Investigating the mechanisms of amylolysis of starch granules by solution-state NMR

Andrew J. Baldwin; Danielle L. Egan; Fredrick J. Warren; Paul D. Barker; Christopher M. Dobson; Peter J. Butterworth; Peter R. Ellis

doi:10.1021/acs.biomac.5b00190

Investigating the mechanisms of amylolysis of starch granules by solution-state NMR

Andrew J. Baldwin^*, Danielle L. Egan, Fredrick J. Warren, Paul D. Barker, Christopher M. Dobson, Peter J. Butterworth, Peter R. Ellis

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

46 Citations (Scopus)

Abstract

Starch is a prominent component of the human diet and is hydrolyzed by α-amylase post-ingestion. Probing the mechanism of this process has proven challenging, due to the intrinsic heterogeneity of individual starch granules. By means of solution-state NMR, we demonstrate that flexible polysaccharide chains protruding from the solvent-exposed surfaces of waxy rice starch granules are highly mobile and that during hydrothermal treatment, when the granules swell, the number of flexible residues on the exposed surfaces increases by a factor of 15. Moreover, we show that these flexible chains are the primary substrates for α-amylase, being cleaved in the initial stages of hydrolysis. These findings allow us to conclude that the quantity of flexible α-glucan chains protruding from the granule surface will greatly influence the rate of energy acquisition from digestion of starch.

Original language	English
Pages (from-to)	1614-1621
Number of pages	8
Journal	BIOMACROMOLECULES
Volume	16
Issue number	5
DOIs	https://doi.org/10.1021/acs.biomac.5b00190
Publication status	Published - 11 May 2015

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abstract = "Starch is a prominent component of the human diet and is hydrolyzed by α-amylase post-ingestion. Probing the mechanism of this process has proven challenging, due to the intrinsic heterogeneity of individual starch granules. By means of solution-state NMR, we demonstrate that flexible polysaccharide chains protruding from the solvent-exposed surfaces of waxy rice starch granules are highly mobile and that during hydrothermal treatment, when the granules swell, the number of flexible residues on the exposed surfaces increases by a factor of 15. Moreover, we show that these flexible chains are the primary substrates for α-amylase, being cleaved in the initial stages of hydrolysis. These findings allow us to conclude that the quantity of flexible α-glucan chains protruding from the granule surface will greatly influence the rate of energy acquisition from digestion of starch.",

author = "Baldwin, {Andrew J.} and Egan, {Danielle L.} and Warren, {Fredrick J.} and Barker, {Paul D.} and Dobson, {Christopher M.} and Butterworth, {Peter J.} and Ellis, {Peter R.}",

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AU - Baldwin, Andrew J.

AU - Egan, Danielle L.

AU - Warren, Fredrick J.

AU - Barker, Paul D.

AU - Dobson, Christopher M.

AU - Butterworth, Peter J.

AU - Ellis, Peter R.

PY - 2015/5/11

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N2 - Starch is a prominent component of the human diet and is hydrolyzed by α-amylase post-ingestion. Probing the mechanism of this process has proven challenging, due to the intrinsic heterogeneity of individual starch granules. By means of solution-state NMR, we demonstrate that flexible polysaccharide chains protruding from the solvent-exposed surfaces of waxy rice starch granules are highly mobile and that during hydrothermal treatment, when the granules swell, the number of flexible residues on the exposed surfaces increases by a factor of 15. Moreover, we show that these flexible chains are the primary substrates for α-amylase, being cleaved in the initial stages of hydrolysis. These findings allow us to conclude that the quantity of flexible α-glucan chains protruding from the granule surface will greatly influence the rate of energy acquisition from digestion of starch.

AB - Starch is a prominent component of the human diet and is hydrolyzed by α-amylase post-ingestion. Probing the mechanism of this process has proven challenging, due to the intrinsic heterogeneity of individual starch granules. By means of solution-state NMR, we demonstrate that flexible polysaccharide chains protruding from the solvent-exposed surfaces of waxy rice starch granules are highly mobile and that during hydrothermal treatment, when the granules swell, the number of flexible residues on the exposed surfaces increases by a factor of 15. Moreover, we show that these flexible chains are the primary substrates for α-amylase, being cleaved in the initial stages of hydrolysis. These findings allow us to conclude that the quantity of flexible α-glucan chains protruding from the granule surface will greatly influence the rate of energy acquisition from digestion of starch.

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Investigating the mechanisms of amylolysis of starch granules by solution-state NMR

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