Transport of proteins to the plant vacuole is not by bulk flow through the secretory system, and requires positive sorting information.

Plant cells, like other eukaryotic cells, use the secretory pathway to target proteins to the vacuolar/lysosomal compartment and to the extracellular space. We wished to determine whether the presence of a hydrophobic signal peptide would result in the transport of a reporter protein to vacuoles by bulk flow; to investigate this question, we expressed a chimeric gene in transgenic tobacco. The chimeric gene, Phalb, used for this study consists of the 1,188-bp 5' upstream sequence and the hydrophobic signal sequence of a vacuolar seed protein phytohemagglutinin, and the coding sequence of a cytosolic seed albumin (PA2). The chimeric protein PHALB cross-reacted with antibodies to PA2 and was found in the seeds of the transgenic plants (approximately 0.7% of total protein), but not in the leaves, roots, or flowers. Immunoblot analyses of seed extracts revealed four glycosylated polypeptides ranging in molecular weight from 29,000 to 32,000. The four polypeptides are glycoforms of a single polypeptide of Mr 27,000, and the heterogeneity is due to the presence of high mannose and endoglycosidase H-resistant glycans. The PHALB products reacted with an antiserum specific for complex plant glycans indicating that the glycans had been modified in the Golgi apparatus. Subcellular fractionation of glycerol extracts of mature seeds showed that only small amounts of PHALB accumulated in the protein storage vacuoles of the tobacco seeds. In homogenates made in an isotonic medium, very little PHALB was associated with the organelle fraction containing the endoplasmic reticulum and Golgi apparatus; most of it was in the soluble fraction. We conclude that PHALB passed through the Golgi apparatus, but did not arrive in the vacuoles. Transport to vacuoles is not by a bulk-flow mechanism, once proteins have entered the secretory system, and requires information beyond that provided by a hydrophobic signal peptide.

Screening for potential child maltreatment in parents of a newborn baby: The predictive validity of an Instrument for early identification of Parents At Risk for child Abuse and Neglect (IPARAN).

For preventive purposes it is important to be able to identify families with a high risk of child maltreatment at an early stage. Therefore we developed an actuarial instrument for screening families with a newborn baby, the Instrument for identification of Parents At Risk for child Abuse and Neglect (IPARAN). The aim of this study was to assess the predictive validity of the IPARAN and to examine whether combining actuarial and clinical methods leads to an improvement of the predictive validity. We examined the predictive validity by calculating several performance indicators (i.e., sensitivity, specificity and the Area Under the receiver operating characteristic Curve [AUC]) in a sample of 4692 Dutch families with newborns. The outcome measure was a report of child maltreatment at Child Protection Services during a follow-up of 3 years. For 17 children (.4%) a report of maltreatment was registered. The predictive validity of the IPARAN was significantly better than chance (AUC=.700, 95% CI [.567-.832]), in contrast to a low value for clinical judgement of nurses of the Youth Health Care Centers (AUC=.591, 95% CI [.422-.759]). The combination of the IPARAN and clinical judgement resulted in the highest predictive validity (AUC=.720, 95% CI [.593-.847]), however, the difference between the methods did not reach statistical significance. The good predictive validity of the IPARAN in combination with clinical judgment of the nurse enables professionals to assess risks at an early stage and to make referrals to early intervention programs.

The upstream domain of soybean oleosin genes contains regulatory elements similar to those of legume storage proteins.

Seed reserve storage products consisting of proteins, oil and starch are accumulated in a developmentally coordinated pattern. The control of the vacuolar storage protein expression has been shown to be transcriptionally regulated and involves a series of positive and negative regulatory as well as enhancing gene elements. We have analyzed the upstream sequence of the genes encoding the soybean oleosins, the protein that encases the oil body. We have found that soybean oleosin genes possess regulatory elements in upstream domain that are similar to those found in vacuolar storage protein genes.

KDEL-Containing Auxin-Binding Protein Is Secreted to the Plasma Membrane and Cell Wall.

