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Type :article
Subject :Q Science (General)
Main Author :Yuhanis Mhd Bakri
Additional Authors :Ahmed Kareem Obaid Aldulaimi
Saripah Salbiah Syed Abdul Azziz
Mohd Azlan Nafiah
Saadon Abdulla Aowda
Muhammad Hazim
Khalijah Awang
Yumi Zuhanis Has-Yun Hashim
Phirdaous Abbas
Title :Cytotoxic and Xanthine Oxidase Inhibitory Activities of Chemical Constituents of Alphonsea cylindrica King
Place of Production :Tanjong Malim
Publisher :Fakulti Sains dan Matematik
Year of Publication :2019
Corporate Name :Universiti Pendidikan Sultan Idris

Abstract : Universiti Pendidikan Sultan Idris
This study aimed to investigate the chemical constituents from Alphonsea cylindrica as well as their cytotoxic and xanthine oxidase inhibitory activities. The chemical compounds were isolated and purified by various chromatographic techniques and their structures were elucidated via modern spectroscopic techniques including NMR, MS, IR, UV and comparison with literature. A study on the barks of A. cylindrica has found eleven known compounds were identified as stigmasterol (1), isoursuline (2), cyathocaline (3), kinabaline (4), muniranine (5), isooncodine (6), iraqiine (7), O-methylmoschatoline (8), kareemine (9), atherospermidine (10) and N-methylouregidione (11). The cytotoxic effect of hexane, DCM and methanol of bark of A. cylindrica as well as the isolated compounds; 1, 2, 3, 4, 5, 7, 8, 9 and 10 were estimated on MCF-7 human breast cancer cells and isoursuline possessed the most potent inhibitory activity with IC50 value of 33 µg/ml. Eight compounds 1, 3, 4, 5, 6, 8, 10 and 11 displayed moderate inhibitory activity effect with IC50 < 100 μM against xanthine oxidase. As a conclusion, eleven compounds have been isolated from the bark of A. cylindrica King. Some of the compounds also showed potential against cytotoxicity and xanthine oxidase inhibitory activities. The findings of this study can enhance the understanding of the chemotaxonomy aspect of the A. cylindrica as well as its potential in traditional and modern medicine.

References

1. Pezzuto, J. M. (1997). Plant-derived anticancer agents. Biochemical Pharmacology, 53(2), 121–133.

2. Shoemaker, R. H. (2006). The NCI60 human tumour cell line anticancer drug screen. Nature Rev., 6(10), 813–823.

3. Tang, Y., Long, J., and Liu, J. (2014). HyperglycemiaAssociated Oxidative Stress Induces Autophagy: Involvement of the ROS-ERK/JNK-p53 Pathway. Autophagy: Cancer, Other Pathologies, Inflammation, Immunity, Infection, and Aging.Elsevier Inc. 1, 105-115.

[4] Dogan, O., Cubukcu, H. C., Durak, Z. E., Kocaoglu, H., and Durak, İ. Biomedical Research (India), (2017). 28(13), 6080–6084.

4. Lopes, J. C., Chatrou, L. W., Mello-Silva, R., Rudall, P. J., and Sajo, M. G. (2018). Phylogenomics and evolution of floral traits in the Neotropical tribe Malmeeae (Annonaceae). Molecular Phylogenetics and Evolution, 118(8), 379–391.

5. Srivastava, G., and Mehrotra, R. C. (2013). First Fossil Record of Alphonsea Hk. f. and T. (Annonaceae) from the Late Oligocene Sediments of Assam, India and Comments on Its Phytogeography. Plos One, 8(1), 1–6.

6. Bosso, T. (2001). Weedy Plants of Ayer Hitam Forest Reserve, Selangor. Pertanika Journal of Tropical Agricultural Science. 24 (3) 1

7. Burkill, I. H. (1935). A Dictionary of the Economic Product of the Malaya Peninsula London: Published on behalf of the governments of the Straits settlements and Federated Malay states by the Crown agents for the colonies. volum II (1-2).

