PLGG1, a plastidic glycolate glycerate transporter, is required for photorespiration and defines a unique class of metabolite transporters.
about
Unknown components of the plastidial permeome.Metabolic connectivity as a driver of host and endosymbiont integration.Large-scale atlas of microarray data reveals the distinct expression landscape of different tissues in Arabidopsis.Large-Scale Public Transcriptomic Data Mining Reveals a Tight Connection between the Transport of Nitrogen and Other Transport Processes in Arabidopsis.The role of photorespiration during the evolution of C4 photosynthesis in the genus Flaveria.Metabolic control of redox and redox control of metabolism in plants.Holins in bacteria, eukaryotes, and archaea: multifunctional xenologues with potential biotechnological and biomedical applications.Activation of auxin signalling counteracts photorespiratory H2O2-dependent cell death.Bile Acid Sodium Symporter BASS6 Can Transport Glycolate and Is Involved in Photorespiratory Metabolism in Arabidopsis thaliana.Sun leaves up-regulate the photorespiratory pathway to maintain a high rate of CO2 assimilation in tobacco.Bending of protonema cells in a plastid glycolate/glycerate transporter knockout line of Physcomitrella patensThioredoxin, a master regulator of the tricarboxylic acid cycle in plant mitochondria.Redirecting the Cyanobacterial Bicarbonate Transporters BicA and SbtA to the Chloroplast Envelope: Soluble and Membrane Cargos Need Different Chloroplast Targeting Signals in Plants.Photorespiratory glycolate oxidase is essential for the survival of the red alga Cyanidioschyzon merolae under ambient CO2 conditionsIdentifying essential genes/reactions of the rice photorespiration by in silico model-based analysis.Physiological evidence for plasticity in glycolate/glycerate transport during photorespirationPan- and core- network analysis of co-expression genes in a model plant.Co-expression analysis as tool for the discovery of transport proteins in photorespiration.Optimization of photosynthesis by multiple metabolic pathways involving interorganelle interactions: resource sharing and ROS maintenance as the bases.Lignin, mitochondrial family, and photorespiratory transporter classification as case studies in using co-expression, co-response, and protein locations to aid in identifying transport functions.Bundle-sheath leakiness in C4 photosynthesis: a careful balancing act between CO2 concentration and assimilation.Regulation of amino acid metabolic enzymes and transporters in plants.Citrulline metabolism in plants.Photorespiratory glycolate-glyoxylate metabolism.On the metabolic interactions of (photo)respiration.Perspectives for a better understanding of the metabolic integration of photorespiration within a complex plant primary metabolism network.A bell pepper cultivar tolerant to chilling enhanced nitrogen allocation and stress-related metabolite accumulation in the roots in response to low root-zone temperature.C4 Photosynthesis in the Rice Paddy: Insights from the Noxious Weed Echinochloa glabrescens.The LysR-type transcriptional regulator, CidR, regulates stationary phase cell death in Staphylococcus aureus.Temperature Shift Experiments Suggest That Metabolic Impairment and Enhanced Rates of Photorespiration Decrease Organic Acid Levels in Soybean Leaflets Exposed to Supra-Optimal Growth Temperatures.Identification of a plastidial phenylalanine exporter that influences flux distribution through the phenylalanine biosynthetic network.Most photorespiratory genes are preferentially expressed in the bundle sheath cells of the C4 grass Sorghum bicolor.2-Hydroxy Acids in Plant Metabolism.Molecular and Physiological Logics of the Pyruvate-Induced Response of a Novel Transporter in Bacillus subtilis.Permeability of the peroxisomal membrane: lessons from the glyoxylate cycle.Comparative Analyses of Transport Proteins Encoded within the Genomes of Bdellovibrio bacteriovorus HD100 and Bdellovibrio exovorus JSS.Photorespiration: origins and metabolic integration in interacting compartments.Transcriptomic and metabolic changes associated with photorespiratory ammonium accumulation in the model legume Lotus japonicus.Photorespiration--a driver for evolutionary innovations and key to better crops.Lack of GLYCOLATE OXIDASE1, but Not GLYCOLATE OXIDASE2, Attenuates the Photorespiratory Phenotype of CATALASE2-Deficient Arabidopsis.
