| scholarly article | Q13442814 |
| P819 | ADS bibcode | 1994PNAS...91.3403K |
| P356 | DOI | 10.1073/PNAS.91.8.3403 |
| P932 | PMC publication ID | 43585 |
| P698 | PubMed publication ID | 8159760 |
| P5875 | ResearchGate publication ID | 15039017 |
| P50 | author | Nadine Paris | Q68477597 |
| P2093 | author name string | J M Butler | |
| T Kirsch | |||
| J C Rogers | |||
| L Beevers | |||
| P2860 | cites work | Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedure and some applications | Q24561689 |
| Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4 | Q25938983 | ||
| Basic local alignment search tool | Q25938991 | ||
| The biogenesis of lysosomes | Q29617860 | ||
| Structure and function of the mannose 6-phosphate/insulinlike growth factor II receptors | Q34236758 | ||
| Intracellular trafficking of secretory proteins | Q35779623 | ||
| Propeptide of a precursor to a plant vacuolar protein required for vacuolar targeting | Q37387173 | ||
| A short C-terminal sequence is necessary and sufficient for the targeting of chitinases to the plant vacuole | Q37625857 | ||
| Protein targeting to the vacuole in plant cells | Q40799610 | ||
| Proaleurain vacuolar targeting is mediated by short contiguous peptide interactions | Q43460307 | ||
| Involvement of the Golgi Apparatus in the Synthesis and Secretion of Hydroxyproline-rich Cell Wall Glycoproteins | Q46857166 | ||
| Coated Vesicles Are Involved in the Transport of Storage Proteins during Seed Development in Pisum sativum L. | Q47923308 | ||
| Isozymes of beta-N-Acetylhexosaminidase from Pea Seeds (Pisum sativum L.). | Q47927099 | ||
| Transmembrane orientation of the mannose 6-phosphate receptor in isolated clathrin-coated vesicles | Q48462040 | ||
| The barley lectin carboxyl-terminal propeptide is a vacuolar protein sorting determinant in plants | Q67895029 | ||
| Different legumin protein domains act as vacuolar targeting signals | Q67908765 | ||
| Reproducible high yield sequencing of proteins electrophoretically separated and transferred to an inert support | Q68328289 | ||
| The cation-independent mannose 6-phosphate receptor binds insulin-like growth factor II | Q70046899 | ||
| Uncoating of clathrin-coated vesicles by uncoating ATPase from developing peas | Q72530698 | ||
| Colocalization of barley lectin and sporamin in vacuoles of transgenic tobacco plants | Q72699094 | ||
| P433 | issue | 8 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 3403-3407 | |
| P577 | publication date | 1994-04-01 | |
| P1433 | published in | Proceedings of the National Academy of Sciences of the United States of America | Q1146531 |
| P1476 | title | Purification and initial characterization of a potential plant vacuolar targeting receptor | |
| P478 | volume | 91 |
| Q47871443 | A Secretion System for Cargo Protein Identification of Vacuolar Sorting Receptors |
| Q74801347 | A Vacuolar-Type H+-ATPase in a Nonvacuolar Organelle Is Required for the Sorting of Soluble Vacuolar Protein Precursors in Tobacco Cells |
| Q74770834 | A Vacuole-Associated Annexin Protein, VCaB42, Correlates with the Expansion of Tobacco Cells |
| Q39746797 | A fluorescent reporter protein containing AtRMR1 domains is targeted to the storage and central vacuoles in Arabidopsis thaliana and tobacco leaf cells |
| Q47985227 | A mobile secretory vesicle cluster involved in mass transport from the Golgi to the plant cell exterior |
| Q36280368 | A putative vacuolar cargo receptor partially colocalizes with AtPEP12p on a prevacuolar compartment in Arabidopsis roots |
| Q52846496 | A recycling-defective vacuolar sorting receptor reveals an intermediate compartment situated between prevacuoles and vacuoles in tobacco. |
| Q28350955 | A vacuolar sorting domain may also influence the way in which proteins leave the endoplasmic reticulum |
