Biocatalysis of Fucodian in Undaria pinnatifida Sporophyll Using Bifidobacterium longum RD47 for Production of Prebiotic Fucosylated Oligosaccharide

Fucosylated oligosaccharide (FO) is known to selectively promote the growth of probiotic bacteria and is currently marketed as a functional health food and prebiotic in infant formula. Despite widespread interest in FO among functional food customers, high production costs due to high raw material costs, especially those related to fucose, are a significant production issue. Therefore, several actions are required before efficient large-scale operations can occur, including (i) identification of inexpensive raw materials from which fucosylated oligosaccharides may be produced and (ii) development of production methods to which functional food consumers will not object (e.g., no genetically modified organisms (GMOs)). Undaria pinnatifida, commonly called Miyeok in Korea, is a common edible brown seaweed plentiful on the shores of the Korean peninsula. In particular, the sporophyll of Undaria pinnatifida contains significant levels of l-fucose in the form of fucoidan (a marine sulfated polysaccharide). If the l-fucose present in Undaria pinnatifida sporophyll was capable of being separated and recovered, l-fucose molecules could be covalently joined to other monosaccharides via glycosidic linkages, making this FO manufacturing technology of value in the functional food market. In our previous work, β-galactosidase (EC 3.2.2.23) from Bifidobacterium longum RD47 (B. longum RD47) was found to have transglycosylation activity and produce FO using purified l-fucose and lactose as substrates. In this research, crude fucodian hydrolysates were separated and recovered from edible seaweed (i.e., U. pinnatifida sporophyll). The extracted l-fucose was purified via gel permeation and ion exchange chromatographies and the recovered l-fucose was used to synthesize FO. B. longum RD47 successfully transglycosilated and produced FO using l-fucose derived from Undaria pinnatifida and lactose as substrates. To the best of our knowledge, this is the first report of synthesized FO using Bifidobacterium spp.

In particular, the sporophyll of Undaria pinnatifida contains relatively higher amounts of fucoidan relative to other parts of the algae [9,10]. Fucose is also found in human milk. Human milk oligosaccharides are known to promote growth and provide protection against pathogens in the intestinal tracts of infants [11]. Approximately 200 neutral and acidic oligosaccharide species with a high degree of fucosylation have been identified in pooled human milk samples. These oligosaccharides are terminated by fucose and exhibit fucosylation rates between 50% and 70% [12,13]. Among the various probiotic cell strains, fucosylated oligosaccharide (FO) can promote the selective growth of Bifidobacterium spp., a well-known beneficial bacterium in the large intestine [14]. Also, FO can inhibit the adhesion of pathogens on epithelial cells [15].
Multiple scholars have reported that microbial galactosidases reveal transglycosyl activities toward L-fucose [16,17]. In our previous work, crude enzyme extracts from B. longum RD47 were found to have transglycosylation activities that produced FO using L-fucose with lactose as a substrate [18]. However, commercially available L-fucose is prohibitively expensive, limiting its use in producing FO in or for the food industry [19]. In this study, we successfully extracted L-fucose from fucoidan of U. pinnatifida sporophyll and used this extract as the raw material for synthesizing FO through B. longum RD47 biocatalysis.

