Team:TecCEM/Results

Cell Gif

Results

Overview

To accomplish our project objective several recombinant proteins must be produced in order to analyze their effects on a co culture of fibroblasts (L929) and mesenchymal cells after an in vitro burn assay. To evaluate the efficiency of the treatment, a measurement of the proliferation rate was performed using LDH (lactate dehydrogenase) as an analysis metabolite. Given that our treatment involves the usage of a growth factor, the rate at which this protein is released into the medium is critical to avoid adverse effects in the cellular line (such as cancer), for that reason a nano encapsulation with chitosan was also performed to control the rate at which our growth factor is released.

Summary

What did we accomplish?

  • Nanoencapsulation in chitosan of leptin, BSA and RFP.
  • Realization of in vitro burn assay.
  • Realization of leptin proliferation essay.
  • Obtaining parts with adequate enzyme recognition sites.
  • Protein production of leptin and tenascin C (More validations are needed).
  • Co-culture of fibroblast and mesenchymal cells.
  • Cellular growth in TaCO-BOB hardware.

What happened?

  • We started ligating parts, no bands of expected size were observed but we attributed this fact to low sensitivity of agarose gels, so we proceeded with transformation and protein induction. Nevertheless, we realized that consistent results were not achieved (bad protein migration rates, sometimes no induction band could be observed). [Unfortunately, we invested a lot of time on this period]
  • Then we started thinking that our parts did not had the necessary extra nucleotides for proper cleavage of restriction enzymes and what we were truly observing was the effect of star activity and inappropriate ligation, resulting in non specific plasmids which did not contained our whole part but conferred the bacteria antibiotic resistance.

How did we solved it?

We designed primers that incorporate the necessary nucleotides into our parts. Thus, we started having proper migrations of project parts and posterious transformations and protein production of BBLEP.

How should we improve?

By including better protein reporters for the screening of transformed, functional bacteria colonies.

Our proyect is divided into three sections which are the following:

  1. Phase 1: E. coli transformation
  2. Phase 2: Protein production
  3. Phase 3: Test in cellular line

Phase 1 E. coli transformation

Once our IDT synthesis arrived, we set the objective of ligating the composite parts of tenascin (BBa_K2719005) [also called BBTNC], leptin (BBa_K2719009) [also called BBLEP] and collagen (BBa_K2719007) [also called BBCOL], into an RFC10 compatible psB1C3 iGEM plasmid for future transformations into E. coli. We had several transformation attempts (Figure 1), most of the times there are no adequate migrations patterns achieved. We carried on with bacterial transformation and protein production, as we thought that bands of ligation could not be seen given the agarose sensibility, surprisingly bacterial colonies (either E. coli BL21(DE3) and DH5 alpha ) were seen (Figure 2) in selective medium but no constant protein production could be achieved (Go to phase 2for more information). After many failed attempts and a lot of time invested, we suspected that maybe ligations were failing due to the absence of “close to the end DNA cleavage nucleotides” (needed for restriction cutting). To solve the problem previously mentioned, primers were designed to tackle this problems using iGEM prefix and suffix sequences as template for amplification. We amplified BBLEP (Figure 3) and ligated it into psB1C3 finally obtaining the expected sizes at each step. Thus with this methodology we could resolve the difficulties for BBLEP and achieving a transformation in BL21(DE3) (Figure 4), due to timewise limitations and the embedded DNA synthesize problems, BBCOL and BBTNC could not be tested with this methodology. Future plans include applying that methodology to those parts and transforming into respective bacteria strains.

Clave 1
Figure 1. First attempt of ligation of IDT parts into a psB1C3 plasmid
  • Experiment: Electrophoresis.
  • Matrix: Agarose (0.85%).
  • Conditions: 100 volts, 60 minutes in TBE buffer.
  • The samples were charged in the following order:
    1. 2-log DNA ladder (6uL)
    2. BBLEP 2739bp (3uL + 3uL of loading buffer)
    3. BBCOL 3566bp (3 uL + 3uL of loading buffer)
    4. BBTNC 3196bp (3 uL + 3uL of loading buffer)
    5. BBTNC 3196bp (3 uL + 3uL of loading buffer)
    6. 2-log DNA ladder (6uL)
    7. 1kb DNA ladder (6uL)
Clave 2
Figure 2. Culture plates containing transformed E. coli .1) E. coli DH5 alpha containing BBCOL 2) E. coli DH5 alpha containing BBLEP 3) E. coli DH5 alpha containing BBTCD.
Clave 3
Clave 3
Figure 3. BBLEP amplicon obtained after PCR with designed primers
  • Experiment: Electrophoresis
  • Matrix: Agarose (0.85%)
  • Conditions: 100 volts, 60 minutes in TBE buffer
  • The samples were charged in the following order:
    1. 2-log DNA ladder (6uL)
    2. BBLEP PCR amplicon (3 uL + 3uL of loading buffer)
Clave 4
Figure 4. Culture plates containing transformed E. coli BL21(DE3) with BBLEP.