| Q49441328 | A vacuolar sorting receptor-independent sorting mechanism for storage vacuoles in soybean seeds |
| Q48308717 | Activation of the Rab7 GTPase by the MON1-CCZ1 Complex Is Essential for PVC-to-Vacuole Trafficking and Plant Growth in Arabidopsis. |
| Q34041194 | An Arabidopsis syntaxin homologue isolated by functional complementation of a yeast pep12 mutant |
| Q44173277 | An in vivo expression system for the identification of cargo proteins of vacuolar sorting receptors in Arabidopsis culture cells. |
| Q50697676 | Arabidopsis vacuolar sorting mutants (green fluorescent seed) can be identified efficiently by secretion of vacuole-targeted green fluorescent protein in their seeds. |
| Q35961137 | AtNHX5 and AtNHX6 Are Required for the Subcellular Localization of the SNARE Complex That Mediates the Trafficking of Seed Storage Proteins in Arabidopsis |
| Q41878776 | AtRMR1 functions as a cargo receptor for protein trafficking to the protein storage vacuole |
| Q51792417 | AtVPS45 is a positive regulator of the SYP41/SYP61/VTI12 SNARE complex involved in trafficking of vacuolar cargo. |
| Q44271494 | BP-80 as a vacuolar sorting receptor |
| Q36328766 | Biogenesis of the protein storage vacuole crystalloid. |
| Q77363883 | Calcium-mediated association of a putative vacuolar sorting receptor PV72 with a propeptide of 2S albumin |
| Q60437279 | Caleosins: Ca2+-binding proteins associated with lipid bodies |
| Q48050460 | Cloning and subcellular location of an Arabidopsis receptor-like protein that shares common features with protein-sorting receptors of eukaryotic cells |
| Q28361769 | Demonstration in yeast of the function of BP-80, a putative plant vacuolar sorting receptor |
| Q77304424 | Deposition of storage proteins |
| Q37400068 | Development and properties of genetically encoded pH sensors in plants |
| Q36236046 | Different sensitivity to wortmannin of two vacuolar sorting signals indicates the presence of distinct sorting machineries in tobacco cells. |
| Q36153510 | Dimerization of the Vacuolar Receptors AtRMR1 and -2 from Arabidopsis thaliana Contributes to Their Localization in the trans-Golgi Network |
| Q61757218 | Dual location of a family of proteinase inhibitors within the stigmas of Nicotiana alata |
| Q52844821 | Evidence for sequential action of Rab5 and Rab7 GTPases in prevacuolar organelle partitioning. |
| Q46974252 | Fluorescent reporter proteins for the tonoplast and the vacuolar lumen identify a single vacuolar compartment in Arabidopsis cells |
| Q35046321 | Forward targeting of Toxoplasma gondii proproteins to the micronemes involves conserved aliphatic amino acids |
| Q58480250 | Functional analysis of a Golgi-localized Kex2p-like protease in tobacco suspension culture cells |
| Q44266998 | Functional identification of sorting receptors involved in trafficking of soluble lytic vacuolar proteins in vegetative cells of Arabidopsis |
| Q45170524 | Golgi-dependent transport of vacuolar sorting receptors is regulated by COPII, AP1, and AP4 protein complexes in tobacco |
| Q42972442 | Homomeric interaction of AtVSR1 is essential for its function as a vacuolar sorting receptor. |
| Q44660751 | How vacuolar sorting receptor proteins interact with their cargo proteins: crystal structures of apo and cargo-bound forms of the protease-associated domain from an Arabidopsis vacuolar sorting receptor. |
| Q61757223 | Identification and Characterization of a Prevacuolar Compartment in Stigmas of Nicotiana alata |
| Q73345059 | Identification and characterization of an 18-kilodalton, VAMP-like protein in suspension-cultured carrot cells |
| Q50512873 | Identification of sorting motifs of AtβFruct4 for trafficking from the ER to the vacuole through the Golgi and PVC. |
| Q45146088 | In vivo intracellular pH measurements in tobacco and Arabidopsis reveal an unexpected pH gradient in the endomembrane system |
