IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054
Bioethanol is an important renewable energy source that can be used to replace fossil fuels. <br /> <br /> Bioethanol has several advantages included reduced pollution, renewable energy, and easy <br /> <br /> starting material for production. First generation bioethanol prod...
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id-itb.:317802018-08-21T16:26:10ZIMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 DONNY RUDINATHA (NIM:20517017), YOSHUA Indonesia Theses INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/31780 Bioethanol is an important renewable energy source that can be used to replace fossil fuels. <br /> <br /> Bioethanol has several advantages included reduced pollution, renewable energy, and easy <br /> <br /> starting material for production. First generation bioethanol production using agricultural stocks <br /> <br /> has drawn a negative connotation in “Food vs Fuel” issues. Second generation bioethanol <br /> <br /> production was used to avoid this controversy using lignocellulose raw materials. These are <br /> <br /> mainly composed of 40% hexose sugar (D-glucose) and 20% pentose sugar (D-xylose). <br /> <br /> The yeast Saccharomyces cerevisiae is used for bioethanol production but cannot naturally <br /> <br /> utilize D-xylose as carbon source. This problem was solved by introducing xylose isomerase <br /> <br /> from fungi and overexpression of genes involved in pentose phosphate pathway. This allowed <br /> <br /> for D-xylose consumption, but only when all the D-glucose has been consumed. To improve the <br /> <br /> simultaneous consumption of D-glucose and D-xylose, evolutionary engineering of S. cerevisiae <br /> <br /> was conducted and a new strain, Evo6, was generated. Evo6 shows improved D-xylose <br /> <br /> consumption compared to the parental strain, albeit with decreased D-glucose consumption and <br /> <br /> therefore reduced growth rate. The main purpose of this research is to increase D-glucose <br /> <br /> consumption in Evo6 for better bioethanol production. <br /> <br /> Evo6 is a flocculating strain caused by significant upregulation of Flo1, a gene involved in <br /> <br /> flocculation. Upon the deletion of FLO1 gene, the flocculation was abolished. Evo6ΔFlo1, used <br /> <br /> in this research, shows improved sugar consumption rates compared to Evo6. Furthermore, <br /> <br /> RNAseq data indicates that in Evo6, Tsl1 and Tps3 are upregulated. These are genes involved in <br /> <br /> trehalose formation. One of the intermediates in this pathway is trehalose-6-phosphate which is <br /> <br /> an inhibitor of hexokinase that phosphorylates glucose into glucose-6-phosphate. Accumulation <br /> <br /> of trehalose-6-phosphate explains the lower D-glucose consumption by the Evo6ΔFlo1 strain. <br /> <br /> Indeed, upon the deletion of TPS3 or TSL1, using CRISPR-Cas9 system, improved D-glucose <br /> <br /> consumption and ethanol production was observed. <br /> <br /> Furthermore in Evo6, Hxt1 is significantly down regulated compared to the parental strain. Hxt1 <br /> <br /> is a low affinity D-glucose transporter that is expressed at high concentrations of D-glucose. <br /> <br /> Overexpression of Hxt1 in Evo6 resulted in enhanced D-glucose metabolism but a lower Dxylose <br /> <br /> consumption. Hxt1 overexpression level was confirmed using qPCR compared to actin <br /> <br /> expression level. Overexpression of Hxt1 was done by changing the promoter using CRISPRCas9 <br /> <br /> system. To further elucidate the increased of D-xylose consumption in Evo6, the Hxt37 <br /> <br /> transporter carrying the N367I point mutation, as found in the Evo6 strain, was overexpressed in <br /> <br /> the parental strain. The mutation converts Hxt37 from a D-glucose into a specific D-xylose <br /> <br /> transporter. Overexpression of Hxt37 N367I resulted in a significant decreased in D-glucose <br /> <br /> metabolism however only a limited increased in D-xylose consumption was observed. <br /> <br /> Overexpression of Hxt37 was done using a plasmid based system. Overall, these data show that <br /> <br /> in strains that carry out D-glucose and D-xylose co-metabolism, D-xylose metabolism lead to <br /> <br /> increased trehalose-6-phosphate production that limits D-glucose consumption. <br /> text |
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Bioethanol is an important renewable energy source that can be used to replace fossil fuels. <br />
<br />
