Published date:Dec 20 2024

Journal Title: Advances in Applied Nano-Bio Technologies

Issue title: Advances in Applied Nano-Bio Technologies: Volume 5 Issue 4

Pages:1 - 25

DOI: 10.18502/aanbt.v5i4.17958

Hanieh BaneshiPerciaVista R&D Co. Shiraz

Nazanin JafariPerciaVista R&D Co. Shiraz

Sahar Almasi-TurkDepartment of Anatomy and Cellular Biology, Bushehr University of Medical Sciences, Bushehr

Nadiar Mussin MaratovichGeneral Surgery, West Kazakhstan Marat Ospanov Medical University, Aktobe

Amin Tamadonamintamaddon@yahoo.comPerciaVista R&D Co. Shiraz

Sponges, among the oldest animals on Earth, are well-known for their ability to produce a wide array of bioactive compounds with diverse biomedical applications. The Persian Gulf, characterized by its extreme temperatures and high salinity, is home to a rich diversity of sponge species that have been found to produce numerous secondary metabolites. This review aims to provide a comprehensive overview of the sponge species identified in the Persian Gulf and their bioactive compounds. Given the unique environmental conditions of the Persian Gulf, including its high salinity and temperature, which influence the production of bioactive compounds, this review focuses on cataloging the sponge species found in this region and their recognized bioactive compounds. A thorough search was conducted using Google Scholar to gather data on the pharmacological properties of these compounds. The findings reveal that bioactive compounds derived from The Persian Gulf sponges possess significant therapeutic and pharmaceutical potential, including antibacterial, antifungal, anticancer, anti-inflammatory, and antioxidant activities. Additionally, some sponge species have been identified as biomarkers and purgatives. This review highlights the critical role of environmental factors such as salinity and temperature in influencing the production and efficacy of these bioactive compounds. The biomedical potential of these compounds and their prospects for contributing to new drug discoveries are also discussed, emphasizing the significance of The Persian Gulf sponges as a source of novel biological products.

Keywords: Sponges, Bioactive Compounds, The Persian Gulf, Biomedical Applications

[1] Lindequist, U., Marine-Derived Pharmaceuticals - Challenges and Opportunities. Biomolecules & Therapeutics, 2016. 24(6): p. 561-571.

[2] Centella, M.H., et al., Marine-derived bioactive compounds for value-added applications in bio-and non-bio sectors. Journal of Cleaner Production, 2017. 168: p. 1559-1565.

[3] Hamayeli, H., M. Hassanshahian, and M. Askari Hesni, Identification of Bioactive Compounds and Evaluation of the Antimicrobial and Anti-biofilm Effect of Psammocinia sp. and Hyattella sp. Sponges from the Persian Gulf. Thalassas: An International Journal of Marine Sciences, 2020. 37(1): p. 357-366.

[4] Ogawara, H., Possible drugs for the treatment of bacterial infections in the future: anti-virulence drugs. J Antibiot (Tokyo), 2021. 74(1): p. 24-41.

[5] Razzaque, M.S., Implementation of antimicrobial stewardship to reduce antimicrobial drug resistance. Expert Rev Anti Infect Ther, 2021. 19(5): p. 559-562.

[6] Wu, L., et al., Marine Power on Cancer: Drugs, Lead Compounds, and Mechanisms. Mar Drugs, 2021. 19(9): p. 488.

[7] Antcliffe, J.B., The oldest compelling evidence for sponges is still early Cambrian in age–reply to Love and Summons (2015). Palaeontology, 2015. 58(6): p. 1137-1139.

[8] Li, F., M. Kelly, and D. Tasdemir, Chemistry, Chemotaxonomy and Biological Activity of the Latrunculid Sponges (Order Poecilosclerida, Family Latrunculiidae). Mar Drugs, 2021. 19(1): p. 27.

[9] Lee, Y.J., Y. Cho, and H.N.K. Tran, Secondary Metabolites from the Marine Sponges of the Genus Petrosia: A Literature Review of 43 Years of Research. Mar Drugs, 2021. 19(3): p. 122.

[10] Said, A.A.E., et al., Bioactive natural products from marine sponges belonging to family Hymedesmiidae. Rsc Advances, 2021. 11(27): p. 16179-16191.

[11] Monaco, R.R. and R.F. Quinlan, Novel natural product discovery from marine sponges and their obligate symbiotic organisms. Biorxiv, 2014: p. 005454.

[12] Leys, S.P. and A. Hill, The physiology and molecular biology of sponge tissues. Adv Mar Biol, 2012. 62: p. 1-56.

