Team:Stanford-Brown/SB16 BioSensor Chromoproteins


Stanford-Brown 2016

Chromoproteins team member Taylor introduces the chromoproteins subproject

Why Study Temperature?

In planetary exploration, monitoring temperature changes in the atmosphere is important for predicting weather patterns and atmospheric stability. At different heights above the planet’s surface, the temperature can vary drastically. The way that the temperature changes from hotter to cooler than back to hotter temperatures can be used to predict how weather and wind patterns will move across that region. This is helpful to know in planetary exploration because it can help predict the weather that various rovers or exploration outposts would have to deal with without relying on expensive satellite equipment. Additionally, the vertical temperature profile of a certain region of a planet’s atmosphere can be used to predict how easily a payload will fall through the atmosphere and land on the planet’s surface. [1]

On Earth, vertical temperature profiles can be obtained using electronic temperature sensors mounted on weather balloons. These balloons go up to different heights in the atmosphere and relay real-time measurements of the atmospheric temperatures. While these electronics are easy to obtain and replace if they are broken on Earth, in the context of planetary exploration, they are irreplaceable and unreliable because it would take years to send replacements if they break and are impossible to fix without also sending replacement parts along the mission. Thus, a biological temperature sensor was developed in order to address these concerns. This biological temperature sensor can be expressed in a small culture of E.coli and be easily replaced simply by maintaining a culture of that particular bacteria.

In order to build a biological temperature sensor, we used chromogenic proteins from the DNA2.0 paintbox and from the iGEM registry. Chromogenic proteins or chromoproteins are colored proteins that have been extracted from a variety of organisms such as the sea anemone, Actinia equine [2] or have been synthetically produced (as was the case for the chromoproteins from DNA2.0). Like all proteins, chromogenic proteins are sensitive to heat; however, their sensitivity to heat is coupled with a visible color loss or change. Our research has shown that different chromoproteins respond to different temperatures by either losing their color or changing to a different color. These differential responses to temperature allowed us to build a biological temperature sensor.

The basic structure of a chromogenic protein consists of a large beta barrel and a chromophore which is supported by the beta barrel. The chromophore interacts with light and gives the protein its distinctive color. Additionally, the shape of the beta barrel is supported by water molecules that interact with the side chains of the amino acids that the beta barrel comprises of. These water molecules are essential for the chromogenic protein to maintain its structure. In response to heat, our hypothesis is that these water molecules are released from the beta barrel, thus allowing the barrel to collapse and the chromophore to no longer be supported enough to produce color [3]. Because planetary exploration requires a sensor that can function in a variety of environments, we tested our chromogenic proteins in a sealed environment and in an open air environment. The following sections details those experiments.

Closed System

Figure 1: This is all of the chromoproteins at a variety of different temperatures. As the temperature gets higher they all loose their color at different temperatures.
To test our chromoproteins in a closed system that did not allow them to interact with anything in the air, we spun down 5 mL cultures of each of our chromoproteins and added 30 µL of the pellet cells to a PCR tube along with 1 µL of 0.165 M EDTA. We then heated these PCR tubes for 5 min at a starting temperature of 40 °C, removed them from the thermal cycler, took a picture, then returned them to the thermal cycler for 5 more minutes at a temperature that was 5 °C higher than the previous. We repeated this process until we reached 100 °C. As can be seen in Figure 1, groups of chromoproteins lose their color at specific temperatures. Additionally, Cupid Pink and Donner Magenta change from pink to purple at 70 °C and 80 °C respectively.
Interestingly, we also observed that if there were certain cultures that were not showing color on a particular day, the heat treatments as described above were able to cause the color we would have initially expected to appear (Figure 2, 3, and 4).

