This article may contain an excessive amount of intricate detail that may interest only a particular audience.(September 2019) |
Gibberellins (GAs) are plant hormones that regulate various developmental processes, including stem elongation, germination, dormancy, flowering, flower development, and leaf and fruit senescence.[1] They are one of the longest-known classes of plant hormone. It is thought that the selective breeding (albeit unconscious) of crop strains that were deficient in GA synthesis was one of the key drivers of the "green revolution" in the 1960s,[2] a revolution that is credited to have saved over a billion lives worldwide.[3]
Chemistry
editAll known gibberellins are diterpenoid acids synthesized by the terpenoid pathway in plastids and then modified in the endoplasmic reticulum and cytosol until they reach their biologically active form.[4] All are derived via the ent-gibberellane skeleton, but are synthesised via ent-kaurene. The gibberellins are named GA1 through GAn in order of discovery.[5] Gibberellic acid, which was the first gibberellin to be structurally characterized, is GA3.[6]
As of 2020[update],[5] there are 136 GAs identified from plants, fungi, and bacteria.[1][6][5]
Gibberellins are tetracyclic diterpene acids. There are two classes, with either 19 or 20 carbons. The 19-carbon gibberellins are generally the biologically active forms. They have lost carbon 20 and, in place, possess a five-member lactone bridge that links carbons 4 and 10. Hydroxylation also has a great effect on its biological activity. In general, the most biologically active compounds are dihydroxylated gibberellins, with hydroxyl groups on both carbons 3 and 13. Gibberellic acid is a 19-carbon dihydroxylated gibberellin.[7]
Bioactive GAs
editThe bioactive Gibberellins are GA1, GA3, GA4, and GA7.[8] There are three common structural traits between these GAs: 1) hydroxyl group on C-3β, 2) a carboxyl group on carbon 6, and 3) a lactone between carbons 4 and 10.[8]
-
Gibberellin A1 (GA1)
-
Gibberellic acid (GA3)
-
ent-Gibberellane
-
ent-Kaurene
The 3β-hydroxyl group can be exchanged for other functional groups at C-2 and/or C-3 positions.[8] GA5 and GA6 are examples of bioactive GAs without a hydroxyl group on C-3β.[8] The presence of GA1 in various plant species suggests that it is a common bioactive GA.[9]
Biological function
editGibberellins are involved in the natural process of breaking dormancy and other aspects of germination. Before the photosynthetic apparatus develops sufficiently in the early stages of germination, the seed reserves of starch nourish the seedling. Usually in germination, the breakdown of starch to glucose in the endosperm begins shortly after the seed is exposed to water.[10] Gibberellins in the seed embryo are believed to signal starch hydrolysis through inducing the synthesis of the enzyme α-amylase in the aleurone cells. In the model for gibberellin-induced production of α-amylase, it is demonstrated that gibberellins from the scutellum diffuse to the aleurone cells, where they stimulate the secretion α-amylase.[4] α-Amylase then hydrolyses starch (abundant in many seeds), into glucose that can be used to produce energy for the seed embryo. Studies of this process have indicated gibberellins cause higher levels of transcription of the gene coding for the α-amylase enzyme, to stimulate the synthesis of α-amylase.[7]
Exposition to cold temperatures increases the production of Gibberellins. They stimulate cell elongation, breaking and budding, and seedless fruits. Gibberellins cause also seed germination by breaking the seed's dormancy and acting as a chemical messenger. Its hormone binds to a receptor, and calcium activates the protein calmodulin, and the complex binds to DNA, producing an enzyme to stimulate growth in the embryo.