Phase 2 Protein production

After doing transformation into E. coli BL21 (DE3) we started the production and purification of our protein of interests. This phase was a key factor for the demonstration of the functionality of our project. First, we obtained polyacrylamide gels that had clear signs of maximum induction of our proteins at 5 hours after IPTG induction. The results that we obtained were inconsistent between several repetitions of the induction.

After that observation several hypotheses were formulated in order to explain those events, the first one was that the synthesis sequence had several errors, which made the peptide product unstable, and an easy target for degradation. This hypothesis was mainly supported by the apparition of the protein at 5h after induction, but its complete disappearance after 16 hours, specifically TCD that needs a protein fusion to improve its stability and reduce the rate of degradation.

The second hypothesis was that the used strain (E. coli BL21 (DE3)) was mislabeled, therefore the transformation and induction were on strains unable to produce RNApol T7. This idea was discarded after several experiments were made on fresh strains, obtaining the same inconsistent results. Even though the results continued to be inconsistent, with the fresh strains some improvement was made. Tenascin was observed for the first time on SDS-PAGE after 5h of induction (see figure 5). Also a Dot Blot was performed in order to evaluate the presence of Tenascin and Leptin using the His-TAG (see figure 7).

The third and last hypothesis was that an error on the synthesis meant that there were not enough nucleotides for allowing the restriction enzymes (EcoRI and PstI) to work properly, reducing ligation efficiency. In order to test this hypothesis new primers were developed, those primers after amplification with PCR, added extra nucleotides to the prefix and suffix o the parts promoting the properly work of the enzymes.

Tenascin confirmation (protein level)

Clave A
Figure 5. Analysis of BBLEP and BBTCD before IPTG induction
  • Experiment: SDS-PAGE
  • Matrix: Polyacrylamide (15%)
  • Conditions: 1080 volts for 20 minutes, 120 volts 60 minutes.
  • Objective: Determine the presence of protein from BBLEP (BBa_K2719009) and BBTCD (BBa_K2719005) in protein producer strain E. coli BL21 (DE3)
  • Description: Crude lysate (30 uL + 10 uL laemmli buffer) coming from transformed BL21 (DE3) strains and induced with 1 mM IPTG for different hours at 37 Celsius degrees were loaded onto polyacrylamide gel and runned with SDS-Tris-Gly buffer
  • The samples were charged in the following order:
    1. BBTCD V2 (At 16 hours of induction) [BBa_K2719005]
    2. BBTCD V1 (At 16 hours of induction) [BBa_K2719005]
    3. BBLEP V2 (At 16 hours of induction) [BBa_K2719009]
    4. BBLEP V3 (At 16 hours of induction) [BBa_K2719009]
    5. BBTCD V1 (At 16 hours of induction) [BBa_K2719005]
    6. BBLEP V1 (At 16 hours of induction) [BBa_K2719009]
    7. BBTCD V2 (At 5 hours of induction) [BBa_K2719005]
    8. BBTCD V1 (At 5 hours of induction) [BBa_K2719005]
    9. BBLEP V2 (At 5 hours of induction) [BBa_K2719009]
    10. Protein Ladder
  • Analysis: In the gel there is a constant band pattern among lanes, which represents the native proteins of BL21 (DE3) strain. On the other hand, a single band is highly ovestanding which can be seen in lane 7, here a single pattern band between 25 and 37 kDa correspond to a possible apparition of BBTCD protein, which has a theoretical weight of 35.1 kDa, the band stand as very likely candidate as its form and luminosity correspond to a common protein band derived from an IPTG expression, nevertheless, at 15 hours the same part (lane 1) shows no sign of the protein, this can be explained as the lost of function of IPTG given by continuous exposure to high temperatures and consequently loss of protein production possibility and gradual degradation of existing protein. For BBLEP no sign of protein production could be recorded. More analysis to BBTCD must be done to corroborate the existence of protein, and a restructure of troubleshooting for BBLEP must be done to create better results of production.