The auxin-binding protein ABP1 has been postulated to mediate auxin-induced cellular changes associated with cell expansion. This protein contains the endoplasmic reticulum (ER) retention signal, the tetrapeptide lysine-aspartic acid-glutamic acid-leucine (KDEL), at its carboxy terminus, consistent with previous subcellular fractionation data that indicated an ER location for ABP1. We used electron microscopic immunocytochemistry to identify the subcellular localization of ABP1. Using maize (Zea mays) coleoptile tissue and a black Mexican sweet (BMS) maize cell line, we found that ABP1 is located in the ER as expected, but is also on or closely associated with the plasma membrane and within the cell wall. Labeling of the Golgi apparatus suggests that the transport of ABP1 to the cell wall occurs via the secretory system. Inhibition of secretion of an ABP homolog into the medium of BMS cell cultures by brefeldin A, a drug that specifically blocks secretion, is consistent with this secretion pathway. The secreted protein was recognized by an anti-KDEL peptide antibody, strongly supporting the interpretation that movement of this protein out of the ER does not involve loss of the carboxy-terminal signal. Cells starved for 2,4-dichlorophenoxyacetic acid for 72 h retained less ABP in the cell and secreted more of it into the medium. The significance of our observations is 2-fold. We have identified a KDEL-containing protein that specifically escapes the ER retention system, and we provide an explanation for the apparent discrepancy that most of the ABP is located in the ER, whereas ABP and auxin act at the plasma membrane.

Cotranslational Integration of Soybean (Glycine max) Oil Body Membrane Protein Oleosin into Microsomal Membranes.

Storage triglycerides in oil seeds are sequestered in discrete organelles termed oil bodies. They are bounded by a monolayer of phospholipids in which a few distinct proteins (oleosins) are embedded. Synthesis of soybean (Glycine max) 24-kD oleosin was analyzed by in vitro transcription and translation in reticulocyte lysate in the presence of canine microsomes. Our results show that 24-kD oleosin is cotranslationally integrated into microsomal membranes. We demonstrate that oleosin is integrated into a bilayer membrane in preference to the oil body monolayer membrane, indicating that oleosin is synthesized on the endoplasmic reticulum (ER). A new model of oil body assembly involving a conformational change through initial association with the ER membrane is proposed.

Vacuolar-Type H+ -ATPases Are Associated with the Endoplasmic Reticulum and Provacuoles of Root Tip Cells.

To understand the origin of vacuolar H+ -ATPases (V-ATPases) and their cellular functions, the subcellular location of V-H+ -ATPases was examined immunologically in root cells of oat seedlings. A V-ATPase complex from oat roots consists of a large peripheral sector (V1) that includes the 70-kD (A) catalytic and the 60-kD (B) regulatory subunits. The soluble V1 complex, thought to be synthesized in the cytoplasm, is assembled with the membrane integral sector (V0) at a yet undefined location. In mature cells, V-ATPase subunits A and B, detected in immunoblots with monoclonal antibodies (Mab) (7A5 and 2E7), were associated mainly with vacuolar membranes (20-22% sucrose) fractionated with an isopycnic sucrose gradient. However, in immature root tip cells, which lack large vacuoles, most of the V-ATPase was localized with the endoplasmic reticulum (ER) at 28 to 31% sucrose where a major ER-resident binding protein equilibrated. The peripheral subunits were also associated with membranes at 22% sucrose, at 31 to 34% sucrose (Golgi), and in plasma membranes at 38% sucrose. Immunogold labeling of root tip cells with Mab 2E7 against subunit B showed gold particles decorating the ER as well as numerous small vesicles (0.1-0.3 [mu]m diameter), presumably pro-vacuoles. The immunological detection of the peripheral subunit B on the ER supports a model in which the V1 sector is assembled with the V0 on the ER. These results support the model in which the central vacuolar membrane originates ultimately from the ER. The presence of V-ATPases on several endomembranes indicates that this pump could participate in diverse functional roles.

Uptake and apparent digestion of cytoplasmic organelles by protein bodies (protein storage vacuoles) in mung bean cotyledons.