Metabolism
editBiosynthesis
editGibberellins are usually synthesized from the methylerythritol phosphate (MEP) pathway in higher plants.[11] In this pathway, bioactive GA is produced from trans-geranylgeranyl diphosphate (GGDP), with the participation of three classes of enzymes: terpene syntheses (TPSs), cytochrome P450 monooxygenases (P450s), and 2-oxoglutarate–dependent dioxygenases (2ODDs).[11][8] The MEP pathway follows eight steps:[8]
- GGDP is converted to ent-copalyl diphosphate (ent-CDP) by ent-copalyl diphosphate synthase (CPS)
- ent-CDP is converted to ent-kaurene by ent-kaurene synthase (KS)
- ent-kaurene is converted to ent-kaurenol by ent-kaurene oxidase (KO)
- ent-kaurenol is converted to ent-kaurenal by KO
- ent-kaurenal is converted to ent-kaurenoic acid by KO
- ent-kaurenoic acid is converted to ent-7a-hydroxykaurenoic acid by ent-kaurenoic acid oxidase (KAO)
- ent-7a-hydroxykaurenoic acid is converted to GA12-aldehyde by KAO
- GA12-aldehyde is converted to GA12 by KAO. GA12 is processed to the bioactive GA4 by oxidations on C-20 and C-3, which is accomplished by 2 soluble ODDs: GA 20-oxidase and GA 3-oxidase.
One or two genes encode the enzymes responsible for the first steps of GA biosynthesis in Arabidopsis and rice.[8] The null alleles of the genes encoding CPS, KS, and KO result in GA-deficient Arabidopsis dwarves.[12] Multigene families encode the 2ODDs that catalyze the formation of GA12 to bioactive GA4.[8]
AtGA3ox1 and AtGA3ox2, two of the four genes that encode GA3ox in Arabidopsis, affect vegetative development.[13] Environmental stimuli regulate AtGA3ox1 and AtGA3ox2 activity during seed germination.[14][15] In Arabidopsis, GA20ox overexpression leads to an increase in GA concentration.[16][17]
Sites of biosynthesis
editMost bioactive Gibberellins are located in actively growing organs on plants.[11] Both GA20ox and GA3ox genes (genes coding for GA 20-oxidase and GA 3-oxidase) and the SLENDER1 gene (a GA signal transduction gene) are found in growing organs on rice, which suggests bioactive GA synthesis occurs at their site of action in growing organs in plants.[18] During flower development, the tapetum of anthers is believed to be a primary site of GA biosynthesis.[18][19]
Differences between biosynthesis in fungi and lower plants
editThe flower Arabidopsis and the fungus Gibberella fujikuroi possess different GA pathways and enzymes.[8] P450s in fungi perform functions analogous to the functions of KAOs in plants.[20] The function of CPS and KS in plants is performed by a single enzyme in fungi (CPS/KS).[21][22][23] In plants the Gibberellin biosynthesis genes are found randomly on multiple chromosomes, but in fungi are found on one chromosome .[24][25]
Plants produce low amount of Gibberellic Acid, therefore is produced for industrial purposes by microorganisms. Industrially GA3 can be produced by submerged fermentation, but this process presents low yield with high production costs and hence higher sale value, nevertheless other alternative process to reduce costs of its production is solid-state fermentation (SSF) that allows the use of agro-industrial residues.[26]
Catabolism
editSeveral mechanisms for inactivating Giberellins have been identified. 2β-hydroxylation deactivates them, and is catalyzed by GA2-oxidases (GA2oxs).[11] Some GA2oxs use 19-carbon Gibberellins as substrates, while other use C20-GAs.[27][28] Cytochrome P450 mono-oxygenase, encoded by elongated uppermost internode (eui), converts Gibberellins into 16α,17-epoxides.[29] Rice eui mutants amass bioactive Gibberellins at high levels, which suggests cytochrome P450 mono-oxygenase is a main enzyme responsible for deactivation GA in rice.[29] The Gamt1 and gamt2 genes encode enzymes that methylate the C-6 carboxyl group of GAs.[30] In a gamt1 and gamt2 mutant, concentrations of GA in developing seeds is increased.[30]
Homeostasis
editFeedback and feedforward regulation maintains the levels of bioactive Gibberellins in plants.[31][32] Levels of AtGA20ox1 and AtGA3ox1 expression are increased in a Gibberellin deficient environment, and decreased after the addition of bioactive GAs,[14][33][34][35][36] Conversely, expression of the Gibberellin deactivation genes AtGA2ox1 and AtGA2ox2 is increased with addition of Gibberellins.[27]
Regulation
editRegulation by other hormones
editThe auxin indole-3-acetic acid (IAA) regulates concentration of GA1 in elongating internodes in peas.[37] Removal of IAA by removal of the apical bud, the auxin source, reduces the concentration of GA1, and reintroduction of IAA reverses these effects to increase the concentration of GA1.[37] This has also been observed in tobacco plants.[38] Auxin increases GA 3-oxidation and decreases GA 2-oxidation in barley.[39] Auxin also regulates GA biosynthesis during fruit development in peas.[40] These discoveries in different plant species suggest the auxin regulation of GA metabolism may be a universal mechanism.
