|Year : 2022 | Volume
| Issue : 77 | Page : 44-51
Screening and characterization of an acid polysaccharide with antioxidant activity in vitro and in vivo from Dendrobium aurantiacum var. denneanum (Kerr)
Yijun Fan1, Xueyan Tan1, Juan Zhao1, Kaigang Yang1, Shengdi Wu1, Jiao Zhang1, Shangrao Pu1, Gang Wang2, Aoxue Luo1
1 Department of Landscape Plants, Sichuan Agricultural University, Chengdu, China
2 Department of Medicinal Plant, Sichuan Agricultural University, Chengdu, China
|Date of Submission||23-Nov-2020|
|Date of Decision||01-Feb-2021|
|Date of Acceptance||26-Jul-2021|
|Date of Web Publication||28-Mar-2022|
Department of Landscape Plants, Sichuan Agricultural University, Chengdu 611130
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Aim: We aimed to monitor an acid polysaccharide with antioxidant activity. Materials and Methods: Three acidic polysaccharides (DAP-A40, DAP-A60, and DAP-A80) were extracted from D. aurantiacum imbricate by alkaline aqueous solution extraction and ethanol precipitation. The structure characterization and antioxidant activity in vitro and in vivo were examined. Results: The molecular weight (MW) of three polysaccharides was 1.70 mol5 Da, 5.78 mol4 Da, and 1.36 mol4 Da, respectively, by high-performance gel chromatography. The consequences of infrared spectrum displayed that three polysaccharides enclosed uronic acid and sulfuric acid groups. DAP-A40 and DAP-A60 were collected of α-configuration pyranose. DAP-A80 was composed of β-configuration pyranose. Antioxidant test exhibited that DAP-A80 had outstanding antioxidant activity. The half-maximal inhibitory concentration of DAP-A80 in dipping power and scavenging the 2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) (ABTS), DPPH, and OH radicals was 163.5 μg/mL, 613.2 μg/mL, 583.2 μg/mL, and 365.1 μg/mL, respectively. The grades of correlation analysis showed that the ability of DAP-A80 to scavenge ABTS, DPPH, and OH radicals was negatively connected with the MW of polysaccharides and certainly correlated with the content of sulfate group. The results of in vivo experiments exposed that DAP-A80 might knowingly decline the formation of malondialdehyde. High levels of DAP-A80 could evocatively upsurge the activity of superoxide dismutase and GSH-Px in mouse serum. Conclusion: DAP-A80 has an antioxidant effect and can be reconnoitered as a health medicine and food.
Keywords: Acid polysaccharide, antioxidant enzymes, Dendrobium aurantiacum var. denneanum (Kerr), free radicals, structure–activity relationship
|How to cite this article:|
Fan Y, Tan X, Zhao J, Yang K, Wu S, Zhang J, Pu S, Wang G, Luo A. Screening and characterization of an acid polysaccharide with antioxidant activity in vitro and in vivo from Dendrobium aurantiacum var. denneanum (Kerr). Phcog Mag 2022;18:44-51
|How to cite this URL:|
Fan Y, Tan X, Zhao J, Yang K, Wu S, Zhang J, Pu S, Wang G, Luo A. Screening and characterization of an acid polysaccharide with antioxidant activity in vitro and in vivo from Dendrobium aurantiacum var. denneanum (Kerr). Phcog Mag [serial online] 2022 [cited 2022 Sep 27];18:44-51. Available from: http://www.phcog.com/text.asp?2022/18/77/44/341081
- Dendrobium aurantiacum var. denneanum (Kerr) are a prized medicinal plant, which has an extensive history in China as Chinese herbal medicine, which is opulent in polysaccharides with strong biological activities. The activities of polysaccharides with different molecular weights and different structural characteristics are unalike. In order to screen and characterize an acid polysaccharide with antioxidant activity, D. aurantiacum var. denneanum (Kerr) polysaccharides were prepared by alkaline water extraction and ethanol precipitation and their structural characteristics were investigated. The results exhibited that a new acid polysaccharide DAP-A80 (Mn = 1.36 × 104 Da) composed of β-configuration pyranose exhibited a strong ability of scavenging free radicals and can meaningfully surge the activity of superoxide dismutase and GSH-Px in mouse serum. The antioxidant effects were positively allied with the content of sulfate group.
Abbreviations used: DAP: Polysaccharide from D. aurantiacum var. denneanum (Kerr); IR: Infrared spectra; OH•: Hydroxyl radicals; ABTS+: 2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid); CAT: Catalase; SOD: Superoxide dismutase; GSH-Px: Glutathione peroxidase; DPPH: 1,1-Diphenyl-2-picrylhydrazyl; GPC: High-performance Gel Permeation Chromatography; MW: Molecular weight. Vc: Vitamin C; MDA: Malondialdehyde.
