Strigolactone regulates shoot development through a core signalling pathway

Bennett, Tom; Liang, Yueyang; Seale, Madeleine; Ward, Sally; Müller, Dörte; Leyser, Ottoline

doi:10.1242/bio.021402

Cited by 126 publications

(89 citation statements)

References 78 publications

(180 reference statements)

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“…On the one hand, strigolactones repress outgrowth of axillary buds by inducing the gene expression of specific TCP transcription factors in the buds, such as BRANCHED 1 ( BRC1 ) (Braun et al ; Dun et al ), and on the other hand, they can inhibit branching by triggering the removal of the PIN‐FORMED 1 (PIN1) auxin efflux proteins from the plasma membrane (Bennett et al ; Crawford et al ; Shinohara et al ). Both pathways probably act in parallel, because tir3‐1 mutant plants with a deficient PIN1 accumulation have no increased BRC1 expression levels and brc1‐2brc2‐1 double mutants have no altered PIN1 distribution or auxin flow (Bennett et al ). In addition to branching inhibition, an even more general role for strigolactones has been suggested in the shoot, such as branch angle influence, leaf margin serrations, internode elongation, leaf senescence and secondary growth processes (Gomez‐Roldan et al ; Umehara et al ; Agusti et al ; de Saint Germain et al ; Lauressergues et al ; Sang et al ; Yamada et al ; Ueda & Kusaba ).…”

Section: Strigolactones Versus Karrikin(‐like)s Let the Game Beginmentioning

confidence: 99%

“…In addition to branching inhibition, an even more general role for strigolactones has been suggested in the shoot, such as branch angle influence, leaf margin serrations, internode elongation, leaf senescence and secondary growth processes (Gomez‐Roldan et al ; Umehara et al ; Agusti et al ; de Saint Germain et al ; Lauressergues et al ; Sang et al ; Yamada et al ; Ueda & Kusaba ). Strigolactone signalling during shoot development has been shown to be regulated by both MAX2 and D14 and to depend on the degradation of SMXL6,SMXL7,SMXL8 proteins, but without requirement of other previously proposed MAX2 targets, such as BRASSINOSTEROID INSENSITIVE 1‐ETHYL METHANESULFONATE‐SUPPRESSOR1 (BES1) and DELLA (Bennett et al ). Recent studies in pea and rice demonstrated that D14 is a mobile signal for fine‐tuning axillary bud outgrowth.…”

Section: Strigolactones Versus Karrikin(‐like)s Let the Game Beginmentioning

confidence: 99%

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Strigolactones, karrikins and beyond

Cuyper

Struk

Braem

et al. 2017

Plant Cell & Environment

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The plant hormones strigolactones are synthesized from carotenoids and signal via the α/β hydrolase DWARF 14 (D14) and the F-box protein MORE AXILLARY GROWTH 2 (MAX2). Karrikins, molecules produced upon fire, share MAX2 for signalling, but depend on the D14 paralog KARRIKIN INSENSITIVE 2 (KAI2) for perception with strong evidence that the MAX2-KAI2 protein complex might also recognize so far unknown plant-made karrikin-like molecules. Thus, the phenotypes of the max2 mutants are the complex consequence of a loss of both D14-dependent and KAI2-dependent signalling, hence, the reason why some biological roles, attributed to strigolactones based on max2 phenotypes, could never be observed in d14 or in the strigolactone-deficient max3 and max4 mutants. Moreover, the broadly used synthetic strigolactone analog rac-GR24 has been shown to mimic strigolactone as well as karrikin(-like) signals, providing an extra level of complexity in the distinction of the unique and common roles of both molecules in plant biology. Here, a critical overview is provided of the diverse biological processes regulated by strigolactones and/or karrikins. These two growth regulators are considered beyond their boundaries, and the importance of the yet unknown karrikin-like molecules is discussed as well.