[13] El-Demerdash, A., et al., Chemistry and Biological Activities of the Marine Sponges of the Genera Mycale (Arenochalina), Biemna and Clathria. Mar Drugs, 2018. 16(6): p. 214.

[14] Bramhachari, P., H. Ehrlich, and R. Pallela, Introduction to the global scenario of marine sponge research. Marine Sponges: Chemicobiological and Biomedical Applications, 2016: p. 1-23.

[15] Wilson, K., et al., Terpene biosynthesis in marine sponge animals. Proc Natl Acad Sci U S A, 2023. 120(9): p. e2220934120.

[16] Ruocco, N., et al., Microbial diversity in Mediterranean sponges as revealed by metataxonomic analysis. Scientific Reports, 2021. 11(1): p. 21151.

[17] Thakur, N., et al., A review on pharmacological and pharmaceutical properties of Genus Stelletta from Marine Sponges. Materials Today: Proceedings, 2021: p. doi.org/10.1016/j.matpr.2021.04.375.

[18] Bergmann, W. and R.J. Feeney, The isolation of a new thymine pentoside from sponges1. Journal of the American Chemical Society, 1950. 72(6): p. 2809-2810.

[19] Hamoda, A.M., et al., Marine Sponge is a Promising Natural Source of Anti-SARS-CoV-2 Scaffold. Frontiers in Pharmacology, 2021. 12: p. 666664.

[20] Varijakzhan, D., et al., Bioactive Compounds from Marine Sponges: Fundamentals and Applications. Mar Drugs, 2021. 19(5): p. 246.

[21] He, Y., et al., A biodegradable antibacterial alginate/carboxymethyl chitosan/Kangfuxin sponges for promoting blood coagulation and full-thickness wound healing. Int J Biol Macromol, 2021. 167: p. 182-192.

[22] Wibowo, R.H., et al. Antifungal activity of bacteria associated Aplysina sp. Sponge collected from Enggano island, north Bengkulu, Indonesia against Candida albicans. in International Seminar on Promoting Local Resources for Sustainable Agriculture and Development (ISPLRSAD 2020). 2021. Atlantis Press.

[23] Presson, J., et al., Antimalarial activity of sea sponge extract of Stylissa massa originating from waters of Rote island. Jurnal Kimia Sains and Aplikasi, 2021. 24(4): p. 136-145.

[24] Casertano, M., et al., Evidence of Insulin-Sensitizing and Mimetic Activity of the Sesquiterpene Quinone Avarone, a Protein Tyrosine Phosphatase 1B and Aldose Reductase Dual Targeting Agent from the Marine Sponge Dysidea avara. Pharmaceutics, 2023. 15(2): p. 528.

[25] Uras, I.S. and B. Konuklugil, Anticancer secondary metabolites from marine sponges. Su Urunleri Dergisi, 2021. 38(1): p. 101-106.

[26] Esposito, R., et al., Sponges and Their Symbionts as a Source of Valuable Compounds in Cosmeceutical Field. Marine Drugs, 2021. 19(8): p. 444.

[27] Gandhimathi, R., et al., Production and characterization of lipopeptide biosurfactant by a sponge-associated marine actinomycetes Nocardiopsis alba MSA10. Bioprocess Biosyst Eng, 2009. 32(6): p. 825-35.

[28] Dhasayan, A., J. Selvin, and S. Kiran, Biosurfactant production from marine bacteria associated with sponge Callyspongia diffusa. 3 Biotech, 2015. 5(4): p. 443-454.

[29] Kiran, G.S., et al., Production of Glycolipid Biosurfactant from Sponge-Associated Marine Actinobacterium MSA21. Journal of Surfactants and Detergents, 2014. 17(3): p. 531-542.

[30] Pazooki, J. and M.S. Khakshoor, Evaluation of the anti-microbial properties of Gelliodes carnosa sponge alkaloid compounds antimicrobial properties of marine sponge. Int. J. of Aquatic Science, 2015. 6(1): p. 84-95.

[31] Mohanty, I., et al., Presence of Bromotyrosine Alkaloids in Marine Sponges Is Independent of Metabolomic and Microbiome Architectures. Msystems, 2021. 6(2): p. e01387-20.

[32] Sha, D., et al., Synthesis and antibacterial activities of quaternary ammonium salts with different alkyl chain lengths grafted on polyvinyl alcohol-formaldehyde sponges. Reactive & Functional Polymers, 2021. 158: p. 104797.

