| scholarly article | Q13442814 |
| P50 | author | Martin Potocký | Q59065956 |
| Přemysl Pejchar | Q38321089 | ||
| Nicolas Vitale | Q46428894 | ||
| Roman Pleskot | Q51776813 | ||
| Viktor Žárský | Q58212171 | ||
| P2093 | author name string | Benedikt Kost | |
| P2860 | cites work | Electrostatics of nanosystems: application to microtubules and the ribosome | Q24555224 |
| Lifeact-mEGFP reveals a dynamic apical F-actin network in tip growing plant cells | Q27348942 | ||
| VMD: visual molecular dynamics | Q27860554 | ||
| Comparative protein modelling by satisfaction of spatial restraints | Q27860866 | ||
| GROMACS 4: Algorithms for Highly Efficient, Load-Balanced, and Scalable Molecular Simulation | Q27860944 | ||
| Positive and negative regulation of a SNARE protein by control of intracellular localization | Q27940373 | ||
| Structural insights into the inhibition of actin-capping protein by interactions with phosphatidic acid and phosphatidylinositol (4,5)-bisphosphate | Q28484772 | ||
| The MARTINI force field: coarse grained model for biomolecular simulations | Q29617215 | ||
| Protein structure prediction and analysis using the Robetta server. | Q30341988 | ||
| Molecular simulation approaches to membrane proteins. | Q30409396 | ||
| Toward optimal fragment generations for ab initio protein structure assembly | Q30421206 | ||
| Magnitude and direction of vesicle dynamics in growing pollen tubes using spatiotemporal image correlation spectroscopy and fluorescence recovery after photobleaching | Q33338389 | ||
| Spatial control of Rho (Rac-Rop) signaling in tip-growing plant cells | Q33345222 | ||
| How accurately can we image inositol lipids in living cells? | Q33953238 | ||
| Phosphatidic acid plays a regulatory role in clathrin-mediated endocytosis | Q34063818 | ||
| Putting the pH into phosphatidic acid signaling | Q34089359 | ||
| Influence of hydrophobic mismatch and amino acid composition on the lateral diffusion of transmembrane peptides | Q34099079 | ||
| Oscillatory ROP GTPase activation leads the oscillatory polarized growth of pollen tubes. | Q34099597 | ||
| Cellular oscillations and the regulation of growth: the pollen tube paradigm | Q34116886 | ||
| Polarized growth: maintaining focus on the tip. | Q34571394 | ||
| Rapid tip growth: insights from pollen tubes | Q35535585 | ||
| Turnover of Phosphatidic Acid through Distinct Signaling Pathways Affects Multiple Aspects of Pollen Tube Growth in Tobacco. | Q35970352 | ||
| Phosphatidylserine dynamics in cellular membranes | Q35998609 | ||
| Rac homologues and compartmentalized phosphatidylinositol 4, 5-bisphosphate act in a common pathway to regulate polar pollen tube growth. | Q36256463 | ||
| Phosphatidic acid- and phosphatidylserine-binding proteins | Q36453653 | ||
| Invasive cells in animals and plants: searching for LECA machineries in later eukaryotic life | Q36874387 | ||
| Reversible binding and rapid diffusion of proteins in complex with inositol lipids serves to coordinate free movement with spatial information | Q37124892 | ||
| Recycling domains in plant cell morphogenesis: small GTPase effectors, plasma membrane signalling and the exocyst. | Q37713937 | ||
| The regulation of vesicle trafficking by small GTPases and phospholipids during pollen tube growth | Q37758565 | ||
| Lipid dynamics in exocytosis. | Q37809768 | ||
| The plant non-specific phospholipase C gene family. Novel competitors in lipid signalling. | Q38054371 | ||
| Regulation of cytoskeletal dynamics by phospholipase D and phosphatidic acid | Q38105750 | ||
| Perspective on the Martini model. | Q38109488 | ||
| The challenges of understanding glycolipid functions: An open outlook based on molecular simulations | Q38177137 | ||
| When fat is not bad: the regulation of actin dynamics by phospholipid signaling molecules. | Q38183389 | ||
| A GFP-mouse talin fusion protein labels plant actin filaments in vivo and visualizes the actin cytoskeleton in growing pollen tubes | Q40982497 | ||
| Effects of propranolol on phosphatidate phosphohydrolase and mitogen-activated protein kinase activities in A7r5 vascular smooth muscle cells | Q41012556 | ||
| Mutual regulation of plant phospholipase D and the actin cytoskeleton. | Q43165373 | ||
| Osmotically induced cell swelling versus cell shrinking elicits specific changes in phospholipid signals in tobacco pollen tubes | Q44739186 | ||
| NADPH oxidase activity in pollen tubes is affected by calcium ions, signaling phospholipids and Rac/Rop GTPases | Q44877631 | ||
| Phosphoinositides and phosphatidic acid regulate pollen tube growth and reorientation through modulation of [Ca2+]c and membrane secretion | Q46443590 | ||
| Distinct endocytic pathways identified in tobacco pollen tubes using charged nanogold | Q46947864 | ||
| The MARTINI Coarse-Grained Force Field: Extension to Proteins. | Q47741405 | ||
