Team:Kyoto/Project

From 2012.igem.org

Revision as of 06:48, 26 September 2012 by Niina (Talk | contribs)

Header Kyoto not home.jpg

  • Home
  • Project
  • Method And Material
  • Notebook
  • Consideration
  • Team
  • SiteMap

Contents

Introduction of Flower Fairy E.coli

Have you ever seen flower fairies? Do you have any idea about how they bloom flowers? Probably no (some of you might come across them in your childhood), because they are imaginary creatures only existing in fairy tales. What if we can live with flower fairies? Their lovely talent for blooming flowers would be profitable for us, including application to agriculture. That’s why we set our project to realize with Synthetic Biology, Flower Fairy E.coli!

Our goal is to produce E.coli which can bloom flowers themselves as Flower Fairy. To make it possible, we focused on FT protein, the identity of Florigen.

Kyoto Wiki intro 1.jpg

There are four issues on the road to embody Flower Fairy as fairy tales. It is unclear even whether E.coli can produce FT because FT is usually produced in an eukaryotic plant cell. After producted, FT have to go over fourth wall, inner and outer membranes, a cell wall of Plant cells and a cell membrane of Plant. Even though these all steps are done successfully, No one knows whether FT protein transcribed in E.coli can activate Flowering of Plant.

FT protein can blooming flower

FT, or FLOWER LOCUS T, is a protein composed of 175 amino acids. In plants, FT protein is produced in leaves and transported to a shoot apex. And then work as a transcription factor and activates floral meristem identity genes, thereby blooming flowers. FT protein can make flowers bloom at low dose. Because FT is normally produced in a eukaryotic cell, we were not sure whether or not E. coli can synthesize, and FT produced by E. coli works successfully in a cell of thale cress (Arabidopsis thaliana). So, confirmation of the functionality of FT is needed.

Wiki intro 2.jpg

  • Kyoto Introduction.png
  • Kyoto Experiment.png
  • Kyoto Discussion.png
  • Kyoto Reference.png

Flower Fairy E.coli

KyotoBSL1.png

Abstract

FLOWERING LOCUS T protein(Florigen, FT protein) is made in the leaves of plants and leads flower formation. Our projecrt,"Flower Fairy E.coli",is to produce florigen by E.coli and introduce it into plant cells, and to make flowers bloom.

We iGEM Kyoto divided a hurdle into three sections, Expression, Secretion, Penetration and Activation. We established secretion system and penetration system of cell membranes (TAT and R9 system), and confirmed whether our E.coli could overcome each steps and had created Flower Fairy E.coli.

Introduction

Motive for Flower Fairy E.coli

Flower fairies live only in fairy tales, but it would be very lovely if they actually existed. Not only they would entertain us, but also their talent for blooming flowers at will would be greatly profitable for us in many aspects, such as agriculture.So we set our project to realize them in real world by synthetic biology.
In order to obtain our goal, it is essential to utilize materials which can control and trigger flowering freely. And then, we noticed that a plant hormone, Florigen, can satisfy above goal.
Florigen is a plant hormone which was suggested and named seventy years ago. Even though various studies about plant hormone has been done, little is known about florigen. At last, Florigen was discovered 2007 and since then, many studies have gradually revealed its function. We would tell you some of the studies below.

Our Fantastic tool "Florigen"

Florigen is a 20kDa of small protein composed of 175 amino acids which are encoded by the FLOWERING LOCUS T (FT) gene. The expression of the FT gene is promoted inside the leaf phloem companion cells by several specific conditions such as long photoperiods, vermalisation, age and so on. After transcripted, FT mRNA is translated into a protein and then transported to the shoot apex thorough sieve tubes. In the shoot apex, FT is combined with FD, which works as a transcriptional factor, and activates floral meristem identity genes such as APETALA 1 (AP1), FRUITFUL (FUL), and LEAFY (LFY). These genes play a significant role in the transformation of the form of a shoot meristem, converting it into a flower bud.
Considering the effect of FT on flowering as mentioned above, we can say that E. coli with a capacity of producing FT are able to bloom flowers, as if they were flower fairies!

