Differential Control of Ethylene Responses by<i>GREEN-RIPE</i>and<i>GREEN-RIPE LIKE1</i>Provides Evidence for Distinct Ethylene Signaling Modules in Tomato

Ma, Qian; Du, Wei; Brandizzí, Federica; Giovannoni, James J.; Barry, Cornelius S.

doi:10.1104/pp.112.205476

Cited by 36 publications

(30 citation statements)

References 78 publications

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“…Previously, phylogenetic analysis suggested that members of the RTE1 gene family from different species form two clades, AtRTE1/SlGR and AtRTH/SIGRL2 (Barry and Giovannoni, 2006;Ma et al, 2012). The AtRTE1/SlGR clade consists of the RTE1 homologs that regulate ethylene signal transduction, such as Arabidopsis RTE1, tomato GR and GRL1, and rice RTH1 (Zhang et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…The AtRTE1/SlGR clade consists of the RTE1 homologs that regulate ethylene signal transduction, such as Arabidopsis RTE1, tomato GR and GRL1, and rice RTH1 (Zhang et al, 2012). The AtRTH/ SIGRL2 clade includes AtRTH and SlGRL2, which have no apparent role in ethylene signaling (Resnick et al, 2006;Ma et al, 2012); petunia PhGRL2, which was proposed to regulate ethylene biosynthesis (Tan et al, 2014), and rice RTH3, whose function is unknown (Zhang et al, 2012). ZmRTL4 is more closely related to the AtRTH/SlGRL2 clade, while ZmRTL2 apparently belongs to the AtRTE1/SlGR clade (Supplemental Fig.…”

Section: Discussionmentioning

confidence: 99%

“…S3) and their functions are unknown. Phylogenetic analysis indicate that ZmRTL1, ZmRTL2, and ZmRTL3 belong to the AtRTE1/SlGR clade of the RTE1 gene family (Barry and Giovannoni, 2006;Ma et al, 2012) while ZmRTL4 is more closely related to the AtRTH/SlGRL2 clade (Supplemental Fig. S4) and therefore, we elected to determine the function of ZmRTL2 and ZmRTL4.…”

Section: Interaction Of Argos With Arabidopsis Rte1 and Maize Homologmentioning

confidence: 99%

“…Transgenic rice (Oryza sativa) plants overexpressing rice REVERSION-TO-ETHYLENE SENSITIVITY1 HOMOLOG1 also showed reduced ethylene responsiveness across a range of biological processes, such as leaf senescence, seedling leaf elongation and development, and coleoptile elongation as well as adventitious root development (Zhang et al, 2012). In the RTE1 gene family, some members, for example, Arabidopsis REVERSION-TO-ETHYLENE SENSITIVITY1 HOMOLOG (RTH) and tomato GRL2, do not appear to play the same role as RTE1 in ethylene signaling (Resnick et al, 2006;Ma et al, 2012). Rice RTH2 and RTH3 were not able to complement the Arabidopsis rte1-2 mutant when their overexpression was driven by the cauliflower mosaic virus 35S promoter (Zhang et al, 2012), but whether they modulate ethylene sensitivity in rice was not determined.…”

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confidence: 99%

“…Arabidopsis RTE1 reduces ethylene responsiveness in an ETR1-dependent manner when overexpressed in Arabidopsis (Resnick et al, 2006;Zhou et al, 2007). Similarly, overexpression of RTE1 tomato (Solanum lycopersicum) homologs GREEN-RIPE (GR) and GREEN-RIPE LIKE1 (GRL1), as well as ectopic expression of the dominant gain-of-function mutant allele Green-ripe (Gr), decreases ethylene response in tomato plants, as shown in seedlings, fruit, abscission zones, and petioles (Barry and Giovannoni, 2006;Ma et al, 2012). Transgenic rice (Oryza sativa) plants overexpressing rice REVERSION-TO-ETHYLENE SENSITIVITY1 HOMOLOG1 also showed reduced ethylene responsiveness across a range of biological processes, such as leaf senescence, seedling leaf elongation and development, and coleoptile elongation as well as adventitious root development (Zhang et al, 2012).…”

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confidence: 99%

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Maize and Arabidopsis ARGOS Proteins Interact with Ethylene Receptor Signaling Complex, Supporting a Regulatory Role for ARGOS in Ethylene Signal Transduction

