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Sains Malaysiana 51(10)(2022):
http://doi.org/10.17576/jsm-2022-5110-04
Expression of Furfural Reductase
Improved Furfural Tolerance in Antarctic Bacterium Pseudomonas extremaustralis
(Pengekspresan Furfural Reduktase Meningkatkan Ketoleranan Furfural dalam Bakteria AntartikaPseudomonas extremaustralis)
AHMAD BAZLI RAMZI1,*, MATTHLESSA MATTHEW MINGGU1, UMMUL SYAFIQAH RUSLAN1,
MOHAMAD HAZWAN FIKRI KHAIRI1&
PEER MOHAMED ABDUL2,3
1Institute of Systems Biology (INBIOSIS), Universiti Kebangsaan Malaysia,
43600 UKM Bangi, Selangor Darul Ehsan, Malaysia
2Research Centre for Sustainable Process Technology,
Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi,
Selangor Darul Ehsan, Malaysia
3Program of Chemical Engineering, Faculty of
Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi,
Selangor Darul Ehsan, Malaysia
Received: 14
December 2021/Accepted: 15 June 2022
Abstract
Whole-cell biocatalysis using Antarctic bacteria is presently hampered
by a lack of genetic information, limited gene tools and critically, a poor
range of cultivation conditions. In this work, biological engineering strategy
was employed for developing Pseudomonas extremaustralis,
a metabolically-versatile and biopolymer-producing Antarctic bacterium, as a
new whole-cell biocatalytic host. For this purpose, gene cloning and plasmid
construction were carried out for overexpression of furfural reductase (FucO), an industrially-important enzyme for degradation of
toxic furfural compound commonly found in lignocellulosic biorefinery. FucO gene from Escherichia coli BL21
was cloned in pJM105 plasmid and transformed into competent cells of P. extremaustralis to generate a biologically-engineered pFucO strain. For functional characterization of the
enzyme, furfural reductase activity was assayed, where the P. extremaustralis pFucO strain exhibited increased furfural reductase activity of about 15.6 U/mg, an
18.8-fold higher than empty plasmid-carrying control pJM105 strain (0.83 U/mg).
Furfural detoxification activity using whole cells was also determined by which
the overexpression of FucO led to increased tolerance
and cell growth with an OD600 value of 5.3 as compared to the control pJM105
strain that was inhibited with 10 mM furfural during 48-hour cultivation.
Therefore, the findings obtained in this study successfully demonstrated the
development of P. extremaustralis as
biocatalytic host for the production of recombinant furfural reductase. The
bioengineering would serve as a modular biotechnological platform for polar
strain and bioproduct development tailored towards industrial biotechnology
applications.
Keywords: Antarctic
bacteria; biological engineering; furfural reductase; Pseudomonas extremaustralis; whole-cell biocatalysis
Abstrak
Penggunaan bakteria
Antartika sebagai biopemangkin keseluruhan sel buat masa ini adalah sangat
terbatas akibat kurangnya maklumat genetik, alatan genetik yang terhad dan
ketidakserasian keadaan pengkulturan. Dalam kajian ini, strategi kejuruteraan
biologi digunakan untuk membangunkan Pseudomonas extremaustralis,
sejenis bakteria yang berasal dari Antartika yang mempunyai metabolisme
versatil, berupaya menghasilkan biopolimer dan sesuai digunakan sebagai perumah
baru biopemangkin keseluruhan sel. Untuk mencapai tujuan ini, pengklonan gen
dan pembinaan plasmid telah dilakukan bagi penghasilan furfural reduktase
(FucO), sejenis enzim yang penting dalam penguraian sebatian toksik furfural
yang kerap ditemui dalam proses penapisan sisa lignoselulosa. Gen FucO daripada Escherichia coli BL21 diklonkan ke dalam plasmid pJM105 dan
dimasukkan ke dalam sel kompeten P. extremaustralis untuk menghasilkan
strain terjurutera biologi pFucO. Untuk pencirian enzim dan kefungsian bakteria
terubah suai biologi ini, aktiviti furfural reduktase telah diasai dengan
strain P. extremaustralis pFucO menghasilkan sebanyak 15.6 U/mg, iaitu
18.8 kali ganda lebih banyak daripada sel yang mengandungi plasmid kawalan
pJM105 (0.83 U/mg). Aktiviti penguraian furfural menggunakan seluruh sel juga
dilakukan yang mana pengaruhan enzim furfural reduktase berjaya meningkatkan
pertumbuhan sel oleh strain pFucO yang menunjukkan OD600 sebanyak 5.3 selepas
48 jam dikultur berbanding strain kawalan pJM105 yang direncatkan apabila diuji
dengan 10 mM furfural. Penemuan kajian ini membuktikan P. extremaustralis terjurutera biologi ini berjaya dibangunkan sebagai perumah biopemangkin untuk
penghasilan furfural reduktase rekombinan. Strategi kejuruteraan biologi ini
akan menjadi pelantar berasaskan bioteknologi untuk pembangunan strain dan
penghasilan bioproduk kutub untuk aplikasi bioteknologi industri.
Kata kunci: Bakteria Antartika; biopemangkin seluruh sel; furfural reduktase; kejuruteraan biologi; Pseudomonas extremaustralis
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*Corresponding author; email: bazliramzi@ukm.edu.my
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