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Phosphorylation of the C Terminus of RHD3 Has a Critical Role in Homotypic ER Membrane Fusion in ArabidopsisThe Arabidopsis pex12 and pex13 mutants are defective in both PTS1- and PTS2-dependent protein transport to peroxisomesDevelopment of an R4 dual-site (R4DS) gateway cloning system enabling the efficient simultaneous cloning of two desired sets of promoters and open reading frames in a binary vector for plant researchThe Plant Organelles Database 2 (PODB2): an updated resource containing movie data of plant organelle dynamicsInteraction between chaperone and protease functions of LON2, and autophagy during the functional transition of peroxisomesHighly oxidized peroxisomes are selectively degraded via autophagy in Arabidopsis.Dynamics of the Light-Dependent Transition of Plant Peroxisomes.Extension of oil biosynthesis during the mid-phase of seed development enhances oil content in Arabidopsis seeds.Quantifying morphological features of actin cytoskeletal filaments in plant cells based on mathematical morphology.Physical interaction between peroxisomes and chloroplasts elucidated by in situ laser analysis.Sucrose Production Mediated by Lipid Metabolism Suppresses the Physical Interaction of Peroxisomes and Oil Bodies during Germination of Arabidopsis thaliana.Gateway Vectors for Simultaneous Detection of Multiple Protein-Protein Interactions in Plant Cells Using Bimolecular Fluorescence Complementation.HSP90 Stabilizes Auxin-Responsive Phenotypes by Masking a Mutation in the Auxin Receptor TIR1.Tonoplast- and plasma membrane-localized aquaporin-family transporters in blue hydrangea sepals of aluminum hyperaccumulating plantAn Efficient Method for the Isolation of Highly Purified RNA from Seeds for Use in Quantitative Transcriptome Analysis.A dual-site gateway cloning system for simultaneous cloning of two genes for plant transformation.HSP90 stabilizes auxin receptor TIR1 and ensures plasticity of auxin responses.Plant peroxisomes.The plant organelles database (PODB): a collection of visualized plant organelles and protocols for plant organelle research.An isoform of Arabidopsis myosin XI interacts with small GTPases in its C-terminal tail region.Plant autophagy is responsible for peroxisomal transition and plays an important role in the maintenance of peroxisomal quality.Seeing is believing: on the use of image databases for visually exploring plant organelle dynamics.Identification of peroxisomal targeting signal of pumpkin catalase and the binding analysis with PTS1 receptor.Gateway binary vectors with the bialaphos resistance gene, bar, as a selection marker for plant transformation.Suppression of peroxisome biogenesis factor 10 reduces cuticular wax accumulation by disrupting the ER network in Arabidopsis thaliana.Peroxisomes are required for in vivo nitric oxide accumulation in the cytosol following salinity stress of Arabidopsis plants.Functional differentiation of peroxisomes revealed by expression profiles of peroxisomal genes in Arabidopsis thaliana.Two cis-acting regulatory elements are involved in the sucrose-inducible expression of the sporamin gene promoter from sweet potato in transgenic tobacco.Arabidopsis ABERRANT PEROXISOME MORPHOLOGY9 is a peroxin that recruits the PEX1-PEX6 complex to peroxisomes.Novel proteins interacting