Ethylene decreases the concentration of bioactive GAs.[41]
Regulation by environmental factors
editRecent evidence suggests fluctuations in GA concentration influence light-regulated seed germination, photomorphogenesis during de-etiolation, and photoperiod regulation of stem elongation and flowering.[8] Microarray analysis showed about one fourth cold-responsive genes are related to GA-regulated genes, which suggests GA influences response to cold temperatures.[15] Plants reduce growth rate when exposed to stress. A relationship between GA levels and amount of stress experienced has been suggested in barley.[42]
Role in seed development
editBioactive GAs and abscisic acid (ABA) levels have an inverse relationship and regulate seed development and germination.[43][44] Levels of FUS3, an Arabidopsis transcription factor, are upregulated by ABA and downregulated by Giberellins, which suggests that there is a regulation loop that establishes the balance of Gibberellins and Abscisic Acid.[45]
In the practice, this means that farmers can alter this balance to make all fruits mature a little later, at a same time, or 'glue' the fruit in the trees until the harvest day (because ABA participates in the maturation of the fruits, and many crops mature and drop a few fruits a day for several weeks, that is undesirable for markets).
Signalling mechanism
editReceptor
editIn the early 1990s, there were several lines of evidence that suggested the existence of a GA receptor in oat seeds located at the plasma membrane. However, despite intensive research, to date, no membrane-bound GA receptor has been isolated. This, along with the discovery of a soluble receptor, GA insensitive dwarf 1 (GID1) has led many to doubt that a membrane-bound receptor exists.[1]
GID1 was first identified in rice[46] and in Arabidopsis there are three orthologs of GID1, AtGID1a, b, and c.[1] GID1s have a high affinity for bioactive GAs.[46] GA binds to a specific binding pocket on GID1; the C3-hydroxyl on GA makes contact with tyrosine-31 in the GID1 binding pocket.[47][48] GA binding to GID1 causes changes in GID1 structure, causing a 'lid' on GID1 to cover the GA binding pocket. The movement of this lid results in the exposure of a surface which enables the binding of GID1 to DELLA proteins.[47][48]
DELLA proteins: Repression of a repressor
editDELLA proteins (such as SLR1 in rice or GAI and RGA in Arabidopsis) are repressors of plant development, characterized by the presence of a DELLA motif (aspartate-glutamate-leucine-leucine-alanine or D-E-L-L-A in the single letter amino acid code).[49]
DELLAs inhibit seed germination, seed growth, flowering and GA reverses these effects.[50] When Gibberellins bind to the GID1 receptor, it enhances the interaction between GID1 and DELLA proteins, forming a GA-GID1-DELLA complex. In that complex it is thought that the structure of DELLA proteins experience changes, enabling their binding to F-box proteins for their degradation.[51][49][52] F-box proteins (SLY1 in Arabidopsis or GID2 in rice) catalyse the addition of ubiquitin to their targets.[51] Adding ubiquitin to DELLA proteins promotes their degradation via the 26S-proteosome.[49] This releases cells from DELLAs repressive effects.
