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120 M.D. Stefano, A. Ferrarini, M. Delledonne Hancock JT, Desikan R, Clarke A, Hurst RD, Neill SJ (2002) Cell signalling following plant/pathogen interactions involves the generation of reactive oxygen and reactive nitrogen species. Plant Physiol. Biochem. 40:611–617 Holub EB (2001) The arms race is ancient history in Arabidopsis, thewildflower.NatRev Genet 2:516–527 Koppenol WH, Moreno JJ, Pryor WA, Ischiropoulos H, Beckman JS (1992) Peroxynitrite, a cloaked oxidant formed by nitric oxide and superoxide. Chem Res Toxicol 5: 834–842 Lamotte O, Gould K, Lecourieux D, Sequeira-Legrand A, Lebrun-Garcia A, Durner J, Pugin A, Wandehenne D (2004) Analysis of nitric oxide signaling functions in tobacco cells challenged by the elicitor cryptogein. Plant Physiol 235:516–529 Lin KT, Xue JY, Nomen M, Spur B, Wong PY (1995) Peroxynitrite induced apoptosis in HL-60 cells. J Biol Chem 270:16487–16490 Mauch-Mani B, Métraux JP (1998) Salicylic acid and systemic acquired resistance to pathogen attack. Ann Bot 82:535–540 McDowell JM, Dangl JL (2000) Signal transduction in the plant immune response. Trends Biochem Sci 25:79–82 McDowell JM, Woffenden BJ (2003) Plant disease resistance genes: recent insights and potential applications. Trends Biotechnol 21:178–183 Murgia I, de Pinto MC, Delledonne M, Soave C, De Gara L (2004) Comparative effects of variuos nitric oxide donors on ferritin regulation, programmed cell death, and cell redox state in plant cells J Plant Physiol 161:777–783 Neill SJ, Desikan R, HancockJT (2003) Nitricoxide signalling in plants. New Phytol 159:11–35 Perazzolli M, Dominici P, Romero-Puertas M, Zago E, Zeier J, Sonoda M, Lamb C, Delledonne M (2004) Arabidopsis non-symbiotic hemoglobin AHb1 modulates nitric oxide bioactivity. Plant Cell 16:2785–2794 Rockel P, Strube F, Rockel A, Wildt J, Kaiser WM (2002) Regulation of nitric oxide (NO) production by plant nitrate reductase in vivo and in vitro. J Exp Bot 53:103–110 Romero-Puertas MC, Perazzolli M, Zago ED, Delledonne M (2004) Nitric oxide signalling functions in plant–pathogen interactions. Cell Microbiol 6:795–803 Ryals JA, Neuenschwander UH, Willits MG, Molina A, Steiner HY, Hunt MD (1996) Systemic acquired resistance. Plant Cell 8:1809–1819 Seregelyes C, Barna B, Hennig J, Konopka D, Pasternak TP, Lukacs N, Feher A, Horvath GV, Dudits D (2003) Phytoglobins can interfere with nitric oxide functions during plant growth and pathogenic response: a transgenic approach. Plant Sci 165:541–550 Shirasu K, Nakajima H, Rajasekhar VK, Dixon RA, Lambas C (1997) Salicylic acid potentiates an agonist-dependent gain control that amplifies pathogen signals in the activation of defense mechanisms. Plant Cell 9:261–270 Sokolovski S, Blatt MR (2004) Nitric oxide block outward-rectifying K + channels indicates direct control by protein nitrosylation in guard cells. Plant Physiol 136:4275–4284 Stamler JS, Lamas S, Fang FC (2001) Nitrosylation: the prototypic redox-based signaling mechanism. Cell 106:675–683 Song, F, Goodman RM (2001) Activity of nitric oxide is dependent on, but is partially required for function of, salicylic acid in the signaling pathway in tobacco systemic acquired resistance. Mol Plant Microbe Interact 14:1458–1462 Tada Y, Mori T, Shinogi T, Yao N, Takahashi S, Betsuyaku S (2004) Nitric oxide and reactive oxygen species do not elicit hypersensitive cell death but induce apoptosis in the adjacent cells during the defense response of oat. Mol Plant Microbe Interact 17:245–253 Wendehenne D, Lamotte O, Frachisse JM, Barbier-Brygoo H, Pugin A (2002) Nitrate efflux is an essential component of the cryptogein signaling pathway leading to defense responses and hypersensitive cell death in tobacco. Plant Cell 14:1937–1951
8 Nitric Oxide Involvement in Incompatible Plant–Pathogen Interactions 121 Yamamoto A, Katou S, Yoshioka H, Doke N, Kawakita K (2004) Involvement of nitric oxide generation in hypersensitive cell death induced by elicitin in tobacco cell suspension culture. J Gen Plant Pathol 70:85–92 Yamasaki H, Sakihama Y (2000) Simultaneous production of nitric oxide and peroxynitrite by plant nitrate reductase: in vitro evidence for the NR-dependent formation of active nitrogen species. FEBS Lett 468:89–92 Zhang C, Czymmek KJ, Shapiro AD (2003) Nitric oxide does not trigger early programmed cell death events but may contribute to cell-to-cell signaling governing progression of the Arabidopsis hypersensitive response. Mol Plant Microbe Interact 16:962–972 Zeidler D, Zähringer U, Gerber I, Dubery I, Hartung T, Bors W, Hutzler P, Durner J (2004) Innate immunity in Arabidopsis thaliana: lipopolysaccharides activate nitric oxide synthase (NOS) and induce defense genes. Proc Natl Acad Sci USA 101:1581115816 Zeier J, Delledonne M, Severi E, Sonoda M, Lamb C (2004) Genetic elucidation of nitric oxide signaling in incompatible plant-pathogen interactions. Plant Physiol 136:2875–2886
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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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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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310 E.Davies,B.Stankovic It is assu
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312 E.Davies,B.Stankovic 21.2 Evide
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314 E.Davies,B.Stankovic Fig.21.3.
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316 E.Davies,B.Stankovic Relative m
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318 E.Davies,B.Stankovic 1992; Beel
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320 E.Davies,B.Stankovic Hentze MW,
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322 J. Fromm, S. Lautner in the ran
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324 J. Fromm, S. Lautner cells (Sam
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326 J. Fromm, S. Lautner 22.5 Ion C
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328 J. Fromm, S. Lautner hastobedon
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330 J. Fromm, S. Lautner Beilby MJ,
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332 J. Fromm, S. Lautner Williams S
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334 S. Mancuso, S. Mugnai like the
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336 S. Mancuso, S. Mugnai 2,000 nM
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338 S. Mancuso, S. Mugnai the fourt
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340 S. Mancuso, S. Mugnai “slow-w
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342 S. Mancuso, S. Mugnai 23.6 Airb
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344 S. Mancuso, S. Mugnai that tree
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346 S. Mancuso, S. Mugnai Fort C, F
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348 S. Mancuso, S. Mugnai Pophof B,
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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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