Your search keyword '"Hamaker BR"' showing total 26 results

1. Structural requirements of flavonoids for the selective inhibition of α-amylase versus α-glucosidase.

Author

Lim J, Ferruzzi MG, and Hamaker BR

Subjects

Flavonoids, Humans, Starch, alpha-Amylases, alpha-Glucosidases

Abstract

In the present study, 14 structurally unique flavonoids were screened to systematically investigate structural requirements for selectively inhibiting human α-amylase versus α-glucosidase to obtain a slow but complete starch digestion for health benefit. The selective inhibition property of three flavonoids chosen against the two classes of starch digestive enzymes was confirmed through various analytical techniques - in vitro inhibition assay, fluorescence quenching, kinetic study, and molecular modeling. Considering the chemical structure of flavonoids, the double bond between C2 and C3 and OH groups at A5 and B3 are critical for the inhibition of α-amylase allowing flavonoids to lie parallel on the α-amylase catalytic active site, whereas the OH groups at B3 and C3 are important for α-glucosidase inhibition causing B-ring specific entry into the catalytic active site of α-glucosidase. Our findings provide insights into how to apply flavonoids to effectively control digestion rate for improving physiological responses., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2022

2. Conditioning with slowly digestible starch diets in mice reduces jejunal α-glucosidase activity and glucogenesis from a digestible starch feeding.

Author

Hasek LY, Avery SE, Chacko SK, Fraley JK, Vohra FA, Quezada-Calvillo R, Nichols BL, and Hamaker BR

Subjects

Animals, Diet, Glucose, Mice, Starch, Digestion, alpha-Glucosidases

Abstract

Objectives: Maltase-glucoamylase (Mgam) and sucrase-isomaltase (Si) are mucosal α-glucosidases required for the digestion of starch to glucose. We hypothesized that a dietary approach to reduce Mgam and Si activities can reduce glucose generation and absorption, and improve glucose control., Methods: Rice starch was entrapped in alginate microspheres to moderate in vitro digestion properties. Three groups of 8-wk old mice (n = 8) were conditioned for 7 d with low 13 C-starch-based materials differing in digestion rates (fast, slow, and slower), and then given a digestible 13 C-labeled cornstarch test feeding to determine its digestion to glucose., Results: Conditioning of the small intestine with the slowly digestible starches for 7 d reduced jejunal α-glucosidase and sucrase activities, as well as glucose absorption for the slowly digestible starch slower group (P < 0.01). A correlative relationship was found between glucose absorption from a cornstarch test feeding given at d 7 and jejunal α-glucosidase and sucrase activities (R 2 = 0.64; 0.67). However, total prandial glucose levels during the 2-h feeding period did not differ., Conclusions: Decreased glucogenesis from a digestible starch feeding was found in mice conditioned on slowly digestible starch diets, suggesting that a dietary approach incorporating slowly digestible starches may change α-glucosidase activities to moderate glucose absorption rate., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

3. Starch digested product analysis by HPAEC reveals structural specificity of flavonoids in the inhibition of mammalian α-amylase and α-glucosidases.

Author

Lim J, Zhang X, Ferruzzi MG, and Hamaker BR

Subjects

Animals, Chromatography, High Pressure Liquid, Chromatography, Ion Exchange, Colorimetry, Enzyme Assays, Enzyme Inhibitors metabolism, Flavonoids metabolism, Kinetics, Starch analysis, Substrate Specificity, alpha-Amylases antagonists & inhibitors, alpha-Glucosidases chemistry, Enzyme Inhibitors chemistry, Flavonoids chemistry, Starch metabolism, alpha-Amylases metabolism, alpha-Glucosidases metabolism

Abstract

An accurate high-performance anion-exchange chromatography (HPAEC) method is presented to measure the inhibition property of flavonoids against mammalian starch digestive enzymes, because flavonoids interfere with commonly used 3,5-dinitrosalicylic acid (DNS) and glucose oxidase/peroxidase (GOPOD) methods. Eriodictyol, luteolin, and quercetin increased absorbance values (without substrate) in the DNS assay and, with substrate, either overestimated or underestimated values in the DNS and GOPOD assays. Using a direct HPAEC measurement method, flavonoids showed different inhibition properties against α-amylase and α-glucosidases, showing different inhibition constants (K i ) and mechanisms. The double bond between C2 and C3 on the C-ring of flavonoids appeared particularly important to inhibit α-amylase, while the hydroxyl group (OH) at C3 of the C-ring was related to inhibition of α-glucosidases. This study shows that direct measurement of starch digestion products by HPAEC should be used in inhibition studies, and provides insights into structure-function aspects of polyphenols in controlling starch digestion rate., (Copyright © 2019. Published by Elsevier Ltd.)

Published

2019

4. Different inhibition properties of catechins on the individual subunits of mucosal α-glucosidases as measured by partially-purified rat intestinal extract.

Author

Lim J, Kim DK, Shin H, Hamaker BR, and Lee BH

Subjects

Animals, Blood Glucose, Carbohydrate Metabolism, Catechin analogs & derivatives, Catechin metabolism, Glucose metabolism, Hydroxybenzoates, Rats, Starch, Substrate Specificity, alpha-Amylases metabolism, Catechin pharmacology, Intestines enzymology, Mucous Membrane metabolism, alpha-Glucosidases metabolism

Abstract

Mucosal α-glucosidases from rat intestinal powder were employed, with a step to remove α-amylase, to measure the possibility of different inhibition of catechins, particularly those found in tea, on the four α-glucosidase enzymes. Inhibition of catechins was investigated for the slowing of digestion of glycemic carbohydrates, thus regulating glucose release and absorption. The α-glucosidases were fractionated using size-exclusion chromatography. The partially purified fractions showed higher α-glucosidase activity without any α-amylase activity. Catechins had selective inhibition properties on the α-glucosidases. In particular, (-)-epigallocatechin gallate (EGCG) and (-)-epicatechin gallate (ECG) showed comparably high inhibitory effect on all four individual α-glucosidases, while (-)-epicatechin (EC), and (+)-catechin (C) indicated a more discriminating effect with relatively higher inhibitory effects on sucrase-isomaltase. The findings suggest that catechins differently inhibit the individual subunits of the α-glucosidases, and that they could modulate postprandial blood glucose levels through slowing digestion rate of starch and other glycemic carbohydrates, including sucrose.

