Lipid function in plant cell polarity

Current Opinion in Plant Biology

Volumn 7, Issue 6, 2004, Pages 670-676

  Fischer, Urs ^a   Men, Shuzhen ^a   Grebe, Markus ^a  

^a SWEDISH UNIVERSITY OF AGRICULTURAL SCIENCES   (Sweden)

Author keywords

[No Author keywords available]

Indexed keywords

GLYCOSYLPHOSPHATIDYLINOSITOL; LIPID; STEROL; VEGETABLE PROTEIN;

ARABIDOPSIS; CELL POLARITY; CYTOLOGY; FLOWER; GROWTH, DEVELOPMENT AND AGING; LIPID METABOLISM; METABOLISM; PHYSIOLOGY; PLANT ROOT; REVIEW; SIGNAL TRANSDUCTION;

ARABIDOPSIS; CELL POLARITY; FLOWERS; GLYCOSYLPHOSPHATIDYLINOSITOLS; LIPID METABOLISM; LIPIDS; PLANT PROTEINS; PLANT ROOTS; SIGNAL TRANSDUCTION; STEROLS;

EID: 6044239517     PISSN: 13695266     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.pbi.2004.09.007     Document Type: Review

References (46)

1. E. Schnepf Cellular polarity Annu Rev Plant Physiol 37 1986 23 47
2. D.J. Cove The generation and modification of cell polarity J Exp Bot 51 2000 831 838
3. T. Sachs Cell polarity and tissue patterning in plants Development 1 1991 83 93
4. M. Grebe, J. Xu, and B. Scheres Cell axiality and polarity in plants - adding pieces to the puzzle Curr Opin Plant Biol 4 2001 520 526
5. J. Heslop-Harrison Pollen germination and pollen-tube growth Int Rev Cytol 107 1987 1 78
6. M. Hülskamp, K. Schneitz, and R.E. Pruitt Genetic evidence for a long-range activity that directs pollen tube guidance in Arabidopsis Plant Cell 7 1995 57 64
7. J. Schiefelbein, M. Galway, J. Masucci, and S. Ford Pollen tube and root-hair tip growth is disrupted in a mutant of Arabidopsis thaliana Plant Physiol 103 1993 979 985
8. M. Grebe Ups and downs of tissue and planar polarity in plants Bioessays 26 2004 719 729
9. A. Müller, C. Guan, L. Gälweiler, P. Tänzler, P. Huijser, A. Marchant, G. Parry, M. Bennett, E. Wisman, and K. Palme AtPIN2 defines a locus of Arabidopsis for root gravitropism control EMBO J 17 1998 6903 6911
10. R. Swarup, J. Friml, A. Marchant, K. Ljung, G. Sandberg, K. Palme, and M. Bennett Localization of the auxin permease AUX1 suggests two functionally distinct hormone transport pathways operate in the Arabidopsis root apex Genes Dev 15 2001 2648 2653
11. G. Schindelman, A. Morikami, J. Jung, T.I. Baskin, N.C. Carpita, P. Derbyshire, M.C. McCann, and P.N. Benfey COBRA encodes a putative GPI-anchored protein, which is polarly localized and necessary for oriented cell expansion in Arabidopsis Genes Dev 15 2001 1115 1127
12. S. Udenfriend, and K. Kodukula How glycosylphosphatidylinositol-anchored membrane proteins are made Annu Rev Biochem 64 1995 563 591
13. H. Ikezawa Glycosylphosphatidylinositol (GPI)-anchored proteins Biol Pharm Bull 25 2002 409 417
14. M.P. Lisanti, I.W. Caras, M.A. Davitz, and E. Rodriguez-Boulan A glycophospholipid membrane anchor acts as an apical targeting signal in polarised epithelial cells J Cell Biol 109 1989 2145 2156
15. K. Simons, and E. Ikonen Functional rafts in cell membranes Nature 387 1997 569 572
16. J.J. Youl, A. Bacic, and D. Oxley Arabinogalactan-proteins from Nicotiana alata and Pyrus communis contain glycosylphosphatidylinositol membrane anchors Proc Natl Acad Sci USA 95 1998 7921 7926
17. D. Oxley, and A. Bacic Structure of the glycosylphosphatidylinositol anchor of an arabinogalactan protein from Pyrus communis suspension-cultured cells Proc Natl Acad Sci USA 96 1999 14246 14251
18. D.J. Sherrier, T.A. Prime, and P. Dupree Glycosylphosphatidylinositol- anchored cell-surface proteins from Arabidopsis Electrophoresis 20 1999 2027 2035
19. F. Elortza, T.S. Nuhse, L.J. Foster, A. Stensballe, S.C. Peck, and O.N. Jensen Proteomic analysis of glycosylphosphatidylinositol-anchored membrane proteins Mol Cell Proteomics 2 2003 1261 1270
20. Z.D. Zhao, L. Tan, A.M. Showalter, D.T. Lamport, and M.J. Kieliszewski Tomato LeAGP-1 arabinogalactan-protein purified from transgenic tobacco corroborates the Hyp contiguity hypothesis Plant J 31 2002 431 444
