Metabolism of<scp>d</scp>-<i>Glycero</i>-<scp>d</scp>-<i>Manno</i>-Heptitol, Volemitol, in Polyanthus. Discovery of a Novel Ketose Reductase1

Häfliger, Beat; Kindhauser, Elsbeth; Keller, Fabian

doi:10.1104/pp.119.1.191

Cited by 23 publications

(13 citation statements)

References 20 publications

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“…This is in contrast to what has been previously reported in hybrid polyanthus (Primula ×polyantha Hort.) for volemitol, another phloem-mobile C7 sugar, (Häfliger et al, 1999) whose levels in phloem exudates were substantially lower (only about one-quarter the concentration) than those of sucrose. Interestingly though, the reducing form of C7 sugar, sedoheptulose, corresponding to the C7 polyol volemitol was also found in phloem exudates, as we have found in the present study for mannoheptulose.…”

Section: Discussionmentioning

confidence: 95%

Postulated Physiological Roles of the Seven-carbon Sugars, Mannoheptulose, and Perseitol in Avocado

Li¹,

Sievert²,

Arpaia³

et al. 2002

jashs

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Avocado (Persea americana Mill.) tissues contain high levels of the seven-carbon (C7) ketosugar mannoheptulose and its polyol form, perseitol. Radiolabeling of intact leaves of `Hass' avocado on `Duke 7' rootstock indicated that both perseitol and mannoheptulose are not only primary products of photosynthetic CO2 fixation but are also exported in the phloem. In cell-free extracts from mature source leaves, formation of the C7 backbone occurred by condensation of a three-carbon metabolite (dihydroxyacetone-P) with a four-carbon metabolite (erythrose-4-P) to form sedoheptulose-1,7-bis-P, followed by isomerization to a phosphorylated d-mannoheptulose derivative. A transketolase reaction was also observed which converted five-carbon metabolites (ribose-5-P and xylulose-5-P) to form the C7 metabolite, sedoheptulose-7-P, but this compound was not metabolized further to mannoheptulose. This suggests that C7 sugars are formed from the Calvin Cycle, not oxidative pentose phosphate pathway, reactions in avocado leaves. In avocado fruit, C7 sugars were present in substantial quantities and the normal ripening processes (fruit softening, ethylene production, and climacteric respiration rise), which occurs several days after the fruit is picked, did not occur until levels of C7 sugars dropped below an apparent threshold concentration of ≈20 mg·g-1 fresh weight. The effect of picking could be mimicked by girdling the fruit stalks, which resulted in ripening on the tree. Again, ripening followed a decline in C7 sugars to below an apparent threshold level. Taken together, these data indicate that the C7 sugars play important roles in carbon allocation processes in the avocado tree, including a possible novel role as phloem-mobile ripening inhibitors.

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Section: Discussionmentioning

confidence: 95%

Postulated Physiological Roles of the Seven-carbon Sugars, Mannoheptulose, and Perseitol in Avocado

Li¹,

Sievert²,

Arpaia³

et al. 2002

jashs

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“…However, its presence, albeit at lower levels, in a range of other families including Apiaceae, Aquifoliaceae, Euphorbiaceae, Lamiaceae, Primulaceae, and Saxifragaceae suggests a broader range of occurrence (Tolbert et al ., 1957: Okuda and Mori, 1974; Häflinger et al ., 1999; Soria et al ., 2009). The only other free C7 sugar described in plants is mannoheptulose (Tesfay et al ., 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Although the basic features of the oxPPP are well established (Kruger and von Schaewen, 2003), details on how exactly the pathway influences other processes are subject to further investigation. In addition to its putative origin, the role of free sedoheptulose in plants remains a matter of debate, except for serving as a precursor for the polyol volemitol in the horticultural hybrid polyanthus (Häflinger et al ., 1999). A possible function as a carbohydrate reserve in CAM (such as starch or soluble sugars), essential to catalyse nocturnal CO 2 uptake, was ruled out earlier by Kull (1965, 1967) based on the absence of clear changing diel patterns of sedoheptulose.…”

Section: Introductionmentioning

confidence: 99%

Sedoheptulose accumulation under CO2 enrichment in leaves of Kalanchoë pinnata: a novel mechanism to enhance C and P homeostasis?

