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Storage Vacuoles (storage + vacuole)

Distribution by Scientific Domains
Life Sciences75%

Kinds of Storage Vacuoles

  • protein storage vacuole
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    Selected Abstracts

    Protein disulfide isomerase family proteins involved in soybean protein biogenesis

    FEBS JOURNAL, Issue 3 2007
    Hiroyuki Wadahama
    Protein disulfide isomerase family proteins are known to play important roles in the folding of nascent polypeptides and the formation of disulfide bonds in the endoplasmic reticulum. In this study, we cloned two similar protein disulfide isomerase family genes from soybean leaf (Glycine max L. Merrill cv. Jack) mRNA by RT-PCR using forward and reverse primers designed from the expressed sequence tag clone sequences. The cDNA encodes a protein of either 364 or 362 amino acids, named GmPDIS-1 or GmPDIS-2, respectively. The nucleotide and amino acid sequence identities of GmPDIS-1 and GmPDIS-2 were 68% and 74%, respectively. Both proteins lack the C-terminal, endoplasmic reticulum-retrieval signal, KDEL. Recombinant proteins of both GmPDIS-1 and GmPDIS-2 were expressed in Escherichia coli as soluble folded proteins that showed both an oxidative refolding activity of denatured ribonuclease A and a chaperone activity. Their domain structures were identified as containing two thioredoxin-like domains, a and a,, and an ERp29c domain by peptide mapping with either trypsin or V8 protease. In cotyledon cells, both proteins were shown to distribute to the endoplasmic reticulum and protein storage vacuoles by confocal microscopy. Data from coimmunoprecipitation and crosslinking experiments suggested that GmPDIS-1 associates with proglycinin, a precursor of the seed storage protein glycinin, in the cotyledon. Levels of GmPDIS-1, but not of GmPDIS-2, were increased in cotyledons, where glycinin accumulates during seed development. GmPDIS-1, but not GmPDIS-2, was induced under endoplasmic reticulum-stress conditions. [source]

    A recombinant multimeric immunoglobulin expressed in rice shows assembly-dependent subcellular localization in endosperm cells

    PLANT BIOTECHNOLOGY JOURNAL, Issue 1 2005
    Liz Nicholson
    Summary To investigate the role of subunit assembly in the intracellular deposition of multimeric recombinant proteins, we expressed a partially humanized secretory immunoglobulin in rice endosperm cells and determined the subcellular locations of the assembled protein and its individual components. Transgenic rice plants expressing either individual subunits or all the subunits of the antibody were generated by particle bombardment, and protein localization was determined by immunoelectron microscopy. Assembly of the antibody was confirmed by immunoassay and coimmunoprecipitation. Immunolocalization experiments showed no evidence for secretion of the antibody or any of its components to the apoplast. Rather, the nonassembled light chain, heavy chain and secretory component accumulated predominantly within endoplasmic reticulum-derived protein bodies, while the assembled antibody, with antigen-binding function, accumulated specifically in protein storage vacuoles. These results show that the destination of a complex recombinant protein within the plant cell is influenced by its state of assembly. [source]

    A novel procedure for gentle isolation and separation of intact infected and uninfected protoplasts from the central tissue of Vicia faba L. root nodules

    PLANT CELL & ENVIRONMENT, Issue 7 2003
    E. PEITER
    ABSTRACT The central tissue of Vicia faba L. root nodules is composed of cells infected with Rhizobium bacteroids and uninfected cells. For the study of various processes, such as plasma membrane transport, it is essential to separate both cell types. Initial attempts to isolate protoplasts according to protocols described in the literature resulted in non-spherical and osmotically inactive material, which is in agreement with previous descriptions. In the study reported herein, it was shown that the plasma membrane of non-spherical infected protoplasts is not intact. A new isolation and separation protocol was developed, based on dissection of the nodule prior to cell wall digestion, non-shaking digestion in hypertonic medium, and a combined procedure for release of protoplasts into slightly hypotonic medium and separation of protoplast fractions by isopycnic density gradient centrifugation. Infected and uninfected protoplasts that were isolated according to this protocol were spherical, osmotically active and excluded propidium iodide, confirming the intactness of their plasma membrane. The common fluorescein diacetate test was shown to be artefactual in infected cells, since viable bacteroids also stain in defective cells. Light and electron microscopic examination of infected protoplasts showed that protoplasts still contained starch after isolation and bacteroids in intact protoplasts had unusually high amounts of polyhydroxybutyrate. The vacuoles of infected protoplasts contained protein and membrane-enclosed structures, and were of non-acid pH; traits that are typical of protein storage vacuoles. [source]

    A role for caleosin in degradation of oil-body storage lipid during seed germination

    THE PLANT JOURNAL, Issue 6 2006
    Marianne Poxleitner
    Summary Caleosin is a Ca2+ -binding oil-body surface protein. To assess its role in the degradation of oil-bodies, two independent insertion mutants lacking caleosin were studied. Both mutants demonstrated significant delay of breakdown of the 20:1 storage lipid at 48 and 60 h of germination. Additionally, although germination rates for seeds were not affected by the mutations, mutant seedlings grew more slowly than wild type when measured at 48 h of germination, a defect that was corrected with continued growth for 72 and 96 h in the light. After 48 h of germination, wild-type central vacuoles had smooth contours and demonstrated internalization of oil bodies and of membrane containing , - and , -tonoplast intrinsic proteins (TIPs), markers for protein storage vacuoles. In contrast, mutant central vacuoles had distorted limiting membranes displaying domains with clumps of the two TIPs, and they contained fewer oil bodies. Thus, during germination caleosin plays a role in the degradation of storage lipid in oil bodies. Its role involves both the normal modification of storage vacuole membrane and the interaction of oil bodies with vacuoles. The results indicate that interaction of oil bodies with vacuoles is one mechanism that contributes to the degradation of storage lipid. [source]