21. W. Sun, Z.D. Zhao, M.C. Hare, M.J. Kieliszewski, and A.M. Showalter Tomato LeAGP-1 is a plasma membrane-bound, glycosylphosphatidylinositol-anchored arabinogalactan-protein Physiol Plant 120 2004 319 327 GFP-LeAGP-1 is shown to be present in PM fractions. Fluorescence microscopy demonstrates its localisation to the PM and the Hechtian threads. Abolition of the carboxy-terminal hydrophobic domain that is required for GPI modification resulted in the secretion of the fusion protein to the interface between the PM and the cell wall.
22. H. Shi, Y. Kim, Y. Guo, B. Stevenson, and J.K. Zhu The Arabidopsis SOS5 locus encodes a putative cell surface adhesion protein and is required for normal cell expansion Plant Cell 15 2003 19 32 SOS5 is the first AGP to have its function addressed by mutant analyses. The sos5 mutant is hypersensitive to salt stress and the function of the SOS5 protein is required for the directional cell expansion of root cells under moderate salt stress conditions.
23. J.C. Sedbrook, K.L. Carroll, K.F. Hung, P.H. Masson, and C.R. Somerville The Arabidopsis SKU5 gene encodes an extracellular glycosyl phosphatidylinositol-anchored glycoprotein involved in directional root growth Plant Cell 14 2002 1635 1648
24. E. Lalanne, D. Honys, A. Johnson, G.H. Borner, K.S. Lilley, P. Dupree, U. Grossniklaus, and D. Twell SETH1 and SETH2, two components of the glycosylphosphatidylinositol anchor biosynthetic pathway, are required for pollen germination and tube growth in Arabidopsis Plant Cell 16 2004 229 240 Mutational analysis of two presumptive subunits of GPI-N- acetylglucosaminyltransferase (GPI-GnT), an enzymatic complex that is required for GPI biosynthesis, reveals the importance of GPI biosynthesis for pollen germination and tube growth.
25. P. Keller, and K. Simons Cholesterol is required for surface transport of influenza virus hemagglutinin J Cell Biol 140 1998 1357 1367
26. M. Bagnat, S. Keranen, A. Shevchenko, A. Shevchenko, and K. Simons Lipid rafts function in biosynthetic delivery of proteins to the cell surface in yeast Proc Natl Acad Sci USA 97 2000 3254 3259
27. M. Bagnat, and K. Simons Cell surface polarisation during yeast mating Proc Natl Acad Sci USA 99 2002 14183 14188
28. S. Heino, S. Lusa, P. Somerharju, C. Ehnholm, V.M. Olkkonen, and E. Ikonen Dissecting the role of the Golgi complex and lipid rafts in biosynthetic transport of cholesterol to the cell surface Proc Natl Acad Sci USA 97 2000 8375 8380
29. J. Valdez-Taubas, and H.R. Pelham Slow diffusion of proteins in the yeast plasma membrane allows polarity to be maintained by endocytic cycling Curr Biol 13 2003 1636 1640 The authors demonstrate that interference with balanced ergosterol levels results in an altered lateral diffusion of polar proteins in the PM that perturbs endocytic recycling. Endocytic cycling is proposed as a sterol-dependent mechanism that regulates the maintenance of cell polarity.
30. F.M. Carland, S. Fujioka, S. Takatsuto, S. Yoshida, and T. Nelson The identification of CVP1 reveals a role for sterols in vascular patterning Plant Cell 14 2002 2045 2058
31. V. Willemsen, J. Friml, M. Grebe, A. van den Toorn, K. Palme, and B. Scheres Cell polarity and PIN protein positioning in Arabidopsis require STEROL METHYLTRANSFERASE1 function Plant Cell 15 2003 612 625 The study described in this paper employs a range of polarity markers and polar auxin transport assays to describe the developmental and cell biological defects of the orc mutant. Phenotypic analyses and positional cloning of the SMT1 gene that is affected by the orc mutation reveal that balanced sterol biosynthesis is required for cell and tissue polarity in plants.
32. K. Umebayashi, and A. Nakano Ergosterol is required for targeting of tryptophan permease to the yeast plasma membrane J Cell Biol 161 2003 1117 1131 The authors demonstrate that interference with balanced ergosterol levels in budding yeast affects the raft-dependent targeting of the tryptophane permease Tat2p to the plasma membrane, and results in the mis-direction of the Tat2p protein into the late endocytic pathway.