Ceusters

Godts

Peshev

et al. 2013

Journal of Experimental Botany

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In contrast to the well-documented roles of its mono- and bisphosphate esters, the occurrence of free sedoheptulose in plant tissues remains a matter of conjecture. The present work sought to determine the origin of sedoheptulose formation in planta, as well as its physiological importance. Elevated CO2 and sucrose induction experiments were used to study sedoheptulose metabolism in the Crassulacean acid metabolism (CAM) plants Kalanchoë pinnata and Sedum spectabile. Experimental evidence suggested that sedoheptulose is produced from the oxidative pentose phosphate pathway intermediate sedoheptulose-7-phosphate, by a sedoheptulose-7-phosphate phosphatase. Carbon flux through this pathway was stimulated by increased triose-phosphate levels (elevated CO2, compromised sink availability, and sucrose incubation of source leaves) and attenuated by ADP and inorganic phosphate (Pi). The accumulation of free sedoheptulose is proposed to act as a mechanism contributing to both C and P homeostasis by serving as an alternative carbon store under elevated CO2 or a compromised sink capacity to avoid sucrose accumulation, depletion of inorganic phosphate, and suppression of photosynthesis. It remains to be established whether this acclimation-avoiding mechanism is confined to CAM plants, which might be especially vulnerable to Pi imbalances, or whether some C3 and C4 plants also dispose of the genetic capacity to induce and accelerate sedoheptulose synthesis upon CO2 elevation.

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“…Mannoheptulose (D-manno-2-heptulose), sedoheptulose (D-altro-2-heptulose), perseitol (D-glycero-D-galactoheptitol) and sedoheptitol (volemitol; D-glycero-D-mannoheptitol) ( Fig. 2) have been detected in various plants (Hä fliger et al 1999;La Forge and Hudson 1917;Okuda and Mori 1974) and fruits (Liu et al 2002). Pitkä nen and Sahlstrom (1968) employed paper chromatography in conjunction with GC to demonstrate that sedoheptulose, mannoheptulose and sedoheptitol were present in trace quantities in human urine, speculating that these species derived from tissue metabolism likely associated with the pentose phosphate cycle pool.…”

Section: Introductionmentioning

confidence: 99%

Detection of transaldolase deficiency by quantification of novel seven‐carbon chain carbohydrate biomarkers in urine

Wamelink

Smith

Jansen

et al. 2007

J of Inher Metab Disea

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Transaldolase deficiency, a recently discovered disorder of carbohydrate metabolism with multisystem involvement, has been diagnosed in 6 patients. Affected patients have abnormal concentrations of polyols in body fluids and in all patients we have previously found increased amounts of a seven-carbon chain carbohydrate which we suspected of being sedoheptulose. We report development of a liquid chromatography-tandem mass spectrometry method for quantitation of the seven-carbon carbohydrates sedoheptulose and mannoheptulose in urine. Additionally, other seven-carbon chain carbohydrates were characterized in urine, including sedoheptitol, perseitol and sedoheptulose 7-phosphate. Transaldolase-deficient patients had significantly increased urinary sedoheptulose and sedoheptulose 7-phosphate, associated with subtle elevations of mannoheptulose, sedoheptitol and perseitol. Our findings reveal novel urinary biomarkers for identification of transaldolase deficiency.

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Metabolism ofd-Glycero-d-Manno-Heptitol, Volemitol, in Polyanthus. Discovery of a Novel Ketose Reductase1

Cited by 23 publications

References 20 publications

Postulated Physiological Roles of the Seven-carbon Sugars, Mannoheptulose, and Perseitol in Avocado

Postulated Physiological Roles of the Seven-carbon Sugars, Mannoheptulose, and Perseitol in Avocado

Sedoheptulose accumulation under CO2 enrichment in leaves of Kalanchoë pinnata: a novel mechanism to enhance C and P homeostasis?

Detection of transaldolase deficiency by quantification of novel seven‐carbon chain carbohydrate biomarkers in urine

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