Physiological implications of arginine metabolism in plants - Wikidata - awgldk - TriplyDB

Physiological implications of arginine metabolism in plants

Physiological implications of arginine metabolism in plants

http://www.wikidata.org/entity/Q26797322

about

The structure of Medicago truncatula δ(1)-pyrroline-5-carboxylate reductase provides new insights into regulation of proline biosynthesis in plants Copper amine oxidase 8 regulates arginine-dependent nitric oxide production in Arabidopsis thaliana.Proteomics-based identification of differentially abundant proteins reveals adaptation mechanisms of Xanthomonas citri subsp. citri during Citrus sinensis infection.Functional characterization and expression analysis of rice δ(1)-pyrroline-5-carboxylate dehydrogenase provide new insight into the regulation of proline and arginine catabolism The gene expression landscape of pine seedling tissues.Effects of down-regulating ornithine decarboxylase upon putrescine-associated metabolism and growth in Nicotiana tabacum L.Comparative proteomic study of Arabidopsis mutants mpk4 and mpk6.Citrulline metabolism in plants.Real-time iTRAQ-based proteome profiling revealed the central metabolism involved in nitrogen starvation induced lipid accumulation in microalgae.Functional Characterization of Four Putative δ1-Pyrroline-5-Carboxylate Reductases from Bacillus subtilis.Biochemical Principles and Functional Aspects of Pipecolic Acid Biosynthesis in Plant Immunity.Fitness costs restrict niche expansion by generalist niche-constructing pathogens.Arabidopsis aldehyde dehydrogenase 10 family members confer salt tolerance through putrescine-derived 4-aminobutyrate (GABA) production.Temporal Effects on Internal Fluorescence Emissions Associated with Aflatoxin Contamination from Corn Kernel Cross-Sections Inoculated with Toxigenic and Atoxigenic Aspergillus flavus.Contributions of two cytosolic glutamine synthetase isozymes to ammonium assimilation in Arabidopsis roots.Evidence for PII with NAGK interaction that regulates Arg synthesis in the microalga Myrmecia incisa in response to nitrogen starvation.Mass Spectrometry Imaging of low Molecular Weight Compounds in Garlic (Allium sativum L.) with Gold Nanoparticle Enhanced Target.Acetylglutamate kinase is required for both gametophyte function and embryo development in Arabidopsis thaliana.The Arabidopsis N-Acetylornithine Deacetylase Controls Ornithine Biosynthesis via a Linear Pathway with Downstream Effects on Polyamine Levels.Exploiting the Genetic Diversity of Maize Using a Combined Metabolomic, Enzyme Activity Profiling, and Metabolic Modeling Approach to Link Leaf Physiology to Kernel Yield.Expression of CphB- and CphE-type cyanophycinases in cyanophycin-producing tobacco and comparison of their ability to degrade cyanophycin in plant and plant extracts.Foliar nitrogen metabolism of adult Douglas-fir trees is affected by soil water availability and varies little among provenances.Phytotoxicity of aminobisphosphonates targeting both δ1 -pyrroline-5-carboxylate reductase and glutamine synthetase.Group-wise ANOVA simultaneous component analysis for designed omics experiments.Hidden Nickel Deficiency? Nickel Fertilization via Soil Improves Nitrogen Metabolism and Grain Yield in Soybean Genotypes.Metabolic Patterns in Spirodela polyrhiza Revealed by 15N Stable Isotope Labeling of Amino Acids in Photoautotrophic, Heterotrophic, and Mixotrophic Growth Conditions.Root proteomic and metabolic analyses reveal specific responses to drought stress in differently tolerant grapevine rootstocks.NMR-based metabolomics of transgenic and non-transgenic sweet orange reveals different responses in primary metabolism during citrus canker development Nitrogen Economy and Nitrogen Environmental Interactions in Conifers Comparison of Vacuum MALDI and AP-MALDI Platforms for the Mass Spectrometry Imaging of Metabolites Involved in Salt Stress in Reconstructing the functions of endosymbiotic Mollicutes in fungus-growing ants

