Composite

Part:BBa_K3111202

Designed by: Matas Deveikis   Group: iGEM19_UCL   (2019-09-18)
Revision as of 13:44, 10 October 2019 by Matas deveikis (Talk | contribs) (Protein analysis)


DARPin929_mScarlet_StrepII

This part encodes DARPin929_mScarlet. The use of this part enabled us to study the binding and uptake of DARPin929 by conducting cell culture studies on SK-BR-3 HER2+ cells. The DARPin is flanked by red fluorescent protein mScarlet on the C-terminus which allowed visualisation of binding under confocal microscopy and a StrepII-tag downstream of this fusion, which allows for column-based purification of the expressed protein. It is expressed under a T7 promoter and a strong RBS.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 575
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal AgeI site found at 1147
  • 1000
    COMPATIBLE WITH RFC[1000]


Experimental Results

DNA Analysis and Cloning

Figure 1: Test digest of BBa_K3111202 within a pSB1C3 plasmid; a-c indicate repeats of different colonies containing the same plasmid cut with BamHI and XbaI type II restriction enzymes.

We started by cloning BBa_K3111202 into pSB1C3 vector. In order to investigate whether the ligation was successful, we picked 4 colonies from the plate containing the transformed DΗ5α, grown into 5 mL cultures, miniprepped and conducted a test digest with restriction enzymes BamHI and XbaI.

We expected bands at 2976 bp and 580 bp and those were obtained only for colony B as observed in Figure 1. Thus, the miniprepped plasmid obtained from that colony was then transformed into BL21 (DE3) into order to proceed with 50 mL cultures to express the protein.

Day 1

Different batches of BL21 (DE3) competent cells were transformed with pSB1C3 plasmids containing BBa_K3111202 sequence coding for mScarlet + DARPin fusion protein. Transformed cells were grown in LB agar plates containing chloramphenicol and glucose. Plates were incubated at 37°C overnight.

Day 2

Transformed colonies containing pSB1C3_ BBa_K3111202 were used to prepare overnight starter cultures containing a total of 5 mL LB broth and chloramphenicol (5 μL). Cultures were incubated at 37°C overnight.

Day 3

A 50 mL scale-up cultures was prepared from a single starter culture containing cells carrying pSB1C3 + BBa_K3111202. The culture was incubated at 37°C until it reached an OD of 0.6. Once they reached OD 0.6, the cultures were induced by addition of 400 μΜ IPTG. The cultures were left to grow again overnight at 37 °C.

Day 4

The culture was collected and transferred into a 50 mL falcon tube. It was spun for 10 minutes at 5000 rpm in order to pellet the cells. Then the supernatant was discarded and the pellet frozen at -80 °C.


Protein analysis

In order to observe whether the DARPin929_mScarlet fusion protein was successfully expressed we analysed our cell pellet using SDS PAGE. The pellet obtained from the 50 mL cultures was then resuspended in Tris Buffer Saline at an OD600 of 10. Once resuspended, the sample was cell lysed using sonication. Following sonication, the sample were span to separate the soluble and insoluble fragments form the whole cell lysate. 50 μL from each sample were obtained and stained with Laemmli reagent.

We proceeded on with purification of the soluble fragment using column chromatography containing Strep-Tactin resin. The process involved packing the column, equilibrating the resin and loading the soluble sample. Then a washing step was performed to remove any potential non bound nonspecific proteins. Then we eluted using competitive elution by loading BXT which competed with the mScarlet-DARPin929-StrepII for binding sites with the resin, thus detaching the protein of interest from the column. Finally, we recycled the column ready for future purifications. From each of the samples obtained during the procedure we obtained 50 μL to use for SDS PAGE and western blotting.

Figure 2: a) SDS PAGE gel b) Western Blot with Strep-Tactin of DARPin929_mScarlet purification; M: PageRuler Protein Ladder, S: Soluble cleared lysate, I: Insoluble fragment of lysate, W: Wash, L: Load, E: E1-4: Elutions 1-4.

The DARPin929_mScarlet_StrepII-tag fusion protein has a total size of 45.1 kDa. As it can be observed from Figure 2 (a) and (b), BBa_K3111202 was highly expressed as it can particularly be observed from the thick bands at 45 kDa in lanes S, I, E1 and E2. We also observe bands at around 35 and 25 kDa, but still smaller than the one at 45 kDa. We speculate that this is due to proteolytic cleavage of the fused mScarlet at specific sites generating smaller bands which are still linked to the DARPin929 and StrepII tag. This might interfere with accurate quantification of binding later on since some DARPins will not have a functional reported fused to them.

It is particularly interesting that in Figure 2 (b) the intensity of non-specific bands is much higher compared to the image of the SDS PAGE. However, we concluded that the chemiluminescent reagent used for western blotting has higher binding affinities on smaller proteins fragments thus giving this false higher concentration of the smaller truncated protein.

Binding to HER2 receptor

The next step after protein purification, was to investigate the targeting peptides' binding effectiveness, which we are using on our drug delivery platform along with the T. maritima encapsulin. This involved culturing HER2 overexpressing SK-BR-3 breast adenocarcinoma cells, to which DARPin929 can bind to with nanomolar affinities, and observing binding and internalization using our fluorescent fusion protein mScarlet.

