Genome-Wide Analysis of the Arabidopsis Leaf Transcriptome Reveals Interaction of Phosphate and Sugar Metabolism

Müller, Renate; Morant, Marc; Jarmer, Hanne Østergaard; Nilsson, Lena; Nielsen, Theodor

doi:10.1104/pp.106.090167

Cited by 301 publications

(324 citation statements)

References 71 publications

(104 reference statements)

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“…These synergistically induced genes could be the converging points for Suc and Pi signals to regulate multiple plant responses to Pi starvation. The synergistic interaction of Suc and low-Pi signals in regulating gene expression at the genomic level has also been observed in a previous study using exogenously applied Suc to Pi-starved excised leaves (Mü ller et al, 2007). Thus, Suc appears to act as a major regulator of the expression of genes that are involved in plant responses to Pi starvation.…”

Section: Discussionmentioning

confidence: 65%

“…In contrast, the Arabidopsis pho3 mutant carries a defective copy of the SUCROSE TRANSPORTER2 (SUC2) gene, leading to substantially reduced transport of Suc from shoot to root and the suppression of induction and secretion of APase on its root surface (Zakhleniuk et al, 2001;Lloyd and Zakhleniuk, 2004). In addition, earlier studies have revealed that the expression of many genes involved in the synthesis, translocation, and degradation of Suc was altered during Pi starvation (Hammond et al, 2003;Vance et al, 2003;Wu et al, 2003;Misson et al, 2005;Mü ller et al, 2007). Furthermore, an increase in Suc biosynthesis in Pi-starved leaves has been observed in a variety of plants, including Arabidopsis, bean, barley (Hordeum vulgare), spinach (Spinacia oleracea), and soybean (Glycine max; Hammond and White, 2008).…”

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confidence: 98%

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Genetic and Genomic Evidence That Sucrose Is a Global Regulator of Plant Responses to Phosphate Starvation in Arabidopsis

et al. 2011

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Plants respond to phosphate (Pi) starvation by exhibiting a suite of developmental, biochemical, and physiological changes to cope with this nutritional stress. To understand the molecular mechanism underlying these responses, we isolated an Arabidopsis (Arabidopsis thaliana) mutant, hypersensitive to phosphate starvation1 (hps1), which has enhanced sensitivity in almost all aspects of plant responses to Pi starvation. Molecular and genetic analyses indicated that the mutant phenotype is caused by overexpression of the SUCROSE TRANSPORTER2 (SUC2) gene. As a consequence, hps1 has a high level of sucrose (Suc) in both its shoot and root tissues. Overexpression of SUC2 or its closely related family members SUC1 and SUC5 in wild-type plants recapitulates the phenotype of hps1. In contrast, the disruption of SUC2 functions greatly inhibits plant responses to Pi starvation. Microarray analysis further indicated that 73% of the genes that are induced by Pi starvation in wild-type plants can be induced by elevated levels of Suc in hps1 mutants, even when they are grown under Pi-sufficient conditions. These genes include several important Pi signaling components and those that are directly involved in Pi transport, mobilization, and distribution between shoot and root. Interestingly, Suc and low-Pi signals appear to interact with each other both synergistically and antagonistically in regulating gene expression. Our genetic and genomic studies provide compelling evidence that Suc is a global regulator of plant responses to Pi starvation. This finding will help to further elucidate the signaling mechanism that controls plant responses to this particular nutritional stress.

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Section: Discussionmentioning

confidence: 65%

mentioning

confidence: 98%

Genetic and Genomic Evidence That Sucrose Is a Global Regulator of Plant Responses to Phosphate Starvation in Arabidopsis

et al. 2011

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“…PPsPase1 and PECP1 are listed as strongly induced in several transcriptomics studies related to phosphate starvation (Misson et al, 2005; Bari et al, 2006;Müller et al, 2007;Thibaud et al, 2010;Hirsch et al, 2011). However, very little is known about their precise expression patterns.…”

Section: Ppspase1 and Pecp1 Are Dynamic Markers Of Pi Starvationmentioning

confidence: 99%

“…Furthermore, their corresponding mutants exhibit altered gene induction and classical Pi starvation responses, including diminished effects on Pi content and lipid remobilization (Pant et al, 2015). Candidates for the systemic control of Pi starvation responses have been proposed, including substantial transport of mRNAs throughout the plant (as reviewed in Puga et al, 2017), and the direct sensing of Pi concentration (or Pi-containing metabolites) by SPX-type proteins (Wang et al, 2009;Puga et al, 2014;Wild et al, 2016).Two phosphatases belonging to the haloacid dehalogenase (HAD) superfamily were identified as some of the most strongly induced transcripts following Pi starvation (Bari et al, 2006;Müller et al, 2007;Thibaud et al, 2010). These enzymes were named PPsPase1 (for pyrophosphatase [PPi]-specific phosphatase1) and PECP1 (for phosphoethanolamine (PEth)/ phosphocholine [PCho] phosphatase1) on the basis of their in vitro activity, following their heterologous expression in bacteria and subsequent purification (May et al, 2011(May et al, , 2012.…”

