Auxin and Light Control of Adventitious Rooting in Arabidopsis Require ARGONAUTE1

Sorin, Céline; Bussell, John D.; Camus, Isabelle; Ljung, Karin; Kowalczyk, Mariusz; Geiss, Gaia; McKhann, Heather I.; Garcion, Christophe; Vaucheret, Hervé; Sandberg, Göran; Bellini, Catherine

doi:10.1105/tpc.105.031625

Cited by 358 publications

(339 citation statements)

References 62 publications

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“…An Arabidopsis transgenic line overexpressing ARF17 developed fewer adventitious roots than wild-type plants, confirming the potential role of ARF genes in the regulation of adventitious root development by auxin (Sorin et al, 2005). It was shown that ARF17, a target of miR160, is a negative regulator, and ARF6 and ARF8, targets of miR167, are positive regulators of adventitious rooting.…”

Section: Genes Asociated With the Adventitious Root Formationmentioning

confidence: 72%

Auxin Control in the Formation of Adventitious Roots

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Bellini

2011

Not Bot Hort Agrobot Cluj

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Adventitious rooting is a complex process and a key step in the vegetative propagation of economically important woody, horticultural and agricultural species, playing an important role in the successful production of elite clones. The formation of adventitious roots is a quantitative genetic trait regulated by both environmental and endogenous factors. Among phytohormones, auxin plays an essential role in regulating roots development and it has been shown to be intimately involved in the process of adventitious rooting. Great progress has been made in elucidating the auxin-induced genes and auxin signaling pathway, especially in auxin response Aux/IAA and Auxin Response Factor gene families. Although some important aspects of adventitious and lateral rooting signaling have been revealed, the intricate signaling network remains poorly understood. This review summarizes some of the current knowledge on the physiological aspects of adventitious root formation and highlights the recent progress made in the identification of putative molecular players involved in the control of adventitious rooting. Despite much has been discovered regarding the effects and regulation of auxins on plant growth since the Darwin experiments, there is much that remains unknown.

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Section: Genes Asociated With the Adventitious Root Formationmentioning

confidence: 72%

Auxin Control in the Formation of Adventitious Roots

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Pamfil

Bellini

2011

Not Bot Hort Agrobot Cluj

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139

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“…miR164 regulates auxin signals for lateral root development by targeting NAC mRNA cleavage (Guo et al, 2005). miR167 regulates plant development by negatively regulating the expression of several AUXIN RESPONSE FACTORS (ARF), including ARF 2, ARF 3, ARF 4, ARF 10, ARF 16, and ARF 17 (Mallory et al, 2005;Sorin et al, 2005;Williams et al, 2005a;Yang et al, 2006). miRNAs regulate phase change in plants.…”

Section: Functions Of Micrornas In Plantsmentioning

confidence: 99%

MicroRNAs and their regulatory roles in animals and plants

Zhang

Wang

Pan

2006

Journal Cellular Physiology

490

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microRNAs (miRNAs) are an abundant class of newly identified endogenous non-protein-coding small RNAs. They exist in animals, plants, and viruses, and play an important role in gene silencing. Translational repression, mRNA cleavage, and mRNA decay initiated by miRNA-directed deadenylation of targeted mRNAs are three mechanisms of miRNA-guided gene regulation at the posttranscriptional levels. Many miRNAs are highly conserved in animals and plants, suggesting that they play an essential function in plants and animals. Lots of investigations indicate that miRNAs are involved in multiple biological processes, including stem cell differentiation, organ development, phase change, signaling, disease, cancer, and response to biotic and abiotic environmental stresses. This review provides a general background and current advance on the discovery, history, biogenesis, genomics, mechanisms, and functions of miRNAs.

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“…This adaptive mechanism involves suppressing lateral root initiation on the dry side of a root Bellini et al (2014) and formatting based on Hochholdinger et al (2004b). The original description of the mutant phenotypes detailed in the table can be found in: Boerjan et al (1995), Delarue et al (1998), Fukaki et al (2002), Sorin et al (2005), Sibout et al (2006), Dello Ioio et al (2007), and Negi et al (2010 …”

Section: Prebranch Site Formationmentioning

confidence: 99%

Branching Out in Roots: Uncovering Form, Function, and Regulation

et al. 2014

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Root branching is critical for plants to secure anchorage and ensure the supply of water, minerals, and nutrients. To date, research on root branching has focused on lateral root development in young seedlings. However, many other programs of postembryonic root organogenesis exist in angiosperms. In cereal crops, the majority of the mature root system is composed of several classes of adventitious roots that include crown roots and brace roots. In this Update, we initially describe the diversity of postembryonic root forms. Next, we review recent advances in our understanding of the genes, signals, and mechanisms regulating lateral root and adventitious root branching in the plant models Arabidopsis (Arabidopsis thaliana), maize (Zea mays), and rice (Oryza sativa). While many common signals, regulatory components, and mechanisms have been identified that control the initiation, morphogenesis, and emergence of new lateral and adventitious root organs, much more remains to be done. We conclude by discussing the challenges and opportunities facing root branching research.

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Auxin and Light Control of Adventitious Rooting in Arabidopsis Require ARGONAUTE1

Cited by 358 publications

References 62 publications

Auxin Control in the Formation of Adventitious Roots

Auxin Control in the Formation of Adventitious Roots

MicroRNAs and their regulatory roles in animals and plants

Branching Out in Roots: Uncovering Form, Function, and Regulation

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