Experiment&Result

We have to go through four steps for purpose of obtaining our goal-Flowering Fairy E.coli-
The four steps are composed of EXPRESSION,SECRETION, PENETRATION, and ACTIVATION

1.EXPRESSION

KyotoStep1.png

On the first step; EXPRESSION, E.coli produce florigen inside of the cells.
When we got FT gene, we had a difficulty in constructing iGEM parts. The problem is that FT sequence had two cleavage sites of iGEM restriction enzymes. In order to eliminate cleavage sites of iGEM restriction enzymes, we performed Inverse PCR of plasmids with two kinds of primer which have mutation.
As a result, we could get mutated plasmids, which are not cleaved by iGEM restriction enzymes. In this way, we made FT gene available.

Previous to experiment, whether FT gene is expressed correctly in E.coli had arouse criticism in our team. This is because, under natural environment, FT gene is expressed and functions in plant cells, which are eukaryote. However, E.coli is prokaryote, so no one knows that FT protein which E.coli made could function.
We transformed E.coli and made them express our FT gene. In order to confirm the expression of FT protein, we performed western blotting and checked the place of the FT protein band.


1. Pre-experiment

Following figure shows the result of western blotting of [http://partsregistry.org/Part:BBa_I746915 BBa_I746915].
Unfortunately, we used inappropriate molecular marker and could'nt confirm the molecular weights of samples.

Western-GFPgenerator.png

Lane1 : IPTG 0mM, sample 10µL
Lane2 : IPTG 1mM, sample 10µL
Lane3 : IPTG 0mM, sample 5µL
Lane4 : IPTG 1mM, sample 5µL
Lane5 : IPTG 0mM, sample 2µL
Lane6 : IPTG 1mM, sample 2µL












2.SECRETION

KyotoStep2.png

On the second step; SECRETION, E.coli secrete florigen outside of the cells
Even though our E.coli can produce FT protein, there remains a big issue: how they can transport proteins to the outside of the cells? To make it possible, we made Tat cassette and kil protein inducer. Our Secretion team made new protein secretion system.







↓Secretion


Even though our fairies can produce FT protein, there remains a big issue: how they can transport proteins to the outside of the cells? To make it possible, we made Tat cassette and kil protein inducer. This cassette lets E.coli carry proteins with torA signal via Tat protein transportation pathway from cytoplasm to periplasm and Kil protein encourage proteins to move from periplasm to surroundings. We made this protein secretion system and visualized and confirmed its functioning by using GFP.


We need secretion system without cell-death

<p>In previous iGEM competition, some kinds of parts and devices for protein translocation were already developed. One of the most widely used parts is lysis cassette(このパーツのページのリンク). This part causes cell lysis and, as a result, makes E.coli scatter materials it includes. This style is, unfortunately, not suitable for our project because of the possibility of accidental all-death. Generally speaking, the concentration of E.coli on flower is not high so that it can’t be ignored that the possibility of occurring all cell-death. Once all our Fairies disappear, flower wouldn’t bloom. In addition to that, lysising E.coli is NOT CUTE.

We tried to seek for a ideal secretion system, which is not harmful and dangerous for both of our fairies and other livings. Finally, We focused on Twin argenine translocation pathway (Tat pathway) of E.coli. It is not pathogenic and carries various kinds of proteins with torA signal(Tat班古い方のレビュー)

What is TAT Secretion pathway

The Twin Arginate Translocation pathway(TAT) is secretion system E.coli originally have. This system can carry proteins that have torA signal anino acid sequences at N terminal. TatA, TatB, TatC and TatD compose Tat complex on inner membrane. Tat complex recognizes torA signal peptide and then it transports protein (with torA) from cytoplasm to periplasm. In addition, protein that has passed through TAT pathway cut off the torA signal. Proteins which are secreted by this system have no tag that obstruct the activation of the protein.

Our Tat cassette and kil inducer

TatABCD composes pathway from cytoplasm to periplasm. Kil makes holes on outer membrane and we expect that protein goes through this holes. Needless to say, function of outer membrane as membrane is essential for E.coli to survive. In other words, overexpression of Kil causes cell death. In this reason, we must find suitable amount of expression.

Detail of Our Secretion System

Our wonderful secretion system is constructed by tatABCD, Kil and another gene. Another gene is PspA (phage-shock protein A) gene. E.coli has it originally and this gene is expressed when their inner membrane is dameged. PspA meintains H+ concentration gradient between periplasm and cytoplasm and membrane potential.

Our secretion system makes many holes on inner and outer membranes. In other words, E.coli which has our secretion system is under the membrane stress conditions. But by introducing pspA into our Flower Fairy E.coli, the E.coli come to be able to maintain the vitality, though they have many holes on the membrane.



