A Concise Review of Extraction and Characterization of Chondroitin Sulphate from Fish and Fish Wastes for Pharmacological Application
Abstract
:1. Introduction
2. Chondroitin Sulphate
2.1. Biosynthesis of CS
2.2. Fish and Fish Wastes for CS Production
2.2.1. Extraction and Isolation Technique
2.2.2. Purification and Characterization
3. Prospective Pharmacological Application
4. Conclusions and Recommendations
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Stages | Enzyme Involved | Specific Function in CS Biosynthesis |
---|---|---|
Initiation | Glycosyltransferase | Catalyzed linkage region in the tetra-saccharide structure |
Disaccharide unit formation | Xylosyltransferase | Catalyzed linkage between xylose and serine residue |
β1,4-galactosyltransferase I and β1,3-galactosyltransferase II | Catalyzed linkage between galactose and serine residues, in turn | |
β1,3-glucuronyltransferase I | Catalyzed the formation of tetrasaccharide linkage region by adding GlcUA residue | |
GalNAc transferase I | Catalyzed transfer of GalNAc residue to the nonreducing terminal GlcA residue and Chondroitin skeleton by adding GlcA and GalNAc residues in turn | |
Polymerization | GalNAc transferase II and GlcA transferase II | Form repeating disaccharide GlcA-GlaNAc in Chondroitin skeleton by alternative catalysis |
Source Name | Body Part | Enzyme | Extraction a | Analytical Methods | Yield | CS | Other GAGs | Reference |
---|---|---|---|---|---|---|---|---|
Nile tilapia | Skin | Alcalase | Acetone, chloroform, methanol, TCA, NaCl, ethanol | AEC, NMR, AGE | 0.15% DW | √ | DS, HS | [33] |
Pacu fish | 0.18% DW | |||||||
Nile tilapia | Scale | Crude papain | Acetone, TCA, ethanol | IEC, AGE, NMR | 0.86% DW | √ | - | [30] |
Nile tilapia | Bone residues (spine) | Papain | Ethanol, NaCl | TGA, DSC, FTIR, SEM | 80% (residue: ethanol) | √ | - | [45] |
Nile tilapia | Skin | Papain | Sodium acetate, CPC, ethanol | IEC, AGE | 10% | √ | DS | [34] |
Grey triggerfish | Skin | Alcalase | Sodium acetate, CPC, NaCl, ethanol | CAE | 8.6% | √ | DS, HS | [23] |
Smooth dogfish | 9.3% | |||||||
Monkfish Codfish Spiny Dogfish and Tuna | Bones | Papain (ED) | Acetone, Sodium acetate, NaCl, ethanol | AEC, AGE | Monkfish 0.34% Codfish 0.011% Dogfish 0.28%Tuna 0.023% (% w/w of bones) | √ | - | [32] |
Silver-banded whiting | Head | Lyase | Ethanol, NaCl, NaOH, | SEC, HPLC, NMR | 70:20% and 50:30%, | √ | HA | [35] |
Salmo salar fish | Collagen-based scaffolds | Papain | Acetone, Sodium acetate, ethanol | Spectrophotometry | 5% | √ | - | [31] |
Labeo rohita Piaractus brachypomus | Head | Papain | Acetone, TCA, ethanol, K-acetate | reverse-phase HPLC. | √ | DS | [17] |
Fish Species | Char. of CS | Exp. Type (Model) | Dose and Admin. | Exp. Cond. | Pharmacology | Key Results | Ref. |
---|---|---|---|---|---|---|---|
Tilapia (Oreochromis niloticus) viscera | 4-sulfated CS (59.6%); 6-sulfated CS (36.6%); Non-sulfated CS (3.4%) | In vitro (chemical analysis) | 20, 40, 100, and 200 µg/mL | 37 °C; 24 h | Antioxidant | ↓ ROS (p < 0.01) highest level at 40 µg/mL | [116] |
Nile tilapia (Oreochromis niloticus) viscera | CS-rich GAGs; Yield (0.15% of the freeze-dried sample) | In vitro (aPTT) | 0.25 mg/mL | 37 °C; 1 min | Anticoagulant | The Nile tilapia increased normal clotting time (2.3–2.8). The Pacu increased normal coagulation time (1.5–2.4) | [33] |
Pacu (Piaractus mesopotamicus) viscera | CS-rich GAGs; Yield (0.158 of the dry sample) | ||||||
Grey triggerfish skins (GTCS) | Purity (99.2%); 41.72 kDa; 4-sulfated CS (59%); 6-sulfated CS (18.2%); Non-sulfated CS (3.5%) | In vitro (HCT116 cells) | 10–200 µg/mL | 1 × 107 cells/mL; 37 °C; 24 h | Anticancer | ↓ 70.6% for GTCS and 72.65% for SHCS (p < 0.05) at 200 µg/mL; No hemolysis; No cytotoxicity against the normal lymphocytes | [117] |
Smooth hound skins (SHCS) | Purity (95.4%); 23.8 kDa; 4-sulfated CS (47%); 6-sulfated CS (14.6%); Non-sulfated CS (5.5%) | ||||||
Salmon cartilage | 4-sulfated CS (30–40%); 6-sulfated CS (50–60%) | In vitro (Chemical analysis) | 1, 2, 5, 10, 20 mg/mL | Chelating with divalent metal ions, Ca2+, Mg2+, Mn2+, or Zn2+ | Antioxidant | Sulfated CS has significant antioxidant potency; CS chelation with Ca2+ or Mg2+ remarkably increased SOD radical scavenging; and CS chelation with Ca2+, Mg2+, Mn2+, or Zn2+ increased hydroxyl radical scavenging | [118] |
