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Gibson

In order to accomplish an efficient and economical DNA fragments assembly, we adopted an enzymatic assembly method named “Gibson assembly” which is wildly used because of its brilliant effectiveness in yielding deserted DNA fragments that may up to several hundred kilobases. In our project, we elaborately modified original Gibson assembly protocol, made it both better and cheaper. And subsequently, we will summarize our practical protocol in detail.

This figure indicates the overall principle of Gibson assembly. In this figure, two DNA fragments which share the same overlapping pieces, are joined together in a one-step isothermal reaction (or precisely called One-step isothermal in vitro recombination). Because the two adjacent DNA fragments share terminal sequence overlap, when T5 exonuclease remove nucleotides from 5’ ends of double-stranded DNA, reminded single-strand overlap region can pair with each other, just like two sticky ends. After two overlapping single-strand DNA annealed, Phusion DNA polymerase fill the gaps and Taq ligase, seals the nicks (It seems not so much complicated, isn’t?  ).

The Protocol of Gibson Assembly:
The required key reagents in Gibson assembly:
T5 exonuclease (NEB, 10U/ul, 1000U )
Phusion DNA polymerase (Thermo, 100 x 50 μl)
Taq DNA ligase (NEB, 10 000U)

First, prepare DNA assembly reagent-enzyme mix (which can be stored at -20℃ until needed). The reagent-enzyme is composed of reaction buffer and enzyme which are commercial available.
And these are our reaction buffer:
5× Isothermal reaction buffer preparing protocol:
1.5 ml 1 M Tris-HCl pH 7.5 (Prepared by adding HCl into 6.05g Tris-base to adjust pH to 7.5. The total volume is 50ml)
75 ul 2 M MgCl2,        (1.9g/10ml)
30 ul 100 mM dGTP,
30 ul 100 mM dATP,
30 ul 100 mM dTTP,
30 ul 100 mM dCTP,
150 ul 1M DTT,
0.75 g PEG-8000,
150 ul 100 mM NAD        (0.33g/5ml)
ddH2O 3 ml.

Assembly master mixture:
320 ul 5* isothermal reaction buffer,
0.64 ul of 10 U /ul T5 exonuclease,
20 ul of 2 U/ul Phusion DNA polymerase,
160 ul of 40 U /ul Taq DNA ligase,
Add water up to a final volume of 1.2 ml.

The volume of mix and DNA is 3:1. For example, 15ul mix + 5ul DNA solution.

To start a Gibson assembly, you can just simply mix the reagent-enzyme mixture with DNA fragments solution, and put the PCR tube that with the mix-DNA mixture into PCR instrument, incubate it at 50℃ as few as 15 minutes, and then the assembly of product- a recombinated DNA fragments is accomplished! By ordinary PCR procedure, we can subsequently amplify the product, for further experiment.

Measurement

To fully test our Cas-9 mediated multi-stage control system, we must establish a method that can measure a gene’s expression level preciously. We choose RFP as our report gene because its expression product can be measured easily. We can not only check whether the RFP is expressed by naked eyes, but also can determine the absolute fluorescent intensity of RFP by Multi-FunctionalXXXXXXX accurately. However, we cannot just simply adapt absolute fluorescent intensity as the RFP expressive level, because the absolute fluorescent intensity can be influenced directiy and greatly by bacterial cell density. The cell density values varies significantly among different samples, so the absolute fluorescent intensity cannot reflect the RFP expressive level truly. So here we adopted a traditional but effective trick to emit the negative affect bacterial cell density.
We define I as the relative fluorescence intensity, OD as XXXXXXXXXXX, and F as absolute fluorescence intensity. Thus, I can be formulated like this:
I = F/OD
Now, the relative fluorescence intensity won’t be influenced by bacterial density, and it obviously can reflect the RFP’s expressive level more accurate than fluorescent intensity.