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Sains Malaysiana 51(11)(2022): 3689-3702
http://doi.org/10.17576/jsm-2022-5111-14
Sintesis dan Pencirian Kompleks Fenolbenzimidazol dan Kajian Interaksi terhadap CT-DNA
(Synthesis and Characterization of Phenolbenzimidazole Complexes and Interaction Studies with
CT-DNA)
NOR FALAHIAH ISMAIL, NUR AQILAH ZAHIRAH NORAZMI & NURUL HUDA ABD
KARIM*
Department of Chemical Sciences, Faculty of Science
and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor Darul Ehsan, Malaysia
Received:
30 March 2022/Accepted: 12 July 2022
Abstrak
Kompleks fenolbenzimidazol berjaya disintesis dan dicirikan menggunakan spektroskopi resonans magnet nukleus (RMN), spektroskopi inframerah transformasi Fourier (FTIR), penentuan julat takat lebur, analisis ultralembayung-boleh nampak (UL-BN), analisis unsur (CHNS), kerentanan magnet dan Kristalografi Sinar-X. Mod pengikatan interaksi antara kompleks fenolbenzimidazol dengan DNA timus anak lembu (CT-DNA) dikaji dengan kaedah pentitratan DNA menggunakan serapan elektronik UL-BN
dan kajian nisbah kepekatan DNA menggunakan analisis pendarfluor. Berdasarkan spektrum UL-BN, anjakan hipokromism dan batokromism diperhatikan apabila kompleks fenolbenzimidazol dititratkan dengan CT-DNA dan menunjukkan pembentukan kompleks baru. Kompleks fenolbenzimidazol berinteraksi dengan CT-DNA secara pengikatan interkalasi dengan pemalar pengikatan, Kb (1.68 ± 1.4) × 105 - (1.02 ± 0.1) × 107 M-1. Kajian pendarfluor dijalankan untuk memerhati sifat optik kompleks fenolbenzimidazol terhadap CT-DNA. Keputusan kajian ini sangat bernilai dan berpotensi dalam menjadikan kompleks fenolbenzimidazol sebagai prob
DNA sensor optik.
Kata kunci: DNA timus; interkalasi; kompleks fenolbenzimidazol
Abstract
Phenolbenzimidazole complexes were successfully synthesized,
and characterizations were carried out using Nuclear Magnetic Resonance
Spectroscopy (NMR), Infrared Spectroscopy (FTIR), melting point range determination,
ultraviolet-visible (UV-Vis) analysis, elemental analysis CHNS, magnetic
susceptibility and X-ray crystallography. The binding modes of interaction between phenolbenzimidazole complexes and calf thymus (CT-DNA) were determined by UV-Vis titration and
fluorescence using distinct ratios. Based on UV-Vis spectra, hypochromism and bathochromism (red-shift) were observed upon titration of the complexes with CT-DNA which
suggested formation of new complexes. Phenolbenzimidazole complexes interact with CT-DNA by intercalation binding mode with the binding
constant, Kb (1.68 ± 1.4) × 105 - (1.02 ± 0.1) × 107 M-1. Fluorescence study was performed to
observe the optical properties of phenolbenzimidazole complexes against CT-DNA. These findings will be valuable for the potential use
of phenolbenzimidazole complex as a probe in optical
sensor DNA.
Keywords: Intercalation; phenolbenzimidazole complexes; thymus DNA
REFERENCES
Aida Mastura, B.M.Y. & Nurul Huda, A.K. 2014. Interaction of
Bis-Zn(II) salphen complex with calf thymus-DNA. AIP Conference Proceedings 1614: 386-392.
Al-Zaqri, N., Salih,
K.S.M., Awwadi, F.F., Alsalme, A., Alharthi, F.A., Alsyahi, A., Al Ali, A.,
Zarrouk, A., Aljohani, M., Chetouni, A. & Warad, I. 2020. Synthesis,
physicochemical, thermal, and XRD/HSA interactions of mixed
[Cu(Bipy)(Dipn)](X)2 complexes: DNA binding and molecular docking evaluation. Journal
of Coordination Chemistry 73(23): 3236-3248.
