Reduction of alpha-galactooligosaccharides in soyamilk by Lactobacillus fermentum CRL 722: in vitro and in vivo evaluation of fermented soyamilk

AIMS: Consumption of soya-derived products has been hampered by the presence of alpha-galactooligosaccharides (alpha-GOS) because mammals lack pancreatic alpha-galactosidase (alpha-Gal) which is necessary for their hydrolysis. These sugars thus reach the large intestine causing gastrointestinal disorders in sensitive individuals. The use of lactic acid bacteria (LAB) expressing alpha-Gal is a promising solution for the degradation of alpha-GOS in soyamilk. METHODS AND RESULTS: The capacity of the LAB Lactobacillus fermentum CRL 722 to properly degrade alpha-GOS was studied in vitro using controlled fermentation conditions and in vivo using a rat model. Lactobacillus fermentum CRL 722 was able to grow on commercial soyamilk and completely eliminated stachyose and raffinose during fermentation because of its high alpha-Gal activity. Rats fed soyamilk fermented by this LAB had smaller caecums compared with rats fed unfermented soyamilk. CONCLUSIONS: Soyamilk fermentation by Lact. fermentum CRL 722 results in the reduction of alpha-GOS concentrations in soyamilk, thus eliminating possible undesirable physiological effects normally associated with its consumption. SIGNIFICANCE AND IMPACT OF THE STUDY: Fermentation with Lact. fermentum CRL 722 could prevent gastrointestinal disorders in sensitive individuals normally associated with the consumption of soya-based products. This LAB could thus be used in the elaboration of novel fermented vegetable products which better suit the digestive capacities of consumers.     

A novel application of Cicer α-galactosidase in reduction of raffinose family oligosaccharides in soybean flour

Raffinose family oligosaccharide (RFOs) especially raffinose and stachyose are responsible for flatulence during intake of soybean derived products. This gives negative impression on the acceptance of soy-based foods. The effect of soaking, cooking and Cicer α-galactosidase treatment for reducing stachyose and raffinose content from the soybean flour was investigated. Cicer α-galactosidase treatment was found to be most effective in comparison to traditional methods, soaking and cooking. Enzymatic treatment for 6 h reduces raffinose and stachyose component of soybean flour by 80.0 % and 85.0 %, respectively. This can be utilized effectively for improving the nutritional quality of soy-based foods on large scale, which could be one of the best alternatives for lactose intolerant population for fulfilling their protein requirement.     

Lactobacillus fermentum CRL 722 is able to deliver active alpha-galactosidase activity in the small intestine of rats

alpha-galactooligosaccharides (alpha-GOS) found in legumes such as soybeans can cause gastrointestinal disorders since mammals lack alpha-galactosidase (alpha-Gal) in the small intestine which is necessary for their hydrolysis. Lactobacillus fermentum CRL 722 is a lactic acid bacterium (LAB) capable of degrading alpha-GOS due to its elevated alpha-Gal activity. When conventional rats were fed live L. fermentum CRL 722 or cell-free extracts of this strain, a short-lived alpha-Gal activity was detected in the upper gastrointestinal tract. The safety of this LAB was also assessed. L. fermentum CRL 722 could thus be used as a vehicle to safely confer alpha-Gal in the small intestine of monogastric animal.     

Integral kinetics of alpha-galactosidase purified from Glycine max for simultaneous hydrolysis of stachyose and raffinose

alpha-Galactosidase from soybean (Glycine max) was purified by a five-step procedure. The enzyme's natural substrates, raffinose and stachyose, have K(m)'s of 3. 0 mM and 4. 79 mM, respectively. The products, galactose and sucrose, were measured after separation by liquid chromatography. Galactose is a competitive product inhibitor of stachyose and raffinose hydrolysis with a K(i) of 0. 12 mM. We determined these parameters by an integral kinetic approach. Stachyose hydrolysis gives a nearly constant level of raffinose shortly after hydrolysis begins. Thus, cleavage of the first alpha-(1,6)-bond in the tetrasaccharide is the rate-limiting step. Since the stachyose hydrolysis yields raffinose, soybean alpha-galactosidase simultaneously hydrolyzes two substrates. We present a novel approach for analyzing simultaneous substrate hydrolysis with competitive product inhibition by a modified integral rate expression. The experimentally found kinetic parameters are confirmed by solving the simultaneous equations which describe the hydrolysis. This technique may be applicable to other hydrolytic enzymes with multiple substrates.     

