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Formation of Mitochondrial Outer Membrane Derived Protrusions and Vesicles in Arabidopsis thalianaCloning of Glycerophosphocholine Acyltransferase (GPCAT) from Fungi and Plants: A NOVEL ENZYME IN PHOSPHATIDYLCHOLINE SYNTHESISThe widespread plant-colonizing bacterial species Pseudomonas syringae detects and exploits an extracellular pool of choline in hostsSoybean Seed Development: Fatty Acid and Phytohormone Metabolism and Their InteractionsRNA-Seq transcriptomic analysis with Bag2D software identifies key pathways enhancing lipid yield in a high lipid-producing mutant of the non-model green alga Dunaliella tertiolectaBottlenecks in erucic acid accumulation in genetically engineered ultrahigh erucic acid Crambe abyssinicaPlant acyl-CoA:lysophosphatidylcholine acyltransferases (LPCATs) have different specificities in their forward and reverse reactionsOverexpression of the Novel Arabidopsis Gene At5g02890 Alters Inflorescence Stem Wax Composition and Affects Phytohormone HomeostasisSFGD: a comprehensive platform for mining functional information from soybean transcriptome data and its use in identifying acyl-lipid metabolism pathwaysAccumulation of high OPDA level correlates with reduced ROS and elevated GSH benefiting white cell survival in variegated leavesModifying the lipid content and composition of plant seeds: engineering the production of LC-PUFA.Mitochondrial outer membrane forms bridge between two mitochondria in Arabidopsis thaliana.Lipid changes after leaf wounding in Arabidopsis thaliana: expanded lipidomic data form the basis for lipid co-occurrence analysis.Proteomic Analysis of Lipid Droplets from Arabidopsis Aging Leaves Brings New Insight into Their Biogenesis and Functions.Current progress towards the metabolic engineering of plant seed oil for hydroxy fatty acids production.Genetic architecture of carbon isotope composition and growth in Eucalyptus across multiple environments.Landscape of the lipidome and transcriptome under heat stress in Arabidopsis thalianaFunctional roles of three cutin biosynthetic acyltransferases in cytokinin responses and skotomorphogenesis.Silencing of the potato StNAC103 gene enhances the accumulation of suberin polyester and associated wax in tuber skinChanges in RNA Splicing in Developing Soybean (Glycine max) Embryos.The emerging biofuel crop Camelina sativa retains a highly undifferentiated hexaploid genome structure.Transcriptional and biochemical responses of monoacylglycerol acyltransferase-mediated oil synthesis and associated senescence-like responses in Nicotiana benthamianaArabidopsis membrane-associated acyl-CoA-binding protein ACBP1 is involved in stem cuticle formation.Genome-wide identification of non-coding RNAs interacted with microRNAs in soybean.Arabidopsis acyl-CoA-binding protein ACBP3 participates in plant response to hypoxia by modulating very-long-chain fatty acid metabolism.ocsESTdb: a database of oil crop seed EST sequences for comparative analysis and investigation of a global metabolic network and oil accumulation metabolismAtMYB41 activates ectopic suberin synthesis and assembly in multiple plant species and cell types.FAX1, a novel membrane protein mediating plastid fatty acid exportIdentification and characterization of transcript polymorphisms in soybean lines varying in oil composition and contentAn annotated database of Arabidopsis mutants of acyl lipid metabolismUnsaturation of very-long-chain ceramides protects plant from hypoxia-induced damages by modulating ethylene signaling in ArabidopsisIdentification of hydroxy fatty acid and triacylglycerol metabolism-related genes in lesquerella through seed transcriptome analysisVesicles bearing Toxoplasma apicoplast membrane proteins persist following loss of the relict plastid or Golgi body disruption.Side-effects of domestication: cultivated legume seeds contain similar tocopherols and fatty acids but less carotenoids than their wild counterparts.Identification of microRNAs and transcript targets in Camelina sativa by deep sequencing and computational methods.Characterization of 19 Genes Encoding Membrane-Bound Fatty Acid Desaturases and their Expression Profiles in Gossypium raimondii Under Low TemperatureTranscriptome Analysis Comparison of Lipid Biosynthesis in the Leaves and Developing Seeds of Brassica napus.Oil biosynthesis in a basal angiosperm: transcriptome analysis of Persea Americana mesocarpIdentification, evolution, and expression partitioning of miRNAs in allopolyploid Brassica napus.Extension of oil biosynthesis during the mid-phase of seed development enhances oil content in Arabidopsis seeds.
