A vacuolar sorting domain may also influence the way in which proteins leave the endoplasmic reticulum.

Protein sorting to plant vacuoles is known to be dependent on a considerable variety of protein motifs recognized by a family of sorting receptors. This can involve either traffic from the endoplasmic reticulum (ER) through the Golgi apparatus or direct ER-to-vacuole transport. Barley aspartic protease (Phytepsin) was shown previously to reach the vacuole via trafficking through the Golgi apparatus. Here we show that Phytepsin normally exits the ER in a COPII-mediated manner, because the Phytepsin precursor accumulates in the ER upon specific inhibition of the formation of COPII vesicles in vivo. Phytepsin differs from its yeast and mammalian counterparts by the presence of a saposin-like plant-specific insert (PSI). Deletion of this domain comprising 104 amino acids causes efficient secretion of the truncated molecule (Phytepsin Delta PSI) without affecting the enzymatic activity of the enzyme. Interestingly, deletion of the PSI also changes the way in which Phytepsin exits the ER. Inhibition of COPII vesicle formation causes accumulation of the Phytepsin precursor in the ER but has no effect on the secretion of Phytepsin Delta PSI. This suggests either that vacuolar sorting commences at the ER export step and involves recruitment into COPII vesicles or that the PSI domain carries two signals, one for COPII-dependent export from the ER and one for vacuolar delivery from the Golgi. The relevance of these observations with respect to the bulk flow model of secretory protein synthesis is discussed.

Glycosylation of phytepsin and expression of dad1, dad2 and ost1 during onset of cell death in germinating barley scutella.

Dysfunction and downregulation of dad (defending against death) has been linked to programmed cell death (PCD) in animals and plants. As DAD is an essential subunit of the oligosaccharyltransferase that is located in the ER membrane, the results have raised the possibility that downregulation of N-linked glycosylation could be involved in the regulation of PCD. Here we show that the 16 kDa subunit of phytepsin, a vacuolar proteinase, is normally processed and glycosylated at the onset of DNA fragmentation in germinating barley scutella. Two cDNA clones encoding dad (dad1, dad2), and one cDNA encoding another subunit of the same oligosaccharyltransferase complex (ost1) were isolated from barley. Northern analysis of germinating scutella show that the expression of only dad1 is declining before onset of DNA fragmentation. In contrast to this, the expression of both dad2 and ost1 increase before onset of DNA fragmentation.

Comparative modelling of barley-grain aspartic proteinase: a structural rationale for observed hydrolytic specificity.

A model of the barley-grain aspartic proteinase (HvAP; Hordeum vulgare aspartic proteinase) has been constructed using the rule-based comparative modelling approach encoded in the COMPOSER suite of computer programs. The model was based on the high resolution crystal structures of six highly homologous aspartic proteinases. Results suggest that the overall three-dimensional structure of HvAP (excluding the plant-specific insert; 104 residues in HvAP) is closer to human cathepsin D than other aspartic proteinases of known three-dimensional structure. Comparisons of the complexes with the substrate modelled in the active site of HvAP with those of the same substrate modelled in the active site of other aspartic proteinases of known three-dimensional structure and specificity, define residues that may influence hydrolytic specificity of the barley enzyme. We have identified residues in the S4 (Ala12), S3 (Gln13, Thr111) S2 (Ala222, Thr287, Met289), S'1 and S'3 (Ile291), S'2 and S'3 (Gln74), S'2 (Arg295), and S'3 (Pro292) pockets, that may account for the observed trends in the kinetic behaviour and specificity when compared to other aspartic proteinases. The plant-specific inserted sequence, which may play a role in the transport of HvAP to plant vacuoles (lysosomes), is similar to the saposins and is predicted to be a mixed alpha-helical and beta-strand domain.

Primary structure of a barley-grain aspartic proteinase. A plant aspartic proteinase resembling mammalian cathepsin D.

Two enzymatically active heterodimeric forms of an aspartic proteinase, a putative 32 kDa + 16 kDa precursor form and a putative 29 kDa + 11 kDa mature form, are present in resting barley grains (Sarkkinen, P., Kalkkinen, N., Tilgmann, C., Siuro, J., Kervinen, J. & Mikola, L., 1990, in the press). The cDNA corresponding to this enzyme has been cloned and sequenced. The full-length 1863-bp cDNA sequence codes for an open reading frame of 508 amino acids. The open reading frame consists of a 66-amino acid preprosequence and a 442-amino acid mature protein. Comparison of the N-terminal amino acid sequences of the enzyme subunits with the sequence of the cDNA clone indicates that the heterodimeric enzyme is translated as a proenzyme which is processed into two subunits. The localisation of the experimentally determined N-terminal amino acid sequences of all four subunits (32 kDa + 16 kDa and 29 kDa + 11 kDa) in the same transcript, as well as the detection of only one 2.0-kb mRNA on Northern blots from resting seeds, clearly indicates that the larger (32 kDa + 16 kDa) enzyme is an intermediate precursor form of the smaller (29 kDa + 11 kDa) enzyme. The processing pattern of the barley enzyme, which is the first sequenced plant aspartic proteinase, differs from that of all other known aspartic proteinases. The barley enzyme is highly similar to mammalian and yeast aspartic proteinases, especially to human and porcine cathepsin D. This similarity is clearly dispersed over two regions, separated by a dissimilar, barley-specific region of 104 amino acids.