| Introduction|| |
Dendrobium is a valuable medicinal plant, which has an extensive history in China as Chinese herbal medicine, tea, and health food. There are 76 species and 2 varieties of Dendrobium in China, more than 50 of which can be employed as “Shihu,” a popular tonic and a traditional Chinese medicine. Sichuan Province is one of the key producing areas of Dendrobium. There are 11 species of Dendrobium, among which D. aurantiacum var. denneanum (Kerr) is the most copious. It has been originated that Dendrobium plants are rich in polysaccharides and have strong biological activities, such as antioxidant and antiaging, hypoglycemic, antitumor,, and immune regulation., At present, the research and application on Dendrobium is mainly dedicated on these species of Dendrobium officinale, Dendrobium huoshanense, and Dendrobium nobile Lindl. Most of these Dendrobium species grow sluggishly and have low reproductive coefficient, so they want to find germplasm resources through tissue culture. Different from these Dendrobium species, D. aurantiacum var. denneanum (Kerr), which is also employed as medicine, can attain high reproduction coefficient, vigorous growth, high yield, and rich resources. However, there were few studies on polysaccharides of D. aurantiacum var. denneanum (Kerr). Our earlier study found that the content of polysaccharide from D. aurantiacum var. denneanum (Kerr) is high, and it can pointedly surge the spleen index and thymus index of mice with S180 sarcoma, promote and regulate the endocrine of interleukin-2 and tumor necrosis factor-α, and coordinate the improvement of immune system function. Therefore, it is of inestimable economic value and great implication to study the active polysaccharides of D. aurantiacum var. denneanum (Kerr).
Adverse stimulation can cause oxidative stress and produce a large number of free radicals. If it is not detached in time, it will harm biological molecules such as protein, DNA, and lipid and cause peroxidation reaction. The unsaturated fatty acids in cell membrane are oxidized and destruct the cell structure. At the same time, toxic substances such as hydroperoxide and malondialdehyde (MDA) will be produced, which will delay the normal metabolic activities of human body and lead to analogous diseases disease and accelerated aging process., Therefore, the search for competent and low toxic free radical scavengers has become a hot spot in biochemistry and medicine. While plant polysaccharides can lessen oxidative damage and its anti-radiation, anti-inflammatory, anti-fatigue, and antiaging effects are linked to their antioxidant properties. Moreover, the source of polysaccharides is ironic, the extraction is simple, and the side effects are low. Therefore, the antioxidant activity of polysaccharides has progressively attracted people's courtesy., In addition to scavenging free radicals directly as hydrogen proton or electron donor, polysaccharides can also act as signal substances to bind to cell receptors and activate intracellular antioxidant-linked signaling pathways. Activation of related transcription pathways can tempt the expression of pro-inflammatory cytokines, antioxidant enzymes, and oxidase genes, thus utilizing immune activity and antioxidant effect. Therefore, in this study, in order to screen and characterize an acid polysaccharide with antioxidant activity, D. aurantiacum var. denneanum (Kerr) polysaccharides were arranged by alkaline water extraction and ethanol precipitation and their structural characteristics were scrutinized. Meanwhile, the antioxidant capacity was verified by in vitro and in vivo experiments.
| Materials and Methods|| |
Superoxide dismutase (SOD), MDA, glutathione peroxidase (GSH-Px), and hydroxyl radical (–OH) test kit were procured from Nanjing Jiancheng Co. (Nanjing, China). Dextrans (2500-2 000 000 Da) were acquired from Pharmacia Co. (Uppsala, Sweden). 1,1-diphenyl-2-picrylhydrazyl(DPPH) radical and Vitamin C (Vc) were obtained from Sigma (St. Louis, USA). ABTS was obtained from Merck(Darmstadt, Germany). Ethanol, petroleum ether, pyridine, hydroxylamine hydrochloride, and all other chemicals and reagents were of analytical grade.
The plants were composed in Xiema Township (Sichuan Province, China). They were recognized as D. aurantiacum var. denneanum (Kerr) by Professor Aoxue Luo from Sichuan Agricultural University. The stems of Dendrobium were unruffled, dried, crushed, and filtered through 40 mother sieves.
Preparation of polysaccharide
Accurately weigh 20.0 g of D. aurantiacum var. denneanum (Kerr) powder into a round bottom flask, add 100 mL petroleum ether (60°C–90°C), and extract for 1 h with micro boiling reflux. Fat-soluble substances were removed by filtration. Add 300 mL 0.2 M sodium hydroxide to the dried residue, stir, and extract it for 6 h at room temperature. Collect the filtrate, extract it once again, and combine the filtrate twice. Adjust the filtrate to neutral with hydrochloric acid, extract the protein with Sevage reagent (n-butanol: chloroform = 1:4), and collect the supernatant. Extract for four times, combine the supernatant collected for four times, and rotate to concentrate to 100 mL. Ethanol was added to the polysaccharide solution slowly until the volume of ethanol reached 40%. The precipitate was composed by centrifugation and labeled as DAP-A40. Then absolute ethanol was added to the filtrate to make the volume of ethanol reach 60%. The precipitate was collected and labeled as DAP-A60. Finally, absolute ethanol was added to the filtrate to make the volume of ethanol reach 80%. The precipitate was collected and labeled as DAP-A80. The precipitates were eroded with acetone, ethyl acetate, and anhydrous ethanol and centrifuged, respectively.
