A new callose function involvement in differentiation and function of fern stomatal complexes

Plant Signaling and Behavior

Volumn 5, Issue 11, 2010, Pages

  Galatis, Basil ^a   Apostolakos, Panagiotis ^a  

^a UNIVERSITY OF ATHENS   (Greece)

Author keywords

Callose; Cytoskeleton; Fern stomata; Guard cell wall thickening; Stomatal function; Stomatal pore formation

Indexed keywords

FILICOPHYTA;

CALLOSE; GLUCAN;

CELL DIFFERENTIATION; CYTOLOGY; DRUG EFFECT; FERN; METABOLISM; PHYSIOLOGY; PLANT STOMA; REVIEW; SIGNAL TRANSDUCTION;

CELL DIFFERENTIATION; FERNS; GLUCANS; PLANT STOMATA; SIGNAL TRANSDUCTION;

EID: 78650151426     PISSN: 15592316     EISSN: 15592324     Source Type: Journal    
DOI: None     Document Type: Article

References (74)

1. Verma DPS, Hong Z. Plant callose synthase complexes. Plant Mol Biol 2001; 47:693-701.
2. Bulone V. In vitro synthesis and analysis of plant (1→3)-β-D-glucans and cellulose: a key step towards the characterization of glucan synthases. In: Brown RM Jr, Saxena IM, eds. Cellulose: Molecular and Structural Biology. Heidelberg: Springer 2007; 123-45.
3. Chen X-Y, Kim J-Y. Callose synthesis in higher plants. Plant Signal Behav 2009; 6:489-92.
4. Bacic A, Fincher GB, Stone BA. Chemistry, Biochemistry and Biology of (1→3)-β-Glucans and Related Polysaccharides. Amsterdam: Academic Press 2009.
5. Stone BA, Clarke AE. Chemistry and Biology of (1,3)- β-Glucans. Bundora Australia: La Trobe University Press 1992.
6. Stone BA. Chemistry of β-glucans. In: Bacic A, Fincher GB, Stone BA, Eds. Chemistry, Biochemistry and Biology of (1→3)-β-glucans and Related Polysaccharides. Amsterdam: Academic Press 2009; 5-46.
7. Sletmoen M, Stokke BT. Higher order structure of (1,3)-β-D-glucans and its influence on their biological activities and complexation abilities. Biopolymers 2008; 89:310-21.
8. Eschrich W. Physiologie der Siebrohrencallose. Planta 1965; 65:280-300.
9. Samuels AL, Giddings TH, Staehelin LA. Cytokinesis in tobacco BY-2 and root tip cells: a new model of cell plate formation in higher plants. J Cell Biol 1995; 30:1345-57.
10. Thiele K, Wanner G, Kindzierski V, Jurgens G, Mayer U, Pachl F, Assaad FF. The timely deposition of callose is essential for cytokinesis in Arabidopsis. Plant J 2009; 58:13-26.
11. Brown RC, Lemmon BE. Callose in cell division. In: Bacic A, Fincher GB, Stone BA, (Eds). Chemistry, Biochemistry and Biology of (1→3)-β-Glucans and Related Polysaccharides. Amsterdam: Academic Press 2009; 425-37.
12. Taylor LP, Hepler PK. Pollen germination anf tube growth. Ann Rev Plant Physiol Plant Mol Biol 1997; 48:461-91.
13. Nishikawa S, Zinkl GM, Swanson RJ, Maruyama D, Prenss D. Callose (β-1,3glucan) is essential for Arabidopsis pollen wall patterning, but not tube growth. BMC Plant Biol 2005; 5:22-30.
14. Newbigin E, Bacic E, Read S. Callose and its role in pollen and embryo sac development in flowering plants. In: Bacic A, Fincher GB, Stone BA, Eds. Chemistry, Biochemistry and Biology of (1→3)-β-Glucans and Related Polysaccharides. Amsterdam: Academic Press 2009; 465-98.
15. Oparka KJ, Roberts AG. Plasmodesmata. A not so open-and-shut case. Plant Physiol 2001; 125:123-6.
16. Levy A, Epel BL. Cytology of the (1→3)-β-glucan (callose) in plasmodesmata and sieve pores. In: Bacic A, Fincher GB, Stone BA, Eds. Chemistry, Biochemistry and Biology of (1→3)-β-Glucans and Related Polysaccharides. Amsterdam: Academic Press 2009; 439-63.
