Structures of building blocks in clusters of sweetpotato amylopectin

φ,β-Limit dextrins of domains and clusters of sweetpotato amylopectin were subjected to extensive hydrolysis by Bacillus amyloliquefaciens α-amylase to release building blocks and reveal the internal structures of clusters. The composition of building blocks was analyzed by size-fractionation, gel permeation chromatography, and high performance anion exchange chromatography. Different domains and clusters had structurally similar building blocks with around three chains per building block and internal chain length around 2.9. Singly branched and doubly branched building blocks were the largest and second largest groups in the clusters. Type A clusters had more large building blocks and contained 5–6 blocks per cluster with an inter-block chain length (IB-CL) of 7.0, whereas type B clusters had less large building blocks and contained 3–4 blocks per cluster with IB-CL 7.9. Models on how the building blocks could be organized into type A and type B clusters are discussed.     

The building block structure of barley amylopectin

Amylopectin branchpoints are present in amorphous lamellae of starch granules and organised into densely branched areas, referred to as building blocks. One single amylopectin cluster contains several building blocks. This study investigated the building block structure of domains (groups of clusters) and clusters in four different barley genotypes. Two of the barleys possessed the amo1 mutation, Glacier Ac38 and the double recessive SW 49427 with both wax and amo1 mutations, and were compared with the two waxy type barleys Cinnamon and Cindy. A previous detailed study on these four barley genotypes showed that the amo1 mutation affected the internal structure of amylopectin as manifested in the composition of clusters. In this work the building blocks were isolated from domains and clusters by extensive treatment with liquefying α-amylase of Bacillus subtilis and structurally characterised with enzymatic and chromatographic techniques. The proportion of large building blocks with a high number of chains was increased in the amo1 barleys, and the chain length between the blocks was short, which explained the previous findings of large clusters with more dense structure in the amo1 amylopectins.     

Relationship between the distribution of the chain length of amylopectin and the crystalline structure of starch granules

The distributions of chain lengths in the amylopectins of starches from 20 species (11 A-, 6 B-, and 3 C-type) were characterised by h.p.l.c. in terms of the relationship between the molecular structure of the amylopectin and the crystalline structure of the starch granule. The weight-average chain-lengths of the amylopectins of the A-, B-, and C-type starches were in the ranges 23–29, 30–44, and 26–29, respectively. Gel-permeation chromatograms of the amylopectins debranched with isoamylase showed bimodal distributions of fractions containing long and short chains for 17 specimens (including corn, rice, potato, etc.) and trimodal distributions, of which the fraction containing short chains had twin peaks, for wheat, tapioca, and tulip amylopectins. The correlation coefficients between the average chain-lengths of amylopectins and the fractions of long and short chains and the ratio of the fractions of short and long chains by weight were 0.90, 0.69, and ?0.95, respectively. In general, amylopectin molecules of A-type starches have shorter chains in both the long- and short-chain fractions and larger amounts of the short-chain fractions than those of the B-type starches. The chain lengths of amylopectins of the C-type starches were intermediate and it is inferred that these starches possibly yield any type of crystalline structure depending on the environmental temperature and other factors, whereas the A- and B-type starches are insensitive to temperature.     

The effects of amylose content on the molecular size of amylose, and on the distribution of amylopectin chain length in maize starches

The amylose to amylopectin ratios in six maize starch samples of differing amylose contents were measured by enzymatic debranching, followed by high performance size exclusion chromatography (HPSEC). The molecular size of amyloses, estimated by -log K_wav, shows progressive decrease with the increase in amylose content in maize starches. The gel permeation chromatographs of the corresponding amylopectins, debranched with isoamylase, showed bimodal distributions containing long and short chains. The average chain length of amylopectin has a correlation with amylose content. The correlation coefficients between amylose content and average chain length, long chain length, weight ratio and the mole ratio of long and short chain length, were 0.97, 0.92, 0.96, 0.94 respectively. The maize starch with the highest amylose content has the lowest amylose molecular size and the longest chains, with a high ratio of long to short chains in its amylopectin fraction. Comparing the values of amylose content determined by HPSEC of starch or debranched starch with those of the iodinecomplex method, we conclude that long chains of amylopectin in high amylose starches contribute significantly to apparent amylose content.     

