Structural Effects of Sulfated-Glycoproteins from Stichopus japonicus on the Nitric Oxide Secretion Ability of RAW 264.7 Cells.

The effect of various levels of proteins, sulfates, and molecular weight (M w) of a sulfated-glycoprotein (NF3) from a sea cucumber, Stichopus japonicus, on nitric oxide (NO) releasing capacity from RAW 264.7 cells was investigated. The NF3 derivatives had various amounts of proteins (4.8~11.2%) and sulfates (6.8~25.2%) as well as different M w (640.3×10(3)~109.2×10(3) g/mol). NF3 was able to stimulate RAW 264.7 cells to release NO with lower protein contents, indicating that the protein moiety was not an important factor to stimulate macrophages. On the other hand, the NO inducing capacity was significantly reduced with decreased levels of sulfates and M w, implying that sulfates and M w played a pivotal role in activating RAW 264.7 cells. It was not clear why sulfates and a certain range of M w were essential for stimulating macrophages. It appeared that certain levels of sulfates and M w of sulfated-glycoproteins were required to bind to the surface receptors on RAW 264.7 cells.

INTRODUCTION

The sulfated fucans (SF) are water-soluble, complex, and heterogeneous macromolecules, predominantly found in the cell wall of marine brown algae and in the body wall of marine invertebrates (1). They have been reported to exhibit various biological and pharmacological activities, such as anticoagulant, antitumor, and immunomodulating activities (2–4). According to Soeda et al. (5), the SF derivatives with various sulfate contents stimulated tissue plasminogen activator (t-PA)-induced plasma clot lysis and prevented the formation of fibrin polymers, and such activities increased proportionally with the degree of sulfation. It was also reported that the over-sulfated fucans possessed higher macrophage-stimulating activities than native SF, and thus more effectively up- regulated cytokine induction from the macrophage cells (6,7). However, partially desulfated fucans with sulfate contents of less than 20% showed drastic decreases in both anticoagulant and anti-cancer activities (8). In a study of Nishino et al. (9), the Mw of SF from Ecklonia kurome was related to their anticoagulant activity. The authors found that SF with Mw ranging from 10×103 to 300×103 g/mol showed the most potent anticoagulant activities, suggesting that a specific range of sugar- chains and a comfortable conformation were required to bind the thrombin for the potent anticoagulant activity. Therefore, the biological activities of SF appeared to be closely related to their compositional and macromolecular structures. Indeed, a basic understanding of both the primary and secondary structures of SF may lead to successful interpretation of their bioactivities.

Sea cucumbers, known as trepang, beche-de-mer or gamat, are marine invertebrates belonging to Echinodermata, Holothuroidea, and Aspidochirotida, and are widely found in the benthic area and deep-seas worldwide (10). They are flexible, elongated, worm-like organisms with a leathery skin and gelatinous body. Sea cucumbers are extensively consumed in China, Japan, Korea and other Asian countries as traditional and nutritional foods and medicinal resources (11). Various components, such as triterpene glycosides, peptides, fatty acids, and SF, are present in the body walls of sea cucumbers (10). Among the various constituents, SF are major edible parts of sea cucumbers (12), and have been broadly studied because of their numerous bioactivities including anticoagulant (13), anti-inflammatory (14), antithrombotic (15), antitumor (16), and immunomodulatory (17) activities. Several studies have been performed for the structure analysis of SF from sea cucumbers using various techniques such as surface-enhanced raman scattering, gas chromatography-mass spectrometry (GC-MS), fourier transform infrared spectroscopy (FTIR), and nuclear magnetic resonance (NMR) spectroscopy after some modifications of sulfated polysaccharides (18,19). The reported backbones of SF from sea cucumbers consisted of (1→3)-linked fuco-pyranosides and/or branched (1→3)-linked fuco-pyranosides substituted at C-4 with a fuco-pyranose, and sulfate substitutions occurred at C-2, C-4 or C-2 and C-4 (18,19).

In our previous study, the soluble compounds were extracted from a sea cucumber, Stichopus japonicus, followed by the removal of free proteins. Despite the free protein removal, the compounds included large amount of proteins bound to the SF. Actually, the protein-sulfated fucan (PSF) complex is the major ingested compound from sea cucumbers when they are consumed. However, the bio-activity studies of sea cucumbers constituents have been focused on the bio-polymers of either proteins or SF itself and not on the complex form of PSF. Upon the investigation of the PSF from sea cucumbers in our previous studies, the crude and fractionated PSF significantly improved the proliferation of murine macrophage cells (RAW 264.7), and strongly stimulated the RAW 264.7 cells to induce the production of NO and some cytokines such as cyclooxygenase (COX)-2, tumor necrosis factor (TNF)-α, interleukin (IL)-10, and IL-6, suggesting that they were strong immunostimulating agents. Among the crude and fractionated fractions, fraction F3 having higher SF (76.6%) exhibited relatively strong immunomodulatory activity. Therefore, in the current study, a further investigation regarding a correlation between the molecular structure and the immunomodulatory activity was performed after the sulfate and protein contents as well as the Mw of the F3 fraction were systematically changed.

MATERIALS AND METHODS

Samples and reagents

The live specimens of sea cucumber S. japonicus were collected from the east coast of Korea. The body wall of the sea cucumber was carefully separated from other tissues, washed with tap water, minced, and lyophilized. The dried sample was ground to powder using a grinder, sieved (<0.5 mm), and stored at −20°C until use. Roswell Park Memorial Institute (RPMI)-1640 medium, penicillin/streptomycin, and fetal bovine serum (FBS) were purchased from Lonza (Walkersville, MD, USA). EZ-Cytox new cell viability assay kit [High sensitive water soluble tetrazolium salt (WST-1)] was purchased from Daeil Lab service Co., Ltd, (Seoul, Korea). Griess reagent (modified) was purchased from Sigma-Aldrich (St. Louis, MO, USA). All of the chemicals and reagents used in this work were of analytical grade.

Isolation and fractionation

The process of extraction and fractionation of the PSF from S. japonicus was performed using a previously described method. Briefly, 20 g milled sample of S. japonicus was suspended in 200 mL 99% ethanol (EtOH) to remove the pigment at 70°C for 2 h. After the depigmentation, the residue was dissolved in distilled water extracted twice at 80°C for 2 h. The extract solution was concentrated and EtOH was added to precipitate the polysaccharide. The polysaccharide was collected by filtration and washed with EtOH and acetone, then dried at room temperature. The dried polysaccharide was redissolved in distilled water, and the deproteinization was carried out using the method reported by Sevag et al. (20). The crude PSF extract was obtained, which was further fractionated by DEAE Sepharose fast flow column (17-0709-01, GE Healthcare Bio-Science AB, Uppsala, Sweden), which was eluted with distilled water and stepwise NaCl gradient (0.5 to 1.5 M). Four purified fractions were obtained and named as F1, F2, F3, and F4.

Preparation of fraction F3 derivatives

The fraction F3 was modified by deproteinization, desulfation, and hydrolysis to obtain three different levels of protein, sulfate content, and Mw according to the experimental conditions mentioned in Table 1. In the deproteinization experiments, the fraction F3 (100 mg) was suspended in 100 mL 0.1 M sodium phosphate buffer (pH 7). 5% Flavourzyme (#2384, Novozyme, Tianjin, China) was added to the sample solution, and the reaction was performed at 50°C for 6, 24, and 48 h, respectively. The enzyme was inactivated at 100°C for 10 min and subsequently dialyzed and lyophilized to obtain deproteinized F3 derivatives. To obtain desulfated derivatives, 100 mg fraction F3 dissolved in distilled water was applied into a Dowex 50 W resin column (#69011-20-7, Sigma-Aldrich) which was eluted with pyridine. The obtained solution was lyophilized to yield the polysaccharide-pyridinium salt. Then, solvolytic desulfation was carried out under different conditions (Table 1) using dimethyl sulfoxide (DMSO)/methanol (MeOH)/pyridine [89:10:1 (v:v:v)] as the reaction medium. The reaction mixture was dialyzed against distilled water and lyophilized to obtain the desulfated samples with certain sulfate amounts. For hydrolysis, briefly, 100 mg fraction F3 was dissolved in 30 mL 0.01 M HCl, and the hydrolysis reaction was performed at 100°C for 2, 5, and 10 min, respectively. The samples were neutralized using 0.05 M NaOH after cooling down, dialyzed in a membrane (#3247027, Spectrum Laboratories Inc., Compton, CA, USA) against distilled water and lyophilized to obtain different Mw of F3 derivatives.

