Team:UANL Mty-Mexico/project/DNA-Program-Supression

From 2014.igem.org

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<p><a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#Description"><font color="blue">Description</font></a> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#Objective"><font color="blue">Objective</font></a> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#Explanation"><font color="blue">Explanation</font></a> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#Bases"><font color="blue">Bases</font></a> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#Conclusion"><font color="blue">Conclusion</font></a><br><br><b>Synthetic Rally</b><br>
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<p align="justify"><b><font color="black" size="5px">DNA Specific Deletion </font></b>
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<br><a name="Description"></a><b>Description</b> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#"><font color="blue">Return</font></a></p>
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</p>
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<p align="justify">One of our activities for human practices consisted in creating a rally that would teach synthetic biology to students from 9th grade. We wanted to show something that was, in some cases, difficult to explain. The plan was to teach them some basic things about molecular biology that would help them understand each of the bases of the rally, including genes and biobricks, and how they could use these to design a circuit for a project. We decided that each of the bases would represent different parts of this year’s circuit, explaining how each of the parts work. For example, base one represented the Promoter; base two, the Riboswitch, and so on. </p>
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<br>
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<p><br><a name="Objective"></a><b>Objective</b> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#"><font color="blue">Return</font></a></p>
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<p>The DNA, just like a lot of other molecules, suffers from deletion; be it to repair, insert a fragment, recombine or as a defense strategy. There are multiple causes for this, but the one that interest us is due to enzymatic action, among which we find exonucleases, restriction enzymes, and other molecules that will be revised shortly.
-
<p align="justify">The objective was mainly to help students understand that genetically modified machines work, basically, like a normal machine. We wanted to explain each of the parts that formed our circuit, how each of them worked according to its function, and how every part is necessary for the circuit to work. But all of these are hard to understand when you can’t see the relation between both types of machines. When you tell people who know nothing about genetic engineering that you are building a genetic machine, they have no idea of what to imagine; of how that could work. So we tried to show it to the students in the simplest way. </p>
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<p/>
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<p><br><a name="Explanation"></a><b>Explanation</b> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#"><font color="blue">Return</font></a></p>
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<p align="justify">The first thing we did when arriving to the school, was to organize all of the materials needed for each one of the bases. While we were doing this, three of our team members went to one of the classrooms that the school had lent us, and explained some basic things about DNA and genes to the students. They explained it in a simple manner, just so the students could understand that these were needed to form the biobricks, and these last ones to form a circuit. But that part was explained later on.</p>
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<p align="justify"><b><font color="black" size="5px"> Endonucleases </font></b></p>
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<p align="justify">After finishing the presentation, the 40 students from the first classroom went outside, to the first base. We divided them in two groups, and gave the first twenty of them small ribands of different colors, to divide them in teams for them to compete. The other twenty were kept waiting, while some of us asked them questions for a survey about transgenic food.</p>
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<p align="justify">We handed out one small card with the drawing of our circuit to each one of the teams from the first group; a card that we would mark, whenever they finished one of the bases, with the points they had earned. The one who came out first place would receive 4 points; second place would receive 3, and third and fourth place would receive 2. We had one person in charge of writing down the points in each card to keep track of who was winning. After explaining all of this, the rally began. </p>
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<p> Nucleases are enzymes with the ability to fragment DNA through phosphodiester bond ruptures. When the cutting site is in the 5’ or 3' end, it’s called an exonuclease; on the other hand, if it's inside the DNA strand, it´s called an endonuclease. Among endonucleases, restriction enzymes, which can recognize specific DNA sequences (Sui-Hong et al, 2010), have been of utmost interest in the manipulation of DNA, from polymorphism identification (molecular diagnosis) to the construction of new DNA sequences (genetic engineering).
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<p align="justify">The first thing we did at each one of the bases was to identify the name; say if it was the promoter, the terminator, the RBS… and we then gave an explanation of what it was without explaining completely how it worked. At the end of the activity, we would state the relationship between what they had played and the way the actual part of the circuit functioned. Then the one in charged would yell, and they would change bases. When the first group passed to the second base, the group that was kept waiting entered the first base. </p>
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</p>
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<p><br><a name="Bases"></a><b>Bases</b> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#"><font color="blue">Return</font></a></p>
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<p align="justify">''BASE 1: PROMOTER'' - The activity was called Streets and Avenues, but the game was changed a little bit. All the teams would be aligned, forming a square, and one person from each team would be standing at each corner. That person would have to find his/her match; someone with the same color inside the square. For example, maybe someone form team Blue, inside the square, would be Yellow. The Yellow person outside would have to find that Blue person before the others found their match, with the path changing just as it does in the common “Streets and Avenues“ game. </p>
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<p align="justify">
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<p align="justify">''How does this relate to the promoter?'' The promoter needs to find the one thing that starts it, for the circuit to start too. </p>
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According to their characteristics, they are divided into four types, from I to IV.  
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<p align="justify">''BASE 2: RIBOSWITCH'' - This activity was called Dragons. Each team had to form a line and hold hands, being really careful not to let go. The person in the very front would be the head, and the last one, with a bandana hanging on their clothes, would be the tail. The objective was that the head would have to take the other team’s bandana, being careful that they didn’t lose theirs. The moment the team lost theirs, they would lose and have to stop right where they were. </p>
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Moreover, each of them has their own specific applications. The most studied and  
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<p align="justify">''How does this relate to the Riboswitch?'' The riboswitch turns the circuit on and off, depending on several conditions. In this game, the team was “On“ while they still had their bandana; they were turned “Off“ when they lost it. </p>
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used are type II restriction enzymes, because they recognize a specific palindromic
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<p align="justify">''BASE 3: PROTEIN CODING SEQUENCES'' - This base was one of the hardest to fulfill. We designed a “labyrinth“ of conditions that each team would have to pass through. They would have to dress up with objects in some boxes, and depending on what they wore, they would move through the squares. The one who found the perfect combination would win.
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sequence and they generally inside this sequence. On the other hand, type I
 +
enzymes cut approximately at a 1000 bp distance, while type III cuts at a 24-26 bp
 +
distance. Finally, type IV has low specificity and only cuts methylated DNA
 +
(Roberts et al, 2003).  
 +
</p>
 +
<p align="justify">
 +
Among type 2 restriction enzymes, there are those who can cut just one strand,
 +
which is called nicking. They are generally named with an N prefix, for example,
 +
N.bstSEI (Roberts et al, 2003).
 +
</p>
 +
<p align="justify">
 +
Restriction enzymes can recognize symmetric and asymmetric sequences
 +
(Pingoud et al, 2001). One way of classifying those that recognize asymmetric
 +
sequences is in 5 classes according to their characteristics (Sui-Hong et al, 2010),
 +
which are shown in the table.
 +
</p>
 +
 