Extraction and Purification of Monosaccharides from U. pinnatifida Sporophyll
The diverse functional materials extracted from seaweeds have attracted great attention among food companies due to their potential as functional foods. The market for these substances is estimated in the billions of dollars [20]. Among them, fucoidan is one of the heterogeneous sulfated complex sugars commonly existing in brown algae. However, the structural characteristics of fucoidan differ in biological activity, depending on the geographical location of the seaweed in which it is found. This is related to the degree of sulphation and the types of monosaccharides within the fucoidan. To evaluate the potential for utilization of U. pinnatifida fucoidan, we characterized it through both quantitative and qualitative analyses.
Crude algal monosaccharides were isolated from U. pinnatifida sporophyll via acid-catalyzed hydrolysis, and the recovered hydrolysates were applied to Bio-LC to evaluate monosaccharide compositions. Each monosaccharide was quantified by comparing the peak area of the sample sugar to that of a standard monosaccharide of known concentration ( Figure 1). The molar ratio of each monosaccharide from the sample was then determined.
From each 100 g sample of dried U. pinnatifida sporophyll, 5.51 ± 1.3 g of monosaccharide was obtained with a dry mass yield of 5.5%. The yield of monosaccharides from U. pinnatifida sporophyll was similar to the ≥3.2% yields previously reported [4,21]. The monosaccharide composition of the purified fucoidan was shown to be galactose, fucose, glucose, mannose, xylose, and arabinose. The major compounds were galactose and fucose with a molar ratio of 1.2:1. The molar ratio of galactose and fucose from U. pinnatifida sporophyll was consistent with a previously reported 1.1:1 ratio [22]. Because our sample was found to contain a sufficient amount of fucose, we conducted further studies to evaluate whether U. pinnatifida hydrolysates could be used for oligosaccharide production via enzymatic glycosylation. U. pinnatifida hydrolysates potentially contain impurities (e.g., sulfate, phosphate, ions, and organic acids) in addition to monosaccharides, which act as enzyme inhibitors. Gel permeation chromatography and ion-exchange chromatography have been shown to not alter the structure of saccharides, so these techniques were used to separate the sugar substances from the acid hydrolysates. Those chromatographic fractions containing L-fucose were further applied to generate FO through transglycosylation of B. longum RD47 β-galactosidase. From each 100 g sample of dried U. pinnatifida sporophyll, 5.51 ± 1.3 g of monosaccharide was obtained with a dry mass yield of 5.5%. The yield of monosaccharides from U. pinnatifida sporophyll was similar to the ≥3.2% yields previously reported [4,21]. The monosaccharide composition of the purified fucoidan was shown to be galactose, fucose, glucose, mannose, xylose, and arabinose. The major compounds were galactose and fucose with a molar ratio of 1.2:1. The molar ratio of galactose and fucose from U. pinnatifida sporophyll was consistent with a previously reported 1.1:1 ratio [22]. Because our sample was found to contain a sufficient amount of fucose, we conducted further studies to evaluate whether U. pinnatifida hydrolysates could be used for oligosaccharide production via enzymatic glycosylation. U. pinnatifida hydrolysates potentially contain impurities (e.g., sulfate, phosphate, ions, and organic acids) in addition to monosaccharides, which act as enzyme inhibitors. Gel permeation chromatography and ion-exchange chromatography have been shown to not alter the structure of saccharides, so these techniques were used to separate the sugar substances from the acid hydrolysates. Those chromatographic fractions containing L-fucose were further applied to generate FO through transglycosylation of B. longum RD47 β-galactosidase.

Synthesis of Fucosylated Oligosaccharide Using β-Galactosidase of B. longum RD47
β-Galactosidase is an enzyme commonly used to prevent lactose crystallization in frozen dairy products via lactose hydrolysis into glucose and galactose. In addition to sugar hydrolysis, βgalactosidase also demonstrates transglycosylation properties when interacting with several simple sugars and recently has been used to produce a variety of oligosaccharides in the lab and at the pilot scale level. Efforts have also been made to produce FO using L-fucose and β-galactosidase biocatalysis. However, the majority of researchers did not specify the origin of the raw materials used in L-fucose production. Finally, several groups have used non-GRAS microorganisms (e.g., E. coli and Bacillus spp.) or genetically modified microorganisms to produce the β-galactosidase used in the production of FO [23][24][25].

