| review article | Q7318358 |
| scholarly article | Q13442814 |
| P2093 | author name string | Kutschera U | |
| Niklas KJ | |||
| P2860 | cites work | Cell-wall synthesis and elongation growth in hypocotyls of Helianthus annuus L | Q86656330 |
| P433 | issue | 11 | |
| P1104 | number of pages | 15 | |
| P304 | page(s) | 1395-1409 | |
| P577 | publication date | 2007-10-01 | |
| P1433 | published in | The Journal of Plant Physiology | Q15755489 |
| P1476 | title | The epidermal-growth-control theory of stem elongation: an old and a new perspective | |
| P478 | volume | 164 |
| Q47254843 | A hypergravity environment increases chloroplast size, photosynthesis, and plant growth in the moss Physcomitrella patens |
| Q33360109 | A mechanically sensitive cell layer regulates the physical properties of the Arabidopsis seed coat |
| Q42380165 | A mechanosensitive Ca2+ channel activity is dependent on the developmental regulator DEK1. |
| Q27300288 | A novel method of measuring leaf epidermis and mesophyll stiffness shows the ubiquitous nature of the sandwich structure of leaf laminas in broad-leaved angiosperm species |
| Q55350725 | A tension-adhesion feedback loop in plant epidermis. |
| Q46246741 | Acid growth: an ongoing trip |
| Q48048246 | An Automated Confocal Micro-Extensometer Enables in Vivo Quantification of Mechanical Properties with Cellular Resolution |
| Q58726987 | Anisotropic growth is achieved through the additive mechanical effect of material anisotropy and elastic asymmetry |
| Q92382093 | Are microtubules tension sensors? |
| Q30668591 | Are trichomes involved in the biomechanical systems of Cucurbita leaf petioles? |
| Q87354392 | Assembly and loss of the polar flagellum in plant-associated methylobacteria |
| Q41893552 | Basic versus applied research: Julius Sachs (1832-1897) and the experimental physiology of plants |
| Q36073538 | Brassinosteroid action in flowering plants: a Darwinian perspective |
| Q53368532 | Cell length instead of cell number becomes the predominant factor contributing to hypocotyl length genotypic differences under abiotic stress in Medicago truncatula. |
| Q27324634 | Cell patterns emerge from coupled chemical and physical fields with cell proliferation dynamics: the Arabidopsis thaliana root as a study system |
| Q84711808 | Cell wall polysaccharide distribution in Sandersonia aurantiaca flowers using immuno-detection |
| Q83483239 | Cellular force microscopy for in vivo measurements of plant tissue mechanics |
| Q34192848 | Chemical and structural analysis of Eucalyptus globulus and E. camaldulensis leaf cuticles: a lipidized cell wall region |
| Q89347678 | Circadian clocks: Who knows where the time goes |
| Q42513390 | Circumnutation and distribution of phytohormones in Vigna angularis epicotyls |
| Q31104733 | Decentralized circadian clocks process thermal and photoperiodic cues in specific tissues. |
| Q45285851 | Differential regulation of cellulose orientation at the inner and outer face of epidermal cells in the Arabidopsis hypocotyl |
| Q92564318 | Discrete mechanical growth model for plant tissue |
| Q57175811 | Dynamical Patterning Modules, Biogeneric Materials, and the Evolution of Multicellular Plants |
| Q33353134 | Elastic domains regulate growth and organogenesis in the plant shoot apical meristem |
| Q48290276 | Epidermal Phytochrome B Inhibits Hypocotyl Negative Gravitropism Non-Cell-Autonomously. |
| Q33350076 | Epidermis: the formation and functions of a fundamental plant tissue. |
| Q48456060 | Evolutionary plant physiology: Charles Darwin's forgotten synthesis |
| Q33679570 | Expansins expression is associated with grain size dynamics in wheat (Triticum aestivum L.). |
| Q64965752 | Feeling Stressed or Strained? A Biophysical Model for Cell Wall Mechanosensing in Plants. |
| Q37634233 | Functional adaptation and phenotypic plasticity at the cellular and whole plant level |
| Q38378767 | Growth-limiting proteins in maize coleoptiles and the auxin-brassinosteroid hypothesis of mesocotyl elongation. |
| Q38929500 | How do plants read their own shapes? |
| Q38095617 | How mechanical stress controls microtubule behavior and morphogenesis in plants: history, experiments and revisited theories |
| Q41882063 | Importance of epidermal clocks for regulation of hypocotyl elongation through PIF4 and IAA29. |
| Q33351276 | In vivo analysis of local wall stiffness at the shoot apical meristem in Arabidopsis using atomic force microscopy. |
| Q41145661 | Is acid-induced extension in seed plants only protein-mediated? |
| Q39429043 | Life behind the wall: sensing mechanical cues in plants |
| Q100387916 | Local HY5 Activity Mediates Hypocotyl Growth and Shoot-to-Root Communication |
| Q47565064 | Macroevolution via secondary endosymbiosis: a Neo-Goldschmidtian view of unicellular hopeful monsters and Darwin's primordial intermediate form |
| Q33356298 | Mechanical control of morphogenesis at the shoot apex |
