Impact of Legume Flour Addition on Pasta Structure: Consequences on Its <Emphasis Type="Italic">In Vitro</Emphasis> Starch Digestibility

Pasta is popular for its ease of cooking and its low glycaemic index (GI). This interesting nutritional property can be attributed to its specific compact structure generally described as a protein network entrapping starch granules. Despite this low GI, pasta is poor in fibres and lack some essential amino acids. To enhance its nutritional composition, pasta can be fortified with non-traditional ingredients such as legume flours. The objective of this study was to investigate the impact of legume flour addition on pasta structure and the inherent consequences on the in vitro digestibility of starch. The addition of a high level (35%, w/w) of legume flour, especially split pea flour, induced some minor structural changes in pasta. The inclusion of fibres, the dilution of gluten proteins by albumins and globulins, and the larger amount of thin protein films (in split pea pasta) may have favoured higher susceptibility of starch to digestive enzymes. At the opposite, the presence of some partially gelatinised starch granules in the core of fortified pasta may have favoured the decrease in the in vitro starch digestibility. As a consequence, a high level of legume flour addition in pasta did not have any significant impact on its in vitro starch digestibility. A high level of split pea and faba bean flours can thus be added to pasta to increase its nutritional composition while keeping its low glycaemic index.     

Ruminal starch digestion characteristics in vitro of barley cultivars with varying amylose content

Three experiments were conducted to study effects of amylose/amylopectin ratios and starch particle size on ruminal digestion characteristics of barley starch using an automated in vitro gas production system. In Experiment 1, starch digestion characteristics were measured in 12 barley cultivars with different amylose/amylopectin ratios, both as milled grain and as purified starch isolated from the original grain samples. The same 12 cultivars, harvested 1 year later from the same locations, were used in Experiment 2. Gas production was measured in milled samples, and in neutral detergent fibre (NDF) extracted from the same samples. The objective of this approach was to estimate gas production from neutral detergent solubles (NDS) as an approximation of starch. This was done by subtracting the NDF gas curve from the total gas production curve. In Experiment 3, starch digestion characteristics were measured for large and small starch granules from nine of the original cultivars used in Experiment 1. The gas curves obtained were fitted to a three-pool Gompertz model, and the effective rate of digestion (kd) was estimated with a two-compartmental rumen model. In Experiment 1, the effective starch kd for milled barley and purified starch were 0.122 and 0.118/h, respectively. Barley cultivars with low amylose (LA) had a higher effective kd (0.148/h) compared with cultivars with normal amylose (NA) (0.115/h) and high amylose (HA) (0.102/h) (P=0.010). Results obtained with milled barley were supported by the purified barley starch sample results, but differences were smaller and only numerically different. In Experiment 2, the ranking of the amylose groups was consistent with those in Experiment 1 (i.e., LA > NA > HA) (P=0.096). However, these differences were not reflected in the effective kd for the NDS fraction (P=0.366). Thus, factors other than those related to starch per se, or other structural features, are apparently important. Barley cultivars in the LA group had a higher effective kd for aNDF (0.098/h) than did NA and HA barley (0.060 and 0.055/h, respectively). Thus, the effect of the amylose group on the effective kd for aNDF corresponded well with the milled barley results. The NDF fraction, directly or indirectly, has a clear impact on the ruminal digestion rate of barley starch. There was no difference in the effective kd for starch between the small (0.126/h) and large (0.129/h) starch granules.     

Legume-Fortified Pasta. Impact of Drying and Precooking Treatments on Pasta Structure and Inherent In Vitro Starch Digestibility

The low glycaemic index of pasta can be attributed to its specific structure. A change in pasta structure can therefore lead to a change in its starch digestibility. The use of drastic drying conditions or the addition of non-traditional ingredients to durum wheat pasta was already demonstrated to affect its structure, leading to a modification of its starch digestibility. However, the combining effect of using different technological treatments and different raw materials on pasta structure and consequences on its starch digestibility pasta are still unknown. The objective of this work was therefore to determine the impact of different technological treatments on the structure and the in vitro starch digestibility (i.e. rapidly available glucose value) of legume-fortified pasta. Legume-fortified pasta was prepared from 65% of durum wheat semolina and 35% of split pea or faba bean flour. Four different technological treatments were applied: drying at low temperature of 55 °C (LT), drying with the application of a very high temperature of 90 °C at low moisture content (VHT.LM), lyophilisation, and precooking followed by LT drying. Legume-fortified pasta dried at LT served as a reference. Lyophilisation induced a higher starch digestibility that could be attributed to the high porosity of pasta and the weakness of its protein network. In contrast, VHT.LM drying and precooking treatment led to a lower in vitro starch digestibility, probably as a result of the strengthening of the protein network at a macromolecular level, protecting starch from enzymatic attack.     