Selection of Tenascin producer strain

  • Experiment: SDS-PAGE
  • Matrix: Polyacrylamide (20%)
  • Conditions: 80 volts for 20 minutes, 120 volts 60 minutes.
  • Objective: Determine the E. coli BL21 (DE3) strain that produce the protein BBTCD (BBa_K2719005).
  • Description: Crude lysate (30 uL + 10 uL laemmli buffer) coming from transformed BL21 (DE3) strains and induced with 1 mM IPTG for different hours at 37 Celsius degrees were loaded onto polyacrylamide gel and runned with SDS-Tris-Gly buffer.
  • The samples were charged in the following order:
    1. BBTCD V1 (At 5 hours of induction) [BBa_K2719005]
    2. BBTCD V3 (At 5 hours of induction) [BBa_K2719005]
    3. BBTCD V2 (At 5 hours of induction) [BBa_K2719009]
    4. Negative control E.coli BL21 (DE3) without transformation (At 5 hours of induction)
    5. Protein Ladder
Clave B
Figure 6. Analysis of BBTCD in different E. coli BL21 strains

Tenascin and leptin confirmation (protein level)

Clave C
Figure 7. Dot Blot analysis of BBTCD and BBLEP
  • Experiment: Dot blot
  • Matrix: Nitrocellulose membrane
  • Conditions: Incubation with Anti His tag antibody (dilution 1:1000) for 1 hour and revelation by Dye Green transilluminator protocol.
  • Objective: Determine the presence of protein from BBLEP (BBa_K2719009) and BBTCD (BBa_K2719005) in protein producer strain E. coli BL21 (DE3)
  • Description: Crude lysate coming from transformed BL21 (DE3) strains and induced with 1 mM IPTG for 5 hours at 37 Celsius degrees were loaded onto nitrocellulose membrane (3 uL) and incubated with Anti His tag antibody coupled with a fluorochrome reporter.
  • The samples were charged in the following order:
    1. Negative control E.coli BL21 (DE3) without transformation (At 3 hours of induction)
    2. Negative control E. coli BL21 (DE3) without transformation (At 5 hours of induction)
    3. BBTCD V2(At 3 hours of induction) [BBa_K2719005]
    4. BBTCD V2(At 5 hours of induction) [BBa_K2719005]
    5. BBLEP V1 (At 3 hours of induction) [BBa_K2719009]
    6. BBLEP V1 (At 5 hours of induction) [BBa_K2719009]
    7. BBLEP V2 (At 3 hours of induction) [BBa_K2719009]
    8. BBLEP V2 (At 5 hours of induction) [BBa_K2719009]
    9. Positive control
    10. Nothing
  • Analysis: After the inconsistent results obtained in the polyacrylamide gels, a Dot Blot was executed. Observation of colored points in positions 3, 5 an 7 gives a positive result in presence of recombinant proteins which contain a histidine tag, in positions 4, 6 and 8 an even more colored point is detected, this confirm that the production of protein increases significantly after 5 hours of induction. On the other hand positions 1 and 2, which accounts for negative control, resolves that E. coli BL21 (DE3) does not produces endogenous native proteins with a high content of histidine tags that could be misunderstood as our protein, this event partially eliminates false positive results. Meanwhile position 9, which account for positive control, shows no coloured point, this effect must be due to the high degree of dilution that we applied to the positive control (1:1000), also there is no visualization of the mark that normally happens when the sample dries, thus we can conclude that our positive control, which was a recombinant protein from E coli, was not in optimal state. This result complicates the final decision about our protein production, for that more dot blots or even western blots must be applied for a better confirmation of results.
Clave C
Figure 8. Western Blot analysis of newly ligated BBLEP [BBa_K2719009].
  • Experiment: Western blot
  • Matrix: Nitrocellulose membrane
  • Conditions: Incubation with Anti His tag antibody (dilution 1:1000) for overnight.
  • Objective: Determine the presence of protein from newly ligated BBLEP (BBa_K2719009) in protein producer strain E. coliBL21 (DE3).
  • Description: CCrude lysate coming from transformed BL21 (DE3) strains and induced with 0.5 mM IPTG for 5 hours at 37 Celsius degrees were loaded onto nitrocellulose membrane (3 uL) and incubated with Anti His tag antibody coupled with a fluorochrome reporter. At left SDS-PAGE 15% gel revealed with Coomassie blue for 30 minutes, at right western blot.
  • The samples were charged in the following order:
    1. Molecular weight ladder Spectra.
    2. BBLEP (At 0 hours of induction)
    3. BBLEP (At 2 hours of induction)
    4. BBLEP (At 4 hours of induction)
    5. BBLEP (At 6 hours of induction)
  • Analysis: