Ionic signaling in plant responses to gravity and touch.
about
A Bird's-Eye View of Molecular Changes in Plant Gravitropism Using Omics TechniquesCalcium mobilizations in response to changes in the gravity vector in Arabidopsis seedlings: possible cellular mechanismsUnited in diversity: mechanosensitive ion channels in plants"Feature Detection" vs. "Predictive Coding" Models of Plant BehaviorRapid and dynamic subcellular reorganization following mechanical stimulation of Arabidopsis epidermal cells mimics responses to fungal and oomycete attack.Spatiotemporal dynamics of the electrical network activity in the root apex.The Root Apex of Arabidopsis thaliana Consists of Four Distinct Zones of Growth Activities: Meristematic Zone, Transition Zone, Fast Elongation Zone and Growth Terminating Zone.Strategies of seedlings to overcome their sessile nature: auxin in mobility control.Joining forces: the interface of gravitropism and plastid protein import.Mechanical stimuli regulate the allocation of biomass in trees: demonstration with young Prunus avium trees.Plasma membrane protein OsMCA1 is involved in regulation of hypo-osmotic shock-induced Ca2+ influx and modulates generation of reactive oxygen species in cultured rice cells.Calcium in plants.Gravity signal transduction in primary roots.Two seven-transmembrane domain MILDEW RESISTANCE LOCUS O proteins cofunction in Arabidopsis root thigmomorphogenesis.The root as a drill: an ethylene-auxin interaction facilitates root penetration in soilA force of nature: molecular mechanisms of mechanoperception in plants.Calcium signaling network in plants: an overview.Comprehensive Analysis of the CDPK-SnRK Superfamily Genes in Chinese Cabbage and Its Evolutionary Implications in Plants.Gravity research on plants: use of single-cell experimental models.Molecular mechanisms of root gravity sensing and signal transduction.Mechanosensitive channels are activated by stress in the actin stress fibres, and could be involved in gravity sensing in plants.Dynamics of auxin-dependent Ca2+ and pH signaling in root growth revealed by integrating high-resolution imaging with automated computer vision-based analysis.Life behind the wall: sensing mechanical cues in plants.Raising salinity tolerant rice: recent progress and future perspectives.Intracellular reorganization and ionic signaling of the Phycomyces stage I sporangiophore in response to gravity and touchCircadian rhythm leaf movement of Phaseolus vulgaris and the role of calcium ionsCortical microtubules are responsible for gravity resistance in plants.Isolation, characterization and immunolocalization of a seed dominant CaM from finger millet (Eleusine coracana L. Gartn.) for studying its functional role in differential accumulation of calcium in developing grains.MCA1 and MCA2 that mediate Ca2+ uptake have distinct and overlapping roles in Arabidopsis.Reversible Change of Extracellular pH at the Generation of Mechano-Induced Electrical Reaction in a Stem of Cucurbita pepo.Roles of a putative mechanosensitive plasma membrane Ca2+-permeable channel OsMCA1 in generation of reactive oxygen species and hypo-osmotic signaling in rice.A test for hydrotropic behavior by roots of two coastal dune shrubs.Gravity-induced modifications to development in hypocotyls of Arabidopsis tubulin mutants.The fast and transient transcriptional network of gravity and mechanical stimulation in the Arabidopsis root apex.A universal role for inositol 1,4,5-trisphosphate-mediated signaling in plant gravitropism.Cytoplasmic calcium increases in response to changes in the gravity vector in hypocotyls and petioles of Arabidopsis seedlings.The Rice E3-Ubiquitin Ligase HIGH EXPRESSION OF OSMOTICALLY RESPONSIVE GENE1 Modulates the Expression of ROOT MEANDER CURLING, a Gene Involved in Root Mechanosensing, through the Interaction with Two ETHYLENE-RESPONSE FACTOR Transcription Factors.Anoxia-induced elevation of cytosolic Ca2+ concentration depends on different Ca2+ sources in rice and wheat protoplasts.Genetic dissection of hormonal responses in the roots of Arabidopsis grown under continuous mechanical impedance.Electrophysiological experiments in microgravity: lessons learned and future challenges.