Published

2019

5. Dietary starch breakdown product sensing mobilizes and apically activates α-glucosidases in small intestinal enterocytes.

Author

Chegeni M, Amiri M, Nichols BL, Naim HY, and Hamaker BR

Subjects

Caco-2 Cells, Humans, Intestine, Small cytology, Maltose metabolism, Membrane Microdomains metabolism, Signal Transduction, Enterocytes metabolism, Starch metabolism, alpha-Glucosidases metabolism

Abstract

Dietary starch is finally converted to glucose for absorption by the small intestine mucosal α-glucosidases (sucrase-isomaltase [SI] and maltase-glucoamylase), and control of this process has health implications. Here, the molecular mechanisms were analyzed associated with starch-triggered maturation and transport of SI. Biosynthetic pulse-chase in Caco-2 cells revealed that the high MW SI species (265 kDa) induced by maltose (an α-amylase starch digestion product) had a higher rate of early trafficking and maturation compared with a glucose-induced SI (245 kDa). The maltose-induced SI was found to have higher affinity to lipid rafts, which are associated with enhanced targeting to the apical membrane and higher activity. Accordingly, in situ maltose-hydrolyzing action was enhanced in the maltose-treated cells. Thus, starch digestion products at the luminal surface of small intestinal enterocytes are sensed and accelerate the intracellular processing of SI to enhance starch digestion capacity in the intestinal lumen.-Chegeni, M., Amiri, M., Nichols, B. L., Naim, H. Y., Hamaker, B. R. Dietary starch breakdown product sensing mobilizes and apically activates α-glucosidases in small intestinal enterocytes.

Published

2018

6. Maltase Has Most Versatile α-Hydrolytic Activity Among the Mucosal α-Glucosidases of the Small Intestine.

Author

Lee BH and Hamaker BR

Subjects

Digestion physiology, Disaccharides metabolism, Humans, Hydrolysis, Starch metabolism, Intestinal Mucosa physiology, Intestine, Small physiology, alpha-Glucosidases physiology

Abstract

Complete digestion of the glycemic carbohydrates to glucose takes place through the combined action of the 4 mucosal α-glucosidases (maltase-glucoamylase and sucrase-isomaltase) in the small intestine. Maltase digests α-1,2- and α-1,3-disaccharides better than the other α-glucosidases, and has, as well, the capability to effectively hydrolyze α-1,4 and α-1,6 linkages that form the major backbone of a starch molecule. This broad hydrolytic activity on α-linkages makes it an enzyme that has the most versatile α-hydrolytic activity among the 4mucosal α-glucosidases. The slowly digestible properties of the unusual linkages from this research suggest the development of new glycemic oligosaccharides which will be hydrolyzed slowly, compared to α-1,4 linkages, for modulating the postprandial glycemic response. In addition, using mammalian mucosal α-glucosidases is a better fit to characterize carbohydrate digestion properties, compared to fungal amyloglucosidase which is currently applied in in vitro assays.

Published

2018

7. Phenolic compounds increase the transcription of mouse intestinal maltase-glucoamylase and sucrase-isomaltase.

Author

Simsek M, Quezada-Calvillo R, Nichols BL, and Hamaker BR

Subjects

Animals, Glucan 1,4-alpha-Glucosidase genetics, Intestines drug effects, Male, Mice, Mice, Inbred BALB C, Sucrase genetics, alpha-Glucosidases genetics, Glucan 1,4-alpha-Glucosidase metabolism, Intestines enzymology, Phenol pharmacology, Sucrase metabolism, alpha-Glucosidases metabolism

Abstract

Diverse natural phenolic compounds show inhibition activity of intestinal α-glucosidases, which may constitute the molecular basis for their ability to control systemic glycemia. Additionally, phenolics can modify mRNA expression for proteins involved in nutritional, metabolic or immune processes. To explore the possibility that phenolics can regulate the mRNA expression, enzymatic activity, and protein synthesis/processing of intestinal Maltase-Glucoamylase (MGAM) and Sucrase-Isomaltase (SI), small intestinal explants from Balb/c mice were cultured for 24 h in the presence or absence of gallic acid, caffeic acid, and (+)-catechin at 0.1, 0.5, and 1 mM. We measured the levels of MGAM and SI mRNA expression by qRT-PCR, maltase and sucrase activities by a standard colorimetric method and the molecular size distribution of MGAM and SI proteins by western blotting. mRNA expression for MGAM was induced by the three phenolic compounds at 0.1 mM. mRNA expression for SI was induced by caffeic and gallic acids, but not by (+)-catechin. Caffeic acid was the most effective inducer of mRNA expression of these enzymes. Total maltase and sucrase activities were not affected by treatment with phenolics. The proportion of high molecular size forms of MGAM was significantly increased by two of the three phenolic compounds, but little effect was observed on SI proteins. Thus, changes in the protein synthesis/processing, affecting the proportions of the different molecular forms of MGAM, may account for the lack of correlation between mRNA expression and enzymatic activity.

