The Arabidopsis CstF64-Like RSR1/ESP1 Protein Participates in Glucose Signaling and Flowering Time Control

Funck, Dietmar; Clauß, Karen; Frommer, Wolf B.; Hellmann, Hanjo

doi:10.3389/fpls.2012.00080

Cited by 14 publications

(14 citation statements)

References 60 publications

(90 reference statements)

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“…Thus far, several components have been proposed to be involved in various Suc signaling processes. For instance, the protein kinase Suc nonfermenting related kinase-1 (SnRK1) is required for Suc signal transduction, leading to starch synthesis and Suc synthase induction in potato (Tiessen et al, 2003); the REDUCED SUC RESPONSE 1 (RSR1) was identified as a critical factor for Suc signaling during seed germination and early seedling development (Funck et al, 2012); the SUC UNCOUPLED 6 (SUN6) is involved in the Suc-mediated down-regulation of photosynthesis genes (Dijkwel et al, 1997); and the IMPAIRED SUC INDUCTION 4 (ISI4) is required for Suc-mediated growth inhibition (Laby et al, 2000). Here, we investigated whether the regulation of Fe deficiency responses by Suc was associated with the aforementioned Suc signaling components by using snrk1.1, snrk1.2, rsr1, sun6, and isi4 mutants.…”

Section: Discussionmentioning

confidence: 99%

Increased Sucrose Accumulation Regulates Iron-Deficiency Responses by Promoting Auxin Signaling in Arabidopsis Plants

Lin

Fan

et al. 2015

Plant Physiol.

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Section: Discussionmentioning

confidence: 99%

Increased Sucrose Accumulation Regulates Iron-Deficiency Responses by Promoting Auxin Signaling in Arabidopsis Plants

Lin

Fan

et al. 2015

Plant Physiol.

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“…The complex links between plant growth, primary metabolism, and flowering time in Arabidopsis are highlighted in a recent article where increased plant growth was positively associated with early-flowering phenotypes (El-Lithy et al, 2010), which may explain the larger rosette area observed prior to flowering in 30-d-old agl22 mutant plants compared with the wild type ( Figure 9A; Supplemental Figure 9B). In addition, starch/ carbohydrate status and metabolite levels have been linked to rosette growth Sulpice et al, 2009), as well as development and flowering time (Zhou et al, 1998;Moore et al, 2003;Funck et al, 2012). Both photosynthesis and flowering are regulated by the light environment and are clearly linked via the carbohydrate status (Zhou et al, 1998;Moore et al, 2003;Funck et al, 2012), connecting primary metabolism with plant growth and development.…”

Section: A Flowering Time Gene Influences Water Use and Photosynthesimentioning

confidence: 99%

“…In addition, starch/ carbohydrate status and metabolite levels have been linked to rosette growth Sulpice et al, 2009), as well as development and flowering time (Zhou et al, 1998;Moore et al, 2003;Funck et al, 2012). Both photosynthesis and flowering are regulated by the light environment and are clearly linked via the carbohydrate status (Zhou et al, 1998;Moore et al, 2003;Funck et al, 2012), connecting primary metabolism with plant growth and development. However, little is known about the link between photosynthetic performance and flowering time especially in flowering time mutants, and at this point, it is unclear why the agl22 mutants exhibited a substantial reduction in photosynthesis already under well-watered conditions.…”

Section: A Flowering Time Gene Influences Water Use and Photosynthesimentioning

confidence: 99%

Time-Series Transcriptomics Reveals That AGAMOUS-LIKE22 Affects Primary Metabolism and Developmental Processes in Drought-Stressed Arabidopsis

et al. 2016

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In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.

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“…In plants, sugar levels influence many developmental phases from seed germination (Pego et al, 1999;Price et al, 2003;Li et al, 2012) to flowering induction (van Dijken et al, 2004;Funck et al, 2012;Wahl et al, 2013) to senescence (Veyres et al, 2008;Wingler et al, 2010Wingler et al, , 2012Thomas, 2013). By taking advantage of the effects of externally supplied sugars on Arabidopsis (Arabidopsis thaliana) growth, genetic screens have often been used to identify mutants with altered responses to sugars (Zhou et al, 1998;Rolland et al, 2002;Rook and Bevan, 2003;Baier et al, 2004;Gibson, 2005).…”

mentioning

confidence: 99%

TANG1, Encoding a Symplekin_C Domain-Contained Protein, Influences Sugar Responses in Arabidopsis

Zheng

Chen

et al. 2015

Plant Physiol.

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Sugars not only serve as energy and cellular carbon skeleton but also function as signaling molecules regulating growth and development in plants. Understanding the molecular mechanisms in sugar signaling pathways will provide more information for improving plant growth and development. Here, we describe a sugar-hypersensitive recessive mutant, tang1. Light-grown tang1 mutants have short roots and increased starch and anthocyanin contents when grown on high-sugar concentration medium. Dark-grown tang1 plants exhibit sugar-hypersensitive hypocotyl elongation and enhanced dark development. The tang1 mutants also show an enhanced response to abscisic acid but reduced response to ethylene. Thus, tang1 displays a range of alterations in sugar signaling-related responses. The TANG1 gene was isolated by a map-based cloning approach and encodes a previously uncharacterized unique protein with a predicted Symplekin tight-junction protein C terminus. Expression analysis indicates that TANG1 is ubiquitously expressed at moderate levels in different organs and throughout the Arabidopsis (Arabidopsis thaliana) life cycle; however, its expression is not affected by high-sugar treatment. Genetic analysis shows that PRL1 and TANG1 have additive effects on sugar-related responses. Furthermore, the mutation of TANG1 does not affect the expression of genes involved in known sugar signaling pathways. Taken together, these results suggest that TANG1, a unique gene, plays an important role in sugar responses in Arabidopsis.

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The Arabidopsis CstF64-Like RSR1/ESP1 Protein Participates in Glucose Signaling and Flowering Time Control

Cited by 14 publications

References 60 publications

Increased Sucrose Accumulation Regulates Iron-Deficiency Responses by Promoting Auxin Signaling in Arabidopsis Plants

Increased Sucrose Accumulation Regulates Iron-Deficiency Responses by Promoting Auxin Signaling in Arabidopsis Plants

Time-Series Transcriptomics Reveals That AGAMOUS-LIKE22 Affects Primary Metabolism and Developmental Processes in Drought-Stressed Arabidopsis

TANG1, Encoding a Symplekin_C Domain-Contained Protein, Influences Sugar Responses in Arabidopsis

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