P2860

Q30381509-7A9A1ADE-3E44-460C-A271-FE7587A2D43F Q33737102-D9143466-7FE4-4FE5-9BBE-C83005E3739D Q33892913-D91514DA-646F-487F-8682-03D846D52118 Q35917725-6DE70048-50CA-4295-A646-56762BED7C87 Q36411019-EB9E98A7-C6F8-4C08-8E7A-1F031E4B5C97 Q36967651-0E325C42-7A29-4D85-8B34-1312A9FFCB2E Q37024201-D071445C-BD53-4DCF-A3BB-BAFE74962FD5 Q38652244-046566D5-45DF-48AE-B104-BDDA16516ACA Q38853705-F219665B-F4DB-47E3-B913-59564DCB8D2A Q40086456-8B9C8F92-D8DC-4DCD-9979-53FCF8C813BB Q40283014-790AC36A-3864-40E6-B26A-4D83B613E66C Q40471961-FF34B04F-A378-4675-B586-9A61390594C4 Q41389524-4ED05D5F-ED43-46CD-8A78-ECC418CC10F6 Q41665317-C425050D-5713-469E-AF08-564F7293857F Q42249085-59D76B55-6087-45B5-92C1-E40CBA201799 Q47132506-4CE9B1A2-9801-4C7A-8871-23B1C986D94C Q47206394-524DE3CE-C050-4740-AA2F-DF6848483AF1 Q47828119-4205AB76-DA19-4617-9C99-FD5CC922D3C6 Q47896702-985C089A-35E2-45E8-B0DC-B1E3F58D037C Q48294441-ADE6F0D9-0B50-4333-A040-70212A1E2F90 Q50709280-02DF9692-9F31-4691-9B6E-714BE582A436 Q51145796-A96B119F-0DD0-4DBC-A86B-45C00B57E7A7 Q53616276-4B4E1728-817F-4DE9-881B-51F77DBBA655 Q55217291-47D64154-801F-420A-BCA6-9BEACD568DB8 Q55264575-19D1B6F8-4FCD-49FE-94F7-E802912F1F07 Q55290071-8DFF6FB7-037F-4C28-B0C9-65E9043F8B70 Q55438687-8622CE2D-E246-4528-A8C6-00F6DFDDCA9A Q57018920-8276DFF2-1F74-48B2-B94E-13B649746AEA Q57995382-1AF4CEB6-976A-4A30-9186-BAD470DADD55 Q58698390-AC03CB00-8F66-4E1B-BC69-BC654906F521 Q59135587-B87D84FA-A839-4B95-B58A-59F348B4E8E7