The large protein bodies of the storage parenchyma cells of mung bean (Vigna radiata) cotyledons contain vesicles measuring 0.2 to 2.0 mum in diameter. The vesicles contain ribosomes, ribosomes, membranous elements which may be derived from the endoplasmic reticulum and occasionally Golgi bodies and mitochondria. The vesicles can be seen by transmission electron microscopy in thin sections of plastic embedded specimens and in replicas of freeze-fractured preparations. Serial sections show that the vesicles are completely separated from the protein body membrane and are not invaginations of that membrane. Vesicles with cytoplasmic structures are seen most frequently in 2 to 4 day old seedlings. The vesicles may be formed when undulations of the protein body membrane are so deep as to permit the pinching-off of a portion of the cytoplasm, resulting in its subsequent isolation from the cytoplasm within the protein body. The digestion of the storage protein in the protein body is accompanied by the disappearance of the ribosomes and the membranous elements in the vesicles. We interpret this disappearance of the cytoplasmic structures in the vesicles as being due to their digestion by the protein body hydrolases (ribonuclease, proteinase and lipolytic enzymes). The uptake of cytoplasmic structures by the protein bodies continues after the reverse proteins have been digested. Cytochemical staining shows that the protein bodies and especially the vesicles are rich in acid phosphatase, a known marker of lytic activity in cells. The evidence presented here indicates that the protein bodies are the intracellular sites at which the digestion of cytoplasmic structure occurs. Protein bodies should therefore be considered not only as compartments for the hydrolysis of the stored protein, but also as autophagic organelles involved in the degradation of cytoplasmic macromolecules. The term protein bodies is well established, but the term protein storage vacuoles may describe these organelles more precisely.

Immunogold-localization and synthesis of an oil-body membrane protein in developing soybean seeds.

The synthesis of a major oil-body membrane brotein was studied in maturing soybean (Glycine max (L.) Merr.) cotyledons. The membrane contained four abundant proteins with apparent molecular mass (Mr) of 34000, 24000, 18000 and 17000. The Mr=24000 protein (mP 24) was selected for more detailed analysis. The protein was purified to apparent homogeneity by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and isolated from the gel by electroelution or chemical hydrolysis of gel crosslinks. It was then used to elicit rabbit antibodies which were judged to be specific when assayed by SDS-PAGE-immunoblot procedures. The mP 24 was localized in immature soybean cotyledon cells by indirect immunogold procedures on thin sections of Lowicryl- and LR-White-embedded tissue. Indirect labeling with the primary antiserum followed by colloidal gold-protein A showed specific labeling of the oil-body membrane and an absence of label on the other subcellular organelles including the endoplasmic reticulum (ER). Parallel tissue samples were studied by conventional transmission electron microscopy. Although segments of the ER were observed to be closely juxtaposed to the oil bodies, continuity between the two organelles was not observed. The synthesis of mP 24 was studied by in-vitro translation and in-vivo labeling with [(3)H]leucine followed by indirect immunoaffinity isolation of the labeled products. The SDS-PAGE fluorography results indicated that the primary translation product and the in-vivo synthesized protein have the same Mr, and this is also the same Mr as the protein in the mature membrane.

Immunocytochemical localization of concanavalin A in developing jack-bean cotyledons.

The lectin, concanavalin A (Con A), was localized in the cotyledon of developing jack beans (Canavalia ensiformis (L.) DC) by electron-microscope immunocytochemistry. In mature seeds, Con A was present in protein-storage vacuoles (protein bodies) of storage-parenchyma cells. Although protein bodies could be seen in other cell types, only protein bodies in storage-parenchyma cells contained Con A. During seed development, Con A was also localized on the endoplasmic reticulum and Golgi apparatus, presumably en route toward deposition within the protein bodies. The intensity of labeling of the endoplasmic reticulum was much greater during the developmental stage of protein-body filling (66% final seed weight) than in mature seeds.

Accumulation and Subcellular Localization of alpha-Galactosidase-Hemagglutinin in Developing Soybean Cotyledons.

We have investigated the accumulation and intracellular localization of soybean (Glycine max [L.] Merr. cv Forrest) alpha-galactosidase-hemagglutinin during seed development. Cotyledon tissue was embedded in Lowicryl K4M and immunocytochemical localization was accomplished through treating thin sections with alpha-galactosidase antisera followed by indirect labeling with protein A coupled to colloidal gold. Gold particles were localized on the Golgi apparatus and protein bodies. We interpret this to indicate that alpha-galactosidase-hemagglutinin is transferred to and transported through the Golgi apparatus and finally deposited within the protein body by a Golgi apparatus-mediated process.

