Team:XMU-China/Project PSystem
From 2014.igem.org
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- | <span style="font-family: Times New Roman; font-weight: 700;">Figure 1. </span>SDS-PAGE analysis of E.coli K strain (<span style="font-family: Times New Roman; font-style: italic;">DH5α</span>). </span><span style="font-family: Times New Roman; font-weight: 700;">(a)</span> Lane 1-2: supernatant and pellet of original </span><span style="font-family: Times New Roman; font-style: italic;">DH5α</span>; Lane 3-4: supernatant and pellet of strain with single plasmid A1 (BBa_K1036003); Lane 5-6: supernatant and pellet of strain with both plasmids A1</span> </span>(BBa_K1036003) and B</span> (BBa_K1036000)</span>. The red arrows indicate the </span><span style="font-family: Times New Roman; font-weight: 700;">misfolding</span> GFP-LVA protein (27.6 kDa) in the precipitation. </span><span style="font-family: Times New Roman; font-weight: 700;">(b)</span> Lane 1-2: supernatant and pellet of original </span><span style="font-family: Times New Roman; font-style: italic;">BL21</span>; Lane 3-4: supernatant and pellet of strain with single plasmid A1</span> (BBa_K1036003)</span>; Lane 5-6: supernatant and pellet of strain with both plasmids A1</span> (BBa_K1036003) </span>and B</span> (BBa_K1036000)</span>. The blue arrows indicate LuxR (27.5 kDa), GFP-LVA (27.6 kDa) and AiiA-LVA (28.7 kDa) in the supernatant. The orange arrows indicate LuxI-LVA (22.4 kDa) in the supernatant. (The marker of b was not in right position, however, the proteins were confirmed by MALDI-TOF-TOF .)</span> | + | <span style="font-family: Times New Roman; font-weight: 700;">Figure 1. </span>SDS-PAGE analysis of E. coli K strain (<span style="font-family: Times New Roman; font-style: italic;">DH5α</span>). </span><span style="font-family: Times New Roman; font-weight: 700;">(a)</span> Lane 1-2: supernatant and pellet of original </span><span style="font-family: Times New Roman; font-style: italic;">DH5α</span>; Lane 3-4: supernatant and pellet of strain with single plasmid A1 (BBa_K1036003); Lane 5-6: supernatant and pellet of strain with both plasmids A1</span> </span>(BBa_K1036003) and B</span> (BBa_K1036000)</span>. The red arrows indicate the </span><span style="font-family: Times New Roman; font-weight: 700;">misfolding</span> GFP-LVA protein (27.6 kDa) in the precipitation. </span><span style="font-family: Times New Roman; font-weight: 700;">(b)</span> Lane 1-2: supernatant and pellet of original </span><span style="font-family: Times New Roman; font-style: italic;">BL21</span>; Lane 3-4: supernatant and pellet of strain with single plasmid A1</span> (BBa_K1036003)</span>; Lane 5-6: supernatant and pellet of strain with both plasmids A1</span> (BBa_K1036003) </span>and B</span> (BBa_K1036000)</span>. The blue arrows indicate LuxR (27.5 kDa), GFP-LVA (27.6 kDa) and AiiA-LVA (28.7 kDa) in the supernatant. The orange arrows indicate LuxI-LVA (22.4 kDa) in the supernatant. (The marker of b was not in right position, however, the proteins were confirmed by MALDI-TOF-TOF .)</span> |
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Revision as of 00:04, 18 October 2014
A REASONABLE EXPLANATION OF MISFOLDING GFP UNDER QS OSCILLATION
In the project of iGEM13 XMU-China, they can’t get expected oscillation. However, this year iGEM14 XMU-China further investigate the reason of abnormal oscillation. We further review SDS-PAGE analysis to confirm the circuit at protein level. The SDS-PAGE data is shown in Figure 1. Based on that, we make a reasonable assumption that the unexpected behavior of the LuxR Promoter leads to the misfolding proteins hence the abnormal oscillation.
