Advertisement

Aktive Bewegungen von Zellen, Organen und Organellen

  • Peter SchopferEmail author
  • Axel Brennicke
Chapter

Zusammenfassung

In diesem Kapitel betrachten wir die aktiven Bewegungsvorgänge bei Pflanzen.Die zunächst verwirrend vielfältige Phänomenologie der Bewegungen lässt sich auf wenige Grundprinzipien zurückführen.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

Weiterführende Literatur

a. Freie Ortsbewegung begeißelter Zellen

  1. Adler J (1988) Chemotaxis: Old and new. Bot Acta 101: 93–100Google Scholar
  2. Borkovich KA, Simon MI (1990) The dynamics of protein phosphorylation in bacterial chemotaxis. Cell 63: 1339–1348Google Scholar
  3. Cosson J, Huitorel P, Barsanti L, Walne PL, Gualtieri P (2001) Flagellar movements and controlling apparatus in flagellates. Crit Rev Plant Sci 20: 297–308Google Scholar
  4. Kreimer G (1994) Cell biology of phototaxis in flagellate algae. Int Rev Cytol 148: 229–310Google Scholar
  5. Silflow CD, Lefebvre PA (2001) Assembly and motility of eucaryotic cilia and flagella. Lessons from Chlamydomonas reinhardtii. Plant Physiol 127: 1500–1507Google Scholar

b. Tropismen

  1. Bergman K, Burke PV, Cerdá-Olmedo E et al. (1969) Phycomyces. Bacteriol Rev 33: 99–157Google Scholar
  2. Blancaflor EB, Masson PH (2003) Plant gravitropism. Unraveling the ups and downs of a complex process. Plant Physiol 133: 1677–1690Google Scholar
  3. Briggs WR, Christie JM, Swartz TE (2005) Phototropins. In: Schaefer E, Nagy F (eds) Photomorphogenesis in plants and bacteria: Function and signal transduction mechanisms. Springer, Dordrecht, pp 225–254Google Scholar
  4. Chen R, Rosen E, Masson PH (1999) Gravitropism in higher plants. Plant Physiol 120: 343–350Google Scholar
  5. Christie JM (2007) Phototropin blue light receptors. Annu Rev Plant Biol 58: 21–45Google Scholar
  6. Eapen D, Barroso ML, Ponce G, Campos ME, Cassab I (2005) Hydrotropism: Root growth responses to water. Trends Plant Sci 10: 44–50Google Scholar
  7. Hart JW (1990) Plant tropisms and other plant movements. Unwin Hyman, LondonGoogle Scholar
  8. Iino M (2001) Phototropism in higher plants. In. Häder D-P, Lebert M (eds) Photomovement. Elsevier, Amsterdam, pp 659–811Google Scholar
  9. Kawai H,Kanegae T, Christensen S,Kiyosue T, Sato Y, Imaizumi T, Kadota A,Wada M (2003) Responses of ferns to red light mediated by an unconventional photoreceptor. Nature 421: 287–290Google Scholar
  10. Kiss JZ (2002) Mechanisms of the early phases of plant gravitropism. Crit Rev Plant Sci 19: 551–573Google Scholar
  11. Konings H (1995) Gravitropism of roots: An evaluation of progress during the last three decades. Acta Bot Neerl 44: 195–223Google Scholar
  12. Palme K, Dovzhenko A, Ditengon FA (2006) Auxin transport and gravitational research: Perspectives. Protoplasma 229: 175–181Google Scholar
  13. Parker KE (1991) Auxin metabolism and transport during gravitropism. Physiol Plant 82: 477–482Google Scholar
  14. Sack FO (1991) Plant gravity sensing. Int Rev Cytol 127: 193–252Google Scholar
  15. Sievers A, Buchen B, Hodick D (1996) Gravity sensing in tipgrowing cells. Trends Plant Sci 1: 273–279Google Scholar

c. Weitere Bewegungsvorgänge

  1. Braam J (2005) In touch: Plant responses to mechanical stimuli. New Phytol 165: 373–389Google Scholar
  2. Bünning E (1953) Entwicklungs- und Bewegungsphysiologie der Pflanze. Springer, BerlinGoogle Scholar
  3. Coté GG (1995) Signal transduction in leaf movement. Plant Physiol. 109: 729–734Google Scholar
  4. Darwin C (1880) The power of movements in plants. Murray, LondonGoogle Scholar
  5. Fleurat-Lessard P (1988) Structural and ultrastructural features of cortical cells in motor organs of sensitive plants. Biol Rev 63: 1–22Google Scholar
  6. Fromm J, Lautner S (2007) Electrical signals and their physiological significance in plants. Plant Cell Environ 30: 249–257Google Scholar
  7. Jaffe MJ, Leopold AC, Staples R (2002) Thigmo responses in plants and fungi. Amer J Bot 89: 375–382Google Scholar
  8. Kagawa T, Wada M (2002) Blue light-induced chloroplast relocation. Plant Cell Physiol 43: 367–371Google Scholar
  9. Koller D (1990) Light-driven leaf movements. Plant Cell Environ 13: 615–632Google Scholar
  10. Raschke K (1979) Movements of stomata. In: Haupt W, Feinleib ME (eds) Physiology of movements. Springer, Berlin (Encycl Plant Physiol NS,Vol VII), pp 383–441Google Scholar
  11. Uehlein N, Kaldenhoff (2008) Aquaporins and plant movements. Ann Bot 101: 1–4Google Scholar
  12. Wada M, Kagawa T, Sato Y (2003) Chloroplast movement. Annu Rev Plant Biol 54: 455–468Google Scholar
  13. Werker E, Shak T, Koller D (1991) Photobiological and structural studies of light-driven movements in the solar-tracking leaf of Lupinus palaestinus Bioss. (Fabaceae). Bot Acta 104: 144–156Google Scholar

