A possible structure of retrograded maize starch speculated by UV and IR spectra of it and its components

“Retrogradation” has been used to describe the changes that occur in starch after gelatinization, from an initially amorphous state to a more ordered or crystalline state, which has a significant impact on starch application in food, textiles and materials fields. But mechanism of starch retrogradation is still unclear until now and there is no breakthrough in this area. Here we are speculating a possible structure of retrograded maize starch by UV (binding with iodine) and IR spectra of it and its compositions. We speculate that nucleation of retrograded starch origins from combination of reducing end of amylopectin and non-reducing end of amylose, and retrogradation terminates at combining of non-reducing end of amylopectin and reducing end of amylose. The chain length of resistant digestion retrograded starch should be nearly same. The hydroxyl associated with sixth carbon atoms of glucan must form hydrogen bond with other hydroxyl of starch.     

Aqueous dissolution of crystalline and amorphous amylose-alcohol complexes

Complexes of amylose, the linear starch polysaccharide, with linear alcohols having chain lengths varying from 4 to 8 carbon atoms, were prepared. Either crystalline or amorphous complexes could be formed depending on preparation conditions. Crystalline complexes gave sharp X-ray diffraction patterns, characteristic of the V_H form of amylose, whereas no observable pattern was obtained from the amorphous form. Thermal dissociation of the complexes occurred at increasing temperatures with increasing alcohol chain length. Crystalline complexes dissociated at temperatures approximately 23°C higher than their amorphous counterparts and the enthalpy of dissociation was also greater for the crystalline samples. Enthalpy values were independent of alcohol chain length. Differences in thermal behaviour of the two types of complex may be described in terms of the polymer crystal lattice energy and may explain the variability of reported results for complex dissociation in the literature.     

Action of porcine-pancreatic amylase on oxidized-reduced amylose of low degree of modification

Amylose was oxidized with 0.1–0.2 mol of periodate per glucose residue (G), and then reduced with sodium borohydride or borotritide to give an oxidized-reduced amylose of low degree of modification. Mild acid hydrolysis gave erythritol, 2-O-α-d-glucosyl-l-erythritol, higher homologs, and other products. Extensive action of porcine-pancreatic amylase on the polymer gave, besides d-glucose and maltose, oligosaccharides containing one or more oxidized-reduced (modified, M), acyclic residues. The enzymic products containing only one oxidized-reduced residue were identified as a modified tetrasaccharide (MG₃) and a modified pentasaccharide (MG₄). Structures of MG₃ and MG₄ were identified by a combination of enzymic and chemical approaches. With glucoamylase, MG₄ was converted into MG plus d-glucose, whereas MG₃ was totally resistant. On mild acidic hydrolysis, MG₃ was converted into 2-O-α-d-glucosyl-d-erythritol plus maltose. These results indicate that MG₃ is G-M-G-G and that MG₄ is G-G-M-G-G. In principle, MG₄ could occupy the five d-glucose residue, substrate-binding site of porcine-pancreatic amylase in such a way that M, the acyclic structure replacing a d-glucose residue, is placed just to the “left” of the catalytic site. The modified structure, being very vulnerable to acidic hydrolysis, might then be expected to be very readily attacked by the amylase, but in fact, it is not.     

Studies on Action Pattern of Amylase-catalized Hydrolysis of Amylose Using TNS Fluorescence as a Probe

A large fluorescence enhancement of 2-p-toluidinylnaphthalene-6-suIfonate (TNS) caused by amylose decreases as the substrate is degraded by amylases. This property was used to follow the enzymatic hydrolysis of amylose and analyze the action pattern of six kinds of amylases. This method can substitute the conventional blue value method, and is more sensitive for short chain amylodextrins. The advantage of the new method over the blue value method is that it is useful to monitor the hydrolysis of maltooligosaccharides to which the blue value method cannot be applicable, and that it enables continuous monitoring of the enzyme reactions.     