[33] Francis, P. and K. Chakraborty, Anti-inflammatory pregnane-type steroid derivatives clathroids A-B from the marine Microcionidae sponge Clathria (Thalysias) vulpina: Prospective duel inhibitors of pro-inflammatory cyclooxygenase-2 and 5-lipoxygenase. Steroids, 2021. 172: p. 108858.

[34] Lewis, E.L. and R.G. Perkin, Salinity - Its Definition and Calculation. Journal of Geophysical Research-Oceans, 1978. 83(Nc1): p. 466-478.

[35] Osinga, R., J. Tramper, and R.H. Wijffels, Cultivation of Marine Sponges. Mar Biotechnol (NY), 1999. 1(6): p. 509-532.

[36] Chennubhotla, V., et al., Seasonal changes in growth and alginic acid and mannitol contents in Sargassum ilicifolium (Tunner) J. Agardh and S. myriocystum J. Agardh. Indian Journal of Marine Sciences, 1982. 11: p. 195-196.

[37] Amsler, C.D., J.B. McClintock, and B.J. Baker, Secondary metabolites as mediators of trophic interactions among Antarctic marine organisms. American Zoologist, 2001. 41(1): p. 17-26.

[38] Bukhari, M., A. Thomas, and N. Wong, Culture conditions for optimal growth of Actinomycetes from marine sponges. Developments in Sustainable Chemical and Bioprocess Technology, 2013: p. 203-210.

[39] Coles, S.L. and P.L. Jokiel, Effects of salinity on coral reefs, in Pollution in tropical aquatic systems. 2018, CRC Press. p. 147-166.

[40] Miller, A.N., et al., Effects of heat and salinity stress on the sponge Cliona celata. International Journal of Biology, 2010. 2(2): p. 3-16.

[41] Fell, P.E., Salinity tolerance and desiccation resistance of the gemmules of the brackish-water sponge, Haliclona loosanoffi. Journal of Experimental Zoology, 1975. 194(2): p. 409-412.

[42] Belarbi el, H., et al., Producing drugs from marine sponges. Biotechnol Adv, 2003. 21(7): p. 585-98.

[43] Jones, A.M. and R. Berkelmans, Flood impacts in Keppel Bay, southern great barrier reef in the aftermath of cyclonic rainfall. PLoS One, 2014. 9(1): p. e84739.

[44] Macleod, R.A., The Question of the Existence of Specific Marine Bacteria. Bacteriol Rev, 1965. 29(1): p. 9-24.

[45] Bugni, T.S. and C.M. Ireland, Marine-derived fungi: a chemically and biologically diverse group of microorganisms. Nat Prod Rep, 2004. 21(1): p. 143-63.

[46] Olano, C., C. Mendez, and J.A. Salas, Antitumor compounds from marine actinomycetes. Mar Drugs, 2009. 7(2): p. 210-48.

[47] Bose, U., et al., LC-MS-based metabolomics study of marine bacterial secondary metabolite and antibiotic production in Salinispora arenicola. Mar Drugs, 2015. 13(1): p. 249-66.

[48] Cleary, D.F.R., A.R.M. Polonia, and N.J. de Voogd, Bacterial Communities Inhabiting the Sponge Biemna fortis, Sediment and Water in Marine Lakes and the Open Sea. Microb Ecol, 2018. 76(3): p. 610-624.

[49] Kim, T.K., M.J. Garson, and J.A. Fuerst, Marine actinomycetes related to the “Salinospora” group from the Great Barrier Reef sponge Pseudoceratina clavata. Environ Microbiol, 2005. 7(4): p. 509-18.

[50] Kiran, G.S., et al., Optimization and production of a biosurfactant from the sponge-associated marine fungus Aspergillus ustus MSF3. Colloids Surf B Biointerfaces, 2009. 73(2): p. 250-6.

[51] Krishnakumar, S., V.D.M. Bai, and J. Premkumar, Production of alpha amylase by salt - Tolerant Actinomycete sp-SBU3 isolated from marine sponge. Indian Journal of Geo-Marine Sciences, 2015. 44(4): p. 583-588.

[52] Han, Y., et al., Characterization of antifungal chitinase from marine Streptomyces sp. DA11 associated with South China Sea sponge Craniella australiensis. Mar Biotechnol (NY), 2009. 11(1): p. 132-40.

[53] Gal-Hemed, I., et al., Marine isolates of Trichoderma spp. as potential halotolerant agents of biological control for arid-zone agriculture. Applied and Environmental Microbiology, 2011. 77(15): p. 5100-5109.