Figure 2: As can be seen above, the bottom row of five PCR tubes containing 30 µL of the cell pellet does not show any color. The chromoproteins in the bottom row are from DNA2.0: Virginia Violet (left), Maccabee Purple, Seraphina Pink, Tinsel Purple, and Donner Magenta.
Figure 3: After these previously colorless cell pellets have been treated at 55 °C for 30 min, 60 °C for 30 min, and 60 °C for 30 min, color can be observed. This color then proceeds to disappear again as the temperature continues to increase.
Figure 4: This time, the color does not return after heat treatments.
After the cell lysate heat tests, we moved towards testing the cell lysate in an exposed air environment. This was done based on the idea that the color change we were seeing was dependent on the interaction of water molecules with the barrel of the chromoproteins. Therefore, we hypothesized that in the exposed air system, the water molecules would not be trapped with the chromoproteins and we might see color change occur sooner. To test this we set up an apparatus that would heat a glass petri dish evenly and allow us to take a video of the cell lysate as it was being heated up as shown in Figure 5.
Figure 5: Setup for conducting temperature testing on chromoproteins.
Twelve chromoproteins that were expressing good color in our cultures were selected for this assay and can be seen in Figure 6.
After this, the glass petri dish was removed from heat and 20 µL of DI water were added to each of the chromoproteins. This was done on the theory that the chromoproteins had not denatured, but rather had lost their color because all of the water molecules which were supporting the structure of their barrel had been driven out by the heat. As can be seen in the image below, some of the chromoproteins regained color when water was added, but this color is different from the starting color. This could be due to the fact that the heating caused the chromoprotein structure to destabilize to a lower energy structure which causes it to have a different color when the water is added to support the barrel.
Figure 6: 30 µL droplets of cell lysate taken from spun down 5 mL cultures of cells expressing chromoproteins were placed on a glass petri dish. Order of Chromoproteins:
Top row: Vixen Purple
Second row: asPink, tsPurple, AE Blue
Third row: Tinsel Purple, Cupid Pink, Prancer Purple, Dreidel Teal
Fourth row: spisPink, scOrange, Blitzen Blue
Fifth row: Donner Magenta
Figure 7: The glass petri dish above was heated to 85 °C which caused all of the chromoproteins to lose their color as is seen below.
Figure 8: Chromoproteins from figure 5 after being brought back to room temperature.
In order to investigate the role that water molecules play in the color change we were observing in our chromoproteins in response to heat, we used a lyophiliser to remove the water from the chromoproteins without heating them. A lyophiliser is a device that operates at sub freezing temperatures under a vacuum which causes water to move directly from the solid phase to the vapor phase. This vapor is then pumped out of the system. Below is an image of two chromoproteins (Prancer Purple and Scrooge Orange) inside the lyophiliser chamber (CP-17). After an hour in the lyophiliser, the filter paper was removed from the chamber and photographd (CP-15). [Caption: Two replicates of Prancer Purple (top) and Scrooge Orange (bottom) are shown after 1 hour of lyophilization]. Water was then added to to the right column of the filter paper which caused the color to return (CP-16) as can be seen by comparing the top and bottom rows of this image. These results show that while color loss does occur when water is removed from the system, it does not have the same effect as heating the sample. In the heat testing experiments, Prancer Purple changed irreversibly to pink when heated whereas in the lyophilization experiment, it regains its color fully. This supports our hypothesis that the color changing in response to heat is dependent on both water loss and a structural change of the protein itself due to heat.

Open System

To delve further into the question of what exactly is happening when these chromoproteins are heated, we used Gibson Assembly to clone the gene coding for the iGEM biobrick AE Blue and the 12 DNA2.0 chromoproteins into pSB1C3. We also added a FLAG, lumio and 6x histidine tag in order be able to extract the expressed protein using nickel column purification. The lumio tag is a specific six amino acid sequence that binds to the Lumio Green Detection ReagentTM [4] which allows the fusion of the lumio tag and the chromoprotein to be detected on an SDS-Page Gel without having to run a staining protocol. The FLAG tag allows for anything after its sequence to be cleaved off of the protein when the extracted protein is incubated with enterokinase [5]. This was done in case the lumio or histidine tag interfered with the chromoprotein structure.
Additionally, a cellulose binding domain was added to each of the chromoproteins. This cellulose binding domain was from the BioBrick BBa_K1321366 which also has a GFP fused to it. For the purposes of our experiments, we isolated the cellulose binding domain from this part using PCR. The cellulose binding domain sequence was isolated from Cellulomonas fimi and has been shown to bind irreversibly to cellulose (cite). In order to ensure that the addition of this larger protein did not interfere with the structure of the chromoproteins, we extracted both the chromoprotein without the cellulose binding domain and with the domain and ran the same heat testing experiments. (INSERT PICTURE CP4: THIS IS THE GIBSON ASSEMBLY DIAGRAM)

The extracted protein was concentrated using microfiltration tubes then allowed to dry on cellulose sheets which had wax wells printed on them. These cellulose sheets with the dried chromoprotein were then placed in a preheated oven and the temperature was increased at five minute intervals until a temperature change was observed.

