Patterning of Leaf Vein Networks by Convergent Auxin Transport Pathways
The formation of leaf vein patterns has fascinated biologists for centuries. Transport of the plant signal auxin has long been implicated in vein patterning, but molecular details have remained unclear. Varied evidence suggests a central role for the plasma-membrane (PM)-localized PIN-FORMED1 (PIN1) intercellular auxin transporter of Arabidopsis thaliana in auxin-transport-dependent vein patterning. However, in contrast to the severe vein-pattern defects induced by auxin transport inhibitors, pin1 mutant leaves have only mild vein-pattern defects. These defects have been interpreted as evidence of redundancy between PIN1 and the other four PM-localized PIN proteins in vein patterning, redundancy that underlies many developmental processes. By contrast, we show here that vein patterning in the Arabidopsis leaf is controlled by two distinct and convergent auxin-transport pathways: intercellular auxin transport mediated by PM-localized PIN1 and intracellular auxin transport mediated by the evolutionarily older, endoplasmic-reticulum-localized PIN6, PIN8, and PIN5. PIN6 and PIN8 are expressed, as PIN1 and PIN5, at sites of vein formation. pin6 synthetically enhances pin1 vein-pattern defects, and pin8 quantitatively enhances pin1pin6 vein-pattern defects. Function of PIN6 is necessary, redundantly with that of PIN8, and sufficient to control auxin response levels, PIN1 expression, and vein network formation; and the vein pattern defects induced by ectopic PIN6 expression are mimicked by ectopic PIN8 expression. Finally, vein patterning functions of PIN6 and PIN8 are antagonized by PIN5 function. Our data define a new level of control of vein patterning, one with repercussions on other patterning processes in the plant, and suggest a mechanism to select cell files specialized for vascular function that predates evolution of PM-localized PIN proteins.
Vyšlo v časopise:
Patterning of Leaf Vein Networks by Convergent Auxin Transport Pathways. PLoS Genet 9(2): e32767. doi:10.1371/journal.pgen.1003294
Kategorie:
Research Article
prolekare.web.journal.doi_sk:
https://doi.org/10.1371/journal.pgen.1003294
Souhrn
The formation of leaf vein patterns has fascinated biologists for centuries. Transport of the plant signal auxin has long been implicated in vein patterning, but molecular details have remained unclear. Varied evidence suggests a central role for the plasma-membrane (PM)-localized PIN-FORMED1 (PIN1) intercellular auxin transporter of Arabidopsis thaliana in auxin-transport-dependent vein patterning. However, in contrast to the severe vein-pattern defects induced by auxin transport inhibitors, pin1 mutant leaves have only mild vein-pattern defects. These defects have been interpreted as evidence of redundancy between PIN1 and the other four PM-localized PIN proteins in vein patterning, redundancy that underlies many developmental processes. By contrast, we show here that vein patterning in the Arabidopsis leaf is controlled by two distinct and convergent auxin-transport pathways: intercellular auxin transport mediated by PM-localized PIN1 and intracellular auxin transport mediated by the evolutionarily older, endoplasmic-reticulum-localized PIN6, PIN8, and PIN5. PIN6 and PIN8 are expressed, as PIN1 and PIN5, at sites of vein formation. pin6 synthetically enhances pin1 vein-pattern defects, and pin8 quantitatively enhances pin1pin6 vein-pattern defects. Function of PIN6 is necessary, redundantly with that of PIN8, and sufficient to control auxin response levels, PIN1 expression, and vein network formation; and the vein pattern defects induced by ectopic PIN6 expression are mimicked by ectopic PIN8 expression. Finally, vein patterning functions of PIN6 and PIN8 are antagonized by PIN5 function. Our data define a new level of control of vein patterning, one with repercussions on other patterning processes in the plant, and suggest a mechanism to select cell files specialized for vascular function that predates evolution of PM-localized PIN proteins.
Zdroje
1. FosterAS (1952) Foliar Venation in Angiosperms from an Ontogenetic Standpoint. American Journal of Botany 39: 752–766.
2. PrayTR (1955) Foliar venation in Angiosperms. II. Histogenesis of the venation of Liriodendron. American Journal of Botany 42: 18–27.
3. SachsT (1989) The development of vascular networks during leaf development. Current Topics in Plant Biochemistry and Physiology 8: 168–183.
4. BerlethT, MattssonJ, HardtkeCS (2000) Vascular continuity and auxin signals. Trends in Plant Science 5: 387–393.
5. GersaniM (1987) The Induction of Differentiation of Organized Vessels in a Storage Organ. Annals of Botany 59: 31–34.
6. MattssonJ, SungZR, BerlethT (1999) Responses of plant vascular systems to auxin transport inhibition. Development 126: 2979–2991.
