AtRMR1 functions as a cargo receptor for protein trafficking to the protein storage vacuole

Organellar proteins are sorted by cargo receptors on the way to their final destination. However, receptors for proteins that are destined for the protein storage vacuole (PSV) are largely unknown. In this study, we investigated the biological role that Arabidopsis thaliana receptor homology region transmembrane domain ring H2 motif protein (AtRMR) 1 plays in protein trafficking to the PSV. AtRMR1 mainly colocalized to the prevacuolar compartment of the PSV, but a minor portion also localized to the Golgi complex. The coexpression of AtRMR1 mutants that were localized to the Golgi complex strongly inhibited the trafficking of phaseolin to the PSV and caused accumulation of phaseolin in the Golgi complex or its secretion. Co-immunoprecipitation and in vitro binding assays revealed that the lumenal domain of AtRMR1 interacts with the COOH-terminal sorting signal of phaseolin at acidic pH. Furthermore, phaseolin colocalized with AtRMR1 on its way to the PSV. Based on these results, we propose that AtRMR1 functions as the sorting receptor of phaseolin for its trafficking to the PSV.     

Biogenesis of the protein storage vacuole crystalloid

We identify new organelles associated with the vacuolar system in plant cells. These organelles are defined biochemically by their internal content of three integral membrane proteins: a chimeric reporter protein that moves there directly from the ER; a specific tonoplast intrinsic protein; and a novel receptor-like RING-H2 protein that traffics through the Golgi apparatus. Highly conserved homologues of the latter are expressed in animal cells. In a developmentally regulated manner, the organelles are taken up into vacuoles where, in seed protein storage vacuoles, they form a membrane-containing crystalloid. The uptake and preservation of the contents of these organelles in vacuoles represents a unique mechanism for compartmentalization of protein and lipid for storage.     

Protein sorting and expression of a unique soybean cotyledon protein,GmSBP, destined for the protein storage vacuole

The initial biochemical characterization of the soybean sucrose-binding protein, GmSBP, within our lab and others produced several incongruous characteristics that required a re-characterization of GmSBP via sequence homology, cell biology, immunolocalization, and semi-quantitative analysis. The GmSBP proteins share amino acid sequence homology as well as putative structural homology with globulin-like seed storage proteins. A comparison to the major soybean seed storage proteins, glycinin and -conglycinin established several storage protein-like characteristics for GmSBP. All three proteins were present in a prevacuolar compartment and protein storage vacuole. All three proteins increased in expression during seed development and are remobilized during germination. Quantitatively, the relative concentrations of GmSBP, -conglycinin (/ subunits), and glycinin (acidic subunits) indicated that GmSBP contributes 19-fold less to the stored nitrogen. The quantitative differences between GmSBP and glycinin may be attributed to the unconserved order and spacing of cis-acting regulatory elements present within the promoter regions. Ultimately, GmSBP is transported to the mature protein storage vacuole. The biological function of GmSBP within the protein storage vacuole remains uncertain, but its localization is a remnant of its evolutionary link to a globulin-like or vicilin-like ancestor that gave rise to the 7S family of storage proteins.     

The protein storage vacuole: a unique compound organelle.

Storage proteins are deposited into protein storage vacuoles (PSVs) during plant seed development and maturation and stably accumulate to high levels; subsequently, during germination the storage proteins are rapidly degraded to provide nutrients for use by the embryo. Here, we show that a PSV has within it a membrane-bound compartment containing crystals of phytic acid and proteins that are characteristic of a lytic vacuole. This compound organization, a vacuole within a vacuole whereby storage functions are separated from lytic functions, has not been described previously for organelles within the secretory pathway of eukaryotic cells. The partitioning of storage and lytic functions within the same vacuole may reflect the need to keep the functions separate during seed development and maturation and yet provide a ready source of digestive enzymes to initiate degradative processes early in germination.     

Identification of the leaf vacuole as a major nitrate storage pool

Highly purified vacuoles were isolated from protoplasts derived from green barley (Hordeum vulgare var. Numar) leaves, in order to determine their role as a NO₃⁻ storage sink. α-Mannosidase and acid phosphatase activities were used as markers to identify vacuoles, α-mannosidase being the more suitable. Nitrate and α-mannosidase, which were released from vacuoles destroyed during lysis of protoplasts, moved at unequal rates in the density gradient used for vacuole isolation. Purified vacuoles retained less NO₃⁻ than α-mannosidase during a single washing. Empirically determined corrections were used to account for NO₃⁻ movement in estimating the percentage of total cellular nitrate found in the vacuole. Vacuoles from plants grown in the presence of NO₃⁻ contained 58% of the total cellular NO₃⁻ and therefore represent a major NO₃⁻ storage pool.     