[54] Batista-Garcia, R.A., et al., Characterization of lignocellulolytic activities from fungi isolated from the deep-sea sponge Stelletta normani. PLoS One, 2017. 12(3): p. e0173750.

[55] Kalkan, S.O., et al., Characterisation of a thermostable and proteolysis resistant phytase from MF82 associated with the marine sponge sp. Biocatalysis and Biotransformation, 2020. 38(6): p. 469-479.

[56] Liu, C., et al., Marine urease with higher thermostability, pH and salinity tolerance from marine sponge-derived Penicillium steckii S4-4. Mar Life Sci Technol, 2021. 3(1): p. 77-84.

[57] Venegas, R.M., J. Acevedo, and E.A. Treml, Three decades of ocean warming impacts on marine ecosystems: A review and perspective. Deep Sea Research Part II: Topical Studies in Oceanography, 2023. 212: p. 105318.

[58] Alosairi, Y., et al., World record extreme sea surface temperatures in the northwestern Arabian/Persian Gulf verified by in situ measurements. Marine Pollution Bulletin, 2020. 161: p. 111766.

[59] Varijakzhan, D., et al., Bioactive Compounds from Marine Sponges: Fundamentals and Applications. Mar Drugs, 2021. 19(5).

[60] González-Aravena, M., et al., Warm temperatures, cool sponges: the effect of increased temperatures on the Antarctic sponge Isodictya sp. PeerJ, 2019. 7: p. e8088.

[61] Vargas, S., L. Leiva, and G. Wörheide, Short-Term Exposure to High-Temperature Water Causes a Shift in the Microbiome of the Common Aquarium Sponge Lendenfeldia chondrodes. Microb Ecol, 2021. 81(1): p. 213-222.

[62] Brinkmann, C.M., A. Marker, and D.İ. Kurtböke An Overview on Marine Sponge-Symbiotic Bacteria as Unexhausted Sources for Natural Product Discovery. Diversity, 2017. 9, DOI: 10.3390/d9040040.

[63] Ibáñez, A., S. Garrido-Chamorro, and C. Barreiro, Microorganisms and Climate Change: A Not So Invisible Effect. Microbiology Research, 2023. 14(3): p. 918-947.

[64] Vanwonterghem, I. and N.S. Webster, Coral Reef Microorganisms in a Changing Climate. iScience, 2020. 23(4): p. 100972.

[65] Hosseini, H., et al., Marine health of the Arabian Gulf: Drivers of pollution and assessment approaches focusing on desalination activities. Marine Pollution Bulletin, 2021. 164: p. 112085.

[66] Keshavarzifard, M., A. Vazirzadeh, and M. Sharifinia, Implications of anthropogenic effects on the coastal environment of Northern Persian Gulf, using jinga shrimp (Metapenaeus affinis) as indicator. Marine Pollution Bulletin, 2020. 159: p. 111463.

[67] Ferrante, M., et al., In vivo exposure of the marine sponge Chondrilla nucula Schmidt, 1862 to cadmium (Cd), copper (Cu) and lead (Pb) and its potential use for bioremediation purposes. Chemosphere, 2018. 193: p. 1049-1057.

[68] Bayani, N., Ecology and environmental challenges of the Persian Gulf. Iranian Studies, 2016. 49(6): p. 1047-1063.

[69] Achlatis, M., et al., Photosynthesis by symbiotic sponges enhances their ability to erode calcium carbonate. Journal of Experimental Marine Biology and Ecology, 2019. 516: p. 140-149.

[70] Derakhshesh, N., et al., Estimatingthe effect of seasonal variation of environmental factors on biomass of sponges placed on artificial structuresofBahrakan coast(North-west of Persian Gulf). Marine Biology, 2012. 4(1): p. 41-50.

[71] Khoshkhoo, Z., Identification and Distribution of Sponges From Larak Island in Persian gulf. Journal of Animal Environment, 2017. 9(4): p. 363-370.

[72] Hassanzadeh, Y., N. Bahador, and M. Baseri Salehi, Isolation and Identification of symbiotic Vibrio alginolyticus from Persian Gulf sponges with API 20NE kit. Journal of Marine Biology, 2014. 6(3): p. 61-68.

[73] Eisapor, S. and S.H. Safaeian, Identification of sponges of inter tidal zone in North of Hengam. International Journal of Marine Science and Environment, 2013. 3(3): p. 141-148.

[74] Dedari, S. and N. Rabbani sagadi, Investigation of spongia (Class Demospongiae) application for absorption of chemical compounds from marine samples. Journal of Marine Science and Technology Research, 2015. 10(1): p. 73-82.

[75] Ghafourian, H., S. Javidi, and M. Rabani, Application of the new 92 GJ nanosorbent-Demospongiae Persian Gulf sponge for manganese ion separation. Journal of Marine Science and Technology Research, 2014. 9(1): p. 35-41.

[76] Kornprobst, J.-M., Sponges in Qatari waters A new source of marine natural products for biological applications. Qatar Univ Sci J, 1999. 19: p. 5-23.

[77] Heidary Jamebozorgi, F., et al., In vitro anti-proliferative activities of the sterols and fatty acids isolated from the Persian Gulf sponge; Axinella sinoxea. Daru, 2019. 27(1): p. 121-135.

[78] Loori, M., I. Sourinejad, and M. Nazemi, Identification and investigation of antibacterial effects of steroidal fraction from the marine sponge Axinella sinoxea Alvarez & Hooper, 2009 in Larak island, the Persian Gulf. Journal of Fisheries Science and Technology, 2021. 10(2): p. 164-172.

[79] Gozari, M., et al., Selective Isolation of the Persian Gulf Sponge-associated Actinobacteria and Evaluation of Cytotoxic and Antioxidant activity of Their Metabolites. Journal of Oceanography, 2020. 11(41): p. 39-48.

[80] Maghsoudlou, A., M. Shokri, and F. Momtazi, Taxonomy and Biogeography of the Persian Gulf Subtidal Sponges: An Estimate of α and β Diversity. Journal of Oceanography, 2014. 5(19): p. 79-89.

[81] Seradj, S.H., et al., Antimicrobial effects of some Persian Gulf marine sponges. Iranian South Medical Journal, 2020. 23(5): p. 494-504.

[82] Matroodi, S., et al., Genotyping-Guided Discovery of Persiamycin A From Sponge-Associated Halophilic Streptomonospora sp. PA3. Front Microbiol, 2020. 11: p. 1237.

[83] Eisapor, S.S., et al., Identification of sponges of off shore zone in North-West of Hengam Island, Persian Gulf. Journal of Marine Science and Technology Research, 2012. 6(4): p. 80-91.

[84] Genin, E., et al., New trends in phospholipid class composition of marine sponges. Comp Biochem Physiol B Biochem Mol Biol, 2008. 150(4): p. 427-31.

[85] Giraldes, B.W., et al., Two new sponge species (Demospongiae: Chalinidae and Suberitidae) isolated from hyperarid mangroves of Qatar with notes on their potential antibacterial bioactivity. PLoS One, 2020. 15(5): p. e0232205.

[86] Najafi, A., et al., First Molecular Identification of Symbiotic Archaea in a Sponge Collected from the Persian Gulf, Iran. Open Microbiol J, 2018. 12: p. 323-332.

[87] Ilkhani, M., et al., Identification species of Demospongiae sponge at Assaluyeh Persian Gulf. Marine Biology, 2020. 12(4): p. 1-10.

[88] Marami Zonouz, S., A. Ardalan Ashja, and M. Eidi, Differential identification of five marine sponges in the intertidal zone of Hormuz island (Persian Gulf) by the microstructure of the spicules. Iranian Journal of Biological Sciences, 2017. 11(1): p. 45-54.

[89] Kazempoor, S., A. Ashja Ardalan, and M. Eidi, Identification of sponges in tidal zone of Hormoz Island, Persian Gulf. Journal of Animal Environment, 2017. 9(1): p. 189-194.

[90] Derakhshesh, N., et al., Comparison productivity of class Desmospongiae (phylum Porifera) on Artificial Reefs (ARs) in Northwest Persian Gulf. Journal of Animal Environment, 2015. 7(3): p. 165-174.

[91] Najafi, A., M. Moradinasab, and I. Nabipour, First Record of Microbiomes of Sponges Collected From the Persian Gulf, Using Tag Pyrosequencing. Front Microbiol, 2018. 9: p. 1500.

[92] Gutekunst, V., et al., A new fistulose demosponge species from the Persian Gulf. Zootaxa, 2018. 4450(5): p. 565-574.

[93] Alidoost Salimi, M., et al., The presence of Clathria sp. on living coral colonies in Kish Island, Persian Gulf. Journal of Animal Environment, 2019. 11(4): p. 377-380.

[94] Kouchaksaraee, R.M., et al., Molecular Networking-Guided Isolation of New Etzionin-Type Diketopiperazine Hydroxamates from the Persian Gulf Sponge Cliona celata. Mar Drugs, 2021. 19(8).