P2860
Q26770650-D3FEAA16-EBC6-4FB3-B5EF-121694C39C46Q26821778-0CCAA6B2-9724-423B-9051-85927E22AA8AQ26851455-E2E48240-75F2-46E2-9463-CBF7279DA854Q30372264-47450D2C-0A0C-49FA-A944-CBA99622C833Q30482409-3C3D9C8C-CD11-4777-A37E-7A543FF86FDBQ30486504-42202A8F-0032-4A32-9FD0-6F229D035B71Q33347242-0108BEF5-E588-409D-BC78-7863EB57FAB1Q33360604-EBCCB082-210C-48D6-9942-A45178B4B284Q33570179-742B0B96-B441-4022-AB17-3B150DAA4993Q34011413-00CAA116-864D-4BF2-87ED-C1097AB87377Q34134639-456EA916-43D8-4936-BD75-692DEDE68527Q34224629-DBA47850-4A67-4980-8BB6-A5DF1D136061Q34435512-DD10EBC9-02CF-4F4D-9F5D-F8F62623582BQ34609914-DBD5BA5A-01DB-48C1-B500-A4297931AE8EQ36119028-D7E01977-4E61-46D2-8C48-E79C8D8FC2E2Q37280982-4CBAE086-14D8-4C50-9CFD-3FA01D414C84Q37514909-0E557BB8-8D92-45D4-87AA-1CAB00916CAFQ37635122-AF818C00-7491-4213-82B3-BB74D37732EDQ38013749-6A4B065E-C24B-4D17-8E6D-4E88370272A2Q38117088-27B81C10-2426-4BC2-9DF0-E0FF579E8387Q38135512-F1272E80-1997-4577-A866-7485BD991831Q39263307-02C5E8EC-AF6A-4511-9547-7B73807E45A1Q39429043-A5976210-6D9A-4C9A-AEFE-37DEC7D634CCQ40109254-0B3D0F4D-EC44-4917-81AA-DB360162DBF0Q40346157-22BF7D87-FA86-4573-8F34-717FB9F44E83Q40382986-AEF12C86-7D5B-46C0-B06D-98753707DA07Q41145611-7CA54C48-3CC5-407B-84FE-0DDBBD575B6DQ42640063-DC777561-2DD1-4E7F-90A3-CAFF99623F23Q43185238-70000353-E999-4E75-9FCA-B705C8C3CAE6Q43189829-DDF7E3E9-3EDE-4993-BBB3-E7E4DF6D1A3BQ43238529-2949F70D-58B4-4BF8-8A2E-89F16D3FCE77Q44374096-65A4F344-F821-472F-B0B0-3B8C5E6E0271Q44526977-1689D5FF-3341-462D-BDCE-E552B1EA57DCQ44860608-75280817-8894-4F32-B5B7-8752C883583FQ44864535-2BECFB96-C833-4942-9921-C1E4AD574A82Q46869084-28613BF3-6ED9-4EDF-A039-4E1488C67922Q48132177-CB55C663-F7A3-494E-9B2C-C7753D619A7BQ50541995-0BF4BFCB-7FEE-4AD0-9C28-E9ED5C5FB2D7Q53497145-3605EDF5-150F-4BFF-8759-BD724EB90DCEQ55082298-00779E14-6DB1-4EB1-9D2F-054F06BBEF98
P2860
Ionic signaling in plant responses to gravity and touch.
description
2002 nî lūn-bûn
@nan
2002 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Ionic signaling in plant responses to gravity and touch.
@ast
Ionic signaling in plant responses to gravity and touch.
@en
Ionic signaling in plant responses to gravity and touch.
@nl
type
label
Ionic signaling in plant responses to gravity and touch.
@ast
Ionic signaling in plant responses to gravity and touch.
@en
Ionic signaling in plant responses to gravity and touch.
@nl
prefLabel
Ionic signaling in plant responses to gravity and touch.
@ast
Ionic signaling in plant responses to gravity and touch.
@en
Ionic signaling in plant responses to gravity and touch.
@nl
P356
P1476
Ionic signaling in plant responses to gravity and touch.
@en
P2093
Gioia D Massa
Jeremiah M Fasano
P2888
P356
10.1007/S003440010049
P50
P577
2002-05-23T00:00:00Z