| scholarly article | Q13442814 |
| P356 | DOI | 10.1104/PP.58.2.210 |
| P698 | PubMed publication ID | 16659649 |
| P2093 | author name string | R E Cleland | |
| P2860 | cites work | Auxin-induced hydrogen ion excretion from Avena coleoptiles | Q34742753 |
| Timing of the Auxin Response in Coleoptiles and Its Implications Regarding Auxin Action | Q36387249 | ||
| Fine control of DNA synthesis in developing chick red blood cells | Q43988823 | ||
| Rapid Auxin-induced Decrease in Free Space pH and Its Relationship to Auxin-induced Growth in Maize and Pea. | Q46031069 | ||
| Growth-limiting Proteins in Relation to Auxin-induced Elongation in Lupin Hypocotyls | Q47944890 | ||
| Effect of pH and Surface Charge on Cell Uptake of Auxin | Q53799502 | ||
| Effect of External K, NH(4), Na, Ca, Mg, and H Ions on the Cell Transmembrane Electropotential of Avena Coleoptile | Q83240466 | ||
| Time course of auxin stimulations of growth | Q83244469 | ||
| Enhancement of wall loosening and elongation by Acid solutions | Q83244509 | ||
| P433 | issue | 2 | |
| P1104 | number of pages | 4 | |
| P304 | page(s) | 210-213 | |
| P577 | publication date | 1976-08-01 | |
| P1433 | published in | Plant Physiology | Q3906288 |
| P1476 | title | Kinetics of Hormone-induced H Excretion | |
| P478 | volume | 58 |
| Q86883950 | Acid growth effects in maize roots: Evidence for a link between auxin-economy and proton extrusion in the control of root growth |
| Q47937389 | Action of protein synthesis inhibitors in blocking electrogenic h efflux from corn roots |
| Q83254809 | An Improved Method for Detecting Auxin-induced Hydrogen Ion Efflux from Corn Coleoptile Segments |
| Q39133467 | Auxin Has No Effect on Modification of External pH by Soybean Hypocotyl Cells |
| Q47730735 | Auxin induces exocytosis and the rapid synthesis of a high-turnover pool of plasma-membrane H(+)-ATPase |
| Q87090725 | Auxin inhibition of acid-and fusicoccin-induced elongation in lentil roots |
| Q41271680 | Auxin-binding Protein 1 Does Not Bind Auxin within the Endoplasmic Reticulum Despite This Being the Predominant Subcellular Location for This Hormone Receptor |
| Q46026475 | Auxin-induced H Secretion in Helianthus and Its Implications. |
| Q83256751 | Auxin-induced changes in the population of translatable messenger RNA in elongating sections of soybean hypocotyl |
| Q74464493 | Auxin-induced growth of Avena coleoptiles involves two mechanisms with different pH optima |
| Q64013124 | Chapter 6 Control of Plant Cell Enlargement By Hydrogen Ions |
| Q83250955 | Comparison of Auxin-induced and Acid-induced Elongation in Soybean Hypocotyl |
| Q74463423 | Comparison of the lipid composition of oat root and coleoptile plasma membranes: lack of short-term change in response to auxin |
| Q87079926 | Continuous measurement of initial curvature of maize coleoptiles induced by lateral auxin application |
| Q87079768 | Does indoleacetic acid promote growth via cell wall acidification? |
| Q83269960 | Does salinity reduce growth in maize root epidermal cells by inhibiting their capacity for cell wall acidification? |
| Q46072668 | Effect of salt on auxin-induced acidification and growth by pea internode sections |
| Q36702384 | Electron and proton transport across the plasma membrane |
| Q64013127 | Evidence against the acid-growth theory of auxin action |
| Q46618738 | Evidence that Auxin-induced Growth of Soybean Hypocotyls Involves Proton Excretion |
| Q95439180 | Evidence that auxin-induced growth of tobacco leaf tissues does not involve cell wall acidification |
| Q87079545 | Growth of Avena coleoptiles and pH drop of protoplast suspensions induced by chlorinated indoleacetic acids |
| Q83258848 | H fluxes in excised samanea motor tissue : I. Promotion by light |
| Q37409069 | Indole-3-acetic acid and fusicoccin cause cytosolic acidification of corn coleoptile cells |
| Q45990391 | Induced k efflux from cultured rose cells : effects of protein-synthesis inhibitors. |
