Team:NTU-Singapore/Project/Prototype/Sense

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Sensing Device



The Sensing device will serve as the trigger for our system to start/stop its activity. As such, it is one of the most important constructs that we are working on.


As we have elaborated earlier in the Prototype Design section, the device consists of mainly a a nitric oxide sensitive promoter that allows for transcription of TetR in high [NO], and is deactivated in low [NO].


Let us now see how exactly the device works.

Abstract

Nitric-oxide (NO) sensing promoter (pNO) is a sigma-54 promoter that is regulated by transcription factor NorR, a member of the prokaryotic EBP (enhancer binding protein) family.

NorR is a NO responsive transcription factor which is activated by interaction with NO. Upon activation, NorR will convert the inactive promoter bound sigma-54 RNA polymerase complex to a transcriptionally competent complex in pNO to promote the downstream transcription of the gene.

Thus, expression of the gene downstream of pNO can be regulated by input of NO.


In our project to tackle atherosclerosis, we seek to locate the presence of the plaque via the detection of NO concentration in the blood vessels. It has been shown that the cholesterol-induced atherosclerosis would usually impair the NO synthesizing ability of the vascular endothelial cells, and thereby leads to a decrease of NO concentration in the plaque region.

By equipping our host cells (preferably T-helper cells; however in our experiment, we have used E.coli) with pNO, our system Plaque Out! will sense the decrease in NO concentration in the plaque region.


This will trigger an inverter module to:

  1. secrete cholesterol esterase (CHE) to digest the plaque
  2. produce infra-red signals to highlight the plaque’s location and
  3. release NO to dilate the vessel after digestion of plaque.


Hence, pNO would serve as the main switch for our system Plaque Out!.


Background

Based on the above described function, we have decided to include the entire NorR-NorV/W intergenic region (in E.coli genome) as our pNO promoter sequence. NorV/W genes encode for flavorubredoxin and an associated flavoprotein which would reduce NO to nitrous oxide.


NTUnorr.png


These NorR and NorVW genes can be found in most proteobacteria, especially E.coli. And they are part of an important mechanism that allows bacteria to survive in anaerobic conditions as well as during nitrosative stress. In these cases, NorR protein serves as a NO-responsive transcriptional activator that regulates expression of the norVW genes.


Mechanism

In the absence of NO, the N-terminal domain of transcription factor NorR typically represses the ATPase activity of NorR.

It is only when NO binds to the ferrous iron center of NorR, it would stimulate ATP hydrolysis by NorR. The ATPase activity of NorR is boosted by binding of NorR to the three enhancer binding sites located upstream in the pNO.

The energy released by ATP hydrolysis enables NorR to activate pNO bound sigma-54 RNA polymerase complex (or RNA polymerase holoenzyme), thus initiating the transcription process.


Sequence

Using NCBI’s reference sequence NC_000913.2, the 186 bp NorR-NorVW intergenic region sequence is obtained using E.coli (strain: K-12; sub-strain: MG1655) as the search organism. The sequence is found in genome position 2830311 – 2830496. The NorR-NorVW intergenic sequence is as follows (5’ - 3’):


TCTTTGCCTCACTGTCAATTTGACTATAGATATTGTCATATCGACCATTTGATTGATAGTCATTTTGACT
ACTCATTAATGGGCATAATTTTATTTATAGAGTAAAAACAATCAGATAAAAAACTGGCACGCAATCTGCA
ATTAGCAAGACATCTTTTTAGAACACGCTGAATAAATTGAGGTTGC


The highlighted sequence is the sigma-54 promoter. The reason why we had included the entire intergenic region as our pNO promoter sequence is that there are 3 enhancer binding sites upstream of the sigma-54 promoter. These enhancer binding sites allow the transcription factor, NorR to bind to the DNA, thus leading to a localized increase in NorR concentration.

As such, the increase in localized NorR concentration facilitates the NorR to make contact with the sigma 54 – RNA polymerase.


Construct Design

In our system, Plaque Out!, we wish to regulate the production of TetR protein with respect to the concentration of NO.

The TetR protein would in turn regulate the production of Cholesterol esterase (CHE), Haem Oxyenase (HO-1), and Infra-red protein (IFP). Thus, our NO sensing construct is as follows:


NTUsysnorr.png


Characteristic Equations

Ligand binding :

Using Hill equation to express the fraction of NO-bound NorR, we assume independent and non-cooperative binding of NO (i.e. Hill coefficient is taken to be 1).