| Pollen tube tip growth depends on plasma membrane polarization mediated by tobacco PLC3 activity and endocytic membrane recycling | Q48082793 | ||
| Petunia phospholipase c1 is involved in pollen tube growth | Q48090130 | ||
| Visualization of phosphatidylinositol 4,5-bisphosphate in the plasma membrane of suspension-cultured tobacco BY-2 cells and whole Arabidopsis seedlings. | Q50663155 | ||
| The recruitment of Raf-1 to membranes is mediated by direct interaction with phosphatidic acid and is independent of association with Ras. | Q52539180 | ||
| Imaging phosphatidylinositol 4-phosphate dynamics in living plant cells. | Q53454838 | ||
| An electrostatic/hydrogen bond switch as the basis for the specific interaction of phosphatidic acid with proteins | Q57098868 | ||
| Lipid Metabolism, Compartmentalization and Signalling in the Regulation of Pollen Tube Growth | Q57558738 | ||
| Phospholipase D1 Production of Phosphatidic Acid at the Plasma Membrane Promotes Exocytosis of Large Dense-core Granules at a Late Stage | Q58025406 | ||
| Nt-RhoGDI2 regulates Rac/Rop signaling and polar cell growth in tobacco pollen tubes | Q58335401 | ||
| Imaging and manipulating phosphoinositides in living cells | Q58451410 | ||
| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | pollen | Q79932 |
| visualization | Q451553 | ||
| biosensor | Q669391 | ||
| P304 | page(s) | 483-494 | |
| P577 | publication date | 2014-04-22 | |
| P1433 | published in | New Phytologist | Q13548580 |
| P1476 | title | Live-cell imaging of phosphatidic acid dynamics in pollen tubes visualized by Spo20p-derived biosensor | |
| P478 | volume | 203 |
| Q37565019 | A Phosphatidic Acid (PA) conveyor system of continuous intracellular transport from cell membrane to nucleus maintains EGF receptor homeostasis |
| Q30776326 | A PtdIns(4)P-driven electrostatic field controls cell membrane identity and signalling in plants. |
| Q38893703 | A central role for phosphatidic acid as a lipid mediator of regulated exocytosis in apicomplexa. |
| Q39023550 | Analysis of Exocyst Subunit EXO70 Family Reveals Distinct Membrane Polar Domains in Tobacco Pollen Tubes. |
| Q64119343 | Anionic Lipids: A Pipeline Connecting Key Players of Plant Cell Division |
| Q37686929 | Anionic lipids and the maintenance of membrane electrostatics in eukaryotes. |
| Q40821099 | Antifungal mechanisms of a plant defensin MtDef4 are not conserved between the ascomycete fungi Neurospora crassa and Fusarium graminearum |
| Q92422856 | Arabidopsis Trichome Contains Two Plasma Membrane Domains with Different Lipid Compositions Which Attract Distinct EXO70 Subunits |
| Q38661400 | Central metabolite and sterol profiling divides tobacco male gametophyte development and pollen tube growth into eight metabolic phases |
| Q46428843 | Comparative Characterization of Phosphatidic Acid Sensors and Their Localization during Frustrated Phagocytosis |
| Q35067464 | Emerging roles for microtubules in angiosperm pollen tube growth highlight new research cues. |
| Q52720799 | Gene Expression Pattern and Protein Localization of Arabidopsis Phospholipase D Alpha 1 Revealed by Advanced Light-Sheet and Super-Resolution Microscopy. |
| Q90681355 | Generation of Superoxide by OeRbohH, a NADPH Oxidase Activity During Olive (Olea europaea L.) Pollen Development and Germination |
| Q43775186 | Heterodimeric capping protein from Arabidopsis is a membrane-associated, actin-binding protein. |
| Q42505184 | In Vivo Imaging of Diacylglycerol at the Cytoplasmic Leaflet of Plant Membranes. |
| Q53595862 | Introduction to a Virtual Special Issue on cell biology at the plant-microbe interface. |
| Q38618572 | Lipid signalling in plant responses to abiotic stress |
| Q30642233 | Loss of the Arabidopsis thaliana P4-ATPases ALA6 and ALA7 impairs pollen fitness and alters the pollen tube plasma membrane |
| Q30315881 | Male functions and malfunctions: the impact of phosphoinositides on pollen development and pollen tube growth. |
| Q43148251 | Non-specific phospholipase C4 mediates response to aluminum toxicity in Arabidopsis thaliana. |
| Q61811029 | Phosphatidic Acid: From Pleiotropic Functions to Neuronal Pathology |
| Q35094427 | Phospholipase D affects translocation of NPR1 to the nucleus in Arabidopsis thaliana. |
| Q38892847 | Phospholipid composition and a polybasic motif determine D6 PROTEIN KINASE polar association with the plasma membrane and tropic responses. |
| Q55514290 | Protein⁻Phospholipid Interaction Motifs: A Focus on Phosphatidic Acid. |
| Q38365330 | The song of lipids and proteins: dynamic lipid-protein interfaces in the regulation of plant cell polarity at different scales. |
| Q92883347 | Tissue-specific accumulation of pH-sensing phosphatidic acid determines plant stress tolerance |
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