Photosynthesis-dependent formation of convoluted plasma membrane domains in Chara internodal cells is independent of chloroplast position

Protoplasma

Volumn 252, Issue 4, 2015, Pages 1085-1096

  Foissner, Ilse ^a   Sommer, Aniela ^a   Hoeftberger, Margit ^a  

^a UNIVERSITY OF SALZBURG   (Austria)

Author keywords

Chara australis; Charasome; Nodal cell; PH banding; Plant; Wound

Indexed keywords

CELL MEMBRANE; CHARA; CHLOROPLAST; METABOLISM; PHOTOSYNTHESIS; PHYSIOLOGY;

CELL MEMBRANE; CHARA; CHLOROPLASTS; PHOTOSYNTHESIS;

EID: 84943450515     PISSN: 0033183X     EISSN: None     Source Type: Journal    
DOI: 10.1007/s00709-014-0742-9     Document Type: Article

References (52)

1. Beilby M, Bisson M (2012) pH banding in charophyte algae. In: Volkov AG (ed) Plant Electrophysiology. Springer Berlin Heidelberg, pp 247–271
2. Beilby MJ, Casanova MT (2014) The physiology of characean cells. Springer, Berlin
3. Bisson MA, Siegel A, Chau R, Gelsomino SA, Herdic SL (1991) Distribution of charasomes in Chara-banding pattern and effect of photosynthetic inhibitors. Aust J Plant Physiol 18:81–93
4. Boutte Y, Moreau P (2014) Plasma membrane partitioning: from macrodomains to new views on plasmodesmata. Front Plant Sci 5: 128–128
5. Braun M (2002) Gravity perception requires statoliths settled on specific plasma membrane areas in characean rhizoids and protonemata. Protoplasma 219:150–159
6. Braun M, Limbach C (2006) Rhizoids and protonemata of characean algae: model cells for research on polarized growth and plant gravity sensing. Protoplasma 229:133–142
7. Brecknock S, Dibbayawan TP, Vesk M, Vesk PA, Faulkner C, Barton DA, Overall RL (2011) High resolution scanning electron microscopy of plasmodesmata. Planta 234:749–758
8. Bulychev AA, Komarova AV (2014a) Long-distance signal transmission and regulation of photosynthesis in characean cells. Biochemistry (Mosc) 79(3):273–281
9. Bulychev AA, Komarova AV (2014b) Proton flows across the plasma membrane in microperforated characean internodes: tonoplast injury and involvement of cytoplasmic streaming. Protoplasma 251:1481-1490.
10. Bulychev AA, Zykov SV, Rubin AB, Muller SC (2003) Transitions from alkaline spots to regular bands during pH pattern formation at the plasmalemma of Chara cells. Eur Biophys J 32:144–153
11. Chau R, Bisson MA, Siegel A, Elkin G, Klim P, Straubinger RM (1994) Distribution of charasomes in Chara—reestablishment and loss in darkness and correlation with banding and inorganic carbon uptake. Aust J Plant Physiol 21:113–123
12. Cook ME, Graham LE, Botha CEJ, Lavin CA (1997) Comparative ultrastructure of plasmodesmata of Chara and selected bryophytes: toward an elucidation of the evolutionary origin of plant plasmodesmata. Am J Bot 84:1169–1178
13. Elzenga JTM, Prins HBA (1989a) Light-induced polar pH changes in leaves of Elodea canadensis I. Effects of carbon concentration and light intensity. Plant Physiol 91:62–67
14. Elzenga JTM, Prins HBA (1989b) Light-induced polar pH changes in leaves of Elodea canadensis II. Effects of ferricyanide: evidence for modulation by the redox state of the cytoplasm. Plant Physiol 91: 68–72
15. Eremin A, Bulychev A, Hauser MJ (2013) Cyclosis-mediated transfer of H2O2 elicited by localized illumination of Chara cells and its relevance to the formation of pH bands. Protoplasma 250:1339–1349
16. Faulkner CR, Blackman LM, Cordwell SJ, Overall RL (2005) Proteomic identification of putative plasmodesmatal proteins from Chara corallina. Proteomics 5:2866–2875
17. Foissner I (1988) The relationship of echinate inclusions and coated vesicles on wound-healing in Nitella flexilis (Characeae). Protoplasma 142:164–175
18. Foissner I (1991) Induction of exocytosis in characean internodal cells by locally restricted application of chlortetracycline and the effect of cytochalasin B, depolarizing and hyperpolarizing agents. Plant Cell Environ 14:907–915
19. Foissner I (2004) Microfilaments and microtubules control the shape, motility, and subcellular distribution of cortical mitochondria in characean internodal cells. Protoplasma 224:145–157
20. Foissner I, Wasteneys GO (2012) The characean internodal cell as a model system for studying wound healing. J Microsc 247:10–22
21. Foissner I, Wasteneys GO (2014) Characean internodal cells as a model system for the study of cell organization. In: KwangWJ (ed) Int Rev Cell Mol Biol, vol 311. Academic Press, pp 307–364
22. Forsberg C (1965) Axenic culture of Chara globularis Thuill. and Chara zeylanica. Life Sci 4:225–226