8. Dsd, S. J., Amgoth, C., S, S. N., Ch, P., Madhavi, J., and A, K. S. (2018). Antioxidant and anticancer activities of an Aporphine alkaloid isolated from Alphonsea sclerocarpa. Journal of Phytopharmacology, 7(1), 51–55.

9. Doddapaneni, S.J.D.S., Amgoth, C., Kalle, A.M., Suryadevara, S.N., Alapati, K.S., 2018. Antimicrobial and anticancer activity of AgNPs coated with Alphonsea sclerocarpa extract. 3 Biotech 8 (3), 1–9.

10. Talip, M. A., Azziz, Saripah S. S. A., Wong, C. F., Awang, K., Naz, H., Bakri, Y. M., Litaudon, M., 2017. New Azafluorenone derivative and antibacterial activities of Alphonsea cylindrica barks. Nat. Prod. Sci. 23 (3), 151–156.

11. Ahmed Kareem Obaid Aldulaimi, Saripah S. S. A., Yuhanis M. B., Mohd A. N., Saadon A. A., Khalijah A., Marc L. (2019). Two New isoquinoline alkaloids from the bark of Alphonsea cylindrica King and their antioxidant activity. Phytochemistry Letters, 29 (2019) 110–114.

12. Ahmed K. O., Azziz S. S. S.. Bakri Y. M., Nafiah M. A., Awang K., Saadon A. A., Hassan N. M., Has-Yun Y. Z., Abdullah F. (2018). Antioxidative and cytotoxic activities of crude and isolated compounds of P. Lateriflora (bl.) King. Journal of Pharmaceutical Sciences and Research, (2018). 10(11), 2718-2721.

13. Khan, A., Tak, H., Nazir, R., and Lone, B. A. (2015). Flora of Kashmir with Antimicrobial Activity-A Review. International Journal of Medical Microbiology and Tropical Diseases 1(1), 30–33.

14. Mayan, K., Samarakoon, S. R., and Tennekoon, K. H. (2016). Evaluation of Selected Natural Compounds for Cancer Stem Cells Targeted Anti-cancer Activity : A Molecular Docking Study. European Journal of Medicinal Plants 15(4), 1–21.

15. Yoshida, N. C., De Siqueira, J. M., Rodrigues, R. P., Correia, R. P., and Garcez, W. S. (2013). An azafluorenone alkaloid and a megastigmane from unonopsis lindmanii (annonaceae). Journal of the Brazilian Chemical Society, 24(4), 529–533.

16. Yang-Chang, W., and Chang-Yih, D. (1990). Two new natural azafluorene alkaloids and a cytotoxic apophine alkaloid from Polialthia longifolia. Journal of Natural Products, 53(5), 1327–1331.

17. Aldulaimi A. K. O., S. S. S. A. Azziz, Y. M. Bakri, M. A. Nafiah, K. Awang, S. A. Aowda, M. Litaudon, N. M. Hassan, H. Naz, P. Abbas, Y. Z. H. Hashim, A. A. Majhool. (2018). Alkaloids from Alphonsea Elliptica Barks and Their Biological Activities Journal of Global Pharma Technology, (2018)10(08):270-275.

18. Iio, M., Moriyama, A., Matsumoto, Y., Takaki, N., and Fukumoto, M. (1985). Inhibition of xanthine oxidase by  flavonoids. Agricultural and Biological Chemistry, 49(7), 2173– 2176.

19. Van Hoorn, D. E. C., Nijveldt, R. J., Van Leeuwen, P. A. M., Hofman, Z., M’Rabet, L., De Bont, D. B. A., and Van Norren, K. (2002). Accurate prediction of xanthine oxidase inhibition based on the structure of flavonoids. European Journal of Pharmacology, 451(2), 111–118.

 


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