Bioethanol has several advantages included reduced pollution, renewable energy, and easy <br />
<br />
starting material for production. First generation bioethanol production using agricultural stocks <br />
<br />
has drawn a negative connotation in “Food vs Fuel” issues. Second generation bioethanol <br />
<br />
production was used to avoid this controversy using lignocellulose raw materials. These are <br />
<br />
mainly composed of 40% hexose sugar (D-glucose) and 20% pentose sugar (D-xylose). <br />
<br />
The yeast Saccharomyces cerevisiae is used for bioethanol production but cannot naturally <br />
<br />
utilize D-xylose as carbon source. This problem was solved by introducing xylose isomerase <br />
<br />
from fungi and overexpression of genes involved in pentose phosphate pathway. This allowed <br />
<br />
for D-xylose consumption, but only when all the D-glucose has been consumed. To improve the <br />
<br />
simultaneous consumption of D-glucose and D-xylose, evolutionary engineering of S. cerevisiae <br />
<br />
was conducted and a new strain, Evo6, was generated. Evo6 shows improved D-xylose <br />
<br />
consumption compared to the parental strain, albeit with decreased D-glucose consumption and <br />
<br />
therefore reduced growth rate. The main purpose of this research is to increase D-glucose <br />
<br />
consumption in Evo6 for better bioethanol production. <br />
<br />
Evo6 is a flocculating strain caused by significant upregulation of Flo1, a gene involved in <br />
<br />
flocculation. Upon the deletion of FLO1 gene, the flocculation was abolished. Evo6ΔFlo1, used <br />
<br />
in this research, shows improved sugar consumption rates compared to Evo6. Furthermore, <br />
<br />
RNAseq data indicates that in Evo6, Tsl1 and Tps3 are upregulated. These are genes involved in <br />
<br />
trehalose formation. One of the intermediates in this pathway is trehalose-6-phosphate which is <br />
<br />
an inhibitor of hexokinase that phosphorylates glucose into glucose-6-phosphate. Accumulation <br />
<br />
of trehalose-6-phosphate explains the lower D-glucose consumption by the Evo6ΔFlo1 strain. <br />
<br />
Indeed, upon the deletion of TPS3 or TSL1, using CRISPR-Cas9 system, improved D-glucose <br />
<br />
consumption and ethanol production was observed. <br />
<br />
Furthermore in Evo6, Hxt1 is significantly down regulated compared to the parental strain. Hxt1 <br />
<br />
is a low affinity D-glucose transporter that is expressed at high concentrations of D-glucose. <br />
<br />
Overexpression of Hxt1 in Evo6 resulted in enhanced D-glucose metabolism but a lower Dxylose <br />
<br />
consumption. Hxt1 overexpression level was confirmed using qPCR compared to actin <br />
<br />
expression level. Overexpression of Hxt1 was done by changing the promoter using CRISPRCas9 <br />
<br />
system. To further elucidate the increased of D-xylose consumption in Evo6, the Hxt37 <br />
<br />
transporter carrying the N367I point mutation, as found in the Evo6 strain, was overexpressed in <br />
<br />
the parental strain. The mutation converts Hxt37 from a D-glucose into a specific D-xylose <br />
<br />
transporter. Overexpression of Hxt37 N367I resulted in a significant decreased in D-glucose <br />
<br />
metabolism however only a limited increased in D-xylose consumption was observed. <br />
<br />
Overexpression of Hxt37 was done using a plasmid based system. Overall, these data show that <br />
<br />
in strains that carry out D-glucose and D-xylose co-metabolism, D-xylose metabolism lead to <br />
<br />
increased trehalose-6-phosphate production that limits D-glucose consumption. <br />
|
| format |
Theses |
| author |
DONNY RUDINATHA (NIM:20517017), YOSHUA |
| spellingShingle |
DONNY RUDINATHA (NIM:20517017), YOSHUA IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| author_facet |
DONNY RUDINATHA (NIM:20517017), YOSHUA |
| author_sort |
DONNY RUDINATHA (NIM:20517017), YOSHUA |
| title |
IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| title_short |
IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| title_full |
IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| title_fullStr |
IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| title_full_unstemmed |
IMPROVING D-XYLOSE AND D-GLUCOSE CO-CONSUMPTION FOR BIOETHANOL PRODUCTION IN Saccharomyces cerevisiae DS71054 |
| title_sort |
improving d-xylose and d-glucose co-consumption for bioethanol production in saccharomyces cerevisiae ds71054 |
| url |
https://digilib.itb.ac.id/gdl/view/31780 |
| _version_ |
1822923693066551296 |