TIP, an integral membrane protein of the protein-storage vacuoles of the soybean cotyledon undergoes developmentally regulated membrane accumulation and removal.

Protein storage vacuoles (PSVs) in soybean (Glycine max (L.) Merr.) cotyledon cells are formed by subdivision of the central vacuole early in seed maturation. They persist until the fifth or sixth day after germination when the central vacuole re-forms. The major integral membrane protein of PSVs, called Tonoplast Integral Protein or TIP, is highly conserved in the seeds of higher plants (K.D. Johnson et al. 1989, Plant Physiol. 91, 1006-1013). The primary sequence of TIP indicates that it may be a pore protein, although of unknown function (K.D. Johnson et al. 1990, Plant Cell 2, 525-532). TIP is apparently seed-specific and is localized in the protein-storage-vacuole membrane of the storageparenchyma cells and the tonoplast of provascular cells. Using correlated immunoblot and electron microscopicimmunocytochemical assays, we have studied TIP accumulation during seed maturation and its disappearance during seed germination. We have determined that the accumulation of TIP in the protein-storage-vacuole membrane is not correlated with the presence or concentration of stored protein in the organelle. Accumulation of TIP occurs primarily after the division of the central vacuole into protein-storage vacuoles is complete and most of the stored protein has been deposited. Transport of TIP to the PSV membrane is apparently mediated by the Golgi apparatus. Quantitative SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis)-immunoblots indicate that, after germination is initiated, TIP abundance is unchanged for the first 4d, but that between days 5 and 7 of growth its abundance decreases drastically. TIP is removed from the PSV membrane prior to the completion of storageprotein mobilization and concurrently with re-formation of the central vacuole. The mechanism of TIP removal appears to involve autophagic sequestering of membrane inside the PSV. The developmental regulation of TIP insertion and removal indicates a physiological function of TIP during late seed maturation or early seedling growth.

Arabinogalactan-rich glycoproteins are localized on the cell surface and in intravacuolar multivesicular bodies.

We investigated the subcellular distribution of antigenic sites immunoreactive to the monoclonal antibody 16.4B4 (PM Norman, VPM Wingate, MS Fitter, CJ Lamb [1986] Planta 167: 452-459) in tobacco (Nicotiana tabacum) leaf cells. This antibody is directed against a glycan epitope in a family of plasma membrane arabinogalactan proteins of 135 to 180 kilodaltons, elaborated from a polypeptide of relative molecular mass 50 kilodaltons (PM Norman, P Kjellbom, DJ Bradley, MG Hahn, CJ Lamb [1990] Planta 181: 365-373). We demonstrated by immunogold electron microscopy that the epitope reactive with monoclonal antibody 16.4B4 is localized on the cell surface in the leaf parenchyma cell periplast. The 16.4B4 antigen is also localized in multivesicular invaginations of the plasma membrane also known as plasmalemmasomes, implying a biochemical and, hence, functional interrelationship between these structures. Monoclonal antibody 16.4B4 also labels intracellular multivesicular bodies that appear to represent internalized plasmalemmasomes. Antibody reactivity was also observed in partially degraded multivesicular bodies sequestered within the central vacuole. We propose that the subcellular distribution of the epitope reactive with monoclonal antibody 16.4B4 defines a plasmalemmasome (or multivesicular body-mediated) pathway for the internalization of the periplasmic matrix for vacuolar mediated disposal. The multivesicular bodies appear to be equivalent to the well-characterized endosomes and multivesicular bodies of animal cells involved in the internalization and lysosome-mediated degradation of extracellular materials.

Characteristics and subcellular localization of phospholipase d and phosphatidic Acid phosphatase in mung bean cotyledons.