Synthesis of Fucosylated Oligosaccharide Using β-Galactosidase of B. longum RD47
β-Galactosidase is an enzyme commonly used to prevent lactose crystallization in frozen dairy products via lactose hydrolysis into glucose and galactose. In addition to sugar hydrolysis, β-galactosidase also demonstrates transglycosylation properties when interacting with several simple sugars and recently has been used to produce a variety of oligosaccharides in the lab and at the pilot scale level. Efforts have also been made to produce FO using L-fucose and β-galactosidase biocatalysis. However, the majority of researchers did not specify the origin of the raw materials used in L-fucose production. Finally, several groups have used non-GRAS microorganisms (e.g., E. coli and Bacillus spp.) or genetically modified microorganisms to produce the β-galactosidase used in the production of FO [23][24][25].
Even though numerous institutions and 110 Nobel laureates have confirmed the safety of genetically modified organisms (GMOs), food consumers continue to be suspicious and non-supportive of them [26,27]. Moreover, health and functional food consumers are willing to pay more to purchase non-GMO foods [28][29][30]. As FO will most likely be an ingredient in functional foods, infant formulas, and pre/probiotic products, the use of GMOs or non-GRAS microorganisms in their production will be a challenge for product approval, at best. Using enzymes naturally produced by probiotic cell (e.g., Bifidobacterium and Lactobacillus spp.) biocatalysis to produce bioactive substances is thus becoming increasingly important in these food industries. In our previous work, the β-galactosidase of B. longum RD47, which has demonstrated transglycosylation activity, aided in FO production using L-fucose and lactose. In the process of transglycosylation, L-fucose acts as an acceptor in the formation of FO [18]. Therefore, L-fucose extracted and purified from U. pinnatifida could potentially be used as a substrate for the enzymatic synthesis of FO, providing new opportunities for the development of biofunctional materials. Figure 2 shows that the β-galactosidase of B. longum RD47 is able to produce FO from L-fucose monosaccharide fractions and lactose. The TLC profile in Figure 2a shows the result of an enzymatic reaction between the monosaccharide fraction and lactose with β-galactosidase of B. longum RD47. In the absence of L-fucose, no FO was produced (Figure 2b). infant formulas, and pre/probiotic products, the use of GMOs or non-GRAS microorganisms in their production will be a challenge for product approval, at best. Using enzymes naturally produced by probiotic cell (e.g., Bifidobacterium and Lactobacillus spp.) biocatalysis to produce bioactive substances is thus becoming increasingly important in these food industries. In our previous work, the βgalactosidase of B. longum RD47, which has demonstrated transglycosylation activity, aided in FO production using L-fucose and lactose. In the process of transglycosylation, L-fucose acts as an acceptor in the formation of FO [18]. Therefore, L-fucose extracted and purified from U. pinnatifida could potentially be used as a substrate for the enzymatic synthesis of FO, providing new opportunities for the development of biofunctional materials. Figure 2 shows that the β-galactosidase of B. longum RD47 is able to produce FO from L-fucose monosaccharide fractions and lactose. The TLC profile in Figure 2a shows the result of an enzymatic reaction between the monosaccharide fraction and lactose with β-galactosidase of B. longum RD47. In the absence of L-fucose, no FO was produced (Figure 2b). The newly generated FO and L-fucose contained in the monosaccharide fraction were clearly distinguished from other molecular spots. Figure 2b shows the effect of B. longum RD47 βgalactosidase treatment on lactose that did not include the monosaccharide fraction treatment. As Lfucose was not treated, newly generated FO was not observed. Lactose was hydrolyzed into galactose and glucose by β-galactosidase and galactosyl oligosaccharides were formed with various degrees of polymerization, as shown in Figures 2a and 2b. The Figure 2a TLC profile results are the same as those previously shown, where commercially available L-fucose (American Chemical Society grade, ≥95%) was used as a fucose substrate for the synthesis of FO via B. longum RD47 β-galactosidase. The FO spot was previously confirmed to be composed of fucose and galactose by MALDI-TOF and LC-ESI/MS [18]. Taken together, the fucose contained in U. pinnatifida sporophyll as a form of fucodian was successfully used for the synthesis of FO by B. longum RD47 β-galactosidase. The newly generated FO and L-fucose contained in the monosaccharide fraction were clearly distinguished from other molecular spots. Figure 2b shows the effect of B. longum RD47 β-galactosidase treatment on lactose that did not include the monosaccharide fraction treatment. As L-fucose was not treated, newly generated FO was not observed. Lactose was hydrolyzed into galactose and glucose by β-galactosidase and galactosyl oligosaccharides were formed with various degrees of polymerization, as shown in Figure 2a,b. The Figure 2a TLC profile results are the same as those previously shown, where commercially available L-fucose (American Chemical Society grade, ≥95%) was used as a fucose substrate for the synthesis of FO via B. longum RD47 β-galactosidase. The FO spot was previously confirmed to be composed of fucose and galactose by MALDI-TOF and LC-ESI/MS [18]. Taken together, the fucose contained in U. pinnatifida sporophyll as a form of fucodian was successfully used for the synthesis of FO by B. longum RD47 β-galactosidase.

Extraction of Crude Fucoidan from U. pinnatifida Sporophyll
U. pinnatifida sporophyll grown in Wando, Korea was purchased from a local grocery in Pohang, Korea. All reagents were purchased from Sigma-Aldrich (Sigma, St. Louis, MO, USA) unless otherwise noted. The purification of fucoidan from U. pinnatifida sporophyll was performed using the Kim et al. method [21], modified as follows: U. pinnatifida sporophyll was homogenized with a food grinder and refluxed with a mixture of methanol/chloroform/water 4/2/1 (v/v/v) using a rotary evaporator to remove colored matter and phenol compounds prior to extraction [31]. After pretreatment, the mixture was centrifuged at 10,000× g for 20 min at 4 • C, after which the supernatant was discarded. The extract was filtered through a cellulose flat sheet filter membrane (Whatman No.1, Whatman, Maidstone, UK). The filtrate was then neutralized with 1 N NaOH, and the solution was precipitated with three volumes of ethanol. After centrifugation at 6,000× g for 30 min at 4 • C, the precipitate was dissolved in distilled water. The pH of the suspension was adjusted to 2.0 with 1 N HCl, and CaCl 2 was added to the final concentration of 2 M. After centrifugation at 6,000× g for 30 min at 4 • C, the precipitate was removed. Then, the supernatant was treated with three volumes of ethanol and repeated three times. The final precipitate was dissolved in distilled water and dialyzed through a MWCO 3500 membrane (Spectrum Laboratories of Repligen, Waltham, MA, USA) at 4 • C in distilled water for 48 h and freeze-dried. This product was then designated as crude fucoidan and its yield was calculated as follows: Yield (%) = [amount of crude fucoidan (g) / amount of Undaria pinnatifida sporophyll (g)] × 100.
The extract was further purified by column chromatography. One gram of crude fucoidan was dissolved in 10 ml of distilled water and applied to a DEAE-cellulose column (100 ml) that had been pre-equilibrated with distilled water (pH 7.0 adjusted with 0.1 M NaOH) and eluted with the same buffer containing increasing concentrations of NaCl (0.1, 0.5, 1.0, 1.5, 2.0 M) until no more carbohydrate was detected. Each fraction was assayed for carbohydrates by thin layer chromatography (TLC). The carbohydrate-positive fractions were pooled together and dialyzed for 24 h through an MWCO 3500 membrane in distilled water and freeze-dried. This product was designated purified crude fucoidan.

Preparation of Purified Fucoidan Hydrolysate from Crude Fucoidan
To obtain purified fucoidan hydrolysate, 10 mg of crude fucoidan was dissolved in 1 mL of distilled water, and an equal volume of 0.2 N HCl was added and allowed to stand for 1 h at 120 • C in an autoclave. After this treatment, the mixture was neutralized with 1 M NaOH, filtered through a 0.45 µm syringe filter, and vacuum dried using a Speed-Vacuum (ScanSpeed 40, LaboGene, Lillerød, Denmark). Various ions including sulfate, phosphate, and uronic acid present in the hydrolysate were removed by ion exchange resin on IRA-400 (Chloride Form, Sigma, USA) and DOWEX 50XW4 (Hydrogen form, Sigma, USA) in an open column. One gram of dried hydrolysate was dissolved in 50 mL of distilled water and loaded onto an IRA-400 open column. The column was then eluted by distilled water and fractions were collected and loaded onto a DOWEX 50XW4 open column. The column was eluted by distilled water and fractions were collected and concentrated in a speed vacuum concentrator (ScanSpeed 40, LaboGene, Denmark). Impurities present in hydrolysate were removed by gel permeation chromatography on a PD Miditrap G-10 (5.3 mL, GE Healthcare, Chicago, IL, USA). One milliliter of hydrolysate dissolved in sterilized water was loaded onto a gravity column of PD Miditrap G-10. The column was eluted with 2 mL of sterilized water. Fractions containing monosaccharides were detected by TLC. Finally, fucose-positive fractions were collected and concentrated by a speed vacuum concentrator.