Next, the centrifuged precipitate was dissolved with deionized water and put into a dialysis bag (7000 Da). After dialysis (magnetic stirring) with deionized water for 72 h, the water was changed every 8 h. After collecting the dialyzed solution, DAP-A40, DAP-A60, and DAP-A80 were attained by drying.
Determination of uronic acid and sulfate sugar content
According to the method from Ludowieg and Dorfman and Boeley, the standard curve was drawn with dry glucuronic acid as control and the content of uronic acid was measured by sulfuric acid carbazole method. Take 1 mL of polysaccharide solution, add 6 mL concentrated sulfuric acid to each tube in ice water bath, shake well, and then water bath at 85°C for 20 min. After taking out, cool to room temperature, add 0.2 mL 0.1% carbazole solution to each tube, and keep at room temperature for 2 h. Adjust to zero with distilled water, determine the absorbance value with ultraviolet (UV) spectrophotometer at 530 nm wavelength, and calculate the content of uronic acid in each sample. For the determination of the content of sugar sulfate in polysaccharide samples, refer to the method of Dodgson and Price and calculate the content of sugar sulfate by barium chloride gelatin turbidimetric method.
Molecular weight detection
The polysaccharide sample was dissolved in deionized water, and the concentration was 5 mg/mL. The molecular weight (MW) of each polysaccharide sample was distinguished by HPLC gel permeation chromatography. The recognition conditions were as follows: the column was Waters ultra-hydraulic linear column (ID: 300 mm × 7.8 mm), the column temperature was room temperature and eluted with 0.2 m phosphoric acid buffer, the flow rate was 0.70 mL/min, and the standard reference substance was dextran (2500-2 000 000 Da).
Infrared spectrum analysis
2.0 mg polysaccharide was mixed with KBr, pressed and scanned by Fourier transform infrared spectrometer (scanning range: 4000/cm-500/cm).
Antioxidants in vitro
The reducibility test of polysaccharide samples was somewhat altered according to the method of Luo et al. The samples were prepared with deionized water into solutions of 3200 μg/mL, 1600 μg/mL, 800 μg/mL, 400 μg/mL, 200 μg/mL, 100 μg/mL, 50 μg/mL and 5 μg/mL. Measure 0.5 mL Vc standard solution (positive control), deionized water (blank control), and polysaccharide sample solutions into the test tube and then add 2.5 mL phosphate buffer solution (PBS) (pH 6.6, 0.2 M) to each test tube and shake well. Then add 2.5 mL 30 mM potassium ferricyanide solution to each test tube and shake well. The test tubes were positioned in a water bath at 50°C for 20 min and then returned to normal temperature after standing at room temperature. Then add 2.5 mL trichloroacetic acid solution (0.6 M) to each test tube, shake well, and stand still. Remove 2.5 mL supernatant from each tube and put it into the new test tube. Add 2.5 mL deionized water to the new test tube, shake well, and then add 0.5 mL ferric chloride solution (6 mM) into the new test tube and shake it calmly. The absorbance of each reaction solution at 700 nm was measured by UV spectrophotometer. Three repetitions and calculate the reduction capacity according to the following formula:
The Ability of 2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) radical scavenging
0.0192 g ABTS powder was exactly weighed and put into the centrifuge tube. 5 mL 0.01 mol/L PBS solution was added into the tube to dissolve it. After the ABTS powder is entirely dissolved, accurately weigh 0.0033 g potassium persulfate into the centrifugal tube and vibrate to make it fully thawed. Then sealing the centrifuge tube, the tube was placed in the dark at room temperature for 16 h. ABTS radical was formed by reaction. Take appropriate amount of reaction solution, add 0.01 mol/L PBS solution for dilution, so that the absorbance value of the diluted solution at 734 nm is 0.70 ± 0.02. The diluent was then equilibrated at room temperature for 30 min and the absorbance of the solution was determined at 734 nm. 1.0 mL Vc standard solution (positive control), deionized water (blank control), and each polysaccharide sample solution were surely transferred into the test tube. Add 1.0 mL of ABTS solution (A734 = 0.70 ± 0.02) to each tube, shake well, and react in the dark for 20 min at room temperature. The absorbance of the solution at 734 nm was measured by UV spectrophotometer. Three repetitions. The clearance rate was calculated as follows:
DPPH radical scavenging ability test
Specifically transfer 0.3 mL Vc standard solution (positive control), deionized water (blank control), and polysaccharide sample solutions of various concentrations into the test tube, add 0.9 mL DPPH solution (0.1 mmol/L), respectively, and react in the dark for 30 min at room temperature. Then, the absorbance of the reaction solution at 517 nm was determined by UV spectrophotometer. Three repetitions. The clearance rate is calculated as follows:
Hydroxyl radical scavenging activity test
The test was carried out according to the hydroxyl radical activity kit (Nanjing Jiancheng Biological Co., Ltd.), Vc was employed as a positive control, equal amount of deionized water was added into the blank control tube, and the absorbance value of each reaction solution at 550 nm was calculated by UV spectrophotometer.