17. Baluška F, Volkmann D, Barlow PW. Actin-based domains of the "cell periphery complex" and their associations with polarized "cell bodies" in higher plants. Plant Biol 2000; 2:253-67.
18. Parre E, Geitmann A. More than a leak sealant. The mechanical properties of callose in pollen tubes. Plant Physiol 2005; 37:274-86.
19. Heslop-Harrison J. Cell walls, cell membranes and protoplasmic connections during meiosis and pollen development. In: Linskens HF, Ed. Pollen Physiology and Ferilization. North-Holland: Amsterdam 1964; 29-47.
20. Yim KO, Bradford JK. Callose deposition is responsible for apoplastic semipermeability of the endosperm envelope of muskmelon seeds. Plant Physiol 1998; 118:83-90.
21. Peterson RL, Firminger MS, Dobrindt LA. Nature of the guard cell wall in leaf stomata of three Ophioglossum species. Can J Bot 1975; 53:1698-711.
22. Peterson RL, Hambleton S. Guard cell ontogeny in leaf stomata of the fern Ophioglossum petiolatum. Can J Bot 1978; 56:2836-52.
23. Waterkeyn L, Bienfait A. Production et dégradation de callose dans les stomates des fougères. La Cellule 1979; 73:83-97.
24. Apostolakos P, Galatis B. Probable cytoskeleton involvement in stomatal pore formation in Asplenium nidus L. Protoplasma 1998; 203:48-57.
25. Apostolakos P, Galatis B. Microtubule and actin filament organization during stomatal morphogenesis in the fern Asplenium nidus. II. Guard cells. New Phytol 1999; 141:209-23.
26. Apostolakos P, Livanos P, Nikolakopoulou TL, Galatis B. The role of callose in guard cell wall differentiation and stomatal pore formation in the fern Asplenium nidus. Ann Bot 2009; 104:1373-87.
27. Apostolakos P, Livanos P, Galatis B. Microtubule involvement in the deposition of radial fibrillar callose arrays in stomata of the fern Asplenium nidus L. Cell Motil Cyt 2009; 66:342-9.
28. Apostolakos P, Livanos P, Nicolakopoulou TL, Galatis B. Callose implication in stomatal opening and closure in the fern Asplenium nidus. New Phytol 2010; 186:623-35.
29. Majewska-Sawka A, Münster A, Rodríguez-García MI. Guard cell wall: immunocytochemical detection of polysaccharide components. J Exp Bot 2002; 53:1067-79.
30. Galatis B, Apostolakos P. The role of the cytoskeleton in the morphogenesis and function of stomatal complexes. New Phytol 2004; 161:613-39.
31. Sack FD. The development and structure of stomata. In: Zeiger E, Farquhar GD, Cowan IR, Eds. Stomatal Function. Stanford CA, USA: Stanford University Press 1987; 59-89.
32. Wilmer C, Fricker M. Stomata. 2nd Edn. London: Chapman and Hall 1996.
33. Hetherington AM. Guard cell signaling. Cell 2001; 107:711-4.
34. Galatis B, Apostolakos P. Microtubule organization and morphogenesis of stomata in caffeine-affected seedlings of Zea mays. Protoplasma 1991; 165:11-26.
35. Galatis B. Microtubules and guard cell morphogenesis in Zea mays L. J Cell Sci 1980; 45:211-44.
36. Galatis B, Mitrakos K. The ultrastructural cytology of the differentiating guard cells of Vigna sinensis. Am J Bot 1980; 67:1243-61.
37. Galatis B, Apostolakos P, Katsaros Ch. Microtubules and their organizing centres in differentiating guard cells of Adiantum capillus-veneris. Protoplasma 1983; 115:176-92.
