Difference between revisions of "Team:HZAU-China/Experiments-Riboswitch"

Line 243: Line 243:
 
             <h3>1.Introduction</h3>
 
             <h3>1.Introduction</h3>
 
             <p>Riboswitches are versatile devices for synthetic biology applications. They are RNA-based gene expression regulatory elements, composed of a ligand-sensing aptamer domain followed by an overlapping expression platform. Mechanisms of modulation of gene expression are highly divergent in prokaryotes and involve control of transcription, translation, splicing, and mRNA stability (1) (Figure 1).</p>
 
             <p>Riboswitches are versatile devices for synthetic biology applications. They are RNA-based gene expression regulatory elements, composed of a ligand-sensing aptamer domain followed by an overlapping expression platform. Mechanisms of modulation of gene expression are highly divergent in prokaryotes and involve control of transcription, translation, splicing, and mRNA stability (1) (Figure 1).</p>
             <img src="#" width="700px">
+
             <img src="https://static.igem.org/mediawiki/2016/9/97/Exp-ribo-fig1.jpeg" width="700px">
 
             <p style="text-align:center">Figure 1. Mechanism of riboswitch</p><br/>
 
             <p style="text-align:center">Figure 1. Mechanism of riboswitch</p><br/>
  
Line 252: Line 252:
 
             <div class="random"><a id="A21" ></a></div>
 
             <div class="random"><a id="A21" ></a></div>
 
             <h4>2.1 Construction of circuits</h4>
 
             <h4>2.1 Construction of circuits</h4>
             <img src="#" width="700px">
+
             <img src="https://static.igem.org/mediawiki/2016/3/35/Exp-ribo-fig2.jpeg" width="700px">
 
             <p style="text-align:center">Figure 2. PSB4A5-735F & peT-Ptac-pleD</p><br/>
 
             <p style="text-align:center">Figure 2. PSB4A5-735F & peT-Ptac-pleD</p><br/>
 
             <p>a. illustration of 735F, we also construction a series of plasmids contain different promoters(J231xx) and riboswitches(Bcxx).</p>
 
             <p>a. illustration of 735F, we also construction a series of plasmids contain different promoters(J231xx) and riboswitches(Bcxx).</p>
Line 271: Line 271:
 
             <div class="random"><a id="A31" ></a></div>
 
             <div class="random"><a id="A31" ></a></div>
 
             <h4>3.1 Phenotype of pleD expression</h4>
 
             <h4>3.1 Phenotype of pleD expression</h4>
             <img src="#" width="700px">
+
             <img src="https://static.igem.org/mediawiki/2016/5/52/Exp-ribo-fig3.jpeg" width="700px">
 
             <p style="text-align:center">Figure 3. Phenotype of pleD expression</p><br/>
 
             <p style="text-align:center">Figure 3. Phenotype of pleD expression</p><br/>
 
             <p>(a). Negative control: DE3 contain pET28b plasmid; experimental group: DE3 contain pET28b-pleD plasmid. The level of aggregation increased with the increase of IPTG’s concentration.</p>
 
             <p>(a). Negative control: DE3 contain pET28b plasmid; experimental group: DE3 contain pET28b-pleD plasmid. The level of aggregation increased with the increase of IPTG’s concentration.</p>
Line 279: Line 279:
 
             <div class="random"><a id="A32" ></a></div>
 
             <div class="random"><a id="A32" ></a></div>
 
             <h4>3.2 Characterization of Riboswitch</h4>
 
             <h4>3.2 Characterization of Riboswitch</h4>
             <img src="#" width="700px">
+
             <img src="https://static.igem.org/mediawiki/2016/9/90/Exp-ribo-fig4.jpeg" width="700px">
 
             <p style="text-align:center">Figure 4.</p><br/>
 
             <p style="text-align:center">Figure 4.</p><br/>
  
             <img src="#" width="700px">
+
             <img src="https://static.igem.org/mediawiki/2016/d/d1/Exp-ribo-fig5.jpeg" width="700px">
 
