so far tested on only a few plant species, vacuole types and payload proteins. Most studies have focused on lytic and protein-storage vacuoles, which may differ substantially from the sugar-storage vacuoles in crops like sugarcane. Our results extend the evidence that NTPP of sporamin can direct heterologous proteins to vacuoles in diverse plant species and indicate that sugarcane sucrose-storage vacuoles (like the lytic vacuoles in other plant species) are hostile to heterologous proteins. A low level of cytosolic NTPP-GFP (green fluorescent protein) was detectable in most cell types in sugarcane and Arabidopsis, but only Arabidopsis mature leaf mesophyll cells accumulated NTPP-GFP to detectable levels in vacuoles. Unexpectedly, efficient developmental mis-trafficking of NTPP-GFP to chloroplasts was found in young leaf mesophyll cells of both species. Vacuolar targeting by tobacco chitinase CTPP was inefficient in sugarcane, leaving substantial cytoplasmic activity of rat lysosomal -glucuronidase (GUS) [ER (endoplasmic reticulum)-RGUS-CTPP]. Sporamin NTPP is a promising targeting signal for studies of vacuolar function and for metabolic engineering. Such applications must take account of the efficient developmental mis-targeting by the signal and the instability of most introduced proteins, even in storage vacuoles.     

Large alkyl side-chains of isoleucine and leucine in the NPIRL region constitute the core of the vacuolar sorting determinant of sporamin precursor

The N-terminal propeptide of the sporamin precursor contains vacuolar targeting information within the Asn-26/Pro-27/Ile-28/Arg-29/Leu-30 (NPIRL) sequence. An Agrobacterium-mediated transient expression assay with tobacco BY-2 cells was employed to investigate the role of each amino acid of the NPIRL region in vacuolar targeting. Replacement of Asn-26, Pro-27, Ile-28 and Leu-30 with several amino acids caused secretion of the mutant prosporamin. Leu was the only amino acid that could be substituted for Ile-28 without affecting transport. Exchange of Leu-30 for amino acids with small side-chains abolished vacuolar delivery. These results indicate that the consensus composition of the NPIRL sequence is [preferably Asn]-[not acidic]-[Ile or Leu]-[any amino acid]-[large and hydrophobic] and suggest that the large alkyl side-chains of Ile-28 and Leu-30 constitute the core of the vacuolar sorting determinant.     

The vacuolar targeting signal of the 2S albumin from Brazil nut resides at the C terminus and involves the C-terminal propeptide as an essential element.

Genetic constructs in which different N- and C-terminal segments of Brazil nut (Bertholletia excelsa H.B.K.) 2S albumin were fused to secretory yeast invertase were transformed into tobacco (Nicotiana tabacum) plants to investigate the vacuolar targeting signal of the 2S albumin. None of the N-terminal segments, including the complete precursor containing all propeptides, was able to direct the invertase to the vacuoles. However, a short C-terminal segment comprising the last 20 amino acids of the precursor was sufficient for efficient targeting of yeast invertase to the vacuoles of the transformed tobacco plants. Further analyses showed that peptides of 16 and 13 amino acids of the C-terminal segment were still sufficient, although they had slightly lower efficiency. When segments of 9 amino acids or shorter were analyzed, a decrease to approximately 30% was observed. These segments included the C-terminal propeptide of four amino acids (Ile-Ala-Gly-Phe). When the 2S albumin was expressed in tobacco, it was also localized to the vacuoles of mesophyll cells. If the C-terminal propeptide was deleted from the 2S albumin precursor, all of this truncated 2S albumin was secreted from the tobacco cells. These results indicate that the C-terminal propeptide is necessary but not sufficient for vacuolar targeting. In addition, an adjacent segment of at least 12 amino acids of the mature protein is needed to form the complete signal for efficient targeting.     

Primary structure and expression of a 24-kD vacuolar protein (VP24) precursor in anthocyanin-producing cells of sweet potato in suspension culture

A 24-kD vacuolar protein (VP24) accumulates abundantly in intravacuolar pigmented globules in anthocyanin-containing sweet potato (Ipomoea batatas) cells in suspension culture. A cDNA clone encoding VP24 was isolated from a cDNA library constructed from light-irradiated suspension-cultured cells. Sequence analysis revealed that a 2.9-kbp VP24 cDNA encodes a protein of 893 amino acid residues with a molecular mass of 96.3 kD. According to the deduced amino acid sequence of VP24 cDNA, VP24 is probably synthesized as a large precursor protein with an N-terminal extension composed of a signal peptide and a propeptide, plus the polypeptide of the mature VP24 and its C-terminal propeptide, which contains the multiple transmembrane domains. A search in the ProDom database revealed the mature VP24 domain belongs to the zinc metalloprotease family. Northern analysis revealed that the single 2.9-kb VP24 mRNA increases rapidly after light irradiation, whereas VP24 mRNA was undetectable in the dark-cultured cells or in the presence of a high concentration of 2,4-dichlorophenoxyacetic acid. Light-induced VP24 gene expression closely correlated with the accumulation of anthocyanin in the vacuoles. These results suggested that proteins derived from the VP24 precursor protein may be involved in vacuolar transport and/or accumulation of anthocyanin synthesized in the cytosol.     