| Q47939338 | Inhibition of Polar Indole-3-acetic Acid Transport by Cycloheximide |
| Q46473063 | Inhibition of stem elongation in cucumis seedlings by blue light requires calcium |
| Q87090010 | Initial phases of indoleacetic acid induced growth in coleoptile segments of Avena sativa L |
| Q46477977 | Involvement of Macromolecule Biosynthesis in Auxin and Fusicoccin Enhancement of beta-Glucan Synthase Activity in Pea. |
| Q83253536 | Ion Fluxes and Phytochrome Protons in Mung Bean Hypocotyl Segments: II. Fluxes of Chloride, Protons, and Orthophosphate in Apical and Subhook Segments |
| Q47105133 | Leaf expansion in Phaseolus: transient auxin-induced growth increase |
| Q35420740 | Mathematical analysis of the chemosmotic polar diffusion of auxin through plant tissues |
| Q87078619 | Membrane potential changes during transport of hexoses in Lemna gibba G1 |
| Q38208376 | Natural compounds as next-generation herbicides |
| Q83250812 | On the Relationship between Extracellular pH and the Growth of Excised Pea Stem Segments |
| Q40174452 | Parasitic origins of nitrogen-mixing Rhizobium-legume symbioses. A review of the evidence |
| Q47706072 | Protein patterns in the oat coleoptile as influenced by auxin and by protein turnover |
| Q47704308 | Protein synthesis and auxin-induced growth: Inhibitor studies |
| Q83256389 | Proton efflux from corn roots induced by tripropyltin |
| Q46031069 | Rapid Auxin-induced Decrease in Free Space pH and Its Relationship to Auxin-induced Growth in Maize and Pea. |
| Q83250703 | Rapid Hormone-induced Hyperpolarization of the Oat Coleoptile Transmembrane Potential |
| Q86811950 | Rapid response of the plasma-membrane potential in oat coleoptiles to auxin and other weak acids |
| Q83270227 | Reexamination of the Acid growth theory of auxin action |
| Q83267023 | Regulation of electrogenic proton pumping by auxin and fusicoccin as related to the growth of Avena coleoptiles |
| Q83256231 | Responses of Avena coleoptiles to suboptimal fusicoccin: kinetics and comparisons with indoleacetic Acid |
| Q44561210 | Role of the plasma membrane H+-ATPase in auxin-induced elongation growth: historical and new aspects |
| Q28360006 | Salinity-induced inhibition of leaf elongation in maize is not mediated by changes in cell wall acidification capacity |
| Q46739197 | Short-term kinetics of elongation growth of gibberellin-responsive lettuce hypocotyl sections |
| Q54588541 | The contribution of tonoplast and plasma membrane to the electrical properties of a higher-plant cell. |
| Q35062488 | The kinetics of bidirectional growth of stem sections from etiolated pea seedlings in response to acid, auxin and fusicoccin |
| Q86639227 | The pH profile for acid-induced elongation of coleoptile and epicotyl sections is consistent with the acid-growth theory |
| Q36409566 | The possible role of redox-associated protons in growth of plant cells |
| Q44516818 | The role of acidification in gibberellic acid- and fusicoccin-induced elongation growth of lettuce hypocotyl sections |
| Q86796444 | The roles of cell-wall acidification and proton-pump stimulation in auxin-induced growth: studies using monensin |
| Q86912235 | The stability of the postulated wall-loosening enzyme in acid-induced growth |
| Q86839054 | Transmembrane electrical potentials in growing maize roots : Anti-auxin effects |
| Q37224333 | Transplasma membrane electron transport in plants |
| Q86760068 | Use of a pH-response curve for growth to predict apparent wall pH in elongating segments of maize coleoptiles and sunflower hypocotyls |
| Q36418924 | Vanadate inhibition of auxin-enhanced H secretion and elongation in pea epicotyls and oat coleoptiles |
| Q86892063 | pH and membrane-potential changes during glucose uptake inLemna gibba G1 and their response to light |
| Q86901011 | pH-Dependent accumulation of indoleacetic acid by corn coleoptile sections |
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