7. SieburthLE (1999) Auxin is required for leaf vein pattern in Arabidopsis. Plant Physiology 121: 1179–1190.
8. GalweilerL, GuanC, MullerA, WismanE, MendgenK, et al. (1998) Regulation of polar auxin transport by AtPIN1 in Arabidopsis vascular tissue. Science 282: 2226–2230.
9. PetrasekJ, MravecJ, BouchardR, BlakesleeJJ, AbasM, et al. (2006) PIN proteins perform a rate-limiting function in cellular auxin efflux. Science 312: 914–918.
10. ScarpellaE, MarcosD, FrimlJ, BerlethT (2006) Control of leaf vascular patterning by polar auxin transport. Genes & Development 20: 1015–1027.
11. WenzelCL, SchuetzM, YuQ, MattssonJ (2007) Dynamics of MONOPTEROS and PIN-FORMED1 expression during leaf vein pattern formation in Arabidopsis thaliana. The Plant Journal 49: 387–398.
12. SachsT (1991) Cell Polarity and Tissue Patterning in Plants. Development Supplement 1: 83–93.
13. SachsT (1981) The control of the patterned differentiation of vascular tissues. Advances in Botanical Research 9: 151–262.
14. GarnettP, SteinacherA, StepneyS, ClaytonR, LeyserO (2010) Computer simulation: the imaginary friend of auxin transport biology. Bioessays 32: 828–835.
15. KrupinskiP, JonssonH (2010) Modeling auxin-regulated development. Cold Spring Harbor Perspectives in Biology 2: a001560 doi:001510.001101/cshperspect.a001560.
16. SantosF, TealeW, FleckC, VolpersM, RupertiB, et al. (2010) Modelling polar auxin transport in developmental patterning. Plant Biology 12 Supplement 1: 3–14.
17. SmithRS, BayerEM (2009) Auxin transport-feedback models of patterning in plants. Plant, Cell & Environment 32: 1258–1271.
18. WabnikK, GovaertsW, FrimlJ, Kleine-VehnJ (2011) Feedback models for polarized auxin transport: an emerging trend. Molecular Biosystems 7: 2352–2359.
19. BilsboroughGD, RunionsA, BarkoulasM, JenkinsHW, HassonA, et al. (2011) Model for the regulation of Arabidopsis thaliana leaf margin development. Proceedings of the National Academy of Sciences, USA 108: 3424–3429.
20. GuenotB, BayerE, KierzkowskiD, SmithRS, MandelT, et al. (2012) PIN1-Independent Leaf Initiation in Arabidopsis. Plant Physiology 159: 1501–1510.
21. KrecekP, SkupaP, LibusJ, NaramotoS, TejosR, et al. (2009) The PIN-FORMED (PIN) protein family of auxin transporters. Genome Biology 10: 249 doi:10.1186/gb-2009-10-12-249.
22. ZazimalovaE, MurphyAS, YangH, HoyerovaK, HosekP (2010) Auxin transporters–why so many? Cold Spring Harbor Perspectives in Biology 2: a001552 doi:10.1101/cshperspect.a001552.
23. PaponovIA, TealeWD, TrebarM, BlilouI, PalmeK (2005) The PIN auxin efflux facilitators: evolutionary and functional perspectives. Trends in Plant Science 10: 170–177.
24. Viaene T, Delwiche CF, Rensing SA, Friml J (2012) Origin and evolution of PIN auxin transporters in the green lineage. Trends in Plant Science In press.
25. ClayNK, NelsonT (2005) Arabidopsis thickvein mutation affects vein thickness and organ vascularization, and resides in a provascular cell-specific spermine synthase involved in vein definition and in polar auxin transport. Plant Physiology 138: 767–777.
26. SassiM, LuY, ZhangY, WangJ, DhonuksheP, et al. (2012) COP1 mediates the coordination of root and shoot growth by light through modulation of PIN1- and PIN2-dependent auxin transport in Arabidopsis. Development 139: 3402–3412.
27. FischerU, IkedaY, LjungK, SerralboO, SinghM, et al. (2006) Vectorial information for Arabidopsis planar polarity is mediated by combined AUX1, EIN2, and GNOM activity. Current Biology 16: 2143–2149.
28. CandelaH, Martinez-LabordaA, MicolJL (1999) Venation pattern formation in Arabidopsis thaliana vegetative leaves. Developmental Biology 205: 205–216.
