Niek Stortenbeker scite author profile

The family of Small Auxin Up-Regulated genes (SAURs) is a family of auxin-responsive genes with about 60 to 140 members in most higher plant species. Despite the early discovery of their auxin responsiveness, their function and mode of action remained unknown for a long time. In recent years, the importance of SAUR genes for the regulation of dynamic and adaptive growth, and the molecular mechanisms by which SAUR proteins act are increasingly understood. SAURs play a central role in auxin-induced acid growth, but can also act independently of auxin, tissue-specifically regulated by various other hormone pathways and transcription factors. In this review, we summarize the recent advances in SAUR gene characterization in Arabidopsis and other plant species. We particularly elaborate on their capacity to fine tune growth in response to internal and external signals, and discuss the breakthroughs in understanding the mode of action of the SAURs in relation to their complex regulation.

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Divergent regulation of Arabidopsis SAUR genes: a focus on the SAUR10-clade

Mourik

Dijk

Stortenbeker

et al. 2017

BMC Plant Biol

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Background Small Auxin-Upregulated RNA (SAUR) genes encode growth regulators that induce cell elongation. Arabidopsis contains more than 70 SAUR genes, of which the growth-promoting function has been unveiled in seedlings, while their role in other tissues remained largely unknown. Here, we focus on the regulatory regions of Arabidopsis SAUR genes, to predict the processes in which they play a role, and understand the dynamics of plant growth.ResultsIn this study, we characterized in detail the entire SAUR10-clade: SAUR8, SAUR9, SAUR10, SAUR12, SAUR16, SAUR50, SAUR51 and SAUR54. Overexpression analysis revealed that the different proteins fulfil similar functions, while the SAUR expression patterns were highly diverse, showing expression throughout plant development in a variety of tissues. In addition, the response to application of different hormones largely varied between the different genes. These tissue-specific and hormone-specific responses could be linked to transcription factor binding sites using in silico analyses. These analyses also supported the existence of two groups of SAURs in Arabidopsis: Class I genes can be induced by combinatorial action of ARF-BZR-PIF transcription factors, while Class II genes are not regulated by auxin.Conclusions SAUR10-clade genes generally induce cell-elongation, but exhibit diverse expression patterns and responses to hormones. Our experimental and in silico analyses suggest that transcription factors involved in plant development determine the tissue specific expression of the different SAUR genes, whereas the amplitude of this expression can often be controlled by hormone response transcription factors. This allows the plant to fine tune growth in a variety of tissues in response to internal and external signals.Electronic supplementary materialThe online version of this article (10.1186/s12870-017-1210-4) contains supplementary material, which is available to authorized users.

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Enrichment and characterization of a nitric oxide-reducing microbial community in a continuous bioreactor

et al. 2023

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Nitric oxide (NO) is a highly reactive and climate-active molecule and a key intermediate in the microbial nitrogen cycle. Despite its role in the evolution of denitrification and aerobic respiration, high redox potential and capacity to sustain microbial growth, our understanding of NO-reducing microorganisms remains limited due to the absence of NO-reducing microbial cultures obtained directly from the environment using NO as a substrate. Here, using a continuous bioreactor and a constant supply of NO as the sole electron acceptor, we enriched and characterized a microbial community dominated by two previously unknown microorganisms that grow at nanomolar NO concentrations and survive high amounts (>6 µM) of this toxic gas, reducing it to N2 with little to non-detectable production of the greenhouse gas nitrous oxide. These results provide insight into the physiology of NO-reducing microorganisms, which have pivotal roles in the control of climate-active gases, waste removal, and evolution of nitrate and oxygen respiration.

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