Arola-Arnal, A., Benet-Buchholz, J., Neidle, S. & Vilar, R. 2008.
Effects of metal coordination geometry on stabilization of human telomeric
quadruplex DNA by square-planar and square-pyramidal metal complexes. Inorganic
Chemistry 47(24): 11910-11919.
Campbell, N.H., Karim, N.H.A., Parkinson, G.N., Gunaratnam, M., Petrucci,
V., Todd, A.K., Vilar, R. & Neidle, S. 2012. Molecular basis of
structure-activity relationships between salphen metal complexes and human
telomeric DNA quadruplexes. Journal of Medicinal Chemistry 55(1):
209-222.
Chandrasekar, T., Arunadevi, A. & Raman, N. 2021. Synthesis, spectral
characterization, DNA-binding and antimicrobial profile of biological active
mixed ligand Schiff base metal(II) complexes incorporating
1,8-diaminonaphthalene. Journal of Coordination Chemistry 74(4-6):
804-822.
Dey, S., Sarkar, S., Paul, H., Zangrando, E. & Chattopadhyay, P. 2010.
Copper(II) complex with tridentate N donor ligand: Synthesis, crystal
structure, reactivity and DNA binding study. Polyhedron 29(6):
1583-1587.
Eda Yuhana, A., Lee, Y.H., Tan, L.L. & Nurul Huda, A.B. 2018. Sintesis
dan pencirian kompleks nikel ( II ) salfen dengan rantai sisi piperidina dan
kajian interaksi dengan DNA denggi. Sains Malaysiana 47(6): 1139-1146.
El-Sayed, Y.S., Gaber, M. & El-Nahass, M.N. 2021. Structural
elucidation, spectroscopic, and metalochromic studies of 2-(2-hydroxy
phenyl)-1-H–benzimidazole complexes: Metal ions sensing, DNA binding, and
antimicrobial activity evaluation. Journal of Molecular Structure 1229:
129809.
Faheem, M., Rathaur, A., Pandey, A., Kumar Singh, V. & Tiwari, A.K.
2020. A review on the modern synthetic approach of benzimidazole candidate. ChemistrySelect 5(13): 3981-3994.
Ghosh, K., Kumar, P., Tyagi, N., Singh, U.P., Aggarwal, V. & Baratto,
M.C. 2010. Synthesis and reactivity studies on new copper(II) complexes: DNA
binding, generation of phenoxyl radical, SOD and nuclease activities. European
Journal of Medicinal Chemistry 45(9): 3770-3779.
Kaushal, R., Thakur, S. & Nehra, K. 2016. ct-DNA binding and
antibacterial activity of octahedral titanium (IV) heteroleptic (benzoylacetone
and hydroxamic acids) complexes. International Journal of Medicinal
Chemistry 2016: 2361214.
Liu, H.K. & Sadler, P.J. 2011. Metal complexes as DNA intercalators. Accounts
of Chemical Research 44(5): 349-359.
Mahmood, K., Hashmi, W., Ismail, H., Mirza, B., Twamley, B., Akhter, Z.,
Rozas, I. & Baker, R.J. 2019. Synthesis, DNA binding and antibacterial
activity of metal(II) complexes of a benzimidazole Schiff base. Polyhedron 157: 326-334.
Mann, J., Baron, A., Opoku-Boahen, Y., Johansson, E., Parkinson, G.,
Kelland, L. & Neidle, S. 2001. A new class of symmetric
bisbenzimidazole-based DNA minor groove-binding agents showing antitumor
activity. Journal of Medicine 44(2): 138-144.
