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The p53 protein is a regulatory protein that can inhibit tumor formation by <br /> <br /> activating cell cycle arrest or apoptosis in cell repair systems. It can interact with <br /> <br /> the hepatitis B virus X protein (HBx) which is often associated as a cause of liver &...
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id-itb.:294272018-02-26T11:07:11Z#TITLE_ALTERNATIVE# IMANSARI NIM: 20715305, MUTIARA Indonesia Theses INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/29427 The p53 protein is a regulatory protein that can inhibit tumor formation by <br /> <br /> activating cell cycle arrest or apoptosis in cell repair systems. It can interact with <br /> <br /> the hepatitis B virus X protein (HBx) which is often associated as a cause of liver <br /> <br /> cancer. The aims of this study are to overproduce and characterize human p53 <br /> <br /> protein with and without coexpression of GroEl-DnaK chaperones on Escherichia <br /> <br /> coli BL21(DE3). The optimization of p53 protein coding gene sequence was <br /> <br /> performed to obtain Codon Adaptation Index (CAI) and %GC of 0.724 and 52.5% <br /> <br /> respectively, which approached the parameters for E. coli B. The optimized p53 <br /> <br /> sequence was inserted on a pET-16b plasmid (pET-16b_p53). This recombinant <br /> <br /> plasmid was transformed to E. coli BL21(DE3) with and without chaperon <br /> <br /> plasmids, pGroElDnaK, and characterized using restriction analysis. The <br /> <br /> optimization of p53 overproduction was done by variation of IPTG concentration <br /> <br /> and induction temperature. High amount of p53 protein was produced at 0.7 mM <br /> <br /> IPTG concentration. Overproduction of p53 at 17°C, 25°C, and 37°C induction <br /> <br /> temperatures showed the same level of expression of p53 protein and formed a <br /> <br /> non-soluble inclusion body. The p53 protein that was coexpressed with the GroEl- <br /> <br /> DnaK chaperone protein at 25°C and 37°C indicated the presence of p53 protein <br /> <br /> in soluble form, but the majority of p53 protein existed in the inclusion body <br /> <br /> form. The p53 inclusion body was then solubilized with Tris HCl buffer pH 7.6 <br /> <br /> containing 8 M urea. The protein was renaturated by decreasing the urea <br /> <br /> concentration to 2 M. The analysis of thermal shift assay (TSA) showed different <br /> <br /> melting curves between before and after it was renatured. TSA analysis of p53 <br /> <br /> protein that interacted with HBx showed a peak with a melting point of 28°C. This <br /> <br /> p53 protein interaction information with HBx could be used to search its inhibitor <br /> <br /> candidate. <br /> text |
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| description |
The p53 protein is a regulatory protein that can inhibit tumor formation by <br />
<br />
activating cell cycle arrest or apoptosis in cell repair systems. It can interact with <br />
<br />
the hepatitis B virus X protein (HBx) which is often associated as a cause of liver <br />
<br />
cancer. The aims of this study are to overproduce and characterize human p53 <br />
<br />
protein with and without coexpression of GroEl-DnaK chaperones on Escherichia <br />
<br />
coli BL21(DE3). The optimization of p53 protein coding gene sequence was <br />
<br />
performed to obtain Codon Adaptation Index (CAI) and %GC of 0.724 and 52.5% <br />
<br />
respectively, which approached the parameters for E. coli B. The optimized p53 <br />
<br />
sequence was inserted on a pET-16b plasmid (pET-16b_p53). This recombinant <br />
<br />
plasmid was transformed to E. coli BL21(DE3) with and without chaperon <br />
<br />
plasmids, pGroElDnaK, and characterized using restriction analysis. The <br />
<br />
optimization of p53 overproduction was done by variation of IPTG concentration <br />
<br />
and induction temperature. High amount of p53 protein was produced at 0.7 mM <br />
<br />
IPTG concentration. Overproduction of p53 at 17°C, 25°C, and 37°C induction <br />
<br />
temperatures showed the same level of expression of p53 protein and formed a <br />
<br />
non-soluble inclusion body. The p53 protein that was coexpressed with the GroEl- <br />
<br />
DnaK chaperone protein at 25°C and 37°C indicated the presence of p53 protein <br />
<br />
in soluble form, but the majority of p53 protein existed in the inclusion body <br />
<br />
form. The p53 inclusion body was then solubilized with Tris HCl buffer pH 7.6 <br />
<br />
containing 8 M urea. The protein was renaturated by decreasing the urea <br />
<br />
concentration to 2 M. The analysis of thermal shift assay (TSA) showed different <br />
<br />
melting curves between before and after it was renatured. TSA analysis of p53 <br />
<br />
protein that interacted with HBx showed a peak with a melting point of 28°C. This <br />
<br />
p53 protein interaction information with HBx could be used to search its inhibitor <br />
<br />
candidate. <br />
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| format |
Theses |
| author |
IMANSARI NIM: 20715305, MUTIARA |
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IMANSARI NIM: 20715305, MUTIARA #TITLE_ALTERNATIVE# |
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IMANSARI NIM: 20715305, MUTIARA |
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IMANSARI NIM: 20715305, MUTIARA |
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| url |
https://digilib.itb.ac.id/gdl/view/29427 |
| _version_ |
1822022066257264640 |