P2860

Physiological implications of arginine metabolism in plants

http://www.wikidata.org/entity/Q26797322

description

2015 nî lūn-bûn

@nan

2015 թուականին հրատարակուած գիտական յօդուած

@hyw

2015 թվականին հրատարակված գիտական հոդված

@hy

2015年の論文

@ja

2015年論文

@yue

2015年論文

@zh-hant

2015年論文

@zh-hk

2015年論文

@zh-mo

2015年論文

@zh-tw

2015年论文

@wuu

name

Physiological implications of arginine metabolism in plants

@ast

Physiological implications of arginine metabolism in plants

@en

Physiological implications of arginine metabolism in plants

@nl

type

label

Physiological implications of arginine metabolism in plants

@ast

Physiological implications of arginine metabolism in plants

@en

Physiological implications of arginine metabolism in plants

@nl

prefLabel

Physiological implications of arginine metabolism in plants

@ast

Physiological implications of arginine metabolism in plants

@en

Physiological implications of arginine metabolism in plants

@nl

P1433

Q26797322-C095B22B-277B-4009-95E2-3A791794DB0B

P1476

Q26797322-1F2D06A2-5BAE-4EC0-9D25-9B085EE411CD

P2093

Q26797322-5124885B-EFF1-47FA-AAD8-EFB9EE1BFE54

Q26797322-6BCF1B44-0172-4D52-8DE0-D97CB0A6ED37

Q26797322-DDA56B8A-7010-4599-9523-EF672C638FD0

P2860

Q26797322-021ED468-69B5-4F8D-94DD-038E552D2285

Q26797322-021F497D-E856-496E-A4DE-E21450E3E0CE

Q26797322-033342FE-AD37-46AD-8234-6CFA9A545518

Q26797322-0577F41D-3C6C-44ED-A41E-4547A0904F15

Q26797322-0766EEE8-E768-4C9C-899F-FEBAA6F5CB95

Q26797322-0AB5673A-C9DB-4E4D-8FD3-5CF9010F5187

Q26797322-0AF475C3-E61A-4C6C-8A0B-A14DEFFFE50F

Q26797322-0B9C9D5E-268A-470A-B6F8-DB70A1C459ED

Q26797322-0CD93DDD-4874-4848-9327-3B7B39B2FBC4

Q26797322-0F45D6AB-28A9-4F45-8DAC-32B65372C774

P304

Q26797322-17E97F63-7128-460D-B8BA-9C1C78B53436

P31

Q26797322-CD5A7AC1-BB4A-4729-AFF4-FDF412EF88C8

P3181

Q26797322-2C1B63CF-1898-4062-99AA-A2CDD3BADE22

P356

Q26797322-D449CF46-09C7-4BED-828F-5BB421932FB0

P407

Q26797322-DE161228-EF81-405E-9A34-5E4156A0C487

P478

Q26797322-8784A6E4-E539-462B-B5FE-A1A29664006B

P50

Q26797322-06E960B1-119D-4B8B-B434-EC578F7F7E4C

Q26797322-42708510-B4B7-4944-91AF-49B92DBB2332

P577

Q26797322-2D827889-E77C-4598-A8A9-0334E23127CE

P5875

Q26797322-05744C51-B5FE-4636-896B-A094B4BD5981

P698

Q26797322-A97967E8-4457-4C87-8141-75F80C642E21

P932

Q26797322-39C82A3F-3172-4168-9BB9-CB1F409BA8A0

P3181

P356

FPLS.2015.00534

P1433

Frontiers in Plant Science

P1476

Physiological implications of arginine metabolism in plants

@en

P2093

Dietmar Funck

http://www.w3.org/2001/XMLSchema#string

Gudrun Winter

http://www.w3.org/2001/XMLSchema#string

Maurizio Trovato

http://www.w3.org/2001/XMLSchema#string

P2860

Biosynthesis and metabolism of arginine in bacteria

Evolution of the arginase fold and functional diversity

Crystal structure of human arginase I complexed with thiosemicarbazide reveals an unusual thiocarbonyl mu-sulfide ligand in the binuclear manganese cluster

Expression pattern of a nuclear encoded mitochondrial arginine-ornithine translocator gene from Arabidopsis

Purification, properties and alternate substrate specificities of arginase from two different sources: Vigna catjang cotyledon and buffalo liver.

Nitric oxide function in plant biology: a redox cue in deconvolution

Crystal structures of Bacillus caldovelox arginase in complex with substrate and inhibitors reveal new insights into activation, inhibition and catalysis in the arginase superfamily

Human arginase II: crystal structure and physiological role in male and female sexual arousal

Ensemble Refinement of Protein Crystal Structures: Validation and Application

Structures of the PutA peripheral membrane flavoenzyme reveal a dynamic substrate-channeling tunnel and the quinone-binding site

P304

534

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P3181

614165

http://www.w3.org/2001/XMLSchema#string

P356

10.3389/FPLS.2015.00534

http://www.w3.org/2001/XMLSchema#string

P407

P478

6

http://www.w3.org/2001/XMLSchema#string

P50

Giuseppe Forlani

Christopher D Todd

P577

2015-07-30T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

281081103

http://www.w3.org/2001/XMLSchema#string

P698

26284079

http://www.w3.org/2001/XMLSchema#string

P932

4520006

http://www.w3.org/2001/XMLSchema#string