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Volumn 64, Issue 15, 2013, Pages 4697-4707

On the role of stress anisotropy in the growth of stems

Author keywords

Cell wall; Cellulose microfibril; Elongation; Growth anisotropy; Maturation stress; Multiscale model; Radial expansion; Residual stress; Tissue stress; Tissue tension

Indexed keywords

CELLULOSE;

EID: 84887910577     PISSN: 00220957     EISSN: 14602431     Source Type: Journal    
DOI: 10.1093/jxb/ert176     Document Type: Review
Times cited : (62)

References (43)
  • 2
    • 67449118809 scopus 로고    scopus 로고
    • Cell wall biosynthesis and the molecular mechanism of plant enlargement
    • Boyer JS. 2009. Cell wall biosynthesis and the molecular mechanism of plant enlargement. Functional Plant Biology 36, 383-394.
    • (2009) Functional Plant Biology , vol.36 , pp. 383-394
    • Boyer, J.S.1
  • 3
    • 77957861787 scopus 로고    scopus 로고
    • The rotation of cellulose synthase trajectories is microtubule dependent and influences the texture of epidermal cell walls in arabidopsis hypocotyls
    • Chan J, Crowell E, Eder M., Calder G, Bunnewell S, Findlay K., Vernhettes S, Höfte H, Lloyd C. 2010. The rotation of cellulose synthase trajectories is microtubule dependent and influences the texture of epidermal cell walls in Arabidopsis hypocotyls. Journal of Cell Science 123, 3490-3495.
    • (2010) Journal of Cell Science , vol.123 , pp. 3490-3495
    • Chan, J.1    Crowell, E.2    Eder, M.3    Calder, G.4    Bunnewell, S.5    Findlay, K.6    Vernhettes, S.7    Höfte, H.8    Lloyd, C.9
  • 4
    • 78650987972 scopus 로고    scopus 로고
    • Maturation stress generation in poplar tension wood studied by synchrotron radiation micro-diffraction
    • Clair B, Alméras T, Pilate G., Jullien D, Sugiyama J, Riekel C. 2011. Maturation stress generation in poplar tension wood studied by synchrotron radiation micro-diffraction. Plant Physiology 155, 562-570.
    • (2011) Plant Physiology , vol.155 , pp. 562-570
    • Clair, B.1    Alméras, T.2    Pilate, G.3    Jullien, D.4    Sugiyama, J.5    Riekel, C.6
  • 5
    • 80051930448 scopus 로고    scopus 로고
    • Differential regulation of cellulose orientation at the inner and outer face of epidermal cells of the arabidopsis hypocotyl
    • Crowell EF, Timpano H, Desprez T., Franssen-Verheijen T, Emons A-M, Höfte H, Vernhettes S. 2011. Differential regulation of cellulose orientation at the inner and outer face of epidermal cells of the Arabidopsis hypocotyl. Plant Cell 23, 2592-2605.
    • (2011) Plant Cell , vol.23 , pp. 2592-2605
    • Crowell, E.F.1    Timpano, H.2    Desprez, T.3    Franssen-Verheijen, T.4    Emons, A.-M.5    Höfte, H.6    Vernhettes, S.7
  • 6
    • 84861923150 scopus 로고    scopus 로고
    • A model of crosslink kinetics in the expanding plant cell wall: Yield stress and enzyme action
    • Dyson RJ, Band LR, Jensen OE 2012. A model of crosslink kinetics in the expanding plant cell wall: yield stress and enzyme action. Journal of Theoretical Biology 307, 125-136.
    • (2012) Journal of Theoretical Biology , vol.307 , pp. 125-136
    • Dyson, R.J.1    Band, L.R.2    Jensen, O.E.3
  • 7
    • 77957111713 scopus 로고    scopus 로고
    • A fibre-reinforced fluid model of anisotropic plant cell growth
    • Dyson RJ, Jensen OE 2010. A fibre-reinforced fluid model of anisotropic plant cell growth. Journal of Fluid Mechanics 655, 472-503.
    • (2010) Journal of Fluid Mechanics , vol.655 , pp. 472-503
    • Dyson, R.J.1    Jensen, O.E.2
  • 8
    • 0000753870 scopus 로고
    • Structural characteristics of developing nitella internodal cell walls
    • Green PB. 1958. Structural characteristics of developing Nitella internodal cell walls. Journal of Biochemical and Biophysical Cytology 4, 505-516.
    • (1958) Journal of Biochemical and Biophysical Cytology , vol.4 , pp. 505-516
    • Green, P.B.1
  • 10
    • 14944350419 scopus 로고    scopus 로고
    • Buckling of inner cell wall layers after manipulations to reduce tensile stress: Observations and interpretations for stress transmission