Identification of the protein storage vacuole and protein targeting to the vacuole in leaf cells of three plant species

Protein storage vacuoles (PSVs) are specialized vacuoles devoted to the accumulation of large amounts of protein in the storage tissues of plants. In this study, we investigated the presence of the storage vacuole and protein trafficking to the compartment in cells of tobacco (Nicotiana tabacum), common bean (Phaseolus vulgaris), and Arabidopsis leaf tissue. When we expressed phaseolin, the major storage protein of common bean, or an epitope-tagged version of alpha-tonoplast intrinsic protein (alpha-TIP, a tonoplast aquaporin of PSV), in protoplasts derived from leaf tissues, these proteins were targeted to a compartment ranging in size from 2 to 5 microm in all three plant species. Most Arabidopsis leaf cells have one of these organelles. In contrast, from one to five these organelles occurred in bean and tobacco leaf cells. Also, endogenous alpha-TIP is localized in a similar compartment in untransformed leaf cells of common bean and is colocalized with transiently expressed epitope-tagged alpha-TIP. In Arabidopsis, phaseolin contained N-glycans modified by Golgi enzymes and its traffic was sensitive to brefeldin A. However, trafficking of alpha-TIP was insensitive to brefeldin A treatment and was not affected by the dominant-negative mutant of AtRab1. In addition, a modified alpha-TIP with an insertion of an N-glycosylation site has the endoplasmic reticulum-type glycans. Finally, the early step of phaseolin traffic, from the endoplasmic reticulum to the Golgi complex, required the activity of the small GTPase Sar1p, a key component of coat protein complex II-coated vesicles, independent of the presence of the vacuolar sorting signal in phaseolin. Based on these results, we propose that the proteins we analyzed are targeted to the PSV or equivalent organelle in leaf cells and that proteins can be transported to the PSV by two different pathways, the Golgi-dependent and Golgi-independent pathways, depending on the individual cargo proteins.     

Delivery of prolamins to the protein storage vacuole in maize aleurone cells

Zeins, the prolamin storage proteins found in maize (Zea mays), accumulate in accretions called protein bodies inside the endoplasmic reticulum (ER) of starchy endosperm cells. We found that genes encoding zeins, α-globulin, and legumin-1 are transcribed not only in the starchy endosperm but also in aleurone cells. Unlike the starchy endosperm, aleurone cells accumulate these storage proteins inside protein storage vacuoles (PSVs) instead of the ER. Aleurone PSVs contain zein-rich protein inclusions, a matrix, and a large system of intravacuolar membranes. After being assembled in the ER, zeins are delivered to the aleurone PSVs in atypical prevacuolar compartments that seem to arise at least partially by autophagy and consist of multilayered membranes and engulfed cytoplasmic material. The zein-containing prevacuolar compartments are neither surrounded by a double membrane nor decorated by AUTOPHAGY RELATED8 protein, suggesting that they are not typical autophagosomes. The PSV matrix contains glycoproteins that are trafficked through a Golgi-multivesicular body (MVB) pathway. MVBs likely fuse with the multilayered, autophagic compartments before merging with the PSV. The presence of similar PSVs also containing prolamins and large systems of intravacuolar membranes in wheat (Triticum aestivum) and barley (Hordeum vulgare) starchy endosperm suggests that this trafficking mechanism may be common among cereals.     

The control of storage xyloglucan mobilization in cotyledons of Hymenaea courbaril

