Team:UNIPV-Pavia/Parts/Characterized

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<li>2. assemble them in a Promoter - XX - Coding sequence circuit, </li></ul></ol>
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<a name='K999'></a><h2>pSB1C3 plasmid with mRFP between S and P bearing pTet (easy-to-clone)</h2>
<a name='K999'></a><h2>pSB1C3 plasmid with mRFP between S and P bearing pTet (easy-to-clone)</h2>
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This vector was designed and realized in order to facilitate the cloning of coding sequences downstream of the strong promoter pTet. This vector was assembled by ligating S-P excided mRFP coding sequence from BBa_J61002 and ligating it in BBa_R0040 cut with S and P. Thus, the resulting vector contains mRFP between S and P. pTet cn be easily excided (E-P) and moved in the desired vector (E-P) and then the desired coding sequence can be easily assembled by digesting S-P the vector and X-P the coding sequence, thus obtaining a final part that is standard10-compatible.  
This vector was designed and realized in order to facilitate the cloning of coding sequences downstream of the strong promoter pTet. This vector was assembled by ligating S-P excided mRFP coding sequence from BBa_J61002 and ligating it in BBa_R0040 cut with S and P. Thus, the resulting vector contains mRFP between S and P. pTet cn be easily excided (E-P) and moved in the desired vector (E-P) and then the desired coding sequence can be easily assembled by digesting S-P the vector and X-P the coding sequence, thus obtaining a final part that is standard10-compatible.  

Revision as of 23:46, 17 September 2011

UNIPV TEAM 2011

Parts

Contents

New parts

J23101x series

  1. BBa_K516130 (wiki name: J101-E5 ) J101-RBS30-mRFP-TT
  2. BBa_K516131 (wiki name: J101-31 ) J101-RBS31-mRFP-TT
  3. BBa_K516132 (wiki name: J101-E7 ) J101-RBS32-mRFP-TT

BBa_J23101 is the reference standard promoter for the computation of RPUs. As discussed in 'data analysis' section, RPUs are relative units for the evaluation of promoter strength, based on a mathematical model of the transcription and the translation of a reporter gene.
The RPUs are supposed to be indepedent on the experimental setup, provided that the reference standard BBa_J23101 must be assayed in the same experimental condition of the studied promoter.
It means that if the studied promoter is in a low copy number plasmid and drives the expression of a reporter protein P, J23101 must be assembled in the same vector upstream of the same reporter P.
This approach is in accordance with the philosophy of synthetic biology, based on the concept of 'modularity' of the components. According to this approach, the assembly of basic well characterized modules to build complex circuits allows the prediction of the circuit behavior starting from the knowledge on the basic parts.
Salis et al. [Nat Biotec, 2009] stated that 'Identical ribosome binding site sequences in different genetic contexts can result in different protein expression levels'

and again 'It is likely that this absence of modularity is caused by the formation of strong secondary structures between the RBS-containing RNA sequence and one protein coding sequence but not another.'

For this reason, RPUs might not be reliable when comparing the same promoter with different RBSs because of the un-modularity of the RBS.
In order to asses what's the effect of RBS 'un-modularity' on RPUs reliability, we have built a set of four constitutive promoters (BBa_J23101) followed by one of the four RBSs tested. These parts were used to evaluate RBS efficiency. Data were collected and analyzed as described in 'Measurements' and 'Data analysis' sections. RPUs and Synthesis rate per cell [AUr] were computed and results are summarized in the table below.

NB: in the RPU computation, the J23101-RBS34-mRFP-TT construct has been considered as the reference standard. With this assumption, RPUs are identical to the estimated RBS efficiency.

J23101 promoter with RBS Scell R.P.U.s
RBS30 122 [13.23] 3.17
RBS31 2 [0.25] 0.05
RBS32 20 [1.7] 0.37
RBS34 50 [1.19] 1
RPUs of J23101 promoter with different RBSs


On the other hand, the hypothesis of RBS modularity depending on the promoter is accepted, the J23101-RBSx series we have provided can be used as a library of ready-to-use reference standard for RPU evaluation, that allows to depurate RPU measurement from RBS effect, thus providing only the promoter strength.

AiiA expression cassette driven by aTc-inducible pTet promoter

LuxI expression cassette driven by aTc-inducible pTet promoter

Existing parts

Notes for promoter characterization

Inducible and constitutive promoters were assembled upstream of different coding sequences containing an RBS from the Community collection.

