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346 S. Mancuso, S. Mugnai Fort C, Fauveau ML, Muller F, Label P, Granier A, Dreyer E (1997) Stomatal conductance, growth and root signalling in young oak seedlings subjected to partial soil drying. Tree Physiol 17:281–289 Fort C, Muller F, Label P, Granier A, Dreyer E (1998) Stomatal conductance, growth and root signalling in Betula pendula seedlings subjected to partial soil drying. Tree Physiol 18:769–776 Fromm J (1991) Control of phloem unloading by action potentials in Mimosa.PhysiolPlant 83:529–533 Fromm J, Eschrich W (1988a) Transport processes in stimulated and non-stimulated leaves of Mimosa pudica. Trees 2:18–24 Fromm J, Eschrich W (1988b) Transport processes in stimulated and non-stimulated leaves of Mimosa pudica.I:Themovementof 14 C-labelled photoassimilates. Trees 2:2–17 Fromm J, Eschrich W (1993) Electric signals released from roots of willow (Salix viminalis L.) change transpiration and photosynthesis. J Plant Physiol 141:673–680 Fromm J, Spanswick R (1993) Characteristics of action potentials in willow (Salix viminalis L.). J Exp Bot 44:1119–1125 Fromm J, Meyer AJ, Weisenseel MH (1997) Growth, membrane potential and endogenous ion currents of willow (Salix viminalis L.) roots are all affected by abscisic acid and spermine. Physiol Plant 99:529–537 Gershenzon J (1994) Metabolic costs of terpenoid accumulation in higher plants. J Chem Ecol 20:1281–1328 Goodwin TW, Mercer EI (1983) Introduction to plant biochemistry, 2nd edn. Pergamon, New York Gowing DJG, Jones HG, Davies WJ (1993) Xylem-transported abscisic acid: the relative importance of its mass and its concentration in the control of stomatal aperture. Plant Cell Environ 16:453–459 Hagen SB, Folstad I, Jakobsen SW (2003) Autumn colouration and herbivore resistance in mountain birch (Betula pubescens). Ecol Lett 6:807–811 Hamilton WD, Brown SP (2001) Autumn tree colours as a handicap signal. Proc R Soc Lond 268:1489–1493 Houwink AL (1935) The conduction of excitation in Mimosa pudica L. Rec Tav Bot Neerl 32:51–91 Jackson GE, Irvine J, Grace J, Khalil AM (1995) Abscisic acid concentrations and fluxes in droughted conifer saplings. Plant Cell Environ 18:13–22 Jia W, Zhang J (1997) Comparison of exportation and metabolism of xylem-delivered ABA in maize leaves at different water status and xylem sap pH. Plant Growth Regul 21:43–49 Jones CG, Hopper RF, Coleman JS, Krischik VA (1993) Control of systematically induced herbivore resistance by plant vascular architecture. Oecologia 93:452–456 Kessler A, Baldwin IT (2001) Defensive function of herbivore-induced plant volatile emissions in nature. Science 291:2141–2144 Khalil AAM, Grace J (1993) Does xylem sap ABA control the stomatal behaviour of waterstressed sycamore (Acer pseudoplatanus L.) seedlings. J Exp Bot 44:1127–1134 Knudsen JT, Tollsten L, Bergstrom LG (1993) Floral scents, a checklist of volatile compounds isolated by head-space techniques. Phytochemistry 33:253–280 Köstner B, Biron P, Siegwolf R, Granier A (1996) Estimates of water vapour flux and canopy conductance of Scots pine at the tree level utilizing different xylem sap flow methods. Theor App Clim 53:105–113 Koziolek C, Grams TEE, Schreiber U, Matyssek R, Fromm J (2004) Transient knockout of photosynthesis mediated by electrical signals. New Phytol 161:715–722
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František Baluška · Stefano Manc
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Dr. František Baluška University
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VI Preface turn, reward the ants by
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VIII Preface of olfactory response.