Method

Making a prepared specimen for the observation with confocal microscope
  • PFA 500μL
  • MilliQ 2100μL
  • Hoechst 1μL
  • Slide glass
  1. Gather fungus body by centrifugal separation.
  2. Add 500μL of the PFA to a microtube containing fungus body and resuspend pellet.
  3. Keep shading it for 10minutes at 4℃.
  4. Centrifuge it for 1minute at 16,000×g and discard the supernatant.
  5. Add 1000μL of MilliQ and 1μL of hoechst to the microtube, resuspend pellet and incubate bacterial suspension for 30minutes or more.
  6. Centrifuge bacterial suspension for 1minute at 16,000×g and discard the supernatant.
  7. Add 1000μL of MilliQ, resuspend pellet, centrifuge bacterial suspension and discard the supernatant again.
  8. Add 100μL of MilliQ and resuspend pellet.
  9. Pipette bacterial suspension on a slide glass and dry it.
  10. Preserve it with shading it.

Construction

Tat secretion cassette with constitutive promoter(BBa_K797004)

This cassette allow E.coli to secrete proteins with torA signal. Wild type Tat protein secretion system is too week so that Kyoto 2012 construct Tat cassette to reinforce the ability of transportation of Tat system. This parts include tatA,B,C protein coding region and pspA (phage shock protein A). Tat A,B,C protein is the main component of Tat complex where proteins with torA signal go through and pspA can encourage protein secretion via Tat system. Kyoto 2012 suggest iGEMers with this new way of secretion and provide them with this cassette regulated by constitutive promoter.

We checked the sequence of tatABCD(BBa_K797000) and the sequence of pspA (BBa_K797001) individually, and then, we made TAT construction composed of constitutive promoter(BBa_J23107), tatABCD (BBa_K797000),pspA(BBa_K797001) and double terminator (BBa_B0015). This TAT secretion cassette is too long device to sequence, so that we performed electrophoresis of this cassette and confirmed the length of our parts.

Considering that the sequences of tatABCD and pspA are correct,and the length of TAT secretion casssette is correct, we declare that this construction of TAT secretion cassette has been completed.</p>

3.PENETRATION

KyotoStep3.png

On the third step; PENETRATION, florigen is absorbed into plant cells.

To realize flower fairy E. coli, FT secreted by E. coli must be absorbed in plant cells. From early stage, we sought various ways to penetrate FT protein into plants, but each way has serious problems. For example, girdling can be used, we think. But, it is difficult to inject FT protein exactly in sieve tube.

In such situation, we found the way of penetration into cells using polyarginine, a type of Cell Penetrating Peptide (CPP). The type is R9 peptide, which comprises a sequence conjugated to nine arginine residues (fig.1).


fig.1 image of R9 peptide (powered by winmostar V3.808d, MOPAC2012)

Polyarginine peptide is thought to act on a cell membrane and cause a specific form of endocytosis, that is, macropinocytosis. Macropinocytosis is not caused by an invagination of the cell membrane, but by the growth on the actin mambrane from protrusions into vesicles called macropinosomes, and no receptors are necessary for the process (fig.2). It is reported that plants use CPP to transport biomolecules such as proteins inside the cell, in spite of their cell walls.
Then, we determined to perform penetration by using FT protein with R9 coding region.

fig.2 how R9 peptide function on cell membrane














2. R9 peptide fusion GFP

After the 4h of IPTG induction, we noticed that E.coli expressing R9::GFP were growing poorly.
Culture1.png

Moreover, we couldn't get any bands of R9::GFP, as shown in the following figure.

Western-R9-GFP2.png

Lane1 : Molecular marker
Lane2 : GFP([http://partsregistry.org/Part:BBa_I746915 BBa_I746915]) IPTG 0mM, sample 10µL
Lane3 : GFP([http://partsregistry.org/Part:BBa_I746915 BBa_I746915]) IPTG 1mM, sample 10µL
Lane4 : R9::GFP IPTG 0mM, sample 10µL
Lane5 : R9::GFP IPTG 1mM, sample 10µL






















3. Separating R9 peptide and GFP

When R9 and GFP were conected, they didn't work normally. By way of experiment, we separated R9::GFP into two segments and soaked plant cells into a sollution of them.