Shark cartilage | 4-sulfated CS (30%); 6-sulfated CS (40%) | ||||||
Ray cartilage | HMWCS; 6-sulfated CS (61.9%); 4-sulfated CS (27.0%); 2-sulfated CS-6-sulfated CS (8.5%); 142 kDa | In vitro (Hippocampal cells from E16 mice) | 2 μg/well | 2 × 104 cells/cm2; 37 °C; 24 h | Neuritogenic activity | ↑ Neurite outgrowth through the HGF signaling pathway; Specific binding of HGF to the CS | [119] |
Skate (Raja pulchra) | HMWCS | In vitro and | 5 or 50 mg/ml | 37 °C; 10 or 30 min | Anti-obesity | Ø Pancreatic lipase activity; Ø Proliferation and lipid accumulation in mature adipocytes; HMWCS has greater lipase inhibitory activity than LMWCS; | [120] |
In vitro (mouse 3T3-L1) | Various concentrations and time points | 37 °C; 15 min | |||||
In vivo (C57B/6 J mice; male; 4w) | 50 mg/5 mL/kg/day; orally | 8 w | |||||
Skate cartilage | CSE, CS | In vivo (Mice) | 200, 400 mg/kg; orally | 3 consecutive days | Antiinflammation, hepatic dyslipidemia | ↑ Hepatic antioxidant enzyme expression levels; Ø Inflammatory factors; ↓ Serum lipid; ↓ hepatic sterol regulatory element-binding proteins expression; ↓ MAPK; and ↓ Apoptopic factors | [121] |
Sturgeon cartilage | AMWCS; 4-sulfated CS (88.8%); 8 kDa | In vitro (Fibroblast) | 100 µg/ml | 1 × 103 cells/well; 37 °C; 24 h | Wound healing | ↑ cell adhesion; ↑ Proliferation and migration on fibroblasts; and ↑ MAPK signaling pathways | [122] |
Sturgeon backbone | AMWCS; 6-sulfated CS (60%); 43 kDa | ||||||
Sturgeon skull | AMWCS; non-sulfated CS (74.2%); 38.5 kDa | In vitro (Rabbit blood) | 1, 3, 5 mg/ml | 360 µL of platelet-poor plasma; 15 min | Anticoagulant, anti-platelet, and thrombolysis | ↑ aPTT; ↑ TT; Ø Platelet aggregation; Dissolved platelet plasma clots; Sturgeon backbone CS was stronger than sturgeon skull CS | [123] |
Sturgeon backbone | AMWCS; 4-sulfated CS (37.8%); 6-sulfated CS (59.6%); 49.2 kDa | ||||||
Shark cartilage | LMWCS (75.7%); 3.9 kDa | In vitro (PC12; SH-SY5Y) | 50, 100, 200 µg/ml | 0.5 × 104 cells/well; 24 h | Neuroprotection | × Cell viability loss and apoptosis; ↓ Intracellular Ca; ↓ ROS levels; ↓ MMP depolarization; and ↓ Protein expression of Caspase-3 | [124] |
Shark cartilage | LMWCS (75.7%); 3.9 kDa | In vivo (Male Balb/c mice; 8 w) | 50, 150, 450 mg/kg; perorally (p.o.) | Daily; 31 days | Neuroprotection | Improved the cognitive impairment; ↑ ChAT level; ↑ SOD; and ↑ GSH-Px; ↓ MDA level; and ↓ AChE level; ↓ Pyramidal cells of CA1 regions; Ø Protein expression of Bax/Bcl-2 and Caspase3, -9. | [124] |
Small sea fish | CS Extracts (CP) | In vitro (CHON-001) | CP 0.2%, 0.3% (v/v in culture medium); CS 3, 200 µg/mL | 48, 72 h | Osteoarthritis | × Chondrocytes decline; Ø Osteo-articular inflammation Ø Apoptosis; and ↑ Proliferation rate | [125] |
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Urbi, Z.; Azmi, N.S.; Ming, L.C.; Hossain, M.S. A Concise Review of Extraction and Characterization of Chondroitin Sulphate from Fish and Fish Wastes for Pharmacological Application. Curr. Issues Mol. Biol. 2022, 44, 3905-3922. https://doi.org/10.3390/cimb44090268
Urbi Z, Azmi NS, Ming LC, Hossain MS. A Concise Review of Extraction and Characterization of Chondroitin Sulphate from Fish and Fish Wastes for Pharmacological Application. Current Issues in Molecular Biology. 2022; 44(9):3905-3922. https://doi.org/10.3390/cimb44090268
Chicago/Turabian StyleUrbi, Zannat, Nina Suhaity Azmi, Long Chiau Ming, and Md. Sanower Hossain. 2022. "A Concise Review of Extraction and Characterization of Chondroitin Sulphate from Fish and Fish Wastes for Pharmacological Application" Current Issues in Molecular Biology 44, no. 9: 3905-3922. https://doi.org/10.3390/cimb44090268
APA StyleUrbi, Z., Azmi, N. S., Ming, L. C., & Hossain, M. S. (2022). A Concise Review of Extraction and Characterization of Chondroitin Sulphate from Fish and Fish Wastes for Pharmacological Application. Current Issues in Molecular Biology, 44(9), 3905-3922. https://doi.org/10.3390/cimb44090268