STABILIZATION OF BACILLUS SP. MUTANT ISOLATE STRAIN KG7' AND STRAIN KG48 BY ADAPTIVE LABORATORY EVOLUTION (ALE) FOR BIOSURFACTANT PRODUCTION
Biosurfactants are widely applied in the petroleum industry because they can increase oil recovery. Compared to synthetic surfactant, biosurfactants are more environmentally responsible and have specific activity in extreme environments, but have not been able to compete economically because of t...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/70866 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Biosurfactants are widely applied in the petroleum industry because they can
increase oil recovery. Compared to synthetic surfactant, biosurfactants are more
environmentally responsible and have specific activity in extreme environments,
but have not been able to compete economically because of the low biosurfactant
production capacity. Through the Adaptation Laboratory Evolution (ALE), the
metabolism of biosurfactant-producing microorganisms can be engineered, so they
can produce more biosurfactants. One of the compounds used as a mutagen in this
process is CTAB. In the process, ALE takes time until a stable mutant is obtained
to be characterized. This research aims to stabilize the mutant isolates of Bacillus
sp. strain KG7’ and KG48 through the ALE strategy and to evaluate the production
and emulsification activity of biosurfactants produced by stable mutant. The isolate
candidate was stabilized by performing gradual exposure to the LB medium which
has given CTAB (a) 3.9 ppm and (b) 4.5 ppm. Mutants are considered to be stable
as the frequency of mutants grow on the medium >90%. The characterization of the
biosurfactant production of selected mutant isolates was carried out on the SMSSe
medium with an incubation time of 96 hours. During the incubation process, the
number of microbes, biosurfactant production, and emulsification index (E24) data
were collected every 12 hours. The results showed that the KG7'a was stable in the
59th generation (93.11%), KG7'b in the 234th generation (90.33%), while KG48 has
not been observed to be stable until the 204th generation (7.08%). Observation of
cell morphology shows that wild-type (WT) cells are longer than KG7' (P <0.1) and
KG48 (P <0.1). Evaluation of biosurfactant production shows that WT was able to
produce biosurfactant as much as 0.123 g/L, while KG7'a only produces 0.107 g/L,
and KG7’b produces 0.101 g/L. E24 evaluation showed that in light petroleum, WT
biosurfactants able to emulsify 58.9% of oil while the two mutants were only 47.6%
(KG7'a) and 51.8% (KG7'b). However, biosurfactants produced by both mutants
can emulsify heavy petroleum 74.5% (KG7'a) and 80% (KG7'b), better than WT
(71.3%). Biosurfactant E24 activity at different harvest time vary for different oil
types. E24 activity of KG7'b in light petroleum was highest at the 12th hour (55%),
E24 in the heavy oil was highest at the 24th hour (75.1%), and E24 in cooking oil
was highest at the 60th hour (25%). This study shows that the KG7’ mutant isolate
was successfully stabilized through the ALE strategy after gradual adaptation to the
59th generation (on CTAB 3.9 ppm) and 234th generation (on CTAB 4.5 ppm) with
biosurfactant production not as much as WT but higher emulsification activity in
heavy petroleum. Based on these phenomena, it is suspected there are differences
in the structure of biosurfactants produced by WT and KG7'b. It can be the basis
for further research in molecular structure characterization and biosurfactant
production optimization through other approaches besides ALE. |
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