Team:Hong Kong HKUST/riboregulator/characterization
From 2014.igem.org
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- | + | Based on this equation, the GFP synthesis rate (dF/dt) for the experiment (<a href= "http://parts.igem.org/Part:BBa_I0500">BBa_I0500</a>-<a href= "http://parts.igem.org/Part:BBa_E0240">BBa_E0240</a>) divided by the ABS (which means the absorbance or OD600) of the cells containing the experiment construct. GFP synthesis rate (dF/dt) for the reference promoter (<a href= "http://parts.igem.org/Part:BBa_J23101">BBa_J23101</a>-<a href= "http://parts.igem.org/Part:BBa_E0240">BBa_E0240</a>) divided by the ABS (which means the absorbance or OD600) of the cells containing the reference promoter construct.<br><br> | |
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- | GFP synthesis rate (dF/dt) for the reference promoter (<a href= "http://parts.igem.org/Part:BBa_J23101">BBa_J23101</a>-<a href= "http://parts.igem.org/Part:BBa_E0240">BBa_E0240</a>) divided by the ABS (which means the absorbance or OD600) of the cells containing the reference promoter construct.<br><br> | + | |
Then, RPU is obtained by dividing the GFP synthesis rate/ABS of experiment with the GFP synthesis rate/ABS of the reference promoter. | Then, RPU is obtained by dividing the GFP synthesis rate/ABS of experiment with the GFP synthesis rate/ABS of the reference promoter. | ||
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<img style= "width:50%" src= "https://static.igem.org/mediawiki/2014/6/60/Riboregulator_ust_Equation.png"/> <br><br> | <img style= "width:50%" src= "https://static.igem.org/mediawiki/2014/6/60/Riboregulator_ust_Equation.png"/> <br><br> | ||
- | + | Based on this equation, the amount of fluorescence [F] for the experiment (<a href= "http://parts.igem.org/Part:BBa_I0500">BBa_I0500</a>-<a href= "http://parts.igem.org/Part:BBa_E0240">BBa_E0240</a>) multiplied by the growth rate (μ) of the cells containing the experiment construct. Amount of fluorescence [F] for the reference promoter (<a href= "http://parts.igem.org/Part:BBa_J23101">BBa_J23101</a>-<a href= "http://parts.igem.org/Part:BBa_E0240">BBa_E0240</a>) multiplied by the growth rate (μ) of the cells containing the reference promoter construct.<br><br> | |
- | + | ||
- | + | ||
Then, RPU is obtained by dividing the fluorescence*growth rate of experiment with the fluorescence*growth rate of the reference promoter.<br><br> | Then, RPU is obtained by dividing the fluorescence*growth rate of experiment with the fluorescence*growth rate of the reference promoter.<br><br> |
Revision as of 23:07, 17 October 2014
Riboregulator Characterization
Introduction
Riboregulator is a type regulatory RNA that can regulate translation. One component of the riboregulator system,
cis-repressing RNA (crRNA). CrRNA contains a cis-repressing sequence which is located 5’ of the RBS and the gene of interest.
When the transcript is formed, the cis-repressing sequence can form a loop to form a complementary base pairs with the RBS and blocking the ribosome entry
to RBS. CrRNA is commonly called “lock” because it “locks” the translation of proteins. When there is a lock, we need a “key”. Component of the system that
act as a key is the taRNA. It can interact (in trans) with the cis-repressing sequence to unlock the RBS and therefore activate translation. The HKUST iGEM 2014
team characterized 4 riboregulator already available in the Part Registry and 1 riboregulator introduced by our team.
