Role of the Rice Hexokinases<i>OsHXK5</i>and<i>OsHXK6</i>as Glucose Sensors

Cho, Jung‐Il; Ryoo, Nayeon; Eom, Joon-Seob; Lee, Dong Hoon; Kim, Hyun-Bi; Jeong, Seok-Won; Lee, Youn‐Hyung; Kwon, Yong-Kook; Cho, Man-Ho; Bhoo, Seong Hee; Hahn, Tae‐Ryong; Park, Youn‐Il; Hwang, Ildoo; Sheen, Jen; Jeon, Jong‐Seong

doi:10.1104/pp.108.131227

Cited by 147 publications

(181 citation statements)

References 72 publications

(115 reference statements)

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“…These results appear to be consistent with the role of Glc-6-P as a substrate for Suc synthesis via SPS, in contrast to the wild-type plants, where Suc was degraded. Our results show that increased HK activity in P SARK ::IPT plants is not associated with detrimental effects on photosynthesis and growth or in accelerating senescence, indicating that the differences between the regulation driven by changes in gene expression and protein activity might involve different signaling pathways, as suggested previously (Cho et al, 2009). …”

Section: Impact Of Ipt Expression On the Regulation Of C Metabolism Usupporting

confidence: 81%

“…It has been shown that HK regulates photosynthesis, growth, and senescence. Increased levels of HK expression reduced growth and photosynthesis and induced senescence in tomato (Solanum lycopersicum) and rice plants (Dai et al, 1999;Cho et al, 2009) Supplemental Fig. S1): 1 (LOC_Os02g14110, aminotransferase), 1.2 (LOC_Os01g08270, aminotransferase), 1.3 (LOC_Os09g28050, aminotransferase), 1.4 (LOC_Os03g18810, aminotransferase), 1.5 (LOC_Os01g55540, aminotransferase), 2 (LOC_Os07g46460, Fd-GOGAT), 3 (LOC_Os02g20360, Tyr aminotransferase), 4 (LOC_Os04g52450, aminotransferase), 5 (LOC_Os08g01410, phosphate/phosphoenolpyruvate translocator), 6 (LOC_Os01g02020, acetyl-CoA acetyltransferase), 7 (LOC_Os07g42600, Ala aminotransferase), 8 (LOC_Os02g07160, glyoxalase family protein), 9 (LOC_Os04g14790, glycerol-3-phosphate dehydrogenase), 10 (LOC_Os02g41680, Phe ammonia-lyase), 11 (LOC_Os04g33300, amino acid kinase), 12 (LOC_Os02g37040, NTP3 [nitrate transporter]), 13 (LOC_Os04g45970, GDH), 14 (LOC_Os01g09000, glutaminyl-tRNA synthetase), 14.2 (LOC_Os07g07260, Gln-dependent NAD), 15 (LOC_Os02g38200, isocitrate dehydrogenase), 15.2 (LOC_Os01g46610, isocitrate dehydrogenase), 16 (LOC_Os02g10070, citrate synthase), 17 (LOC_Os03g05390, citrate transporter), 18 (LOC_Os04g31700, methylisocitrate lyase 2), 19 (LOC_Os10g08550, enolase), 20 (LOC_Os08g09200, aconitate hydratase), 20.2 (LOC_Os03g04410, aconitate hydratase), 21 (LOC_Os04g56400, Gln synthetase), 22.1 (LOC_Os06g16420, amino acid transporter), 22.2 (LOC_Os04g12499, amino acid transporter), 22.3 (LOC_Os06g36210, amino acid transporter), 22.4 (LOC_Os06g43700, amino acid transporter), 22.4 (LOC_Os11g09020, amino acid transporter), 22.5 (LOC_Os12g42850, amino acid permease), 22.6 (LOC_Os03g25869, amino acid permease), 22.7 (LOC_Os08g23440, amino acid permease), 22.8 (LOC_Os10g30090, amino acid permease), 22.9 (LOC_Os11g05690, amino acid permease), 22.10 (LOC_Os04g35540, amino acid transporter), 22.11 (LOC_Os08g03350, amino acid transporter), 22.12 (LOC_Os01g40410, amino acid transporter), 22.13 (LOC_Os01g63854, amino acid transporter), 22.14 (LOC_Os02g44980, amino acid transporter), 22.15 (LOC_Os02g09810, amino acid transporter), 22.16 (LOC_Os04g38680, amino acid transporter), 22.17 (LOC_Os05g50920, amino acid transporter), 22.18 (LOC_Os01g65000, ammonium transporter protein), 23.1 (LOC_Os02g34580, ammonium transporter protein), 23.2 (LOC_Os03g62200, ammonium transporter protein), 23.3 (LOC_Os04g43070, ammonium transporter protein), 24.1 (LOC_Os03g13240, peptide transporter PTR2), 24.2 (LOC_Os06g49250, peptide transporter PTR2), 24.3 (LOC_Os10g02240, peptide transporter PTR2), 24.4 (LOC_Os10g33170, peptide transporter PTR2), 24.5 (LOC_Os03g51050, peptide transporter PTR2), 25.1 (LOC_Os03g13274, NO 3 peptide transporter PTR2), 25.2 (LOC_Os10g42900, NO 3 peptide transporter PTR3), 26 (LOC_Os11g24450, 2-oxoglutarate/malate translocator), 27 (LOC_Os08g43170, hydroxymethylglutaryl-CoA synthase), and 28 (LOC_Os02g32490, acetyl-CoA synthetase).…”