Evaluation of Monosaccharide Composition of Fucoidan Hydrolysate by Bio-LC
Bio-LC was performed to determine the composition of the monosaccharides [32]. Bio-LC analysis was carried out on a Dionex-2500 ion chromatography (Thermo Fisher Scientific, Waltham, MA, USA) instrument equipped with an ED40 Gold electrode, pulsed by an amprometry detector (Thermo Fisher Scientific, Waltham, MA, USA). All samples were microfiltered through a 0.2 µm cutoff PVDF membrane filter, and the sample injection volume was 10 µL. All chromatographic separation procedures were carried out on a CARBOPAC_PA1 column (4 × 250 mm) from Dionex. The 1.0 mL/min flow rate was constant. The mobile phase was 2 mM potassium hydroxide, and the Mar. Drugs 2019, 17, 117 6 of 8 solvent composition was performed as follows: 2 mM (1-35 min); 2-100 mM (35-36 min); 100 mM (36-56 min); 100-2 mM (56-57 min); 2 mM (58-63 min). Standard solutions were prepared in distilled water to calculate the concentration of monosaccharides in the samples.

Synthesis of Fucosylated Oligosaccharide Using B. longum RD47
Bifido LTD (Hongcheon, Korea) generously donated frozen B. longum RD47 cell stock. B. longum RD47 was activated by two successive precultures in MRS medium (Difco, Detroit, MI, USA) with 0.05% (w/v) cysteine-HCl at 37 • C for 18 h. The activated B. longum RD47 was inoculated in 8 ml MRS containing 0.05% (w/v) cysteine-HCl and grown at 37 • C for 18 h under anaerobic conditions. The activated microorganisms were centrifuged at 16,000× g for 5 min. Cells were harvested by centrifugation and washed twice in 50 mM sodium phosphate buffer (PB, pH 6.6). The supernatant was then discarded. For the preparation of β-galactosidase extracts, washed B. longum RD47 cells were resuspended in one volume of PB (pH 6.6) and disrupted with a sonicator (Sonicator 500, Q-Sonica, Newtown, CT, USA) in 1.0 s on/1.0 s off intervals for 5 min. Supernatant was used after centrifugation at 16,000× g for 12 min at 4 • C. β-Galactosidase activity was measured by testing the para-nitrophenol (pNP) D-β-galacto-pyranosides as substrate. Enzyme solution (80 µL, 5 µL of crude enzyme extracts in 75 µL of PB) was added to 20 µL of 5 mM pNP-D-galactoside in 50 mM PB (pH 6.6). The mixture was incubated at 37 • C for 10 min and the reaction was stopped by adding 100 µL of 1 M Na 2 CO 3 . Enzyme activity was measured via spectrophotometer in microplates at 405 nm. Specific activity (enzyme activity level relative to cell mass) was determined as units of β-galactosidase activity. One unit, equivalent to the relative enzyme activity, was determined as the amount of product converted by 1 mL of B. longum RD 47 crude enzyme over 1 min. To synthesize FO, 1 g of fucoidan hydrolysate and 400 mg of lactose were mixed, 1 mL of which solution in PB (pH 6.6) was prepared for reaction. The enzyme extract (40 µL) was added to a sugar solution and the mixture was incubated at 37 • C. After 24 h incubation, the reaction was terminated by boiling for 10 min. The total activity of β-galactosidase was 5.31 µM pNP (min·mL) −1 . The types of carbohydrates produced as a result of the enzyme reaction were evaluated by one-or two-dimensional TLC. After enzyme reaction, samples were loaded onto silica gel plate 60 (Merck, Darmstadt, Germany); the mobile phase was composed of 1-propanol, distilled water, and ethyl acetate (7/2/1, v/v/v). The sulfuric acid-ethanol (1/9, v/v) solution was sprayed and dried and the developing solvent of 2D TLC was composed of ethyl acetate, 1-propanol, DW, and acetic acid (4/2/2/1, v/v/v/v). Finally, the silica gel plate was heated at 110 • C for 5 min for visualization.

Conclusions
In this study, the fucose containing the polysaccharide known as fucoidan was extracted from U. pinnatifida sporophyll. The purified fucoidan was hydrolyzed and used to synthesize FOs using a crude enzyme extract from B. longum RD47. The synthesis of FO was confirmed by 2D TLC, indicating that fucose from U. pinnatifida sporophyll was confirmed as a substitute for expensive commercial L-fucose. For later application, L-fucose from U. pinnatifida could be used as a substrate for the enzymatic condensation of FO. This may provide new opportunities for the development of new prebiotics. To the best of our knowledge, this is also the first report to produce prebiotic FO using Bifidobacterium spp.