Some Using Places of Marine-Derived Aspergillus niger in Biotechnology: A Mini Review

Yıl 2024, Cilt: 3 Sayı: 1, 130 - 141, 25.04.2024

Zehra Torun

Öz

Marine animals and plants, as well as inanimate habitats such as saltwater, sediments, hydrothermal vents, mud, and mudflats, are all home to marine fungi. Marine fungi are resistant to harsh marine conditions and may adapt. These marine microorganisms are significant because they can be easily cultivated and used repeatedly, as well as being safely stored in a laboratory setting. Thus, they are included in many biotechnological applications. In this review, we aimed to sum up the use of marine-derived Aspergillus niger fungus in biotechnology. The use of fungi in biotechnological applications such as bioremediation of heavy metals, biosynthesis of nanoparticle and nanofluid samples, production of valuable enzymes was explained in the section of biotechnological applications.

Anahtar Kelimeler

Marine fungi, eco-friendly applications, biotechnology

Kaynakça

• Giddings LA, Newman D J. Bioactive compounds from extremophilic marine fungi. In Fungi in Extreme Environments: Ecological Role and Biotechnological Significance, 2019. 349-382. Springer, Cham.
• Saravanakumar K, Rajendren N, Kathiresan K, Wang MH. Medicinal Drug‐related Bioactive Agents from Marine Fungi. Encyclopedia of Marine Biotechnology, (2020);4: 2173-2190.
• Damare S, Singh P, Raghukumar S. Biotechnology of marine fungi. Biology of Marine Fungi, 2012; 277-297.
• Tieghem, PV. Description d'une nouvelle espèce d'Aspergillus: A. niger. Paper presented at the Annales des Sciences Naturelles Botanique, 1867.
• Bennett JW. An overview of the genus Aspergillus. Aspergillus: molecular biology and genomics, 2010. 1-17.
• Varga J, Frisvad JC, Kocsubé S, Brankovics B, Tóth B, Szigeti G, Samson R. New and revisited species in Aspergillus section Nigri. Studies in Mycology, 2011; 69: 1-17.
• Lima MA, de Oliveira MdC., Pimenta A, Uchôa P. Aspergillus niger: A Hundred Years of Contribution to the Natural Products Chemistry. Journal of the Brazilian Chemical Society. 2019.
• Rateb ME, Ebel R. Secondary metabolites of fungi from marine habitats. Nat Prod Rep, 2011; 28(2): 290-344.
• Ehrlich HL. Microbes and metals. Applied microbiology and biotechnology, 1997; 48(6): 687-692.
• Vala AK, Anand N, Bhatt PN, Joshi HV. Tolerance and accumulation of hexavalent chromium by two seaweed associated aspergilli. Marine Pollution Bulletin, 2004; 48(9-10): 983-985.
• Khambhaty Y, Mody K, Basha S, Jha B. Kinetics, equilibrium and thermodynamic studies on biosorption of hexavalent chromium by dead fungal biomass of marine Aspergillus niger. Chemical Engineering Journal, 2009; 145(3): 489-495.
• Xu S, Zhang Q, Bai D, Cai L, Lu T, Yao S. Removal process and mechanism of hexavalent chromium by adsorption-coupled reduction with marine-derived Aspergillus niger mycelial pellets. Chinese Journal of Chemical Engineering, 2021.
• Iskandar NL, Zainudin NAIM, Tan SG. Tolerance and biosorption of copper (Cu) and lead (Pb) by filamentous fungi isolated from a freshwater ecosystem. Journal of Environmental Sciences, 2011; 23(5): 824-830.
• Gazem MA, Nazareth S. Sorption of lead and copper from an aqueous phase system by marine-derived Aspergillus species. Annals of Microbiology, 2013; 63(2): 503-511.
• Shah SS, Palmieri MC, Sponchiado SRP, Bevilaqua D. Environmentally sustainable and cost-effective bioleaching of aluminum from low-grade bauxite ore using marine-derived Aspergillus niger. Hydrometallurgy, 2020; 195, 105368.
• Dinçer AR, Güneş Y, Karakaya N, Güneş E. Comparison of activated carbon and bottom ash for removal of reactive dye from aqueous solution. Bioresource Technology, 2007; 98(4): 834-839.
• Yagub MT, Sen TK, Afroze S, Ang HM. Dye and its removal from aqueous solution by adsorption: a review. Advances in Colloid and Interface Science, 2014; 209: 172-184.
• Liu S, Song H, Wei S, Liu Q, Li X, Qian X. Effect of direct electrical stimulation on decolorization and degradation of azo dye reactive brilliant red X-3B in biofilm-electrode reactors. Biochemical Engineering Journal, 2015; 93: 294-302.
• Wang MX, Zhang QL, Yao SJ. A novel biosorbent formed of marine-derived Penicillium janthinellum mycelial pellets for removing dyes from dye-containing wastewater. Chemical Engineering Journal, 2015; 259: 837-844.
• Wucherpfennig T, Kiep KA, Driouch H, Wittmann C, Krull R. Morphology and rheology in filamentous cultivations. Advances in Applied Microbiology, 2010; 72: 89-136.
• Krull R, Cordes C, Horn H, Kampen I, Kwade A, Neu TR, Nörtemann B. Morphology of filamentous fungi: linking cellular biology to process engineering using Aspergillus niger. In Biosystems Engineering II, 2010; 1-21. Springer, Berlin, Heidelberg.
• Papagianni M. Fungal morphology and metabolite production in submerged mycelial processes. Biotechnology Advances, 2004; 22(3): 189-259.
• Sharma P, Kaur H, Sharma M, Sahore V. A review on applicability of naturally available adsorbents for the removal of hazardous dyes from aqueous waste. Environmental monitoring and assessment, 2011; 183(1): 151-195.
• Assadi MM, Jahangiri MR. Textile wastewater treatment by Aspergillus niger. Desalination, 2001; 141(1): 1-6.
• Lu T, Zhang Q, Yao S. Efficient decolorization of dye-containing wastewater using mycelial pellets formed of marine-derived Aspergillus niger. Chinese Journal of Chemical Engineering, 2017; 25(3): 330-337.
• Vala AK, Shah S. Rapid synthesis of silver nanoparticles by a marine-derived fungus Aspergillus niger and their antimicrobial potentials. International Journal of Nanoscience and Nanotechnology, 2012; 8(4): 197-206.
• Vala AK, Chudasama B, Patel RJ. Green synthesis of silver nanoparticles using marine-derived fungus Aspergillus niger. Micro & Nano Letters, 2012; 7(8): 859-862.
• Dave V, Vala AK, Patel R. Observation of weak localization of light in gold nanofluids synthesized using the marine derived fungus Aspergillus niger. RSC Advances, 2015; 5(22): 16780-16784.
• Abdelwahab GM, Mira A, Cheng YB, Abdelaziz TA, Lahloub MFI, Khalil AT. Acetylcholine esterase inhibitory activity of green synthesized nanosilver by naphthopyrones isolated from marine-derived Aspergillus niger. PloS One, 2021; 16(9): e0257071.
• Bonugli-Santos RC, dos Santos Vasconcelos MR, Passarini MR, Vieira GA, Lopes VC, Mainardi PH, Sette LD. Marine-derived fungi: diversity of enzymes and biotechnological applications. Frontiers in Microbiology, 2015; 6: 269
• Labrou N. (Ed.). Therapeutic Enzymes: Function and Clinical Implications, 2019; Vol. 1148. Springer Nature.
• Zhao XQ, Xu XN, Chen LY. Production of enzymes from marine actinobacteria. Advances in Food and Nutrition Research, 2016; 78: 137-151.
• Fu CC, Hung TC, Chen JY, Su CH, Wu WT. Hydrolysis of microalgae cell walls for production of reducing sugar and lipid extraction. Bioresource Technology, 2010; 101(22): 8750-8754.
• Xue DS, Chen HY, Ren YR, Yao SJ. Enhancing the activity and thermostability of thermostable β-glucosidase from a marine Aspergillus niger at high salinity. Process Biochemistry, 2012; 47(4): 606-611.
• Xue DS, Chen HY, Lin DQ, Guan YX, Yao SJ. Optimization of a natural medium for cellulase by a marine Aspergillus niger using response surface methodology. Applied Biochemistry and Biotechnology, 2012; 167(7): 1963-1972.
• Xue D, Lin D, Gong C, Peng C, Yao S. Expression of a bifunctional cellulase with exoglucanase and endoglucanase activities to enhance the hydrolysis ability of cellulase from a marine Aspergillus niger. Process Biochemistry, 2017; 52: 115-122.
• Xue DS, Liang LY, Zheng G, Lin DQ, Zhang QL, Yao SJ. Expression of Piromyces rhizinflata cellulase in marine Aspergillus niger to enhance halostable cellulase activity by adjusting enzyme-composition. Biochemical Engineering Journal, 2017; 117: 156-161.
• Xue DS., Liang LY, Lin DQ, Gong CJ, Yao SJ. Halostable catalytic properties of exoglucanase from a marine Aspergillus niger and secondary structure change caused by high salinities. Process Biochemistry, 2017; 58: 85-91.
• Cai LN, Xu SN, Lu T, Lin DQ, Yao SJ. Directed expression of halophilic and acidophilic β-glucosidases by introducing homologous constitutive expression cassettes in marine Aspergillus niger. Journal of Biotechnology, 2019; 292: 12-22.
• Cai LN, Lu T, Lin DQ, Yao SJ. Discovery of extremophilic cellobiohydrolases from marine Aspergillus niger with computational analysis. Process Biochemistry, 2022; 115: 118-127.
• Eriksson KEL. Concluding remarks: Where do we stand and where are we going?: Lignin biodegradation and practical utilization. Journal of Biotechnology, 1993; 30(1): 149-158.
• Raghukumar C, Muraleedharan U, Gaud VR, Mishra R. Xylanases of marine fungi of potential use for biobleaching of paper pulp. Journal of Industrial Microbiology and Biotechnology, 2004; 31(9): 433-441
• Devi S, Kulshreshtha A, Rai AK, Azmi W. Bench-scale production of L-asparaginase from Erwinia carotovora in a laboratory fermenter. Int. J. Life Sci. Pharm. Res., 2012; 3: 25-35.
• Duval M, Suciu S, Ferster A, Rialland X, Nelken B, Lutz P, Philippe N. Comparison of Escherichia coli–asparaginase with Erwinia-asparaginase in the treatment of childhood lymphoid malignancies: results of a randomized European Organisation for Research and Treatment of Cancer—Children's Leukemia Group phase 3 trial. Blood, The Journal of the American Society of Hematology, 2002; 99(8): 2734-2739.
• Pieters R, Hunger SP, Boos J, Rizzari C, Silverman L, Baruchel A, Pui CH. L‐asparaginase treatment in acute lymphoblastic leukemia: a focus on Erwinia asparaginase. Cancer, 2011; 117(2): 238-249.
• Vala AK, Dave BP. Explorations on marine-derived fungi for L-Asparaginase–enzyme with anticancer potentials. Current Chemical Biology, 2015; 9(1): 66-69.
• Vala AK, Dudhagara DR, Dave BP. Process‐centric and data‐centric strategies for enhanced production of l‐asparaginase—an anticancer enzyme, using marine‐derived Aspergillus niger. Journal of Chemometrics, 2018; 32(7): e3024.
• Vala AK, Dudhagara D, Dave BP. Enhanced L-asparaginase production by a marine-derived euryhaline Aspergillus niger strain AKV MKBU–a statistical model, 2018.
• Vala AK, Sachaniya B, Dudhagara D, Panseriya HZ, Gosai H, Rawal R, Dave BP. Characterization of L-asparaginase from marine-derived Aspergillus niger AKV-MKBU, its antiproliferative activity and bench scale production using industrial waste. International Journal of Biological Macromolecules, 2018; 108: 41-46.