23. Franceschi VR, Lucas WJ (1980) Structure and possible function(s) of charasomes; complex plasmalemma-cell wall elaborations present in some characean species. Protoplasma 104:253–271
24. Franceschi VR, Lucas WJ (1981) The charasome periplasmic space. Protoplasma 107:269–284
25. Hodick D (1993) The protonema of Chara fragilis desv.: regenerative formation, photomorphogenesis, and gravitropism. Bot Acta 106:388–393
26. Jarsch IK, Konrad SSA, Stratil TF, Urbanus SL, Szymanski W, Braun P, Braun K-H, Ott T (2014) Plasmamembranes are subcompartmentalized into a plethora of coexisting and diverse microdomains in Arabidopsis and Nicotiana benthamiana. Plant Cell 26:1698–1711
27. Kamitsubo E (1972) A “window technique” for detailed observation of characean cytoplasmic streaming. Exp Cell Res 74:613–616
28. Klima A, Foissner I (2008) FM dyes label sterol-rich plasma membrane domains and are internalized independently of the cytoskeleton in characean internodal cells. Plant Cell Physiol 49:1508–1521
29. Klima A, Foissner I (2011) Actin-dependent deposition of putative endosomes and endoplasmic reticulum during early stages ofwound healing in characean internodal cells. Plant Biol 13:590–601
30. Lange K (2011) Fundamental role of microvilli in the main functions of differentiated cells: outline of an universal regulating and signaling system at the cell periphery. J Cell Physiol 226:896–927
31. Ligrone R, Vaughn KC, Rascio N (2011) A cytochemical and immunocytochemical analysis of the wall labyrinth apparatus in leaf transfer cells in Elodea canadensis. Ann Bot 107:717–722
32. Lingwood D, Simons K (2009) Lipid rafts as a membrane-organizing principle. Science 327:46–50
33. Lucas WJ, Smith FA (1973) The formation of alkaline and acid regions at the surface of Chara corallina cells. J Exp Bot 24:1–14
34. Lucas WJ, Brechignac F, Mimura T, Oross JW (1989) Charasomes are not essential for photosynthetic utilization of exogenous HCO3 in Chara corallina. Protoplasma 151:106–114
35. Malinsky J, Opekarová M, Grossmann G, Tanner W (2013) Membrane microdomains, rafts, and detergent-resistant membranes in plants and fungi. Annu Rev Plant Biol 64:501–529
36. Martiniere A, Gayral P, Hawes C, Runions J (2011) Building bridges: formin1 of Arabidopsis forms a connection between the cell wall and the actin cytoskeleton. Plant J 66:354–365
37. McCurdy DW, Patrick JW, Offler CE (2008)Wall ingrowth formation in transfer cells: novel examples of localized wall deposition in plant cells. Curr Opin Plant Biol 11:653–661
38. Mongrand S, Stanislas T, Bayer EMF, Lherminier J, Simon-Plas F (2011) Membrane rafts in plant cells. Trends Plant Sci 15:656–663
39. Offler CE, McCurdy DW, Patrick JW, Talbot MJ (2003) Transfer cells: cells specialized for a special purpose. Annu Rev Plant Biol 54:431–454
40. Price GD, Badger MR (1985) Inhibition by proton buffers of photosynthetic utilization of bicarbonate in Chara corallina. Aust J Plant Physiol 12:257–267
41. Price GD, Whitecross MI (1983) Cytochemical localization of ATPase activity on the plasmalemma of Chara corallina. Protoplasma 116: 65–74
42. Price GD, Badger MR, Bassett ME, Whitecross MI (1985) Involvement of plasmalemmasomes and carbonic anhydrase in photosynthetic utilization of bicarbonate in Chara corallina. Aust J Plant Physiol 12:241–256
43. Prins HBA, Elzenga JTM (1989) Bicarbonate utilization—function and mechanism. Aquat Bot 34:59–83
44. Prins HBA, Snel JFH, Zanstra PE, Helder RJ (1982) The mechanism of bicarbonate assimilation by the polar leaves of Potamogeton and Elodea. CO2 concentrations at the leaf surface. Plant Cell Environ 5: 207–214
45. Schmoelzer PM, Hoeftberger M, Foissner I (2011) Plasma membrane domains participate in pH banding of Chara internodal cells. Plant Cell Physiol 52:1274–1288
46. Shimmen T, Yamamoto A (2002) Induction of a new alkaline band at a target position in internodal cells of Chara corallina. Plant Cell Physiol 43:980–983
47. Shimmen T, Yokota E (2004) Cytoplasmic streaming in plants. Curr Opin Cell Biol 16:68–72
48. Spear DG, Barr JK, Barr CE (1969) Localization of hydrogen ion and chloride ion fluxes in Nitella. J Gen Physiol 54:397–414
49. Thomas C (2012) Bundling actin filaments from membranes: some novel players. Front Plant Sci 3:188
50. Uijttewaal WSJ (2014) Hydrodynamics of shallow flows: application to rivers. J Hydraul Res 52:157–172
51. Volkov AG (2006) Plant electrophysiology. Springer, Berlin
52. Wood RD, Imahori K (1965) Monograph of the characeae. Cramer, Weinheim