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The antibacterial and antifungal potential of marine natural ingredients from the symbiont bacteria of mangrove

Publish place: Global Journal of Environmental Science and Management، Vol: 9، Issue: 4
Publish Year: 1402
نوع سند: مقاله ژورنالی
زبان: English
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لینک ثابت به این Paper:
https://civilica.com/doc/1645602

شناسه ملی سند علمی:

JR_GJESM-9-4_011

تاریخ نمایه سازی: 16 اردیبهشت 1402

Abstract:

BACKGROUND AND OBJECTIVES: Mangroves are known to contain tannins, flavonoids, and quinones, which have the potential to be antibacterial, effective even against multidrug-resistant bacteria. Mangroves also have antifungal and antiviral properties. Although, mangroves are known for their use as medicinal ingredients, information regarding symbiont bacteria’s antibacterial and antifungal potential is still scarce. Therefore, this study aimed to examine symbiont bacteria in the fruit and leaves of Xylocarpus granatum as additional raw materials for anti-acne cosmetic creams and moisturisers.METHODS: Symbiont bacteria were isolated using the pour plate method through Zobell ۲۲۱۶E and incubated for ۲ x ۲۴ hours at ۲۷.۵ Celcius degree. Afterwards, ۱۳ isolates were successfully isolated and characterised based on their morphology. Further, everal tests were conducted, including the antibacterial test, antifungal test, molecular identification, and gas chromatography-mass spectrometry. The pathogenic bacteria used in the antibacterial test were Staphylococcus aureus, Vibrio harveyi, and Vibrio alginolyticusFINDINGS: The antibacterial test results showed that eight isolates were capable of producing an inhibition zone against S. aureus, seven isolates were positive for antibacterial activity against Vibrio harveyi, and ۱۰ isolates were positive for antibacterial activity against Vibrio alginolyticus. The pathogenic fungi used in the antifungal test were Malassezia furfur and Candida albicans. The antifungal test results demonstrated that six isolates could produce inhibition zones against Malassezia furfur and Candida albicans. Furthermore, molecular identification was carried out on six potential isolates based on the antibacterial and antifungal tests, which were X۲.۵۲, X۱.۶۵, X۱.۶۴, X۱.۵۳, X۱.۵۴, and X۱.۶۳. The molecular identification results revealed the occurrence of four species in the Xylocarpus granatum mangroves, namely, Sinomicrobium oceani, Proteus mirabilis, Pseudomonas khazarica, and Alcaligenes aquatilis.CONCLUSION: The study found that the mangrove symbiont bacteria had antibacterial and antifungal potential. The compound with the highest concentration in six isolates was ۹-octadecenoic acid, methyl ester. This type of content has antibacterial potential and is also predicted to have antifungal potential.

Keywords:

Bacteria , cosmetic , GC-MS , fungi , Pathogenic

Authors

D. Pringgenies

Department of Marine Science, Faculty of Fisheries and Marine Science, Diponegoro University, Jl. Prof. H. Soedarto, S.H., Tembalang, Semarang, Central Java, ۵۰۲۷۵, Indonesia

W. Ari Setyati

Department of Marine Science, Faculty of Fisheries and Marine Science, Diponegoro University, Jl. Prof. H. Soedarto, S.H., Tembalang, Semarang, Central Java, ۵۰۲۷۵, Indonesia

F. Feliatra

Faculty of Fisheries and Marine Sciences, Riau University, Pekanbaru, Indonesia

D. Ariyanto

Research Center for Oceanography, National Research and Innovation Agency (BRIN), Ancol, Jakarta, Indonesia