Published

2017

8. Number of branch points in α-limit dextrins impact glucose generation rates by mammalian mucosal α-glucosidases.

Author

Lee BH and Hamaker BR

Subjects

Animals, Hydrolysis, Starch metabolism, alpha-Amylases metabolism, Dextrins chemistry, Glucose biosynthesis, alpha-Glucosidases metabolism

Abstract

α-Amylase first hydrolyzes starch structures to linear maltooligosaccharides and branched α-limit dextrins, then complete hydrolysis to glucose takes place through the mucosal α-glucosidases. In this study, we hydrolyzed waxy corn starch (WCS) by human pancreatic α-amylase to determine the digestion and structural properties of different size fractions of the branched α-limit dextrins. The α-amylolyzed WCS was separated by size exclusion chromatography, and the analyzed chromatograms showed four main hydrolyzate fractions. The first three eluted peaks (regions I-III) corresponded to branched α-limit dextrins, while region IV was the linear maltooligosaccharides. Based on the chromatographic and NMR analyses of the individual peaks, Region I, II, and III had multiple (>2), two, and one α-1,6 linkages, respectively, and region I was the most slowly hydrolyzed to glucose by mucosal α-glucosidases (hydrolysis rate: Region I

Published

2017

9. Contribution of the Individual Small Intestinal α-Glucosidases to Digestion of Unusual α-Linked Glycemic Disaccharides.

Author

Lee BH, Rose DR, Lin AH, Quezada-Calvillo R, Nichols BL, and Hamaker BR

Subjects

Animals, Glucose chemistry, Hydrogen-Ion Concentration, Hydrolysis, Maltose chemistry, Oligosaccharides chemistry, Rats, Recombinant Proteins chemistry, Starch chemistry, Digestion, Disaccharides chemistry, Intestine, Small enzymology, Sucrase-Isomaltase Complex chemistry, alpha-Glucosidases chemistry

Abstract

The mammalian mucosal α-glucosidase complexes, maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI), have two catalytic subunits (N- and C-termini). Concurrent with the desire to modulate glycemic response, there has been a focus on di-/oligosaccharides with unusual α-linkages that are digested to glucose slowly by these enzymes. Here, we look at disaccharides with various possible α-linkages and their hydrolysis. Hydrolytic properties of the maltose and sucrose isomers were determined using rat intestinal and individual recombinant α-glucosidases. The individual α-glucosidases had moderate to low hydrolytic activities on all α-linked disaccharides, except trehalose. Maltase (N-terminal MGAM) showed a higher ability to digest α-1,2 and α-1,3 disaccharides, as well as α-1,4, making it the most versatile in α-hydrolytic activity. These findings apply to the development of new glycemic oligosaccharides based on unusual α-linkages for extended glycemic response. It also emphasizes that mammalian mucosal α-glucosidases must be used in in vitro assessment of digestion of such carbohydrates.

Published

2016

10. Dietary phenolic compounds selectively inhibit the individual subunits of maltase-glucoamylase and sucrase-isomaltase with the potential of modulating glucose release.

Author

Simsek M, Quezada-Calvillo R, Ferruzzi MG, Nichols BL, and Hamaker BR

Subjects

Animals, Digestion, Enzyme Inhibitors metabolism, Glucan 1,4-alpha-Glucosidase metabolism, Humans, Kinetics, Mice, Oligo-1,6-Glucosidase metabolism, Phenol metabolism, Sucrase metabolism, alpha-Glucosidases metabolism, Enzyme Inhibitors chemistry, Glucan 1,4-alpha-Glucosidase chemistry, Glucose chemistry, Oligo-1,6-Glucosidase chemistry, Phenol chemistry, Sucrase chemistry, alpha-Glucosidases chemistry

Abstract

In this study, it was hypothesized that dietary phenolic compounds selectively inhibit the individual C- and N-terminal (Ct, Nt) subunits of the two small intestinal α-glucosidases, maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI), for a modulated glycemic carbohydrate digestion. The inhibition by chlorogenic acid, caffeic acid, gallic acid, (+)-catechin, and (-)-epigallocatechin gallate (EGCG) on individual recombinant human Nt-MGAM and Nt-SI and on mouse Ct-MGAM and Ct-SI was assayed using maltose as the substrate. Inhibition constants, inhibition mechanisms, and IC50 values for each combination of phenolic compound and enzymatic subunit were determined. EGCG and chlorogenic acid were found to be more potent inhibitors for selectively inhibiting the two subunits with highest activity, Ct-MGAM and Ct-SI. All compounds displayed noncompetitive type inhibition. Inhibition of fast-digesting Ct-MGAM and Ct-SI by EGCG and chlorogenic acid could lead to a slow, but complete, digestion of starch for improved glycemic response of starchy foods with potential health benefit.

Published

2015

11. Branch pattern of starch internal structure influences the glucogenesis by mucosal Nt-maltase-glucoamylase.

Author

Lin AH, Ao Z, Quezada-Calvillo R, Nichols BL, Lin CT, and Hamaker BR

Subjects

Digestion, Glycogen metabolism, Humans, alpha-Amylases metabolism, Glucose metabolism, Intestinal Mucosa enzymology, Starch chemistry, Starch metabolism, alpha-Glucosidases metabolism

Abstract

To produce sufficient amounts of glucose from food starch, both α-amylase and mucosal α-glucosidases are required. We found previously that the digestion rate of starch is influenced by its susceptibility to mucosal α-glucosidases. In the present study, six starches and one glycogen were pre-hydrolyzed by α-amylase for various time periods, and then further hydrolyzed with the mucosal α-glucosidase, the N-terminal subunit of maltase-glucoamylase (Nt-MGAM), to generate free glucose. Results showed that α-amylase amplified the Nt-MGAM glucogenesis, and that the amplifications differed in various substrates. The amount of branches within α-amylase hydrolysate substrates was highly related to the rate of Nt-MGAM glucogenesis. After de-branching, the hydrolysates showed three fractions, Fraction 1, 2, and 3, in size exclusion chromatographs. We found that the α-amylase hydrolysates with higher quantity of the Fraction 3 (molecules with relatively short chain-length) and shorter average chain-length of this fraction had lower rates of Nt-MGAM glucogenesis. This study revealed that the branch pattern of α-amylase hydrolysates modulates glucose release by Nt-MGAM. It further supported the hypothesis that the internal structure of starch affects its digestibility at the mucosal α-glucosidase level., (Published by Elsevier Ltd.)

