Team:NTU-Singapore/Project/Prototype/Image

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Imaging Device



The Imaging device is also one of our featured parts.

As we have elaborated earlier in the Prototype Design section, the device consists of mainly pTet regulated expression of IFP & HO-1, which in turn generate a unique fluorescence signal in the infrared spectrum!


We are extremely pleased to report that we have successfully converted this novel reporter protein into a standard Biobrick! Let us now see how exactly the device works.

Abstract

As part of the imaging capability we want for our system, we have eschewed traditional reporter proteins like GFP or YFP and have identified a novel reporter protein, infrared fluorescent protein (IFP). A recent work by Xiaokun et. al. (Tsien Lab, UCSD) has shown successful mammalian expression of infrared fluorescent protein engineered from a bacterial phytochrome. Xiaokun et. al. have also expressed the infrared fluorescent protein in E. coli strain TOP10.


IFP is preferred for our system over other FPs such as GFP or YFP because it has a unique excitation and emission maxima. The wavelength range of IFP fits so well with the wavelength range of typical in vivo optical imaging in deep tissues of animals i.e. between 650 and 900 nm for excitation and emission maxima respectively. This is because this range of wavelength minimizes the absorbance by haemoglobin, water and lipids, as well as light-scattering.

Therefore, IFP is particularly suitable for our ideal system as we desire to locate the atherosclerotic plaque site without invasive procedures.


Background

Our pLaqUe Out! system must be capable of highlighting the atherosclerotic plaque site upon detection by the preceding sensing mechanism of nitric oxide sensing promoter (pNO). The first thing that came to our mind was the variety of known fluorescent proteins (FPs) such as GFP, RFP, YFP, CFP. However, since our ultimate environment for our pLaqUe Out! system is in vivo, we envisioned an ideal system that can express a novel reporter protein with properties suitable for in vivo optical imaging. IFP was chosen as a potential candidate.


The gene encoding IFP used in our expression system is essentially the gene for IFP1.4. Xiaokun et. al. have shown that IFP1.4 was obtained from the gene encoding IFP1.0 by saturation, random mutagenesis, and DNA shuffling; and it was shown to be about four times brighter than IFP1.0, with a relative brightness of 383%.


NTUifpspec.png



Fig 1. - Normalized excitation (blue) and emission (red) spectra for Infrared Fluorescent Protein


Overall, IFP has an excitation and emission maxima of 684 nm & 708 nm respectively; compare this with the excitation and emission maxima for other fluorescent proteins, which have not exceeded 598 and 655 nm respectively.


Mechanism

Infrared fluorescent protein is a monomeric protein engineered from a bacterial phytochrome of the species Deinococcus radiodurans.


This bacteriophytochrome incorporates biliverdin IXα (BV) as the chromophore. Biliverdin IXα is in fact a natural product of heme catabolism by the enzyme heme oxygenase-1 (HO-1). BV is essential because in a mouse experiment conducted by Xiaokun et. al., BV has been shown to increase the infrared fluorescence to a maximal fivefold 1 hour after BV injection in the mouse with exogenously added BV.

In a phone call made to Dr. Xiaokun Shu, we have also been told that BV helps to stabilize the infrared fluorescent protein. Hence, it is essential that we incorporate HO-1 into our system to generate biliverdin IXα.


Construct Design

As you recall, our ideal system is designed to be in a T-helper cell chassis. However, for the purpose of expression of the infrared fluorescent protein, we have used E. coli strain K12 as our bacterial expression system. In order to realize the expression system, we incorporate parts i.e. the genes encoding infrared fluorescent protein and heme oxygenase-1 into the device.


The Imaging device is designed to function this way, working only in low [NO] conditions (i.e. in atherosclerotic plaque sites) :

NTUifpprosys.png


After TetR repression stops at plaque site with low [NO], both HO-1 & IFP are expressed. The HO-1 catalyzes the conversion of haem to biliverdin, which then binds to IFP to allow generation of infrared signal. Once infrared signalling has begun, we can begin imaging for the plaque site from without, and establish the location of the plaque site.


Of course, at this stage we also foresee numerous other medical/non-medical uses for the IFP protein!


Characteristic Equations

Transcription of IFP / HO-1

First, we can define the stoichiometric ration of IFP to HO-1 transcribed.

