Cytosolic cycles regulate the turnover of sucrose in heterotrophic cell-suspension cultures of Chenopodium rubrum L.

Dancer, Jane E.; Hatzfeld, Wolf-Dieter; Stitt, Mark

doi:10.1007/bf00197115

Cited by 105 publications

(74 citation statements)

References 27 publications

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“…The high fluxes of sucrose cycling found here are consistent with those found in ripening bananas (23) and in maize root tips (20). Possible roles for this futile cycle include the following: maintaining the balance between the accumulation of sucrose and the demand for carbon for respiration and biosynthesis in the cell (45,47,48) or the regulation of the sucrose and hexose concentrations in relation to the water status of the cell (20). It is interesting to note that the rate of sucrose cycling was closely related with glucose influx (around 6-fold) but in no case with alterations in hexose or starch accumulation.…”

Section: Stability Of Central Metabolism and Futilesupporting

confidence: 83%

“…8 and Table IV). A similarly high activity of the oxidative pentose phosphate pathway was found in maize root tips (20), and in cells of C. rubrum (47) and Daucus carota (48). A considerable recycling of triose phosphate in the cytosol has also been observed in C. rubrum cells and potato tubers (44) and an active futile cycle of sucrose in sugarcane (45), corn root tips (20), maturing banana (23), and kiwifruit (49), but lower values were found in C. rubrum cells (44).…”

Section: Stability Of Central Metabolism and Futilementioning

confidence: 77%

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The Metabolic Architecture of Plant Cells

Rontein

Dieuaide-Noubhani

Dufourc

et al. 2002

Journal of Biological Chemistry

182

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The changes in the intermediary metabolism of plant cells were quantified according to growth conditions at three different stages of the growth cycle of tomato cell suspension. Eighteen fluxes of central metabolism were calculated from 13 C enrichments after near steady-state labeling by a metabolic model similar to that described in Dieuaide-Noubhani et al. (Dieuaide-Noubhani, M., Raffard, G., Canioni, P., Pradet, A., and Raymond, P. (1995) J. Biol. Chem. 270, 13147-13159), and 10 net fluxes were obtained directly from end-product accumulation rates. The absolute flux values of central metabolic pathways gradually slowed down with the decrease of glucose influx into the cells. However, the relative fluxes of glycolysis, the pentose-P pathway, and the tricarboxylic acid cycle remained unchanged during the culture cycle at 70, 28, and 40% of glucose influx, respectively, and the futile cycle of sucrose remained high at about 6-fold the glucose influx, independently from carbon nutritional conditions. This natural resistance to flux alterations is referred to as metabolic stability. The numerous anabolic pathways, including starch synthesis, hexose accumulation, biosynthesis of wall polysaccharides, and amino and organic acid biosynthesis were comparatively low and variable. The phosphoenolpyruvate carboxylase flux decreased 5-fold in absolute terms and 2-fold in relation to the glucose influx rate during the culture cycle. We conclude that anabolic fluxes constitute the flexible part of plant cell metabolism that can fluctuate in relation to cell demands for growth.Plants are able to grow under a wide range of environmental conditions (extreme temperatures, insufficient or excessive light, and shortage of water or mineral nutrients) and show a robust physiological homeostasis. To ensure this homeostasis, plant metabolism has to be very flexible (1). In all cells, the central carbon metabolism provides energy, cofactor regeneration, and building blocks for biomass and secondary metabolism. The flexibility of plant metabolism, which is probably an evolutionary adaptation to the variable environmental conditions plants normally experience, has been explained by the buffering effect of carbon storage and allocation (2) and by the complexity of regulation or built-in redundancy owing to alternative enzymes and pathways for many processes (3). For example, parallel glycolytic pathways are present in the cytosol and plastid; in the cytosol, the classic key sites for regulation of glycolysis at phosphofructokinase and pyruvate kinase (PK) 1 can be bypassed by pyrophosphate:fructose-6-phosphate phosphotransferase and phosphoenolpyruvate carboxylase (PEPC) (3).The development of genetic engineering, which introduced a new dimension to pathway knowledge by allowing precise modifications of specific enzymatic reactions in metabolic pathways, also highlighted the flexibility of plant primary metabolism (4 -6). Pyrophosphate:fructose-6-phosphate phosphotransferase and cytosolic PK, which generally have been considered essenti...

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Section: Stability Of Central Metabolism and Futilesupporting

confidence: 83%

Section: Stability Of Central Metabolism and Futilementioning

confidence: 77%

The Metabolic Architecture of Plant Cells

Rontein

Dieuaide-Noubhani

Dufourc

et al. 2002

Journal of Biological Chemistry

182

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“…However, a similar pattern of induction by the hexose sugars is also seen in C. rubrum cell culture (2) and for the Incw2 gene in developing endosperm in vitro kernel cultures (27). A ''futile cycle'' of suc synthesis and cleavage, similar to the previously proposed suc turn-over reactions in several plant systems (2,28,29), is postulated as a possible basis for the hexose induction of the two Incw genes. In sycamore suspension cells, an SS pathway is proposed to be relatively more important than an invertase pathway when suc is limiting (15).…”

Section: Discussionsupporting

confidence: 70%

Sugars modulate an unusual mode of control of the cell-wall invertase gene ( Incw 1) through its 3′ untranslated region in a cell suspension culture of maize

Cheng

Taliercio

Chourey

1999

Proc. Natl. Acad. Sci. U.S.A.