Mixed micelles of (32)P-labeled phosphatidylcholine or phosphatidic acid (PA) and the nonionic detergent octylphenol polyethylene oxide (NP-40 Nonidet) were used to assay the activities of phospholipase D and PA phosphatase in crude extracts of mung bean (Vigna radiata) cotyledons. Together these enzymes degrade phosphatidylcholine to free choline, inorganic phosphate, and sn-1,2-diacylglycerol. Both enzymes have pH optima around 5.0. The enzymes are present in fully imbibed cotyledons and increase in activity during seedling growth. Fractionation of cotyledon extracts on sucrose gradients showed that the cells contain two PA phosphatases. One enzyme with a pH optimum of 7.5 has the same distribution on sucrose gradient as the endoplasmic reticulum marker enzyme NADH-cytochrome c reductase. The other, PA phosphatase, with a pH optimum of 5.0, was present in a protein body-rich fraction and in the load portion of the gradient. Fractionation of broken protoplasts on Ficoll gradients (a method which allows for the isolation of a high proportion of intact protein bodies) indicates that most of the cellular phospholipase D and PA phosphatase (pH 5.0) are associated with the protein bodies. Using column chromatography (DEAE-cellulose and Sephadex G-200), PA phosphatase (pH 5.0) was found to be a different enzyme from the major acid phosphatase in the cotyledons. Apparent molecular weights of phospholipase D and PA phosphatase were 150,000 and 37,000, respectively. The activity of phospholipase D was not affected by free choline, but was markedly inhibited by the choline analog and plant growth retardant isopropyl 4'-(trimethylammonium chloride-5'-methylphenyl piperidine-1-carboxylate (AMO 1618). The finding that these acid hydrolases are located in the protein bodies supports the conclusion that protein bodies form the general lytic compartment in the storage parenchyma cells.

Bark and Leaf Lectins of Sophora japonica Are Sequestered in Protein-Storage Vacuoles.

The leguminous tree Sophora japonica contains a family of closely related, but distinct, lectins. Different members of this family are independently expressed in seeds, leaves, and bark (CN Hankins, J Kindinger, LM Shannon 1987 Plant Physiol 83: 825-829; 1988 Plant Physiol 86: 67-10). The inter-, and intracellular distribution of the bark and leaf lectins was studied by indirect postembedding immunogold electron microscopy. Aldehyde fixed bark and leaves postifixed with OsO(4) and embedded in LR White resin permitted sensitive and specific immunogold labeling while maintaining cellular ultrastructure. The leaf and bark tissue cells contain protein-filled storage vacuoles which occupy most the cell's interior volume. The leaf and bark vacuoles closely resemble the protein bodies, or protein storage vacuoles, of seed cotyledons. The leaf and bark lectins were found to be exclusively sequestered in the protein-storage vacuoles of these tissues.

Concanavalin A is synthesized as a glycoprotein precursor.

Concanavalin A (Con A) is a tetrameric lectin which is synthesized in the cotyledons of developing jack-bean (Canavalia ensiformis (L.) D.C.) seeds and accumulates in the protein bodies of storage-parenchyma cells. The polypeptides of Con A have a molecular weight of 27000 and a relative molecular mass (Mr) of 30000 when analyzed by gel electrophoresis on denaturing polyacrylamide gels. In-vitro translation of RNA isolated from immature jack-bean cotyledons shows that Con A is synthesized as a polypeptide with Mr 34000. In-vivo pulse labeling of cotyledons with radioactive amino acids or glucosamine also resulted in the formation of a 34000-Mr polypeptide. In-vivo labeling with radioactive amino acids in the presence of tunicamycin yielded an additional polypeptide of 32000 Mr. Together these results indicate that Con A is cotranslationally processed by the removal of a signal sequence and the addition of an oligosaccharide side chain of corresponding size. Analysis of the structure of the oligogosaccharide side chain was accomplished through glycosidase digestion of glycopeptides isolated from [(3)H]glucosamine-labeled Con A. Incubation of the labeled glycopeptides with endoglycosidase H, α-mannosidase or ß-N-acetylglucosaminidase, followed by gel filtration, allowed us to deduce that the oligosaccharide side chain of pro-Con A is a high-mannose oligosaccharide. Pulse-chase experiments with labeled amino acids are consistent with the interpretation that the glycosylated precursor of Con A is processed to mature Con A (Mr=30000). The 4000 decrease in Mr is interpreted to result from the removal of a small glycopeptide. The implications of the conversion of a glycoprotein pro-Con A to mature Con A are discussed in the context of the unique circular permutation of the primary structure of Con A.