The control on the left was soaked in only GFP, and on the right-hand side the sample was soaked in GFP and R9. These two pictures show the action of R9 peptide. R9 peptide kept GFP in or around plant cells. This figure strongly suggests that R9 peptide works successfully and penetrates cell membrane with GFP.


















4. Activation

KyotoStep4.png

Finaly, we verified whether FT normally worked in plant cells. Probably R9 penetrates cell membranes with proteins, so we injectd a sollution of FT and R9 into plant cells derived from Arabidopsis thaliana. FT protein activates various other proteins. We checked the change of activity of them by RT-PCR.

This is the result of RT-PCR. The left is control. It is

4. Verification of FT Function



















Discussion

Future Works

We noticed only flowering and florigen in this time but there are many many other plant hormones. We made translocation pathway from E.coli into plant cells, so we will be able to introduce plant hormones into plant cells if E.coli can make them. It means we can control plant growth in any stage through genetically engineered E.coli. In the future that is not so far, we will be able to meddle in plants' growth――germinating, elongation, flowering, and fructification. We human will finally accomplish a technology that control plants perfectly.

Moreover, R9 peptide functions not only plant cell. R9 peptide works on animal cell similarly. It means that we found a pathway into any kinds of cells. R9 peptide tag enables us to introduce proteins into any cells, so we will be able to controll all living cells using this technology.

References

[1]Microsugar Chang et al. (2005)"Cellular internalization of fluorescent proteins via arginine-rich intracellular

delivery peptide in plant cells" Plant Cell Physiol, 46(3), 482–488
[2]Paula Teper-Bamnolker and Alon Samach1 (2005) "The flowering integrator FT regulates SEPALLATA3 and FRUITFULL accumulation in Arabidopsis leaves" The Plant Cell, 17, 2661–2675
[3]Philip A. Wigge et al. "Integration of spatial and temporal information during floral induction in Arabidopsis [4]Sara Trabulo et al.(2010). "Cell-penetrating peptides—mechanisms of cellular uptake and generation of delivery systems" Pharmaceuticals, 3, 961-993
[5]Unnamalai N, Kang BG, Lee. (2004) "Cationic oligopeptide-mediated delivery of dsRNA for post-transcriptional gene silencing in plant cells." FEBS Lett 21;566(1-3):307-10.
[6]Chang M, Chou JC, Lee HJ.(2005) "Cellular internalization of fluorescent proteins via arginine-rich intracellular delivery peptide in plant cells." Plant Cell Physiol;46(3):482-8.
Wigge PA, Kim MC, Jaeger KE, Busch W, Schmid M, Lohmann JU, Weigel D.(2005)"Integration of spatial and temporal information during floral induction in Arabidopsis." Science.12;309(5737):1056-9. ↓Secretion
[7]Tracy Palmer and Ben C. Berks "The twin-arginine translocation (Tat) protein export pathway"
[8]J. H. Choi. S. Y. Lee "Secretory and extracellular production of recombinant proteins using Escherichia coli"
[9]G. Miksch · E. Fiedler · P. Dobrowolski · K. Friehs "The kil gene of the ColE1 plasmid of Escherichia coli controlled by a growth-phase-dependent promoter mediates the secretion of a heterologous periplasmic protein during the stationary phase"
[10]Brad A. Seibel* and Patrick J. Walsh "Trimethylamine oxide accumulation in marine animals: relationship to acylglycerol storage"


Golden Gate Assembly

Introduction

BioBrick is useful for us because we can look for required BioBrick parts from its registory and recombine genes easily. If we want to introduce many parts into one plasmid, however, we have to repeat the process; restrict enzyme digestion and ligation. It takes us too much time and sometimes we lose enough time for other experiments.

We want to reduce the time required for the recombination of genes and get enough time for verification of the expression and the effect of genes.

Golden Gate Assembly is the one of the ways to make it possible.

What's Golden Gate Assembly

Golden Gate Assembly is a method which enables us introduce plural gene segments into one plasmid all at once. We don't need to digest gene by restrict enzyme before ligation because restrict enzyme digestion and ligation are compleated by just one PCR.

Golden Gate Assembly use the feature of restrict enzyme "BsaI".
BsaI recognizes the sequence "GGTCTC" and cut DNA like the figure. And BsaI activity is independent of the sequences of the downstream of the recognition site.

Results

Discussion

References