The assembled RBSs are:

BioBrick code Declared efficiency
BBa_B0030 0,6
BBa_B0031 0,07
BBa_B0032 0,3
BBa_B0034 1

For an inducible device, the RBS variation has the purpose to stretch the induction curve, thus modulating its PoPs-OUT range.

The complex RBS-promoter acts as a whole regulatory element and determines the amount of translated protein. RBSs have been reported to have an un-modular behavior, since the translational efficiency is not independent on the coding sequences, but variates as an effect of different mRNA structure stability [Salis et al., Nat Biotec, 2009].
It is not possible to separate the effects of the sole promoter and of the sole RBS on the total amount/activity of gene product (in this case study, mRFP).

For this reason, every combination 'Promoter+RBS' was studied as a different regulatory element. Regulatory elements were characterized using mRFP reporter protein for different RBSs in terms of Synthesis rate per Cell (Scell) and R.P.U.s (Relative Promoter Units) as explained in measurements section.

Operative parameters of the promoter are derived from the estimated Hill equations obtained by nonlinear least sqares fitting (lsqnonlin Matlab routine) of the Hill function expressed in RPUs :

    • RPUmax is equal to the α and represents the maximum promoter activity,
    • RPUmin is equal to the α * δ represents the minimum promoter activity,
    • Switch point is computed as the abscissa of the inflection point of the Hill curve and it is representative of the position of linear region,
    • Linearity boundaries are determined as the intersection between the tangent line to the inflection point and the upper and lower horizontal boundaries of the Hill curve.

RBSs

The complex RBS-promoter acts as a whole regulatory element and determines the amount of translated protein. RBSs have been reported to have an un-modular behavior, since the translational efficiency is not independent on the coding sequences, but variates as an effect of different mRNA structure stability [Salis et al., Nat Biotec, 2009]. In addition, it is not possible to separate the effects of the sole promoter and of the sole RBS on the total amount of mRFP produced. For this reason, every combination 'Promoter+RBS' was studied as a different regulatory element. The evaluation of RBS efficiency can be performed in a very intuitive fashion:

  • 1. select the RBSs you want to study,
  • 2. assemble them in a Promoter - XX - Coding sequence circuit,
  • 3. measure the output of the circuits and calculate the RBS efficiency as the ratio of the output relative to the output of the circuit with the standard RBS.

This simple measurement system allows the quantification of RBS efficiency depending on the whole measurement system (i.e.: promoter and encoded gene). Today it has not still been completely validated the hypothesis that every functional module in a genetic circuit maintains its behavior when assembled in a complex circuits, even if many researchers implicitly accept this hypothesis when performing characterization experiments.
To rationally assess the impact that this hypothesis has on the genetic circuit design and fine tuning, several measurement systems were built to evaluate the dependance of RBS modularity from the promoter or the coding sequence separately.
In particular, in order to investigate if RBS efficiency depends on the promoter, the same coding devices (RBSx-RFP-TT) were assembled downstream of different promoters (J23101, pTet, pLux). Measuring the system output and evaluating the RBS efficiency. The results are summarized in the table below:

RBS effpLux* effpTet* effJ23101** Declared efficiency
B00300.401.68143.170,6
B00310.01ND0.050,07
B00320.190.41930.370,3
B00341111

On the other end, to investigate the dependance of RBS modularity on the coding sequence, the same regulatory elements (pTet-RBSx) were assembled upstream of different encoded gene (mRFP, AiiA and LuxI). RBS efficiency was assessed and the results are summarized in the table below:

RBS effmRFP** effAiiA*** effLuxI**** Declared efficiency
B00301.720.530.450,6
B00310.030.830.0280,07
B00320.370.50N.D.0.3
B00341111

* The RBS efficiency for inducible devices expressing mRFP was estimated as the ratio of the AUCs (Area under the curve) of the induction curve of the system with the studied RBS and the B0034 reference: AUCP, RBSx/AUCP, B0034
** The RBS efficiency for constitutive promoters expressing mRFP was computed as the ratio between ScellP, RBSx/ScellP, B0034
*** The RBS efficiency for pTet promoter driving the expression of AiiA enzyme was computed as the ratio αpTet, RBSxpTet, B0034 estimated for the measurement system pTet-RBSx-AiiA-TT. αpTet was estimated as described here. pTet was tested at full induction (100 ng/ml).
****The RBS efficiency for promoters driving the expression of LuxI was computed as the ratio αpTet, RBSxpTet, B0034 estimated from the measurement systems pTet-RBSx-LuxI. αpTet was estimated as described here. pTet was tested at full induction (100 ng/ml).



The parts we used to characterize the RBSs are listed here:

pLux promoter

    • BBa_K516330 (wiki name: E17 ) pLambda-RBS30-LuxR-T-pLux-RBS30-mRFP-TT
    • BBa_K516331 (wiki name: E18 ) pLambda-RBS30-LuxR-T-pLux-RBS31-mRFP-TT
    • BBa_K516332 (wiki name: E19 ) pLambda-RBS30-LuxR-T-pLux-RBS32-mRFP-TT
    • BBa_K516334 (wiki name: E20 ) pLambda-RBS30-LuxR-T-pLux-RBS34-mRFP-TT

The estimated parameters for the Hill functions are summarized in the table below. For more details on parameter estimation, see the model section.

RBS αpLux δpLux ηpLux kpLux
BBa_B0030 438 [10] 0.05 [>100] 2 [47] 1.88 [27]
BBa_B0031 9.8 [7] 0.11 [57] 1.2 [29] 1.5 [26]
BBa_B0032 206 [3] 0 [>>100] 1.36 [10] 1.87 [9]
BBa_B0034 1105 [6] 0.02 [>100] 1.33 [19] 2.34 [18]
Data are provided as average [CV%]

From this table, it is evident that, whilst αpLux assumes significantly different values for different RBSs, ηpLux and kpLux assume very similar values. This result shows that RBS variation modulates the amplitude of Hill function, not affecting the shape of the curve. The four induction curves result to be the same Hill function modulated in amplitude by a parameter, that is the estimated RBS efficiency for this measurement system.
These results are quite encouraging, because suggest that, given the non-modular behavior of RBS dpending on the encoded gene, the RBS has a modular behaviour respect to the promoter.

The operative parameters are summarized in the table below:

RBS RPUmax RPUmin Switch point [nM] Linear boundaries [MIN; MAX] [nM]
B00304.280.201.08[0.36; 3.27]
B00314.930.550.25[0.03; 2.30]
B00329.490.020.47[0.07; 3.07]
B003421.530.510.53[0.08; 3.77]

These operative parameters provide useful information on the behavior of this 3OC6-HSL inducible device. RPUmax assumes very different values, showing that the modulation in amplitude of the Hill can't be explained by a linear dependance on the RBS efficiency (in this case, in fact, the same RPUs should be observed for every RBS, since the standard reference used for RPUs computation)

pTet promoter

The protocols for the characterization of pTet promoter are reported in the pTet measurement section.
This promoter is widely studied and characterized usually using the strong RBS BBa_B0034. Here we have characterized its transcriptional strength as a function of aTc induction (ng/ul) for different RBSs. Four different induction curves were obtained and are reported in figure:

The data collected from the mRFP measurement systems were processed as described in data analysis section. The induction curves were obtained by fitting a Hill function as described in modelling section and the estimated parameters for pTet are reported in the pictures and in table below.

The estimated parameters of the Hill curves described in the figures are summarized in the table below:



RBS αpTet δpTet ηpTet kpTet
BBa_B0030 230.67 [3.7] 0.028 [91.61] 4.61 [23.73] 8.75 [4.16]
BBa_B0031 ND ND ND ND
BBa_B0032 55.77 [12] 1.53E-11 [>>100] 4.98 [57.62] 7.26 [14.98]
BBa_B0034 120 [5.95] 0.085 [40.6] 24.85 [47.6] 9 [5.43]
Data are provided as average [CV%]

The measurement system pTet-B0031-mRFP-TT couldn't be assayed because its fluorescence output is under the detectability threshold of our measurement instrument. For this reason, the parameters of the corresponding Hill curve couldn't be estimated and are reported as 'Not Determined' ND.

α parameter (representing the maximum trascriptional rate in the studied range of induction) varies as expected with the RBS variation and also the δ and η parameters are quite different among the RBS variations.
The KpTet parameter is quite constant among the RBS variations, thus suggesting that in this case the RBS variation doesn't substantially affect the switch point of the Hill curve, even if the amplitude and the maximum slope are not quite maintained (for the η parameter, maybe fitting problems).