This involved culturing the cancer cells in T75 T-flasks until confluency was reached. After this, the cells were counted in order to passage them at the correct seeding density in the 6 wells plate where DARPin929 binding would be tested. The cells were left in the incubator at 37 °C and at 5% CO2 for 3 days in order to attach to the base of the flask and adapt. This allowed the appropriate morphology of the cells to be reached in order to optimise the final results of the experimentation.

Once the cells have attached, the DARPin929 hybrid protein was introduced to the media at concentration of 1,2 and 3 μM. These 3 different loading concentrations were tested to investigate the optimal concentration for improved binding and incorporation of the DARPin929, which would let us determine the possible required concentration of our novel drug delivery platform. To further incorporate the advice received from Dr. Yin Wu and Michael O’ Neil the cells were incubated at 37 °C for 1 hour to simulate the body temperature. For binding comparison, we also had a replicate of the plate at room temperature ca. 22 °C. Once incubation was completed, the medium was removed and cells washed with PBS to remove any unbound protein. 1 mL of DAPI, a nucleus-specific stain, was then added to help increase contrast and visualisation of the cells. Then plates were then visualised using EVOS inverted microscope.

Figure 3: Confocal microscopy post incubation of 6-well plate at 22 °C for an hour. mScarlet_DARPin929 denotes BBa_K3111201, while DARPin929_mScarlet denotes BBa_K3111202.
Figure 4:Confocal microscopy post incubation of 6-well plate at 37 °C for an hour. mScarlet_DARPin929 denotes BBa_K3111201, while DARPin929_mScarlet denotes BBa_K3111202.

Figure 3 and 4 indicate the images obtained in different wells post-incubation. These 2 experiments were done to optimise the condition of binding. While yet not conclusive, we could observe that fluorescence was observed both on the periphery and within the cells; sign that the DARPin gets internalised. DARPin_mScarlet, even at the lowest concentration showed better binding and uptake compared to mScarlet_DARPin. Nonetheless, while at lower intensity we could observe the same results using the required DARPin hybrid. Furthermore, 37 °C was more optimal for both constructs for binding and uptake and it would resemble the tumour microenvironment more closely . Finally, we concluded that 3 μM would be the best concentration for optimal binding.

In order to validate the binding specificity of BBa_K3111202, we conducted further control mammalian cell culture experiments by applying the optimal concentration of 3 μM of the protein hybrid found throughout our optimisation experiments. These experiments were done to firstly make sure that proteins without fused DARPins would not bind or get uptaken by the cells. This was done by applying rTurboGFP at the same concentration. Secondly to observe the specificity of DARPin and subsequently our drug delivery platform we then applied the DARPin_mScarlet fusions, on Mesenchymal stem cells (MSCs) which do not express HER2 receptors. Additionally, we wanted to observe the fate of encapsulins once applied on cells. Thus we manufactured encapsulins without DARPins (BBa_K3111104) but surface displayed iLOV, a cyan fluorescent protein and applied it at the same concentration as the previous constructs on SK-BR-3 cells. Moreover to better replicate the tumour microenvironment we incubated mScarlet_DARPin929 with SK-BR-3 cells at hypoxic environment of 2% oxygen to observe whether binding was affected.

Figure 5: Confocal microscopy of controls post incubation of 6-well plate at 37 °C and 20% oxygen for an hour; Scalebar: 200 μm. mScarlet_DARPin929 denotes BBa_K3111201, DARPin929_mScarlet denotes BBa_K3111202 and T.maritima + iLOV denotes BBa_K3111104.


From Figure 5, we observed no fluorescence thus no binding or uptake of both rTurboGFP and Thermotoga maritima encapsulin fused with iLOV. Thus, we confirm that in the absence of DARPins fusion proteins cannot bind or get internalised. Moreover, we observe no red fluorescence on the MSCs indicating the specificity of DARPin only for HER2 receptors, thus confirming the potential for targeted delivery platforms by using DARPin.

However, to obtain greater accuracy of binding percentage we proceeded with flow cytometry. Thus, we dislodged the cells from their growth wells using EDTA, while not affecting the binding of the DARPin and the HER2 receptor, and then used the sample for flow cytometry. The equipment used has 4 lasers emitting different light wavelength. In our particular case we were observing the results obtained from the ones specifically detecting fluorescence within the mScarlet and CFP region.

Figure 6: Flow cytometry of 6-well plate post incubation at 37 °C and 20% oxygen for an hour; MSCs: mesenchymal stem cells. mScarlet_DARPin929 denotes BBa_K3111201, DARPin929_mScarlet denotes BBa_K3111202 and T.maritima + iLOV denotes BBa_K3111104.

The flow cytometry data allowed precise quantification of the population of cells that has the DARPin929 bound on the surface. In the plots of Figure 6, whatever is on the right-hand side of the red line shows binding and correspondingly whatever is on the left, no binding. Based on Figure 6 (a) & (d) we observe that DARPin929_mScarlet has better binding efficiency with 29.8% compared to mScarlet_DARPin929 with only 19.6%. Clearly it can be noticed, that there is no unspecific binding when no DARPin is present as in the cases of rTurboGFP and T. maritima encapsulin fused with iLOV as well as when the DARPin fusion proteins have no receptor to bind to as in the case of Figure 6 (b) and (e).

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