[95] Jafari, M.A., J. Seyfabadi, and M.R. Shokri, Internal bioerosion in dead and live hard corals in intertidal zone of Hormuz Island (Persian Gulf). Mar Pollut Bull, 2016. 105(2): p. 586-92.

[96] Futterer, D.K., Significance of the boring sponge Cliona for the origin of fine grained material of carbonate sediments. Journal of Sedimentary Research, 1974. 44(1): p. 79-84.

[97] Ebadi, K., M. Zarei, and A.M. Sanati, Optimization of Crude Oil Biodegradation by Brevibacterium sp. Isolated from the Native Sponges of the Persian Gulf. Iran J Biotechnol, 2021. 19(2): p. e2690.

[98] Zarei, M., M. Jahedi, and F. Nozhat, Antibacterial activity of actinomycetes isolated from native sponge of Persian Gulf (Kharku Island) against pathogens. Journal of Aquatic Ecology, 2017. 7(1): p. 50-58.

[99] Ebadi, K. and A.M. Sanati, Biodegrading crude oil from the native sponges of the Persian Gulf Dictyonella sp. Journal of Oceanography, 2016. 7(27): p. 59-68.

[100] Aghvami, M., et al., Selective Cytotoxicity of alpha-Santonin from the Persian Gulf Sponge Dysidea Avara on Pediatric ALL B-lymphocytes via Mitochondrial Targeting. Asian Pac J Cancer Prev, 2018. 19(8): p. 2149-2154.

[101] Nazemi, M., et al., Cytotoxicity Activity and Druggability Studies of Sigmasterol Isolated from Marine Sponge Dysidea avara Against Oral Epithelial Cancer Cell (KB/C152) and T-Lymphocytic Leukemia Cell Line (Jurkat/ E6-1). Asian Pac J Cancer Prev, 2020. 21(4): p. 997-1003.

[102] Nazemi, M., et al., Extraction and identification of α-Santonin compound from sponge Dysidea avara and evaluation of its cytotoxic activity on carcinogenic cells. Iranian Scientific Fisheries Journal, 2019. 28(1): p. 39-47.

[103] Derakhshesh, N., et al., Histological Study of Reproduction Indices in Dysidea fragilis Species (phylum: Porifera). Journal of Oceanography, 2014. 4(16): p. 85-93.

[104] Nazemi, M., et al., Antimicrobial activities of semi polar-nonpolar and polar secondary metabolites of sponge from Hengam Island, Persian Gulf. Iranian Journal of Fisheries Sciences, 2017. 16(1): p. 200-209.

[105] Hamayeli, H., et al., Study the antimicrobial effect of three marine sponges (Dysidea sp.) collected at Persian Gulf on some pathogenic bacteria in planktonic and biofilm forms. Iranian Journal of Medical Microbiology, 2017. 11(4): p. 45-56.

[106] Khakshoor, M.S. and J. Pazooki, Antimicrobial activity of flavonoid compounds from marine sponge Gelliodes carnosa(Persian Gulf). Journal of Animal Environment, 2012. 4(3): p. 59-68.

[107] Njinkoue, J., et al. Phospholipid fatty acid composition of nine marine sponges from Qatar. in Marine lipids. Proceedings of the symposium held in Brest, France, 19-20 November 1998. 2000. IFREMER.

[108] Safaeian, S., et al., Antimicrobial activity of marine sponge extracts of offshore zone from Nay Band Bay, Iran. Journal De Mycologie Medicale, 2009. 19(1): p. 11-16.

[109] Nazemi, M. and Y. Moradi, Marine sponges as drug in the treatment of microbial diseases. Human & Environment, 2016: p. -.

[110] Heidary Jamebozorgi, F., et al., Cytotoxic activity of hexane and dichloromethane parts of methanol extract of Ircinia mutans sponge on three human cancer cell lines. Iranian Scientific Fisheries Journal, 2018. 27(2): p. 105-114.

[111] Karimpoor, M., et al., Antibacterial and antioxidant potential of Haliclona caerulea extracts from Tidal Island Larak, Persian Gulf. Modares Journal of Biotechnology, 2018. 9(3): p. 347-353.

[112] Seydi, E., et al., Selective Toxicity of Persian Gulf Sea Cucumber (Holothuria parva) and Sponge (Haliclona oculata) Methanolic Extracts on Liver Mitochondria Isolated from an Animal Model of Hepatocellular Carcinoma. Hepat Mon, 2015. 15(12): p. e33073.

[113] Derakhshesh, N., et al., Biomass and production of the marine sponge family: haliclonidae (Haliclona simulans and Haliclona oculata) on artificial reefs in northwest of the Persian Gulf. Journal of Oceanography, 2013. 4(14): p. 77-84.

[114] Norouzi, E., et al., Bioaccumulation of copper, iron and zinc in marine sponges Haliclona sp. On the island of Qeshm and Lark. Journal of Environmental Science and Technology, 2016: p. -.

[115] Nazemi, M., et al., Antifungal and antibacterial activity of Haliclona sp. from the Persian Gulf, Iran. J Mycol Med, 2014. 24(3): p. 220-4.

[116] Nazemi, M., et al., Antibacterial activities of from Persian Gulf. Proceedings of 2010 International Conference on Biotechnology and Food Science (Icbfs 2010), 2010. 1(2): p. 46-50.

[117] Nazemi, M., Review of the cytotoxic activity (anticancer) of marine sponges. Utilization and Cultivation of Aquatics, 2016. 5(4): p. 71-80.

[118] Arast, Y. and J. Pourahmad, Selective toxicity of standardized extracts of persian gulf sponge (Ircinia mutans) on skin cells and mitochondria isolated from melanoma induced mouse. International Pharmacy Acta, 2019. 2(1): p. 2e5:1-12.

[119] Heidary Jamebozorgi, F., et al., Cytotoxic furanosesquiterpenoids and steroids from Ircinia mutans sponges. Pharm Biol, 2021. 59(1): p. 575-583.

[120] Nazemi, M., et al., Investigation of antifungal effect of secondary polar-non-polar metabolites of Ircinia mutans sponge in summer and winter in Kish Island, Persian Gulf.

[121] Salamat, N. and N. Derakhshesh, Histological study of two sponge species with and without spicules in class Demospongiae. Aquatics Physiology and Biotechnology, 2014. 1(2): p. 55-70.

[122] Nazemi, M., et al., Comparison of antibacterial activity in methanol extract of sea cucumber (Holothuria leucospilota) and sponge Niphates furcata from Hengam Island, Persian Gulf. Marine Biology, 2017. 8(4): p. 65-72.

[123] Ebadi, K., M. Zarei, and A.M. Sanati, Isolation and molecular identification of oil degrading bacteria associated with Pachychalina sp sponge. Journal of Marine Science and Technology, 2019. 17(4): p. 22-35.

[124] Saveh Dorodi, M., Infestation of the pearl oysters by the boring and fouling organisms in the northern coast of Persian Gulf. Iranian Scientific Fisheries Journal, 1995. 4(1): p. 15-30.

[125] Nazemi, M., et al. First record on the distribution and abundance of three sponge species from Hormoz island, Persian Gulf-Iran. in Biological Forum. 2015. Research Trend.

[126] Sadeghi, P., et al., First record of sponge distribution in the Persian Gulf, (Hengam Island, Iran). Pak J Biol Sci, 2008. 11(21): p. 2521-4.

[127] Khakshoor, M.S. and J. Pazooki, Bactericidal and fungicidal activities of different crude extracts of (sponge, Persian Gulf). Iranian Journal of Fisheries Sciences, 2014. 13(3): p. 776-784.

[128] Nazemi, M., et al., Extraction, identification and biological activities (antibacterial, antifungal and cytotoxic) of terpenoid from sponge Dysidea spp. in Hengam Island, Persian gulf for antibiotic and anticancer drugs. 2018, Iranian Fisheries Science Research Institute.

[129] Nazemi, M., et al., Comparison of antibacterial activities of extracts in two different seasons from Kish Island, Persian Gulf, Iran. Iranian Journal of Fisheries Sciences, 2014. 13(4): p. 823-833.

[130] Nazemi, M., et al., Investigation of antibacterial activities of sponge Axinella sinoxea’s extracts from Larak Island, Persian Gulf. Journal of Aquatic Ecology, 2012. 1(4): p. 65-54.

[131] El-Hawary, S.S., et al., Bioactive Brominated Oxindole Alkaloids from the Red Sea Sponge Callyspongia siphonella. Mar Drugs, 2019. 17(8): p. 465.

[132] Kouchaksaraee, R.M., et al., Molecular Networking-Guided Isolation of New Etzionin-Type Diketopiperazine Hydroxamates from the Persian Gulf Sponge Cliona celata. Mar Drugs, 2021. 19(8): p. 439.

[133] Andersen, R.J., Tetracetyl clionamide, a 6-bromotryptophan derivative from the sponge Cliona celata. Tetrahedron Letters, 1978. 19(29): p. 2541-2544.