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Figure 1. SDS-PAGE analysis of E. coli K strain (DH5α). (a) Lane 1-2: supernatant and pellet of original DH5α; Lane 3-4: supernatant and pellet of strain with single plasmid A1 (BBa_K1036003); Lane 5-6: supernatant and pellet of strain with both plasmids A1 (BBa_K1036003) and B (BBa_K1036000). The red arrows indicate the misfolding GFP-LVA protein (27.6 kDa) in the precipitation. (b) Lane 1-2: supernatant and pellet of original BL21; Lane 3-4: supernatant and pellet of strain with single plasmid A1 (BBa_K1036003); Lane 5-6: supernatant and pellet of strain with both plasmids A1 (BBa_K1036003) and B (BBa_K1036000). The blue arrows indicate LuxR (27.5 kDa), GFP-LVA (27.6 kDa) and AiiA-LVA (28.7 kDa) in the supernatant. The orange arrows indicate LuxI-LVA (22.4 kDa) in the supernatant. (The marker of b was not in right position, however, the proteins were confirmed by MALDI-TOF-TOF .) |
As the SDS-PAGE shows, a large amount of GFP-LVA and LuxI-LVA appear in pellet where misfolding proteins often exist. Both proteins directly affect the oscillation result. And it is critical to find out the reason for misfolding proteins. iGEM14 XMU-China make the following assumption:
The research reveals an unexpected behavior[1] of Lux pR (BBa_R0062). In the absence of autoinducer 3OC6 (AHL), LuxR binds to Plux (Lux pR) and activates backwards transcription (Figure 2).
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Figure 2. Relative RFP fluorescence for a control construct designed to measure backwards transcription from Lux pR. Addition of LuxR and 3OC6 90 (AHL) as indicated. Error bars in all panels are one standard deviation. |
The imperfect simplification of setting lux pL and Lux pR in the same direction:
From the original design by Jeff Hasty, Lux pR and Lux pL are set in opposite directions (Figure 3A). In the absence of AHL, LuxR could activate backward transcription of Lux pR leading to more expression of LuxR which is critical to meet the oscillation conditions. However, present literature don’t consider the backwards transcription which have effect on quorum sensing oscillation.
A. Original Design
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B. iGEM13 XMU-China Design
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Figure 3A.Top row is the original design by Jeff Hasty.B. Bottom row is the simplified design which sets lux pL and lux pR in the same direction. |
In the simplified design (Figure 3B), when LuxR activates the backward transcription, RNA polymerase will be blocked by the terminators B0015. So that this simplification doesn’t perform as same as original design. Actually, the reverse terminated efficiency of B0015 is 0.295(CC)[2] which may lead to leakage transcription. However, the correct sequence of GFP-LAA can’t be transcribed during the backwards transcription, even if the minus-strand of GFP-LAA could be transcribed, the sequence of the RNA is not in the right direction of GFP-LAA, hence incorrect amino acid sequences may be translated, resulting in misfolding GFP just as the SDS-PAGE shows (Figure 1).
Because of the imperfect simplified design doesn’t follow the original function completely, the abnormal oscillation is justifiable. Misfolding protein is an evidence to support our assumption.
iGEM14 XMU-China involved sequence comparison to investigate the difference between the original and the registry parts. We find that the original Lux pR has 20bp overlapping sequence with original Lux pR. There is a restriction enzyme cutting site (EcoR I) at the 56bp of original Lux pR (Figure 4).
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Figure 4. Schematic of original QS promoter. |
Parts registry truncate the original Lux pR at 56bp to get the 55bp Lux pR (BBa_R0062). On the contrary, Lux pL (BBa_R0063) is longer the original Lux pL, and at the end of BBa_R0063 is initial part of 41bp LuxR (BBa_C0062). Thus new problems arise—is the modification of original QS promoter reasonable? Does the modification result in the unexpected backward transcription?
Quorum sensing system is so widely used in the synthetic biology, we think it’s remarkable to make it clear. We highlight the abnormal phenomenon of QS oscillation which may be caused by imperfect simplification for the very first time. We hope that more efforts could be made to figure out the interaction between QS oscillation parts.[3]
References
2. http://parts.igem.org/Part:BBa_B0015