An immobilized alpha-galactosidase continuous flow reactor

An α-galactosidase which will hydrolyze the oligosaccharides melibiose, raffinose, and stachyose has been immobilized on nylon microfibrils suitable for use in large flow-through reactors. This catalyst system is stable for many months, both under use and storage conditions. The immobilized enzyme behaves similarly to the enzyme in solution, characteristically exhibiting both product and substrate inhibition. The catalyst is prepared in situ and a large, 8-liter reactor has been made. The catalyst has been used to reduce the raffinose concentration in beet sugar molasses.     

Expression of rice (Oryza sativa L. var. Nipponbare) alpha-galactosidase genes in Escherichia coli and characterization

Two putative alpha-galactosidase genes from rice (Oryza sativa L. var. Nipponbare) belonging to glycoside hydrolase family 27 were cloned and expressed in Escherichia coli. These enzymes showed alpha-galactosidase activity and were purified by Ni Sepharose column chromatography. Two purified recombinant alpha-galactosidases (alpha-galactosidase II and III; alpha-Gal II and III) showed a single protein band on SDS-PAGE with molecular mass of 42 kDa. These two enzymes cleaved not only alpha-D-galactosyl residues from the non-reducing end of substrates such as melibiose, raffinose, and stachyose, but also liberated the galactosyl residues attached to the O-6 position of the mannosyl residue at the reducing-ends of mannobiose and mannotriose. In addition, these enzymes clipped the galactosyl residues attached to the inner-mannosyl residues of mannopentaose. Thus, alpha-Gal II catalyzes efficient degalactosylation of galactomannans, such as guar gum and locust bean gum.     

Enzymatic control of the accumulation of verbascose in pea seeds

Verbascose, the pentasaccharide of the raffinose family of oligosaccharides, consists of galactose units joined to sucrose. In pea (Pisum sativum) seeds, the content of verbascose is highly variable. In a previous study on a high‐verbascose pea cultivar, the present authors have demonstrated that verbascose is synthesized by a multifunctional stachyose synthase (EC 2.4.1.67), which utilizes raffinose as well as stachyose as a galactosyl acceptor. Herein the results of a study of the cloning and functional expression of stachyose synthase from the low‐verbascose genotype SD1 are reported and it is demonstrated that this line contains a protein with a reduced ability to synthesize verbascose. Analysis of seeds from seven pea lines revealed a positive correlation between verbascose synthase activity and verbascose content. Among these genotypes, only the SD1 line showed low verbascose synthase activity when the data were normalized to stachyose synthase activity. These results suggest that differences in the level of verbascose synthase activity could be caused by mutations in the stachyose synthase gene as well as by variation in the amount of the protein. The lines were also analysed for activity of α‐galactosidase, a catabolic enzyme that could limit the extent of verbascose accumulation. No relationship was found between α‐galactosidase activity and the amount of raffinose family oligosaccharides.     

Soluble carbohydrates of Pinus sylvestris L. sapwood and heartwood

Summary The amounts of glucose, fructose, sucrose, arabinose/galactose, raffinose/stachyose and starch were investigated in the outer sapwood, innermost sapwood, transition zone and heartwood of four stems of Pinus sylvestris L. The samples were taken in October and the determination of the compounds was done enzymatically. It was not possible to distinguish arabinose from galactose and raffinose from stachyose. The amounts of glucose, fructose and sucrose were greatest in the outer sapwood and decreased gradually towards the innermost sapwood and the heartwood. In the outermost heartwood glucose, fructose and sucrose were only present in trace amounts. Raffinose/stachyose showed highest concentrations in the outer sapwood and decreased towards the heartwood. In contrast, the concentrations of arabinose/galactose increased towards the heartwood and the greatest amount was found in the inner heartwood. When identified by thin-layer chromatography (TLC), arabinose was found to be present in greater amounts than galactose. The amount of starch decreased markedly towards heartwood. However, the amounts of sugars in all the studied stems was very variable. The changes in the amounts of carbohydrates in the different zones of the stems and the possible relationships of these phenomena with heartwood formation are discussed.     