Temperature effect on retrogradation rate and crystalline structure of amylose

Commercial potato amylose was used to study temperature effects on the retrogradation of amylose solutions (3.5mg/ml). The retrogradation rate decreased as incubation temperature increased (5 to 45 °C). The degree of retrogradation within 24 h decreased from 58.8 to 7.1% as incubation temperature increased from 5 to 45 °C. In the amylose solution, different-sized molecular subfractions retrograded at different rates. After incubating at 5 °C for 100 days, the majority of the amylose molecules retrograded and precipitated from the solution; at 45 °C, only amylose of the small-molecular subfraction (number average, DP_n = 110; weight average, DP_w = 150) retrograded and precipitated. Entanglement of molecules was observed in size exclusion chromatograms. The morphology of retrograded amylose observed by using a scanning electron microscope differed with the retrogradation temperature. The chain length of amylose crystalline segments, prepared by hydrolysis of retrograded amylose, showed a narrow distribution (polydispersity from 1.21 to 1.67). The chain lengths of resistant segments increased DP_n from 39 to 52 and DP_w from 47 to 72 for α-amylolysis and DP_n from 34 to 40 and DP_w from 48 to 67 for 16% sulfuric acid hydrolysis, when incubation temperature increased from 5 to 45 °C.     

Conformational features of a hexapeptide model Ac-TGAAKA-NH2 corresponding to a hydrated alpha helical segment from glyceraldehyde 3-phosphate dehydrogenase: implications for the role of turns in helix folding

Recent analysis of alpha helices in protein crystal structures, available in literature, revealed hydrated alpha helical segments in which, water molecule breaks open helix 5-->1 hydrogen bond by inserting itself, hydrogen bonds to both C=O and NH groups of helix hydrogen bond without disrupting the helix hydrogen bond, and hydrogen bonds to either C=O or NH of helix hydrogen bond. These hydrated segments display a variety of turn conformations and are thought to be 'folding intermediates' trapped during folding-unfolding of alpha helices. A role for reverse turns is implicated in the folding of alpha helices. We considered a hexapeptide model Ac-1TGAAKA6-NH2 from glyceraldehyde 3-phosphate dehydrogenase, corresponding to a hydrated helical segment to assess its role in helix folding. The sequence is a site for two 'folding intermediates'. The conformational features of the model peptide have been investigated by 1H 2D NMR techniques and quantum mechanical perturbative configuration interaction over localized orbitals (PCILO) method. Theoretical modeling largely correlates with experimental observations. Based upon the amide proton temperature coefficients, the observed d alpha n(i, i + 1), d alpha n(i, i + 2), dnn(i, i + 1), d beta n(i, i + 1) NOEs and the results from theoretical modeling, we conclude that the residues of the peptide sample alpha helical and neck regions of the Ramachandran phi, psi map with reduced conformational entropy and there is a potential for turn conformations at N and C terminal ends of the peptide. The role of reduced conformational entropy and turn potential in helix formation have been discussed. We conclude that the peptide sequence can serve as a 'folding intermediate' in the helix folding of glyceraldehyde 3-phosphate dehydrogenase.     

Purification and Properties of Extracellular Amylase from the Hyperthermophilic Archaeon Thermococcus profundus DT5432

A hyperthermophilic archaeon, Thermococcus profundus DT5432, produced extracellular thermostable amylases. One of the amylases (amylase S) was purified to homogeneity by ammonium sulfate precipitation, DEAE-Toyopearl chromatography, and gel filtration on Superdex 200HR. The molecular weight of the enzyme was estimated to be 42,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The amylase exhibited maximal activity at pH 5.5 to 6.0 and was stable in the range of pH 5.9 to 9.8. The optimum temperature for the activity was 80(deg)C. Half-life of the enzyme was 3 h at 80(deg)C and 15 min at 90(deg)C. Thermostability of the enzyme was enhanced in the presence of 5 mM Ca(sup2+) or 0.5% soluble starch at temperatures above 80(deg)C. The enzyme activity was inhibited in the presence of 5 mM iodoacetic acid or 1 mM N-bromosuccinimide, suggesting that cysteine and tryptophan residues play an important role in the catalytic action. The amylase hydrolyzed soluble starch, amylose, amylopectin, and glycogen to produce maltose and maltotriose of (alpha)-configuration as the main products. Smaller amounts of larger maltooligosaccharides were also produced with a trace amount of glucose. Pullulan; (alpha)-, (beta)-, and (gamma)-cyclodextrins; maltose; and maltotriose were not hydrolyzed.     