 +
<p align="justify">
 +
Type II restriction enzymes have come to be used so much in the molecular
 +
biology field, that commercially they are the most exploited. But even among them,  
 +
there can be advantages and disadvantages. For example, if an enzyme has a  
 +
recognition site of a few nucleotides, it is better suited for diagnostic trials than for
 +
genetic engineering. For this reason the use and research of new enzymes has
 +
begun, along with the de novo design of others (Sui-Hong et al, 2010).
 +
</p>
 +
 
 +
<p align="justify">
 +
The mode of action of type II restrictions enzymes can be imitated with artificially
 +
designed enzymes. For example, the union of proteins and/or peptides that
 +
recognize certain sequences with others that have the capacity of excising DNA.  
 +
</p>
 +
 
 +
<p align="justify">
 +
In our project we plan to use endonucleases, together with polypeptides that
 +
recognize longer sequences than restriction enzymes, in order to increase the
 +
specificity.
 +
</p>
 +
 
 +
<p align="justify"><b><font color="black" size="5px"> Zinc- Finger Nucleases (ZFN)  </font></b></p>
 +
 
 +
<p align="justify">
 +
Zinc-finger nucleases are agents that have been used for DNA modification by
 +
means of the fusion of a zinc finger, designed or preexistent, with the active
 +
domain of the Fokl enzyme; this Phusion molecule is called “Zinc Finger Nuclease”
 +
or ZFN (Kim et al, 1996). They have been used in different organisms, from
 +
animals to plants (Miller et al, 2007) with the purpose of modifying them, for
 +
example, through an integration of complete genes (Moehle et al, 2007).  
 +
</p>
 +
 
 +
<p align="justify">
 +
An important aspect to be considered before using this technology, is that in order
 +
to cut it needs to dimerize with the functional domain of another Fokl (Bitinaite,
 +
1998). That’s why it´s required to design adjacent ZFNs whose Fokl domains
 +
interact in an intermediate site. There are also other advantages, like its high
 +
specificity due to the ability to design binding sites of over 18 bp (Urnov et al, 2005)
 +
and because they normally only cut once they have bound to the specific site
 +
(Vanamee et al, 2001). On the other hand, when the ZFP has not joined its specific
 +
site, Fokl remains as a monomer even to the 15 µM (Kaczorowski et al, 1989),
 +
making the appearance of cuts in non-specific sites more difficult.  
 +
</p>
 +
 
