Team:Tsinghua/Experiment1
From 2009.igem.org
GuoQiangChen (Talk | contribs) (→Top-Down Approach) |
GuoQiangChen (Talk | contribs) (→Synthesis of the Genome of GenSniper) |
||
(8 intermediate revisions not shown) | |||
Line 1: | Line 1: | ||
- | =Synthesis of the Genome | + | {{Tsinghua/ProjectHeader}} |
+ | |||
+ | |||
+ | =Synthesis of the GenSniper Genome= | ||
==Bottom-Up Approach== | ==Bottom-Up Approach== | ||
In the bottom-up approach, we amplify the biobricks from both the bacteriophage lambda and the adenovirus genome and incorporate them with a given order into molecular cloning vector(s). | In the bottom-up approach, we amplify the biobricks from both the bacteriophage lambda and the adenovirus genome and incorporate them with a given order into molecular cloning vector(s). | ||
Line 8: | Line 11: | ||
[[Image:pACYCDuet1.jpg|450px|pACYCDuet1]] | [[Image:pACYCDuet1.jpg|450px|pACYCDuet1]] | ||
- | We incorporate the segment from Nu1 to B on bacteriophage lambda genome into pET-28a while clone the left segment from C to FII (C will be further engineered) into pACYCDuet-1. Before | + | We incorporate the segment from Nu1 to B on bacteriophage lambda genome into pET-28a while clone the left segment from C to FII (C will be further engineered) into pACYCDuet-1. Before co-transformation with therapeutic DNA, we firstly co-transform the two plasmids encoding the GenSniper genome into BL21 (DE3) and evaluate their function. |
- | [[Image:BUA001.jpg| | + | [[Image:BUA001.jpg|700px|center|BUA001]] |
==Top-Down Approach== | ==Top-Down Approach== | ||
- | In the top-down approach, the part of needed segment on the lambda genome will be firstly | + | In the top-down approach, the part of needed segment on the lambda genome will be firstly cut by restriction enzyme B''am''HI and H''ind''III and then incorporated into pET-28a. The remain segment will be further integrated into downstream of the primary clone. Additionally, an expression module for Q protein will be constructed for induction of the expression of the GenSniper genome. |
[[Image:TDA001.jpg|800px|center|TDA001]] | [[Image:TDA001.jpg|800px|center|TDA001]] | ||
=GenSniper Production Evaluation= | =GenSniper Production Evaluation= | ||
+ | Firstly, we will spread the co-transformed BL21 (DE3) E.coli strains onto Kan-Cm double antibiotics plate to test their compatibility. | ||
+ | |||
+ | Secondly, we will measure the OD changes of the co-transformed E.coli strains to evaluate the function of lysis genes. | ||
+ | |||
+ | Thirdly, we will perform the virion isolation procedure on our lysed cell culture. Then electronic microscopy will be applied to observe the package of the GenSniper viroin. | ||
+ | |||
+ | [[Image:Evaluation.jpg|800px|center|thumb|Experiment Design for GenSniper Production Evaluation]] |
Latest revision as of 17:04, 21 October 2009
Home | Background | Brainstorming | Design | Experiment | Results | Conclusion | Protocol |
---|
Contents |
Synthesis of the GenSniper Genome
Bottom-Up Approach
In the bottom-up approach, we amplify the biobricks from both the bacteriophage lambda and the adenovirus genome and incorporate them with a given order into molecular cloning vector(s).
Specifically, we choose two molecular cloning vectors to encode two sections of the gene therapy vector genome, pET-28a and pACYCDuet-1.
We incorporate the segment from Nu1 to B on bacteriophage lambda genome into pET-28a while clone the left segment from C to FII (C will be further engineered) into pACYCDuet-1. Before co-transformation with therapeutic DNA, we firstly co-transform the two plasmids encoding the GenSniper genome into BL21 (DE3) and evaluate their function.
Top-Down Approach
In the top-down approach, the part of needed segment on the lambda genome will be firstly cut by restriction enzyme BamHI and HindIII and then incorporated into pET-28a. The remain segment will be further integrated into downstream of the primary clone. Additionally, an expression module for Q protein will be constructed for induction of the expression of the GenSniper genome.
GenSniper Production Evaluation
Firstly, we will spread the co-transformed BL21 (DE3) E.coli strains onto Kan-Cm double antibiotics plate to test their compatibility.
Secondly, we will measure the OD changes of the co-transformed E.coli strains to evaluate the function of lysis genes.
Thirdly, we will perform the virion isolation procedure on our lysed cell culture. Then electronic microscopy will be applied to observe the package of the GenSniper viroin.