Identification of three proteins up-regulated by raw starch in Cytophaga sp.

Raw starch-digesting amylases (RSDAs) in many microorganisms convert starch granules into maltodextrins and simple sugars. We cloned and sequenced from Cytophaga sp. an RSDA with an excellent raw starch digestion activity. This RSDA was highly inducible by raw starch, but not by other sugars, suggesting that an unknown signal transduction mechanism is involved in the degradation of raw starch. We used a proteomic approach to investigate the effect of raw starch on protein expression in Cytophaga sp. Using MALDI–TOF MS protein analysis, we have identified three proteins up-regulated by raw starch, i.e., a 60-kDa chaperonin (cpn60), glutaminase, and pyruvate phosphate dikinase (PPDK). Subsequent time-course studies detected an increased expression of RSDA as well as the highest expression of PPDK occurring 6 h post-incubation with raw corn starch, implying that the latter enzyme may work along with RSDA on the digestion of raw starch. Finding these proteins up-regulated by raw starch may provide an insight into how Cytophaga sp. cells respond to raw starch stimulation.     

The role of two isoenzymes of alpha-amylase of Araucaria araucana (Araucariaceae) on the digestion of starch granules during germination

Starch is the principal reserve of Araucaria araucana seeds, and it is hydrolysed during germination mainly by alpha-amylase. There are several alpha-amylase isoenzymes whose patterns change in the embryo and in the megagametophyte from the one observed in quiescent seeds (T(0)) to a different one observed 90 h after imbibition (T(90)). The objective of this research was to study the roles of two purified alpha-amylase isoenzymes by in vitro digestion of starch granules extracted from the tissues at two times of imbibition: one is abundant in quiescent seeds and the other is abundant after 90 h of imbibition. The isoenzymes digested the starch granules of their own stage of germination better, since the isoenzyme T(0) digested starch granules mainly from quiescent seeds, while the isoenzyme T(90) digested starch mainly at 90 h of imbibition. The sizes of the starch granule and the tissue from which these granules originated make a difference to digestion by the isoenzymes. Embryonic isoenzyme T(0) digested large embryonic starch granules better than small and medium-sized granules, and better than those isolated from megagametophytes. Similarly isoenzyme T(90) digested small embryonic starch granules better than medium-sized and large granules, and better than those isolated from megagametophytes. However, a mixture of partially purified megagametophytic isoenzymes T(0) and T(90) digested the megagametophytic granules better than those isolated from embryos. Studies of in vitro sequential digestion of starch granules with these isoenzymes corroborated their specificity. The isoenzyme T(90) digested starch granules previously digested by the isoenzyme T(0). This suggests that in vivo these two isoenzymes may act sequentially in starch granule digestion.     

Different endosperm structures in wheat and corn affected in vitro rumen fermentation and nitrogen utilization of rice straw-based diet

Starchy grain is usually supplemented to diets containing low-quality forage to provide sufficient energy for ruminant animals. Ruminal degradation of grain starch mainly depends on the hydrolysis of the endosperm, which may be variable among grain sources. This study was conducted to investigate the influence of endosperm structure of wheat and corn on in vitro rumen fermentation and nitrogen (N) utilization of rice straw. The 3×4 factorial design included three ratios of concentrate to forage (35:65, 50:50 and 65:35) and four ratios of wheat to corn starch (20:80, 40:60, 60:40 and 80:20). The endosperm structure was detected by scanning electronic microscopy and a confocal laser scanning microscopic. An in vitro gas test was performed to evaluate the rumen fermentation characteristics and N utilization. Starch granules were embedded in the starch–protein matrix in corn, but more granules were separated from the matrix in the wheat endosperm. With the increasing ratio of wheat, rate and extent of gas production, total volatile fatty acids, and ammonia N increased linearly (P<0.01), but microbial protein concentration decreased (quadratic, P<0.01), with the maximum value at a ratio of 40% wheat. The efficiency of N utilization decreased linearly (P<0.01). Rumen fermentation and N utilization were significantly affected by the concentrate-to-forage ratio (P<0.01). Significant interactions between the concentrate-to-forage ratio and the wheat-to-corn ratio were detected in total volatile fatty acids and the efficiency of N utilization (P<0.01). In summary, the starch–protein matrix and starch granules in the wheat and corn endosperm mixture play an important role in the regulation of rumen fermentation and N utilization under low-quality forage.     