| Q36256386 | Integral membrane protein sorting to vacuoles in plant cells: evidence for two pathways. |
| Q71485933 | Interaction of a potential vacuolar targeting receptor with amino- and carboxyl-terminal targeting determinants |
| Q46808793 | Lack of a vacuolar sorting receptor leads to non-specific missorting of soluble vacuolar proteins in Arabidopsis seeds |
| Q73592716 | Large alkyl side-chains of isoleucine and leucine in the NPIRL region constitute the core of the vacuolar sorting determinant of sporamin precursor |
| Q40230853 | Localization of green fluorescent protein fusions with the seven Arabidopsis vacuolar sorting receptors to prevacuolar compartments in tobacco BY-2 cells. |
| Q33356007 | MTV1 and MTV4 encode plant-specific ENTH and ARF GAP proteins that mediate clathrin-dependent trafficking of vacuolar cargo from the trans-Golgi network. |
| Q38008636 | Mechanisms and concepts paving the way towards a complete transport cycle of plant vacuolar sorting receptors. |
| Q39799995 | Membrane traffic and fusion at post-Golgi compartments |
| Q48043811 | Molecular cloning and further characterization of a probable plant vacuolar sorting receptor. |
| Q48091993 | Multiple vacuolar sorting determinants exist in soybean 11S globulin |
| Q63255707 | Multivesicular bodies mature from the trans-Golgi network/early endosome in Arabidopsis |
| Q50630141 | N-linked glycosylation of AtVSR1 is important for vacuolar protein sorting in Arabidopsis. |
| Q49166359 | Nanobody-triggered lockdown of VSRs reveals ligand reloading in the Golgi. |
| Q35592089 | New insight into the structure and regulation of the plant vacuolar H+-ATPase |
| Q78760176 | Physical methods |
| Q37809579 | Plant RMR proteins: unique vacuolar sorting receptors that couple ligand sorting with membrane internalization. |
| Q71129259 | Plant cells contain two functionally distinct vacuolar compartments |
| Q36650539 | Plant prevacuolar/endosomal compartments |
| Q33859533 | Plant vacuoles |
| Q36841562 | Post-Golgi protein traffic in the plant secretory pathway. |
| Q73224377 | Post-translational maturation of natural and drug-induced missorted phytohemagglutinin |
| Q41460087 | Preliminary X-ray analysis of the binding domain of the soybean vacuolar sorting receptor complexed with a sorting determinant of a seed storage protein |
| Q58480228 | Protein mobilization in germinating mung bean seeds involves vacuolar sorting receptors and multivesicular bodies |
| Q35040466 | Protein-protein interactions in the secretory pathway, a growing demand for experimental approaches in vivo |
| Q45211535 | Receptor salvage from the prevacuolar compartment is essential for efficient vacuolar protein targeting |
| Q48042401 | Receptor-mediated sorting of soluble vacuolar proteins ends at the trans-Golgi network/early endosome |
| Q38854589 | Receptor-mediated sorting of soluble vacuolar proteins: myths, facts, and a new model |
| Q44394284 | Receptor-mediated transport of vacuolar proteins: a critical analysis and a new model |
| Q40381042 | Selective membrane protein internalization accompanies movement from the endoplasmic reticulum to the protein storage vacuole pathway in Arabidopsis. |
| Q82221559 | Sorting and anterograde trafficking at the Golgi apparatus |
| Q58480252 | Sorting of membrane proteins to vacuoles in plant cells |
| Q77304438 | Sorting of proteins to vacuoles in plant cells |
| Q34080598 | Sorting of soluble proteins in the secretory pathway of plants |
| Q40887835 | Structural requirements for ligand binding by a probable plant vacuolar sorting receptor |
| Q24805462 | Subcellular distribution of the V-ATPase complex in plant cells, and in vivo localisation of the 100 kDa subunit VHA-a within the complex |
| Q48058617 | TNO1 is involved in salt tolerance and vacuolar trafficking in Arabidopsis |
| Q50729583 | Targeting of the plant vacuolar sorting receptor BP80 is dependent on multiple sorting signals in the cytosolic tail. |
