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Sains Malaysiana 48(5)(2019):
1019–1024 http://dx.doi.org/10.17576/jsm-2019-4805-10
The Potential Effect of Fatty Acids
from Pliek U on Epidermal
Fatty Acid Binding Protein: Chromatography and Bioinformatic
Studies (Potensi Kesan Asid Lemak
daripada Pliek
U pada Epidermis Asid Lemak Pengikat Protein: Kajian Kromatografi dan Bioinformatik) NANDA EARLIA1,
RAHMAD
RAHMAD2,
MOHAMAD
AMIN3,
CRS
PRAKOESWA4,
KHAIRAN
KHAIRAN5
& RINALDI IDROES2,5* 1Graduate School of
Mathematics and Applied Sciences, Universitas
Syiah Kuala, Banda Aceh, 23111, Indonesia 2Department of Chemistry,
Faculty Mathematics and Natural Sciences, Universitas
Syiah Kuala, Banda Aceh, 23111, Indonesia
3Department of Biology,
Faculty Mathematics and Natural Sciences, Universitas
Negeri Malang, Malang, 65145, Indonesia
4Faculty of Medicine,
Universitas Airlangga
- Dr Soetomo
General Academic Hospital, Surabaya, 60132, Indonesia 5Department of Pharmacy,
Faculty Mathematics and Natural Sciences, Universitas
Syiah Kuala, Banda Aceh, 23111, Indonesia Diserahkan: 15 Januari 2019/Diterima: 28 Mac 2019 ABSTRACT The fatty acid analysis in Pliek U and its bioinformatic studies had
been carried out and reported. Herein, fatty acids were analyzed
by gas chromatography-mass spectrometry (GC-MS), meanwhile their potential
effect, based on its interaction on epidermal fatty acid binding
protein (E-FABP), was studied by bioinformatics approach with reverse
docking technique using palmitic acid as a control compound. For
the stated purpose, two Pliek U
extracts were prepared, namely ethanolic
Pliek U extract (EPUE), and ethanolic of residue
hexane of Pliek U extract (ERHPUE).
The GC-MS results showed that lauric,
myristic, palmitic, and oleic acids
were predominant, followed by stearic, capric,
linoleic, and caprylic acids. Reverse docking results showed that linoleic
acid had the lowest binding affinity (-5.9 kcal/mol)
and was strongly bound to E-FABP on the same side of amino acid
GLN
A98, ARG
A81, TYR A22, and LYS A61.
These findings indicated that linoleic acid has a potential utility
as a drug candidate for atopic dermatitis treatment. Keywords: Atopic dermatitis;
bioinformatics; E-FABP; fatty acid; gas chromatography;
Pliek U ABSTRAK Analisis asid lemak pada
Pliek U dan kajian
bioinformatiknya telah
dijalankan dan dilaporkan. Di sini, asid lemak telah
dianalisis menggunakan
spektrometri gas kromatografi -
jisim (GC-MS), sementara
kesan potensinya
berdasarkan interaksi pada epidermis asid lemak pengikat protein (E-FABP),
dikaji menggunakan
kaedah bioinformatik dengan teknik dok
berbalik menggunakan
asid palmitik sebagai
sebatian kawalan.
Untuk maksud yang dinyatakan, dua ekstrak Pliek U telah disediakan; ekstrak etanolik Pliek U (EPUE) dan
ekstrak etanolik
sisa heksana Pliek U (ERHPUE). Keputusan
GC-MS
menunjukkan asid
laurik, miristik,
palmitik dan oleik
adalah pradominan,
diikuti oleh asid
stearik, caprik,
linoleik dan caprilik.
Keputusan dok
berbalik menunjukkan asid linoleik mempunyai
pengikat afiniti
terendah (-5.9 kcal/mol) dan terikat dengan
kuat kepada
E-FABP pada sisi yang sama dengan asid
amino GLN A98, ARG A81, TYR A22
dan LYS A61. Penemuan ini
menunjukkan asid linoleik mempunyai
potensi utiliti
sebagai calon dadah
untuk rawatan
dermatitis atopik. Kata kunci: Asid
lemak; dermatitis atopik;
bioinformatik; E-FABP; kromatografi gas; Pliek U RUJUKAN Arpi, Normalina. 2013.
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https://doi.org/10.1016/j.jaci.2014.06.014. *Pengarang untuk surat-menyurat; email: rinaldi.idroes@unsyiah.ac.id
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