    • Hejnowicz Z, Borowska-Wykrȩt D. 2005. Buckling of inner cell wall layers after manipulations to reduce tensile stress: observations and interpretations for stress transmission. Planta 220, 465-473.
    • (2005) Planta , vol.220 , pp. 465-473
    • Hejnowicz, Z.1    Borowska-Wykrȩt, D.2
  • 11
    • 0033942345 scopus 로고    scopus 로고
    • Tensile tissue stress affects the orientation of cortical microtubules in the epidermis of sunflower hypocotyl
    • Hejnowicz Z, Rusin A, Rusin T. 2000. Tensile tissue stress affects the orientation of cortical microtubules in the epidermis of sunflower hypocotyl. Journal of Plant Growth Regulation 19, 31-44.
    • (2000) Journal of Plant Growth Regulation , vol.19 , pp. 31-44
    • Hejnowicz, Z.1    Rusin, A.2    Rusin, T.3
  • 12
    • 77956983456 scopus 로고
    • Tissue stresses in organs of herbaceous plants. I. Poisson ratios of tissues and their role in determination of the stresses
    • Hejnowicz Z, Sievers A. 1995a. Tissue stresses in organs of herbaceous plants. I. Poisson ratios of tissues and their role in determination of the stresses. Journal of Experimental Botany 46, 1035-1043.
    • (1995) Journal of Experimental Botany , vol.46 , pp. 1035-1043
    • Hejnowicz, Z.1    Sievers, A.2
  • 13
    • 0028860033 scopus 로고
    • Tissue stresses in organs of herbaceous plants. II. Determination in three dimensions in the hypocotyl of sunflower
    • Hejnowicz Z, Sievers A. 1995b. Tissue stresses in organs of herbaceous plants. II. Determination in three dimensions in the hypocotyl of sunflower. Journal of Experimental Botany 46, 1045-1053.
    • (1995) Journal of Experimental Botany , vol.46 , pp. 1045-1053
    • Hejnowicz, Z.1    Sievers, A.2
  • 14
    • 17544369999 scopus 로고    scopus 로고
    • Tissue stresses in organs of herbaceous plants. III. Elastic properties of the tissues of sunflower hypocotyl and origin of tissue stresses
    • Hejnowicz Z, Sievers A. 1996. Tissue stresses in organs of herbaceous plants. III. Elastic properties of the tissues of sunflower hypocotyl and origin of tissue stresses. Journal of Experimental Botany 47, 519-528.
    • (1996) Journal of Experimental Botany , vol.47 , pp. 519-528
    • Hejnowicz, Z.1    Sievers, A.2
  • 16
    • 84995056601 scopus 로고
    • The role of the epidermis in the control of elongation growth in stems and coleoptiles
    • Kutschera U. 1992. The role of the epidermis in the control of elongation growth in stems and coleoptiles. Botanica Acta 105, 246-252.
    • (1992) Botanica Acta , vol.105 , pp. 246-252
    • Kutschera, U.1
  • 17
    • 35348880882 scopus 로고    scopus 로고
    • The epidermal-growth-control theory of stem elongation: An old and a new perspective
    • Kutschera U, Niklas KJ 2007. The epidermal-growth-control theory of stem elongation: an old and a new perspective. Journal of Plant Physiology 164, 1395-1409.
    • (2007) Journal of Plant Physiology , vol.164 , pp. 1395-1409
    • Kutschera, U.1    Niklas, K.J.2
  • 18
    • 84855894789 scopus 로고    scopus 로고
    • Tensional stress generation in gelatinous fibres: A review and possible mechanism based on cellwall structure and composition
    • Mellerowicz EJ, Gorshkova TA 2012. Tensional stress generation in gelatinous fibres: a review and possible mechanism based on cellwall structure and composition. Journal of Experimental Botany 63, 551-565.
    • (2012) Journal of Experimental Botany , vol.63 , pp. 551-565
    • Mellerowicz, E.J.1    Gorshkova, T.A.2
  • 19
    • 79551713682 scopus 로고    scopus 로고
    • VirtualLeaf: An open-source framework for cell-based modeling of plant tissue growth and development
    • Merks RMH, Guravage M, Inzé D, Beemster GTS. 2011. VirtualLeaf: an open-source framework for cell-based modeling of plant tissue growth and development. Plant Physiology 155, 656-666.
    • (2011) Plant Physiology , vol.155 , pp. 656-666
    • Merks, R.M.H.1    Guravage, M.2    Inzé, D.3    Beemster, G.T.S.4
  • 20
    • 23744448744 scopus 로고
