Auxin Metabolism and Function in the Multicellular Brown Alga<i>Ectocarpus siliculosus</i>

Bail, Aude Le; Billoud, Bernard; Kowalczyk, Nathalie; Kowalczyk, Mariusz; Gicquel, Morgane; Panse, Sophie Le; Stewart, S.; Scornet, Delphine; Cock, J. Mark; Ljung, Karin; Charrier, Bénédicte

doi:10.1104/pp.109.149708

Cited by 103 publications

(122 citation statements)

References 57 publications

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“…The recent identification of auxin and its proposed actions in a brown algal model, Ectocarpus siliculosus (Le Bail et al 2010), may lend support to the latter hypothesis. However, this raises the question of how the systems were recruited in different phylogenetic groups (e.g.…”

Section: Discussionmentioning

confidence: 66%

“…Lau et al (2009) reviewed the evidence that auxin can have physiological effects on algal growth, as well as evidence to the contrary, and concluded by doubting the functional relevance of auxin in algae, suggesting instead that IAA may simply be a byproduct of tryptophan. However, a recent paper on the brown alga E. siliculosus suggests a role for IAA in development, although the response pathway appears to be different to that in vascular plants ( Le Bail et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Consistent with that, Rensing et al (2008) reported that genes thought to be related to auxin homeostasis were not found in the genomes of the aquatic unicellular green algae Ostreococcus tauri, Ostreococcus lucimarinus and Chlamydomonas reinhardtii. However, IAA has been identified in multicellular algae, including Fucus distichus and Ectocarpus siliculosus (Basu et al 2002;Le Bail et al 2010), and importantly, Nitella spp. (Sztein et al 2000).…”

Section: Introductionmentioning

confidence: 99%

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Evolution of growth-promoting plant hormones

Ross

Reid

2010

Functional Plant Biol.

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Abstract. The plant growth hormones auxin, gibberellins (GAs) and brassinosteroids (BRs) are major determinants of plant growth and development. Recently, key signalling components for these hormones have been identified in vascular plants and, at least for the GAs and BRs, biosynthetic pathways have been clarified. The genome sequencing of a range of species, including a few non-flowering plants, has allowed insight into the evolution of the hormone systems. It appears that the moss Physcomitrella patens can respond to auxin and contains key elements of the auxin signalling pathway, although there is some doubt as to whether it shows a fully developed rapid auxin response. On the other hand, P. patens does not show a GA response, even though it contains genes for components of GA signalling. The GA response system appears to be more advanced in the lycophyte Selaginella moellendorffii than in P. patens. Signalling systems for BRs probably arose after the evolutionary divergence of the mosses and vascular plants, although detailed information is limited. Certainly, the processes affected by the growth hormones (e.g. GAs) can differ in the different plant groups, and there is evidence that with the evolution of the angiosperms, the hormone systems have become more complex at the gene level. The intermediate nature of mosses in terms of overall hormone biology allows us to speculate about the possible relationship between the evolution of plant growth hormones and the evolution of terrestrial vascular plants in general.

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Section: Discussionmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evolution of growth-promoting plant hormones

Ross

Reid

2010

Functional Plant Biol.

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“…The best explored putative phytohormones in brown algae are auxins, which exert a growth-promoting function in land plants, but most research has concentrated on the effects of indole-3-acetic (IAA) on growth and cell polarity, rather than its influence on fertility (Basu et al 2002, Lin and Stekoll 2007, Le Bail et al 2010. Auxin was shown to promote growth and inhibit sporogenesis when applied exogenously to Saccharina japonica, and the auxin oxidase activity in sporophyllous tissue was shown to be dramatically increased (Kai et al 2006).…”

Section: Endogenous Signalingmentioning

confidence: 99%

Seaweed reproductive biology: environmental and genetic controls

et al. 2017

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Knowledge of life cycle progression and reproduction of seaweeds transcends pure academic interest. Successful and sustainable seaweed exploitation and domestication will indeed require excellent control of the factors controlling growth and reproduction. The relative dominance of the ploidy-phases and their respective morphologies, however, display tremendous diversity. Consequently, the ecological and endogenous factors controlling life cycles are likely to be equally varied. A vast number of research papers addressing theoretical, ecological and physiological aspects of reproduction have been published over the years. Here, we review the current knowledge on reproductive strategies, trade-offs of reproductive effort in natural populations, and the environmental and endogenous factors controlling reproduction. Given that the majority of ecophysiological studies predate the "-omics" era, we examine the extent to which this knowledge of reproduction has been, or can be, applied to further our knowledge of life cycle control in seaweeds.

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“…It is likely that elements of this module were present in unicellular plants since the cell walls of unicellular algae are not mechanically isotropic and manifest morphologies that are distinctly non-spherical. In addition, endogenous auxin has been identified in some multicellular algae (Boot et al, 2012), even in lineages that are not related to the green algal and land plant clade (e.g., the brown alga Ectocarpus siliculosus, in which auxin might play a crucial role in the elongation of the filamentous thallus; Le Bail et al, 2010). Likewise, the effects of auxins on the dynamics of the cytoskeleton of unicellular charophycean algae appear to be similar to those observed for embryophytes (Jin et al, 2008).…”

Section: Polarity and The Determination Of The Apical-basal Axis (Pol)mentioning

confidence: 77%

Dynamical patterning modules in plant development and evolution

Hernández-Hernández

Niklas²,

Newman³

et al. 2012

Int. J. Dev. Biol.

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Broad comparative studies at the level of developmental processes are necessary to fully understand the evolution of development and phenotypes. The concept of dynamical patterning modules (DPMs) provides a framework for studying developmental processes in the context of wide comparative analyses. DPMs are defined as sets of ancient, conserved gene products and molecular networks, in conjunction with the physical morphogenetic and patterning processes they mobilize in the context of multicellularity. The theoretical framework based on DPMs originally postulated that each module generates a key morphological motif of the basic animal body plans and organ forms. Here, we use a previous definition of the plant multicellular body plan and describe the basic DPMs underlying the main features of plant development. For each DPM, we identify characteristic molecules and molecular networks, and when possible, the physical processes they mobilize. We then briefly review the phyletic distribution of these molecules across the various plant lineages. Although many of the basic plant DPMs are significantly different from those of animals, the framework established by a DPM perspective on plant development is essential for comparative analyses aiming to provide a truly mechanistic explanation for organic development across all plant and animal lineages.

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Auxin Metabolism and Function in the Multicellular Brown AlgaEctocarpus siliculosus

Cited by 103 publications

References 57 publications

Evolution of growth-promoting plant hormones

Evolution of growth-promoting plant hormones

Seaweed reproductive biology: environmental and genetic controls

Dynamical patterning modules in plant development and evolution

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