The operative parameters are summarized in the table below:

RBS RPUmax RPUmin Switch point [ng/μ] Linear boundaries [MIN; MAX] [ng/μ]
B00301.53~07.95[4.66;11.99]
B0031NDNDNDND
B00323.16~06.7[4.45;10.05]
B00342.730.238.96[8.27;9.71]

From these parameters, it is evident that whilst the switch-point is almost maintained for all the RBSs, the linear boundaries are similar for RBS30 and RBS32 but for RBS34 are moved on the right of one order of magnitude.

AiiA gene - BBa_C0060

The activity of AiiA enzyme has been evaluated by testing the measurement systems pTet-RBSx-AiiA-TT. The HSL synthesis rate has been evaluated according to the model equations, properly adjusted. In particular, the ODE system is reported here:

System of equations for AiiA characterization

Since the measurement systems are only assayed in the exponential growth phase, the third equation can be modified as follows:

dN/dt=N*μ

because N<Nmax.
The parameters Nmax, μ and γHSL (see the Results section for more details) are known.
These parameters are summarized in the table below:

Nmax μ γHSL
1*109 0.003152 0

The parameters Kcat, KM,AiiA and αRBSx were estimated with a simultaneous fitting of the data collected as described in measurement section for the four measurement parts pTet-RBSx-AiiA-TT assayed by BBa_T9002 biosensor section. The estimated parameters for the enzymatic activity of AiiA are reported in the table below:

Kcat KM, AiiA αB0030 αB0031 αB0032 αB0034


LuxI gene - BBa_C0061

LuxI has been characterized through the Biosensor BBa_T9002 (see modeling section).
The HSL synthesis rate has been evaluated according to the model equations, properly adjusted. In particular, the ODE system is reported here:

System of equations for LuxI characterization

Since the measurement systems are only assayed in the exponential growth phase, the third equation can be modified as follows:

dN/dt=N*μ

because N<Nmax.
The parameters Nmax, μ and γHSL (see the Results section for more details) are known.
These parameters are summarized in the table below:

Nmax μ γHSL
1*109 0.003152 0

The parameters Vmax, KM,LuxI and αRBSx were estimated with a simultaneous fitting of the data collected as described in measurement section for the four measurement parts pTet-RBSx-LuxI-TT assayed by BBa_T9002 biosensor section. The estimated parameters for the enzymatic activity of LuxI are reported in the table below:

KM, LuxI Vmax αB0030 αB0031 αB0032 αB0034
1.5*104 3.63*10-9 247 15 ND 553


pSB1C3 plasmid with mRFP between S and P bearing pTet (easy-to-clone)

This vector was designed and realized in order to facilitate the cloning of coding sequences downstream of the strong promoter pTet. This vector was assembled by ligating S-P excided mRFP coding sequence from BBa_J61002 and ligating it in BBa_R0040 cut with S and P. Thus, the resulting vector contains mRFP between S and P. pTet cn be easily excided (E-P) and moved in the desired vector (E-P) and then the desired coding sequence can be easily assembled by digesting S-P the vector and X-P the coding sequence, thus obtaining a final part that is standard10-compatible.

Existing parts: sequence debugging

    • BBa_K516021 (wiki name: E10 ) RBS31-AiiA-TT Rebuilt existing part from BBa_I13914 (DNA planning)
    • BBa_K516022 (wiki name: E11 ) RBS32-AiiA-TT Rebuilt existing part from BBa_I13912 (DNA planning)
    • BBa_K516030 (wiki name: E5 ) RBS30-mRFP-TT Rebuilt existing part from BBa_S04180 (DNA planning)
    • BBa_K516032 (wiki name: E7 ) RBS32-mRFP-TT Rebuilt existing part from BBa_ J133000 (DNA planning)
    • BBa_K516214 (wiki name: E16 ) pTet-RBS34-LuxI Rebuilt existing part from BBa_S03623 (DNA available, only 2008 kit, inconsistent)
    • BBa_K516222 (wiki name: E26 ) pTet-RBS32-AiiA-TT Rebuilt existing part from BBa_ J22071 (2008 only, Bad sequencing)
    • BBa_K516224 (wiki name: E27 ) pTet-RBS34-AiiA-TT Rebuilt existing part from BBa_K077047 (Part deleted)
    • BBa_K516232 (wiki name: E23 ) pTet-RBS32-mRFP-TT Rebuilt existing part from BBa_I20252 (DNA planning)

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