Thus, fraction of NO-bound NorR is described as follows:

NTUnorrfrac.png


Since the dissociation constant Kd1 can be illustrated as:

NTUnorrdiss.png


Fraction of NO-bound NorR can be expressed as a function of available NO concentration, [NO]free

NTUnorrtrans.png


Transcription of TetR

Deterministic first order differential equation (ODE) is used to depict the NO-regulated transcription of TetR.

NTUtetrtranscript.png

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


Translation of TetR

Deterministic first order ODE is used again to represent the translation of TetR protein.

NTUtetrtransl.png

Where Ktl is the translation rate of mRNA & Dp is the degradation rate of TetR protein.


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 transcription factor, NorR in E.coli is assumed to be in excess and constant. Hence, [NorR] is not taken into account in our model
  3. There is no time lag for NO diffusion from ext. environment into the cell
  4. Constant Degradation rates for mRNA as well as protein

Instead of modelling with TetR, we are using GFP as our output. This is part of our effort in trying to predict the wetlab characterization of pNO.


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

NTUpnosys.png


Device Construction

pNO-B0034-GFP-B0015 (pSB1A2)

To study the strength of pNO, we have decided to use pNO for the expression of green fluorescence protein (GFP).

pNO was first directly synthesized by GENEARTTM, one of the sponsors for iGEM. After digesting it with EcoRI and SpeI, it was ligated to B0034-GFP-B0015 as follows:


NTUpnotestcon.png


The test construct, pNO-B0034-GFP-B0015 was characterized using fluorescence detecting microplate reader, Synergy HT from BioTek, U.S.A.


J23119-B0034-NorR-B0015 (pSB1A2) / (pSB3K2)

Though the transcription factor, NorR has been endogenously expressed in E.coli, our desired chassis is the macrophage. Thus, a NorR producing construct has to be created in order to equip the macrophage with the capability to detect NO.

In addition, to reduce competitive binding of NorR between the endogenous NorR-NorVW intergenic region (in E.coli) and our pNO construct, large scale production of NorR is necessary.


NorR sequence was first extracted from E.coli chromosomal DNA (K-12, DH10B) via polymerase chain reaction (PCR). Next, the linearized dsDNA was converted to a biobrick part by adding prefix and suffix using PCR.


NTUnorrcon.png


Lastly, the biobrick NorR was digested with relevant restriction enzymes (EcoRI / XbaI / SpeI / PstI) in order to be ligated to form the stated construct.


Device Characterization

NorR characterization

Primer synthesis

Using NCBI’s reference sequence NC_000913.2 and E.coli (strain: K-12; substrain: MG1655) as search organism, the DNA sequence for NorR was obtained. The 1515 bp NorR resides at genome position 2828797 – 2830311, and the sequence is as follows:

ATGAGTTTTTCCGTTGATGTGCTGGCGAATATCGCCATCGAATTGCAGCGTGGGATTGGTCACCAGGATC
GTTTTCAGCGCCTGATCACCACGCTACGTCAGGTGCTGGAGTGCGATGCGTCTGCGTTGCTACGTTACGA
TTCGCGGCAGTTTATTCCGCTTGCCATCGACGGTCTGGCAAAGGATGTACTCGGTAGACGCTTTGCGCTG
GAAGGGCATCCACGGCTGGAAGCGATTGCCCGCGCCGGGGATGTGGTGCGCTTTCCCGCAGACAGCGAAT
TGCCCGATCCCTATGACGGTTTGATTCCTGGGCAGGAGAGTCTGAAGGTTCACGCCTGCGTTGGTCTGCC
ATTGTTTGCCGGGCAAAACCTGATCGGCGCACTGACGCTCGACGGGATGCAGCCCGATCAGTTCGATGTT
TTCAGCGACGAAGAGCTACGGCTGATTGCTGCGCTGGCGGCGGGAGCGTTAAGCAATGCGTTGCTGATTG
AACAACTGGAAAGCCAGAATATGCTGCCAGGCGATGCCACGCCGTTTGAAGCGGTGAAACAGACGCAGAT
GATTGGCTTGTCCCCTGGCATGACGCAACTGAAAAAAGAGATTGAGATTGTGGCGGCGTCCGATCTCAAC
GTCCTGATCAGCGGTGAGACTGGAACCGGTAAGGAGCTGGTGGCGAAAGCGATTCATGAAGCCTCGCCAC
GGGCGGTGAATCCGCTGGTCTATCTCAACTGTGCTGCACTGCCGGAAAGTGTGGCGGAAAGTGAGTTGTT
CGGGCATGTGAAAGGAGCGTTTACTGGCGCTATCAGTAATCGCAGCGGGAAGTTTGAAATGGCGGATAAC
GGCACGCTGTTTCTGGATGAGATCGGCGAGTTGTCGTTGGCATTGCAGGCCAAGCTGCTGAGGGTGTTGC
AGTATGGCGATATTCAGCGCGTTGGCGATGACCGTTGTTTGCGGGTCGATGTGCGCGTGCTGGCGGCGAC
TAACCGCGATTTACGCGAAGAGGTGCTGGCAGGGCGATTCCGCGCCGATTTGTTTCATCGCCTGAGCGTG
TTTCCACTTTCGGTGCCGCCGCTGCGTGAGCGGGGCGATGATGTCATTCTGCTGGCGGGGTATTTCTGCG
AGCAGTGTCGTTTGCGGCAGGGGCTCTCCCGCGTGGTATTAAGTGCCGGAGCGCGAAATTTACTGCAACA
CTACAGTTTTCCGGGAAACGTGCGCGAACTGGAACATGCTATTCATCGGGCGGTAGTTCTGGCGAGAGCC
ACCCGCAGCGGCGATGAAGTGATTCTTGAGGCGCAACATTTTGCTTTTCCTGAGGTGACGTTGCCGACGC
CAGAAGTGGCGGCGGTGCCCGTTGTTAAGCAAAACCTGCGTGAAGCGACAGAAGCGTTCCAGCGTGAAAC
TATTCGTCAGGCACTGGCACAAAATCATCACAACTGGGCTGCCTGCGCGCGGATGCTGGAAACCGACGTC
GCCAACCTGCATCGGCTGGCGAAACGTCTGGGATTGAAGGATTAA