 +
<p align="justify">
 +
However, it is necessary to mention that some possible disadvantages exist, ones
 +
that may surface in spite of good planning. One of them is that the effectiveness of
 +
a ZFN in one species doesn’t it will function in others (--). Another downside may
 +
be that the designed ZFNs work, but once they homodimerize they cut sites they
 +
weren’t designed for, becoming toxic for the cell (Beumer et al, 2006). Due to this,  
 +
the designing of new ZFN requires experimentation to assure its correct
 +
functioning.  
 +
</p>
 +
 
 +
<p align="justify">
 +
In our project ZFNs will be used, and to avoid the problems mentioned above, we  
 +
will use ZFNs that have been previously tested in E. coli. This is because our aim
 +
is to prove the utility of said protein in our project.  
 +
</p>
 +
 
 +
<p align="justify"><b><font color="black" size="5px"> CRISPR Cas9 (Adaptative immune system) </font></b></p>
 +
 
 +
<p align="justify">
 +
Characteristics:  
 +
<br>1. System guided by RNA
 +
<br>2. Method that controls genetic expression
 +
<br>3. Cas9 endonuclease
 +
</p>
 +
<p align="justify">
</p>
</p>
-
<p align="justify">''How does this relate to the protein coding sequence?'' Protein coding sequences, as stated in the Registry of Standard Biological Parts, encode the amino acid sequence of one particular protein. In the game there was only one perfect combination, one combination that would make you win; and you had to find it. </p>
 
-
<p align="justify">“BASE 4: RBS“ - This activity was somewhat simple, yet fun anyway. We would have two people holding a piece of fabric next to two other people, also holding a piece of fabric, and they would be passing along a small ball, in several different ways, to a small box on the other side of the field. For example, the first time it would be walking and passing the ball however they could. The second time, they would have to throw it as higher as possible, and running. The third time would be running backwards, and the fourth would be jumping on one foot. Only one team got to the fifth time, and they had to do it backwards and jumping on one foot. At the end, the team with the greatest amount of balls inside their box, won.</p>
 
-
<p align="justify">''How does this relate to the RBS?'' The RBS is the place where the ribosomes bind and start the process of translation. The small balls represent the ribosome trying to get to the RBS, the box. </p>
 
-
<p align="justify">“BASE 5: REPORTER“ - The activity was quite simple, and at the same time complicated. We had to build 4 boxes with wires, batteries and a light bulb; only two wires would be connected to the batteries and could turn on the light bulb. There were 20 wires, and the first team who found the combination and turn on the light, would win.</p>
 
-
<p align="justify">''How does this relate to the Reporter?'' The light would turn on whenever the right wires were connected; it acted like a signal. That’s what the reporter does; when the condition is fulfilled, it sends a signal to let you know, just like the light.</p>
 
-
<p align="justify">“BASE 6: TERMINATOR“ - The last activity was just like a game named Doctor, except that we used balloons instead. Each team would have to get in a closed circle, but instead of holding hands directly, they would hold a large balloon. Then they would have to tangle, without letting go of the balloons, as much as possible. The “doctor“ would then have to undo their “knot“, without breaking the circle. The first ones to blow up or let go of their balloon would lose. </p>
 
-
<p align="justify">''How does this relate to the terminator?“ The terminator causes transcription to stop; it sort of “breaks it off“. In the game, “transcription“ stopped whenever the person blow up or let go of the balloon. </p>
 
-
<p><br><a name="Conclusion"></a><b>Conclusion</b> - <a href="https://2013hs.igem.org/Team:CIDEB-UANL_Mexico/HP-SchoolDiffusion-SyntheticRally#"><font color="blue">Return</font></a></p>
 
-
<p align="justify">At the end of the rally, we gave an explanation of the whole circuit; how every part was connected to make it function. We answered questions, we took a picture, and we prized the winner team with a box of cookies. Some of them asked if we had a page on Facebook, and others just thanked us for coming. </p>
 
-
<p align="justify">One of the girls who was helping us with the rally, was not from the team. She was from second semester, and was really interested in iGEM when she found out about it, so she asked if she could come and help. She was of great support; taking pictures and helping us organize everything. At the end it all worked out, even though the day before we were all going crazy because most of the things were missing. It was a really fun experience. </p>
 
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<img src="https://static.igem.org/mediawiki/2013hs/d/d3/D9b5b18226b32476e3e16622aae4da9e.jpg" height="300px" />
 
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Revision as of 01:12, 18 October 2014

Project
DNA / Program Supression

DNA Specific Deletion


The DNA, just like a lot of other molecules, suffers from deletion; be it to repair, insert a fragment, recombine or as a defense strategy. There are multiple causes for this, but the one that interest us is due to enzymatic action, among which we find exonucleases, restriction enzymes, and other molecules that will be revised shortly.