Published

2014

12. Mucosal C-terminal maltase-glucoamylase hydrolyzes large size starch digestion products that may contribute to rapid postprandial glucose generation.

Author

Lee BH, Lin AH, Nichols BL, Jones K, Rose DR, Quezada-Calvillo R, and Hamaker BR

Subjects

Blood Glucose metabolism, Digestion, Duodenum metabolism, Humans, Hydrolysis, Maltose analogs & derivatives, Maltose metabolism, Mucous Membrane metabolism, Oligosaccharides metabolism, Polysaccharides metabolism, Postprandial Period, Recombinant Proteins metabolism, alpha-Amylases metabolism, Glucose metabolism, Starch chemistry, alpha-Glucosidases metabolism

Abstract

Scope: The four mucosal α-glucosidases, which differ in their digestive roles, generate glucose from glycemic carbohydrates and accordingly can be viewed as a control point for rate of glucose delivery to the body. In this study, individual recombinant enzymes were used to understand how α-glucan oligomers are digested by each enzyme, and how intermediate α-amylolyzed starches are hydrolyzed, to elucidate a strategy for moderating the glycemic spike of rapidly digestible starchy foods., Methods and Results: The C-terminal maltase-glucoamylase (ctMGAM, commonly termed "glucoamylase") was able to rapidly hydrolyze longer maltooligosaccharides, such as maltotetraose and maltopentaose, to glucose. Moreover, it was found to convert larger size maltodextrins, as would be produced early in α-amylase digestion of starch, efficiently to glucose. It is postulated that ctMGAM has the additional capacity to hydrolyze large α-amylase products that are produced immediately on starch digestion in the duodenum and contribute to the rapid generation of glucose from starch-based meals., Conclusion: The findings suggest that partial inhibition of ctMGAM, such as by natural inhibitors found in foods, might be used to moderate the early stage of high glycemic response, as well as to extend digestion distally; thereby having relevance in regulating glucose delivery to the body., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

13. Maltase-glucoamylase modulates gluconeogenesis and sucrase-isomaltase dominates starch digestion glucogenesis.

Author

Diaz-Sotomayor M, Quezada-Calvillo R, Avery SE, Chacko SK, Yan LK, Lin AH, Ao ZH, Hamaker BR, and Nichols BL

Subjects

Animals, Blood Glucose metabolism, Intestinal Mucosa enzymology, Intestinal Mucosa metabolism, Intestine, Small enzymology, Intestine, Small metabolism, Mice, Mice, Knockout, Mutation, Postprandial Period, alpha-Glucosidases genetics, Dietary Carbohydrates metabolism, Digestion genetics, Gluconeogenesis, Glucose metabolism, Starch metabolism, Sucrase-Isomaltase Complex metabolism, alpha-Glucosidases metabolism

Abstract

Objectives: Six enzyme activities are needed to digest starch to absorbable free glucose; 2 luminal α-amylases (AMY) and 4 mucosal maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI) subunit activities are involved in the digestion. The AMY activities break down starch to soluble oligomeric dextrins; mucosal MGAM and SI can either directly digest starch to glucose or convert the post-α-amylolytic dextrins to glucose. We hypothesized that MGAM, with higher maltase than SI, drives digestion on ad limitum intakes and SI, with lower activity but more abundant amount, constrains ad libitum starch digestion., Methods: Mgam null and wild-type (WT) mice were fed with starch diets ad libitum and ad limitum. Fractional glucogenesis (fGG) derived from starch was measured and fractional gluconeogenesis and glycogenolysis were calculated. Carbohydrates in small intestine were determined., Results: After ad libitum meals, null and WT had similar increases of blood glucose concentration. At low intakes, null mice had less (f)GG (P = 0.02) than WT mice, demonstrating the role of Mgam activity in ad limitum feeding; null mice did not reduce fGG responses to ad libitum intakes demonstrating the dominant role of SI activity during full feeding. Although fGG was rising after feeding, fractional gluconeogenesis fell, especially for null mice., Conclusions: The fGNG (endogenous glucogenesis) in null mice complemented the fGG (exogenous glucogenesis) to conserve prandial blood glucose concentrations. The hypotheses that Mgam contributes a high-efficiency activity on ad limitum intakes and SI dominates on ad libitum starch digestion were confirmed.

Published

2013

14. Mammalian mucosal α-glucosidases coordinate with α-amylase in the initial starch hydrolysis stage to have a role in starch digestion beyond glucogenesis.