Fermentation of stachyose and raffinose by hind-gut bacteria of the weanling pig

Two pigs were weaned at 28 d of age, and one pig each was placed on a corn-soy (CS) or a corn-soy diet containing 40% lactose (CSL). After 28 d a fecal sample was taken from each pig. The fecal bacterial community was fractionated and used as a source of inoculum to determine if high levels of lactose added to CS diets would modify the structure of the hind-gut microbial community and the in vitro breakdown of stachyose (soy molasses served at the source of stachyose) and raffinose. Bacterial growth rate tended to the higher with the CSL diet. Higher growth rates for bacteria from the CSL-fed pig were supported by the higher acetate: propionate production when compared to the CS diet. All the stachyose and raffinose disappeared during the 48 h fermentation. To our knowledge, this is the first report that stachyose or raffinose are completely fermented by the hind-gut bacteria of the weanling pig, and that this process can be affected by the addition of high levels of lactose to the diet.     

Effect of pH on<Emphasis Type="Italic"> Lactobacillus fermentum</Emphasis> growth,raffinose removal, α-galactosidase activity and fermentation products

In this study, the behaviour of Lactobacillus fermentum CRL 722 and CRL 251 were evaluated under different pH conditions (pH 6.0, 5.5, 5.0, 4.5) and without pH control. Growth was similar under all conditions assayed except at pH 4.5. These microorganisms were able to eliminate raffinose, a nondigestible -oligosaccharide (NDO) found in soy products, showing a consumption rate of 0.25 g l^–1 h^–1 (pH 6.0–5.0). The removal of raffinose was due to the high -galactosidase (-gal) activities of these lactic acid bacteria, which was highest at pH 5.5 (5.0 U/ml). The yield of organic acids produced during raffinose consumption was also highest at this pH. The results of this study will allow selection of the optimum growth conditions of L. fermentum with elevated levels of -gal to be used in the reduction of NDO in soy products when used as starter cultures.     

Purification and characterization of two alpha-galactosidases associated with catabolism of guar gum and other alpha-galactosides by Bacteroides ovatus.

When Bacteroides ovatus is grown on guar gum, a galactomannan, it produces alpha-galactosidase I which is different from alpha-galactosidase II which it produces when grown on galactose, melibiose, raffinose, or stachyose. We have purified both of these enzymes to apparent homogeneity. Both enzymes appear to be trimers and have similar pH optima (5.9 to 6.4 for alpha-galactosidase I, 6.3 to 6.5 for alpha-galactosidase II). However, alpha-galactosidase I has a pI of 5.6 and a monomeric molecular weight of 85,000, whereas alpha-galactosidase II has a pI of 6.9 and a monomeric molecular weight of 80,500. alpha-Galactosidase I has a lower affinity for melibiose, raffinose, and stachyose (Km values of 20.8, 98.1, and 8.5 mM, respectively) than does alpha-galactosidase II (Km values of 2.3, 5.9, and 0.3 mM, respectively). Neither enzyme was able to remove galactose residues from intact guar gum, but both were capable of removing galactose residues from guar gum which had been degraded into large fragments by mannanase. The increase in specific activity of alpha-galactosidase which was associated with growth on guar gum was due to an increase in the specific activity of enzyme I. Low, constitutive levels of enzyme II also were produced. By contrast, enzyme II was the only alpha-galactosidase that was detectable in bacteria which had been grown on galactose, melibiose, raffinose, or stachyose.     

Specific growth rate of bifidobacteria cultured on different sugars

The ability of six bifidobacterial strains (3 of human origin and 3 isolates from fermented milk products) to utilize glucose, lactose, melezitose, sucrose, raffinose, and stachyose was determined. Dairy-related bifidobacterial strains were identified asBifidobacterium animalis (2 strains) or asB. pseudolongum (1 strain). Human strains includedB. longum (2 strains) andB. breve (1 strain). All strains fermented lactose, sucrose, raffinose, and stachyose. Melezitose was utilized only byB. longum. B. pseudolongum did not ferment either glucose or melezitose. All isolates had a higher specific growth rate on raffinose and stachyose than on glucose. Dairy strains grew slowly on glucose compared to human strains.     