Development of a low glycemic maize starch: preparation and characterization

A low glycemic index starch was developed by partial alpha-amylase treatment, and its fine structure responsible for slowly digestible and resistant properties was investigated. Different digestion rates were obtained for gelatinized, retrograded starch by varying the enzyme dosage and reaction time. Analysis by high performance size-exclusion chromatography (HPSEC) coupled with multiangle laser-light scattering indicated that the molecular weighs of amylopectin and amylose were reduced during the digestion, to less than 100 kDa. A debranched chain length study using high performance anion-exchange chromatography equipped with an amyloglucosidase reactor and a pulsed amperometric detector and HPSEC revealed that short chains of amylopectin and noncrystalline amylose were rapidly digested, while DPn 121 chains showed resistance, followed by DPn 46 chains. X-ray diffraction analysis revealed that the crystalline structure in the treated starches survived cooking. These starches not only have slowly digestible and resistant character, but also retain some branched structure for adequate functionality.     

The amylase gene-enzyme system of chickens. II. Biochemical characterization of allozymes

The chicken amylase allozymes, AmyF and AmyS, were extracted from pancreatic tissues of AmyF/F and AmyS/S individuals and purified. Activities were measured under various reaction conditions (= treatments) to assess whether the allozymes were functionally different. The amylases had properties typical of alpha-amylases, i.e., both were inhibited by ethylenediaminetetraacetate and alpha-amylase inhibitor from wheat, had pH optima between 7.0 and 8.0, and could utilize a variety of substrates containing alpha 1,4 linkages. The amylases were also found to be inhibited by potassium phosphate buffer and p-chloromercuribenzoate. In terms of substrate specificity, both amylases could utilize all of the substrates tested with activity observed in the following order: amylopectin greater than potato starch greater than dextrin greater than glycogen greater than amylose. Statistical analysis indicated significant functional differences between the two allozymes in terms of specific activities, substrate specificities, and inhibitor sensitivities. AmyF had a significantly lower specific activity than did AmyS. The amylases responded differently to the substrate amylose, with AmyF better able to digest this substrate. AmyS was less sensitive than AmyF to alpha-amylase inhibitor from wheat.     

Crystallinity and structure of starch using wide angle X-ray scattering

Wide angle X-ray diffraction was used to evaluate the crystalline fraction of a variety of starches, using preliminary smoothing then an iterative smoothing algorithm to estimate amorphous background scattering. This methodology was then used to determine initial crystallinity and monitor gelation and retrogradation of high amylose thermoplastic starch used to produce film. Retrogradation was monitored over a 5-day period. It was found that the starch film retrograded rapidly over the first 12 h with the film displaying both B-type crystallinity and long range amorphous ordering that were separately quantitatively calculated. Changes in starch films, including complete or partial gelatinization, retrogradation and crystallinity, were all determined through wide angle X-ray diffraction.     

Digestive amylase of a primitive animal,the scorpion: Purification and biochemical characterization

Scorpion, one of the most ancient invertebrates was chosen, as a model of a primitive animal, to purify and characterize an amylase located in the hepatopancreas. The scorpion digestive amylase (SDA) was purified. Pure SDA was obtained after heat treatment followed by ammonium sulfate fractionation and three steps of chromatography. The pure amylase is not glycosylated and has a molecular mass of 59,101 Da determined by MALDI-TOF MS analysis. The maximal amylase activity was measured at pH 7.0 and 50 °C, in the presence of Ca²⁺ and using potato starch as substrate. The enzyme was able to hydrolyze also, glycogen and amylose. The 23 NH₂-terminal amino acid SDA residues were sequenced. The sequence obtained is similar to those of mammalian and avian pancreatic amylases. Nevertheless, polyclonal antibodies directed against SDA failed to recognize classical digestive amylases like the porcine pancreatic one.     

Proline residues in transmembrane alpha helices affect the folding of bacteriorhodopsin

Proline residues occur frequently in transmembrane alpha helices, which contrasts with their behaviour as helix-breakers in water-soluble proteins. The three membrane-embedded proline residues of bacteriorhodopsin have been replaced individually by alanine and glycine to give P50A, or P50G on helix B, P91A, or P91G on helix C, and P186A or P186G on helix F, and the effect on the protein folding kinetics has been investigated. The rate-limiting apoprotein folding step, which results in formation of a seven transmembrane, alpha helical state, was slower than wild-type protein for the Pro50 and Pro91 mutants, regardless of whether they were mutated to Ala or Gly. These proline residues give rise to several inter-helix contacts, which are therefore important in folding to the seven transmembrane helix state. No evidence for cis-trans isomerisations of the peptidyl prolyl bonds was found during this rate-limiting apoprotein folding step. Mutations of all three membrane-embedded proline residues affected the subsequent retinal binding and final folding to bacteriorhodopsin, suggesting that these proline residues contribute to formation of the retinal binding pocket within the helix bundle, again via helix/helix interactions. These results point to proline residues in transmembrane alpha helices being important in the folding of integral membrane proteins. The helix/helix interactions and hydrogen bonds that arise from the presence of proline residues in transmembrane alpha helices can affect the formation of transmembrane alpha helix bundles as well as cofactor binding pockets.     