Riboregulators have cognate pairs. For certain crRNA, there is a corresponding taRNA that can activate “unlock” the repression by crRNA. We originally thought that Lock 3c and Key 3c (Table 1.) were cognate pairs, but they turned out to be that iGEM 2006_Berekley simply made different variants of Lock 3 and Key 3. They gave put an alphabet at the end of the name every time they produced different variant of lock 3 and key 3. The lock 3 and key 3 variants were created independently from each other so the letters at the end of name does not mean correspondence. Other teams should take note of this when they consider using riboregulators variants from iGEM 2006_Berkeley. |
Riboregulator Results
To characterize the different riboregulator pairs, we kept the genetic context identical except for the various cr-repressing sequence, trans-activating sequence and the RBS. The RBS sequence also had to be different for some of the riboregulator system. This is because the cr-repressing sequence depends on the RBS sequence; In order to repress translation, the cis-repressing sequence need to interact with the RBS, and the interaction depends on the sequences. Since different teams used different RBS to design their cis-repressing sequence, we also had to use corresponding RBS for characterization. We had a constitutive promoter BBa_J23102 to drive the expression of the cis-repressed GFP translation unit. For the expression taRNA, we wanted to control the expression and therefore we decided to use arabinose inducible PBAD promoter BBa_I0500 . The promoter was chosen because the 3’ end after the transcription start site of the promoter is short. Longer 3’ end can affect the function of the taRNA (source) (Figure 1. A). (fsd different between –TA and -CR). For the riboregulator system to work, the repression of GFP synthesis needs to be first observed when the cis-repressing sequence is added 5’ of the RBS of the system. Significant repression can be seen in Lock 1-Key1, Lock 3-Key 3, and Medium lock (Lock m)-Key for medium lock (Key m) cognate pairs (Figure 1. B, C, D respectively). For Lock 3c-Key 3c pair, we do not see repression when cis-repressing sequence is introduced to the system. Instead, converse can be observed. When we don’t have cis-repressing sequence, we see significant drop in the fluorescence (Figure 1.E). For HKUST lock 1 and HKUST key 1 cognate pair, some repression is observed, but the system seems very leaky compared to other riboregulator system. Also, no fluoresce can be observed when trans-activating component is introduced without the presence of the cis-repressing sequence (Figure 1.F). For the sake of time, we did not have the chance to sequence confirm the entire set of riboregulator pairs’ controls. We did, however, sequence verified the cognate pairs and lock3c-key 3c pair. The sequence matched except for HKUST lock 1-HKUST key 1. The deviation from expected result for HKUST lock 1-HKUST key 1 may be explained by the sequencing results. For lock3c-key3c, since the sequence matched 100%, we can simply conclude that we have a faulty system. After repression, the system needs to be activated when taRNA is expressed. |
PBAD Characterization
Introduction
PBAD promoter is an arabinose inducible promoter. In nature, the promoter exist in the arabinose operon to regulate the transcription of araB, araA, and araD. The arabinose operon or the ara operon encode enzymes needed or the catabolism of arabinose to xylulose 5- phosphate which is an intermediate of the pentose phosphate pathway. The Pc promoter which is adjacent to the PBAD promoter transcribes the araC gene in the opposite direction. AraC protein is responsible to repress the activity of the PBAD promoter when arabinose is absent. Once arabinose is present,the AraC protein binds to the arabinose and dimerize. The dimerize form of AraC-arabinose can activate the PBAD promoter. |
PBAD promoter BBa_I0500 in Part Registry
There are several PBAD promoters in the Part Registry. The promoter that we were interested was BBa_B0015 because of two reasons. First, BBa_I0500 , along with PBAD, has araC gene regulated by the Pc promoter. Without the AraC, the repression and induction of PBAD can only work on strain that are AraC+. By coupling the araC gene with the PBAD promoter, we can be free from such restraints. Second, BBa_I0500 needed debugging. BBa_I0500 , although it is useful, it is not requestable because of inconsistency in sequencing. Also, in the experience page, two teams, Groningen 2011 and Cambridge 2011 had some discrepancy between how the promoter was induced. In brief, Groningen results show that the induction of the promoter by arabinose was gradual while Cambridge reported that it was more of an “on-or-off” induction. We wanted to solve these problems so that the part could be more reliable for other users |
Results
In order to solve the discrepancy between Groningen 2011 and Cambridge 2011, we have calculated the Relative Promoter Unit of the PBAD promoter in three different cell strains across increasing arabinose concentration. The three strains that have chosen was: DH10B, BW25113, and DH5alpha. Groningen 2011 used cell strain DH5alpha to obtain the 3-D plot while Cambridge 2011 used BW27783. Unfortunately, we did not had access to the strain, so we had to use another similar strain BW25113. We thought that we had the capacity to test out another strain, so we added DH10B to the experiment. Only DH5alpha has araC in its genome. All other strains have deletion of araC (and other genes in the L-arabinose operon). Figure 3. RPU of PBAD promoter in three different cell strains across different arabinose concentration.Relative Promoter Unit of PBAD promoter was calculated in three strains: DH10B, BW25113 and DH5alpha. Gradient arabinose concentration (% w/v) from 0% to 1.0% with 0.2% increments was used to test the variation of promoter strength (RPU) in different concentration of arabinose. Each strain of cells inoculated overnight in various arabinose concentration above. The cells were diluted around 10 fold and grown until they reached mid-log phase (OD600 0.3-0.5). Cells were fixed and fluorescence was measured using FACS. The graph represent triplicate mean ±SD.RPU of PBAD in different cell strains PBAD Leakage Figure 4. Leakage of PBAD promoter in different cell strain.For each strain, fluorescence at no arabinose induction was normalized to the fluorescence at maximum observed fluorescence. The column graphs represent triplicate mean ± SD.3-D graphs for DH10B and DH5α Figure 5. |
Discussion
Groningen 2011 results may not truly represent the gradual induction of PBAD promoter |
Methods
Construction Measurement
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