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306 R. Stahlberg, R.E. Cleland, E. Van Volkenburgh Green TR, Ryan CA (1972) Wound-induced proteinase inhibitor in plant leaves: a possible defense mechanism against insects. Science 175:776–777 Gronewald JW, Hansen JB (1980) Sensitivity of proton and ion transport mechanisms of corn roots injury to injury. Plant Sci Lett 18:143–150 Haberlandt G (1890) Das reizleitende Gewebesystem der Sinnpflanze. Thieme, Leipzig Herde O, Fuss H, Pena-Cortes H, Fisahn J (1995) Proteinase inhibitor II gene expression inducedbyelectrical stimulation andcontrol ofphotosyntheticactivityintomatoplants. Plant Cell Physiol 36:737–742 Herde O, Atzorn R, Fisahn J, Wasternak C, Willmitzer L, Pena-Cortes H (1996) Localized wounding by heat initiates the accumulation of proteinase inhibitor II in abscisic acid deficient tomato plants by triggering jasmonic acid biosynthesis. Plant Physiol 112:853–860 Herde O, Fuss H, Pena-Cortes H, Willmitzer L, Fisahn J (1998) Remote stimulation by heat induces characteristic membrane-potential responses in the veins of wild-type and abscisic acid-deficient tomato plants. Planta 206:146–153 Houwinck AL (1935) The conduction of excitation in Mimosa pudica. Rec Trav Bot Neerl 32:51–91 Julien JL, Desbiez MO, de Jaeger G, Frachisse JM (1991) Characteristics of the wave of depolarization induced by wounding in Bidens pilosa L. J Exp Bot 42:131–137 Kinraide TB, Wyse RE (1986) Electrical evidence for turgor inhibition of proton extrusion in sugar beet taproots. Plant Physiol 82:1148–1150 Koopowitz H, Dhyse R, Fosket DE (1975) Cell membrane potentials of higher plants: changes induced by wounding. J Exp Bot 26:131–137 Koziolek C, Grams TE, Schreiber U, Matyssek R, Fromm J (2003) Transient knockout of photosynthesis mediated by electrical signals. New Phytol 161:715–722 Malone M (1992) Kinetics of wound-induced hydraulic signals and variation potentials in wheat seedlings. Planta 187:505–510 Malone M (1996) Rapid, long-distance signal transmission in higher plants. Adv Bot Res 22:163–228 Malone M, Stankovic B (1991) Surface potentials and hydraulic signals in wheat leaves following localized wounding by heat. Plant Cell Environ 14:431–436 Malone M, Palumbo L, Boari F, Monteleone M, Jones HG (1994) The relationship between wound-induced proteinase inhibitors and hydraulic signals in tomato seedlings. Plant Cell Environ 17:81–87 Mancuso S (1999) Hydraulic and electrical transmission of wound-induced signals in Vitis vinifera. Aust J Plant Physiol 26:55–61 Mertz SM, Higinbotham N (1976) Transmembrane electropotentials in barley roots as related to cell type, cell location, and cutting and aging effects. Plant Physiol 57:123-128 Okamoto H (1955) On the distribution of electric potential in the seedling of Vigna sesquipedalis and its change by light stimulation. Bot Mag (Tokyo) 68:1–15 Opritov VA (1978) Propagating excitation and assimilate transport in the phloem. Sov Plant Physiol 25:1042–1048 Opritov VA, Pyatygin SS, Vodeneev VA (2002) Direct coupling of action potential generation in cells of a higher plant (Cucurbita pepo) with the operation of an electrogenic pump. Russ J Plant Physiol. 49:142–147 Palmgren MG (1998) Proton gradients and plant growth: role of the plasma membrane H + -ATPase. Adv Bot Res 28:1–70 Pena-Cortes H, Fisahn J, Wilmitzer L (1995) Signals involved in wound-induced proteinase inhibitor II gene expression in tomato and potato plants. Proc Nat Acad Sci USA 92:4106– 4113 Pickard BG (1973) Action potentials in higher plants. Bot Rev 39:172–201