Antioxidant activity in vivo
Specific-pathogen-free Kunming mice (male: female = 50:50, provided by Sichuan Academy of Medical Sciences) weighing 18–22 g were used in this study. All experimental processes of animals were permitted by the Ethics Committee for Animal Experimentation of Sichuan Agricultural University and carried out in accordance with the Regulations of Experimental Animal Administration distributed by the State Committee of Science and Technology of the People's Republic of China.
The mice were fed at a temperature of 21°C ± 1°C, a relative humidity of 50%–60%, 12 h of light and dark cycles, and free contact to food and water. Forty mice were arbitrarily separated into four groups, comprising control group (normal saline group), high concentration polysaccharide group (3200 μg/mL), medium concentration polysaccharide group (1600 μg/mL), and low concentration polysaccharide group (800 μg/mL). Each group was induced by a single intraperitoneal injection of D-galactose (100 mg/kg/day body weight, D-galactose dissolved in 0.9% saline solution). D-galactose model control group was intraperitoneally injected with 0.2 mL normal saline (0.9% w/V). After 28 days, the mice were destroyed by cervical dislocation. Blood samples were composed of the eye socket of mice, centrifuged, and treated with serum. The activities of GSH-Px, SOD, and the content of MDA were measured.
The test results are articulated by mean ± standard deviation. Statistical analysis was conducted with SPSS 23.0 (SPSS Inc., Chicago, USA), and significant difference, very noteworthy difference, and enormously important difference were uttered by P < 0.05, P < 0.01, and P < 0.001, respectively.
| Results|| |
Content of uronic acid and sulfate sugar in polysaccharides
DAP-A40, DAP-A60, and DAP-A80 were gained by alkaline water extraction and ethanol precipitation. The content of uronic acid in each polysaccharide sample is revealed in [Table 1]. It can be seen from [Table 1] that the content of uronic acid in DAP-A60 is the uppermost and that in DAP-A80 is the bottommost. DAP-A40 had the highest content of sugar sulfate and DAP-A80 had the lowest content.
|Table 1: Contents of uronic acid and sulfate sugar in polysaccharide of Dendrobium aurantiacum var. denneanum (Kerr)|
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Molecular weight analysis
The three polysaccharides were all white-like powder. High-performance gel permeation chromatography presented a single peak. According to the standard curve of MW, the MW was intended by using Empower software [Table 2]. It can be seen from the table that the weight average MW of the three polysaccharide samples is DAP-A40 > DAP-A60 > DAP-A80, in which DAP-A40 is an order of magnitude larger than DAP-A60 and DAP-A80, but there is no order of magnitude difference between DAP-A60 and DAP-A80. The number average MW of the three polysaccharides was DAP-A60> DAP-A40> DAP-A80. The polydispersity index of the three samples was DAP-A40> DAP-A60> DAP-A80, which disclosed that the distribution breadth of DAP-A60 and DAP-A80 was smaller than that of DAP-A40.
|Table 2: Relative molecular weight of polysaccharides from Dendrobium aurantiacum var. denneanum (Kerr)|
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Analysis of polysaccharide fragments by infrared spectroscopy
According to the infrared spectra of the polysaccharide samples, there were clear absorption peaks at 3400/cm, 2900/cm, 1600/cm, and 1400/cm. The absorption peak near 3400/cm is the distinguishing peak of –OH stretching vibration. The absorption peak near 2900/cm is the characteristic peak of –CH stretching vibration. The absorption peaks near 1600/cm and 1400/cm were stretching vibration of carboxylate anion groups, which designated that carboxyl groups were existing in the samples. The infrared spectra also showed that the three polysaccharides had multiple absorption peaks at 1200/cm-1000/cm, which were characteristic peaks of C–OH side group and stretching vibration of C–O–C glycoside band. According to the above grades, all the three samples were polysaccharides.
The infrared spectrum of DAP-A40 [Figure 1] expressed that the absorption peak near 1634/cm of DAP-A40 may be the characteristic peak of N–H angular vibration in primary amino group, secondary amino group, or amide group and stretching vibration of C = O in carbonyl group. The absorption peak here also specifies that there may be crystal water in DAP-A40. The peak near 1383/cm is the characteristic peak of symmetry stretching vibration of C = O in carbonyl group. The absorption peak near 1240/cm is the superposition of the characteristic peak of O-H variable angle vibration in –COOH and the characteristic peak of S = O stretching vibration in sulfuric acid group. At 1154/cm, 1080/cm, and 1023/cm, three characteristic peaks of pyranoside looked incessantly, representing that the monosaccharide group of DAP-A40 was pyranose. At 859/cm, the characteristic peak of α-glycosidic bond appeared.
The infrared spectrum of DAP-A60 [Figure 2] exhibited that the absorption peak near 1644/cm of DAP-A60 may be the characteristic peak of N–H angular vibration in primary amino group, secondary amino group, or amide group and stretching vibration of C = O in carbonyl group. The absorption peak here also directs that there may be crystal water in DAP-A60. At 1521/cm, the characteristic absorption peak of N–H variable angle vibration in the first-order amino group appears and the characteristic peak of C–O stretching vibration in –COOH seems at 1422/cm. The absorption peaks near 1243/cm are S = O stretching vibration in sulfuric acid group; three consecutive absorption peaks of pyranoside appear at 1157/cm, 1079/cm, and 1018/cm, and there are characteristic peaks of α-glycoside bond at 858/cm.