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Section: Strigolactones Versus Karrikin(‐like)s Let the Game Beginmentioning

confidence: 99%

Section: Strigolactones Versus Karrikin(‐like)s Let the Game Beginmentioning

confidence: 99%

Strigolactones, karrikins and beyond

Cuyper

Struk

Braem

et al. 2017

Plant Cell & Environment

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“…Although karrikins were instrumental in the discovery of KAI2 -not least because they are a potent activator of KAI2-dependent signalling, even in non-fire-prone plants -we now appreciate that KAI2 regulates some of the wide number of physiological processes that are dependent on MAX2. These include effects on seed germination and seedling development, as are well established, but effects on leaf development are also evident, at least in Arabidopsis (Waters et al 2012a(Waters et al , 2015bBennett et al 2016) (Fig. 2).…”

Section: Beyond Karrikins: What Else Does Kai2 Do?mentioning

confidence: 71%

“…D53 is another member of the SMXL family, all of which share similarity to the ClpB/HEAT SHOCK PROTEIN 100 (HSP100) class of heat shock proteins. In Arabidopsis, three D53 homologues (SMXL6, SMXL7 and SMXL8) act redundantly to mediate all tested strigolactonerelated components of MAX2 function (Soundappan et al 2015;Liang et al 2016;Bennett et al 2016). This redundancy might explain why suppressor screens for the increased shoot branching phenotype of max2 had not uncovered this protein family.…”

Section: : the Smxl Familymentioning

confidence: 99%

From little things big things grow: karrikins and new directions in plant development

Waters¹

2017

Functional Plant Biol.

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Abstract. Karrikins are a family of compounds generated via the incomplete combustion of plant matter. Since their discovery as seed germination stimulants in 2004, a great deal has been learned about the chemistry and the biological mode of action of karrikins. Much interest and progress have stemmed from the structural similarity of karrikins to that of strigolactones -the shoot branching hormone. This review will provide a historical account of some of the more significant discoveries in this area of plant biology. It will discuss how the study of these abiotic signalling molecules, combined with advances in our understanding of strigolactones, has led us towards the discovery of new mechanisms that regulate plant growth and development.

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“…MeCLA then binds and induces conformational changes to the D14 α/β‐fold hydrolase allowing the interaction with a SKP1‐CUL1‐F‐box‐protein (SCF)‐type ubiquitin ligase complex to transmit the SL signal via proteasomal degradation of negative regulators of SL signaling. An integral component of this complex, the MAX2 leucine rich F‐box protein, seems to be involved in the ubiquitination of putative transcriptional regulators controlling most of the SL‐dependent responses characterized so far, including members of the SUPPRESSOR OF MAX2 (SMAX1) and SMAX1‐LIKE families (Bennett et al., ; Jiang et al., ; Soundappan et al., ; Wang et al., ). However, the function and exact mechanism of action of most of these target proteins are still under debate.…”

Section: Introductionmentioning

confidence: 99%

Genetic dissection of cell wall defects and the strigolactone pathway in Arabidopsis

Ramírez

Pauly

2019

Plant Direct

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Defects in the biosynthesis and/or deposition of secondary plant cell wall polymers result in the collapse of xylem vessels causing a dwarfed plant stature and an altered plant architecture termed irregular xylem ( irx ) syndrome. For example, reduced xylan O ‐acetylation causes strong developmental defects and increased freezing tolerance. Recently, we demonstrated that the irx syndrome in the trichome birefringence‐like 29/eskimo1 ( tbl29/esk1 ) mutant is dependent on MORE AXILLARY GROWTH 4 ( MAX 4), a key enzyme in the biosynthesis of the phytohormone strigolactone ( SL ). In this report, we show that other xylan‐ and cellulose‐deficient secondary wall mutants exhibit increased freezing tolerance correlated with the irx syndrome. In addition, these phenotypes are also dependent on MAX 4, suggesting a more general interaction between secondary wall defects and SL biosynthesis. In contrast, MAX 4 does not play a role in developmental defects triggered by primary wall deficiencies, suggesting that the interaction is restricted to vascular tissue. Through a reverse genetics approach, the requirement of different components of the SL pathway impacting the irx syndrome in tbl29 was evaluated. Our results show that the tbl29 ‐associated irx phenotypes are dependent on the MAX 3 and MAX 4 enzymes, involved in the early steps of SL biosynthesis. In contrast, this signaling is independent on downstream enzymes in the biosynthesis and perception of SL such as MAX 1 and MAX 2.

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Strigolactone regulates shoot development through a core signalling pathway

Cited by 126 publications

References 78 publications

Strigolactones, karrikins and beyond

Strigolactones, karrikins and beyond

From little things big things grow: karrikins and new directions in plant development

Genetic dissection of cell wall defects and the strigolactone pathway in Arabidopsis

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