植物组织中低聚糖乙酰化及毛细管气相色谱分析

建立一种用乙酰化衍生处理低聚糖并用毛细管气相色谱-FID进行分析的方法。以1-甲基咪唑为催化剂并以乙酸酐为乙酰化试剂, 同时对植物样品中蔗糖、棉子糖和水苏糖等低聚糖乙酰化产物进行毛细管气相色谱分离和FID检测。确定了低聚糖乙酰化衍生物的毛细管气相色谱分析条件, 并对低聚糖乙酰化反应条件及色谱分离条件进行了优化。结果表明, 在80–1 000 ng·μL^–1范围内线性关系良好, 蔗糖、棉子糖和水苏糖的相关系数(R)分别为0.995 2、0.995 7和0.987 7, 并且精准度与回收率均较高。使用该方法对低聚糖进行乙酰化反应重现性好、所需样品材料及试剂量少且污染毒害小, 能够得到理想的分离、检测和定量分析效果, 适用于少量植物组织中低聚糖的定量分析。该方法在食品、医药检测和基础科学研究领域均具有广泛的适用性及参考价值。     

α-Galactosidase from sweet chestnut seeds

The major sugars of fresh seeds of Castanea sativa were shown to be raffinose, stachyose and sucrose. Drying seeds at 25° for 14 weeks increased the ratio raffinose: stachyose from 1.1 to 3.5, reduced sucrose content by ca 50 % and decreased total extractable α-galactosidase. The enzyme activity was resolved into two peaks, a high MW form I (apparent MW215 000) and a low MW form II (apparent MW 53 000). The latter form was predominant in the extract of fresh seeds whereas the former was the main form in the 14-week dried seeds. An increase in the amount of enzyme I was also observed when a buffered extract (pH 5.5) of fresh seeds was stored at 4°. Enzymes I and II had pH optima of 4.5 and 6, respectively. Both enzymes hydrolysed p-nitrophenyl α-d-galactoside at a much greater rate than the natural substrates raffinose, stachyose, locust bean gum and carob gum. However, enzyme I showed preference for stachyose as compared to raffinose; the opposite order was observed for enzyme II.     

A novel alkaline alpha-galactosidase from melon fruit with a substrate preference for raffinose

The cucurbits translocate the galactosyl-sucrose oligosaccharides raffinose and stachyose, therefore, alpha-galactosidase (alpha-D-galactoside galactohydrolase, EC 3.2.1.22) is expected to function as the initial enzyme of photoassimilate catabolism. However, the previously described alkaline alpha-galactosidase is specific for the tetrasaccharide stachyose, leaving raffinose catabolism in these tissues as an enigma. In this paper we report the partial purification and characterization of three alpha-galactosidases, including a novel alkaline alpha-galactosidase (form I) from melon (Cucumis melo) fruit tissue. The form I enzyme showed preferred activity with raffinose and significant activity with stachyose. Other unique characteristics of this enzyme, such as weak product inhibition by galactose (in contrast to the other alpha-galactosidases, which show stronger product inhibition), also impart physiological significance. Using raffinose and stachyose as substrates in the assays, the activities of the three alpha-galactosidases (alkaline form I, alkaline form II, and the acid form) were measured at different stages of fruit development. The form I enzyme activity increased during the early stages of ovary development and fruit set, in contrast to the other alpha-galactosidase enzymes, both of which declined in activity during this period. In the mature, sucrose-accumulating mesocarp, the alkaline form I enzyme was the major alpha-galactosidase present. We also observed hydrolysis of raffinose at alkaline conditions in enzyme extracts from other cucurbit sink tissues, as well as from young Coleus blumei leaves. Our results suggest different physiological roles for the alpha-galactosidase forms in the developing cucurbit fruit, and show that the newly discovered enzyme plays a physiologically significant role in photoassimilate partitioning in cucurbit sink tissue.     

Chain Elongation of raffinose in pea seeds. Isolation, characterization, and molecular cloning of mutifunctional enzyme catalyzing the synthesis of stachyose and verbascose.

