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Sains Malaysiana 44(10)(2015): 1501–1510
Anticholesterol
Activity of Anacardium occidentale Linn. Does it Involve in Reverse Cholesterol Transport?
(Aktiviti
Antikolesterol Anacardium occidentale Linn: Adakah Pengangkutan
Kolesterol Berbalik Terlibat)
MOHD KAMAL NIK HASAN1*, IHSAN SAFWAN KAMARAZAMAN1, DARYL JESUS ARAPOC3, NUR
ZALIKHA MOHD TAZA1, ZULKHAIRI HJ. AMOM2, RASADAH MAT ALI1, MOHD SHAHIDAN MOHD ARSHAD1, ZAMREE MD SHAH1 & KHAIRUL KAMILAH ABDUL KADIR1
1Natural Products Division,
Forest Research Institute of Malaysia, 52109 Kepong, Selangor Darul Ehsan, Malaysia
2Department of Basic Sciences,
Faculty of Health Sciences, Universiti Teknologi MARA (UiTM)
43200 Puncak Alam, Selangor Darul
Ehsan, Malaysia
3Agensi Nuklear Malaysia,
43000 Bangi, Selangor Darul Ehsan, Malaysia
Received: 29 January
2015/Accepted: 4 June 2015
ABSTRACT
Anacardium occidentale belongs to
the Anacardiaceae family. It had been scientifically proven to have
anti-hypercholesterolemia effect in high cholesterol diet induced
animal laboratory study. However there is no study regarding the
mechanisms involves in cholesterol reducing effect by A. occidentale
leaves extract. In this study, cytotoxic assessment and anti-cholesterol
activity of A. occidentale leaves aqueous extract (AOE) were investigated. Cytotoxic
study was performed by exposing hepatoma cell (Hep G2) towards AOE
with concentration ranging from 0.002 to 20 mg/mL
for 24 h. Anacardium occidentale extract was found to be
not toxic to the cell. Then, the highest and not toxic AOE concentrations (20, 10, 5 and 2.5 mg/mL) were selected
for anti-cholesterol study. The ability of AOE to
reduce cholesterol in cell culture experiment was carried out by
pretreating Hep G2 with selected concentrations of AOE in 6-well plate before the
cell was exposed to low density lipoprotein (LDL).
The concentration of farnesyl-diphosphate farnesyltransferase (FDFT1),
apolipoprotein A1 (Apo A1), lecithin-cholesterol acyltransferase
(LCAT),
low density lipoprotein receptor (LDL R), scavenger receptor B1
(SR-B1),
ATP
binding cassette transporter A1 (ABCA-1)
and hepatic lipase (HL) were determined from the 6-well plate
media. The results showed that AOE did
not significantly increase the concentration of LDLR.
However, AOE significantly increased the concentration of FDFT1,
APO
A1, LCAT, SRB-1,
ABCA-1 and HL. The HMGR activity experiment showed
that all selected AOE concentrations cannot significantly
reduce the HMGR enzyme activity. These findings
suggested that AOE may involve in reverse cholesterol
transport process to reduce cholesterol metabolism in Hep G2 cell.
Keywords: Anacardium
occidentale; cholesterol metabolism; cytotoxic; Hep G2; reverse cholesterol
transport
ABSTRAK
A. occidentale
adalah daripada keluarga Anacardiaceae. Ia
telah terbukti secara saintifik mempunyai kesan antihiperkolesterolemia
terhadap haiwan eksperimen makmal yang diberikan diet berkolesterol
tinggi. Walau bagaimanapun, mekanisme
yang terlibat dalam menurunkan kolesterol oleh ekstrak daun A.
occidentale masih belum dikaji. Dalam
penyelidikan ini, penilaian sitotoksik dan aktiviti antikolesterol
oleh ekstrak akuas daun A. occidentale (AOE)
telah dikaji. Kajian sitotoksik telah dilakukan dengan mendedahkan
sel hepatoma (Hep G2) kepada AOE berkepekatan daripada 0.002 hingga
20 mg/mL selama 24 jam. Ekstrak
A. occidentale didapati tidak toksik kepada sel.
Kemudian, kepekatan AOE tertinggi dan tidak toksik (20, 10,
5 dan 2.5 mg/mL) telah dipilih untuk kajian antikolesterol.
Keupayaan AOE untuk mengurangkan kolesterol dalam eksperimen kultur sel dilakukan dengan merawat Hep G2 menggunakan AOE
berkepekatan terpilih dalam plat 6-telaga sebelum
sel didedahkan dengan lipoprotein ketumpatan rendah (LDL). Kepekatan farnesil-difosfat
farnesiltransferase (FDFT1), apolipoprotin A1 (Apo
A1), lesitin-kolesterol asiltransferase (LCAT), reseptor ketumpatan rendah
lipoprotein (LDLR), reseptor pembangkai -B1 (SR-B1),
kaset pengangkut pengikat ATP A1 (ABCA-1)
dan lipase hepatik (HL) telah ditentukan dalam media daripada
plat 6-telaga. Hasil kajian menunjukkan
bahawa AOE tidak meningkatkan kepekatan LDLR secara
signifikan. Walau bagaimanapun, AOE meningkatkan
kepekatan FDFT1, APO A1, LCAT,
SRB-1
dan ABCA-1 secara signifikan. Ujian
aktiviti HMGR menunjukkan bahawa semua kepekatan AOE terpilih
tidak boleh mengurangkan aktiviti enzim HMGR. Penemuan ini menunjukkan
bahawa AOE mungkin terlibat dalam proses pengangkutan
kolesterol berbalik untuk mengurangkan metabolisme kolesterol dalam
sel Hep G2.
Kata kunci: Anacardium occidentale; Hep G2; metabolisme kolesterol;
pengangkutan kolesterol berbalik; sitotoksik
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*Corresponding author; email: mohdkamal@frim.gov.my
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