P2860
Q27331738-3A28C96D-10CE-4D88-9433-7DD914BF04C8Q28114320-573DECBF-0C45-4AA0-9F3C-A02845CB0D55Q28493000-C95345AD-2E4A-4EAD-AD35-CB449EF0E0AAQ28602696-4C3943A8-0BC2-4CF4-AC40-4D675D6C39BBQ28607051-B3C1C96E-26E2-4E02-92A0-D9A45BA51255Q28652569-3C4BF3A5-DD4F-4D1A-81D2-B8D514BB22E4Q28660969-40FD237E-4B65-4AE9-893C-1F2FD5A3DF68Q28818227-DF49E597-9E40-4F15-AE62-9B4D9D2F7268Q30000675-5A9A9188-4FD8-4D13-A3F6-37C6D1F3DAAEQ30378262-FF4761A4-7302-4B79-A9F9-7ED2C98C850DQ30389801-AA400C6C-86F3-4D31-AC80-89286AA3D3BBQ30794702-5F325D97-3B97-4921-9527-AC8E2081E1ACQ30848671-2B43407E-7FA8-4E8D-BAD3-FC630E899F51Q30853815-A2439436-8970-49B0-BFCE-2860CE010D3BQ30883930-221E1703-A27F-4B0E-8538-A08A60BACE0DQ30887134-121CC1AA-2606-45AE-972A-D292216EC201Q30959283-9E107669-7134-4DE2-8A44-D670DA94E8D6Q33360357-DA4785E5-D908-4BB3-BE40-DE729A8D9E16Q33363685-8EE8AD1D-D322-46D2-A810-2FF5C7A8E98BQ33565196-BE05BCC6-4C9F-41F6-87F8-84B60BC2EECDQ33587367-401E8A1F-54F5-4BE8-A7F5-95E7823FAD09Q33662192-76FA9078-A93F-4123-8F9D-1CBE7237262BQ34149457-A97135F7-D80F-43AA-A652-0B17E9F64E8FQ34762904-52B35470-F386-458F-9D14-3295E822E056Q35023013-56B65BEE-DAB7-44AC-A577-8196D1C8656BQ35033405-D12C2320-2268-4701-9D54-2B6395D82D0BQ35061963-CF4835D2-A683-4046-A236-9036AF0FF3C9Q35130903-F5BFB33F-D0CF-49B3-B995-931D428CD955Q35154668-61EF51D9-FE94-49D0-B14F-68D81D473EC7Q35212259-41F8BD9F-69AF-4999-BE92-CAD83FBE8E60Q35231788-735E65C0-22D5-4183-9866-A293DA0859C6Q35237911-7065902D-E07B-47B3-9D8E-8A03739F68FAQ35392172-E4C075E9-AAB5-4881-A2CA-C26E599657CAQ35531147-808A69B1-88CF-4588-9638-539E539FDA0CQ35591033-8A549D9B-9340-4DE1-9706-1C611B40B6CEQ35609934-5346BF98-86CC-4453-826A-C560AEA3A63DQ35627833-3DE09C91-FB2D-4D99-B96A-EAA68DFC47BAQ35746971-354379EC-0C58-4DB1-9ADB-005F1A9A7DF9Q35769677-4D096E22-DA1E-4829-B1A3-9EB5AE70AB76Q35821832-1220B2AE-02E5-42D2-8964-2948250CAC5A
P2860
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Acyl-lipid metabolism.
@en
Acyl-lipid metabolism.
@nl
type
label
Acyl-lipid metabolism.
@en
Acyl-lipid metabolism.
@nl
prefLabel
Acyl-lipid metabolism.
@en
Acyl-lipid metabolism.
@nl
P2093
P2860
P356
P1433
P1476
Acyl-lipid metabolism.
@en
P2093
Allan Debono
Amélie A Kelly
Basil Shorrosh
Changcheng Xu
David Bird
Fred Beisson
Hajime Wada
Ian A Graham
Ikuo Nishida
Isabel Molina
P2860
P356
10.1199/TAB.0161
P577
2013-01-29T00:00:00Z