Mohd Sukri, S.A., Lee, Y.H. & Abd Karim, N.H. 2017. Synthesis,
characterization and DNA-binding studies of hydroxyl functionalized
platinum(II) salphen complexes. Journal of Fluorescence 27(3):
1009-1023.
Munawar, K.S., Ali, S., Tahir, M.N., Khalid, N., Abbas, Q., Qureshi, I.Z.,
Hussain, S. & Ashfaq, M. 2020. Synthesis, spectroscopic characterization,
X-ray crystal structure, antimicrobial, DNA-binding, alkaline phosphatase and
insulin-mimetic studies of oxidovanadium(IV) complexes of azomethine
precursors. Journal of Coordination Chemistry 73(16): 2275-2300.
Norhidayah, S., Lee, Y., Nurul Izzaty, H. & Nurul Huda, A. 2016.
Synthesis and characterization of 6,6’-Bis (2-Hydroxyphenyl)-2,2’-Bipyridyl
Ligand and its platinum complex for the interaction with Ct-DNA. Journal of
Analytical Sciences 20(1): 111-120.
Paul, K., Bindal, S. & Luxami, V. 2013. Synthesis of new conjugated
coumarin – Benzimidazole hybrids and their anticancer activity. Bioorganic
& Medicinal Chemistry 23(12): 3667-3672.
Roshatiara, S., Muhammad Ameerullah, S., Nur Hasyareeda, H. & Nurul
Huda, A. 2017. Interaction of n,n’-bis[4-[1-(2-hydroxyethoxy)]
salicylidene]-phenyldiamine-nickel(II) and copper(II) complexes with
G-quadruplex DNA. Malaysian Journal of Analytical Science 21(3):
544-551.
Sahudin, M.A., Su’ait, M.S., Tan, L.L., Lee, Y.H. & Abd Karim, N.H.
2019. Zinc(II) salphen complex-based fluorescence optical sensor for biogenic
amine detection. Analytical and Bioanalytical Chemistry 411(24):
6449-6461.
Shahabadi, N. & Mohammadi, S. 2012. Synthesis characterization and DNA
interaction studies of a new ZN(II) complex containing different dinitrogen
aromatic ligands. Bioinorganic Chemistry and Applications 2012: 571913.
Singla, P., Luxami, V. & Paul, K. 2014. Benzimidazole-biologically
attractive scaffold for protein kinase inhibitors. RSC Advances 4(24):
12422-12440.
Sirajuddin, M., Ali, S. & Badshah, A. 2013. Drug-DNA interactions and
their study by UV-Visible, fluorescence spectroscopies and cyclic voltametry. Journal
of Photochemistry and Photobiology B: Biology 124: 1-19.
Topala, T., Andreea, B., Oprean, L. & Oprean, R. 2014. Experimental
techniques employed in the study of metal complexes-DNA – Interactions. Farmacia 62(6): 1049-1061.
Veerasamy, R., Roy, A., Karunakaran, R. & Rajak, H. 2021.
Structure–activity relationship analysis of benzimidazoles as emerging
anti-inflammatory agents: An overview. Pharmaceuticals 14(7): 663.
Wu, H., Kou, F., Jia, F., Liu, B., Yuan, J. & Bai, Y. 2011. Synthesis
and characterization of the ligand based on benzimidazole and its copper
complex: DNA binding and antioxidant activity. Bioinorganic Chemistry and
Applications 2011: 105431.
Xu, H., Xu, Z.F., Yue, Z.Y., Yan, P.F., Wang, B., Jia, L.W., Li, G.M.,
Sun, W.B. & Zhang, J.W. 2008. A novel deep blue-emitting ZnII complex based
on carbazole-modified 2-(2-hydroxyphenyl)benzimidazole: Synthesis, bright
electroluminescence, and substitution effect on photoluminescent, thermal, and
electrochemical properties. Journal of Physical Chemistry C 112(39):
15517-15525.
*Corresponding author; email: nurulhuda@ukm.edu.my
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