| Q28658551 | Mechanical forces as information: an integrated approach to plant and animal development |
| Q34854606 | Mechanical modelling quantifies the functional importance of outer tissue layers during root elongation and bending. |
| Q48279148 | Mechanical regulation of organ asymmetry in leaves. |
| Q33362011 | Mechanical stress contributes to the expression of the STM homeobox gene in Arabidopsis shoot meristems |
| Q33362027 | Mechanically, the Shoot Apical Meristem of Arabidopsis Behaves like a Shell Inflated by a Pressure of About 1 MPa. |
| Q44111184 | Metabolic scaling theory in plant biology and the three oxygen paradoxa of aerobic life |
| Q45255809 | Methylotrophic bacteria on the surfaces of field-grown sunflower plants: a biogeographic perspective |
| Q37968628 | Microtubule and cellulose microfibril orientation during plant cell and organ growth |
| Q33365228 | Model of polar auxin transport coupled to mechanical forces retrieves robust morphogenesis along the Arabidopsis root |
| Q38033585 | Morpho-elastodynamics: the long-time dynamics of elastic growth |
| Q38366563 | Multiscale models in the biomechanics of plant growth. |
| Q38126482 | On the role of stress anisotropy in the growth of stems. |
| Q42771607 | Ontogenetic changes in the scaling of cellular respiration with respect to size among sunflower seedlings |
| Q38698038 | Organ-specific rates of cellular respiration in developing sunflower seedlings and their bearing on metabolic scaling theory |
| Q33351493 | Organogenesis from stem cells in planta: multiple feedback loops integrating molecular and mechanical signals |
| Q89475815 | Pectin methylesterase selectively softens the onion epidermal wall yet reduces acid-induced creep |
| Q38213230 | Physical forces regulate plant development and morphogenesis |
| Q38160188 | Plant biomechanics and mechanobiology are convergent paths to flourishing interdisciplinary research |
| Q37321942 | Plant cell shape: modulators and measurements |
| Q42174835 | Plant development, auxin, and the subsystem incompleteness theorem |
| Q34987272 | Plasma membrane H⁺ -ATPase regulation is required for auxin gradient formation preceding phototropic growth. |
| Q47679404 | Pollen tube growth and guidance: Occam's razor sharpened on a molecular arabinogalactan glycoprotein Rosetta Stone |
| Q90048487 | Rapid Auxin-Mediated Cell Expansion |
| Q35851948 | Rapid auxin-mediated changes in the proteome of the epidermal cells in rye coleoptiles: implications for the initiation of growth |
| Q57898813 | Reaction of sunflower varieties toSclerotinia sclerotiorumunder various inoculation methods, time of field evaluation and phylogenic stages of host |
| Q91716262 | Reorientation of Cortical Microtubule Arrays in the Hypocotyl of Arabidopsis thaliana Is Induced by the Cell Growth Process and Independent of Auxin Signaling |
| Q91304967 | Reply to 'Early shaping of a leaf' |
| Q37622066 | Reshaping Plant Biology: Qualitative and Quantitative Descriptors for Plant Morphology |
| Q37980361 | Root phototropism: from dogma to the mechanism of blue light perception |
| Q33921150 | SHINE transcription factors act redundantly to pattern the archetypal surface of Arabidopsis flower organs |
| Q35575172 | Salinity stiffens the epidermal cell walls of salt-stressed maize leaves: is the epidermis growth-restricting? |
| Q38123149 | Shrinking the hammer: micromechanical approaches to morphogenesis |
| Q26865223 | Slow, fast and furious: understanding the physics of plant movements |
| Q90318244 | Stem cells within the shoot apical meristem: identity, arrangement and communication |
| Q27323326 | Stress and strain provide positional and directional cues in development |
| Q37700557 | Subcellular and supracellular mechanical stress prescribes cytoskeleton behavior in Arabidopsis cotyledon pavement cells |
| Q54969693 | The Role of Auxin in Cell Wall Expansion. |
| Q37849735 | The biophysical design of plant cuticles: an overview. |
| Q37104711 | The epidermis coordinates auxin-induced stem growth in response to shade. |
| Q39662800 | The evolution of the plant genome-to-morphology auxin circuit. |
| Q41875753 | The growing outer epidermal wall: design and physiological role of a composite structure |
| Q51552921 | The importance of leaf cuticle for carbon economy and mechanical strength. |
| Q33348317 | The mechanics behind plant development |
| Q38230014 | There's more than one way to skin a fruit: formation and functions of fruit cuticles |
| Q30495520 | Tissue-specific transcriptome profiling of the citrus fruit epidermis and subepidermis using laser capture microdissection |
| Q48088332 | Ultrastructure of the Epidermal Cell Wall and Cuticle of Tomato Fruit (Solanum lycopersicum L.) during Development. |
| Q82231038 | WallGen, software to construct layered cellulose-hemicellulose networks and predict their small deformation mechanics |
| Q50421811 | Why plants make puzzle cells, and how their shape emerges. |
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