Table 1

Preparation conditions for deproteinated (DP1, DP2, and DP3), desulfated (DS1, DS2, and DS3), and hydrolyzed (DH1, DH2, and DH3) F3 from Stichopus japonicus

Samples	Temperature (°C)	Reaction time	Reaction medium
Deproteinated F3
DP1	50	6 h	5% Flavozymes (phosphate buffer at pH 7.0)
DP2	50	24 h	5% Flavozymes (phosphate buffer at pH 7.0)
DP3	50	48 h	5% Flavozymes (phosphate buffer at pH 7.0)
Desulfated F3
DS1	120	20 min	DMSO/MeOH/Pyridine [89:10:1 (v:v:v)]
DS2	120	90 min	DMSO/MeOH/Pyridine [89:10:1 (v:v:v)]
DS3	120	120 min	DMSO/MeOH/Pyridine [89:10:1 (v:v:v)]
Hydrolyzed F3
DH1	100	2 min	0.01 M HCl (pH 2.3)
DH2	100	5 min	0.01 M HCl (pH 2.3)
DH3	100	10 min	0.01 M HCl (pH 2.3)

Measurement of protein, sulfate content, and molecular weight

Protein content of the samples was estimated by the Lowry method using a DC protein assay kit (Bio-Rad, Hercules, CA, USA) with bovine serum albumin as a standard (Sigma-Aldrich) (21), and the UV chromatogram was recorded by high-performance size-exclusion chromatography (HPSEC) coupled with an UV (HPSEC-UV) system. Determination of sulfate content of the samples was carried out by the bariumchloride-gelatin method using K2SO4 as a standard after hydrolysis of the samples with 0.5 M HCl (22), and the FTIR spectra (KBr disc) of the samples were recorded using a Tensor 27 spectrophotometer (Bruker Corporation, Karlsruhe, Germany). For the Mw measurement, PSF was dissolved in distilled water (2.5 mg/mL) at 75°C for 15 min, and determined by the HPSEC coupled with an UV, multi-angle laser light-scattering (MALLS) and refractive index (RI) detection (HPSEC-UV-MALLS-RI) system according to our previous method (23).

Assays for macrophage proliferation

For the macrophage proliferation analysis, RAW 264.7 cells (1×106 cells/mL) (100 μL) were under preincubation in a 96-well microplate with RPMI-1640 medium containing 10% FBS, and 100 μL of the samples (10 μg/mL) was added for further incubation at 37°C in a 5% CO2 incubator. After 72 h, 10% WST-1 reagent (110 μL) was added to the plate after removal of the medium and incubated at 37°C for another 1.5 h. The 100 μL supernatant was transferred to a 96-well microplate, and the absorbance was measured at 450 nm. The proliferation was expressed using this equation:

where At and Ac are the absorbances of the test group and normal control group, respectively.

Nitric oxide production

To determine NO production, 100 μL RAW 264.7 cells (1×106 cells/mL) were plated in 96-well microplate plates and incubated for 24 h at 37°C in the presence of 5% CO2. The medium was removed and added 200 μL samples solution (10 μg/mL), medium (as normal control), and 1 μg/mL lipopolysaccharides as a positive control for further incubation 24 h. 100 μL of the cell culture supernatants was mixed with an equal volume of Griess reagent to determine the nitrite concentration according to the method described by Green et al. (24). After incubation at room temperature for 10 min, the absorbance was measured at 540 nm with an EL-800 microplate reader (BioTek instruments Inc., Winooski, VT, USA), and the NO concentration was calculated using sodium nitrite as a standard.

Statistical analyses

All experiments were performed in triplicate (n=3). Data were presented as the mean values with the standard deviation. All statistical analyses were performed using SAS (SAS Institute, Cary, NC, USA). Significant differences were tested by a Student’s t-test, a one-way analysis of variance (ANOVA), and Duncan’s multiple-range test. The critical P value was set at 0.01, and a probability value of P<0.01 was considered to be statistically significant.

RESULTS AND DISCUSSION

Characterization of fraction F3 derivatives

In our previous study, PSF was extracted from the body wall of sea cucumber, S. japonicus, subsequently fractionated by ion-exchange chromatography, which yielded four fractions (F1, F2, F3, and F4). Among these fractions, the F3 fraction mainly consisted of carbohydrates (44.6%) and sulfates (32.0%) with relatively lower protein contents (14.1%) compared to F1 and F2, and exhibited strong immunomodulatory activities, producing high level of NO and cytokines from RAW 264.7 cells. Monosaccharide composition analysis showed that carbohydrates of F3 were mainly composed of fucose (94.8%), and minor amounts of galactose (4.3%) glucose (0.6%), and mannose (0.3%). Methylation and NMR analysis revealed that the structure of F3 was mainly composed of a backbone of (1→3)-α-L-linked fucosyl residues with sulfation at C-2 and/or C-4.

