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Sains Malaysiana 47(12)(2018): 3003–3008 http://dx.doi.org/10.17576/jsm-2018-4712-09
Arabidopsis AT2G02870 Loss of
Function Mutants Lead to Enhanced Production of Hydroperoxide Lyase Pathway
Genes and Products
(Mutan Fungsi-Hilang Arabidopsis AT2G02870 Membawa
kepada Peningkatan Gen
dan Produk Tapak Jalan Hidroperoksida Liase)
MUHAMMAD NAEEM-UL-HASSAN1,3,
ZAMRI
ZAINAL1,2, NUR ATHIRAH
ABD
HAMID2,
MUHAMMAD SAJAD2,4 & ISMANIZAN ISMAIL1,2*
1Centre
for Biotechnology and Functional Food, Faculty of Science and
Technology, University Kebangsaan Malaysia, 46300 Bangi UKM, Selangor
Darul Ehsan, Malaysia
2Institute of Systems Biology (INBIOSIS), Universiti Kebangsaan
Malaysia, 46300 Bangi UKM, Selangor Darul Ehsan, Malaysia
3Department of Chemistry, University of Sargodha, Sargodha, Pakistan
4Department of Plant Breeding and Genetics, University College
of Agriculture and Environmental Sciences,
Diserahkan: 4 September 2018 /Diterima:
19 September 2018
ABSTRACT
F-box proteins containing variable
C-terminal domains make an essential part of SKP1-Cullin-Ring
box-F box (SCF) complex. SCF complex catalyzes the final
step to link the ubiquitin tag with the target protein, destined for
degradation, through F-box protein that confer overall substrate specificity to
the complex. In this study, we analyzed the role of At2g02870,
a Kelch containing F-box protein from Arabidopsis thaliana, by using
reverse genetics strategy. At2g02870 loss of function mutant lines (at2g02870)
were analyzed and compared with wild type plants for the expression of genes
and products of hydroperoxide lyase (HPL) branch of oxylipin
pathway. We found that the at2g02870 plants have enhanced expression of HPL pathway
genes and produce more green leaf volatiles (GLV)
than the wild type plants. Our results suggested that the gene is involved in
the regulation of HPL pathway, possibly through the
degradation of enzymes or/and the regulatory factors of the pathway.
Keywords: F-box proteins; hydroperoxide
lyase; Kelch-repeat; lipoxygenase; oxylipin
ABSTRAK
Protein kotak F mengandungi pelbagai
domain C-terminal yang membentuk bahagian penting kompleks SKP-Cullin-Ring
box-F box (SCF). Kompleks SCF memangkinkan peringkat
akhir pengikatan tag ubiquitin dengan protein sasaran untuk degradasi, melalui
protin kotak F yang memberikan kespesifikan substrak secara keseluruhan kepada
kompleks. Dalam kajian ini, kami menganalisis peranan At2g02870,
protein kotak F yang mengandungi Kelch dari Arabidopsis thaliana menggunakan
strategi genetik berbalik. Titisan mutan kehilangan fungsi At2g02870 telah
dianalisis dan dibandingkan dengan tumbuhan jenis liar untuk pengekpsresan gen
dan produk cabang hidroksiperoksida liase (HPL)
tapak jalan oksilipin. Kami dapati tumbuhan at2g02870 telah meningkatkan
pengekspresan gen tapak jalan HPL dan menghasilkan lebih
banyak bahan meruap daun hijau (GLV) berbanding dengan tumbuhan
jenis liar. Keputusan kami menunjukkan gen tersebut terlibat dalam pengawalan
tapak jalan HPL, kemungkinan melalui degradasi enzim atau/dan faktor
pengawalan tapak jalan tersebut.
Kata
kunci: Hidroperoksida liase; Kelch-berulang; lipoksigenase; oksilipin; protein
kotak F
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*Pengarang untuk
surat-menyurat; email: maniz@ukm.edu.my
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