    • Transverse viscoelastic extension in nitella. I. Relationship to growth rate
    • Métraux J.P., Taiz L. 1978. Transverse viscoelastic extension in Nitella. I. Relationship to growth rate. Plant Physiology 61, 135-138.
    • (1978) Plant Physiology , vol.61 , pp. 135-138
    • Métraux, J.P.1    Taiz, L.2
  • 21
    • 67650859608 scopus 로고    scopus 로고
    • The power and control of gravitropic movements in plants: A biomechanical and systems biology view
    • Moulia B, Fournier M. 2009. The power and control of gravitropic movements in plants: a biomechanical and systems biology view. Journal of Experimental Botany 60, 461-486.
    • (2009) Journal of Experimental Botany , vol.60 , pp. 461-486
    • Moulia, B.1    Fournier, M.2
  • 22
    • 0030759835 scopus 로고    scopus 로고
    • The role of the epidermis as a stiffening agent in tulipa (Liliaceae) stems
    • Niklas KJ, Paolillo DJ Jr. 1997. The role of the epidermis as a stiffening agent in Tulipa (Liliaceae) stems. American Journal of Botany 84, 735-744.
    • (1997) American Journal of Botany , vol.84 , pp. 735-744
    • Niklas, K.J.1    Paolillo Jr., D.J.2
  • 23
    • 0032229463 scopus 로고    scopus 로고
    • Preferential states of longitudinal tension in the outer tissues of taraxacum officinale (Asteraceae) peduncles
    • Niklas KJ, Paolillo DJ Jr. 1998. Preferential states of longitudinal tension in the outer tissues of Taraxacum officinale (Asteraceae) peduncles. American Journal of Botany 85, 1068-1081.
    • (1998) American Journal of Botany , vol.85 , pp. 1068-1081
    • Niklas, K.J.1    Paolillo Jr., D.J.2
  • 25
    • 0342803827 scopus 로고    scopus 로고
    • Axis elongation can occur with net longitudinal orientation of wall microfibrils
    • Paolillo DJ Jr. 2000. Axis elongation can occur with net longitudinal orientation of wall microfibrils. New Phytologist 145, 449-455.
    • (2000) New Phytologist , vol.145 , pp. 449-455
    • Paolillo Jr., D.J.1
  • 26
    • 0037253414 scopus 로고    scopus 로고
    • Tissue stresses and resistance to water flow conspire to uncouple the water potential of the epidermis from that of the xylem in elongating plant stems
    • Passioura JB, Boyer JS 2003. Tissue stresses and resistance to water flow conspire to uncouple the water potential of the epidermis from that of the xylem in elongating plant stems. Functional Plant Biology 30, 325-334.
    • (2003) Functional Plant Biology , vol.30 , pp. 325-334
    • Passioura, J.B.1    Boyer, J.S.2
  • 27
    • 0009381434 scopus 로고
    • A difference between auxin-induced and hydrogen ion-induced growth
    • Perley JE, Penny D, Penny P. 1975. A difference between auxin-induced and hydrogen ion-induced growth. Plant Science Letters 4, 133-136.
    • (1975) Plant Science Letters , vol.4 , pp. 133-136
    • Perley, J.E.1    Penny, D.2    Penny, P.3
  • 28
  • 29
    • 0034045768 scopus 로고    scopus 로고
    • The mechanic state of 'inner tissue' in the growing zone of sunflower hypocotyls and the regulation of its growth rate following excision
    • Peters WS, Tomos AD 2000. The mechanic state of 'inner tissue' in the growing zone of sunflower hypocotyls and the regulation of its growth rate following excision. Plant Physiology 123, 605-612.
    • (2000) Plant Physiology , vol.123 , pp. 605-612
    • Peters, W.S.1    Tomos, A.D.2
  • 30
    • 0000207614 scopus 로고
    • Cell growth and the structure and mechanical properties of the wall in internodal cells of nitella opaca. I. Wall structure and growth
    • Probine MC, Preston RD 1961. Cell growth and the structure and mechanical properties of the wall in internodal cells of Nitella opaca. I. Wall structure and growth. Journal of Experimental Botany 12, 261-282.
    • (1961) Journal of Experimental Botany , vol.12 , pp. 261-282
    • Probine, M.C.1    Preston, R.D.2
  • 31
    • 0001211398 scopus 로고
    • Cell growth and the structure and mechanical properties of the wall in internodal cells of nitella opaca. II. Mechanical properties of the walls