Apparent processing of a soybean oil body protein accompanies the onset of oil mobilization.

The membrane surrounding the oil body contains several different specific polypeptides. To study the biosynthesis and posttranslational modification of these polypeptides we have prepared monoclonal antibodies against purified oil bodies of soybean (Glycine max). Three of the five monoclonals selected recognize a molecular mass 34 kilodalton protein (P34). Epitope mapping of CNBr and proteolytic fragments of P34 indicates that two of the anti-P34 monoclonal antibodies are directed at different epitopes. P34 is accumulated during seed maturation at the same time as the reserve proteins and oil. SDS/PAGE-immunoblots of germinating soybean seed cotyledons indicate that the protein is initially present as a molecular mass 34 kilodalton polypeptide and is processed to molecular mass 32 kilodalton on the fourth through sixth days of seedling growth simultaneously with the onset of oil mobilization. A comparison of reduced and carboxymethylated oil body proteins with nonreduced proteins by SDS/PAGE indicates that P34 exists in vivo as a dimer of molecular mass 58 kilodalton. Comparing the amino terminal sequences of P34 and P32 indicates that their difference is at least in part due to the removal of the amino terminus of P34. The amino terminal sequences of P34 and P32 were aligned to show that the transition of P34 to P32 was accompanied by the removal of a hydrophilic decapeptide (KKMKKEQYSC) at the amino terminus of P34. Hopp-Woods hydrophilicity analysis of the deleted amino terminus of P34 shows that it is more hydrophilic and charged than the sequence of the protein which immediately follows.

Correct post-translational modification and stable vacuolar accumulation of phytohemagglutinin engineered to contain multiple methionine residues.

Most legume seed storage proteins are deficient in sulfur amino acids. In this study, we demonstrate that replacing specific amino acid residues of a seed protein with methionine residues at positions known to be occupied by methionine residues in homologous proteins, is an effective strategy to create methionine-enriched seed proteins. Mutant phytohemagglutinin polypeptides with three or four methionine residues were found to undergo correct post-translational modifications in transformed cultured tobacco cells and to accumulate stably in the protein storage vacuoles of transgenic tobacco seeds.

An abundant, highly conserved tonoplast protein in seeds.

We have isolated the membranes of the protein storage vacuoles (protein bodies) from Phaseolus vulgaris cotyledons and purified an integral membrane protein with M(r) 25,000 (TP 25). Antiserum to TP 25 recognizes an abundant polypeptide in the total cell extracts of many different seeds (monocots, dicots, and a gymnosperm), and specifically labels the vacuolar membranes of thin-sectioned soybean embryonic axes and cotyledons. TP 25 was not found in the starchy endosperm of barley and wheat or the seed coats of bean but was present in all seed parts examined that consist of living cells at seed maturity. The abundance of TP 25 was not correlated with the amount of storage protein in seed tissue, and the protein was not found in leaves that accumulate leaf storage protein. On the basis of its abundance, evolutionary conservation, and distribution in the plant, we propose that TP 25 may play a role in maintaining the integrity of the tonoplast during the dehydration/rehydration sequence of seeds.

In vitro mutated phytohemagglutinin genes expressed in tobacco seeds: role of glycans in protein targeting and stability.

Phytohemagglutinin is a glycoprotein that accumulates in the protein storage vacuoles of bean seeds. The mature glycoprotein has a high-mannose and a complex glycan. We describe here the use of site-directed mutagenesis and expression of the mutated genes in transgenic tobacco to study the role of glycans in intracellular targeting. The reading frame for phytohemagglutinin-L was mutated so that either one or both of the glycosylation signals were disrupted to specifically prevent the attachment of asparagine-linked glycans. Expression of these genes with the beta-phaseolin promoter in the seeds of transgenic tobacco plants showed that phytohemagglutinin-L with only one glycan or without glycans was correctly targeted to the protein storage vacuoles of the seeds. Furthermore, the absence of either the complex glycan or the high-mannose glycan did not alter the processing of the other glycan. On the basis of these results, we propose that the targeting signal of this vacuolar protein is contained in its polypeptide domain and not in its glycans.