20 Slow Wave Potentials 307 Rhodes JD, Thain JF, Wildon DC (1996) The pathway for systemic electrical signal conduction in the wounded tomato plant. Planta 200:50–57 Ricca U (1916) Soluzione d’un problema di fisiologia: la propagazione di stimulo nella Mimosa. Nuovo G Bot Ital 23:51–170 Roblin G (1985) Analysis of the variation potential induced by wounding in plants. Plant Cell Physiol 26:455–461 Roblin G, Bonnemain J-L (1985) Propagation in Vicia faba stem of a potential variation by wounding. Plant Cell Physiol 26:1273–1283 Schildknecht H (1984) Turgorins – new chemical messengers for plant behavior. Endeav NS 8:113–117 Sibaoka T (1953) Some aspects of the slow conduction of stimuli in the leaf of Mimosa pudica. Sci Rep Tohoku Univ 20:72–88 Sibaoka T (1969) Physiology of rapid movements in higher plants. Annu Rev Plant Physiol 20:165–184 Sibaoka T (1991) Rapid plant movements triggered by action potentials. Bot Mag (Tokyo) 104:73–95 Sibaoka T (1997) Application of leaf extract causes repetitive action potentials in Biophytum sensitivum. J Plant Res 110:485–487 Shimmen T (2001) Electrical perception of “death message” in Chara:involvementofturgor pressure. Plant Cell Physiol 42:366–373 Sinyukhin AM, Britikov EA (1967) Action potentials in the reproductive system of plants. Nature 215:1278–1280 Spanjers AW (1981) Biolelectric potential changes in the style of Lilium longiflorum Thunb. after self- and cross-pollination of the stigma. Planta 153:1–5 Stahlberg R, Cosgrove DJ (1992) Rapid alteration in growth rate and electric potentials upon stem excision in pea seedlings. Planta 187:523–531 Stahlberg R, Cosgrove DJ (1994) Comparison of electric and growth responses to excision in in cucumber and pea seedlings. I. Short-distance effects are due to wounding. Plant Cell Environ 18:33–41 Stahlberg R, Cosgrove DJ (1995) Comparison of electric and growth responses to excision in cucumber and pea seedlings. II. Long-distance effects are due to hydraulic signals. Plant Cell Environ 18:33–41 Stahlberg R, Cosgrove DJ (1996) Induction and ionic basis of slow wave potentials in seedlings of Pisum sativum L. Planta 200:416–425 Stahlberg R, Cosgrove DJ (1997a) The propagation of slow wave potentials in pea epicotyls. Plant Physiol 113:209–217 Stahlberg R, Cosgrove DJ (1997b) Mannitol inhibits growth of intact cucumber but not pea seedlings by mechanically collapsing the root pressure. Plant Cell Environm 20:1135– 1144 Stahlberg R, Cosgrove DJ (1997c) Slow wave potentials in cucumber differ in form and growth effect from those in pea seedlings. Physiol Plant 101:379–388 Stahlberg R, Cleland RE, Van Volkenburgh E (2005a) Propagating electrical signals can be induced by environmental stimuli. Abstracts of the American Society of Plant Biologists Stahlberg R, Cleland RE, Van Volkenburgh E (2005b). Decrement and amplification of slow wave potentials during their propagation in Helianthus annuus L. shoots. Planta 220:550–558 Stankovic B, Davies E (1996) Both action potentials and variation potentials induce proteinase inhibitor gene expression in tomato. FEBS Lett 390:275–279 Stankovic B, Davies E (1998) The wound response in tomato involves rapid growth and electric responses, systemically up-regulated transcription of proteinase inhibitor and calmodulin and down-regulated translation. Plant Cell Physiol 39:268–274
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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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24 Electrophysiology and Phototropi
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370 E. Wagner et al. Table 25.1. Fl
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372 E. Wagner et al. Exudation [µl
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374 E. Wagner et al. metabolism at
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376 E. Wagner et al. The circadian
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378 E. Wagner et al. Fig.25.5. Time
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380 E. Wagner et al. Fig.25.7. Patt
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382 E. Wagner et al. Fig.25.9. Time
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384 E. Wagner et al. Fig.25.11. a K
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386 E. Wagner et al. 25.9 Conclusio
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388 E. Wagner et al. Lecharny A, Wa
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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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