Hymenaea courbaril is a leguminous tree species from the neotropical rain forests. Its cotyledons are largely enriched with a storage cell wall polysaccharide (xyloglucan). Studies of cell wall storage polymers have been focused mostly on the mechanisms of their disassembly, whereas the control of their mobilization and the relationship between their metabolism and seedling development is not well understood. Here, we show that xyloglucan mobilization is strictly controlled by the development of first leaves of the seedling, with the start of its degradation occurring after the beginning of eophyll (first leaves) expansion. During the period of storage mobilization, an increase in the levels of xyloglucan hydrolases, starch, and free sugars were observed in the cotyledons. Xyloglucan mobilization was inhibited by shoot excision, darkness, and by treatment with the auxin-transport inhibitor N-1-naphthylphthalamic acid. Analyses of endogenous indole-3-acetic acid in the cotyledons revealed that its increase in concentration is followed by the rise in xyloglucan hydrolase activities, indicating that auxin is directly related to xyloglucan mobilization. Cotyledons detached during xyloglucan mobilization and treated with 2,4-dichlorophenoxyacetic acid showed a similar mobilization rate as in attached cotyledons. This hormonal control is probably essential for the ecophysiological performance of this species in their natural environment since it is the main factor responsible for promoting synchronism between shoot growth and reserve degradation. This is likely to increase the efficiency of carbon reserves utilization by the growing seedling in the understorey light conditions of the rain forest.     

Dual lipolytic control of body fat storage and mobilization in Drosophila

Energy homeostasis is a fundamental property of animal life, providing a genetically fixed balance between fat storage and mobilization. The importance of body fat regulation is emphasized by dysfunctions resulting in obesity and lipodystrophy in humans. Packaging of storage fat in intracellular lipid droplets, and the various molecules and mechanisms guiding storage-fat mobilization, are conserved between mammals and insects. We generated a Drosophila mutant lacking the receptor (AKHR) of the adipokinetic hormone signaling pathway, an insect lipolytic pathway related to ß-adrenergic signaling in mammals. Combined genetic, physiological, and biochemical analyses provide in vivo evidence that AKHR is as important for chronic accumulation and acute mobilization of storage fat as is the Brummer lipase, the homolog of mammalian adipose triglyceride lipase (ATGL). Simultaneous loss of Brummer and AKHR causes extreme obesity and blocks acute storage-fat mobilization in flies. Our data demonstrate that storage-fat mobilization in the fly is coordinated by two lipocatabolic systems, which are essential to adjust normal body fat content and ensure lifelong fat-storage homeostasis.     

Sugars as a metabolic regulator of storage protein mobilization in germinating seeds of yellow lupine (Lupinus luteus L.)

The intensity of protein reserve activation in yellow lupine (Lupinus luteus L.) organs cultured in vitro in the presence of saccharose and without sugar in the medium was studied. Isolated embryo axes, excised cotyledons and seeds deprived of their testae were grown on Heller medium: a) with 60 mM saccharose (+S), b) without sugar (−S) and c) for 72 hours without saccharose + for 24 hours in the presence of saccharose (−S→+S). Using nitroanilide substrates, exo- and endopeptidase proteolytic activity was investigated in enzymatic extracts. Proteolytic activity was examined in organs isolated from swollen seeds and also in organs cultured for 24, 48, 72 and 96 hours. The proteolytic activity was higher in organs cultured on medium without saccharose. Stimulation of the proteolytic activity on the first day of culture was not significant, but intensified in the successive days of culture. The organ subcultured onto a medium with saccharose (−S→+S) caused a significant limitation of proteolytic activity, even to a markedly lower level in comparison to that activity level in the material continuously supplemented with saccharose. Observations of ultrastructure in Transmission Electron Microscopy revealed increased protein body degradation in the absence of saccharose in the medium and an increased degree of cell vacuolization, which may be indicative of intensifying autophagic processes under conditions of carbohydrate deficit.     

Protein quality control along the route to the plant vacuole.

To acquire information on the relationships between structural maturation of proteins in the endoplasmic reticulum (ER) and their transport along the secretory pathway, we have analyzed the destiny of an assembly-defective form of the trimeric vacuolar storage glycoprotein phaseolin. In leaves of transgenic tobacco, where assembly-competent phaseolin is correctly targeted to the vacuole, defective phaseolin remains located in the ER or a closely related compartment where it represents a major ligand of the chaperone BiP. Defective phaseolin maintained susceptibility to endoglycosidase H and was slowly degraded by a process that is not inhibited by heat shock or brefeldin A, indicating that degradation does not involve transport along the secretory pathway. These results provide evidence for the presence of a quality control mechanism in the ER of plant cells that avoids intracellular trafficking of severely defective proteins and eventually leads to their degradation.     

