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As Rfp is the transcription readout for these constructs, red colonies were expected to be observed on agar + bacitracin plates. But at the concentration of 10 uL/mL, we did not observe any red colonies. We carried out same experiments in various concentrations of bacitracin ranging from 10 to 200 uL/mL. At such high concentrations of antibiotic, though we were able to see colonies, none of them were observed to be red. <br> | As Rfp is the transcription readout for these constructs, red colonies were expected to be observed on agar + bacitracin plates. But at the concentration of 10 uL/mL, we did not observe any red colonies. We carried out same experiments in various concentrations of bacitracin ranging from 10 to 200 uL/mL. At such high concentrations of antibiotic, though we were able to see colonies, none of them were observed to be red. <br> | ||
To troubleshoot this issue, we tried out this promoter with only reporter gene downstream of it. We did not see any red colonies with this construct as well. We concluded that this promoter is not able to express any gene downstream of it and decided to try out different inducible promoters. | To troubleshoot this issue, we tried out this promoter with only reporter gene downstream of it. We did not see any red colonies with this construct as well. We concluded that this promoter is not able to express any gene downstream of it and decided to try out different inducible promoters. | ||
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Revision as of 10:16, 13 October 2018
Results
Extraction of Exudates
Our first aim was to identify the different promoters the would be expressed in presence of root exudates. We sought out to observe differences in gene expression in Bacillus subtilis in the presence of root exudates of 4 different crops. Tomato, Wheat, Rice, and Soybean are the most commonly grown crops in Maharashtra, India. Therefore, exudates of these four crops were extracted using protocol explained in Experiments tab.
To collect the exudates, these crops were grown in sterilized soil for three weeks, and the exudates were extracted using water as solvent. Though most of the literature that we referred to suggested the use of artificial media such as Murashige & Skoog medium (MS medium), we decided to go use soil as our medium for plant growth to replicate natural condition to the highest extent possible. Presence of other microbial flora would have caused disturbances during the collection of exudates and RNA sequencing, hence the soil was sterilized using autoclave before sowing the seeds.
Seeds were procured from S.U.B. Agro Pvt. Ltd., Pune. Collected exudate mixture with water was concentrated using evaporation under vacuum using RotaVap. Some of the chemical moieties in exudate mixtures were expected to be heat sensitive, hence the application of vacuum. (Please click here for detailed protocol).
Concentrated exudates were stored at 40C place for further experiments.
Construction of Amplification Circuit
As discussed in design (give link), as a case study, we worked towards developing a positive feedback circuit which can act as genetic amplifier. Various steps towards building the construct as well as the parts used in the process are documented below.
We started building our construct from the last element in the circuit and sequentially added required elements upstream of the sequence.
Expected output (Choice of reporter gene):
The aim was to build a positive feedback amplifier circuit for with an aim of release of phosphodiesterase (phoD) enzyme. phoD gene was isolated from the genomic DNA of B. subtilis 168 strain by PCR. (Write what PhoD does).
We selected the reporter gene, Red Fluorescent Protein (rfp), as output for our amplifier circuit because of ease in quantification by measurement of fluorescence. This part was obtained from iGEM 2018 Distribution Kit (Part #BBa_J04450).
Transcription activator (TA):
In order to construct the positive feedback amplifier, we required a transcription activator which did not interfere with native gene regulation in either B. subtilis or E. coli.
We chose two such transcription activators from the iGEM distribution kit:
- Pag activator from phage PSP3 (Part #BBa_I746351): This is a transcriptional unit containing Pax activator and a ribosome binding site (Part #BBa_B0034) upstream of it.
- Ogr activator from phage P2 (Part #BBa_I746350): This is a transcriptional unit containing Ogr activator and a ribosome binding site (Part #BBa_B0034) upstream of it.
These parts were cloned upstream of rfp. Positive clones were screened by performing double digestion with EcoRI and PstI and were confirmed by agarose gel electrophoresis.
Promoter induced by transcription activator:
Promoter which is inducible by transcription activator is pivotal part in the circuit as it regulates the transcription of its inducer, i.e. transcription activator itself (See Design page). Hence, for these constructs, choice of promoters is those that are induced by transcription activators Pag and/or Ogr activators.
PF (Part #BBa_I746360) and PO (Part #BBa_I746361) are such promoters, both isolated form phage P2, which can be induced by transcription activators, Pag and Ogr. As both of these are not native to B. subtilis, they are not expected to interfere with native gene transcription.
We chose following two composite parts which contain promoters with the transcription activators upstream of them:
- Part #BBa_K274380: Promoter PF (Part #BBa_I746360), with Pag activator (Part #BBa_I746351) upstream of it.
- Part #BBa_K274371: Promoter PO (Part #BBa_I746361), with Ogr activator (Part #BBa_I746350) upstream of it.
These parts were successfully cloned upstream of the constructs in Figure 1.
Inducible Promoter:
The aim of this case study is to use the promoters which are induced by the root exudates of crops for the activation of genetic amplifier. But while the results of RNA sequencing were awaited, we decided to test and characterize our circuit with other inducible promoters readily available in iGEM parts registry. Although there are several promoters for B. subtilis reported in iGEM Registry, there are limited number of inducible promoters available. PLiaI (Part #BBa_823001) is bacitracin inducible promoter. We decided to go ahead with this promoter as the chances of leaky expression for an antibiotic-inducible promoter are very low. We cloned promoter upstream of the constructs shown in Figure 2,
Because of lack of any other inducible promoter from B. subtilis in registry, we decided to isolate them from B. subtilis 168 genomic DNA. We chose the following promoters:
- PXylA: Xylose inducible promoter
- PMtlA: Mannitol inducible promoter
- PMalA: Maltose inducible promoter
As the sizes of these sequences were very low (160 bp), experiments were carried out to construct these promoters from synthetic oligos with overlap region.
PCR was carried out using the oligos (each 90 bp long) and Taq polymerase enzyme to construct the promoter sequences. DNA of desired length (160 bp) was not observed on agarose gel.
Experiments to construct promoters using PCR were retried by changing various parameters of the polymerase chain reactions such as annealing temperature, annealing time, number of cycles. Experiment to isolate promoter sequences from the genomic DNA of B. subtilis 168 using same oligos was also carried out. We did not get a part of desired size from any of the trials.
We decided to check the validity of the construct constitutive promoter for B. subtilis available in the iGEM Distribution Kit (Promoter veg: Part #BBa_K143012). But because of lack of time, we were unable to ligate this promoter with our construct and characterize our whole circuit.