NTUifpstoi.png


Next, we establish the deterministic repression-regulated transcription rate of IFP & HO-1.

NTUifptransc.png

Where Vmax is max transcription rate & Dm is the degradation rate of mRNA.

Again, bracketed term generates the fraction of pTet not bound with TetR i.e. actively promoting pTet sites.


Translation of IFP / HO-1

Deterministic first order ODE is used again to represent the translation of IFP / HO-1 protein. Same eqn with appropriate term and constants changed.

NTUifptransl.png

Where Ktl is the translation rate of mRNA & Dp is the degradation rate of IFP / H0-1 protein.


Infrared signal production

Before the infrared signal can be produced, HO-1 must first convert haem to biliverdin.

NTUifpbil.png


And then finally we can determine an equation for rate of infrared signal, (assuming that intensity of infrared signal is directly proportional with the amount of bound-IFP-Biliverdin in the system).

NTUifpsig.png based on the ratio of bound / activated to total [IFP] available: NTUifpact.png


Modelling & Simulation

We make the following assumptions:

  1. Biological systems of transcription and translation are assumed to be linear and time-invariant.
  2. Concentration of the haem is considered to be non-limiting.
  3. There is no time lag between expression & activity.
  4. Constant Degradation rates for mRNA as well as protein.
  5. Intensity of infrared signal is directly proportional to [IFP-BV] complex.


The following is our Sensing device represented as a Simulink system. Please click on it for a larger view.

NTUifpsys.png


Device Construction

Researchers at Tsien’s Lab graciously provided us the gene sequence of IFP1.4 optimized for E. coli, and we synthesize the gene encoding IFP1.4 with GeneArt in accordance with the standard stated by the Registry of Standard Biological Parts.

Part: BBa_I15008 from the Registry of Standard Biological Parts contains the HO-1 gene sequence of cyanobacteria, Synechocystis and therefore is extracted directly for our needs.


In order to achieve the final construct as described in the device construction, the following Biobricks have been successfully constructed:

  1. IFP (synthesized from GeneArt) click here for GeneArt sequencing results
  2. RBS-HO1
  3. IFP-T
  4. RBS-IFP
  5. RBS-HO1-T
  6. RBS-IFP-T
  7. RBS-HO1-RBS-IFP-T
  8. pTet-RBS-HO1-T
  9. J23119-RBS-HO1-T
  10. J23119-RBS-IFP-T
  11. J23119-RBS-HO1-T-J23119-RBS-IFP-T
  12. J23119-R-IFP-T in KAN vector


Another approach in ensuring our proteins are expressed is by co-transformation of ampicillin-resistant plasmid of J23119-RBS-HO1-T and kanamycin-resistant plasmid of J23119-RBS-IFP-T into the cell.


Our parts listed above have been verified by confirming the DNA fragments size of the agarose gel electrophoresis of the double digestion and PCR products. 1stBASE has sequenced the part J23119-RBS-IFP-T we have constructed and the results are positive! The summary of the sequencing results is as follows:


NTU119-1.png

NTU119-2.png


J23119 Sequencing

Due to the limit of the Sequencer, the first 10 base pairs of the promoter cannot be verified.


NTUrbs.png


RBS 5 (Part: BBa_B0034)

100% verified!


NTUifpterm.png


Terminator (Part: BBa_B0015)

100% sequence identity.


IFP verification

NTUifpver.png NTUifpver2.png


We had sent our IFP gene sequence in the final construct for verification and it came back indicating 100% success. This means that our entire construct has an almost perfect sequence identity, and true enough, it WORKS!


Device Characterization

Two approaches are performed in the laboratory to determine the successful expression of infrared fluorescent protein (IFP) or heme oxygenase-1 (HO-1) and thus the functionality of our imaging device. SDS-PAGE is conducted to verify the correct protein size of IFP and HO-1 that we have set out to express.


Imaging experiments with the appropriate optical instruments for the detection of the infrared fluorescence emission of our constructs are also conducted repeatedly. The excitation and emission maxima of IFP are 684 and 708 nm respectively; thus, our experimental setup must be equipped with the appropriate optical components that are of this wavelength range.


