about
Reactive Nitrogen Species in Mitochondria and Their Implications in Plant Energy Status and Hypoxic Stress ToleranceRedox regulation of plant developmentNitric oxide: a multifaceted regulator of the nitrogen-fixing symbiosisEvolution and mechanisms of plant tolerance to flooding stressNitrogen metabolism in plants under low oxygen stress.The Caenorhabditis globin gene family reveals extensive nematode-specific radiation and diversificationHypoxia-responsive microRNAs and trans-acting small interfering RNAs in ArabidopsisParallel evolution of nitric oxide signaling: diversity of synthesis and memory pathways.In vivo protein tyrosine nitration in Arabidopsis thalianaOxygen and nitric oxide rebinding kinetics in nonsymbiotic hemoglobin AHb1 from Arabidopsis thaliana.Identification of hypoxia-inducible target genes of Aspergillus fumigatus by transcriptome analysis reveals cellular respiration as an important contributor to hypoxic survivalHigh yields of hydrogen production induced by meta-substituted dichlorophenols biodegradation from the green alga Scenedesmus obliquusNitric oxide produced by cytochrome c oxidase helps stabilize HIF-1α in hypoxic mammalian cells.Knocking down mitochondrial iron transporter (MIT) reprograms primary and secondary metabolism in rice plants.How unique is the low oxygen response? An analysis of the anaerobic response during germination and comparison with abiotic stress in rice and Arabidopsis.Which role for nitric oxide in symbiotic N2-fixing nodules: toxic by-product or useful signaling/metabolic intermediate?Bcl-2 family proteins as regulators of oxidative stress.Loss of the plant DEAD-box protein ISE1 leads to defective mitochondria and increased cell-to-cell transport via plasmodesmata.Regulation of the molecular response to oxygen limitations in plants.Structural and functional properties of class 1 plant hemoglobins.Reciprocal regulation of cellular nitric oxide formation by nitric oxide synthase and nitrite reductases.Nitric oxide in plants: an assessment of the current state of knowledge.What happens to plant mitochondria under low oxygen? An omics review of the responses to low oxygen and reoxygenation.Glycolytic Coupling to Mitochondrial Energy Production Ensures Survival in an Oxygen Rich Environment.Atmospheric emission of nitric oxide and processes involved in its biogeochemical transformation in terrestrial environment.Proteomic Profiling and the Predicted Interactome of Host Proteins in Compatible and Incompatible Interactions Between Soybean and Fusarium virguliforme.Biotechnological approaches to creation of hypoxia and anoxia tolerant plants.Differential expression patterns of non-symbiotic hemoglobins in sugar beet (Beta vulgaris ssp. vulgaris).Musings about the effects of environment on photosynthesis.Both plant and bacterial nitrate reductases contribute to nitric oxide production in Medicago truncatula nitrogen-fixing nodules.Linking waterlogging tolerance with Mn²⁺ toxicity: a case study for barley.Comparative analysis between plant species of transcriptional and metabolic responses to hypoxia.The Nitrate Transporter Family Protein LjNPF8.6 Controls the N-Fixing Nodule Activity.Bioenergetic reprogramming plasticity under nitrogen depletion by the unicellular green alga Scenedesmus obliquus.The occurrence and control of nitric oxide generation by the plant mitochondrial electron transport chain.Inverse modulation of the energy sensor Snf1-related protein kinase 1 on hypoxia adaptation and salt stress tolerance in Arabidopsis thaliana.
P2860
Q26752260-35443C60-CFCD-4EB9-8030-9D54E7149CD3Q27003988-A5E3BFED-28BD-4829-ADCE-084270467AE9Q28085315-9CBFC1D0-8D0D-43C9-A20B-925FE9716E2CQ28752322-E149B511-B705-4D95-99A7-4C131CE470F3Q30724290-B5226EB2-69A4-47DD-A717-A6A155275192Q30848918-02590F1B-97EC-4323-91AB-C698460C7453Q33509460-5CF45C01-5A74-49E8-8D9C-1A5D74F9B877Q33700502-34E5FAB6-09EC-4CE2-9F1D-1F4066956EA5Q33838009-C73E14E1-9EF2-4781-A3FE-D8BE2C79774FQ34060377-8D5DA70B-2F76-48AE-BA4B-00323F382421Q34297578-CFC7CE36-5E6A-49DB-A630-9F3E5F0E1C10Q34473906-0F4CBDF7-C518-40E3-8995-060A97C1253FQ35926937-895F403D-53A1-4CE9-B8F4-C6A5FA988B74Q36603731-2FDA6C6B-1373-4C22-BBDA-DED05A70C4F4Q37207996-6687D8DA-C821-4475-A3E4-ED5DEEDEBA36Q37222643-24BE9809-4A69-42FD-B5F5-68E025DFD683Q37367025-1F34474F-2A9A-45E3-A261-EA73F5414F1EQ37386034-2A1B93C9-185A-4200-9EAD-8251FC4203F9Q37811042-A2FD0A73-004E-4006-8C1A-FBEF4F505A89Q37858923-7166B9FD-BF84-4B2C-9C13-93ADC5111B4FQ37940831-8BD3F183-3776-4D78-B955-913368CBC796Q38078367-A06D5E65-E958-4B9B-87B3-300506C4796FQ38191657-5A0A3431-8D54-42CC-A20E-7C8D70093576Q38903447-AFAA8353-8BC4-49DE-9368-D7A1C5E3A81EQ38988525-3CECFC2C-1B72-438E-B74F-3107DE69DD36Q40588427-31D20EEE-8A0C-4B7D-A27F-05B6363E7852Q42003196-138E4061-BA14-421B-9B56-B545DBA67F5BQ42640888-DB75BD41-1F12-4950-8CCA-5C4F80097D43Q43098981-F6B7995A-ECD5-43AF-83A1-FA6E1F3A31D0Q43797900-AF3CDA79-4F1C-42F0-B8B8-79E6D8D94A2EQ46871870-926C4A33-53FA-4FD7-B24C-BA96003BB71AQ46976218-92ECADCC-9AC8-4079-923D-77C9B2EB39D2Q47770953-189E9625-7803-4BBF-8195-AE7F29D8E3D1Q47820527-222D8EB7-22B0-48C5-8CEE-A5E03AA6E798Q48017820-CF988BA8-D986-4E58-A699-D7E2F24501DBQ54348035-D41C4E79-01F4-405F-AF61-52275FEC52B1
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 26 June 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Plant mitochondrial function during anaerobiosis.
@en
Plant mitochondrial function during anaerobiosis.
@nl
type
label
Plant mitochondrial function during anaerobiosis.
@en
Plant mitochondrial function during anaerobiosis.
@nl
prefLabel
Plant mitochondrial function during anaerobiosis.
@en
Plant mitochondrial function during anaerobiosis.
@nl
P2860
P356
P1433
P1476
Plant mitochondrial function during anaerobiosis
@en
P2093
Robert D Hill
P2860
P304
P356
10.1093/AOB/MCN100
P407
P577
2008-06-26T00:00:00Z