Kinetics of starch digestion in sweetpotato flours from Papua New Guinean and Australian cultivars

Twenty-five sweetpotato cultivars from Papua New Guinea (PNG) and Australia were studied for their flour digestibility properties. The cultivars displayed monophasic digestograms, and a modified first-order kinetic model adequately predicted the rate and extent of starch digestion. Flours from all the cultivars had high average glycemic index (GI_avg) and glycemic load (GL). This study of starch digestion in a wide range of sweetpotato cultivars demonstrates associations and interactions of non-starch components in the flours, and their effects on starch digestibility. The presence of resistant starch (RS) in some cultivars is highlighted with respect to its potential contribution to human health and nutrition.     

Purification of a debranching enzyme (R-enzyme) from malted barley,and the role of the enzyme in the digestion of starch granules during the germination of barley seeds

A debranching enzyme (R-enzyme or pullulan-6-glucanohydrolase, EC3.2.1.41), free from contaminating carbohydrases and homogeneous by poly(acrylamide) disc-gel electrophoresis, has been purified from malted barley. A partially purified preparation of this enzyme (3.1 units/mg of protein) accelerated the rate of digestion of barley-starch granules by the action of purified alpha and beta amylases to the same extent as was effected by the dialyzed, crude extract from malted barley. Contrary to expectation, the debranching enzyme, purified to homogeneity (10 units/mg of protein), had very little accelerating effect. These results indicate that a factor or factors, which may be maltase or α-d-glucosidase and were lost during the purification of the debranching enzyme, may play a role in the digestion of starch granules by the dialyzed, crude extract from malted barley in vitro and by enzymes in the endosperm of germinating barley seeds in vivo. The debranching enzymes, including barley-malt R-enzyme, Aerobacter pullulanase, and Pseudomonas isoamylase, did not digest starch granules to a detecble extent.     

Seed-specific expression of the wheat puroindoline genes improves maize wet milling yields

The texture of maize ( Zea mays L.) seeds is important to seed processing properties, and soft dent maize is preferred for both wet-milling and livestock feed applications. The puroindoline genes ( Pina and Pinb ) are the functional components of the wheat ( Triticum aestivum L.) Hardness locus and together function to create soft grain texture in wheat. The PINs (PINA and PINB) are believed to act by binding to lipids on the surface of starch granules, preventing tight adhesion between starch granules and the surrounding protein matrix during seed maturation. Here, maize kernel structure and wet milling properties were successfully modified by the endosperm-specific expression of wheat Pins ( Pina and Pinb ). Pins were introduced into maize under the control of a maize γ- Zein promoter. Three Pina/Pinb expression positive transgenic lines were evaluated over two growing seasons. Textural analysis of the maize seeds indicated that the expression of PINs decreased adhesion between starch and protein matrix and reduced maize grain hardness significantly. Reduction in pressure required to fracture kernels ranged from 15.65% to 36.86% compared with control seeds. Further, the PINs transgenic maize seeds had increased levels of extractable starch as characterized by a small scale wet milling method. Starch yield was increased by 4.86% on average without negatively impacting starch purity. The development of softer maize hybrids with higher starch extractability would be of value to maize processors.     

Slow digestion property of native cereal starches

The slow digestion property of native cereal starches, represented by normal maize starch, was investigated. The in vitro Englyst test showed that 53.0% of the maize starch is slowly digestible starch (SDS), and scanning electron microscopy (SEM) revealed that SDS starts from an increase of pore size until almost complete fragmentation of starch granules. However, similar amounts of SDS ( approximately 50%) were shown for partially digested fragmented starch residuals, which would normally be considered resistant to digestion based on the Englyst assay. Molecularly, both amylopectin (AP) and amylose (AM) contributed to the amount of SDS as evidenced by a similar ratio of AP to AM at different digestion times. Consistently, similar degrees of crystallinity, comparable gelatinization behavior, and similar debranched profiles of starch residuals following different digestion times indicated that the crystalline and amorphous regions of starch granules were evenly digested through a mechanism of side-by-side digestion of concentric layers of semicrystalline shells of native starch granules.     