In order to investigate a correlation between the molecular structure and the immunomodulatory activity, the fraction F3 was deproteinated, desulfated, and hydrolyzed under the conditions shown in Table 1. The proximate composition of native F3 (NF3) and deproteinated F3 (DP1~3) is presented in Table 2. The enzyme treatment (6 h) led to a marked decrease in the protein content of F3 fraction from 14.1% to 11.2%, significantly decreased to 8.1% with the increase in reaction time to 24 h, and again drastically decreased to 4.8% after 48 h treatment. The HPSEC-UV chromatograms of DP1~3 are shown in Fig. 1. Compared with NF3, DP1~3 exhibited considerably lower UV peak levels, corresponding to their protein contents, indicating that the enzyme treatment effectively removed the proteins from NF3. Table 2 also shows that the enzyme treatment significantly decreased the Mw of NF3 from 982.0×103 g/mol to 932.5×103, 921.2×103, and 901.8×103 g/mol for DP1, DP2, and DP3, respectively, while maintaining similar levels of sulfate contents. It was unclear why the Mw of NF3 significantly decreased after the flavourzyme treatment because flavourzyme is not a carbohydrate-hydrolyzing enzyme. It is likely that the removal of protein from NF3 might be related to its decrease in Mw. Wada et al. (25) also reported a mass reduction of a glycoprotein after completely removing its proteins, suggesting that the protein moiety considerably contributed to the Mw of the glycoprotein.

Table 2

Chemical composition and Mw of NF3 from Stichopus japonicus and its derivatives

Derivatives	Protein content (%)	Sulfate content (%)	Mw (103 g/mol)
NF3	14.1±0.1	32.0±1.0	982.0±15.1
DP1	11.2±0.1	27.5±0.5	932.5±20.1
DP2	8.1±0.1	23.1±0.3	921.2±19.4
DP3	4.8±0.1	30.1±0.4	901.8±14.7
DS1	13.6±0.2	25.2±0.3	680.3±10.2
DS2	12.8±0.1	16.6±0.2	402.2±8.6
DS3	13.0±0.2	6.8±0.3	212.5±12.0
DH1	13.0±0.3	31.1±0.4	640.3±18.2
DH2	13.2±0.2	28.3±0.3	340.4±12.7
DH3	12.3±0.4	30.6±0.4	109.2±13.6

Fig. 1

UV chromatograms of NF3 and deproteinated F3, DP1, DP2, and DP3.

For the desulfated samples (DS1~3), a considerable desulfation (21.2%) occurred after the reaction for 20 min (DS1). Increased reaction for 90 and 120 min led to further removal of sulfate esters, 48.1% (DS2) and 78.8% (DS3), respectively, which was also indicated in the FTIR spectra as shown in Fig. 2. Compared to the NF3, two characteristic absorption bands at 1240 cm−1 and 820 cm−1 in the DS1, DS2, and DS3 spectra successively decreased with increasing desulfation time. These results indicate that the sulfate esters are successfully removed from NF3 by the reaction. However, the desulfation reaction also led to considerable decrease in the Mw of NF3 from 982.0×103 g/mol to 680.3×103, 402.2×103, and 212.5×103 g/mol after 20, 90, and 120 min reactions, respectively. The occurrence of molecular degradation seemed to be inevitable due to the heat treatment (120°C) during the solvolytic reaction. It was also reported by Kawashima et al. (7) that the polymeric degradation simultaneously occurred in the desulfation process of the sulfated fucans.

Fig. 2

FTIR spectra of NF3 and desulfated F3 at 120°C for 20 min (DS1), for 90 min (DS2), and for 120 min (DS3).

Fig. 3 shows the HPSEC chromatograms of NF3 and partially hydrolyzed NF3 (DH1~3). Such hydrolysis times (2, 5, and 10 min) were selected to obtain derivatives having similar Mw ranges of DP1~3 and DS1~3 to exclude the Mw effect in those samples on NO production from RAW 264.7 cells. As shown in the HPSEC chromatograms, NF3 was eluted from the SEC columns between the elution times of 35~51 min. The acid and heat treatment in boiling water for 2 min slightly altered the elution time and the shape of the elution profile. However, when heated for 5 and 10 min, the elution times of the sample molecules were significantly changed with peak shifts in the chromatograms, implying the occurrence of polymeric degradation. The molecular degradation is also shown in Table 2. The Mw of NF3 calculated from the ASTRA software decreased from 982.0×103 g/mol to 640.3×103 g/mol after 2 min of heating in boiling water, markedly decreased to 340.4×103 g/mol with the increase of heating time to 5 min, and significantly decreased to 109.2×103 g/mol after 10 min of heating. These results showed that the Mw values of DH1~3 were in the similar Mw ranges of DP1~3 and DS1~3. Despite the significant decreases in the Mw, the hydrolysis appeared to be mild because the protein and sulfate contents of DH1~3 were relatively similar to those of NF3. The above results reveal that it is possible to obtain NF3 derivatives having different amounts of proteins and sulfates as well as different Mw. Therefore, these modified derivatives enable us to investigate the effects of various proteins, sulfates and Mw on the NO releasing capacity from RAW 264.7 cells.