To ensure that the endogenous NorR sequence can be directly converted into a biobrick part without any modification, the sequence was checked with Webcutter 2.0 (http://rna.lundberg.gu.se/cutter2/) for any presence of EcoRI / NotI / XbaI / SpeI / PstI restriction sites. Since none of these restriction sites was found in the endogenouse NorR genome, direct PCR extraction can be performed. PCR primers were designed using NCBI’s PrimerBlast.


The primer sequences for NorR Extraction :

Forward Primer (27 bases): 5’-TTAATCCTTCAATCCCAGACGTTTCGC-3’

Reverse Primer (26 bases):5’- ATGAGTTTTTCCGTTGATGTGCTGGC-3’


Since NorR sequence is on the anti-sense strand of E.coli genome, the biobrick prefix has to be added to the reverse primer, rather than forward primer, and vice-versa.

The primer sequences for Biobrick conversion :

Addition of Preffix to Reverse primer – Forward Primer (50 bases) : 5’-GTT TCT TCG AAT TCG CGG CCG CTT CTA GAG ATGAGTTTTTCCGTTGATGT-3’

Addition of Suffix to Forward primer – Reverse Primer (50 bases) : 5’-GTT TCT TCC TGC AGC GGC CGC TAC TAG TA TTAATCCTTCAATCCCAGACG-3’

The oligonucleotides were synthesized by one of our team’s sponsor, 1st Base Holdings, Singapore.


Ethanol Precipitation of E.coli Chromosomal DNA

Invitrogen’s TOP10 cells were first grown for 16 hours in 5 ml LB media at 37 deg C, 250 rpm before being centrifuge at 4000 rpm for 10 mins. The supernatant was decanted, and the cells were lysed using QIAGEN miniprep kit’s P1, P2 and N3 buffers. Since QIAquick spin columns can only immobilized DNA strands up to 10kb, hence, it was not used for the extraction of E.coli chromosomal DNA. Instead, ethanol precipitation was performed.

Procedures of ethanol precipitation:

  1. 1/10 vol of 3M Sodium Acetate (pH 5.2) was added to the supernatant containing E.coli DNA, P1, P2 and N3 buffers.
  2. 3 vol. of ice-cold absolute ethanol (stored at -20 deg C) was then added to the mixture.
  3. Incubate the sample on ice for 30 mins before spinning the sample at 13,000 rpm for 15 min.
  4. Decant the supernatant, and add 1 ml of 70 % ethanol was added to wash any salts present.
  5. Centrifuge for another 10 min at 13,000 rpm before decanting the supernatant. Air-dry the sample for 15 min.
  6. Add de-ionized water or Tris-HCl buffer (pH 7.5) to re-suspend the DNA precipitate.


Literature / References

Please proceed here to view our full list of references.



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