Section: Discussionmentioning

confidence: 99%

“…Interestingly, HK roles in sugar sensing and signaling seem to be independent of the enzyme activity, as demonstrated using catalytically inactive OsHXK alleles of OsHXK5 and OsHXK6 in rice plants (Cho et al, 2009). This notion was further supported by the higher HK activity found in P SARK ::IPT plants that correlated well with an increase in Glc-6-P without detrimental effects on photosynthesis, growth, or senescence.…”

Section: Gs Nadh-gogat Gdh Amination [Gdh a ] And Deamination [Gdh mentioning

confidence: 99%

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Stress-Induced Cytokinin Synthesis Increases Drought Tolerance through the Coordinated Regulation of Carbon and Nitrogen Assimilation in Rice

et al. 2013

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The effects of water deficit on carbon and nitrogen metabolism were investigated in flag leaves of wild-type and transgenic rice (Oryza sativa japonica 'Kitaake') plants expressing ISOPENTENYLTRANSFERASE (IPT; encoding the enzyme that mediates the rate-limiting step in cytokinin synthesis) under the control of P SARK , a maturation-and stress-induced promoter. While the wildtype plants displayed inhibition of photosynthesis and nitrogen assimilation during water stress, neither carbon nor nitrogen assimilation was affected by stress in the transgenic P SARK ::IPT plants. In the transgenic plants, photosynthesis was maintained at control levels during stress and the flag leaf showed increased sucrose (Suc) phosphate synthase activity and reduced Suc synthase and invertase activities, leading to increased Suc contents. The sustained carbon assimilation in the transgenic P SARK ::IPT plants was well correlated with enhanced nitrate content, higher nitrate reductase activity, and sustained ammonium contents, indicating that the stress-induced cytokinin synthesis in the transgenic plants played a role in maintaining nitrate acquisition. Protein contents decreased and free amino acids increased in wild-type plants during stress, while protein content was preserved in the transgenic plants. Our results indicate that the stress-induced cytokinin synthesis in the transgenic plants promoted sink strengthening through a cytokinin-dependent coordinated regulation of carbon and nitrogen metabolism that facilitates an enhanced tolerance of the transgenic plants to water deficit.

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Section: Impact Of Ipt Expression On the Regulation Of C Metabolism Usupporting

confidence: 81%

Section: Discussionmentioning

confidence: 99%

Section: Gs Nadh-gogat Gdh Amination [Gdh a ] And Deamination [Gdh mentioning

confidence: 99%

See 1 more Smart Citation

Stress-Induced Cytokinin Synthesis Increases Drought Tolerance through the Coordinated Regulation of Carbon and Nitrogen Assimilation in Rice

et al. 2013

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“…Especially, two hexokinases of rice (OsHXK5 and 6) also have been demonstrated to serve as glucose sensor and also their catalytically inactive forms still successfully delivered the sugar regulation, too [Cho et al (2009a), see Cho (2009b) for review]. However, the finding of the uncoupling of the metabolic and signaling activities of hexokinase unwittingly led to underscore the possible interaction of sugar signaling with the cellular metabolic status.…”

Section: Discussionmentioning

confidence: 99%

Differential Anoxic Expression of Sugar-Regulated Genes Reveals Diverse Interactions between Sugar and Anaerobic Signaling Systems in Rice