The infrared spectrum of DAP-A80 [Figure 3] illustrated that the absorption peak near 1643/cm of DAP-A80 may be the characteristic peak of N–H angular vibration in primary amino group, secondary amino group, or amide group and stretching vibration of C = O in carbonyl group. The absorption peak here also specifies that DAP-A80 has the characteristic peak of crystal water. The characteristic peak of C–O stretching vibration in –COOH looks at 1411/cm. The weak absorption peak near 1245/cm is S = O extending vibration in sulfuric acid group. The characteristic absorption peak of pyranoside appears at 1150/cm, 1077/cm, and 1039/cm. The peak of 901/cm is the characteristic of glycosidic bond with β-configuration performed.
Antioxidant activity of polysaccharide fragments
Reducibility of polysaccharide fragments
The results of reducibility investigation are revealed in [Figure 4]. It can be seen from the figure that the positive control and the three polysaccharides have a definite decreased ability to ferric ions. However, the reducing ability of polysaccharides to Fe (el is different at different concentrations. When the concentration was in the range of 25–800 μg/mL, the reducing ability of DAP-A60 and DAP-A80 augmented with the increase of concentration, but it was visibly weaker than Vc. When the concentration was higher than 800 μg/mL, the reducing ability of DAP-A60 and DAP-A80 increased slowly. When the concentration was 3200 μg/mL, the reducing ability of DAP-A80 was close to that of Vc (P > 0.05) and its half-maximal inhibitory concentration (IC50) was 163.5 μg/mL [Table 3]. However, the reducing ability of DAP-A40 was lower than that of Vc and had no clear change with the surge of concentration.
|Table 3: The half-maximal inhibitory concentration of different samples (μg/mL)|
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It can be seen that the reducing ability of each polysaccharide sample is dissimilar. Among them, DAP-A80 has the solidest scavenging ability and its reduction ability is close to that of positive control at high concentration (3200 μg/mL). DAP-A40 had the feeblest reduction ability, which was much lower than that of the positive control.
Ability of polysaccharides to scavenge 2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) free radicals
It can be seen from [Figure 5] that the polysaccharide samples and Vc have confident scavenging ability to ABTS free radicals. When the concentration was in the range of 25–800 μg/mL, the scavenging ability of DAP-A60 and DAP-A80 to ABTS radical augmented with the increase of concentration, viewing a certain concentration dependence. When the concentration of DAP-A80 was 800 μg/mL, the scavenging capacity of DAP-A80 was close to that of Vc (P > 0.05) and its IC50 was 613.2 μg/mL [Table 3].
|Figure 5: The abilities of polysaccharides to scavenge 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) free radicals|
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When the concentration of DAP-A80 was higher than 800 μg/mL, the scavenging ability of DAP-A80 to ABTS radical was near to that of Vc and almost no change was detected. However, the scavenging ability of DAP-A60 to ABTS radical augmented with the increase of concentration. When the concentration of DAP-A60 was 3200 μg/mL, the scavenging capacity of DAP-A60 to ABTS free radical was 87.6%, which had no momentous difference compared with Vc (P > 0.05), and IC50 was 1839.8 μg/mL [Table 3]. However, DAP-A80 had the same scavenging capacity at the concentration of 800 μg/mL. Therefore, DAP-A80 has a stronger ability to scavenge ABTS radicals than DAP-A60. However, DAP-A40 had the weakest ability to scavenge ABTS free radicals. When the concentration was 3200 μg/mL, the scavenging rate of DAP-A40 was only 9.66%. The scavenging ability of Vc and the other two polysaccharide samples was much lower than that of DAP-A40 group. It can be seen that the scavenging ability of the polysaccharides to ABTS radical is diverse. Among them, DAP-A80 has the strongest scavenging ability and it has stretched the clearance ability of positive control at a low concentration (800 μg/mL). DAP-A40 had the weakest ability to eliminate ABTS.
Ability of polysaccharides to scavenge DPPH free radicals
The DPPH radical scavenging outcomes of polysaccharide samples and Vc are publicized in [Figure 6]. It can be seen from the figure that when the polysaccharide concentration is in the range of 25–800 μg/mL, the scavenging ability of each polysaccharide sample upsurges with the increase of the concentration, viewing a certain degree of concentration dependence. The positive control Vc showed a very strong scavenging capacity, even at a low concentration (25 μg/mL), its scavenging capacity could extent to 66.2%. When the concentration increased to 1600 μg/mL, scavenging ability on DPPH radical was no significant difference between DAP-A80 and Vc (P > 0.05) and the IC50 of DAP-A80 was 583.2 mg/mL [Table 3]. When the concentration was 1600 μg/mL, the scavenging ability of DAP-A60 and DAP-A40 on DPPH radical was also amplified to some extent, but it was much lower than that of Vc (P < 0.05). When the concentration was higher than 1600 μg/mL, the DPPH radical scavenging ability of DAP-A80 was slightly higher than that of Vc. The DPPH radical scavenging capacity of DAP-A60 was increased greatly, but it was still suggestively lower than that of Vc. The DPPH radical scavenging ability of DAP-A40 was still significantly lower than that of Vc (P < 0.05). It can be seen that the DPPH radical scavenging ability of each polysaccharide sample is different. The scavenging ability of DAP-A80 was the sturdiest. DAP-A40 had the weakest scavenging ability to DPPH free radicals, even at a high concentration (3200 μg/mL), its scavenging rate was only 22.49%.