29. NelsonT, DenglerN (1997) Leaf Vascular Pattern Formation. Plant Cell 9: 1121–1135.
30. PeretB, SwarupK, FergusonA, SethM, YangY, et al. (2012) AUX/LAX genes encode a family of auxin influx transporters that perform distinct functions during Arabidopsis development. Plant Cell 24: 2874–2885.
31. BarbezE, KubesM, RolcikJ, BeziatC, PencikA, et al. (2012) A novel putative auxin carrier family regulates intracellular auxin homeostasis in plants. Nature 485: 119–122.
32. GeislerM, MurphyAS (2006) The ABC of auxin transport: the role of p-glycoproteins in plant development. FEBS Letters 580: 1094–1102.
33. LiuC, XuZ, ChuaNH (1993) Auxin Polar Transport Is Essential for the Establishment of Bilateral Symmetry during Early Plant Embryogenesis. Plant Cell 5: 621–630.
34. HadfiK, SpethV, NeuhausG (1998) Auxin-induced developmental patterns in Brassica juncea embryos. Development 125: 879–887.
35. GordonSP, HeislerMG, ReddyGV, OhnoC, DasP, et al. (2007) Pattern formation during de novo assembly of the Arabidopsis shoot meristem. Development 134: 3539–3548.
36. MravecJ, SkupaP, BaillyA, HoyerovaK, KrecekP, et al. (2009) Subcellular homeostasis of phytohormone auxin is mediated by the ER-localized PIN5 transporter. Nature 459: 1136–1140.
37. GangulyA, LeeSH, ChoM, LeeOR, YooH, et al. (2010) Differential auxin-transporting activities of PIN-FORMED proteins in Arabidopsis root hair cells. Plant Physiology 153: 1046–1061.
38. BoscoCD, DovzhenkoA, LiuX, WoernerN, RenschT, et al. (2012) The endoplasmic reticulum localized PIN8 is a pollen specific auxin carrier involved in intracellular auxin homeostasis. The Plant Journal 71: 860–870.
39. DingZ, WangB, MorenoI, DuplakovaN, SimonS, et al. (2012) ER-localized auxin transporter PIN8 regulates auxin homeostasis and male gametophyte development in Arabidopsis. Nature Communications 3: 941 doi:10.1038/ncomms1941.
40. YamasakiS, Sakata-SogawaK, HasegawaA, SuzukiT, KabuK, et al. (2007) Zinc is a novel intracellular second messenger. Journal of Cell Biology 177: 637–645.
41. DonAS, Martinez-LamencaC, WebbWR, ProiaRL, RobertsE, et al. (2007) Essential requirement for sphingosine kinase 2 in a sphingolipid apoptosis pathway activated by FTY720 analogues. Journal of Biological Chemistry 282: 15833–15842.
42. TanY, DourdinN, WuC, De VeyraT, ElceJS, et al. (2006) Ubiquitous calpains promote caspase-12 and JNK activation during endoplasmic reticulum stress-induced apoptosis. Journal of Biological Chemistry 281: 16016–16024.
43. ColeL, DaviesD, HydeGJ, AshfordAE (2000) ER-Tracker dye and BODIPY-brefeldin A differentiate the endoplasmic reticulum and golgi bodies from the tubular-vacuole system in living hyphae of Pisolithus tinctorius. Journal of Microscopy 197: 239–249.
44. HeislerMG, OhnoC, DasP, SieberP, ReddyGV, et al. (2005) Patterns of Auxin Transport and Gene Expression during Primordium Development Revealed by Live Imaging of the Arabidopsis Inflorescence Meristem. Current Biology 15: 1899–1911.
45. VietenA, VannesteS, WisniewskaJ, BenkovaE, BenjaminsR, et al. (2005) Functional redundancy of PIN proteins is accompanied by auxin-dependent cross-regulation of PIN expression. Development 132: 4521–4531.
46. NemhauserJL, HongF, ChoryJ (2006) Different plant hormones regulate similar processes through largely nonoverlapping transcriptional responses. Cell 126: 467–475.
47. XuJ, HofhuisH, HeidstraR, SauerM, FrimlJ, et al. (2006) A molecular framework for plant regeneration. Science 311: 385–388.
48. WeijersD, Franke-van DijkM, VenckenRJ, QuintA, HooykaasP, et al. (2001) An Arabidopsis Minute-like phenotype caused by a semi-dominant mutation in a RIBOSOMAL PROTEIN S5 gene. Development 128: 4289–4299.