P2860
Q27686761-8622EBF9-588F-4A64-945E-72E6A80FDB1AQ30662218-B29DEEBD-CE79-4425-B7B8-DCB2B6E41105Q31063446-43112A9E-4C9B-4CB6-A2F1-8DD6524C08DEQ31123719-D8A4C447-32F6-4E69-A25B-35DC32C59972Q33920736-09B1D65E-D363-4973-A107-8F8AFBF5B8C3Q34154548-8C4248F8-C9F4-4E05-97C9-7C44E3637A72Q34435161-DD7F11A5-55F5-4393-A4B5-33414264ACB8Q34491416-E69CA4D3-5FEE-47C7-8639-A10AA407FB82Q34554302-1773976C-69C5-4C2D-8C54-A0B00550165FQ34622066-B516B9D3-6429-4834-AF5A-34220F6861BDQ35203311-91CC6108-7AE2-48EC-93FB-3D12829F62E7Q35212687-283DF0E7-8027-4BE2-A8AA-B240FC5D4986Q36627419-7B498563-A061-4C28-A356-42D9CD0066C8Q36903729-4BB3C1A9-FD1D-4B2F-8703-3728CCF7895FQ36943998-404CB87F-17EF-4954-93AA-C6038F4B7D1CQ36999921-E8FD6BD4-AEB8-4E19-B790-5D4FD941D139Q37508331-F2024774-4A30-46CE-966A-5CB8AD61682BQ38099400-7134DC09-0200-49E1-9F5E-3073D0C24C37Q38123716-DABE1EE0-33F8-4117-8A01-C959D02E765EQ38199676-70BCB9AC-8445-4DE6-9FD9-D06E6D98EC3CQ38206336-482FCD32-4078-43AA-9481-D00F0FFE12E0Q38239081-18F19B71-7807-45B4-BD94-A07F864A72F3Q38652244-6089E49D-67D2-477E-BC4D-61A6B6C69922Q38781455-A40048A5-A8B7-4045-8C4C-0675D71901E4Q38793910-B83FC19C-6C8C-4295-BF49-741C3774FF00Q38800335-6E8B0494-B75C-4C3B-AAF3-6AFE44ED50F6Q38864229-DC9014F9-F2B3-4ED4-B0F7-C4EE1D9B6BCAQ40363511-D7B832A9-9E27-4CCD-AB4A-57D9D289412BQ41036308-DE43E2EE-9851-4EB0-AF3C-91286ACACB29Q41587929-25BAACE3-3987-4EE4-A7A2-1D3516E25804Q41850468-1515C981-D69B-47ED-9D01-1E7ED7F358C5Q41892134-16D756D3-A54D-4D54-9089-47F7CB8AFA80Q41938841-D7B7CEA0-5BE8-4539-A8EF-81FD3DB738A6Q42282140-775CE0D5-B841-4A23-AC6E-5BD2B459C519Q42554010-14FBE4A0-CC1F-44C8-8AC0-F974370BD57EQ45931672-582689C4-C39B-4BE5-BE85-1939CD2DA225Q45955944-794C8E39-5D0E-45B2-A159-E0B01CC8A6BCQ46407087-DB1E878C-ECAA-4773-998D-C81C6DF59A2BQ46488751-A1637878-AB5E-4C20-A3FB-0A3F3E02689BQ46542391-E7C2BD2E-D8B8-495C-91EE-57AC540B1126
P2860
PLGG1, a plastidic glycolate glycerate transporter, is required for photorespiration and defines a unique class of metabolite transporters.
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
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@ast
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@en
type
label
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@ast
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@en
prefLabel
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@ast
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@en
P2093
P2860
P356
P1476
PLGG1, a plastidic glycolate g ...... ss of metabolite transporters.
@en
P2093
Andrea Bräutigam
Andreas P M Weber
Matthias A Schulz
Thea R Pick
Toshihiro Obata
P2860
P304
P356
10.1073/PNAS.1215142110
P407
P577
2013-02-04T00:00:00Z