Lim

Lee

Yim

et al. 2013

Molecules and Cells

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The interaction between the dual roles of sugar as a metabolic fuel and a regulatory molecule was unveiled by examining the changes in sugar signaling upon oxygen deprivation, which causes the drastic alteration in the cellular energy status. In our study, the expression of anaerobically induced genes is commonly responsive to sugar, either under the control of hexokinase or non-hexokinase mediated signaling cascades. Only sugar regulation via the hexokinase pathway was susceptible for O 2 deficiency or energy deficit conditions evoked by uncoupler. Examination of sugar regulation of those genes under anaerobic conditions revealed the presence of multiple paths underlying anaerobic induction of gene expression in rice, subgrouped into three distinct types. The first of these, which was found in type-1 genes, involved neither sugar regulation nor additional anaerobic induction under anoxia, indicating that anoxic induction is a simple result from the release of sugar repression by O 2 -deficient conditions. In contrast, type-2 genes also showed no sugar regulation, albeit with enhanced expression under anoxia. Lastly, expression of type-3 genes is highly enhanced with sugar regulation sustained under anoxia. Intriguingly, the inhibition of the mitochondrial ATP synthesis can reproduce expression pattern of a specific set of anaerobically induced genes, implying that rice cells may sense O 2 deprivation, partly via perception of the perturbed cellular energy status. Our study of interaction between sugar signaling and anaerobic conditions has revealed that sugar signaling and the cellular energy status are likely to communicate with each other and influence anaerobic induction of gene expression in rice.

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“…The amplified product was digested with XbaI and XhoI and was cloned into the region between the CaMV35S promoter and sGFP of the JJ461 binary vector (Cho et al, 2009). The primers used were 5#-GCTCTAGACTCTTCTGAACTAACCCAAA-GAT-3# and 5#-CCCTCGAGATCGGTGACCTCTCCTCCTTGAT-3# (the underlined sequences indicate XbaI and XhoI sites, respectively).…”

Section: Construction Of the Ossut2-gfp Fusion Vector And Subcellularmentioning

confidence: 99%

Impaired Function of the Tonoplast-Localized Sucrose Transporter in Rice, OsSUT2, Limits the Transport of Vacuolar Reserve Sucrose and Affects Plant Growth

et al. 2011

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Physiological functions of sucrose (Suc) transporters (SUTs) localized to the tonoplast in higher plants are poorly understood. We here report the isolation and characterization of a mutation in the rice (Oryza sativa) OsSUT2 gene. Expression of OsSUT2-green fluorescent protein in rice revealed that OsSUT2 localizes to the tonoplast. Analysis of the OsSUT2 promoter::bglucuronidase transgenic rice indicated that this gene is highly expressed in leaf mesophyll cells, emerging lateral roots, pedicels of fertilized spikelets, and cross cell layers of seed coats. Results of Suc transport assays in yeast were consistent with a H + -Suc symport mechanism, suggesting that OsSUT2 functions in Suc uptake from the vacuole. The ossut2 mutant exhibited a growth retardation phenotype with a significant reduction in tiller number, plant height, 1,000-grain weight, and root dry weight compared with the controls, the wild type, and complemented transgenic lines. Analysis of primary carbon metabolites revealed that ossut2 accumulated more Suc, glucose, and fructose in the leaves than the controls. Further sugar export analysis of detached leaves indicated that ossut2 had a significantly decreased sugar export ability compared with the controls. These results suggest that OsSUT2 is involved in Suc transport across the tonoplast from the vacuole lumen to the cytosol in rice, playing an essential role in sugar export from the source leaves to sink organs.

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Role of the Rice HexokinasesOsHXK5andOsHXK6as Glucose Sensors

Cited by 147 publications

References 72 publications

Stress-Induced Cytokinin Synthesis Increases Drought Tolerance through the Coordinated Regulation of Carbon and Nitrogen Assimilation in Rice

Stress-Induced Cytokinin Synthesis Increases Drought Tolerance through the Coordinated Regulation of Carbon and Nitrogen Assimilation in Rice

Differential Anoxic Expression of Sugar-Regulated Genes Reveals Diverse Interactions between Sugar and Anaerobic Signaling Systems in Rice

Impaired Function of the Tonoplast-Localized Sucrose Transporter in Rice, OsSUT2, Limits the Transport of Vacuolar Reserve Sucrose and Affects Plant Growth

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