Author

Dhital S, Lin AH, Hamaker BR, Gidley MJ, and Muniandy A

Subjects

Animals, Humans, Hydrolysis, Intestines enzymology, Kinetics, Maltose metabolism, Molecular Weight, Pancreas enzymology, Protein Subunits metabolism, Rats, Starch chemistry, Stereoisomerism, Temperature, Zea mays chemistry, Glucose biosynthesis, Mucous Membrane enzymology, Starch metabolism, alpha-Amylases metabolism, alpha-Glucosidases metabolism

Abstract

Starch digestion in the human body is typically viewed in a sequential manner beginning with α-amylase and followed by α-glucosidase to produce glucose. This report indicates that the two enzyme types can act synergistically to digest granular starch structure. The aim of this study was to investigate how the mucosal α-glucosidases act with α-amylase to digest granular starch. Two types of enzyme extracts, pancreatic and intestinal extracts, were applied. The pancreatic extract containing predominantly α-amylase, and intestinal extract containing a combination of α-amylase and mucosal α-glucosidase activities, were applied to three granular maize starches with different amylose contents in an in vitro system. Relative glucogenesis, released maltooligosaccharide amounts, and structural changes of degraded residues were examined. Pancreatic extract-treated starches showed a hydrolysis limit over the 12 h incubation period with residues having a higher gelatinization temperature than the native starch. α-Amylase combined with the mucosal α-glucosidases in the intestinal extract showed higher glucogenesis as expected, but also higher maltooligosaccharide amounts indicating an overall greater degree of granular starch breakdown. Starch residues after intestinal extract digestion showed more starch fragmentation, higher gelatinization temperature, higher crystallinity (without any change in polymorph), and an increase of intermediate-sized or small-sized fractions of starch molecules, but did not show preferential hydrolysis of either amylose or amylopectin. Direct digestion of granular starch by mammalian recombinant mucosal α-glucosidases was observed which shows that these enzymes may work either independently or together with α-amylase to digest starch. Thus, mucosal α-glucosidases can have a synergistic effect with α-amylase on granular starch digestion, consistent with a role in overall starch digestion beyond their primary glucogenesis function.

Published

2013

15. Enzyme-synthesized highly branched maltodextrins have slow glucose generation at the mucosal α-glucosidase level and are slowly digestible in vivo.

Author

Lee BH, Yan L, Phillips RJ, Reuhs BL, Jones K, Rose DR, Nichols BL, Quezada-Calvillo R, Yoo SH, and Hamaker BR

Subjects

Animals, Blood Glucose, Humans, Hydrolysis, Male, Molecular Weight, Mucous Membrane enzymology, Nuclear Magnetic Resonance, Biomolecular, Rats, Recombinant Proteins metabolism, Starch chemistry, Starch metabolism, Glucose biosynthesis, Glucose chemistry, Polysaccharides chemistry, Polysaccharides metabolism, alpha-Glucosidases metabolism

Abstract

For digestion of starch in humans, α-amylase first hydrolyzes starch molecules to produce α-limit dextrins, followed by complete hydrolysis to glucose by the mucosal α-glucosidases in the small intestine. It is known that α-1,6 linkages in starch are hydrolyzed at a lower rate than are α-1,4 linkages. Here, to create designed slowly digestible carbohydrates, the structure of waxy corn starch (WCS) was modified using a known branching enzyme alone (BE) and an in combination with β-amylase (BA) to increase further the α-1,6 branching ratio. The digestibility of the enzymatically synthesized products was investigated using α-amylase and four recombinant mammalian mucosal α-glucosidases. Enzyme-modified products (BE-WCS and BEBA-WCS) had increased percentage of α-1,6 linkages (WCS: 5.3%, BE-WCS: 7.1%, and BEBA-WCS: 12.9%), decreased weight-average molecular weight (WCS: 1.73×10(8) Da, BE-WCS: 2.76×10(5) Da, and BEBA-WCS 1.62×10(5) Da), and changes in linear chain distributions (WCS: 21.6, BE-WCS: 16.9, BEBA-WCS: 12.2 DPw). Hydrolysis by human pancreatic α-amylase resulted in an increase in the amount of branched α-limit dextrin from 26.8% (WCS) to 56.8% (BEBA-WCS). The α-amylolyzed samples were hydrolyzed by the individual α-glucosidases (100 U) and glucogenesis decreased with all as the branching ratio increased. This is the first report showing that hydrolysis rate of the mammalian mucosal α-glucosidases is limited by the amount of branched α-limit dextrin. When enzyme-treated materials were gavaged to rats, the level of postprandial blood glucose at 60 min from BEBA-WCS was significantly higher than for WCS or BE-WCS. Thus, highly branched glucan structures modified by BE and BA had a comparably slow digesting property both in vitro and in vivo. Such highly branched α-glucans show promise as a food ingredient to control postprandial glucose levels and to attain extended glucose release.

Published

2013

16. Starch digestion and patients with congenital sucrase-isomaltase deficiency.

Author

Hamaker BR, Lee BH, and Quezada-Calvillo R

Subjects

Carbohydrate Metabolism, Inborn Errors diet therapy, Humans, Sucrase-Isomaltase Complex metabolism, Carbohydrate Metabolism, Inborn Errors metabolism, Dietary Carbohydrates metabolism, Digestion, Intestine, Small enzymology, Starch metabolism, Sucrase-Isomaltase Complex deficiency, alpha-Glucosidases metabolism

Published

2012

17. Direct starch digestion by sucrase-isomaltase and maltase-glucoamylase.

Author

Lin AH, Hamaker BR, and Nichols BL Jr

Subjects

Carbohydrate Metabolism, Inborn Errors metabolism, Humans, Sucrase-Isomaltase Complex deficiency, Carbohydrate Metabolism, Inborn Errors diet therapy, Dietary Carbohydrates metabolism, Digestion, Starch metabolism, Sucrase-Isomaltase Complex metabolism, alpha-Glucosidases metabolism