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  • Amani, A.M., (۲۰۱۴). Synthesis, characterization and antibacterial and antifungal evaluation ...
  • Ariyanto, D.; Bengen, D.G.; Prartono, T.; Wardiatno, Y., (۲۰۱۸). Short ...
  • Ariyanto, D.; Gunawan, H.; Puspitasari, D.; Ningsih. S.S; Jayanegara, A.; ...
  • Anggelina, A.C.; Pringgenies, D.; Setyati, W.A., (۲۰۲۱). Presence of biosynthetic ...
  • Balaraman, P.; Balasubramanian, B.; Liu, W.C.; Kaliannan, D.; Durai, M.; ...
  • Balouiri, M.; Sadiki, M.; Ibnsouda, S.K., (۲۰۱۶). Methods for in vitro evaluating ...
  • Cogen, A.L.; Nizet, V.; Gallo, R.L., (۲۰۰۸). Skin microbiota: a ...
  • Chen, L.W.; Chung, H.L.; Wang, C.C.; Su, J.H.; Chen, Y.J.; ...
  • Chiller, K.; Selkin, B.A.; Murakawa, G.J., (۲۰۰۱). Skin microflora and ...
  • Cowen, L.E.; Sanglard, D.; Howard, S.J.; Rogers, D; Perlin, D.S., ...
  • Cushnie, T.P.; Lamb, A.J., (۲۰۰۵). Antimicrobial activity of flavonoids. Int ...
  • Darmadi, J.; Batubara, R.R.; Himawan, S.; Azizah, N.N.; Audah, H.K.; ...
  • Das, S.K.; Prusty, A.; Samantaray, D.; Hasan, M.; Jena, S.; ...
  • Dey, D.; Quispe, C.; Hossain, R.; Jain, D.; Ahmed Khan, ...
  • De La Hoz-Romo, M.C.; Díaz, L.; Villamil, L., (۲۰۲۲). Marine ...
  • Ding, J.; Wu, B.; Chen, L., (۲۰۲۲). Application of marine ...
  • Durán, R.E., Bárbara F.S.S.; Méndez. V., Jaén-Luchoro, D.; Moore, E.R.B.; ...
  • Eswaraiah, G.; Peele K.A.; Krupanidhi, S.; Kumar, R.B.; Venkateswarulu T.C., ...
  • Fox, A., (۱۹۹۹). Carbohydrate profiling of bacteria by gas chromatography–mass ...
  • Guimarães, A.; Venâncio, A., (۲۰۲۲). The Potential of Fatty Acids ...
  • Hossain, C.M.; Ryan, L.K.; Gera, M.; Choudhuri, S.; Lyle, N.; ...
  • Hsouna, A.B.; Alayed, A.S., ( ۲۰۱۲). Gas chromatography-mass spectrometry (GC-MS) ...
  • Jangjou, A.; Zareshahrabadi, Z.; Abbasi, M.; Talaiekhozani, A.; Kamyab, H.; ...
  • Jegatheesan, A.; Sudhakar, M.P.; Poonam, C.; Perumal, K.; Arunkumar, K., ...
  • Kaczmarek, B., (۲۰۲۰). Tannic acid with antiviral and antibacterial activity ...
  • Kokoska, L.; Kloucek, P; Leuner, O.; Novy, P., (۲۰۱۹). Plant-derived products ...
  • Krishnamoorthy, K.; Subramaniam, P., (۲۰۱۴). Phytochemical profiling of leaf, stem, ...
  • Ningsih, S.S.; Puspitasari, D.; Ningsih. S.S; Jayanegara, A.; Hamim H.; ...
  • Park, H.J.; Jin, G.; Nakhleh, L., (۲۰۱۰). Bootstrap-based support of ...
  • Panico, A.; Serio, F.; Bagordo, F.; Grassi, T.; Idolo, A.; ...
  • Pringgenies, D.; Setyati, W.A.; Djunaedi, A.; Pramesti, R.; Rudiyanti S.; ...
  • Pringgenies, D.; Setyati, W.A., (۲۰۲۱). Antifungal strains and gene mapping ...
  • Qadri, H.; Shah, A.H.; Ahmad, S.S.; Almilaibary A.; Mir, M.A., ...
  • Rojas, F.D.; Sosa, M.D.L.A, Fernández, M.S.; Cattana, M.E., (۲۰۱۴). Antifungal ...
  • Revie, N.M.; Iyer, K.R.; Robbins, N.; Cowen, L.E., (۲۰۱۸). Antifungal ...
  • Simlai, A.; Rai, A.; Mishra, S.; Mukherjee, K.; Roy, A., ...
  • Setyati, W.A.; Pringgenies, D.; Soenardjo, N.; Pramesti, R., (۲۰۲۱) Actinomycetes ...
  • Tahir, N.A.; Qader, K.O.; Azeez, H.A.; Rashid, J.S., (۲۰۱۸). Inhibitory ...
  • Tam, K.; Torres V.J., (۲۰۱۹). Staphylococcus aureus secreted toxins and ...
  • Tarhriz, V.; Nouioui, I.; Spröer, C.; Verbarg, S.; Ebrahimi, V.; ...
  • Wasfi, R., Hamed, S.M., Amer M.A., Fahmy, L.I., (۲۰۲۰). Proteus ...
  • Xu, Y.; Tian, X.-P.; Liu, Y.-J.; Li, J.; Kim, C.-J.; ...
  • Yuan, F.; Yin, S.; Xu. Y.; Xiang, L.; Wang, H.; ...
  • Zahara, K.; Bibi, Y.; Arshad, M.; Kaukab, G.; Al, S.; ...
  • Zulaikha, R.; Sharifah, N.S.I., Praveena, S.M., (۲۰۱۵). Hazardous ingredients in ...
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