Difference between revisions of "Part:BBa M30011:Experience"
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===Applications of BBa_M30011=== | ===Applications of BBa_M30011=== | ||
| − | Technion-Israel 2014 iGEM team | + | |
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| + | == Stockholm 2015 iGEM Team == | ||
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| + | We wanted to us BBa_M30011 as part of an OmpR dependent regulatory circuit which produces GFP at low osmolarity and RFP at high osmolarity (BBa_K1766004). First we wanted to characterize how BBa_M30011 responds to changes in osmolarity. | ||
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| + | We transformed two E. coli strains with BBa_M30011 in pSB1C3. One expressed wild-type EnvZ (TOP10) and the other was EnvZ deficient (BW25113). We then cultured both strains at different osmolarities by using minimal media substituted with 0%, 5%, 10% or 15% sucrose. The fluoresence was measured using a plate reader (Excitation:580+/-10 nm, Emission:627+/-30 nm). Absolute fluoresence values were adjusted for optical density and normailized using the 0% samples. | ||
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| + | [[File:BBa_M30011 osmograph1.png|500px|thumb|right|Results of osmolarity test 1]] | ||
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| + | == Technion-Israel 2014 iGEM team == | ||
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We used the biobrock BBa_M30011 (ompR controlled mRFP) to test the Taz construct (BBa_K1343016) we created. In addition, we decided to test the biobrick BBa_M30011 in response to changes in osmolarity. | We used the biobrock BBa_M30011 (ompR controlled mRFP) to test the Taz construct (BBa_K1343016) we created. In addition, we decided to test the biobrick BBa_M30011 in response to changes in osmolarity. | ||
Revision as of 11:17, 17 September 2015
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Applications of BBa_M30011
Stockholm 2015 iGEM Team
We wanted to us BBa_M30011 as part of an OmpR dependent regulatory circuit which produces GFP at low osmolarity and RFP at high osmolarity (BBa_K1766004). First we wanted to characterize how BBa_M30011 responds to changes in osmolarity.
We transformed two E. coli strains with BBa_M30011 in pSB1C3. One expressed wild-type EnvZ (TOP10) and the other was EnvZ deficient (BW25113). We then cultured both strains at different osmolarities by using minimal media substituted with 0%, 5%, 10% or 15% sucrose. The fluoresence was measured using a plate reader (Excitation:580+/-10 nm, Emission:627+/-30 nm). Absolute fluoresence values were adjusted for optical density and normailized using the 0% samples.
Technion-Israel 2014 iGEM team
We used the biobrock BBa_M30011 (ompR controlled mRFP) to test the Taz construct (BBa_K1343016) we created. In addition, we decided to test the biobrick BBa_M30011 in response to changes in osmolarity.
Two isogenic strains of E. coli K12, BW25113 (parent strain from the Keio collection) and JW3367-3 (with ΔEnvZ mutation) were transformed with pSB1C3 carrying the BBa_M30011 reporter. The bacteria were cultured in growth media containing varying concentrations of NaCl. After two hours of growth the relative RFP fluorescence of the cultures was determined (fluorescence/OD).
As a positive control we used E. coli Top10 transformed with biobrick BBa_J04450 (RFP under Plac).
OD was measured at 600nm. Fluorescence excitation wavelength: 560nm Fluorescence emission wavelength: 612nm
Figure 1: Relative fluorescence dependent on NaCl concentration (mM)
We expected that the mutant strain (ΔEnvZ) would show a constant level of relative fluorescence which is lower than that of the parent strain. This is because histidine kinase protein which detects osmolarity changes in the cells environment (EnvZ) is not present in the mutant. The EnvZ does not phosphorylate the ompR. The low level of fluorescence could be due to another mechanism (such as an acetyl phosphate dependent mechanism) which phosphorylates the ompR, leading to activation of the PompC promoter. In Figure 1 we see that the mutant showed the expected constant low level of relative fluorescence.
Since the parent strain (+EnvZ) is sensitive to osmolarity changes in the cell’s environment, we expected that an increase in NaCl concentration would cause an increase in relative fluorescence. This is because at high osmolarity, more ompR is phosphorylated, leading to increased activation of the PompC promoter. However, the parent strain also showed a constant (but high) level of expression (see Figure 1). We repeated the experiment three times with different ranges and dilutions of NaCl concentration but all showed a similar result.
Figure 2: (A) E. coli BW25113 with no plasmid. (B) E. coli BW25113 containing ompR controlled mRFP (BBa_M30011) on pSB1C3. (C) E. coli JW3367-3 (ΔEnvZ) containing ompR controlled mRFP (BBa_M30011) on pSB1C3. (D) E. coli JW3367-3 (ΔEnvZ) with no plasmid.
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