Team:CIDEB-UANL Mexico/Project

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Web Site for Igem project of CIDEB

Project

Abstract

Nowadays due to the contamination caused by pollutants such as heavy metals, it is important the implementation of simple and complete detection methods. This project aims to create a biosensor that may detect the presence of heavy metals in water. In order to construct the biosensor, a genetic circuit was built into E. coli. The circuit represents a model, which works with Arabinose. It is a semi-quantitative biosensor. The circuit has 3 parts: High concentration, Low concentration and Stand-by state. Each part of the circuit has a different response: when there is a high concentration of Arabinose the bacteria shows a yellow fluorescent color; when the concentration is low it uses a sensitivity tunner that increases the response from the same amount of Arabinose, which makes the bacteria to appear in a red fluorescence; and when there is no Arabinose in the sample, the bacteria shows a green fluorescence.

General Idea

The heavy metals which are found in the crust of the Earth and they bring us both benefits and potential damage for humanity. The various damages that they can cause are reflected especially in our health and in the environment. For this reason we are searching for an easy way to determine the presence of heavy metals in the environment by this manner we can stop harmful situations for our ambience now and in the future.
That is why we decide that it would be useful to create a biosensor with bacteria to measure heavy metals concentration in samples. To test the biosensor we will use Arabinose. The reason of using Arabinose instead of heavy metals is for safety reasons because work with such materials will be a high risk to our health. Thus we first construct the model with Arabinose to see if it really works and if it does, then other biosensor which could detect the concentration of heavy metals could be constructed.

Circuit

genes

 

Stand by

The first part is called Stand-by. It is in a turned on all the time and it indicates that there is no presence of Arabinose in the sample. Thus we need a constitutive promoter that is always on and in this case we have the part R0053 that corresponds to the promoter p22-cll which position in the DNA plates sent from the MIT is 1-6M. We have to observe a response to know if the promoter is always working. In this case, a reporter will be used. This reporter is a GFP protein that emits green color fluorescence. The following part is a RBS followed by a reporter. In this case, we found  a biobrick, K081012 with a location in plates 3-12M, that includes a RBS, a reporter, and a terminator, all together in a vector. What we have to do is to join the constitutive promoter 1-6M with the biobricks composed of 3 parts, the 3-12M.

High Concentration

In the High concentration section, we use the pBAD promoter which works with the AraC and acts as a repressor: when there is no Arabinose it represses the DNA transcription (..?) and when Arabinose is present it keeps working the pBAD. When Arabinose enters into the bacteria it joins with the AraC and these 2 mlecules joined are the ones that will be quantified. This promoter is found in a biobrick, I0500, joined with an AraC part. This biobrick has a location 1-14N in the plates. The following part is a RBS, but it has to be compatible with the circuit. We found 3 RBS compatible and we chose the B0034 which is the most recommended of the 3 in the  Registry of Standard Biological Parts (http://partsregistry.org/Main_Page) and It has a location 1-2M in the plates. In this section, Also we need a response that indicates the presence of the Arabinose in high concentration, and this response will be through the YFP reporter. This part is the E0032 with a location 1-6E. Then we need another RBS and another part that will repress the section of Low concentration because Low and High concentration work with the same promoter, as we can see in the first image of the whole circuit. The repressor will act when the response of the amount of Arabinose measured is bigger than the response of the low concentration. In this way only the part of High concentration will keep on. In this part we use a biobrick which has the 3 parts: a RBS, a repressor, and a terminator. This is the part p0152 with a location 1-10E. This is the last part of the High concentration section.

Low Concentration

The parts that compose the Low concentration section are: the promoter pBAD I0500 (1-14N) which is the same of the High concentration, the part I746352 (2-12G) which has a RBS with a phiR73 and it is joined with the p0153 (1-10G). The amount of Arabinose is measured by the pBAD and then the response is increased by the sensitivity tuner. The phiR73 (that is in the 2-12G) receives the amount measured by the pBAD and it sends the signal to the pLL wich is a promoter I746365 (2-14A) which is joined with the part p0151 (1-10C). The p0151 has a RBS and the cI that multiplies the response received and it sends it to the part I12006 (2-11J). Also it has a terminator. Then the part 2-11J is the promoter that receives the response increased from the cI. It is joined with the part K081014 (3-12O) which has a RBS, the RFP that will give the red fluorescence response and a double terminator. The promoter receives the response increased and with this final response the red color appears. In this final part is where the high concentration’s repressor acts. The part 1-10G has a repressor which turns off the stand-by section of the circuit.

List of parts

In the following table we can see a list of the parts used in the Project. This list includes the parts already explained and also the vectors used in the project.

Parts

Número

Plate

Well

Plasmid

Resistance

pConst+RBS+araC

I0500

1

14N

pSB2K3

K/K

RBS (elowitz)

B0034

1

2M

pSB1A2

A/A

Promotor p22 cll

R0053

1

6M

pSB1A2

A/A

YFP

E0032

1

6E

pSB1A2

A/A

rbs + cl434 + doble terminador

P0152

1

10E

pSB1A2

A/A

rbs + cL+ doble terminador

P0151

1

10C

pSB1A2

A/A

rbs + c22 + terminador

p0153

1

10G

pSB1A2

A/A

RBS 1 + CDS

I746352

2

12G

pSB1A2

A/A

Promoto prm

I12006

2

11J

pSB2K3

K/K

pLL promoter

I746365

2

14A

pSB1A2

A/A

rbs + GFP + terminador

K081012

3

12M

pSB1AK3

AK/AK

rbs + mRFP1 + terminador

K081014

3

12O

pSB1AK3

AK/AK

pSB1T3

pSB1T3

1

7A

T

pSB1C3

pSB1C3

1

3A

C

pSB1AT3

pSB1AT3

1

13A

AT

pSB1K3

pSB1K3

1

5A

K

pSB1A3

pSB1A3

1

1G

AT

 

In order to build the circuit we followed some standard protocols. In a general way we will explain how to build the circuit.

    1. Localize the DNAs that will be used, in the plates sent from the MIT and hydrate them.
    2. Transform the DNAs into the E. Colli bacteria.
    3. Culture the bacteria into tubes and store some as reserves.
    4. The other tubes are used to do MiniPreparation of plasmid DNA in order to extract DNA from the bacteria and check their quality by running them in an agarose gel.
    5. Cut the parts that are inside of the vector with restriction enzymes type II. This enzymes cut in a specific place.

     

     

     

Latest News

March 25, 2012

Headline

Back in the early nineties (yeah, i'm old) i was tripping ballz on acid one night with some friends.

class="date"> March 26, 2012

Headline II

At some point one of us got the brilliant idea to test out our clairvoyant abilities under the influence and we set up a nifty experiment where one of us would take a random card out of a playing deck and would try to 'send' the card telepathically to one of the others. When me and my best friend at the time were up, I ended up calling the exact card three times in a row.

March 27, 2012

Headline III

Pretty much left the room speechless. The weird thing is, when we talked about it later on we both sort of knew beforehand we could do this and couldn't stop smiling during the whole ordeal.

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