    • Probine MC, Preston RD 1962. Cell growth and the structure and mechanical properties of the wall in internodal cells of Nitella opaca. II. Mechanical properties of the walls. Journal of Experimental Botany 13, 111-127.
    • (1962) Journal of Experimental Botany , vol.13 , pp. 111-127
    • Probine, M.C.1    Preston, R.D.2
  • 33
    • 0001969116 scopus 로고
    • Cell expansion patterns and directionality of wall mechanical properties in nitella
    • Richmond PA, Métraux JP, Taiz L. 1980. Cell expansion patterns and directionality of wall mechanical properties in Nitella. Plant Physiology 65, 211-217.
    • (1980) Plant Physiology , vol.65 , pp. 211-217
    • Richmond, P.A.1    Métraux, J.P.2    Taiz, L.3
  • 34
    • 80054699517 scopus 로고    scopus 로고
    • Chemically mediated mechanical expansion of the pollen tube cell wall
    • Rojas ER, Hotton S, Dumais J. 2011. Chemically mediated mechanical expansion of the pollen tube cell wall. Biophysical Journal 101, 1844-1853.
    • (2011) Biophysical Journal , vol.101 , pp. 1844-1853
    • Rojas, E.R.1    Hotton, S.2    Dumais, J.3
  • 36
    • 34250266990 scopus 로고
    • The kinetics of bidirectional growth of stem sections from etiolated pea seedlings in response to acid, auxin and fusicoccin
    • Taiz L, Métraux JP. 1979. The kinetics of bidirectional growth of stem sections from etiolated pea seedlings in response to acid, auxin and fusicoccin. Planta 146, 171-178.
    • (1979) Planta , vol.146 , pp. 171-178
    • Taiz, L.1    Métraux, J.P.2
  • 37
    • 0010026582 scopus 로고
    • Changes in microfibril arrangement on the inner surface of the epidermal cell walls in the epicotyl of vigna angularis ohwi et ohashi during cell growth
    • Takeda K, Shibaoka H. 1981. Changes in microfibril arrangement on the inner surface of the epidermal cell walls in the epicotyl of Vigna angularis Ohwi et Ohashi during cell growth. Planta 151, 385-392.
    • (1981) Planta , vol.151 , pp. 385-392
    • Takeda, K.1    Shibaoka, H.2
  • 39
    • 84859771647 scopus 로고    scopus 로고
    • Mechanical stress acts via katanin to amplify differences in growth rate between adjacent cells in arabidopsis
    • Uyttewaal M, Burian A, Alim K., et al 2012. Mechanical stress acts via katanin to amplify differences in growth rate between adjacent cells in Arabidopsis. Cell 149, 439-451.
    • (2012) Cell , vol.149 , pp. 439-451
    • Uyttewaal, M.1    Burian, A.2    Alim, K.3
  • 40
    • 69649101860 scopus 로고    scopus 로고
    • Tissue tension and axial growth of cylindrical structures in plants and elastic tissues
    • Vandiver R, Goriely A. 2008. Tissue tension and axial growth of cylindrical structures in plants and elastic tissues. Europhysics Letters 84, 58004.
    • (2008) Europhysics Letters , vol.84 , pp. 58004
    • Vandiver, R.1    Goriely, A.2
  • 41
    • 33645241838 scopus 로고    scopus 로고
    • Loss of stability, pH, and the anisotropic extensibility of chara cell walls
    • Wei C, Lintilhac LS, Lintilhac PM 2006. Loss of stability, pH, and the anisotropic extensibility of Chara cell walls. Planta 223, 1058-1067.
    • (2006) Planta , vol.223 , pp. 1058-1067
    • Wei, C.1    Lintilhac, L.S.2    Lintilhac, P.M.3
  • 42
    • 0000324261 scopus 로고
    • Alignment of cortical microtubules by anisotropic wall stresses
    • Williamson RE. 1990. Alignment of cortical microtubules by anisotropic wall stresses. Australian Journal of Plant Physiology 17, 601-613.
    • (1990) Australian Journal of Plant Physiology , vol.17 , pp. 601-613
    • Williamson, R.E.1
  • 43
    • 84868324514 scopus 로고    scopus 로고
    • Architecture-based multiscale computational modeling of plant cell wall mechanics to examine the hydrogen-bonding hypothesis of the cell wall network structure model
    • Yi H, Puri VM 2010. Architecture-based multiscale computational modeling of plant cell wall mechanics to examine the hydrogen-bonding hypothesis of the cell wall network structure model. Plant Physiology 160, 1281-1292.
    • (2010) Plant Physiology , vol.160 , pp. 1281-1292
    • Yi, H.1    Puri, V.M.2


* 이 정보는 Elsevier사의 SCOPUS DB에서 KISTI가 분석하여 추출한 것입니다.