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Contents 1 The Green Plant as an In
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Contents XIII 6 Signals and Targets
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Contents XV 11 Amino Acid Transport
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Contents XVII 15 Regulation of Plan
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Contents XIX 21.3 Conclusions and P
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Contents XXI 27.3.2 Catechin Induce
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XXIV Contributors Correa-Aragunde,
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XXVI Contributors Lamattina, L. (e-
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XXVIII Contributors Song, C. Depart
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1 The Green Plant as an Intelligent
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2 Neurobiological View of Plants an
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38 P.W. Barlow Thestimulipresentedt
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40 P.W. Barlow that a tropism is su
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42 P.W. Barlow the auxin flow into
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44 P.W. Barlow afferentnervousimpul
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46 P.W. Barlow analysis. In particu
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48 P.W. Barlow reception of his boo
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50 P.W. Barlow Iijima M, Kono Y (19
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4 How Can Plants Choose the Most Pr
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66 P.M. Neumann Finally, I examined
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68 P.M. Neumann evolutionary progre
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70 P.M. Neumann conclusion is that
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72 P.M. Neumann resources from matu
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6 Signals and Targets Triggered by
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6TargetsofSI 77 6.1.2 Self-Incompat
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6TargetsofSI 79 by Yang 2002) has p
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6TargetsofSI 81 al. 2002). Thus, SI
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6TargetsofSI 83 Fig.6.2. PrABP80 ha
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6TargetsofSI 85 many of the genes e
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6TargetsofSI 87 [Ca 2+ ]i may signa
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6TargetsofSI 89 is crosstalk betwee
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6TargetsofSI 91 Hepler PK, Vidali L
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6TargetsofSI 93 Snowman BN, Kovar D
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96 T. Nürnberger, B. Kemmerling Wh
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98 T. Nürnberger, B. Kemmerling Fo
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100 T. Nürnberger, B. Kemmerling p
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102 T. Nürnberger, B. Kemmerling i
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104 T. Nürnberger, B. Kemmerling r
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106 T. Nürnberger, B. Kemmerling F
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108 T. Nürnberger, B. Kemmerling M
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8 Nitric Oxide Involvement in Incom
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124 M.L. Lanteri et al. 9.1.1 Auxin
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126 M.L. Lanteri et al. Fig.9.1. Sc
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128 M.L. Lanteri et al. Fig.9.2. NO
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130 M.L. Lanteri et al. 9.3.1 Nitri
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132 M.L. Lanteri et al. Fig.9.3. Sc
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134 M.L. Lanteri et al. Bellamine J
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136 M.L. Lanteri et al. Pagnussat G
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138 S.J. Murch H 3C CH3 CH3 N H 2C
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140 S.J. Murch edible plants (Manch
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142 S.J. Murch However, over the la
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144 S.J. Murch of monoamine, amino
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146 S.J. Murch On Guam and in other
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148 S.J. Murch 10.4 Conclusions and
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150 S.J. Murch Lindstrom H, Luthman
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11 Amino Acid Transport in Plants a
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11 AA transport in plant versus neu
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12 GABA and GHB Neurotransmitters i
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188 M. Gilliham et al. Fig.13.1. Ar
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190 M. Gilliham et al. as compatibl
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192 M. Gilliham et al. apex (Zhang
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194 M. Gilliham et al. 13.3.3 Are A
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196 M. Gilliham et al. sufficiently
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198 M. Gilliham et al. 2005). It is
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200 M. Gilliham et al. 13.4.5 NSCC
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202 M. Gilliham et al. Kang J, Meht
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204 M. Gilliham et al. Zheng Y, Mel
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206 E.B. Blancaflor, K.D. Chapman F
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208 E.B. Blancaflor, K.D. Chapman N
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210 E.B. Blancaflor, K.D. Chapman v
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212 E.B. Blancaflor, K.D. Chapman l
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214 E.B. Blancaflor, K.D. Chapman N
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216 E.B. Blancaflor, K.D. Chapman 1
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218 E.B. Blancaflor, K.D. Chapman G
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15 Regulation of Plant Growth and D
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16 Physiological Roles of Nonselect
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16 Nonselective cation channels 237
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Fig.16.1. Possible roles of nonsele
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17 Touch-Responsive Behaviors and G
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18 Oscillations in Plants Sergey Sh
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18 Oscillations in Plants 263 Tempo
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18 Oscillations in Plants 265 Dries
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18 Oscillations in Plants 267 backg
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18 Oscillations in Plants 269 The f
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18 Oscillations in Plants 271 prehe
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18 Oscillations in Plants 273 Cardo
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18 Oscillations in Plants 275 Shaba
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278 K.Trebacz,H.Dziubinska,E.Krol W
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280 K.Trebacz,H.Dziubinska,E.Krol T
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282 K.Trebacz,H.Dziubinska,E.Krol E
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284 K.Trebacz,H.Dziubinska,E.Krol 1
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286 K.Trebacz,H.Dziubinska,E.Krol n
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288 K.Trebacz,H.Dziubinska,E.Krol D
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290 K.Trebacz,H.Dziubinska,E.Krol S
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292 R. Stahlberg, R.E. Cleland, E.
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294 R. Stahlberg, R.E. Cleland, E.
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26 Signals and Signalling Pathways
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404 L.G. Perry et al. properties (S
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406 L.G. Perry et al. Fig.27.1. A s
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408 L.G. Perry et al. phytotoxins i
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410 L.G. Perry et al. monooxygenase
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412 L.G. Perry et al. 27.4 (±)-Cat
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414 L.G. Perry et al. (±)-catechin
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416 L.G. Perry et al. mineralizatio
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418 L.G. Perry et al. Dyer AR (2004
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420 L.G. Perry et al. Singh HP, Bat
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422 V.Ninkovic,R.Glinwood,J.Petters
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436 Subject Index defense 67, 95-10
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438 Subject Index sieve-tube-elemen
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