Targets of DELLA proteins
editTranscription factors
editThe first targets of DELLA proteins identified were Phytochrome Interacting Factors (PIFs). PIFs are transcription factors that negatively regulate light signalling and are strong promoters of elongation growth. In the presence of GA, DELLAs are degraded and this then allows PIFs to promote elongation.[53] It was later found that DELLAs repress a large number of other transcription factors, among which are positive regulators of auxin, brassinosteroid and ethylene signalling.[54][55] DELLAs can repress transcription factors either by stopping their binding to DNA or by promoting their degradation.[53]
Prefoldins and microtubule assembly
editIn addition to repressing transcription factors, DELLAs also bind to prefoldins (PFDs). PFDs are molecular chaperones (they assist in the folding of other proteins) that work in the cytosol, but when DELLAs bind to them are restricted to the nucleus. An important function of PFDs is to assist in the folding of β-tubulin, a vital component of the cytoskeleton in the form of microtubules. As such, in the absence of Gibberellins (high level of DELLA proteins), PFDs reduce its activity, leading to a lower cellular pool of β-tubulin. When GA is present the DELLAs are degraded, PFDs can move to the cytosol and assist in the folding of β-tubulin. As such, GA allows for re-organisation of the cytoskeleton, and the elongation of cells.[56]
Microtubules are also required for the trafficking of membrane vesicles, that is needed for the correct positioning of several hormone transporters. One of the most well characterized hormone transporters are PIN proteins, which are responsible for the movement of the hormone auxin between cells. In the absence of Gibberellins, DELLA proteins reduce the levels of microtubules and thereby inhibit membrane vesicle trafficking. This reduces the level of PIN proteins at the cell membrane, and the level of auxin in the cell. GA reverses this process and allows for PIN protein trafficking to the cell membrane to enhance the level of auxin in the cell.[57]
References
edit- ^ a b c d Hedden P, Sponsel V (2015). "A Century of Gibberellin Research". Journal of Plant Growth Regulation. 34 (4): 740–60. doi:10.1007/s00344-015-9546-1. PMC 4622167. PMID 26523085.
- ^ Spielmeyer W, Ellis MH, Chandler PM (June 2002). "Semidwarf (sd-1), "green revolution" rice, contains a defective gibberellin 20-oxidase gene". Proceedings of the National Academy of Sciences of the United States of America. 99 (13): 9043–8. Bibcode:2002PNAS...99.9043S. doi:10.1073/pnas.132266399. PMC 124420. PMID 12077303.
- ^ "Norman Borlaug: A Billion Lives Saved". www.agbioworld.org. Retrieved 2018-05-11.
- ^ a b Campbell N, Reec JB (2002). Biology (6th ed.). San Francisco: Benjamin Cummings. ISBN 9780805366242.
- ^ a b c Sponsel, Valerie M.; Hedden, Peter (2010), Davies, Peter J. (ed.), "Gibberellin Biosynthesis and Inactivation", Plant Hormones, Dordrecht: Springer Netherlands, pp. 63–94, doi:10.1007/978-1-4020-2686-7_4, ISBN 978-1-4020-2684-3, retrieved 2022-01-29
- ^ a b Hedden, Peter (2020-11-23). "The Current Status of Research on Gibberellin Biosynthesis". Plant and Cell Physiology. 61 (11): 1832–1849. doi:10.1093/pcp/pcaa092. ISSN 1471-9053. PMC 7758035. PMID 32652020.
- ^ a b "Gibberellins". AccessScience. doi:10.1036/1097-8542.289000.
- ^ a b c d e f g h i j Yamaguchi S (2008). "Gibberellin metabolism and its regulation". Annual Review of Plant Biology. 59: 225–51. doi:10.1146/annurev.arplant.59.032607.092804. PMID 18173378.
- ^ MacMillan J (December 2001). "Occurrence of Gibberellins in Vascular Plants, Fungi, and Bacteria". Journal of Plant Growth Regulation. 20 (4): 387–442. doi:10.1007/s003440010038. PMID 11986764. S2CID 44504525.
- ^ Davies PJ. "Plant growth". AccessScience. doi:10.1036/1097-8542.523000.
- ^ a b c d Hedden P, Thomas SG (May 2012). "Gibberellin biosynthesis and its regulation". The Biochemical Journal. 444 (1): 11–25. doi:10.1042/BJ20120245. PMID 22533671. S2CID 25627726.
- ^ Koornneef M, van der Veen JH (November 1980). "Induction and analysis of gibberellin sensitive mutants in Arabidopsis thaliana (L.) heynh". Theoretical and Applied Genetics. 58 (6): 257–63. doi:10.1007/BF00265176. PMID 24301503. S2CID 22824299.