A model for starch breakdown in higher plants

An in vitro system for the breakdown of starch granules by mixtures of α- and β-amylase is developed and discussed with reference to information concerning the degradation of starch in vivo. β-Amylase has no action on starch granules and has very little effect on the rate of starch granule digestion by α-amylase. It does, however, affect the product distribution in an α-amylase digest and is considered to attack dextrin intermediates produced by the action of α-amylase on the starch granules.     

The surface structure of a complex substrate revealed by enzyme kinetics and Freundlich constants for α-amylase interaction with the surface of starch

Background

Starch is a main source of carbohydrate in human diets, but differences are observed in postprandial glycaemia following ingestion of different foods containing identical starch contents. Such differences reflect variations in rates at which different starches are digested in the intestine. In seeking explanations for these differences, we have studied the interaction of α-amylase with starch granules. Understanding this key step in digestion should help with a molecular understanding for observed differences in starch digestion rates.

Methods

For enzymes acting upon solid substrates, a Freundlich equation relates reaction rate to enzyme adsorption at the surface. The Freundlich exponent (n) equals 2/3 for a liquid-smooth surface interface, 1/3 for adsorption to exposed edges of ordered structures and 1.0 for solution–solution interfaces. The topography of a number of different starch granules, revealed by Freundlich exponents, was compared with structural data obtained by differential scanning calorimetry and Fourier transform infrared spectroscopy with attenuated total internal reflectance (FTIR-ATR).

Results

Enzyme binding rate and FTIR-ATR peak ratio were directly proportional to n and Δ_gelH was inversely related to n. Amylase binds fastest to solubilised starch and to granules possessing smooth surfaces at the solid–liquid interface and slowest to granules possessing ordered crystalline surfaces.

Conclusions

Freundlich exponents provide information about surface blocklet structures of starch that supplements knowledge obtained from physical methods.

General Significance

Nanoscale structures at the surface of starch granules influence hydrolysis by α-amylase. This can be important in understanding how dietary starch is digested with relevance to diabetes, cardiovascular health and cancer.     

Digestion of Barley, Maize, and Wheat by Selected Species of Ruminal Bacteria

Differences in the digestion of barley, maize, and wheat by three major ruminal starch-digesting bacterial species, Streptococcus bovis 26, Ruminobacter amylophilus 50, and Butyrivibrio fibrisolvens A38, were characterized. The rate of starch digestion in all cereal species was greater for S. bovis 26 than for R. amylophilus 50 or B. fibrisolvens A38. Starch digestion by S. bovis 26 was greater in wheat than in barley or maize, whereas starch digestion by R. amylophilus 50 was greater in barley than in maize or wheat. B. fibrisolvens A38 digested the starch in barley and maize to a similar extent but was virtually unable to digest the starch in wheat. The higher ammonia concentration in cultures of B. fibrisolvens A38 when grown on wheat than when grown on barley or maize suggests that B. fibrisolvens A38 utilized wheat protein rather than starch. Scanning electron microscopy revealed that B. fibrisolvens A38 initially colonized cell wall material, while S. bovis 26 randomly colonized the endosperm and R. amylophilus 50 preferentially colonized starch granules. There was subsequent colonization but only superficial digestion of wheat starch granules by B. fibrisolvens A38. Variation in the association between starch and protein within the endosperm of cereal grains contributes to the differential effectiveness with which amylolytic species can utilize cereal starch.     

Starch Source Influences Dietary Glucose Generation at the Mucosal α-Glucosidase Level

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.     

Heterogeneity of lotus rhizome starch granules as revealed by α-amylase degradation

Lotus (Nelumbo nucifera Gaertn.) rhizome starch granules have an elongated oval shape with the hilum located at one end. The morphologic characteristics were used as a direction anchor to study the heterogeneity of molecular organization of starch granules using microscopy before and after partial digestion by bacterial α-amylase (Bacillus sp.) The partially digested granule showed a single, big eroded hole at the end distant from the hilum. The enzyme-attacked end was revealed to be the loosely packed end and to be the weak point for enzyme hydrolysis. The α-amylase hydrolyzed the loosely packed central part of the granule faster than the densely packed periphery, and left an empty shell with a fish-bone-like tunnel inside. The periphery was more resistant to amylase hydrolysis and had strong birefringence. For the whole starch granule, the selectivity of α-amylase hydrolysis was low for the crystalline and amorphous regions and for amylose and amylopectin molecules. This study elucidated that the molecular organization of lotus rhizome starch granules was heterogeneous.     