Endonucleases

Nucleases are enzymes with the ability to fragment DNA through phosphodiester bond ruptures. When the cutting site is in the 5’ or 3' end, it’s called an exonuclease; on the other hand, if it's inside the DNA strand, it´s called an endonuclease. Among endonucleases, restriction enzymes, which can recognize specific DNA sequences (Sui-Hong et al, 2010), have been of utmost interest in the manipulation of DNA, from polymorphism identification (molecular diagnosis) to the construction of new DNA sequences (genetic engineering).

According to their characteristics, they are divided into four types, from I to IV. Moreover, each of them has their own specific applications. The most studied and used are type II restriction enzymes, because they recognize a specific palindromic sequence and they generally inside this sequence. On the other hand, type I enzymes cut approximately at a 1000 bp distance, while type III cuts at a 24-26 bp distance. Finally, type IV has low specificity and only cuts methylated DNA (Roberts et al, 2003).

Among type 2 restriction enzymes, there are those who can cut just one strand, which is called nicking. They are generally named with an N prefix, for example, N.bstSEI (Roberts et al, 2003).

Restriction enzymes can recognize symmetric and asymmetric sequences (Pingoud et al, 2001). One way of classifying those that recognize asymmetric sequences is in 5 classes according to their characteristics (Sui-Hong et al, 2010), which are shown in the table.

Type II restriction enzymes have come to be used so much in the molecular biology field, that commercially they are the most exploited. But even among them, there can be advantages and disadvantages. For example, if an enzyme has a recognition site of a few nucleotides, it is better suited for diagnostic trials than for genetic engineering. For this reason the use and research of new enzymes has begun, along with the de novo design of others (Sui-Hong et al, 2010).

The mode of action of type II restrictions enzymes can be imitated with artificially designed enzymes. For example, the union of proteins and/or peptides that recognize certain sequences with others that have the capacity of excising DNA.

In our project we plan to use endonucleases, together with polypeptides that recognize longer sequences than restriction enzymes, in order to increase the specificity.

Zinc- Finger Nucleases (ZFN)

Zinc-finger nucleases are agents that have been used for DNA modification by means of the fusion of a zinc finger, designed or preexistent, with the active domain of the Fokl enzyme; this Phusion molecule is called “Zinc Finger Nuclease” or ZFN (Kim et al, 1996). They have been used in different organisms, from animals to plants (Miller et al, 2007) with the purpose of modifying them, for example, through an integration of complete genes (Moehle et al, 2007).

An important aspect to be considered before using this technology, is that in order to cut it needs to dimerize with the functional domain of another Fokl (Bitinaite, 1998). That’s why it´s required to design adjacent ZFNs whose Fokl domains interact in an intermediate site. There are also other advantages, like its high specificity due to the ability to design binding sites of over 18 bp (Urnov et al, 2005) and because they normally only cut once they have bound to the specific site (Vanamee et al, 2001). On the other hand, when the ZFP has not joined its specific site, Fokl remains as a monomer even to the 15 µM (Kaczorowski et al, 1989), making the appearance of cuts in non-specific sites more difficult.

However, it is necessary to mention that some possible disadvantages exist, ones that may surface in spite of good planning. One of them is that the effectiveness of a ZFN in one species doesn’t it will function in others (--). Another downside may be that the designed ZFNs work, but once they homodimerize they cut sites they weren’t designed for, becoming toxic for the cell (Beumer et al, 2006). Due to this, the designing of new ZFN requires experimentation to assure its correct functioning.

In our project ZFNs will be used, and to avoid the problems mentioned above, we will use ZFNs that have been previously tested in E. coli. This is because our aim is to prove the utility of said protein in our project.

CRISPR Cas9 (Adaptative immune system)

Characteristics:
1. System guided by RNA
2. Method that controls genetic expression
3. Cas9 endonuclease

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