49. DonnerTJ, SherrI, ScarpellaE (2009) Regulation of preprocambial cell state acquisition by auxin signaling in Arabidopsis leaves. Development 136: 3235–3246.
50. RomanoCP, HeinMB, KleeHJ (1991) Inactivation of auxin in tobacco transformed with the indoleacetic acid-lysine synthetase gene of Pseudomonas savastanoi. Genes & Development 5: 438–446.
51. JensenPJ, HangarterRP, EstelleM (1998) Auxin transport is required for hypocotyl elongation in light-grown but not dark-grown Arabidopsis. Plant Physiology 116: 455–462.
52. GraumannK, EvansDE (2011) Nuclear envelope dynamics during plant cell division suggest common mechanisms between kingdoms. Biochemistry Journal 435: 661–667.
53. OdaY, FukudaH (2011) Dynamics of Arabidopsis SUN proteins during mitosis and their involvement in nuclear shaping. The Plant Journal 66: 629–641.
54. Ludwig-MullerJ (2012) Auxin conjugates: their role for plant development and in the evolution of land plants. Journal of Experimental Botany 62: 1757–1773.
55. Rolland-LaganAG, PrusinkiewiczP (2005) Reviewing models of auxin canalization in the context of leaf vein pattern formation in Arabidopsis. The Plant Journal 44: 854–865.
56. WabnikK, Kleine-VehnJ, BallaJ, SauerM, NaramotoS, et al. (2010) Emergence of tissue polarization from synergy of intracellular and extracellular auxin signaling. Molecular Systems Biology 6: 447 doi:10.1038/msb.2010.103.
57. ScarpellaE, FrancisP, BerlethT (2004) Stage-specific markers define early steps of procambium development in Arabidopsis leaves and correlate termination of vein formation with mesophyll differentiation. Development 131: 3445–3455.
58. McKownAD, DenglerNG (2009) Shifts in leaf vein density through accelerated vein formation in C(4) Flaveria (Asteraceae). Annals of Botany 104: 1085–1098.
59. PrusinkiewiczP, CrawfordS, SmithRS, LjungK, BennettT, et al. (2009) Control of bud activation by an auxin transport switch. Proceedings of the National Academy of Sciences, USA 106: 17431–17436.
60. BallaJ, KalousekP, ReinohlV, FrimlJ, ProchazkaS (2011) Competitive canalization of PIN-dependent auxin flow from axillary buds controls pea bud outgrowth. The Plant Journal 65: 571–577.
61. SachsT (1970) A control of bud growth by vascular tissue differentiation. Israel Journal of Botany 19: 484–498.
62. HawleyRS, GillilandWD (2006) Sometimes the result is not the answer: the truths and the lies that come from using the complementation test. Genetics 174: 5–15.
63. WabnikK, Kleine-VehnJ, GovaertsW, FrimlJ (2011) Prototype cell-to-cell auxin transport mechanism by intracellular auxin compartmentalization. Trends in Plant Science 16: 468–475.
64. LigroneR, DuckettJG, RenzagliaKS (2000) Conducting tissues and phyletic relationships of bryophytes. Philosophical Transactions of the Royal Society of London Series B-Biological Sciences 355: 795–813.
65. SawchukMG, DonnerTJ, HeadP, ScarpellaE (2008) Unique and overlapping expression patterns among members of photosynthesis-associated nuclear gene families in Arabidopsis. Plant Physiology 148: 1908–1924.
66. DemandolxD, DavoustJ (1997) Multicolour analysis and local image correlation in confocal microscopy. Journal of Microscopy 185: 21–36.
67. MandersEMM, VerbeekFJ, AtenJA (1993) Measurement of Colocalization of Objects in Dual-Color Confocal Images. Journal of Microscopy 169: 375–382.
Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2013 Číslo 2
- Je „freeze-all“ pro všechny? Odborníci na fertilitu diskutovali na virtuálním summitu
- Gynekologové a odborníci na reprodukční medicínu se sejdou na prvním virtuálním summitu
Najčítanejšie v tomto čísle
- Complex Inheritance of Melanoma and Pigmentation of Coat and Skin in Grey Horses
- Coordination of Chromatid Separation and Spindle Elongation by Antagonistic Activities of Mitotic and S-Phase CDKs
- Autophagy Induction Is a Tor- and Tp53-Independent Cell Survival Response in a Zebrafish Model of Disrupted Ribosome Biogenesis
- Assembly of the Auditory Circuitry by a Genetic Network in the Mouse Brainstem