Identification of a membrane-associated cysteine protease with possible dual roles in the endoplasmic reticulum and protein storage vacuole

SH-EP is a vacuolar cysteine proteinase from germinated seeds of Vigna mungo. The enzyme has a C-terminal propeptide of 1 kDa that contains an endoplasmic reticulum (ER) retention signal, KDEL. The KDEL-tail has been suggested to function to store SH-EP as a transient zymogen in the lumen of the ER, and the C-terminal propeptide was thought to be removed within the ER or immediately after exit from the ER. In the present study, a protease that may be involved in the post-translational processing of the C-terminal propeptide of SH-EP was isolated from the microsomes of cotyledons of V. muno seedlings. cDNA sequence for the protease indicated that the enzyme is a member of the papain superfamily. Immunocytochemistry and subcellular fractionation of cotyledon cells suggested that the protease was localized in both the ER and protein storage vacuoles as enzymatically active mature form. In addition, protein fractionations of the cotyledonary microsome and Sf9 cells expressing the recombinant protease indicated that the enzyme associates with the microsomal membrane on the luminal side. The protease was named membrane-associated cysteine protease, MCP. The possibility that a papain-type enzyme, MCP, exists as mature enzyme in both ER and protein storage vacuoles will be discussed.     

The role of the vacuole in the accumulation and mobilization of sucrose

The contribution that isolated vacuoles have made to understanding sucrose storage and mobilization is reviewed briefly, with particular reference to the storage root of red beet (Beta vulgaris L.). Work with isolated vacuoles has shown that in this tissue sucrose is confined to the vacuole and some progress has been made in elucidating the possible mechanism of sucrose transport into the vacuole. The evidence that this is a H⁺: sucrose antiport, dependent on the activity of a proton-translocating ATPase is examined. It is concluded that while there is some evidence for the presence of a proton pump, a link between this and sucrose uptake has still to be established. Using isolated vacuoles it has been demonstrated that during mobilization of sucrose, hydrolysis occurs within the vacuole but the mechanism of unloading of hexoses from the vacuole remains to be elucidated.     

Selective membrane protein internalization accompanies movement from the endoplasmic reticulum to the protein storage vacuole pathway in Arabidopsis

In plant cells, certain membrane proteins move by unknown mechanisms directly from the endoplasmic reticulum (ER) to prevacuolar or vacuole-like organelles where membrane is internalized to form a dense, lattice-like structure. Here, we identify a sequence motif, PIEPPPHH, in the cytoplasmic tail of a membrane protein that directs the protein from the ER to vacuoles where it is internalized. A type II membrane protein in Arabidopsis thaliana, (At)SRC2 (for Soybean Gene Regulated by Cold-2), binds specifically to PIEPPPHH and moves from the ER to the same vacuoles where it is internalized. Not all proteins that move in this pathway are internalized because another Arabidopsis type II membrane protein, (At)VAP (for Vesicle-Associated Protein), localizes to the same organelles but remains exposed on the limiting membrane. The identification of (At)SRC2 and its preference for interaction with a targeting motif specific for the ER-to-vacuole pathway may provide tools for future dissection of mechanisms involved in this unique trafficking system.     

Growth control in the Salmonella-containing vacuole

Salmonella enterica is an intracellular bacterial pathogen that inhabits membrane-bound vacuoles of eukaryotic cells. Coined as the 'Salmonella-containing vacuole' (SCV), this compartment has been studied for two decades as a replicative niche. Recent findings reveal, however, marked differences in the lifestyle of bacteria enclosed in the SCV of varied host cell types. In fibroblasts, the emerging view supports a model of bacteria facing in the SCV a 'to grow' or 'not to grow' dilemma, which is solved by entering in a dormancy-like state. Fine-tuning of host cell defense/survival routes, drastic metabolic shift down, adaptation to hypoxia conditions, and attenuation of own virulence systems emerge as strategies used by Salmonella to intentionally reduce the growth rate inside the SCV.     

Membrane anchors effectively traffic recombinant human glucocerebrosidase to the protein storage vacuole of Arabidopsis seeds but do not adequately control N-glycan maturation

Key message

Human glucocerebrosidase with vacuolar anchoring domains was targeted to protein storage vacuoles (PSVs) of Arabidopsis seeds, but unexpectedly via the Golgi complex. PSV-targeting to effectively avoid problematic N-glycans is protein dependent.

