Chemistry of xylopyranosides

Thorsheim, Karin; Siegbahn, Anna; Johnsson, Richard; Stålbrand, Henrik; Manner, Sophie; Widmalm, Göran; Ellervik, Ulf

doi:10.1016/j.carres.2015.10.004

Cited by 30 publications

(35 citation statements)

References 382 publications

(292 reference statements)

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“…Monogastric animals do not have endogenous enzymes capable of degrading xylan to release monomeric xylose for absorption in the small intestine; consequently, there was little need to develop efficient mechanisms for xylose metabolism. Furthermore, xylose is a rare carbohydrate in mammalian cells and so far is only found as a link between the protein and glycosaminoglycan chains of some proteoglycans and in the Notch receptor [ 1 ]. The Notch receptor is part of a highly conserved core signaling pathway required for various cell fate decisions at multiple stages of development [ 70 ].…”

Section: Xylose Metabolismmentioning

confidence: 99%

“…The Notch receptor is part of a highly conserved core signaling pathway required for various cell fate decisions at multiple stages of development [ 70 ]. However, UDP-xylose, the activated precursor for xylose involvement in these structures, is synthesized from UDP-glucose and is not derived from dietary xylose sources [ 1 ]. As a result, the absence of an efficient or well-conserved pathway for xylose metabolism comes as no surprise because there has been no need.…”

Section: Xylose Metabolismmentioning

confidence: 99%

“…Xylose, as a major constituent of plant xylan polymers, is one of the most abundant carbohydrates on the earth, second only to glucose [ 1 , 2 ]. This abundant pentose sugar, along with arabinose, makes up a majority of the hemicellulose backbone as arabinoxylan in the cell walls of cereal grains fed to pigs [ 3 ].…”

Section: Introductionmentioning

confidence: 99%

“…Cereal arabinoxylans (also known as pentosans) are composed of a linear β-1,4-linked xylose backbone which may be substituted at the 2’-OH and/or 3’-OH, generally with single arabinose residues (Fig. 1 ) [ 1 ]. In contrast to α-linked starch, which is hydrolyzed to glucose by endogenous enzymes, β-linkages in arabinoxylan and other non-starch polysaccharides (NSP) must be degraded by microbial enzymes.…”

Section: Introductionmentioning

confidence: 99%

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Xylose: absorption, fermentation, and post-absorptive metabolism in the pig

Huntley

Patience

2018

J Animal Sci Biotechnol

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Xylose, as β-1,4-linked xylan, makes up much of the hemicellulose in cell walls of cereal carbohydrates fed to pigs. As inclusion of fibrous ingredients in swine diets continues to increase, supplementation of carbohydrases, such as xylanase, is of interest. However, much progress is warranted to achieve consistent enzyme efficacy, including an improved understanding of the utilization and energetic contribution of xylanase hydrolysis product (i.e. xylooligosaccharides or monomeric xylose). This review examines reports on xylose absorption and metabolism in the pig and identifies gaps in this knowledge that are essential to understanding the value of carbohydrase hydrolysis products in the nutrition of the pig. Xylose research in pigs was first reported in 1954, with only sporadic contributions since. Therefore, this review also discusses relevant xylose research in other monogastric species, including humans. In both pigs and poultry, increasing purified D-xylose inclusion generally results in linear decreases in performance, efficiency, and diet digestibility. However, supplementation levels studied thus far have ranged from 5% to 40%, while theoretical xylose release due to xylanase supplementation would be less than 4%. More than 95% of ingested D-xylose disappears before the terminal ileum but mechanisms of absorption have yet to be fully elucidated. Some data support the hypothesis that mechanisms exist to handle low xylose concentrations but become overwhelmed as luminal concentrations increase. Very little is known about xylose metabolic utilization in vertebrates but it is well recognized that a large proportion of dietary xylose appears in the urine and significantly decreases the metabolizable energy available from the diet. Nevertheless, evidence of labeled D-xylose-1-14 C appearing as expired 14 CO 2 in both humans and guinea pigs suggests that there is potential, although small, for xylose oxidation. It is yet to be determined if pigs develop increased xylose metabolic capacity with increased adaptation time to diets supplemented with xylose or xylanase. Overall, xylose appears to be poorly utilized by the pig, but it is important to consider that only one study has been reported which supplemented D-xylose dietary concentrations lower than 5%. Thus, more comprehensive studies testing xylose metabolic effects at dietary concentrations more relevant to swine nutrition are warranted.

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Section: Xylose Metabolismmentioning

confidence: 99%

Section: Xylose Metabolismmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Xylose: absorption, fermentation, and post-absorptive metabolism in the pig

Huntley

Patience

2018

J Animal Sci Biotechnol

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“…The lack of selectivity at room temperature can be explained by a higher thermodynamic stability of the α-xylopyranosides compared to the corresponding β-xylopyranosides. Apparently, anomerisation of the kinetically formed β-anomer easily takes place under mild reaction conditions at ambient temperature [ 40 ], but it is suppressed by decreased temperature in combination with an appropriate promoter (ZnO–I 2 ). Moreover, this new promoter was successfully applied to the reactions of the corresponding acceptor and four other glycosyl bromides, i.e., D-glucosyl ( Table 1 , entries 4 and 9), D-galactosyl ( Table 1 , entry 13), lactosyl ( Table 1 , entry 17) and L-arabinosyl ( Table 1 , entry 19).…”

Section: Resultsmentioning

confidence: 99%

A selective and mild glycosylation method of natural phenolic alcohols

Mastihubová¹,

Poláková²

2016

Beilstein J. Org. Chem.

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SummarySeveral bioactive natural p-hydroxyphenylalkyl β-D-glucopyranosides, such as vanillyl β-D-glucopyranoside, salidroside and isoconiferin, and their glycosyl analogues were prepared by a simple reaction sequence. The highly efficient synthetic approach was achieved by utilizing acetylated glycosyl bromides as well as aromatic moieties and mild glycosylation promoters. The aglycones, p-O-acetylated arylalkyl alcohols, were prepared by the reduction of the corresponding acetylated aldehydes or acids. Various stereoselective 1,2-trans-O-glycosylation methods were studied, including the DDQ–iodine or ZnO–ZnCl2 catalyst combination. Among them, ZnO–iodine has been identified as a new glycosylation promoter and successfully applied to the stereoselective glycoside synthesis. The final products were obtained by conventional Zemplén deacetylation.

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O‐glycosylation of Proteins

2019

Co and Post‐Translational Modifications of Therapeutic Antibodies and Proteins

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Chemistry of xylopyranosides

Cited by 30 publications

References 382 publications

Xylose: absorption, fermentation, and post-absorptive metabolism in the pig

Xylose: absorption, fermentation, and post-absorptive metabolism in the pig

A selective and mild glycosylation method of natural phenolic alcohols

O‐glycosylation of Proteins

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