mentioning

confidence: 99%

“…Two phosphatases belonging to the haloacid dehalogenase (HAD) superfamily were identified as some of the most strongly induced transcripts following Pi starvation (Bari et al, 2006;Müller et al, 2007;Thibaud et al, 2010). These enzymes were named PPsPase1 (for pyrophosphatase [PPi]-specific phosphatase1) and PECP1 (for phosphoethanolamine (PEth)/ phosphocholine [PCho] phosphatase1) on the basis of their in vitro activity, following their heterologous expression in bacteria and subsequent purification (May et al, 2011(May et al, , 2012.…”

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confidence: 99%

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The Phosphate Fast-Responsive Genes PECP1 and PPsPase1 Affect Phosphocholine and Phosphoethanolamine Content

et al. 2018

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Phosphate starvation-mediated induction of the HAD-type phosphatases PPsPase1 (AT1G73010) and PECP1 (AT1G17710) has been reported in Arabidopsis (Arabidopsis thaliana). However, little is known about their in vivo function or impact on plant responses to nutrient deficiency. The preferences of PPsPase1 and PECP1 for different substrates have been studied in vitro but require confirmation in planta. Here, we examined the in vivo function of both enzymes using a reverse genetics approach. We demonstrated that PPsPase1 and PECP1 affect plant phosphocholine and phosphoethanolamine content, but not the pyrophosphate-related phenotypes. These observations suggest that the enzymes play a similar role in planta related to the recycling of polar heads from membrane lipids that is triggered during phosphate starvation. Altering the expression of the genes encoding these enzymes had no effect on lipid composition, possibly due to compensation by other lipid recycling pathways triggered during phosphate starvation. Furthermore, our results indicated that PPsPase1 and PECP1 do not influence phosphate homeostasis, since the inactivation of these genes had no effect on phosphate content or on the induction of molecular markers related to phosphate starvation. A combination of transcriptomics and imaging analyses revealed that PPsPase1 and PECP1 display a highly dynamic expression pattern that closely mirrors the phosphate status. This temporal dynamism, combined with the wide range of induction levels, broad expression, and lack of a direct effect on Pi content and regulation, makes PPsPase1 and PECP1 useful molecular markers of the phosphate starvation response.Plant growth is highly sensitive to a lack of phosphate (Pi); hence, the application of Pi fertilizers has become standard practice for high-throughput crop production (Cordell et al., 2009). Most phosphorus in the soil is not available to plants, as it is combined with other minerals or parts of organic compounds (Bieleski, 1973;Raghothama and Karthikeyan, 2005). Only a small fraction of soluble Pi (usually present at a concentration of ,10 mM in the soil) can be taken up by plants.Although growth is not optimal under limiting conditions, plants can withstand changing Pi concentrations within heterogeneous soils or in the external nutrient supply that can lead to reprogramming of their metabolism and architecture (Hammond et al., 2003;Péret et al., 2011;Plaxton and Tran, 2011). Root architecture can be modified to facilitate Pi uptake by favoring the development of lateral roots (at the expense of primary root elongation in many plants including Arabidopsis), increasing the density and length of root hairs, and limiting the development of aerial parts (López-Bucio et al., 2002;Svistoonoff et al., 2007;Gruber et al., 2013). Pi uptake mechanisms are enhanced at the root/soil interface, particularly through the stimulation of Pi transport activity (Mudge et al., 2002;Shin et al., 2004;Nussaume et al., 2011; Ayadi et al., 2015). In parallel, mobilization of Pi sources fr...

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Phenylpropanoid Metabolism in Plants: Biochemistry, Functional Biology, and Metabolic Engineering

Iandolino

Cook

2009

Plant Phenolics and Human Health

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Genome-Wide Analysis of the Arabidopsis Leaf Transcriptome Reveals Interaction of Phosphate and Sugar Metabolism

Cited by 301 publications

References 71 publications

Genetic and Genomic Evidence That Sucrose Is a Global Regulator of Plant Responses to Phosphate Starvation in Arabidopsis

Genetic and Genomic Evidence That Sucrose Is a Global Regulator of Plant Responses to Phosphate Starvation in Arabidopsis

The Phosphate Fast-Responsive Genes PECP1 and PPsPase1 Affect Phosphocholine and Phosphoethanolamine Content

Phenylpropanoid Metabolism in Plants: Biochemistry, Functional Biology, and Metabolic Engineering

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