Prototyping a biological thermometer

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Testing the prototype

In collaboration with the Stanford High Altitude Ballooning Team, we field tested our AE Blue-CBD fusion protein at a high altitude. This AE Blue-CBD fusion protein was extracted from the cells that were expressing it and purified using dialysis to ensure that only the fusion protein remained for this experiment. It is important to note that nothing living was sent into the environment to be tested and that our sample was recovered. No environmental contamination occurred as a result of this experiment.
Using our extracted fusion protein, we plated 20 µL drops onto a cellulose sheet that had had wax wells printed onto it (CP-19). Every well seen in this image is from the same chromoprotein. This chromoprotein is the same as was seen earlier in the NASA logo heat test. Because there are higher levels of UV radiation in the atmosphere than are in our lab environment, we used UV-opaque and UV-transparent glass to cover the top and bottom row of the grid. The center row was left exposed to the elements as a control. These were then mounted onto the payload of the Stanford High Altitude Balloon Team’s balloon (CP-20-22) and were readied for launch! A GoPro was mounted on the payload as well in order to catch inflight data. In this image, taken at 10000 feet from the surface, the chromoproteins can be seen starting to change their color from blue to purple (CP-23). A tracking device placed on the balloon allowed for the payload to be recovered once the balloon had burst. This image was taken of the fusion proteins immediately after payload recovery (CP-18).

As can be seen, the once-blue fusion proteins are now purple. This purple color was persistent for six hours before eventually returning back to blue which is unlike previous heat tests in that usually the blue color comes back rather quickly. This could have occurred for a variety of reasons. The simplest explanation is that the exposure time to heat stress was much longer in the field test than in the lab. Usually our heat test experiments last anywhere from 5 to 30 minutes of constant heat exposure. As a result, it might be easier for the chromoproteins to regain their structure afterwards. Because all three of the levels of UV-exposure that were tested had the same degree of color change, it seems unlikely that the exposure to UV was responsible for the prolonged color change we witnessed. However, it is possible that even the UV-resistant glasses we used were not enough to block out trace amounts of UV and that these trace amounts of UV destabilized the structure of the chromoproteins in such a way that the prolonged color change occurred. Above is a video commemorating the event.
References
1) Schlatter, Thomas W. "Atmospheric Composition and Vertical Structure." National Oceanic and Atmospheric Administration (2009): n. pag. Web.
2) Shkrob, Maria A., Yurii G. Yanushevich, Dmitriy M. Chudakov, Nadya G. Gurskaya, Yulii A. Labas, Sergey Y. Poponov, Nikolay N. Mudrik, Sergey Lukyanov, and Konstantin A. Lukyanov. "Far-red Fluorescent Proteins Evolved from a Blue Chromoprotein from Actinia Equina." Biochem. J. Biochemical Journal 392.3 (2005): 649-54. Web.
3) Langan, P.s., D.w. Close, L. Coates, R.c. Rocha, K. Ghosh, C. Kiss, G. Waldo, J. Freyer, A. Kovalevsky, and A.r.m. Bradbury. "Corrigendum to “Evolution and Characterization of a New Reversibly Photoswitching Chromogenic Protein, Dathail” [J. Mol. Biol., 428, (2016), 1776–89]." Journal of Molecular Biology 428.20 (2016): 4244. Web.
4) "Lumio Green Detection Kit - Thermo Fisher Scientific."; N.p., n.d. Web. 2 Oct. 2016. 5) "FLAG Tag Peptide|Versatile Fusion Tag|CAS# 98849-88-8." FLAG Tag Peptide|Versatile Fusion Tag|CAS# 98849-88-8. N.p., n.d. Web. 02 Oct. 2016.