Fig. 3

The HPSEC chromatograms of NF3 and hydrolyzed F3 at 100°C for 2 min (DH1), for 5 min (DH2), and for 10 min (DH3).

Proliferation and Nitric oxide production from RAW 264.7 cells

Upon stimulation by various external factors, macrophages release some chemokines such as NO, IL-1β, TNF-α, reactive oxygen intermediates, and other substances to remove pathogens and/or cells including cancer cells. Especially, the released NO from macrophages is a highly reactive and an important molecule in the control of the immune system (26). Fig. 4A shows the effect of NF3 and its derivatives at concentration of 10 μg/mL on the proliferation of macrophage cells, RAW 264.7. The presence of NF3 and its derivatives considerably improved cell proliferation (P<0.01), suggesting that these samples were not toxic to RAW 264.7 cells at the concentration tested in this study.

Fig. 4

Macrophage proliferation (A) and NO production (B) of RAW 264.7 cells following treatment with NF3, deproteinated F3 (DP1~3), desulfated F3 (DS1~3), and hydrolyzed F3 (DH1~3). RAW 264.7 cells (1×105 cells/well) were treated with 10 μg/mL samples or 1μg/mL LPS (positive control). Values were presented as mean±standard deviation (n=3). The letters (a–c) indicated a significant difference (P<0.01) between the native F3 and different derivatives.

The effect of the molecular structures of NF3 and its derivatives on the immunomodulating activity was monitored on the basis of their NO releasing capacity from RAW 264.7 cells (Fig. 4B). The level of NO produced from RAW 264.7 cells by NF3 (10 μg/mL) was found to be high (>24 μM/mL), indicating its potent immuno-stimulatory activity. No significant difference on the NO production was found on the DP1~3, indicating that protein moiety in NF3 was not a major factor on the stimulation of RAW 264.7 cells. However, significantly lower levels of NO production were observed by DS2, DS3, DH2, and DH3, suggesting that the sulfates and Mw played an important role on the RAW 264.7 cell stimulation.

It was reported by Chen et al. (27) that a sulfated-glycoprotein from Lycium barbarum L. stimulated peritoneal macrophages, markedly up-regulating the expression of CD40, CD80, CD86, and MHC class II molecules, in which the protein moiety of the glycoproteins was directly correlated with the macrophage stimulation. The results suggested that the protein moiety was critical for the interaction with the macrophage cells, probably through the regulation of the binding ability of the glycoproteins to the cell receptor. Such trend, however, was not observed in the current study. Instead, in the current study, the sulfates and Mw of NF3 were found to be directly related to the NO releasing capacity from RAW 264.7 cells. With lower levels of sulfates and Mw, the NF3 was unable to stimulate the RAW 264.7 cells, suggesting that the sulfates and Mw played a pivotal role in the binding of NF3 on the receptor of RAW 264.7 cells. According to Jiang et al. (6), the sulfate content in the sulfated-fucans was correlated with the up-regulation of cytokine responses from RAW 264.7 cells, indicating that the sulfates were essential for the stimulation of the macrophages. In addition, other reports demonstrated that the sulfates of the sulfated-fucans played a pivotal role in its anticancer (28), antiviral (29), and anticoagulant (8) activities. Furthermore, the Mw of sulfated-fucans was an important structural element responsible for its antiviral (30), anticoagulant (31), and antitumor activities (32). However, in other sulfated-fucans from Undaria pinnatifida, the decrease of Mw was not responsible for the activation of the macrophages and the cytokine production (7). Therefore, it was suggested that the active component of the sulfated-glycoproteins could be varied and be a unique characteristic depending on their origins.

In the current study, the effects of sulfate and protein contents as well as Mw of NF3 obtained from S. japonicus on the immunomodulation were systematically investigated through the NO production from RAW 264.7 cells. NF3 could not stimulate the RAW 264.7 cells to produce NO with decreased levels of sulfates and Mw, which appeared to be critical to activate the macrophages. However, it was unclear why sulfates and a certain range of Mw were essential for stimulating macrophages. Further investigation on the complex formation of the sulfated-glycoproteins and cell surface receptors is required, because it appeared that certain levels of sulfates and Mw of sulfated-glycoproteins are necessary to bind to the surface receptors on RAW 264.7 cells. Therefore, more research on the binding mechanism between the sulfated-glycoprotein and cell surface receptors would lead to better understanding of the relationship between its molecular structures and bioactivities.