             <p style="text-align:center">Figure 5.</p>
 
             <p style="text-align:center">Figure 5.</p>
 
             <p>We use “red-through rate” (RTR) of the downstream gene to measure the terminator forming efficiency of a riboswitch. </p>
 
             <p>We use “red-through rate” (RTR) of the downstream gene to measure the terminator forming efficiency of a riboswitch. </p>

Revision as of 18:33, 19 October 2016

hardware

Riboswitch

1.Introduction

Riboswitches are versatile devices for synthetic biology applications. They are RNA-based gene expression regulatory elements, composed of a ligand-sensing aptamer domain followed by an overlapping expression platform. Mechanisms of modulation of gene expression are highly divergent in prokaryotes and involve control of transcription, translation, splicing, and mRNA stability (1) (Figure 1).

Figure 1. Mechanism of riboswitch


2.Method

2.1 Construction of circuits

Figure 2. PSB4A5-735F & peT-Ptac-pleD


a. illustration of 735F, we also construction a series of plasmids contain different promoters(J231xx) and riboswitches(Bcxx).

b. Plasmid pET-Ptac-pleD contain a tac promoter with a lacO site.

2.2 Congo red staining assay

Strains were grown at 37 °C and 200 rpm in LB medium with 50 μ g/mL kanamycin (LB/Kan) until OD600 reach about 0.5. Subsequently, 5 μ L cultures were applied onto the LB/Kan plates (0.75% Agar) containing 80 μ g/mL Congo red and IPTG. Colony morphology was examined by visual inspection after 2 day incubation at 25 °C.

2.3 Characterization of riboswitches-Determination of RFI

Cells from the overnight starter culture were diluted 1:5000, induced with different concentrations and combinations of inducers, and grown in M9 media for 18H at 28℃. Just before measurement, the resulting saturated cultures were diluted 1:20 in PBS. Samples were then analyzed on a plate reader. Absorbance at 600 and (AB600) and GFP intensity were measured (600 nm absorbance filter, 0.1 second counting time for AB; 485 nm excitation filter, 525 nm emission filter for GFP). Media background was substracted from AB600 and GFP values, and AB600 values obtained from the plate reader were converted to optical density (OD) by using the equation: OD600 = ((AB600-0.06)*3.11)-0.0158. Average OD600 in the measured samples were between 0.2-0.3, and we did not observe correlations between OD and GFP levels. For each well, the GFP value was divided by the OD600 value to correct for differences in cell density. GFP/OD were plotted using the R (ggplot2).

3.Result

3.1 Phenotype of pleD expression

Figure 3. Phenotype of pleD expression


(a). Negative control: DE3 contain pET28b plasmid; experimental group: DE3 contain pET28b-pleD plasmid. The level of aggregation increased with the increase of IPTG’s concentration.

(b).For demonstrating expression of pleD, we used Congo red staining assay. As previous mentioned, high concentration of c-di-GMP could induce E. coli synthesize exopolysaccharides, and Congo red binding is a complex phenotype that reflects various outer membrane and surface properties including the presence of adhesive structures such as curli fimbria which are involved in biofilm formation. Wild type: DE3 contain pET28b plasmid, colony which was stained red color contain pET-pleD plasmid; Concentration of IPTG: 0.5mM.


3.2 Characterization of Riboswitch

Figure 4.


Figure 5.

We use “red-through rate” (RTR) of the downstream gene to measure the terminator forming efficiency of a riboswitch.

The red-through rate of each riboswitch in liquid medium was assessed by relative fluorescence intensity, which is the ratio of specific activity of a test strain to specific activity of the control strain (pET-28-pleD/J23117+sfGFP) with the same promoter of test circuits (such as J23117+Bc3-5+sfGFP).

Reference

1. M. Wachsmuth, S. Findeiß, N. Weissheimer, P. F. Stadler, M. Mörl, De novo design of a synthetic riboswitch that regulates transcription termination. Nucleic Acids Research 41, 2541-2551 (2012).