Published

2012

18. Inhibition of maltase-glucoamylase activity to hydrolyze α-1,4 linkages by the presence of undigested sucrose.

Author

Lee BH, Quezada-Calvillo R, Nichols BL Jr, Rose DR, and Hamaker BR

Subjects

Humans, Hydrolysis, Sucrase-Isomaltase Complex metabolism, Carbohydrate Metabolism, Inborn Errors metabolism, Dietary Carbohydrates metabolism, Glycoside Hydrolase Inhibitors, Starch metabolism, Sucrase-Isomaltase Complex deficiency, Sucrose metabolism, alpha-Glucosidases metabolism

Published

2012

19. Starch source influences dietary glucose generation at the mucosal α-glucosidase level.

Author

Lin AH, Lee BH, Nichols BL, Quezada-Calvillo R, Rose DR, Naim HY, and Hamaker BR

Subjects

Animals, Humans, Hydrolysis, Kinetics, Mice, Molecular Weight, Protein Subunits chemistry, Starch chemistry, Zea mays chemistry, alpha-Amylases chemistry, Carbohydrate Metabolism, Dextrins chemistry, Glucose chemistry, Mucous Membrane enzymology, alpha-Glucosidases chemistry

Abstract

The quality of starch digestion, related to the rate and extent of release of dietary glucose, is associated with glycemia-related problems such as diabetes and other metabolic syndrome conditions. Here, we found that the rate of glucose generation from starch is unexpectedly associated with mucosal α-glucosidases and not just α-amylase. This understanding could lead to a new approach to regulate the glycemic response and glucose-related physiologic responses in the human body. There are six digestive enzymes for starch: salivary and pancreatic α-amylases and four mucosal α-glucosidases, including N- and C-terminal subunits of both maltase-glucoamylase and sucrase-isomaltase. Only the mucosal α-glucosidases provide the final hydrolytic activities to produce substantial free glucose. We report here the unique and shared roles of the individual α-glucosidases for α-glucans persisting after starch is extensively hydrolyzed by α-amylase (to produce α-limit dextrins (α-LDx)). All four α-glucosidases share digestion of linear regions of α-LDx, and three can hydrolyze branched fractions. The α-LDx, which were derived from different maize cultivars, were not all equally digested, revealing that the starch source influences glucose generation at the mucosal α-glucosidase level. We further discovered a fraction of α-LDx that was resistant to the extensive digestion by the mucosal α-glucosidases. Our study further challenges the conventional view that α-amylase is the only rate-determining enzyme involved in starch digestion and better defines the roles of individual and collective mucosal α-glucosidases. Strategies to control the rate of glucogenesis at the mucosal level could lead to regulation of the glycemic response and improved glucose management in the human body.

Published

2012

20. Modulation of starch digestion for slow glucose release through "toggling" of activities of mucosal α-glucosidases.

Author

Lee BH, Eskandari R, Jones K, Reddy KR, Quezada-Calvillo R, Nichols BL, Rose DR, Hamaker BR, and Pinto BM

Subjects

Animals, Diabetes Mellitus metabolism, Drosophila melanogaster, Glycoside Hydrolases chemistry, Glycosylation, Humans, Hydrolysis, Inhibitory Concentration 50, Intestinal Mucosa metabolism, Kinetics, Mice, Models, Chemical, Obesity metabolism, Protein Structure, Tertiary, Recombinant Proteins chemistry, Glucose metabolism, Mucous Membrane enzymology, alpha-Glucosidases metabolism

Abstract

Starch digestion involves the breakdown by α-amylase to small linear and branched malto-oligosaccharides, which are in turn hydrolyzed to glucose by the mucosal α-glucosidases, maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI). MGAM and SI are anchored to the small intestinal brush-border epithelial cells, and each contains a catalytic N- and C-terminal subunit. All four subunits have α-1,4-exohydrolytic glucosidase activity, and the SI N-terminal subunit has an additional exo-debranching activity on the α-1,6-linkage. Inhibition of α-amylase and/or α-glucosidases is a strategy for treatment of type 2 diabetes. We illustrate here the concept of "toggling": differential inhibition of subunits to examine more refined control of glucogenesis of the α-amylolyzed starch malto-oligosaccharides with the aim of slow glucose delivery. Recombinant MGAM and SI subunits were individually assayed with α-amylolyzed waxy corn starch, consisting mainly of maltose, maltotriose, and branched α-limit dextrins, as substrate in the presence of four different inhibitors: acarbose and three sulfonium ion compounds. The IC(50) values show that the four α-glucosidase subunits could be differentially inhibited. The results support the prospect of controlling starch digestion rates to induce slow glucose release through the toggling of activities of the mucosal α-glucosidases by selective enzyme inhibition. This approach could also be used to probe associated metabolic diseases.

Published

2012

21. Unexpected high digestion rate of cooked starch by the Ct-maltase-glucoamylase small intestine mucosal α-glucosidase subunit.

Author

Lin AH, Nichols BL, Quezada-Calvillo R, Avery SE, Sim L, Rose DR, Naim HY, and Hamaker BR

Subjects

Animals, Cooking, Digestion, Gelatin metabolism, Hot Temperature, Humans, Intestinal Mucosa enzymology, Intestinal Mucosa metabolism, Intestine, Small metabolism, Mice, Protein Subunits metabolism, Recombinant Proteins metabolism, alpha-Amylases metabolism, alpha-Glucosidases genetics, Intestine, Small enzymology, Starch metabolism, alpha-Glucosidases metabolism

Abstract

For starch digestion to glucose, two luminal α-amylases and four gut mucosal α-glucosidase subunits are employed. The aim of this research was to investigate, for the first time, direct digestion capability of individual mucosal α-glucosidases on cooked (gelatinized) starch. Gelatinized normal maize starch was digested with N- and C-terminal subunits of recombinant mammalian maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI) of varying amounts and digestion periods. Without the aid of α-amylase, Ct-MGAM demonstrated an unexpected rapid and high digestion degree near 80%, while other subunits showed 20 to 30% digestion. These findings suggest that Ct-MGAM assists α-amylase in digesting starch molecules and potentially may compensate for developmental or pathological amylase deficiencies.