et al. 2016

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The phytohormone ethylene regulates plant growth and development as well as plant response to environmental cues. ARGOS genes reduce plant sensitivity to ethylene when overexpressed in transgenic Arabidopsis (Arabidopsis thaliana) and maize (Zea mays). A previous genetic study suggested that the endoplasmic reticulum and Golgi-localized maize ARGOS1 targets the ethylene signal transduction components at or upstream of CONSTITUTIVE TRIPLE RESPONSE1, but the mechanism of ARGOS modulating ethylene signaling is unknown. Here, we demonstrate in Arabidopsis that ZmARGOS1, as well as the Arabidopsis ARGOS homolog ORGAN SIZE RELATED1, physically interacts with Arabidopsis REVERSION-TO-ETHYLENE SENSITIVITY1 (RTE1), an ethylene receptor interacting protein that regulates the activity of ETHYLENE RESPONSE1. The protein-protein interaction was also detected with the yeast split-ubiquitin two-hybrid system. Using the same yeast assay, we found that maize RTE1 homolog REVERSION-TO-ETHYLENE SENSITIVITY1 LIKE4 (ZmRTL4) and ZmRTL2 also interact with maize and Arabidopsis ARGOS proteins. Like AtRTE1 in Arabidopsis, ZmRTL4 and ZmRTL2 reduce ethylene responses when overexpressed in maize, indicating a similar mechanism for ARGOS regulating ethylene signaling in maize. A polypeptide fragment derived from ZmARGOS8, consisting of a Pro-rich motif flanked by two transmembrane helices that are conserved among members of the ARGOS family, can interact with AtRTE1 and maize RTL proteins in Arabidopsis. The conserved domain is necessary and sufficient to reduce ethylene sensitivity in Arabidopsis and maize. Overall, these results suggest a physical association between ARGOS and the ethylene receptor signaling complex via AtRTE1 and maize RTL proteins, supporting a role for ARGOS in regulating ethylene perception and the early steps of signal transduction in Arabidopsis and maize.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Interaction Of Argos With Arabidopsis Rte1 and Maize Homologmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Maize and Arabidopsis ARGOS Proteins Interact with Ethylene Receptor Signaling Complex, Supporting a Regulatory Role for ARGOS in Ethylene Signal Transduction

et al. 2016

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Amplification and Adaptation in the Ethylene Signaling Pathway

et al. 2019

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Plants are exquisitely sensitive to the ethylene signal and also respond to a much wider range of ethylene concentrations than would seem possible based on the simple circuitry of its primary signal transduction pathway, suggesting the existence of mechanisms for amplification and adaptation to ethylene signals. Here, such regulatory systems are considered within the context of what is known about the plant ethylene signaling pathway as well as signaling by the animal G-protein coupled receptors, and the bacterial methyl-accepting chemotaxis proteins.Magnitude amplification and sensitivity amplification mechanisms are considered as strategies for amplification of the ethylene signal. Several families of negative feedback regulators that desensitize plants to ethylene and thereby facilitate the ethylene adaptation response of plants are described. These negative feedback regulators include the ethylene receptors themselves, the reversion-to-ethylene sensitivity1 (RTE1)/greenripe (GR) family, and the auxin-regulated gene involved in organ size (ARGOS) family, all of which function at the level of the ethylene receptors to desensitize plants to ethylene. These negative regulators also include the ein3binding F box protein (EBF) family of F-box proteins, which target the ethylene insensitive3 (ein3)/ein3-lik (EIL) family of transcription factors for degradation. Ethylene signal amplification and adaptation employ both transcriptional and post-transcriptional regulation.

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The Molecular Regulation of Ethylene in Fruit Ripening

Liu

Tang

Ming-chun³

et al. 2020

Small Methods

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Fleshy fruits are major sources of necessary nutrients in many diets worldwide. Most fruit quality attributes emerge during ripening making the fruit more attractive to consumers. Understanding the molecular regulatory network underpinning fleshy fruit ripening is important not only for fruit quality improvement but also for postharvest shelf life. The phytohormone ethylene plays an essential role in climacteric fruit ripening and a number of studies have demonstrated that ethylene signaling components and related transcription factors are involved in the regulation of fruit ripening. However, the transcriptional network by which ethylene interacts with other signaling pathways to regulate the ripening process is not fully understood. In this review, focusing on the tomato as a reference species, the key points regarding the role of ethylene in coordinating the ripening process at the molecular and physiological levels are described. The interplay between ethylene and ripening‐related regulators and its crosstalk with other phytohormones and present recent data on ripening‐related epigenetic modifications are also discussed. Overall, the paper summarizes the most advanced research progress in this area to help facilitate its future development.

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Differential Control of Ethylene Responses byGREEN-RIPEandGREEN-RIPE LIKE1Provides Evidence for Distinct Ethylene Signaling Modules in Tomato

Cited by 36 publications

References 78 publications

Maize and Arabidopsis ARGOS Proteins Interact with Ethylene Receptor Signaling Complex, Supporting a Regulatory Role for ARGOS in Ethylene Signal Transduction

Maize and Arabidopsis ARGOS Proteins Interact with Ethylene Receptor Signaling Complex, Supporting a Regulatory Role for ARGOS in Ethylene Signal Transduction

Amplification and Adaptation in the Ethylene Signaling Pathway

The Molecular Regulation of Ethylene in Fruit Ripening

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