- ^ Mitchum MG, Yamaguchi S, Hanada A, Kuwahara A, Yoshioka Y, Kato T, Tabata S, Kamiya Y, Sun TP (March 2006). "Distinct and overlapping roles of two gibberellin 3-oxidases in Arabidopsis development". The Plant Journal. 45 (5): 804–18. doi:10.1111/j.1365-313X.2005.02642.x. PMID 16460513.
- ^ a b Yamaguchi S, Smith MW, Brown RG, Kamiya Y, Sun T (December 1998). "Phytochrome regulation and differential expression of gibberellin 3beta-hydroxylase genes in germinating Arabidopsis seeds". The Plant Cell. 10 (12): 2115–26. doi:10.1105/tpc.10.12.2115. PMC 143973. PMID 9836749.
- ^ a b Yamauchi Y, Ogawa M, Kuwahara A, Hanada A, Kamiya Y, Yamaguchi S (February 2004). "Activation of gibberellin biosynthesis and response pathways by low temperature during imbibition of Arabidopsis thaliana seeds". The Plant Cell. 16 (2): 367–78. doi:10.1105/tpc.018143. PMC 341910. PMID 14729916.
- ^ Coles JP, Phillips AL, Croker SJ, García-Lepe R, Lewis MJ, Hedden P (March 1999). "Modification of gibberellin production and plant development in Arabidopsis by sense and antisense expression of gibberellin 20-oxidase genes". The Plant Journal. 17 (5): 547–56. doi:10.1046/j.1365-313X.1999.00410.x. PMID 10205907.
- ^ Huang S, Raman AS, Ream JE, Fujiwara H, Cerny RE, Brown SM (November 1998). "Overexpression of 20-oxidase confers a gibberellin-overproduction phenotype in Arabidopsis". Plant Physiology. 118 (3): 773–81. doi:10.1104/pp.118.3.773. PMC 34787. PMID 9808721.
- ^ a b Kaneko M, Itoh H, Inukai Y, Sakamoto T, Ueguchi-Tanaka M, Ashikari M, Matsuoka M (July 2003). "Where do gibberellin biosynthesis and gibberellin signaling occur in rice plants?". The Plant Journal. 35 (1): 104–15. doi:10.1046/j.1365-313X.2003.01780.x. PMID 12834406.
- ^ Itoh H, Tanaka-Ueguchi M, Kawaide H, Chen X, Kamiya Y, Matsuoka M (October 1999). "The gene encoding tobacco gibberellin 3beta-hydroxylase is expressed at the site of GA action during stem elongation and flower organ development". The Plant Journal. 20 (1): 15–24. doi:10.1046/j.1365-313X.1999.00568.x. PMID 10571861.
- ^ Rojas MC, Hedden P, Gaskin P, Tudzynski B (May 2001). "The P450-1 gene of Gibberella fujikuroi encodes a multifunctional enzyme in gibberellin biosynthesis". Proceedings of the National Academy of Sciences of the United States of America. 98 (10): 5838–43. Bibcode:2001PNAS...98.5838R. doi:10.1073/pnas.091096298. PMC 33300. PMID 11320210.
- ^ Kawaide H, Imai R, Sassa T, Kamiya Y (August 1997). "Ent-kaurene synthase from the fungus Phaeosphaeria sp. L487. cDNA isolation, characterization, and bacterial expression of a bifunctional diterpene cyclase in fungal gibberellin biosynthesis". The Journal of Biological Chemistry. 272 (35): 21706–12. doi:10.1074/jbc.272.35.21706. PMID 9268298.
- ^ Toyomasu T, Kawaide H, Ishizaki A, Shinoda S, Otsuka M, Mitsuhashi W, Sassa T (March 2000). "Cloning of a full-length cDNA encoding ent-kaurene synthase from Gibberella fujikuroi: functional analysis of a bifunctional diterpene cyclase". Bioscience, Biotechnology, and Biochemistry. 64 (3): 660–4. doi:10.1271/bbb.64.660. PMID 10803977.