| Q50719725 | The C-terminal region of alpha' subunit of soybean beta-conglycinin contains two types of vacuolar sorting determinants. |
| Q44425317 | The GTPase ARF1p controls the sequence-specific vacuolar sorting route to the lytic vacuole |
| Q60958472 | The Multivesicular Body and Autophagosome Pathways in Plants |
| Q73534161 | 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 |
| Q41847643 | The PA domain: a protease-associated domain |
| Q50542144 | The cytosolic tail dipeptide Ile-Met of the pea receptor BP80 is required for recycling from the prevacuole and for endocytosis. |
| Q37877481 | The development of transgenic crops to improve human health by advanced utilization of seed storage proteins |
| Q37879991 | The formation, function and fate of protein storage compartments in seeds. |
| Q28365102 | The internal propeptide of the ricin precursor carries a sequence-specific determinant for vacuolar sorting |
| Q77304417 | The molecular characterization of transport vesicles |
| Q36328331 | The plant vacuolar sorting receptor AtELP is involved in transport of NH(2)-terminal propeptide-containing vacuolar proteins in Arabidopsis thaliana. |
| Q36892431 | The plant vesicle-associated SNARE AtVTI1a likely mediates vesicle transport from the trans-Golgi network to the prevacuolar compartment |
| Q44392172 | The position of the proricin vacuolar targeting signal is functionally important |
| Q58478818 | The proteolytic processing of seed storage proteins in Arabidopsis embryo cells starts in the multivesicular bodies |
| Q36333523 | The riddle of the plant vacuolar sorting receptors |
| Q35625707 | The secretory system of Arabidopsis. |
| Q84719422 | The small GTPase Rab5a is essential for intracellular transport of proglutelin from the Golgi apparatus to the protein storage vacuole and endosomal membrane organization in developing rice endosperm |
| Q33600192 | The specificity of vesicle trafficking: coat proteins and SNAREs |
| Q71822071 | 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 |
| Q30832551 | Trafficking of Vacuolar Sorting Receptors: New Data and New Problems |
| Q50486365 | Trafficking of vacuolar proteins: the crucial role of Arabidopsis vacuolar protein sorting 29 in recycling vacuolar sorting receptor. |
| Q41288792 | Transport of proteins in eukaryotic cells: more questions ahead |
| Q95433061 | Transport of storage proteins to protein storage vacuoles is mediated by large precursor-accumulating vesicles |
| Q61757229 | Uncoating the mechanisms of vacuolar protein transport |
| Q33954504 | Unique features of the plant vacuolar sorting machinery |
| Q36833749 | Vacuolar Sorting Receptor-Mediated Trafficking of Soluble Vacuolar Proteins in Plant Cells |
| Q27026111 | Vacuolar protein sorting mechanisms in plants |
| Q78132292 | Vacuolar protein trafficking and vesicles. Continuing To sort it all out |
| Q34795684 | Vacuolar sorting receptor for seed storage proteins in Arabidopsis thaliana |
| Q78132396 | Vacuolar storage proteins and the putative vacuolar sorting receptor BP-80 exit the golgi apparatus of developing pea cotyledons in different transport vesicles |
| Q42944678 | Vacuolar storage proteins are sorted in the cis-cisternae of the pea cotyledon Golgi apparatus |
| Q61955230 | Vacuolar transport in tobacco leaf epidermis cells involves a single route for soluble cargo and multiple routes for membrane cargo |
| Q34080601 | Vacuoles and prevacuolar compartments. |
| Q77735910 | What do proteins need to reach different vacuoles? |
| Q36633862 | delta-Tonoplast intrinsic protein defines unique plant vacuole functions. |
| Q43855357 | pH Regulation by NHX-Type Antiporters Is Required for Receptor-Mediated Protein Trafficking to the Vacuole in Arabidopsis. |
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