Published

2012

22. Mucosal maltase-glucoamylase plays a crucial role in starch digestion and prandial glucose homeostasis of mice.

Author

Nichols BL, Quezada-Calvillo R, Robayo-Torres CC, Ao Z, Hamaker BR, Butte NF, Marini J, Jahoor F, and Sterchi EE

Subjects

Animal Feed, Animals, Fasting, Genotype, Insulin blood, Mice, Mice, Knockout, Mucous Membrane enzymology, Sucrase metabolism, alpha-Glucosidases deficiency, alpha-Glucosidases genetics, Digestion, Glucose metabolism, Homeostasis, Starch metabolism, alpha-Glucosidases metabolism

Abstract

Starch is the major source of food glucose and its digestion requires small intestinal alpha-glucosidic activities provided by the 2 soluble amylases and 4 enzymes bound to the mucosal surface of enterocytes. Two of these mucosal activities are associated with sucrase-isomaltase complex, while another 2 are named maltase-glucoamylase (Mgam) in mice. Because the role of Mgam in alpha-glucogenic digestion of starch is not well understood, the Mgam gene was ablated in mice to determine its role in the digestion of diets with a high content of normal corn starch (CS) and resulting glucose homeostasis. Four days of unrestricted ingestion of CS increased intestinal alpha-glucosidic activities in wild-type (WT) mice but did not affect the activities of Mgam-null mice. The blood glucose responses to CS ingestion did not differ between null and WT mice; however, insulinemic responses elicited in WT mice by CS consumption were undetectable in null mice. Studies of the metabolic route followed by glucose derived from intestinal digestion of (13)C-labeled and amylase-predigested algal starch performed by gastric infusion showed that, in null mice, the capacity for starch digestion and its contribution to blood glucose was reduced by 40% compared with WT mice. The reduced alpha-glucogenesis of null mice was most probably compensated for by increased hepatic gluconeogenesis, maintaining prandial glucose concentration and total flux at levels comparable to those of WT mice. In conclusion, mucosal alpha-glucogenic activity of Mgam plays a crucial role in the regulation of prandial glucose homeostasis.

Published

2009

23. Luminal starch substrate "brake" on maltase-glucoamylase activity is located within the glucoamylase subunit.

Author

Quezada-Calvillo R, Sim L, Ao Z, Hamaker BR, Quaroni A, Brayer GD, Sterchi EE, Robayo-Torres CC, Rose DR, and Nichols BL

Subjects

Acarbose, Catalysis, Dextrins metabolism, Humans, Hydrogen-Ion Concentration, Oligosaccharides metabolism, Polysaccharides metabolism, Protein Subunits metabolism, Recombinant Proteins, Sucrase-Isomaltase Complex metabolism, alpha-Glucosidases metabolism, Glycoside Hydrolase Inhibitors, Protein Subunits chemistry, Starch metabolism, alpha-Glucosidases chemistry

Abstract

The detailed mechanistic aspects for the final starch digestion process leading to effective alpha-glucogenesis by the 2 mucosal alpha-glucosidases, human sucrase-isomaltase complex (SI) and human maltase-glucoamylase (MGAM), are poorly understood. This is due to the structural complexity and vast variety of starches and their intermediate digestion products, the poorly understood enzyme-substrate interactions occurring during the digestive process, and the limited knowledge of the structure-function properties of SI and MGAM. Here we analyzed the basic catalytic properties of the N-terminal subunit of MGAM (ntMGAM) on the hydrolysis of glucan substrates and compared it with those of human native MGAM isolated by immunochemical methods. In relation to native MGAM, ntMGAM displayed slower activity against maltose to maltopentose (G5) series glucose oligomers, as well as maltodextrins and alpha-limit dextrins, and failed to show the strong substrate inhibitory "brake" effect caused by maltotriose, maltotetrose, and G5 on the native enzyme. In addition, the inhibitory constant for acarbose was 2 orders of magnitude higher for ntMGAM than for native MGAM, suggesting lower affinity and/or fewer binding configurations of the active site in the recombinant enzyme. The results strongly suggested that the C-terminal subunit of MGAM has a greater catalytic efficiency due to a higher affinity for glucan substrates and larger number of binding configurations to its active site. Our results show for the first time, to our knowledge, that the C-terminal subunit of MGAM is responsible for the MGAM peptide's "glucoamylase" activity and is the location of the substrate inhibitory brake. In contrast, the membrane-bound ntMGAM subunit contains the poorly inhibitable "maltase" activity of the internally duplicated enzyme.

Published

2008

24. Luminal substrate "brake" on mucosal maltase-glucoamylase activity regulates total rate of starch digestion to glucose.