[134] Nazemi, M., Extraction and characterization of phytol fraction from marine sponge Dysidea avara and evaluation of antimicrobial and cytotoxic activities. Journal of Oceanography, 2022. 12(48): p. 129-140.

[135] Pejin, B., et al., Further Evaluation of Antimicrobial Activity of the Marine Sesquiterpene Hydroquinone Avarol. Current Pharmaceutical Biotechnology, 2014. 15(6): p. 583-588.

[136] Nasiri, N., M.R. Taherizadeh, and M. Gozari, Investigating the Antimicrobial Activity of Bacteria associated with the Marine sponge Haliclona sp. collected from the Persian Gulf. Journal of Marine Medicine, 2022. 4(4): p. 215-222.

[137] Zarei, M. and M. Jahedi, Determination of antifungal activity of Staphylococcus haemolyticus and Bacillus sp. Isolated from native sponge of Persian Gulf. Journal of Animal Environment, 2018. 10(4): p. 559-566.

[138] Jassbi, A.R., Biological active natural products from marine organisms and terrestrial plants of Iran. Planta Medica, 2016. 82(S 01): p. P548.

[139] Gozari, M., et al., An “olivomycin A” derivative from a sponge-associated Streptomyces sp. strain SP 85. 3 Biotech, 2019. 9(12): p. 439.

[140] Mahdian, D., et al., Cytotoxicity evaluation of extracts and fractions of five marine sponges from the Persian Gulf and HPLC fingerprint analysis of cytotoxic extracts. Asian Pacific Journal of Tropical Biomedicine, 2015. 5(11): p. 896-901.

[141] Nazemi, M., et al., Cytotoxic activity of natural components soluble in methanol and diethyl ether of Dysidea pallescens from Hengam Island, Persian Gulf. Iranian Scientific Fisheries Journal, 2016. 24(4): p. 1-8.

[142] Pejin, B., et al., In vitro evaluation of cytotoxic and mutagenic activity of avarol. Nat Prod Res, 2016. 30(11): p. 1293-6.

[143] Imperatore, C., et al., Investigating the Antiparasitic Potential of the Marine Sesquiterpene Avarone, Its Reduced form Avarol, and the Novel Semisynthetic Thiazinoquinone Analogue Thiazoavarone. Mar Drugs, 2020. 18(2): p. 112.

[144] Heidary Jamebozorgi, F., et al., Cytotoxic activity of hexane and dichloromethane parts of methanol extract of Ircinia mutans sponge on three human cancer cell lines. Iranian Scientific Fisheries Journal, 2018. 27(2): p. 105-114.

[145] Golfakhrabadi, F., et al., Isolation, identification, and HPTLC quantification of dehydrodeoxycholic acid from Persian Gulf sponges. J Pharm Biomed Anal, 2021. 197: p. 113962.

[146] Khaledi, M., et al., Chemical profiling and anti-psoriatic activity of marine sponge (Dysidea avara) in induced imiquimod-psoriasis-skin model. PLoS One, 2020. 15(11): p. e0241582.

[147] Bary, K., B. Elamraoui, and T. Bamhaoud, Chemical characterization of Cliona viridis: Sponge of Atlantic Moroccan Coast. Int. J. Innov. Sci. Res, 2016. 26: p. 14-22.

[148] Seradj, H., et al., Antioxidant activity of six marine sponges collected from the Persian Gulf. Iranian Journal of Pharmaceutical Sciences, 2012. 8(4): p. 249-255.

[149] Hosseini, E.K., H. Ghafourian, and M. Rabbani, Selective Separation of Lead Ions Using New Nano-Adsorbent GH-92. International Journal of Computational and Theoretical Chemistry, 2018. 6(1): p. 14.

[150] Ghafourian, H., E. Khodadad Hosseini, and M. Rabbani, A Novel GH-92 Nano-Adsorbent Using the Sponge from the Persian Gulf for Lead and Cadmium Removal. Journal of Water and Wastewater; Ab va Fazilab ( in persian ), 2015. 26(2): p. 2-12.

[151] Dehdari, S., M. Rabani, and N. Sadjadi, Investigation of spongia(Class Demospongiae) application for absorption of chemical compounds from marine samples. Journal of Marine Science and Technology Research, 2015. 10(1): p. 73-82.

[152] Norouzi, E., et al., Bioaccumulation of copper, iron and zinc in marine sponges Haliclona sp. on the island of Qeshm and Lark. Journal of Environmental Science and Technology, 2017. 19(5): p. 497-506.