|Figure 6: The abilities of polysaccharides to scavenge DPPH free radicals|
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Ability of polysaccharides to scavenge OH free radicals
[Figure 7] indicates the hydroxyl radical scavenging results of three polysaccharide samples and Vc. It can be seen from the graph results that when the concentration of polysaccharides is in the range of 25–800 μg/mL, the scavenging ability of polysaccharides to hydroxyl radical increases with the increase of concentration, showing a certain concentration dependence. Among them, DAP-A80 enlarged the most. When the concentration was 800 μg/mL, the clearance rate of DAP-A80 reached the maximum value, close to Vc. The IC50 of DAP-A80 was 365.1 μg/mL [Table 3], which was much stronger than the other two polysaccharide samples (IC50 of 4538.0 and 4500.6 μg/mL, respectively). When the concentration sustained to increase, the clearance rate of DAP-A80 was near Vc and did not alteration. When the concentration continued to increase, the scavenging rate of DAP-A60 and DAP-A40 to OH radical augmented slowly. Although it also showed a concentration-dependent manner, its scavenging capacity was weak, even at high concentrations, it was significantly lower than that of positive control and DAP-A80 (P < 0.05). It can be seen that the scavenging ability of these three polysaccharide fragments to OH radical is dissimilar. Among them, DAP-A80 has the strongest scavenging ability and it has grasped the clearance ability of positive control at a low concentration (800 μg/mL). However, DAP-A40 and DAP-A60 showed a weak scavenging effect on OH radicals.
Correlation analysis of antioxidant activity of polysaccharides
The relationship between the content of sulfated sugar and uronic acid, MW, and antioxidant activity of three polysaccharide samples of D. aurantiacum var. denneanum (Kerr) is shown in [Table 4]. The MW of polysaccharide was negatively connected with its capability to scavenge ABTS, DPPH, and OH free radicals and was significantly interrelated with the activity of scavenging ABTS and DPPH free radicals. The correlation coefficients were −0.988 and −0.994, respectively. However, the content of sulfate group was definitely correlated with ABTS, DPPH, and OH radical scavenging activities and the correlation coefficients were 0.915, 0.932, and 0.869, respectively. On the contrary, there was no relationship between the content of glucuronic acid and antioxidant capacity. At the same time, the reducing ability of polysaccharides has no correlation with MW, sulfate sugar, and uronic acid. Therefore, the results displayed that the MW and the content of sulfated sugar could ominously affect the free radical scavenging ability of polysaccharides.
|Table 4: Relationship between the content of molecular weight, sulfate content, uronic acid, and the antioxidant activity|
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Antioxidant activities in vivo
The marks of antioxidant experiment in vitro presented that DAP-A80 had the strongest antioxidant activity, so DAP-A80 was picked to estimate the antioxidant activity in vivo. The results are shown in [Table 5]. It can be seen from the table that there was no substantial change between DAP-A80 and the control at low concentrations. With the increase in the concentration, the effect of DAP-A80 on GSH-Px augmented progressively. The maximum activity was recorded at DAP-A80/H. DAP-A80 might enticingly recover the activity of GSH-Px (P < 0.01). Compared with the control group, DAP-A80 expressively augmented the activity of SOD at low concentration (P < 0.05). With the increase in polysaccharide levels, the effect of DAP-A80 on the activity of SOD is superior. According to the results, low levels of DAP-A80 might knowingly eradicate MDA from mouse serum compared with control and the higher the concentration of DAP-A80 was the more perceptible the effect of clear MDA.
| Discussion|| |
The monosaccharide groups of polysaccharides cover different numbers of active hydroxyl groups, which deliver active hydrogen or electrons. They can act as donors of hydrogen protons or electrons, straight quench free radicals, or inhibit the chain reaction of free radicals, so as to evade the damage of free radicals to cells. Their derivatives increase the active groups such as amino group and carboxyl group, which will advance the ability of scavenging free radicals. In this study, three polysaccharide fragments showed different antioxidant activities in vitro. Among them, DAP-A80 had the stoutest antioxidant activity, especially at the high concentration (3200 μg/mL), its antioxidant capacity was near to the positive control Vc, and there was no significant difference (P < 0.05).
Combined with some reports, we reflect that DAP-A80 may quench free radicals or inhibit the chain reaction of free radicals, thus comprehending chemical antioxidant. Similar results are also imitated in other polysaccharides, such as the polysaccharides extracted from pistachio external hull have a palpable scavenging effect on ABTS free radical and DPPH free radical, and the Sagittaria trifolia polysaccharide can knowingly scavenge hydroxyl, DPPH, and ABTS free radicals.