The cluster structure of barley amylopectins of different genetic backgrounds

The unit chains of amylopectin are organized into clusters. In this study, the cluster structure was analysed in detail in four different genotypes of barley, of which two possessed the amo1 genetic background. Amylose content of the barley starches differed from 0 to 32.6%. Isolated amylopectin was hydrolysed with α-amylase from Bacillus subtilis into domains, defined as groups of clusters, which were size-fractionated by methanol. The domain fractions were further treated with α-amylase to release single clusters. Amylopectin, domains and clusters were subsequently treated with phosphorylase and β-amylase to produce φ,β-limit dextrins and the detailed internal structures of these different structure levels were investigated. Analysis was performed with gel-permeation and anion-exchange chromatography. Equal amount of A-chains were detected in all barleys, but the distribution of B-chains differed. At least two types of domain structures were identified in all four barley varieties. Large domains were built up by large clusters and small domains by small clusters. In all four barley samples the number of long chains was small suggesting that shorter chains with a degree of polymerization of 25-35 also are involved in the interconnection of clusters. The cluster structure of the amylopectin correlated with the genetic background. The two barley samples with amo1 genetic background possessed a more dense structure. Internal chain lengths in these two barleys were shorter resulting in larger domains built up by larger clusters.     

Structural heterogeneity in waxy-rice starch

Alpha-amylase of B. amyloliquefaciens was used for the structural characterization of the amylopectin from waxy-rice starch. Fractions of -dextrins with a degree of polymerization (d.p.) <5000 were isolated from amylopectin hydrolysates after 1 and 3 h. φ,β-Limit dextrins were prepared by successive phosphorolysis and beta-amylolysis of the fractions and these were analysed by a second alpha-amylolysis. Based on the hydrolysis pattern, the limit dextrins were divided into two major groups, A and B, which possessed units of clusters of d.p. 100–200 and 90–130, respectively. An extensive alpha-amylolysis resulted in characteristic distributions of dextrins with d.p. <80 which represented branched building blocks. Type A dextrins possessed more larger building blocks with d.p. 40, but less intermediate and small blocks, than type B. The φ,β-limit dextrin of the original amylopectin had a distinct distribution enriched in small building blocks. A model is proposed in which the two types of dextrins originate from regular and less regular structural domains of the amylopectin fraction within the starch granules.     

Effects of amylopectin structure and molecular weight on microstructural and rheological properties of mixed beta-lactoglobulin gels

Nongelling amylopectin fractions from potato and barley have been used to form mixed beta-lactoglobulin gels. The amylopectin fractions were produced by varying the time of alpha-amylase hydrolysis followed by sequential ethanol precipitation. The molecular weights, radius of gyration, chain length distribution, and viscosity of the fractions were established. The mixed gels were analyzed rheologically with dynamic mechanical analysis in shear and microstructurally with light microscopy, transmission electron microscopy, and nuclear magnetic resonance spectroscopy. The result of the gel studies clearly showed that small differences in the molecular weight of amylopectins have a significant influence on the kinetics of protein aggregation and thereby on the gel microstructure and the rheological behavior of the gel. Both an increase in the molecular weight and a higher concentration of amylopectins resulted in a more open protein network structure, with thicker strands of larger and more close-packed beta-lactoglobulin clusters, which showed a larger storage modulus. The transmission electron micrographs revealed that degraded amylopectins were enclosed inside the protein clusters in the mixed gels, whereas nondegraded amylopectin was only found outside the protein clusters. The volume-weighted mean value of the molecular weight of the amylopectins was found to vary between 3.2 x 10(4) and 5.0 x 10(7) Da and the ratio of gyration between 14 and 61 nm. The maximum in chain length distribution was generally somewhat distributed toward longer chain lengths for potato compared to barley, but the differences in chain length distribution were minor compared to those seen in the molecular weight and ratio of gyration between the fractions.     

