THE POTENCY OF ANTITUBERCULOSIS ACTIVITY OF SECONDARY METABOLITES FROM GARUGA FLORIBUNDA AND ITS DERIVATIVES USING THE IN SILICO METHOD, ALONG WITH ITS ISOLATION AND TRANSFORMATION
Tuberculosis (TB) is a disease caused by the Mycobacterium tuberculosis (MTB) with high cases of drug resistance in patients (MDR/Multi Drug Resistant). TB treatment using isoniazid is considered less effective due to the presence of KatG mutation as an isoniazid activating catalyst on the InhA....
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/67532 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Tuberculosis (TB) is a disease caused by the Mycobacterium tuberculosis (MTB) with
high cases of drug resistance in patients (MDR/Multi Drug Resistant). TB treatment
using isoniazid is considered less effective due to the presence of KatG mutation as
an isoniazid activating catalyst on the InhA. Therefore, there is an urge to find
alternative drugs, such as from plants, that directly inhibit InhA without the activation
of KatG catalyst. One of the plant genus that has been widely used as a medicine for
asthma and lung infections is Garuga. The main secondary metabolite from this genus,
i.e. a cyclic diarylheptanoid, has been reported to have antibacterial activity. One
species of Garuga growing in Indonesia is G. floribunda. A previous study on the
heartwood of G. floribunda identified the presence of two cyclic diarylheptanoid
compounds, namely alnusdiol and alnuson. Moreover, the prenylation of alnusdiol
produced monoprenylated (AHS-1) has also been reported. In this research, the
potency study of the inhibition ability of the cyclic diarylheptanoid and its
transformation products towards InhA have been carried out using the in silico method.
Those cyclic diarylheptanoids included alnusdiol, alnuson, AHS-1, and the product of
transformation simulation of phenolic group on alnusdiol, i.e. allylation (AHS-2),
benzylation (AHS-3), and the reaction with triethylene glycol monomethylether
(ALN-1). In addition, the isolation of secondary metabolites of alnusdiol from Garuga
floribunda was carried out in several steps, including maceration of heart wood powder
with acetone solvent, fractionation of acetone extract and purification of the obtained
fractions using various chromatographic techniques ((Vacuum Liquid
Chromatography (VLC) and Gravity Column Chromatography (GCC)). Subsequently,
the alnusdiol derivative with the best potential activity was also synthesized. The
structure of the isolated compound and the alnusdiol derivative was characterized
using NMR spectroscopy data. The results of the in silico study showed that the
monobenzylation alnusdiol (AHS-3) product had the best inhibition potential with a
docking score of ?9.9 kcal/mol. Hydrogen bonding and hydrophobic interactions that
stabilize the complex between AHS-3 with InhA, in addition to the interaction of key
residues on Tyr158. Moreover, the isolation of secondary metabolite from heart wood
of Garuga floribunda yielded alnusdiol as the main product with mass of 104.1 mg
(percent yield of 1.69 ×10-2%). The benzylation reaction of alnusdiol that was carried
by reflux at 56 oC, produced alnusdiol monobenzylation (AHS-3) yield of 66,1%. The
determination of the structure of the isolated compound and the transformed
compound was carried out based on 1D-NMR spectroscopic data (1H-NMR and 13CNMR)
showed that the isolated compound, i.e. alnusdiol, has been obtained and the
benzylation reaction has occurred only in one phenolic group of alnusdiol. |
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