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We show here that a cell-wall invertase encoded by the Incw1 gene is regulated at both the transcriptional and posttranscriptional levels by sugars in a heterotrophic cell suspension culture of maize. The Incw1 gene encoded two transcripts: Incw1-S (small) and Incw1-L (large); the size variation was attributable to different lengths in the 3 untranslated region. Both metabolizable and nonmetabolizable sugars induced Incw1-L RNA apparently by default. However, only the metabolizable sugars, sucrose and D-glucose, were associated with the increased steady-state abundance of Incw1-S RNA, the concomitant increased levels of INCW1 protein and enzyme activity, and the downstream metabolic repression of the sucrose synthase gene, Sh1. Conversely, nonmetabolizable sugars, including the two glucose analogs 3-O-methylglucose and 2-deoxyglucose, induced greater steady-state levels of the Incw1-L RNA, but this increase did not lead to either an increase in the levels of the INCW1 protein͞enzyme activity or the repression of the Sh1 gene. We conclude that sugar sensing and the induction of the Incw1 gene is independent of the hexokinase pathway. More importantly, our results also suggest that the 3 untranslated region of the Incw1 gene acts as a regulatory sensor of carbon starvation and may constitute a link between sink metabolism and cellular translation in plants.The enzyme invertase (EC 3.2.1.26), also known as ␤-fructofuranosidase, is known to catalyze sucrose (suc) cleavage to its monosaccharide constituents, glucose (glc) and fructose, in an irreversible manner. At least two forms of the enzyme, soluble and particulate, are features common to all invertases, and recent molecular analyses indicate that each belongs to two distinct class of small gene families (ref. 1 and references therein). The physiological role of the invertases is believed to be in suc partitioning between source and sink regions of the plant. In general, the vacuolar invertases are believed to be important in the regulation of hexose levels in certain specific tissues and in the use of stored suc in vacuoles. The cell-wall forms (extracellular or secreted) are associated with rapidly growing tissues and have been implicated in phloem unloading and source͞sink regulation (2).Although the experimental evidence is largely correlative in nature, a lot of insight regarding the roles of invertases is now emerging from studies of transgenic or mutant plants. Among several studies on transgenic plants, the most detailed analyses are reported in potato where yeast invertase has been expressed in both the cytosol and apoplast (3). Tissue-specific elevated expression of invertase in both cellular locations leads to substantial reductions in tuber suc content and a corresponding large increase in glc content. More importantly, the apoplastic and cytosolic increases in enzyme activities are associated with different phenotypic responses: an increased tuber size but reduced tuber number in the former and a reversed pattern in the latter. In contrast, w...

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“…Changes in the specific radioactivity of soluble carbohydrates and starch in mature peach leaves measured after a pulsechase experiment. The leaves were labeled using 14CO2 for 4 min, 7 h after the beginning of the photoperiod; the chase lasted 8 h. Soluble carbohydrates and starch were extracted and specific radioactivity was determined after HPLC separation as described in "Materials and Methods." These data represent the means ± SD of four replicates.…”

Section: Compartmentation and Export Of Photoassimilatesmentioning

confidence: 99%

Carbon Fluxes in Mature Peach Leaves

Moing¹,

Carbonne²,

Rashad³

et al. 1992

Plant Physiol.

107

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The turnover and transport of sugars are described in peach (Prunus persica L. Batsch), a species exporting both sucrose and sorbitol. Apparent export rate was slower in peach leaves than in leaves of herbaceous species. Sorbitol was the major soluble end product of photosynthesis and the major soluble carbohydrate in the leaf (higher than sucrose). Carbon fluxes were described using 14C labeling, radioactivity loss curves, and compartmental analysis during the second half of the photoperiod when chemical steady state was reached for soluble carbohydrates. The measured specific radioactivity of sucrose was typical of a primary product. The delayed decrease in specific radioactivity of sorbitol indicated that part of it was secondarily synthesized. Sucrose is proposed to be the carbon source for the delayed synthesis of sorbitol in the light. The sorbitol to sucrose ratio was higher in the petiole than in the leaf tissues. In phloem sap, obtained using stylectomy of aphids and collected from the main stem between source leaves and apex, this ratio was lower than in the petiole, suggesting a preferential sorbitol demand by sinks.

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Cytosolic cycles regulate the turnover of sucrose in heterotrophic cell-suspension cultures of Chenopodium rubrum L.

Cited by 105 publications

References 27 publications

The Metabolic Architecture of Plant Cells

The Metabolic Architecture of Plant Cells

Sugars modulate an unusual mode of control of the cell-wall invertase gene ( Incw 1) through its 3′ untranslated region in a cell suspension culture of maize

Carbon Fluxes in Mature Peach Leaves

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