De novo design: backbone conformational constraints in nucleating helices and beta-hairpins.

A modular approach to synthetic protein design is being developed using conformationally constrained amino acid as stereochemical directors of polypeptide chain folding. An overview of studies aimed at constructing peptide helices using alpha,alpha-dialkyated residues and beta-hairpins using D-Pro as a turn nucleator is presented. The construction of helix-helix motifs and three- and four-stranded structures has been achieved using non-protein amino acids to stabilize specific elements of secondary structures.     

Reactions of alpha amylases with starch granules in aqueous suspension giving products in solution and in a minimum amount of water giving products inside the granule

Porcine pancreatic alpha amylase (PPA) and Bacillus amyloliquefaciens alpha amylase (BAA) were allowed to react with starch granules from maize, waxy maize, amylomaize-7, and potato in an aqueous suspension with a starch to water ratio of 1:10 and in a minimum of water with a starch to water ratio of 1:1. Quantitative amounts of the maltodextrin products were determined by TLC and scanning densitometry. The two alpha amylases gave different products that were characteristic of their unique action patterns. The percent conversion differed for the different kinds of starches and for the two kinds of reaction conditions. Maize and waxy maize starches were converted into about twice as much maltodextrins than were amylomaize-7 and potato starches by both enzymes and under both reaction conditions. The aqueous suspension gave much greater conversion into maltodextrins than did the minimum water condition. BAA gave 3-14% greater conversion of the granules into maltodextrins than did PPA, with the exception of potato starch.     

Amylopectin molecular structure reflected in macromolecular organization of granular starch

For lintners with negligible amylose retrogradation, crystallinity related inversely to starch amylose content and, irrespective of starch source, incomplete removal of amorphous material was shown. The latter was more pronounced for B-type than for A-type starches. The two predominant lintner populations, with modal degrees of polymerization (DP) of 13-15 and 23-27, were best resolved for amylose-deficient and A-type starches. Results indicate a more specific hydrolysis of amorphous lamellae in such starches. Small-angle X-ray scattering showed a more intense 9-nm scattering peak for native amylose-deficient A-type starches than for their regular or B-type analogues. The experimental evidence indicates a lower contrasting density within the "crystalline" shells of the latter starches. A higher density in the amorphous lamellae, envisaged by the lamellar helical model, explains the relative acid resistance of linear amylopectin chains with DP > 20, observed in lintners of B-type starches. Because amylopectin chain length distributions were similar for regular and amylose-deficient starches of the same crystal type, we deduce that the more dense (and ordered) packing of double helices into lamellar structures in amylose-deficient starches is due to a different amylopectin branching pattern.     

A model for the action of cereal alpha amylases on amylose

A model is proposed to explain the action of cereal alpha amylases (EC 3.2.1.1) on such linear substrates as amylose. It is suggested that, at the active site of the enzyme, there are nine contiguous subsites, each capable of interacting with a glucose residue. An estimate is made of the energies involved in subsite-glucose interaction, and values obtained for the binding energies are used to predict the distributions of small oligosaccharides to be expected at intermediate stages of amylose hydrolysis catalyzed by cereal alpha amylases.     

Folding mechanisms of proteins with high sequence identity but different folds

The problem of how a protein folds from a linear chain of amino acids to the three-dimensional structure necessary for function is often investigated using proteins with a low degree of sequence identity that adopt different folds. The design of pairs of proteins with a high degree of sequence identity but different folds offers the opportunity for a complementary study; in two highly similar sequences, which residues are the most important in directing folding to a particular structure? Here we use molecular dynamics simulations to characterize the folding-unfolding pathways of a pair of proteins designed by Bryan and co-workers [Alexander, P. A., et al. (2005) Biochemistry 44, 14045-14054; He, Y. N., et al. (2005) Biochemistry 44, 14055-14061]. Despite being 59% identical, the two protein sequences fold to two different structures. The first sequence folds to the alpha+beta protein G structure and the second to the all-alpha-helical protein A structure. We show that the final protein structure is determined early along the folding pathway. In folding to the protein G structure, the single alpha-helix (alpha1) and the beta3-beta4 turn fold early. Formation of the hairpin turn essentially prevents folding to helical structure in this region of the protein. This early structure is then consolidated by formation of long-range hydrophobic interactions between alpha1 and the beta3-beta4 turn. The protein A sequence differs both in the residues that form the beta3-beta4 turn and also in many of the residues that form the early hydrophobic interactions in the protein G structure. Instead, in the protein A sequence, a more hierarchical mechanism is observed, with helices folding before many of the tertiary interactions are formed. We find that small, but critical, sequence differences determine the topology of the protein early along the folding pathway, which help to explain the process by which one fold can evolve into another.     