38. Zachariadis M, Apostolakos P, Galatis B. Morphogenesis of 'floating' stomata in the fern Anemia mandioccana. Stomatal pore formation. In: Tsekos I, Moustakas M, (Eds). Progress in Botanical Research. Dordrecht, The Netherlands: Kluwer Academic Publishers 1998; 615-8.
39. Jaffe MJ, Leopold AC. Callose deposition during gravitropism of Zea mays and Pisum sativum and its inhibition by 2-deoxy-D-glucose. Planta 1984; 161:20-6.
40. Škalamera D, Heath MC. Cellular mechanisms of callose deposition in response to fangal infection or chemical damage. Can J Bot 1996; 74:1236-42.
41. Quader H, Bechtler Ch. The calcium transport inhibitor cyclopiazonic acid reversibly affects the shape of the endoplasmic reticulum in onion epidermal cells. Mitt Inst Allg Bot Hamburg 1996; 26:191-9.
42. Vaughn KC, Hoffman JC, Hahn MG, Staehelin LA. The herbicide dichlobenil disrupts cell plate formation: immunogold characterization. Protoplasma 1996; 194:117-32.
43. Sabba RP, Durso NA, Vaughn KC. Structural and immunocytochemical characterization of the walls of dichlobenil-habituated BY-2 cells. Plant Sci 1999; 160:275-90.
44. DeBolt S, Gutierrez R, Ehrhardt DW, et al. Morlin, an inhibitor of cortical microtubule dynamics and cellulose synthase movement. Proc Nat Acad Sci USA 2007; 104:5855-9.
45. Hong Z, Delauney AJ, Verma DPS. A cell plate-specific callose synthase and its interaction with phragmoplastin. Plant Cell 2001; 13:755-68.
46. Stevens RA, Martin ES. Structural and functional aspects of stomata: I. Developmental studies in Polypodium vulgare. Planta 1978; 142:307-16.
47. Waterkeyn L. Cytochemical localization and function of the 3-linked glucan callose in the developing cotton fibre cell wall. Protoplasma 1981; 106:49-67.
48. Van Amstel TNM, Kengen HMP. Callose deposition in the primary wall of suspension cells and regenerating protoplasts, and its relationship to patterned cellulose synthesis. Can J Bot 1996; 74:1040-9.
49. Hirai N, Sonobe S, Hayashi T. In situ synthesis of β-glucan microfibrils on tobacco plasma membrane sheets. Proc Natl Acad Sci USA 1998; 95:15102-6.
50. Fukumoto T, Hayashi N, Sasamoto H. Atomic force microscopy and laser confocal scanning microscopy analysis of callose fibers developed from protoplasts of embryogenic cells of a conifer. Planta 2005; 223:40-5.
51. Bulone V, Fincher GB, Stone BA. In vitro synthesis of a microfibrillar (1→3)-β-D-glucan by a rye grass (Lolium multiflorum) endosperm. (1→3)-β-D-glucan synthase enriched by product entrapment. Plant J 1995; 8:213-25.
52. Him JLK, Pelosi L, Chanzy H, Putaux J-L, Bulone V. Biosynthesis of (1→3)-β-D-glucan (callose) by detergent extracts of a microsomal fraction from Arabidopsis thaliana. Eur J Biochem 2001; 268:4628-38.
53. Cifuentes C, Bulone V, Emons AMC. Biosynthesis of callose and cellulose by detergent extracts of tobacco cell membranes and quantification of the polymers synthesized in vitro. J Int Plant Biol 2010; 52:221-33.
54. Heath IB. A unified hypothesis for the role of membrane bound enzyme complexes and microtubules in plant cell wall synthesis. J Theor Biol 1974; 48:445-9.
55. Paredez AR, Somerville CR, Ehrhardt DW. Visualization of cellulose synthase demonstrates functional association with microtubules. Science 2006; 312:1491-5.