Author

Quezada-Calvillo R, Robayo-Torres CC, Ao Z, Hamaker BR, Quaroni A, Brayer GD, Sterchi EE, Baker SS, and Nichols BL

Subjects

Animals, Biopsy, Child, Digestion, Duodenum enzymology, Enterocytes enzymology, Humans, Immunoprecipitation, Intestinal Mucosa enzymology, Mice, Oligo-1,6-Glucosidase metabolism, Starch metabolism, Enterocytes metabolism, Glucan 1,4-alpha-Glucosidase metabolism, Glucose metabolism, Polysaccharides metabolism, alpha-Glucosidases metabolism

Abstract

Background: Starches are the major source of dietary glucose in weaned children and adults. However, small intestine alpha-glucogenesis by starch digestion is poorly understood due to substrate structural and chemical complexity, as well as the multiplicity of participating enzymes. Our objective was dissection of luminal and mucosal alpha-glucosidase activities participating in digestion of the soluble starch product maltodextrin (MDx)., Patients and Methods: Immunoprecipitated assays were performed on biopsy specimens and isolated enterocytes with MDx substrate., Results: Mucosal sucrase-isomaltase (SI) and maltase-glucoamylase (MGAM) contributed 85% of total in vitro alpha-glucogenesis. Recombinant human pancreatic alpha-amylase alone contributed <15% of in vitro alpha-glucogenesis; however, alpha-amylase strongly amplified the mucosal alpha-glucogenic activities by preprocessing of starch to short glucose oligomer substrates. At low glucose oligomer concentrations, MGAM was 10 times more active than SI, but at higher concentrations it experienced substrate inhibition whereas SI was not affected. The in vitro results indicated that MGAM activity is inhibited by alpha-amylase digested starch product "brake" and contributes only 20% of mucosal alpha-glucogenic activity. SI contributes most of the alpha-glucogenic activity at higher oligomer substrate concentrations., Conclusions: MGAM primes and SI activity sustains and constrains prandial alpha-glucogenesis from starch oligomers at approximately 5% of the uninhibited rate. This coupled mucosal mechanism may contribute to highly efficient glucogenesis from low-starch diets and play a role in meeting the high requirement for glucose during children's brain maturation. The brake could play a constraining role on rates of glucose production from higher-starch diets consumed by an older population at risk for degenerative metabolic disorders.

Published

2007

25. Contribution of mucosal maltase-glucoamylase activities to mouse small intestinal starch alpha-glucogenesis.

Author

Quezada-Calvillo R, Robayo-Torres CC, Opekun AR, Sen P, Ao Z, Hamaker BR, Quaroni A, Brayer GD, Wattler S, Nehls MC, Sterchi EE, and Nichols BL

Subjects

Acarbose metabolism, Acarbose pharmacology, Animals, Gene Expression Regulation, Enzymologic drug effects, Gene Expression Regulation, Enzymologic physiology, Isomaltose metabolism, Maltose metabolism, Mice, Mice, Knockout, alpha-Glucosidases genetics, Glucose biosynthesis, Intestinal Mucosa enzymology, Jejunum enzymology, Starch metabolism, alpha-Glucosidases metabolism

Abstract

Digestion of starch requires activities provided by 6 interactive small intestinal enzymes. Two of these are luminal endo-glucosidases named alpha-amylases. Four are exo-glucosidases bound to the luminal surface of enterocytes. These mucosal activities were identified as 4 different maltases. Two maltase activities were associated with sucrase-isomaltase. Two remaining maltases, lacking other identifying activities, were named maltase-glucoamylase. These 4 activities are better described as alpha-glucosidases because they digest all linear starch oligosaccharides to glucose. Because confusion persists about the relative roles of these 6 enzymes, we ablated maltase-glucoamylase gene expression by homologous recombination in Sv/129 mice. We assayed the alpha-glucogenic activities of the jejunal mucosa with and without added recombinant pancreatic alpha-amylase, using a range of food starch substrates. Compared with wild-type mucosa, null mucosa or alpha-amylase alone had little alpha-glucogenic activity. alpha-Amylase amplified wild-type and null mucosal alpha-glucogenesis. alpha-Amylase amplification was most potent against amylose and model resistant starches but was inactive against its final product limit-dextrin and its constituent glucosides. Both sucrase-isomaltase and maltase-glucoamylase were active with limit-dextrin substrate. These mucosal assays were corroborated by a 13C-limit-dextrin breath test. In conclusion, the global effect of maltase-glucoamylase ablation was a slowing of rates of mucosal alpha-glucogenesis. Maltase-glucoamylase determined rates of digestion of starch in normal mice and alpha-amylase served as an amplifier for mucosal starch digestion. Acarbose inhibition was most potent against maltase-glucoamylase activities of the wild-type mouse. The consortium of 6 interactive enzymes appears to be a mechanism for adaptation of alpha-glucogenesis to a wide range of food starches.

Published

2007

26. Evidence of native starch degradation with human small intestinal maltase-glucoamylase (recombinant).

Author

Ao Z, Quezada-Calvillo R, Sim L, Nichols BL, Rose DR, Sterchi EE, and Hamaker BR

Subjects

Digestion, Glucan 1,4-alpha-Glucosidase metabolism, Humans, Hydrolysis, Kinetics, Manihot, Pancreas enzymology, Recombinant Proteins metabolism, Rhizopus enzymology, Zea mays, alpha-Amylases metabolism, Intestine, Small enzymology, Starch metabolism, alpha-Glucosidases metabolism

Abstract

Action of human small intestinal brush border carbohydrate digesting enzymes is thought to involve only final hydrolysis reactions of oligosaccharides to monosaccharides. In vitro starch digestibility assays use fungal amyloglucosidase to provide this function. In this study, recombinant N-terminal subunit enzyme of human small intestinal maltase-glucoamylase (rhMGAM-N) was used to explore digestion of native starches from different botanical sources. The susceptibilities to enzyme hydrolysis varied among the starches. The rate and extent of hydrolysis of amylomaize-5 and amylomaize-7 into glucose were greater than for other starches. Such was not observed with fungal amyloglucosidase or pancreatic alpha-amylase. The degradation of native starch granules showed a surface furrowed pattern in random, radial, or tree-like arrangements that differed substantially from the erosion patterns of amyloglucosidase or alpha-amylase. The evidence of raw starch granule degradation with rhMGAM-N indicates that pancreatic alpha-amylase hydrolysis is not a requirement for native starch digestion in the human small intestine.

Published

2007