33. M. Grebe, J. Xu, W. Möbius, T. Ueda, A. Nakano, H.J. Geuze, M.B. Rook, and B. Scheres Arabidopsis sterol endocytosis involves actin-mediated trafficking via ARA6-positive early endosomes Curr Biol 13 2003 1378 1387 The study introduces the use of the sterol-binding antibiotic filipin for fluorescent detection of plant endocytic sterol trafficking. This sterol trafficking is correlated with polar endocytic PIN2 recycling.
34. M. Suzuki, Y. Kamide, N. Nagata, H. Seki, K. Ohyama, H. Kato, K. Masuda, S. Sato, T. Kato, and S. Tabata Loss of function of 3-hydroxy-3-methylglutaryl coenzyme A reductase 1 (HMG1) in Arabidopsis leads to dwarfing, early senescence and male sterility, and reduced sterol levels Plant J 37 2004 750 761
35. K. Schrick, S. Fujioka, S. Takatsuto, Y.D. Stierhof, H. Stransky, S. Yoshida, and G. Jürgens A link between sterol biosynthesis, the cell wall, and cellulose in Arabidopsis Plant J 38 2004 227 243
36. H.J. Meijer, and T. Munnik Phospholipid-based signaling in plants Annu Rev Plant Physiol Plant Mol Biol 54 2003 265 306 A comprehensive and very informative recent review on phospholipid signalling in plants.
37. X. Wang Lipid signaling Curr Opin Plant Biol 7 2004 329 336 A focused and informative very recent update on plant phospholipid signalling.
38. Y. Ohashi, A. Oka, R. Rodrigues-Pousada, M. Possenti, I. Ruberti, G. Morelli, and T. Aoyama Modulation of phospholipid signaling by GLABRA2 in root-hair pattern formation Science 300 2003 1427 1430 The authors identify the Arabidopsis phospholipase Dζ1 (PLDζ1) that acts downstream of the homeodomain protein GLABRA2 and is directly negatively controlled by GLABRA2 at the transcriptional level. Reduction of PLDζ1 transcript levels results in trichoblast and root-hair polarity defects, whereas its ectopic overexpression induces root hair formation.
39. R.G. Anthony, R. Henriques, A. Helfer, T. Meszaros, G. Rios, C. Testerink, T. Munnik, M. Deak, C. Koncz, and L. Bogre A protein kinase target of a PDK1 signalling pathway is involved in root hair growth in Arabidopsis EMBO J 23 2004 572 581 The authors identify a PA-activated signalling pathway in which PA acts on the 3′-phosphoinositide-dependent kinase AtPDK1. In turn, AtPDK1 activates an AGC kinase. agc2-1 mutants are characterized by defects in polar root hair tip growth and AGC2-GFP localises to the root-hair tip.
40. M. Potocky, M. Elias, B. Profotova, Z. Novotna, O. Valentova, and V. Zarsky Phosphatidic acid produced by phospholipase D is required for tobacco pollen tube growth Planta 217 2003 122 130 Pharmacological studies reveal a role for PA in pollen-tube growth. The nature of the inhibitors and activators that are employed indicates that PA action is based on PLD activity.
41. P. Dhonukshe, A.M. Laxalt, J. Goedhart, T.W. Gadella, and T. Munnik Phospholipase D activation correlates with microtubule reorganization in living plant cells Plant Cell 15 2003 2666 2679 Pharmacological activation of PLD leads to microtubule reorganisation in tobacco BY2 cells. The authors propose a model in which PLD serves as a dynamic linker between the PM and microtubules.
42. J. Marc, D.E. Sharkey, N.A. Durso, M. Zhang, and R.J. Cyr Isolation of a 90-kD microtubule-associated protein from tobacco membranes Plant Cell 8 1996 2127 2138
43. J.C. Gardiner, J.D. Harper, N.D. Weerakoon, D.A. Collings, S. Ritchie, S. Gilroy, R.J. Cyr, and J. Marc A 90-kD phospholipase D from tobacco binds to microtubules and the plasma membrane Plant Cell 13 2001 2143 2158
44. 3 levels. cvp2 mutants are affected in vascular pattering.
45. J.J. Esseling, F.G. Lhuissier, and A.M. Emons Nod factor-induced root hair curling: continuous polar growth towards the point of nod factor application Plant Physiol 132 2003 1982 1988 External spot application of a purified nod factor is shown to induce the reorientation of polar tip growth, demonstrating that nod factor can act as an extrinsic polarity cue.
46. M. den Hartog, N. Verhoef, and T. Munnik Nod factor and elicitors activate different phospholipid signaling pathways in suspension-cultured alfalfa cells Plant Physiol 132 2003 311 317