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132 M.L. Lanteri et al. Fig.9.3. Schematic representation that integrates the signaling pathways and molecules involved in the indole acetic acid (IAA) – and the NO-induced adventitious root formation (ARF) in cucumber explants. The auxin IAA is synthesized in the shoot apical meristem of the seedling and is basipetally transported to the basal region of the hypocotyl. There, IAA triggers a local and transient generation of NO in a yet unknown manner (Pagnussat et al. 2002). Thereafter, an NO-mediated cyclic GMP (cGMP) dependentpathwaythat probably includes the modulation of cytosolic Ca 2+ concentration is operative to trigger ARF (Pagnussat et al. 2003; Lanteri et al., submitted). In parallel, a cGMP-independent pathway that involves the activation of a mitogen-activated protein kinase signaling cascade is required for ARF (Pagnussat et al. 2004). Both pathways could mediate downstream responses including the induction of cell division and differentiation resulting in ARF. NPA 1-naphthylphthalamic acid, GC guanylate cyclase, PDE phosphodiesterase, ⊥ inhibition Overall, the available data suggest a picture in which basipetal transport of auxins induces an NO burst in the basal region of the hypocotyl, where the adventitious root primordia develop. Then, NO triggers a bifurcated signaling cascade that includes both cGMP-dependent and -independent pathways. The activation of both pathways seems to be required for ARF
9 Nitric Oxide and Auxin in Root Development 133 in cucumber explants since the effect of both auxins and NO is abolished when one of them is compromised (Fig. 9.3). 9.4 Conclusions and Future Perspectives We are clearly taking the first steps in order to describe at what different levels NO modulates root morphology and physiology. Nevertheless, the major challenge will be the integration of the myriad of signals involved in root development and the linkage between them and the different enzymatic and nonenzymatic NO sources in roots. Considerable effort and imagination will be necessary to design innovative approaches and experimental models which should include different factors affecting the signals associated with root growth. The availability of water, oxygen and nutrients, the interaction with soil microorganisms (pathogens and nonpathogens), the production and modification of plant growth-promoting compounds by those organisms together with the geneticbackgroundofeachplantspeciesshouldbeconsideredandintegrated in the near future. The application of genetic tools and the analysis of root growth behavior under different soil conditions will surely contribute to deciphering the participation of root systems in plant productivity. In turn, NO which has been postulated as a key player in many of the known auxinmediated processes associated with root development, should be considered as a mammalian-like neurotransmitter when describing its behavior in future discussions. The basic knowledge discussed in this review will clearly have a tremendous impact owing to its potential application for improving programs of rooting that are actually being used in nurseries. Undoubtedly, NO actions should be taken into account when studying the specific requirements of each plant species that determines its root growth pattern. Acknowledgements. This work was supported by ANPCyT, CONICET, Fundación Antorchas and UNMdP, Argentina. <strong>References</strong> Baluška F, Šamaj J, Menzel D (2003) Polar transport of auxin: carrier-mediated flux across the plasma membrane or neurotransmitter-like secretion? Trends Cell Biol 13: 282–285 Baluška F, Mancuso S, Volkmann D, Barlow P (2004) Root apices as plant command centres: the unique ‘brain-like’ status of the root apex transition zone. Biologia 59:7–19
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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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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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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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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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278 K.Trebacz,H.Dziubinska,E.Krol W
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280 K.Trebacz,H.Dziubinska,E.Krol T
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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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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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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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