Research displays that the biological activity of polysaccharides is carefully connected to their structural characteristics. Therefore, the relationship between the structural characteristics of polysaccharides and their capacity to scavenge free radicals was considered in this study. The results showed that the MW of polysaccharide was negatively correlated with its ability to scavenge ABTS+, DPPH, and ·OH radicals and was ominously correlated with the activity of scavenging ABTS + and DPPH free radicals. The correlation coefficients were −0.988 and −0.994, respectively. This may be due to the higher the MW, the worse the water solubility and the weaker the binding ability with the receptor, causing the poor adhesion of polysaccharides on target organs, which greatly lessens its effect.
It is stated that the sulfated groups in polysaccharides typically affect their biological activities. The results of this experiment also showed that the content of sulfate group in polysaccharide samples was positively correlated with ABTS, DPPH, and OH radical scavenging activities and the correlation coefficients were 0.915, 0.932, and 0.869, respectively. Therefore, the results indicated that the MW and the content of sulfated sugar could pointedly affect the free radical scavenging ability of polysaccharides.
SOD and GPx are the foremost antioxidant enzymes in cells, which can aid cells to resist oxidation. In this study, DAP-A80 can surge cell viability, enhance the activities of antioxidant enzymes SOD and GPx, and diminish the content of MDA in cells with oxidative damage in a concentration-dependent manner. It has been stated that polysaccharides can not only scavenge free radicals as hydrogen proton or electron donors, but also bind to cell receptors as signal substances, activate antioxidant related signal pathways and regulate antioxidant enzymes, so as to play an antioxidant role. Hence, combined with the results of this experiment, we deduce that DAP-A80 can diminish the MDA and increase the activities of GSH-PX and SOD in mice. Similar results are also reproduced in other polysaccharides, such as Hericium erinaceus crude polysaccharide can reduce the activity of myeloperoxidase in gastric tissue, increase the activities of SOD and GPx, expand the antioxidant status of gastric tissue, and help to maintain the integrity of gastric mucosa.
| Conclusion|| |
In this study, DAP-A40, DAP-A60, and DAP-A80 were acquired by alkaline aqueous solution extraction and ethanol precipitation. The content of glucuronic acid was tried. GPC analysis showed that the MW of DAP-A40, DAP-A60, and DAP-A80 was 1.70 × 105 Da, 5.78 × 104 Da, and 1.36 × 104 Da, respectively. Infrared spectrum unveiled that DAP-A40 and DAP-A60 were α-configuration polysaccharides. The results exposed that DAP-A80 has a strong antioxidant activity in vitro and in vivo.
All experimental processes of animals were approved by the Ethics Committee for Animal Experimentation of Sichuan Agricultural University and carried out in accordance with the Regulations of Experimental Animal Administration issued by the State Committee of Science and Technology of the People's Republic of China.
This research was funded by International Science and Technology Innovation Cooperation Project of Sichuan (2022YFH0036) and Sichuan 19 Science and Technology Program (2021YFYZ0012).
Financial support and sponsorship
This study was financially supported by the National Natural Science Foundation of China.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Bao XS, Shun QS, Chen LZ. Chinese Medicinal Dendrobium. Shanghai: Fudan University Press; 2001.
Luo AX, He XJ, Zhou SD, Fan YJ, Luo AS, Chun Z. Purification, composition analysis and antioxidant activity of the polysaccharides from Dendrobium nobile
Lindl. Carbohyd. Polym 2010;79:1014-9.
Zhao YP, Son YO, Kim SS, Jang YS, Lee JC. Antioxidant and anti-hyperglycemic activity of polysaccharide isolated from Dendrobium chrysotoxum
lindl. J Biochem Mol Biol 2007;40:670-7.
He TG, Yang LT, Li YR, Wang CQ, Huang DP. Physicochemical properties and antitumor activity of polysaccharide DCPP1a-1 from suspension-cultured protocorms of Dendrobium candidum
. Nat Prod Res Dev 2007;19:578-83.
Wang JH, Luo JP, Zha XQ, Feng BJ. Comparison of antitumor activities of different polysaccharide fractions from the stems of Dendrobium nobile
Lindl. Carbohyd Polym 2010;79:114-8.
Xia LJ, Liu XF, Guo HY, Zhang H, Zhu J, Ren FZ. Partial characterization and immunomodulatory activity of polysaccharides from the stem of Dendrobium officinale
(Tiepishihu) in vitro
. J Funct Foods 2012;4:294-301.
Pan LH, Wang J, Ye XQ, Zha XQ, Luo JP. Enzyme-assisted extraction of polysaccharides from Dendrobium chrysotoxum
and its functional properties and immunomodulatory activity. LWT Food Sci Technol 2015;60:1149-54.
Fan Y, Yu Q, Wang G, Tan J, Liu S, Pu S, et al.
Effects of non-thermal plasma treatment on the polysaccharide from Dendrobium nobile
Lindl. and its immune activities in vitro
. Int J Biol Macromol 2020;153:942-50.