- ^ Tudzynski B, Kawaide H, Kamiya Y (September 1998). "Gibberellin biosynthesis in Gibberella fujikuroi: cloning and characterization of the copalyl diphosphate synthase gene". Current Genetics. 34 (3): 234–40. doi:10.1007/s002940050392. PMID 9745028. S2CID 3021994.
- ^ Hedden P, Phillips AL, Rojas MC, Carrera E, Tudzynski B (December 2001). "Gibberellin Biosynthesis in Plants and Fungi: A Case of Convergent Evolution?". Journal of Plant Growth Regulation. 20 (4): 319–331. doi:10.1007/s003440010037. PMID 11986758. S2CID 25623658.
- ^ Kawaide H (March 2006). "Biochemical and molecular analyses of gibberellin biosynthesis in fungi". Bioscience, Biotechnology, and Biochemistry. 70 (3): 583–90. doi:10.1271/bbb.70.583. PMID 16556972. S2CID 20952424.
- ^ Lopes AL, Silva DN, Rodrigues C, Costa JL, Machado MP, Penha RO, Biasi LA, Ricardo C (2013). "Gibberellic acid fermented extract obtained by solid-state fermentation using citric pulp by Fusarium moniliforme: Influence on Lavandula angustifolia Mill. cultivated in vitro". Pak J Bot. 45: 2057–2064.
- ^ a b Thomas SG, Phillips AL, Hedden P (April 1999). "Molecular cloning and functional expression of gibberellin 2- oxidases, multifunctional enzymes involved in gibberellin deactivation". Proceedings of the National Academy of Sciences of the United States of America. 96 (8): 4698–703. Bibcode:1999PNAS...96.4698T. doi:10.1073/pnas.96.8.4698. PMC 16395. PMID 10200325.
- ^ Schomburg FM, Bizzell CM, Lee DJ, Zeevaart JA, Amasino RM (January 2003). "Overexpression of a novel class of gibberellin 2-oxidases decreases gibberellin levels and creates dwarf plants". The Plant Cell. 15 (1): 151–63. doi:10.1105/tpc.005975. PMC 143488. PMID 12509528.
- ^ a b Zhu Y, Nomura T, Xu Y, Zhang Y, Peng Y, Mao B, Hanada A, Zhou H, Wang R, Li P, Zhu X, Mander LN, Kamiya Y, Yamaguchi S, He Z (February 2006). "ELONGATED UPPERMOST INTERNODE encodes a cytochrome P450 monooxygenase that epoxidizes gibberellins in a novel deactivation reaction in rice". The Plant Cell. 18 (2): 442–56. doi:10.1105/tpc.105.038455. PMC 1356550. PMID 16399803.
- ^ a b Varbanova M, Yamaguchi S, Yang Y, McKelvey K, Hanada A, Borochov R, Yu F, Jikumaru Y, Ross J, Cortes D, Ma CJ, Noel JP, Mander L, Shulaev V, Kamiya Y, Rodermel S, Weiss D, Pichersky E (January 2007). "Methylation of gibberellins by Arabidopsis GAMT1 and GAMT2". The Plant Cell. 19 (1): 32–45. doi:10.1105/tpc.106.044602. PMC 1820973. PMID 17220201.
- ^ Hedden P, Phillips AL (December 2000). "Gibberellin metabolism: new insights revealed by the genes". Trends in Plant Science. 5 (12): 523–30. doi:10.1016/S1360-1385(00)01790-8. PMID 11120474.
- ^ Olszewski N, Sun TP, Gubler F (2002). "Gibberellin signaling: biosynthesis, catabolism, and response pathways". The Plant Cell. 14 Suppl (Suppl): S61–80. doi:10.1105/tpc.010476. PMC 151248. PMID 12045270.
- ^ Chiang HH, Hwang I, Goodman HM (February 1995). "Isolation of the Arabidopsis GA4 locus". The Plant Cell. 7 (2): 195–201. doi:10.1105/tpc.7.2.195. PMC 160775. PMID 7756830.
- ^ Matsushita A, Furumoto T, Ishida S, Takahashi Y (March 2007). "AGF1, an AT-hook protein, is necessary for the negative feedback of AtGA3ox1 encoding GA 3-oxidase". Plant Physiology. 143 (3): 1152–62. doi:10.1104/pp.106.093542. PMC 1820926. PMID 17277098.