d. Sammelwerke

  1. Haberlandt G (1909) Physiologische Pflanzenanatomie. Engelmann, LeipzigGoogle Scholar
  2. Häder D-P, Lebert M (eds) (2001) Photomovement. Elsevier, AmsterdamGoogle Scholar
  3. Haupt W, Feinleib ME (eds) (1979) Physiology of movements. Springer, Berlin (Encycl Plant Physiol NS,Vol VII)Google Scholar
  4. Hensel W (1983) Pflanzen in Aktion. Spektrum, HeidelbergGoogle Scholar
  5. Koller D (2000) Plants in search of sunlight. Adv Bot Res 33: 35–131Google Scholar

In Abbildungen und Tabellen zitierte Literatur

  1. Boysen-Jensen P (1939) Die Elemente der Pflanzenphysiologie. Fischer, JenaGoogle Scholar
  2. Brauner L, Hager A (1958) Planta 51: 115–147Google Scholar
  3. Briggs WR, Baskin TI (1988) Bot Acta 101: 133–139Google Scholar
  4. Briggs WR, Tocher RD,Wilson JF (1957) Science 126: 210–212Google Scholar
  5. Diehn B (1973) Science 181: 1009–1015Google Scholar
  6. Engelberth J, Wanner G, Groth B, Weiler E (1995) Planta 196: 539–550Google Scholar
  7. Eschrich W (1989) Stofftransport in Bäumen. Sauerländer, Frankfurt a.M.Google Scholar
  8. Etzold H (1965) Planta 64: 254–280Google Scholar
  9. Fondeville JC, Borthwick HA, Hendricks SB (1966) Planta 69: 357–364Google Scholar
  10. Gillespie B, Thimann KV (1963) Plant Physiol 38: 214–225Google Scholar
  11. Grolig F,Wagner G (1988) Bot Acta 101: 2–6Google Scholar
  12. Haupt W (1965) Naturwiss Rdsch 18: 261–267Google Scholar
  13. Haupt W (1970) Physiol vég 8: 551–563Google Scholar
  14. Haupt W, Scheuerlein R (1990) Plant Cell Environ 13: 595–614Google Scholar
  15. Iino M (1991) Plant Cell Environ 14: 279–286Google Scholar
  16. Iino M (1995) Plant Cell Environ 36: 361–367Google Scholar
  17. Iino M (2001) In: Häder D-P, Lebert M (eds) Photomovement. Elsevier, Amsterdam, pp 659–811Google Scholar
  18. Iino M, Briggs WR (1984) Plant Cell Environ 7: 97–104Google Scholar
  19. Ingold CT (1963) Dispersal of fungi. Clarendon, OxfordGoogle Scholar
  20. Juniper BE, Groves S, Landau-Schachar B,Andus LJ (1966) Nature 209: 93–94Google Scholar
  21. Kleinig H, Sitte P (1999) Zellbiologie. 4. Aufl. Fischer, StuttgartGoogle Scholar
  22. Li Y,Wu YH,Hagen G,Guilfoyle T (1999) Plant Cell Physiol 40: 675–682Google Scholar
  23. Macdonald IR, Hart JW (1987) Plant Physiol 84: 568–570Google Scholar
  24. Manton I (1963) J Roy Microscop Soc 82: 279–285Google Scholar
  25. Mohr H (1956) Planta 47: 127–158Google Scholar
  26. Oltmanns F (1922) Morphologie und Biologie der Algen. Fischer, JenaGoogle Scholar
  27. Page RM (1962) Science 138: 1238–1245Google Scholar
  28. Schumacher W (1958) In: Lehrbuch für Botanik. (Strasburger et al.), 27. Aufl. Fischer, StuttgartGoogle Scholar
  29. Shropshire W (1974) In: Schenk GO (ed) Progress in Photobiology. Dt Ges Lichtforsch, Frankfurt a.M. (paper No 024)Google Scholar
  30. Sievers A (1984) Rheinisch-Westfälische Akademie der Wissensch, Vorträge. N 335,Westdeutscher Verlag, OpladenGoogle Scholar
  31. Sievers A, Schröter K (1971) Planta 96: 339–353Google Scholar
  32. Sievers A,Volkmann D (1972) Planta 102: 160–172Google Scholar
  33. Steiner AM (1967) Naturwiss 54: 497–498Google Scholar
  34. Takahashi N, Goto N, Okada K, Takahashi H (2002) Planta 216: 203–211Google Scholar
  35. Takano M, Takahashi H, Hirsawa T, Suge H (1995) Planta 197: 410–413Google Scholar
  36. Taylor EW (1989) Nature 340: 354–355Google Scholar
  37. Volkmann D, Buchen B, Hejnowicz Z, Tewinkel M, Sievers A (1991) Planta 185: 153–161Google Scholar
  38. Volkmann D, Sievers A (1979) In: Encycl Plant Physiol NS, Vol VII. Springer, Berlin, pp 573–600Google Scholar
  39. Woitzik F,Mohr H (1988) Plant Cell Environ 11: 653–661Google Scholar
  40. Zurzycki J (1962) Acta Soc Bot Polon 31: 489–538Google Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2010

Authors and Affiliations

  1. 1.Institut für BiologieUniverstität FreiburgFreiburgDeutschland
  2. 2.Molekulare BotanikUniversität UlmUlmDeutschland

Personalised recommendations