Profiling of cool-season forage arabinoxylans via a validated HPAEC-PAD method

Joyce, Glenna E.; Kagan, Isabelle A.; Flythe, Michael D.; Harlow, Brittany E.; Schendel, Rachel R.

doi:10.3389/fpls.2023.1116995

Cited by 3 publications

(2 citation statements)

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“…Species differences in short-chain fructan catabolism in the present study were also reflected in patterns of appearance and disappearance of bifurcose and 1-nystose, but not in free sugar concentrations. A more frequent sampling interval and employing techniques to improve resolution of glucose, fructose, and sucrose peaks such as the method recently developed by Joyce et al [44] could aid in characterizing fluctuations in these mono and disaccharides during catabolism of grass fructans. It should be noted that in bovine fermentations in the current study, the greatest degradation of both long-and short-chain fructans occurred during the 2-4 h period, with long-chain fructans non-detectable and short-chain fructans almost completely utilized by 4 h. It is therefore possible that the capacity of the bovine rumen microbiota to catabolize grass fructans exceeded the fructans provided by the orchardgrass used as the fermentative substrate in this experiment.…”

Section: Discussionmentioning

confidence: 99%

Fructan Catabolism by Rumen Microbiota of Cattle and Sheep

Weinert-Nelson,

Kagan,

Ely

et al. 2023

Fermentation

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Fructans serve as the primary form of storage carbohydrate in cool-season grasses, but little is known about potential differences in ruminal fermentation of fructans between cattle and sheep. An ex vivo study was conducted to evaluate species differences in fructan catabolism. Buffered media containing ground orchardgrass (Dactylis glomerata L.) substrate was inoculated with uncultivated rumen microbiota obtained from cattle and sheep (n = 4 species−1). Fructan profiles were monitored over the incubation period (8 h; 39 °C) using high-performance anion-exchange chromatography coupled to pulsed amperometric detection (HPAEC-PAD). In both species, disappearance of long-chain fructans (degree of polymerization [DP] > 8) was evident by 2 h of incubation (p < 0.01), whereas short-chain fructans (DP 4–8) increased from 0 to 2 h prior to subsequent degradation (p < 0.01). However, the overall rate of long-chain fructan catabolism was greater in bovine versus ovine fermentations, particularly between 2 and 4 h (p < 0.01). Additionally, rapid utilization of short-chain fructans occurred from 2 to 4 h in bovine fermentations, but was delayed in ovine fermentations, with substantial degradation occurring only after 4 h of incubation (p < 0.01). These results indicate that rumen microbiota of cattle may have a greater capacity for fructan degradation.

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Section: Discussionmentioning

confidence: 99%

Fructan Catabolism by Rumen Microbiota of Cattle and Sheep

Weinert-Nelson,

Kagan,

Ely

et al. 2023

Fermentation

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“…Key variables such as acid hydrolysis duration, temperature, and acid concentration are meticulously adjusted to ensure the optimal recovery, precision, and reproducibility of monosaccharide data [8]. Tailoring hydrolysis conditions to suit the dissociation of polysaccharides with diverse structural characteristics is crucial to achieving accurate results [9,10]. For instance, distinct ketoses (e.g., D-fructose) and aldoses (e.g., D-glucose) may yield identical alditol products upon reduction, owing to the enolization and dehydration processes converting D-fructose to alditol under harsh hydrolytic conditions.…”

Section: Introductionmentioning

confidence: 99%

Exploration and Improvement of Acid Hydrolysis Conditions for Inulin-Type Fructans Monosaccharide Composition Analysis: Monosaccharide Recovery and By-Product Identification

Zong,

Lei,

Yin

et al. 2024

Foods

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Acid hydrolysis serves as the primary method for determining the monosaccharide composition of polysaccharides. However, inappropriate acid hydrolysis conditions may catalyze the breakdown of monosaccharides such as fructans (Fru), generating non-sugar by-products that affect the accuracy of monosaccharide composition analysis. In this study, we determined the monosaccharide recovery rate and non-sugar by-product formation of inulin-type fructan (ITF) and Fru under varied acid hydrolysis conditions using HPAEC-PAD and UPLC-Triple-TOF/MS, respectively. The results revealed significant variations in the recovery rate of Fru within ITF under different hydrolysis conditions, while glucose remained relatively stable. Optimal hydrolysis conditions for achieving a relatively high monosaccharide recovery rate for ITF entailed 80 °C, 2 h, and 1 M sulfuric acid. Furthermore, we validated the stability of Fru during acid hydrolysis. The results indicated that Fru experienced significant degradation with an increasing temperature and acid concentration, with a pronounced decrease observed when the temperature exceeds 100 °C or the H2SO4 concentration surpasses 2 M. Finally, three common by-products associated with Fru degradation, namely 5-hydroxymethyl-2-furaldehyde, 5-methyl-2-furaldehyde, and furfural, were identified in both Fru and ITF hydrolysis processes. These findings revealed that the degradation of Fru under acidic conditions was a vital factor leading to inaccuracies in determining the Fru content during ITF monosaccharide analysis.

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