56. Wasteneys GO, Fujita M. Establishing and maintaining axial growth: wall mechanical deposition and the cytoskeleton. J Plant Res 2006; 119:5-10.
57. Lloyd CW, Chan J. The parallel lines of microtubules and cellulose microfibrils. Curr Opin Plant Biol 2008; 11:641-6.
58. Nick P. Control of cell axis. In: Nick P, ed. Plant Microtubules: Development and Flexibility. Berlin: Springer-Verlag, Plant Cell Monographs 2008; 17:3-46.
59. Gregory ACE, Smith C, Kerry ME, Wheatley ER, Bolwell PG. Comparative subcellular immunolocalization of polypeptides associated with xylan and callose synthases in french bean (Phaseolus vulgaris) during secondary wall formation. Phytochemistry 2002; 59:249-59.
60. Vaughn KC, Talbot MJ, Offler CE, McCurdy DW. Wall ingrowths in epidermal transfer cells of Vicia faba cotyledons are modified primary walls marked by localized accumulations of arabinogalactan proteins. Plant & Cell Physiol 2007; 48:159-68.
61. Salnikov V, Grimson MJ, Seagull RW, Haigler CH. Localization of sucrose synthase and callose in freeze-substituted secondary-wall-stage cotton fibers. Protoplasma 2003; 221:175-84.
62. Ferguson C, Teezi TT, Siika-aho M, Read SM, Bacic A. Location of cellulose and callose in pollen tubes and grains of Nicotiana tabacum. Planta 1998; 206:452-60.
63. Schuette S, Wood AJ, Geisler M, Geisler-Lee J, Ligrone R, Renzaglia KS. Novel localization of callose in spores of Physcomitrella patens and phylogenomics of the callose synthase gene family. Ann Bot 2009; 103:749-56.
64. Chaffey NJ, Barlow PW. Myosin, microtubules and microfilaments: co-operation between cytoskeletal components during cambial cell division and secondary vascular differentiation in trees. Planta 2002; 214:526-36.
65. Fukuda M, Hasezawa S, Asai N, Nakajima N, Kondo N. Dynamic organization of microtubules in guard cells of Vicia faba L. with diurnal cycle. Plant & Cell Physiol 1998; 39:80-6.
66. Yu R, Huang RF, Wang XC, Yuam M. Microtubule dynamics are involved in stomatal movement of Vicia faba L. Protoplasma 2001; 216:113-8.
67. Apostolakos P, Panteris E, Galatis B. Microtubule and actin filament organization during stomatal morphogenesis in the fern Asplenium nidus. I. Guard cell mother cell. Protoplasma 1997; 198:93-106.
68. Kauss H. Some aspects of calcium-dependent regulation in plant metabolism. Ann Rev Plant Physiol 1987; 38:47-72.
69. Haley A, Russel AJ, Wood N, Allan AC, Knight A, et al. Effects of mechanical signaling on plant cell cytosolic calcium. Proc Nat Acad Sci USA 1995; 92:4124-8.
70. Silver FH, Siperko LM. Mechanosensing and mechanochemical transduction: How is mechanical energy sensed and converted into chemical energy in an extracellular matrix. Crit Rev Biomed Engin 2003; 31:255-331.
71. Takeuchi Y, Kondo N. Effect of abscisic acid on cellwall metabolism in guard cells of Vicia faba L. Plant Cell Physiol 1988; 29:573-80.
72. Jones L, Milne JL, Ashford D, McQueen-Mason SJ. Cell wall arabinan is essential for guard cell function. Proc Natl Acad Sci USA 2003; 100:11783-8.
73. Jones L, Milne JL, Ashford D, McCann MC, McQueen-Mason SJ. A conserved functional role of pectic polymers in stomatal guard cells from a range of plant species. Planta 2005; 221:255-64.
74. Popper ZA, Fry SG. Primary cell wall composition of pteridophytes and spermatophytes. New Phytol 2004; 164:165-74.