Low-coverage massively parallel pyrosequencing of cDNAs enables proteomics in non-model species: comparison of a species-specific database generated by pyrosequencing with databases from related species for proteome analysis of pea chloroplast envel
about
Discovering New Biology through Sequencing of RNAApplications of next generation sequencing in molecular ecology of non-model organismsEST analysis reveals putative genes involved in glycyrrhizin biosynthesisCharacterization of the rainbow trout transcriptome using Sanger and 454-pyrosequencing approachesIntegrated proteome and metabolite analysis of the de-etiolation process in plastids from rice (Oryza sativa L.).Comprehensive transcriptome analysis of the highly complex Pisum sativum genome using next generation sequencing.A J-like protein influences fatty acid composition of chloroplast lipids in Arabidopsis.Microbiology and proteomics, getting the best of both worlds!The protein composition of the digestive fluid from the venus flytrap sheds light on prey digestion mechanisms.TGD1, -2, and -3 proteins involved in lipid trafficking form ATP-binding cassette (ABC) transporter with multiple substrate-binding proteins.Shotgun proteomics as a viable approach for biological discovery in the Pacific oyster.Interaction of actin and the chloroplast protein import apparatus.Post-genomics studies of developmental processes in legume seeds.Plant organelle proteomics: collaborating for optimal cell function.RNA-Seq Assembly - Are We There Yet?Proteomics of nonmodel plant species.A decade of plant proteomics and mass spectrometry: translation of technical advancements to food security and safety issues.Cross-talk between calcium signalling and protein phosphorylation at the thylakoid.An evaluation of coral lophelia pertusa mucus as an analytical matrix for environmental monitoring: A preliminary proteomic study.T-DNA insertion in aquaporin gene AtPIP1;2 generates transcription profiles reminiscent of a low CO2 response.Combined EST and proteomic analysis identifies rapidly evolving seminal fluid proteins in Heliconius butterflies.Proteomic analysis of the defense response of wheat to the powdery mildew fungus, Blumeria graminis f. sp. tritici.Defining the core proteome of the chloroplast envelope membranes.The plastid outer envelope protein OEP16 affects metabolic fluxes during ABA-controlled seed development and germination.Dynamic Remodeling of the Plastid Envelope Membranes - A Tool for Chloroplast Envelope in vivo Localizations.Mining the soluble chloroplast proteome by affinity chromatography.Studies of a biochemical factory: tomato trichome deep expressed sequence tag sequencing and proteomics.Biochemical and Transcriptional Regulation of Membrane Lipid Metabolism in Maize Leaves under Low Temperature.Comparative proteomics of chloroplast envelopes from C3 and C4 plants reveals specific adaptations of the plastid envelope to C4 photosynthesis and candidate proteins required for maintaining C4 metabolite fluxes.Eukaryotic Hsp70 chaperones in the intermembrane space of chloroplastsAn mRNA blueprint for C4 photosynthesis derived from comparative transcriptomics of closely related C3 and C4 speciesApplications of Quantitative Proteomics in Plant Research
P2860
Q28607787-178E81DA-033A-4054-87D3-47BC5F7DC4F2Q28744282-B2EEA26E-C7D5-4C92-BCC0-827474F6416FQ33566376-439F153D-3566-4EBD-A9B0-2CD94761CF20Q33717579-093163B6-F23F-4185-A718-1EB29114D2C3Q33854385-725531DF-B1AB-4F11-ACCD-1E28AB62F07EQ33898632-3ABE417A-56A8-4376-AF29-06193F07D431Q34058264-ED7C06BE-C064-4E83-84B0-FC1B833DABE7Q34307889-88BC6896-19F6-4C89-AE5C-3A82912B38C1Q34379076-CE16EEAA-9FC2-4591-9131-5471917478D9Q36033275-91C25D4A-8141-4815-8B2B-2C3A0BD66DA5Q36519054-5112045B-DCA2-4E35-A134-7A84829F206EQ37254044-189B7B20-F9BD-42FA-9442-8704CC90462FQ37578922-506EFC3F-5B3C-4BC6-9A11-7E2932D5139EQ37805395-219DA7FE-D16A-46A0-9529-F7EB5C1CD505Q38051330-FCE670D6-D648-4055-ADD5-E753E4EB1EACQ38057719-7E5BAEDA-E59C-4FFE-9059-2370B36CB51FQ38073737-020594DA-16AE-44BB-9DB0-172C0CB936CEQ38561849-5EE34A8A-7ACD-4A10-B310-2072E782758DQ38835254-1714D25B-F395-4E5D-AE4D-179CC3B098F9Q38916722-94BD4595-0D34-4DDD-8075-2514F0466C6BQ39884980-E643EC35-01EC-4F1E-A68B-392FB9CCC5ABQ41725031-91DC25FE-7976-4B2D-A8EA-6087434C5025Q41810124-FA54EBFD-0420-457C-9899-E5AC16FC1EB3Q42036604-06264693-BD6F-492F-A2EA-02042BC90B2BQ42174846-F6288A52-08D2-433E-AD66-03590922BB51Q42431381-ABD1E08D-8B31-4E42-B4EE-162E50746E29Q43079296-FEF7930F-210C-487E-B8F3-E311F13F9775Q46237849-8892BBC7-D44F-416A-86D9-3BF4085B4C47Q46503145-5C16495F-EFA5-4D73-A453-7823D7F48E08Q55113568-C8F725E5-D4EB-4676-85B0-B1CF588FC914Q57251605-7D7C78ED-AD03-45E2-BEF6-8BF607C1602EQ58055618-C4E4CBEE-841B-42AF-9199-40044EA474EF
P2860
Low-coverage massively parallel pyrosequencing of cDNAs enables proteomics in non-model species: comparison of a species-specific database generated by pyrosequencing with databases from related species for proteome analysis of pea chloroplast envel
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh
2008年學術文章
@zh-hant
name
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@en
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@nl
type
label
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@en
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@nl
prefLabel
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@en
Low-coverage massively paralle ...... lysis of pea chloroplast envel
@nl
P2093
P1476
Low-coverage massively paralle ...... s of pea chloroplast envelopes
@en
P2093
Curtis G Wilkerson
Doug Whitten
John E Froehlich
Kevin M Carr
Roshan P Shrestha
P356
10.1016/J.JBIOTEC.2008.02.007
P577
2008-02-17T00:00:00Z