with peroxisomal protein receptor PEX7 in Arabidopsis thaliana.Two Sec13p homologs, AtSec13A and AtSec13B, redundantly contribute to the formation of COPII transport vesicles in Arabidopsis thaliana.A vacuolar iron transporter in tulip, TgVit1, is responsible for blue coloration in petal cells through iron accumulation.Peroxisomal localization of a myosin XI isoform in Arabidopsis thaliana.An Arabidopsis dynamin-related protein, DRP3A, controls both peroxisomal and mitochondrial division.Stromal and thylakoid-bound ascorbate peroxidases are produced by alternative splicing in pumpkin.The Plant Organelles Database 3 (PODB3) update 2014: integrating electron micrographs and new options for plant organelle research.Diffuse decapping enzyme DCP2 accumulates in DCP1 foci under heat stress in Arabidopsis thaliana.A defect of peroxisomal membrane protein 38 causes enlargement of peroxisomes.Molecular components required for the targeting of PEX7 to peroxisomes in Arabidopsis thaliana.Novel gateway binary vectors for rapid tripartite DNA assembly and promoter analysis with various reporters and tags in the liverwort Marchantia polymorpha
P50
Q27320208-361DC52F-E275-47B3-9ED0-79F1E5FE9215Q28249541-ACC35323-A92D-4D55-B03C-F971C4054F3AQ33693968-B94FFC03-B683-408A-AED7-822B6074384FQ33693968-E8F0AF2A-8B75-4EE0-BAC7-3DF3F0FF1C23Q33758117-932AB37E-7B14-461C-86A6-9AA717021B4CQ33879358-424C5FC9-5CFF-4C83-953F-80F1660EFC9EQ34394370-E00E932D-382D-4B6F-89B9-5E7A052C513EQ35660585-09AAB811-4DB5-49E8-AE80-9310D8FFDB3AQ35821832-52F1DAB7-2892-484B-8EE4-E1B0302EC72DQ35835967-A85DCFE1-5BD1-453B-89DA-95625E2ACDF6Q36035855-7C5EC411-4415-4A53-BFFE-067A774EF55FQ36088151-5FDBFA67-CE98-457F-8F5E-DFB8C07DD6CBQ36094886-7130EF49-F7DD-4D98-82E7-005AA4F878E4Q36183675-D2D5F57A-886A-4AC3-9B77-253F2CA7B2D8Q36198483-C09821D9-599D-4500-98F5-A3103186EADEQ36258565-167E3953-B0AA-4FF8-A9C3-35424CD220C9Q36370718-989215B4-B50F-48DF-998C-EA4543B971DCQ36377911-525A1381-E96C-486A-ADED-55D084C98529Q36402773-920230C8-3EEA-4DD2-BBAB-E75064F266B1Q36454300-D68F6305-B4B3-4220-8031-D439D289E132Q36922293-ACA83B6C-1890-49FD-8212-D4C6E4C0B185Q37428818-4D6F19C6-B9A2-4AE5-A501-8C60EF4C79E4Q37597743-ADE43CB0-B04D-433E-B4EE-7D22AF0FB0CEQ38351080-DAFC0C7F-32D0-454B-ACEA-1623CB3D8C44Q43041428-31EF0690-EE43-4C88-A99A-BCE70340635AQ43247686-B3505753-331E-4EF9-8972-1AD2A5E4508EQ43270648-98B20A2A-2034-4DBD-842F-2223D442B63FQ44710712-05C41FBA-7165-4242-B634-08A958F739F3Q45227268-831B05EA-0E4E-43F8-A6CC-106B8E472E0CQ45472570-5800035B-AE7B-4989-BC5D-00C3672BA407Q45782158-3C310E68-7C55-49D9-A63A-877D4E1CC354Q45928022-2EA7678C-CF59-4DBB-984A-A8E16B238EF5Q46359318-4CAF78CB-99B0-444F-B5D4-6C34BE0A0BA4Q46406298-FBA6EA43-0529-45AB-B89B-1DAB26A69C5CQ47757537-4D1393B9-CC5A-4369-BE6C-7429057855EFQ48046059-1C33CDC4-42E1-4773-87E0-C65D41B474C9Q50146580-8C7AB80F-31BE-4702-BF09-25F6F7D168C4Q50447198-9EF1B595-9314-4986-AA91-AF5658C428E1Q50508991-EE854DAA-9063-41DD-8A09-693B116BE1FFQ50588546-EBA34299-5F57-48B2-9542-63E57CFACC7F
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Shoji Mano
@ast
Shoji Mano
@en
Shoji Mano
@es
Shoji Mano
@nl
Shoji Mano
@sl
type
label
Shoji Mano
@ast
Shoji Mano
@en
Shoji Mano
@es
Shoji Mano
@nl
Shoji Mano
@sl
prefLabel
Shoji Mano
@ast
Shoji Mano
@en
Shoji Mano
@es
Shoji Mano
@nl
Shoji Mano
@sl
P106
P108
P1153
7006380466
P31
P496
0000-0003-1323-3308