- ^ Phillips AL, Ward DA, Uknes S, Appleford NE, Lange T, Huttly AK, Gaskin P, Graebe JE, Hedden P (July 1995). "Isolation and expression of three gibberellin 20-oxidase cDNA clones from Arabidopsis". Plant Physiology. 108 (3): 1049–57. doi:10.1104/pp.108.3.1049. PMC 157456. PMID 7630935.
- ^ Xu YL, Li L, Gage DA, Zeevaart JA (May 1999). "Feedback regulation of GA5 expression and metabolic engineering of gibberellin levels in Arabidopsis". The Plant Cell. 11 (5): 927–36. doi:10.1105/tpc.11.5.927. PMC 144230. PMID 10330476.
- ^ a b Ross JJ, O'Neill DP, Smith JJ, Kerckhoffs LH, Elliott RC (March 2000). "Evidence that auxin promotes gibberellin A1 biosynthesis in pea". The Plant Journal. 21 (6): 547–52. doi:10.1046/j.1365-313x.2000.00702.x. PMID 10758505.
- ^ Wolbang CM, Ross JJ (November 2001). "Auxin promotes gibberellin biosynthesis in decapitated tobacco plants". Planta. 214 (1): 153–7. Bibcode:2001Plant.214..153W. doi:10.1007/s004250100663. PMID 11762165. S2CID 31185063.
- ^ Wolbang CM, Chandler PM, Smith JJ, Ross JJ (February 2004). "Auxin from the developing inflorescence is required for the biosynthesis of active gibberellins in barley stems". Plant Physiology. 134 (2): 769–76. doi:10.1104/pp.103.030460. PMC 344552. PMID 14730077.
- ^ Ngo P, Ozga JA, Reinecke DM (July 2002). "Specificity of auxin regulation of gibberellin 20-oxidase gene expression in pea pericarp". Plant Molecular Biology. 49 (5): 439–48. doi:10.1023/A:1015522404586. PMID 12090620. S2CID 22530544.
- ^ Achard P, Baghour M, Chapple A, Hedden P, Van Der Straeten D, Genschik P, Moritz T, Harberd NP (April 2007). "The plant stress hormone ethylene controls floral transition via DELLA-dependent regulation of floral meristem-identity genes". Proceedings of the National Academy of Sciences of the United States of America. 104 (15): 6484–9. Bibcode:2007PNAS..104.6484A. doi:10.1073/pnas.0610717104. PMC 1851083. PMID 17389366.
- ^ Vettakkorumakankav NN, Falk D, Saxena P, Fletcher RA (1999). "A Crucial Role for Gibberellins in Stress Protection of Plants". Plant and Cell Physiology. 40 (5): 542–548. doi:10.1093/oxfordjournals.pcp.a029575.
- ^ Batge SL, Ross JJ, Reid JB (1999). "Abscisic acid levels in seeds of the gibberellin-deficient mutant lh-2 of pea (Pisum sativum)". Physiologia Plantarum. 195 (3): 485–490. doi:10.1034/j.1399-3054.1999.105313.x.
- ^ White CN, Proebsting WM, Hedden P, Rivin CJ (April 2000). "Gibberellins and seed development in maize. I. Evidence that gibberellin/abscisic acid balance governs germination versus maturation pathways". Plant Physiology. 122 (4): 1081–8. doi:10.1104/pp.122.4.1081. PMC 58942. PMID 10759503.
- ^ Gazzarrini S, Tsuchiya Y, Lumba S, Okamoto M, McCourt P (September 2004). "The transcription factor FUSCA3 controls developmental timing in Arabidopsis through the hormones gibberellin and abscisic acid". Developmental Cell. 7 (3): 373–85. doi:10.1016/j.devcel.2004.06.017. PMID 15363412.
- ^ a b Ueguchi-Tanaka M, Nakajima M, Katoh E, Ohmiya H, Asano K, Saji S, Hongyu X, Ashikari M, Kitano H, Yamaguchi I, Matsuoka M (July 2007). "Molecular interactions of a soluble gibberellin receptor, GID1, with a rice DELLA protein, SLR1, and gibberellin". The Plant Cell. 19 (7): 2140–55. doi:10.1105/tpc.106.043729. PMC 1955699. PMID 17644730.