Use of (13)c MAS NMR to study domain structure and dynamics of polysaccharides in the native starch granules

To investigate the domain structure and dynamics of polysaccharides in the native starch granules, a variety of high resolution, solid-state (13)C NMR techniques have been applied to all three (A-, B-, and C-) types of starch with different water content. Both single-pulse-excitation magic-angle-spinning (SPEMAS) and cross-polarization-magic-angle-spinning (CPMAS) methods have been employed together with the PRISE (proton relaxation induced spectral-editing) techniques to distinguish polysaccharide fractions in different domains and having distinct dynamics. It has been found that, for all three types of dry starch granules, there are two sets of NMR signals corresponding to two distinct ordered polysaccharides. Hydration leads to substantial mobilization of the polysaccharides in the amorphous regions, but no fundamental changes in the rigidity of the polysaccharides in the crystalline (double) helices. Full hydration also leads to limited mobility changes to the polysaccharides in the amorphous lamellae (branching zone) within the amylopectin clusters and in the gaps between the arrays of the amylopectin clusters. Under magic-angle spinning, proton relaxation-time measurements showed a single component for T(1), two components for T(1rho), and three components for T(2). PRISE experiments permitted the neat separation of the (13)C resonances of polysaccharides in the crystalline lamellae from those in the amorphous lamellae and the amylose in the gaps between amylopectin clusters. It has been found that the long (1)H T(1rho) component ( approximately 30 ms) is associated with polysaccharides in the crystalline lamellae in the form of double helices, whereas the short T(1rho) component (2-4 ms) is associated with amylose in the gaps between amylopectin clusters. The short (1)H T(2) component ( approximately 14 micros) is associated with polysaccharides in the crystalline lamellae; the intermediate component (300-400 micros) is associated with polysaccharides in the amorphous lamellae and amylose in the gaps between amylopectin clusters. The long T(2) component is associated with both mobile starch protons and the residue water protons.     

Effect of neohesperidin dihydrochalcone on the activity and stability of alpha‐amylase: a comparative study on bacterial,fungal, and mammalian enzymes

Neohesperidin dihydrochalcone (NHDC) was recently introduced as an activator of mammalian alpha‐amylase. In the current study, the effect of NHDC has been investigated on bacterial and fungal alpha‐amylases. Enzyme assays and kinetic analysis demonstrated the capability of NHDC to significantly activate both tested alpha‐amylases. The ligand activation pattern was found to be more similar between the fungal and mammalian enzyme in comparison with the bacterial one. Further, thermostability experiments indicated a stability increase in the presence of NHDC for the bacterial enzyme. In silico (docking) test locates a putative binding site for NHDC on alpha‐amylase surface in domain B. This domain shows differences in various alpha‐amylase types, and the different behavior of the ligand toward the studied enzymes may be attributed to this fact. Copyright © 2015 John Wiley & Sons, Ltd.     

Models for deploymerizing enzymes: criteria for discrimination of models

Several models for the action of alpha amylase have been proposed to account for the nonrandom distribution of oligosaccharides in the amylase digests of polysaccharides. The preferred-attack model attempts to account for the nonrandom distribution by assuming that the probability for bond cleavage depends upon the position of the bond in the chain. The repetitive, or multiple-attack, model suggests that the nonrandom distribution of oligosaccharides arises because an amylase can form a cage-like complex with a substrate and attack it several times during a single encounter. The multiple-enzyme or dual-site model suggests that the nonrandom yield of oligosaccharides arises from the combined action of exo- and endo-enzymes. The effects of pH, inhibitors, and substrate chain-length on enzyme action have been studied in several laboratories to determine which of the three action-patterns best describes the action of alpha amylase. The influence of these variables on product distributions or enzyme action-patterns are mathematically modeled in the Appendix. The experimental data on porcine-pancreatic alpha amylase are discussed in the light of the derivations.