Extensive post-translational processing of potato tuber storage proteins and vacuolar targeting

Potato tuber storage proteins were obtained from vacuoles isolated from field-grown starch potato tubers cv. Kuras. Vacuole sap proteins fractionated by gel filtration were studied by mass spectrometric analyses of trypsin and chymotrypsin digestions. The tuber vacuole appears to be a typical protein storage vacuole absent of proteolytic and glycolytic enzymes. The major soluble storage proteins included 28 Kunitz protease inhibitors, nine protease inhibitors 1, eight protease inhibitors 2, two carboxypeptidase inhibitors, eight patatins and five lipoxygenases (lox), which all showed cultivar-specific sequence variations. These proteins, except for lox, have typical endoplasmic reticulum (ER) signal peptides and putative vacuolar sorting determinants of either the sequence or structure specific type or the C-terminal type, or both. Unexpectedly, sap protein variants imported via the ER showed multiple molecular forms because of extensive and unspecific proteolytic cleavage of exposed N- and C-terminal propeptides and surface loops, in spite of the abundance of protease inhibitors. Some propeptides are potential novel vacuolar targeting peptides. In the insoluble vacuole fraction two variants of phytepsin (aspartate protease) were identified. These are most probably the processing enzymes of potato tuber vacuolar proteins. Database Proteome data have been submitted to the PRIDE database under accession number 17707.     

Enzymic and structural studies on processed proteins from the vacuolar (lutoid-body) fraction of latex of Hevea brasiliensis

The lutoid-body (bottom) fraction of latex from the rubber tree (Hevea brasiliensis) contains a limited number of major proteins. These are the chitin-binding protein hevein, its precursor and C-terminal fragment of the precursor, a basic chitinase/lysozyme, and a β-1,3-glucanase. The content and properties of the latter enzyme differ between lutoid-body fractions from four different rubber clones (cultivars). While the enzyme from clone GT.1 is a glycoprotein with carbohydrate attached to two glycosylation sites, the enzymes from other clones contain little or no carbohydrate. Latex from clone GT.1 has a higher β-1,3-glucanase content than those from the other three clones, but with a significantly lower specific activity. The enzyme exhibits a pH optimum at 4.5, but there is a second one at 6.7. Peptides isolated from β-1,3-glucanase of clone GT.1 showed that the enzyme is heterogeneous at the C-terminus, probably as a result of removal of a vacuolar targeting sequence by an endopeptidase, followed by further removal of C-terminal residues by a carboxypeptidase-like activity. This incomplete digestion can be related to glycosylation at the extreme C-terminus of the mature enzyme. Non-glycosylated Hevea β-1,3-glucanases exhibit less C-terminal heterogeneity. A homologue of the antifungal protein osmotin was isolated from rubber clones which are less susceptible to fungal diseases. Another identified protein is identical to a citrate binding protein (CBP), already sequenced as cDNA, but with cleaved-off N-terminal signal and C-terminal vacuolar targeting peptides. Four C-terminal propeptides of vacuolar proteins in Hevea are positively identified, which is a valuable contribution to previously known examples of this type of processing.     

Identifying MHC class I epitopes by predicting the TAP transport efficiency of epitope precursors

We are able to make reliable predictions of the efficiency with which peptides of arbitrary lengths will be transported by TAP. The pressure exerted by TAP on Ag presentation thus can be assessed by checking to what extent MHC class I (MHC-I)-presented epitopes can be discriminated from random peptides on the basis of predicted TAP transport efficiencies alone. Best discriminations were obtained when N-terminally prolonged epitope precursor peptides were included and the contribution of the N-terminal residues to the score were down-weighted in comparison with the contribution of the C terminus. We provide evidence that two factors may account for this N-terminal down-weighting: 1) the uncertainty as to which precursors are used in vivo and 2) the coevolution in the C-terminal sequence specificities of TAP and other agents in the pathway, which may vary among the various MHC-I alleles. Combining predictions of MHC-I binding affinities with predictions of TAP transport efficiency led to an improved identification of epitopes, which was not the case when predictions of MHC-I binding affinities were combined with predictions of C-terminal cleavages made by the proteasome.