- ^ a b Murase K, Hirano Y, Sun TP, Hakoshima T (November 2008). "Gibberellin-induced DELLA recognition by the gibberellin receptor GID1". Nature. 456 (7221): 459–63. Bibcode:2008Natur.456..459M. doi:10.1038/nature07519. PMID 19037309. S2CID 16280595.
- ^ a b Shimada A, Ueguchi-Tanaka M, Nakatsu T, Nakajima M, Naoe Y, Ohmiya H, Kato H, Matsuoka M (November 2008). "Structural basis for gibberellin recognition by its receptor GID1". Nature. 456 (7221): 520–3. Bibcode:2008Natur.456..520S. doi:10.1038/nature07546. PMID 19037316. S2CID 205215510.
- ^ a b c Davière JM, Achard P (March 2013). "Gibberellin signaling in plants". Development. 140 (6): 1147–51. doi:10.1242/dev.087650. PMID 23444347.
- ^ Achard P, Genschik P (2009). "Releasing the brakes of plant growth: how GAs shutdown DELLA proteins". Journal of Experimental Botany. 60 (4): 1085–92. doi:10.1093/jxb/ern301. PMID 19043067.
- ^ a b Lechner E, Achard P, Vansiri A, Potuschak T, Genschik P (December 2006). "F-box proteins everywhere". Current Opinion in Plant Biology. 9 (6): 631–8. Bibcode:2006COPB....9..631L. doi:10.1016/j.pbi.2006.09.003. PMID 17005440.
- ^ McGinnis KM, Thomas SG, Soule JD, Strader LC, Zale JM, Sun TP, Steber CM (May 2003). "The Arabidopsis SLEEPY1 gene encodes a putative F-box subunit of an SCF E3 ubiquitin ligase". The Plant Cell. 15 (5): 1120–30. doi:10.1105/tpc.010827. PMC 153720. PMID 12724538.
- ^ a b Zheng Y, Gao Z, Zhu Z (October 2016). "DELLA-PIF Modules: Old Dogs Learn New Tricks". Trends in Plant Science. 21 (10): 813–815. doi:10.1016/j.tplants.2016.08.006. PMID 27569991.
- ^ Oh E, Zhu JY, Bai MY, Arenhart RA, Sun Y, Wang ZY (May 2014). "Cell elongation is regulated through a central circuit of interacting transcription factors in the Arabidopsis hypocotyl". eLife. 3. doi:10.7554/eLife.03031. PMC 4075450. PMID 24867218.
- ^ Marín-de la Rosa N, Sotillo B, Miskolczi P, Gibbs DJ, Vicente J, Carbonero P, Oñate-Sánchez L, Holdsworth MJ, Bhalerao R, Alabadí D, Blázquez MA (October 2014). "Large-scale identification of gibberellin-related transcription factors defines group VII ETHYLENE RESPONSE FACTORS as functional DELLA partners". Plant Physiology. 166 (2): 1022–32. doi:10.1104/pp.114.244723. PMC 4213073. PMID 25118255.
- ^ Locascio A, Blázquez MA, Alabadí D (May 2013). "Dynamic regulation of cortical microtubule organization through prefoldin-DELLA interaction". Current Biology. 23 (9): 804–9. Bibcode:2013CBio...23..804L. doi:10.1016/j.cub.2013.03.053. hdl:10251/66422. PMID 23583555.
- ^ Salanenka Y, Verstraeten I, Löfke C, Tabata K, Naramoto S, Glanc M, Friml J (April 2018). "Gibberellin DELLA signaling targets the retromer complex to redirect protein trafficking to the plasma membrane". Proceedings of the National Academy of Sciences of the United States of America. 115 (14): 3716–3721. Bibcode:2018PNAS..115.3716S. doi:10.1073/pnas.1721760115. PMC 5889667. PMID 29463731.
External links
edit- Gibberellin in the Pesticide Properties DataBase (PPDB)