Raffinose oligosaccharides are major soluble carbohydrates in seeds and other tissues of plants. Their biosynthesis proceeds by stepwise addition of galactose units to sucrose, which are provided by the unusual donor galactinol (O-alpha-d-galactopyranosyl-(1-->1)-l-myo-inositol). Chain elongation may also proceed by transfer of galactose units between raffinose oligosaccharides. We here report on the purification, characterization, and heterologous expression of a multifunctional stachyose synthase (EC ) from developing pea (Pisum sativum L.) seeds. The protein, a member of family 36 of glycoside hydrolases, catalyzes the synthesis of stachyose, the tetrasaccharide of the raffinose series, by galactosyl transfer from galactinol to raffinose. It also mediates the synthesis of the pentasaccharide verbascose by galactosyl transfer from galactinol to stachyose as well as by self-transfer of the terminal galactose residue from one stachyose molecule to another. These activities show optima at pH 7.0. The enzyme also catalyzes hydrolysis of the terminal galactose residue of its substrates, but is unable to initiate the synthesis of raffinose oligosaccharides by galactosyl transfer from galactinol to sucrose. A minimum reaction mechanism which accounts for the broad substrate specificity and the steady-state kinetic properties of the protein is presented.     

Galactinol synthase activity and soluble sugars in developing seeds of four soybean genotypes

Galactinol synthase (UDP-galactose:inositol galactosyltransferase) is the first unique enzyme in the biosynthetic pathway of raffinose saccharides. Its role as a regulator of carbon partitioning between sucrose and raffinose saccharides in developing soybean (Glycine max L. Merrill) seeds was examined. Galactinol synthase activity and concentrations of sucrose, stachyose, and raffinose were compared during seed development between two genotypes that were high and two genotypes that were low in mature seed raffinose saccharide concentration. In all genotypes, sucrose concentration increased as seed development progressed, but in both low raffinose saccharide genotypes, greater increases in sucrose concentration were observed late in seed development. Sucrose to stachyose ratios in mature seeds were 2.3-fold greater in low raffinose saccharide genotypes than in the high raffinose saccharide genotypes. During seed development, higher levels of galactinol synthase activity were observed in the high raffinose saccharide genotypes than in the low raffinose saccharide genotypes. A common linear relationship for all four soybean genotypes was shown to exist between galactinol formed estimated from galactinol synthase activity data and the concentration of galactose present in raffinose saccharides. Results of this study implied that galactinol synthase is an important regulator of carbon partitioning between sucrose and raffinose saccharides in developing soybean seeds.     

植物中棉子糖系列寡糖代谢及其调控关键酶研究进展

棉子糖系列寡糖代谢与植物生长发育、逆境胁迫、种子耐贮性及脱水耐性等关系密切.棉子糖系列寡糖的合成从棉子糖的合成开始,由半乳糖苷肌醇上的半乳糖基的转移依次生成棉子糖、水苏糖、毛蕊花糖等.寡糖代谢是一个复杂的调控体系,其中肌醇-1-磷酸合成酶、肌醇半乳糖苷合成酶、蔗糖合成酶、棉子糖合成酶、水苏糖合成酶和毛蕊花糖合成酶等参与了棉子糖系列寡糖的生物合成过程.本文对植物中棉子糖系列寡糖的代谢及其重要调控酶的特性、功能及分子生物学研究进展进行综述.     

Carbohydrate Changes during Maturation of Cucumber Fruit : Implications for Sugar Metabolism and Transport

Changes in the carbohydrate profiles in the mesocarp, endocarp, and seeds of maturing cucumber (Cucumis sativus, L.) fruit were analyzed. Fruit maturity was measured by a decrease in endocarp pH, which was found to correlate with a loss in peel chlorophyll and an increase in citric acid content. Concentrations of glucose and fructose (8.6-10.3 milligrams per gram fresh weight, respectively) were found to be higher than the concentration of sucrose (0.3 milligrams per gram fresh weight) in both mesocarp and endocarp tissue. Neither raffinose nor stachyose were found in these tissues. The levels of glucose and fructose in seeds decreased during development, but sucrose, raffinose, and stachyose accumulated during the late stages of maturation. Both raffinose and stachyose were found in the seeds of six lines of Cucumis sativus L. This accumulation of raffinose saccharides coincided with an increase in galactinol synthase activity in the seeds. Funiculi from maturing fruit were found to be high in sucrose concentration (4.8 milligrams per gram fresh weight) but devoid of both raffinose and stachyose. The results indicated that sucrose is the transport sugar from the peduncle to seed, and that raffinose saccharide accumulation in the seed is the result of in situ biosynthesis and not from direct vascular transport of these oligosaccharides into the seeds.