Characterization of a Granule-Bound Starch Synthase Isoform Found in the Pericarp of Wheat

Waxy wheat (Triticum aestivum L.) lacks the waxy protein, which is also known as granule-bound starch synthase I (GBSSI). The starch granules of waxy wheat endosperm and pollen do not contain amylose and therefore stain red-brown with iodine. However, we observed that starch from pericarp tissue of waxy wheat stained blue-black and contained amylose. Significantly higher starch synthase activity was detected in pericarp starch granules than in endosperm starch granules. A granule-bound protein that differed from GBSSI in molecular mass and isoelectric point was detected in the pericarp starch granules but not in granules from endosperm. This protein was designated GBSSII. The N-terminal amino acid sequence of GBSSII, although not identical to wheat GBSSI, showed strong homology to waxy proteins or GBSSIs of cereals and potato, and contained the motif KTGGL, which is the putative substrate-binding site of GBSSI of plants and of glycogen synthase of Escherichia coli. GBSSII cross-reacted specifically with antisera raised against potato and maize GBSSI. This study indicates that GBSSI and GBSSII are expressed in a tissue-specific manner in different organs, with GBSSII having an important function in amylose synthesis in the pericarp.     

Role of granule-bound starch synthase in determination of amylopectin structure and starch granule morphology in potato.

Reductions in activity of SSIII, the major isoform of starch synthase responsible for amylopectin synthesis in the potato tuber, result in fissuring of the starch granules. To discover the causes of the fissuring, and thus to shed light on factors that influence starch granule morphology in general, SSIII antisense lines were compared with lines with reductions in the major granule-bound isoform of starch synthase (GBSS) and lines with reductions in activity of both SSIII and GBSS (SSIII/GBSS antisense lines). This revealed that fissuring resulted from the activity of GBSS in the SSIII antisense background. Control (untransformed) lines and GBSS and SSIII/GBSS antisense lines had unfissured granules. Starch analyses showed that granules from SSIII antisense tubers had a greater number of long glucan chains than did granules from the other lines, in the form of larger amylose molecules and a unique fraction of very long amylopectin chains. These are likely to result from increased flux through GBSS in SSIII antisense tubers, in response to the elevated content of ADP-glucose in these tubers. It is proposed that the long glucan chains disrupt organization of the semi-crystalline parts of the matrix, setting up stresses in the matrix that lead to fissuring.     

Porcine pancreatic alpha-amylase hydrolysis of native starch granules as a function of granule surface area

Porcine pancreatic alpha-amylase activity on native starch granules is more accurately described as a function of surface area of the granules rather than of substrate concentration. The apparent K(m) of alpha-amylolysis of native starch from potato, maize, and rice expressed as a function of substrate concentration was largest for potato with a single value of V(max). However, the ratio of the slope of a Lineweaver-Burk plot to that of rice for enzymatic hydrolysis of native potato and maize starch were 7.78 and 2.58, respectively, which were very close to the ratio of surface area per mass of the two starch granules to that of rice. Therefore, the reciprocal of initial velocity was a linear function of the reciprocal of surface area for each starch granule. Surface area was calculated assuming the starch granules were spherical. The values obtained by this calculation were in good agreement with the value obtained by the photomicrographic method. By comparing enzymatic digestion of native maize granules to that of rice granules, it was concluded that the presence of pores in maize granules appeared to significantly affect overall rate of digestion after sufficient reaction time, but not at the very initial stage of hydrolysis.     

Cytological identification and characterization of the nuclear matrix

The presence of a matrix system in the nucleus has been cytologically demonstrated in intact untreated and α-amanitin-treated HeLa and rat kangaroo cells. The matrix is Feulgen negative and is stained very faintly with toluidine blue, whereas it can be brightly stained with haemalum or light green. It is highly susceptible to pepsin digestion but resistant to RNase. Ultrastructurally the matrix consists of 50–60 Å thick fibrils. Some granules, which may be ribonuclear protein granules are also found associated with the fibrils. The matrix is essentially a network of acidic protein.