Heterogeneity in branching of amylopectin

The angular dependence of scattered light from amylopectin and its β-limit dextrin, the mean square radius of gyration and the molecular weights M_w and M_n have been calculated on the basis of the cascade branching theory for the homogeneously branched model by Meyer &; Bernfeld (1940) (Model I) and for the two heterogeneously branched structures suggested by French (1972) (Model II) and by Robin et al. (1974, 1975) (Model III). The calculations take into account the particularities of topology in branched molecules and the experimentally determined ratio of the number of A- and B-chains, A/B = 1. Furthermore, an average branching density of 4% and an interconnecting chain length of ovbar|n_i2 = 22, found by gel permeation chromatography (GPC) after debranching, were used. The constraints lead to the conclusion that amylopectin is heterogeneously branched. Densely branched clusters containing 3·22 branching units are interconnected by longer chains of 22 units in length. Comparison of the calculated angular dependence of light scattering with measurements from a maize amylopectin β-limit dextrin in 1 n NaOH solution gives strong evidence for a modified Robin-Mercier model. The modification consists of the conclusion that the interconnecting chains are preferentially B-chains, such that these chains carry on the average 1·4 clusters, while Robin and Mercier assume exactly 2 clusters. Our result is in agreement with the distribution of chain length found after debranching the amylopectin β-limit dextrin.     

Examination of molar-based distribution of A,B and C chains of amylopectin by fluorescent labeling with 2-aminopyridine

A method for determination of a molar-based distribution of A, B and C chains of amylopectin was developed. Labeling with fluorescent 2-aminopyridine was proportional to the number-average degree of polymerization (dp(n)) of the chains in the range of 6-440. Number-average chain lengths (cl(n)) of amylopectins from six different plant sources (rice, maize, wheat, potato, sweet potato and yam) determined by the labeling method were in good agreement with values obtained by determination of non-reducing residues. The molar-based distributions were polymodal (A, B(1) and B(2)+B(3) fractions) and characteristic to botanical sources. Amylopectins from starches with A-crystalline type had higher amount of A+B(1) chains (90-93% by mole) than starches with B-type (68-87%). Molar ratios of (A+B(1))/(B(2)+B(3)) were 8.9-12.9 for the A-type starches and 2.1-6.5 for the B-type starches, suggesting that amylopectins of A-type starches had 1.5-2 times more branches per cluster than B-type. The distributions of C chains, except for amylomaize, showed a broad, asymmetrical profile from dp approximately 10 to approximately 130 with a peak at dp approximately 40 and were very similar among botanical sources, suggesting that the biosynthetic process for C chains is similar in different plant species.     

Dermatan sulfates of normal and scarred fascia

We evaluated the composition of dermatan sulfates (DS) derived from 23 samples of normal and 23 samples of scarred fascia lata. We analyzed the molecular weight of intact DS chains and the length of chain regions comprising: (1) clusters of L-iduronate-containing disaccharides ("iduronic sections"); (2) clusters of D-glucuronate-containing disaccharides ("glucuronic sections"); and (3) copolymeric sections with both types of disaccharides. A portion of scarred fascia DS chains demonstrated higher molecular weight compared with those from normal tissue. Most disaccharides of DS chains derived from both fascia types form copolymeric segments - heterogeneous in size - with alternatively distributed single disaccharides with glucuronic residues and mainly single ones with iduronate. Only a small number of disaccharides form "glucuronic sections" of heterogeneous size or short "iduronic sections". However, the scarred fascia DS chains demonstrate an increased content of shorter "glucuronic sections" and shorter, often oversulfated, copolymeric segments. It seems that in normal fascia, the DS chain type with a single, long copolymeric region and a single, shorter "glucuronic section" is predominant, while in scarred tissue an increase in multidomain DS chain content may occur.     

Fine structure characterization of amylopectins from grain amaranth starch

The aim of this study was to determine the fine structure of amylopectin from grain amaranth. Amaranthus amylopectin was hydrolyzed with α-amylase, and single clusters and a group of clusters (domain) were isolated by methanol precipitation. The domain and the clusters were treated with phosphorylase a and then β-amylase to remove all external chains, whereby the internal structure was obtained. The ,β-limit dextrins were analyzed on Sepharose CL 6B. The average DP (degree of polymerization) and peak-DP values of fractions of clusters were 57 and 82, respectively; the values of the domain were 137 and 309, respectively. The unit chain length profiles were analyzed by high-performance anion-exchange chromatography with pulsed amperometric detector (HPAEC–PAD). The results showed that the domain fraction contained 2.2 clusters, and single clusters were composed of 13 chains. The ,β-limit dextrins of the clusters were further hydrolyzed with α-amylase to characterize their building block composition. The average DP of the branched blocks was 11 and they contained on average 2.5 chains. Their average chain length, internal chain length, and degree of branching were approximately 4.3, 2.8, and 14, respectively. A cluster consisted of 6 branched blocks, and the internal chain length between the blocks was 6.8.     

Structures of clusters in sweetpotato amylopectin

Sweetpotato amylopectin was subjected to partial hydrolysis by α-amylase from Bacillus amyloliquefaciens to release the clusters. Clusters were then fractionated and precipitated by methanol and structurally characterized by gel-permeation chromatography and high-performance anion-exchange chromatography. An initial stage of α-amylolysis on the amylopectin isolated mostly domains but also clusters. A second stage of α-amylolysis on the domains and clusters further isolated their respective clusters and sub-clusters. All the domains, clusters and sub-clusters were sequentially subjected to phosphorolysis and β-amylolysis to obtain their internal part. The degree of polymerization of the clusters in the form of φ,β-limit dextrins were from 58 to 86. Each domain contained 2–8 clusters. Two types of clusters were structurally identified. Type A clusters were larger and contained about 12 chains per cluster with higher degree of branching (DB), whereas those of type B were smaller and contained about eight chains per cluster with lower DB.     

Chemical and physical properties of ginkgo (Ginkgo biloba) starch

Starch isolated from mature Ginkgo biloba seeds and commercial normal maize starches were subjected to α-amylolysis and acid hydrolysis. Ginkgo starch was more resistant to pancreatic α-amylase hydrolysis than the normal maize starch. The chain length distribution of debranched amylopectin of the starches was analyzed by using high performance anion-exchange chromatography equipped with an amyloglucosidase reactor and a pulsed amperometric detector. The chain length distribution of ginkgo amylopectin showed higher amounts of both short and long chains compared to maize starch. Naegeli dextrins of the starches prepared by extensive acid hydrolysis over 12 days demonstrated that ginkgo starch was more susceptible than normal maize to acid hydrolysis. Ginkgo dextrins also demonstrate a lower concentration of singly branched chains than maize dextrins, and unlike maize dextrin, debranched ginkgo shows no multiple branched chains. The ginkgo starch displayed a C-type X-ray diffraction pattern, compared to an A-type pattern for maize. Ginkgo starch and maize starch contained 24.0 and 17.6% absolute amylose contents, respectively.     

The fine structure of rice-starch amylopectin and its relation to the texture of cooked rice

Starches derived from 20 rice varieties containing from very low to very high total and hot-water-insoluble amylose-equivalent (AE) were fractionated by gelpermeation chromatography (GPC). Fraction I (amylopectin) and fraction II (amylose) correlated well with the insoluble-AE and soluble-AE, respectively, of the parent rice. Thus soluble-AE broadly represented the true rice amylose and insoluble-AE the iodine affinity of amylopectin. Amylopectins of eight representative varieties were therefore debranched and fractionated by GPC to study their chain profiles. Amylopectins from the highest-AE variety had the largest proportion of long B chains and the lowest proportion of short chains, while the reverse was true for waxy rice. Other varieties broadly followed this correlation between B-chain length and AE. In addition, when the eight amylopectins were first hydrolysed with β-amylase to remove the external chains and the β-limit dextrins were then debranched and fractionated, the greatest drop in the amount of long B chains occurred in the highest-insoluble-AE variety and the smallest drop (nil), in waxy rice. In other words, highest-insoluble-AE (i.e. high-iodine-affinity) amylopectin had not only the highest amount of long B chains, but the largest proportion of these chains was in the exterior region (carrying non-reducing ends), and vice versa. Difference in cooked rice texture seemed to be related to this difference in the fine structure of its amylopectin.     

Soluble starch synthase I: a major determinant for the synthesis of amylopectin in Arabidopsis thaliana leaves

A minimum of four soluble starch synthase families have been documented in all starch-storing green plants. These activities are involved in amylopectin synthesis and are extremely well conserved throughout the plant kingdom. Mutants or transgenic plants defective for SSII and SSIII isoforms have been previously shown to have a large and specific impact on the synthesis of amylopectin while the function of the SSI type of enzymes has remained elusive. We report here that Arabidopsis mutants, lacking a plastidial starch synthase isoform belonging to the SSI family, display a major and novel type of structural alteration within their amylopectin. Comparative analysis of beta-limit dextrins for both wild type and mutant amylopectins suggests a specific and crucial function of SSI during the synthesis of transient starch in Arabidopsis leaves. Considering our own characterization of SSI activity and the previously described kinetic properties of maize SSI, our results suggest that the function of SSI is mainly involved in the synthesis of small outer chains during amylopectin cluster synthesis.     

A comparison of the size and shape of β-limit dextrin and amylopectin using pulsed field-gradient nuclear magnetic resonance and analytical ultracentrifugation

The size and shape of β-limit dextrin have been investigated by using pulsed, field-gradient nuclear magnetic resonance and analytical ultracentrifugation. In addition, the β-limit dextrin has been compared with the amylopectin from which it was derived by enzymic hydrolysis. When measuring size and shape, dimethyl sulfoxide was used as the solvent, in order to avoid problems of polymer agggregation. The results suggest that β-limit dextrin is an oblate ellipsoid with an axial ratio of ∼5:1, and the corresponding amylopectin molecule is even flatter. This indicates that the linear segments beyond the final branch-points of amylopectin lie in the plane of its branched core. The study also demonstrated that the density of packing of polymer chains in this branched core is much greater than at the periphery of amylopectin, and that the latter region is the location of the great majority of the nonreducing chains cleaved by beta amylase. Furthermore, the different sized molecules in amylopectin samples appear to undergo the same degree of degradation by this enzyme.     

Phosphate esters in amylopectin clusters of potato tuber starch

Starch phosphate is important in starch metabolism and in order to deduce its location and structural effects in clusters and building blocks of amylopectin, these were isolated from a normal potato (WT) and two starches with antisense suppressed glucan water dikinase (asGWD) activity and starch branching enzyme (asSBE) activity possessing suppressed and increased phosphate contents, respectively. Neutral N-chains and phosphorylated P-chains of the amylopectin macromolecules were similar in WT and asGWD, whereas asSBE possessed considerably longer P-chains. Cluster β-limit dextrins were isolated by α-amylase treatment and successive β-amylolysis. Cluster sizes were generally smaller in asSBE. The building block composition of neutral N-clusters were very similar in WT and asGWD, while asSBE was different, containing less blocks with degree of polymerization (DP)>14. Phosphate content of the P-clusters of WT and asGWD was rather similar, while asSBE contained highly phosphorylated P-clusters with proportionally more P-chains and a low degree of branching. The average chain lengths of the P-clusters were, however, similar in all samples. Our data demonstrate only minor effect on the cluster structure in relation to phosphate deposition suggesting conserved reaction patterns of starch phosphorylation. Models are suggested to account for the principle structural and functional effects of starch phosphate esters.     

The relationship between internal chain length of amylopectin and crystallinity in starch

Molecular models of amylopectin were created and investigated by computer simulation. First, single and double helices of various lengths were constructed. The 1 → 6 branching in double and single helices of amylopectin was studied. Subunits of single helices, double helices, and branch points were used as building blocks of larger systems. The possible makeup of amylopectin unit clusters was investigated via a series of models, including single–single, double–single, and double–double helix systems. The lengths of the single helix section that linked two branch points (internal chains) was systematically varied between values of 0–10 glucose residues. It was found that certain internal chain lengths lead to parallel double helices. Thus, it was postulated that the length of internal chains may determine the degree of local crystallinity. Furthermore, it was noted that some of the low‐energy arrangement of double helices could be superimposed on either the two adjacent and nonadjacent double helices of crystalline A and B starch polymorphs. In other cases, the distance between the double helices is so large that it may in fact be a model for branching between two amylopectin crystals or unit clusters. Results obtained through this work were corroborated, where possible, with information available from crystallographic, branching, and enzymatic studies. © 1999 John Wiley & Sons, Inc. Biopoly 50: 381–390, 1999     

Modeling of α(1–4) chain arrangements in α(1–4)(1–6) glucans: The action and outcome of β-amylase and Pseudomonas stutzeri amylase on an α(1–4)(1–6) glucan model

Simulated enzymic debranching of a β-limit dextrin model, prepared from a computed construct made by random extension and branching, and given the CCL value of w-maize amylopectin (and equal amounts of external chains with ECL values of 2 and 3) has been related to experimental chromatograms of the debranched β-limit dextrin of the amylopectin. The profile was similar to those from gel chromatograms and IEC-PAD chromatography.The equivalent lengths in glucosyl units of grid-links (g-links) of internal and external chains in constructs were calculated from the ICL and ECL values of amylopectin and models produced from the constructs with the appropriate lengths for internal and external chains. These derived models were subjected to simulated hydrolysis by Pseudomonas stutzeri amylase and the products compared with those of the experimental distribution from w-maize amylopectin. With the model the amounts of maltotetraose and maltodextrins released were similar to the experimental values but the distribution of branched maltodextrins was quite different. Unlike w-maize amylopectin – a polymer with the cluster structure – which has given a profile of molecular sizes of maltodextrins with low amounts of single and small numbers of internal chains and with a peak at a M_W of about 14,000 (13 chains), in the model the proportion of maltodextrin with one internal chain was high and as d.p. increased the amounts decreased exponentially. This would be expected if the distribution of internal chains in the core was random. It is suggested that in the core of a model prepared from a construct made with alternating probabilities of extension – one in which this probability is high relative to branching, and a second in which it is low – may give clusters of branched maltodextrins with short internal chains which are joined by longer chains; more closely approximating the distribution of internal chains of different lengths in amylopectin.An arrangement for amylopectin molecules in the starch granule has been proposed. In this, they have a wafer-like, discoidal shape, composed of the amorphous zone overlain with the double helical, crystalline region. The flat macromolecules are concentrically layered with the former on the inside and the latter oriented to the outside of the granule.     

Multiple branching in glycogen and amylopectin

The β-amylase limit dextrins of glycogen and amylopectin are completely debranched by joint action of isoamylase and pullulanase. Action of isoamylase alone results in incomplete debranching as a consequence of the inability of this enzyme to hydrolyze those A-chains that are two glucose units in length (half the total number of A-chains). From the reducing powers released by isoamylase acting (a) alone and (b) in conjunction with pullulanase, the relative numbers of A- (unsubstituted) and B- (substituted) chains in the β-dextrins, and therefore in the native polysaccharides themselves, can be calculated. Examination of a series of glycogens and amylopectins in this way showed that the ratio of A-chains: B-chains is markedly higher in amylopectins (1.5–2.6:1) than in glycogens (0.6–1.2:1). Glycogen typically contains A-chains and B-chains in approximately equal numbers; amylopectin typically contains approximately twice as many A-chains as B-chains. These polysaccharides therefore differ in degree of multiple branching as well as in average chain length. A consequence of these findings is that amylopectin cannot be formed in vivo by debranching of a glycogen precursor, as proposed by Erlander, since it is impossible to increase the A:B chain ratio by action of a debranching enzyme.