Our positive control for all detection of infrared fluorescence emission in the following optical imaging experiments is the cell culture of sample from Tsien’s Lab. In a Materials Transfer Agreement with Tsien’s Lab, they have provided us the DNA sample.

We extracted out the DNA sample from the paper spot according to the protocol of plasmid resuspension from iGEM paper spots. The DNA resuspension was transformed into E. coli strain K12. Upon inoculation, we successfully obtained the green yellowish cell culture, indicating the presence of biliverdin in the cell culture.


NTUtsiencell.jpg




Cell cultures

(samples of Tsien’s Lab)

These were incubated overnight at 37oC upon induction with L-arabinose 20% are green yellowish due to biliverdin.


Fluorescence Microscopy

Our first attempt in imaging our cell culture for the construct J23119-RBS-HO1-RBS-IFP-T is through the Axiovert 200 (Zeiss) fluorescence microscope.


Cell culture was inoculated overnight for 16 hours. Prior to the imaging experiment, we re-inoculated the cell culture and allowed the growth for four hours.

The only drawback of the fluorescence microscope was that the filter was of the excitation range of 575-625 nm and emission range of 660-710 nm [far red/cy5]. We further hypothesized that we did not manage to image the infrared fluorescence due to the limitation of appropriate filter for the fluorescence microscope.


As most of the microscopes are equipped with excitation and emission filters of wavelengths that are not in our desired range, we switched our alternatives to self-assembled optical experiment setup. With this in mind, we had collaborated with Prof. Lee Kijoon on the optical imaging.


Optical Experiment Setup

Ocean Optics USB-4000 Portable Spectrometer

A 660 nm Melles Griot 56ICS254/HS plus 56IMA022 laser is used as the light source. The 660 nm laser source fits almost perfectly with the ideal excitation maximum at 684 nm.


We shine the 660 nm laser onto our four-hour re-inoculated cell culture. The Ocean Optics USB-4000 Portable Spectrometer detects any signal emitted by the cell culture with an optical fiber connected to the spectrometer. The optical fiber is pointed and directed towards the cell culture for signal receiving.


The optical fiber is sensitive to any signal, including the excitation laser source. For this reason, we included SEMROCK dichroic mirror placed at 45-degree angle of incidence to isolate the excitation light source from the data acquisition. The emission spectrum for our construct is generated with Ocean Optics SpectraSuite software.


NTUifpsetup.jpg



Ocean Optics USB-4000 Portable Spectrometer

Our self-assembled optical experimental setup initiated by Prof. Lee Kijoon for infrared emission detection.


In our attempts to optimize the experimental setup, we conducted repeated experiments with the positive control (sample of Tsien’s Lab) to generate the maximum signal intensity.

Our optical experimental setup proved to be working well when we managed to optimize our readings to a maximum peak of intensity (counts) of 1500 for a 16-hour cell culture incubated at 37°C (fluoresence emission spectrum attached as below) :


NTUifptsienres.jpg


Fluorescence emission spectrum of 16-hour Tsien Lab cell culture

Note excitation near the peak excitation wavelength at 660 nm. This fluorescence emission spectrum was obtained with electric dark correction.


Nikon Eclipse TS100 Inverted Microscope

Instead of emission spectrum, cell culture live imaging is performed as well.


The previous optical experiment setup is modified with the inclusion of Nikon Eclipse TS100 Inverted Microscope coupled to DS-Fi1 camera to image the cells. The software NIS Elements D is for image capturing from the microscope.

Another modification we have made to this experimental setup is the replacement of the SEMROCK dichroic mirror with an emission filter, to enable this microscope to function as a fluorescence microscope. The emission filter is the SEMROCK single bandpass filter with the centre wavelength at 710 nm with average transmission of 93% over a range of 40 nm; perfectly fits our expected emission range, with maximum at 708 nm.


NTUifpsetup2.jpg

Our self-assembled optical experiment setup with for infrared protein


We performed the cell culture imaging with the excitation light source of 660 nm laser diode and the SEMROCK single bandpass filter which serves as our emission filter. This modification was done to make Nikon Eclipse TS100 Inverted Microscope functions almost as a fluorescence microscope for our imaging purposes.


Literature / References

Please proceed here to view our full list of references.



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