Fan YJ, He XJ, Zhou SD, Luo AX, He T, Chun Z. Composition analysis and antioxidant activity of polysaccharide from Dendrobium denneanum
. Int J Biol Macromol 2009;45:169-73.
Fan YJ, Luo AX. Evaluation of anti-tumor activity of water-soluble polysaccharides from Dendrobium denneanum
. Afr J Pharm Pharmacol 2011;5:415-20.
Peter A, Southorn GP. Free radicals in medicine. I. Chemical nature and biologic reactions. Mayo Clin Proc 1988;63:381-9.
Zhou TY, Xiang XW, Du M, Zhang LF, Cheng NX, Liu XL, et al.
Protective effect of polysaccharides of sea cucumber Acaudina leucoprocta
on hydrogen peroxide-induced oxidative injury in RAW264.7 cells. Int J Biol Macromol 2019;139:1133-40.
Qin T, Ren Z, Liu X, Luo Y, Long Y, Peng S, et al.
Study of the selenizing Codonopsis pilosula
polysaccharides protects RAW264.7 cells from hydrogen peroxide-induced injury. Int J Biol Macromol 2019;125:534-43.
Diao Y, Xin YQ, Zhou Y, Li N, Pan XL, Qi SM, et al.
Extracellular polysaccharide from Bacillus sp. strain LBP32 prevents LPS-induced inflammation in RAW 264.7 macrophages by inhibiting NF-κB and MAPKs activation and ROS production. Int Immunopharmacol 2014;18:12-9.
Schepetkin IA, Quinn MT. Botanical polysaccharides: Macrophage immunomodulation and therapeutic potential. Int Immunopharmacol 2006;6:317-33.
Ludowieg J, Dorfman A. A micromethod for the colorimetric determination of N-acetyl groups in acid mucopolysaccharides. Biochim Biophys Acta 1960;38:212-8.
Boeley JG. Glycoprotein and Proteoglycan Techniques. Amsterdam, New York and Oxford: Elsevier; 1985. p. 149-51.
Dodgson KS, Price RC. A note on the determination of the ester sulfate content of sulfated polysaccharides. Biochem J 1962;84:106-10.
Luo AX, He XJ, Zhou SD, Fan YJ, He T, Chun Z. In vitro
antioxidant activities of a water-soluble polysaccharide derived from Dendrobium nobile
Lindl. extracts. Int J Biol Macromol 2009;45:359-63.
Wang YG, Li YL, Ma XQ, Ren HW, Fan WG, Leng FF, et al.
Extraction, purification and bioactivities analyses of polysaccharides from Glycyrrhiza uralensis
. Ind Crops Prod 2018;122:596-608.
Luo AX, Luo AS, Huang JD, Fan YJ. Purification, characterization and antioxidant activities in vitro
and in vivo
of the polysaccharides from Boletus edulis
Bull. Molecules 2012;17:8079-90.
Luo AX, Fan YJ. In vitro
antioxidant of a water-soluble polysaccharide from Dendrobium fimhriatum
Hook.var.oculatum Hook. Int J Mol Sci 2011;12:4068-79.
Liu XG, Bian J, Li DQ, Liu CF, Xu SS, Zhang GL, et al.
Structural features, antioxidant and acetylcholinesterase inhibitory T activities of polysaccharides from stem of Physalis alkekengi
L. Ind Crops Prod 2019;129:654-61.
Xia Z. Preparation of the oligosaccharides derived from Flammulina velutipes
and their antioxidant activities. Carbohydr Polym 2015;118:41-3.
Frank SP. Application of Infrared, Xaman and Resonance Raman Spectroscopy in Biochemist. New York: Plenum Plenum Press; 1963.
Anthony TT, Jamine L, Yuan CL. Laser Raman spectroscopic study of carbohydrates: 1-Thio-β-D-hexopyranosides. Carbohyd Res1978;67:295-304.
Barrett TW, Peticolas WL. Laser Raman inelastic light scattering investigations of hyaluronic acid primary and secondary structure. J Raman Spectrosc 1979;8:35-8.
Mariem H, Hajer B, Wafa K, Fatma K, Anissa H, Ali B, et al.
Polysaccharides extracted from pistachio external hull: Characterization, antioxidant activity and potential application on meat as preservative. Ind Crops Prod 2020;148:112315.
Gu J, Zhang H, Wen C, Zhang J, He Y, Ma H, et al.
Purification, characterization, antioxidant and immunological activity of polysaccharide from Sagittaria sagittifolia
L. Food Res Int 2020;136:109345.
Bilal MK, Qiu HM, Wang XF, Liu ZY, Zhang JY, GuoYJ, et al.
Physicochemical characterization of Gracilaria chouae
sulfated polysaccharides and their antioxidant potential. Int J Biol Macromol. 2019;134: 255-261.
Wang XY, Yin JY, Zhao MM, Liu SY, Nie SP, Xie MY. Gastroprotective activity of polysaccharide from Hericium erinaceus
against ethanol-induced gastric mucosal lesion and pylorus ligation-induced gastric ulcer, and its antioxidant activities. Carbohydr Polym 2018;186:100-9.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6], [Figure 7]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]