Abstract

Plant-specific N-glycosylation patterns elaborated within the Golgi complex are a major limitation of using plants to produce biopharmaceuticals as the presence of β1,2 xylose and/or α1,3 fucose residues on the recombinant glycoprotein can render the product immunogenic if administrated parenterally. A reporter protein fused to a vacuolar membrane targeting motif comprised of the BP-80 transmembrane domain (TMD), and the cytoplasmic tail (CT) of α-tonoplast intrinsic protein (α-TIP) is delivered to protein storage vacuoles (PSVs) of tobacco seeds by ER-derived transport vesicles that bypass the Golgi complex. This prompted us to investigate whether a pharmaceutical glycoprotein is targeted to PSVs using the same targeting sequences, thus avoiding the unwanted plant-Golgi-specific complex N-glycan modifications. The human lysosomal acid β-glucosidase (glucocerebrosidase; GCase) (EC 3.2.1.45) fused to the BP-80 TMD and α-TIP CT was produced in Arabidopsis thaliana wild-type (Col-0) seeds. The chimeric GCase became localized in PSVs but transited through the Golgi complex, as indicated by biochemical analyses of the recombinant protein’s N-glycans. Our findings suggest that use of this PSV-targeting strategy to avoid problematic N-glycan maturation on recombinant therapeutic proteins is not consistently effective, as it is likely protein- and/or species-specific.     

Genetic control of chloroplast pigment development in soybeans as a function of leaf and plant maturity

Changes in the major chloroplast pigments of pigment-deficient genotypes of soybeans were studied as a function of leaf age and plant age. The trends of pigment development are plotted as a function of relative leaf age at two periods of plant development. Comparisons are made between aging leaves from different nodes and leaves of different ages from the same node. In addition, trends of pigment development are expressed as a ratio of pigment-deficient/normal genotypes for five different genotypes and seven sampling periods. Those genotypes that exhibit a lag in production of pigments during leaf development show a similar lag in overall plant pigment development.     

Dual roles of Bradyrhizobium japonicum nickelin protein in nickel storage and GTP-dependent Ni mobilization

The hydrogenase accessory protein HypB, or nickelin, has two functions in the N(2)-fixing, H(2)-oxidizing bacterium Bradyrhizobium japonicum. One function of HypB involves the mobilization of nickel into hydrogenase. HypB also carries out a nickel storage/sequestering function in B. japonicum, binding nine nickel ions per monomer. Here we report that the two roles (nickel mobilization and storage) of HypB can be separated in vitro and in vivo using molecular and biochemical approaches. The role of HypB in hydrogenase maturation is completely dependent on its intrinsic GTPase activity; strains which produce a HypB protein that is severely deficient in GTPase activity but that fully retains nickel-sequestering ability cannot produce active hydrogenase even upon prolonged nickel supplementation. A HypB protein that lacks the nickel-binding polyhistidine region near the N terminus lacks only the nickel storage capacity function; it is still able to bind a single nickel ion and also retains complete GTPase activity.     

Enolase activates homotypic vacuole fusion and protein transport to the vacuole in yeast

Membrane fusion and protein trafficking to the vacuole are complex processes involving many proteins and lipids. Cytosol from Saccharomyces cerevisiae contains a high Mr activity, which stimulates the in vitro homotypic fusion of isolated yeast vacuoles. Here we purify this activity and identify it as enolase (Eno1p and Eno2p). Enolase is a cytosolic glycolytic enzyme, but a small portion of enolase is bound to vacuoles. Recombinant Eno1p or Eno2p stimulates in vitro vacuole fusion, as does a catalytically inactive mutant enolase, suggesting a role for enolase in fusion that is separate from its glycolytic function. Either deletion of the non-essential ENO1 gene or diminished expression of the essential ENO2 gene causes vacuole fragmentation in vivo, reflecting reduced fusion. Combining an ENO1 deletion with ENO2-deficient expression causes a more severe fragmentation phenotype. Vacuoles from enolase 1 and 2-deficient cells are unable to fuse in vitro. Immunoblots of vacuoles from wild type and mutant strains reveal that enolase deficiency also prevents normal protein sorting to the vacuole, exacerbating the fusion defect. Band 3 has been shown to bind glycolytic enzymes to membranes of mammalian erythrocytes. Bor1p, the yeast band 3 homolog, localizes to the vacuole. Its loss results in the mislocalization of enolase and other vacuole fusion proteins. These studies show that enolase stimulates vacuole fusion and that enolase and Bor1p regulate selective protein trafficking to the vacuole.