The Metabolic Fate of C14 Labeled Pentoses in Man

Segal, Stanton; Foley, Joseph B.

doi:10.1172/jci103815

Cited by 40 publications

(11 citation statements)

References 24 publications

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“…In the tracer experiment, the specific activity of the C1402 increased at a faster rate, reached a peak about 40 minutes earlier, and maintained a much higher activity throughout the interval of observation. Both of the curves appear to show a period of constant specific activity after the peak labeling has been reached, a finding not encountered in studying the C1402 excretion after the administration of other labeled pentoses (44).…”

Section: Excretion Of Ribose As C140mentioning

confidence: 81%

The Metabolism of D-Ribose in Man

Segal¹,

Foley²

1958

J. Clin. Invest.

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Section: Excretion Of Ribose As C140mentioning

confidence: 81%

The Metabolism of D-Ribose in Man

Segal¹,

Foley²

1958

J. Clin. Invest.

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“…Earlier researchers (Segal & Foley, 1959) report that labelled D-xylose infusion in man resulted in an average 44% urinary recovery of the total dose. These researchers proposed that the pentose 169 sugars may be converted, in part, to glucose or may enter glycogenesis via the pentose phosphate pathway.…”

Section: Discussionmentioning

confidence: 97%

Comparison of gavage, water bottle, and a high-moisture diet bolus as dosing methods for quantitative D-xylose administration to B6D2F1 (Mus musculus) mice

1993

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SummaryGavage, water bottle, and diet incorporation are 3 dosing methods used orally to administer test compounds to rodents. These 3 methods were compared in mice to determine which represented the most quantitative delivery system. For dietary incorporation, a highmoisture bolus form of NIH-31 rodent meal was developed using hydroxypropyl methylcellulose as an autoclave-stable binding agent. A highmoisture bolus was selected to increase the acceptability of the dosed diet and to promote quantitative consumption through reduced wastage. The test compound used was D-xylose, a pentose sugar that may be quantitatively detected, colorimetrically, in urine following oral dosing. Six male and 6 female B6D2F1 mice were placed in metabolism cages and dosed with a known quantity of D-xylose by each of the 3 methods. Urine was collected before and after each method of administration and analysed for total D-xylose; the per cent recovery was based upon the amount of D-xylose consumed.Quantitative consumption was apparently greatest for water bottle dosing with an average recovery of 56·0070 of the original Dxylose dose. High-moisture bolus incorporation ranked second with 50· 0070D-xylose recovery, and gavage was third with 41· 0070 D-xylose recovery.

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“…Bifidobacteria metabolize glucose and fructose through a particular metabolic pathway, socalled bifid shunt, and form lactate and acetate via D-xylulose-5-phosphate as major metabolites. L-Arabinose is a poorly absorbed sugar (33) and is scarcely metabolized in humans (34). Therefore, most of the L-arabinose is thought to utilize by intestinal bacteria.…”

Section: G Effects Of Polysaccharides and Hrgps Containing L-arabinomentioning

confidence: 99%

Functional Analysis of Degradative Enzymes for Hydroxyproline-linked ^|^beta;-L-Arabinofuranosides in Bifidobacterium longum

Fujita¹,

Kitahara²,

Suganuma³

2012

TIGG

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Abstractβ-L-Arabinofuranosides are hydroxyproline (Hyp)-linked sugar chains of extensin observed in plant cell wall fractions. Despite the broad distribution of β-Larabinofuranosyl residues in plants, degradative enzymes have not yet been identified. In 2011, we cloned and characterized the first degradative enzymes for Hyp-linked β-L-arabinofuranosides from Bifidobacterium longum. These enzymes were composed of a glycoside hydrolase (GH) family 43 α-L-arabinofuranosidase (HypAA) releasing L-arabinose from Arafα1-3Arafβ1-2Arafβ1-2Arafβ-Hyp, a GH121 β-L-arabinobiosidase (HypBA2) releasing Arafβ1-2Araf (β-Ara 2 ) from Arafβ1-2Arafβ1-2Arafβ-Hyp, and a GH127 β-L-arabinofuranosidase (HypBA1) degrading β-Ara 2 to L-arabinose. These enzymes are encoded in a conserved gene cluster on several B. longum genomes, but not in genome sequences of other intestinal bacteria. Hyp-linked β-L-arabinofuranosides were utilized as carbohydrate sources by B. longum. This review presents the functional features of enzymes for Hyp-linked β-L-arabinofuranosides and the predicted metabolic pathway in B. longum. A. IntroductionL-Arabinose residues are the main constituents of sugars in plant cell walls, and they are mostly present in the form of α-L-furanose in polysaccharides such as arabinan, arabinoxylan, and pectic arabinogalactan. Glycoside hydrolases involved in the degradation of α-Larabinofuranosides are present in 6 glycoside hydrolase (GH) families (GH3, GH43, GH51, GH54, GH62, and GH93) in the CAZy database. In addition, degradative enzymes for α-and β-L-arabinopyranoside linkages were also found in the GH42 and GH27 families, respectively (1,2). On the other hand, β-L-arabinofuranoside linkages constitute sugar chains of hydroxyproline-rich glycoproteins (HRGPs), which are known

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The Metabolic Fate of C14 Labeled Pentoses in Man

Cited by 40 publications

References 24 publications

The Metabolism of D-Ribose in Man

The Metabolism of D-Ribose in Man

Comparison of gavage, water bottle, and a high-moisture diet bolus as dosing methods for quantitative D-xylose administration to B6D2F1 (Mus musculus) mice

Functional Analysis of Degradative Enzymes for Hydroxyproline-linked ^|^beta;-L-Arabinofuranosides in Bifidobacterium longum

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