Team:SDU-Denmark/Tour34
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<font color="3397FE">"With great power comes great responsibility!" - <b>Voltaire</b></font> | <font color="3397FE">"With great power comes great responsibility!" - <b>Voltaire</b></font> | ||
</p> | </p> | ||
- | <a class="popupImg alignRight" style="width: | + | <a class="popupImg alignRight" style="width:400px" target="_blank" href="https://static.igem.org/mediawiki/2014/d/d5/2014SDUsafety2.jpg" title="Working in the lab includes responsibilty."> |
- | <img src="https://static.igem.org/mediawiki/2014/6/6d/2014SDUsafety1.jpg" style="width: | + | <img src="https://static.igem.org/mediawiki/2014/6/6d/2014SDUsafety1.jpg" style="width:400px" /> |
</a> | </a> | ||
<p> | <p> | ||
- | <span class="intro">The role of a synthetic biologist</span> involves the analysis of the biosafety of the systems designed. Biosafety is the prevention of an accidental or unintentional exposure to pathogens, and to analyze this | + | <span class="intro">The role of a synthetic biologist</span> involves the analysis of the biosafety of the systems designed. Biosafety is the prevention of an accidental or unintentional exposure to pathogens, and to analyze this it is useful to evaluate the risk involved in the project which can be expressed as |
<span class="sourceReference">“Risk= Hazard x Probability”.</span> | <span class="sourceReference">“Risk= Hazard x Probability”.</span> | ||
<span class="tooltip"> | <span class="tooltip"> | ||
Line 20: | Line 20: | ||
<h4>Hazard</h4> | <h4>Hazard</h4> | ||
<p> | <p> | ||
- | <span class="intro">To evaluate the potential</span> | + | <span class="intro">To evaluate the potential hazardousness</span> of our project, we started by looking at the components of the system. |
Our main chassis, <i>E.coli</i> K12 MG1655 is a non-pathogen <i>E.coli</i> | Our main chassis, <i>E.coli</i> K12 MG1655 is a non-pathogen <i>E.coli</i> | ||
<span class="sourceReference">strain.</span> | <span class="sourceReference">strain.</span> | ||
Line 29: | Line 29: | ||
- | + | Further more, it is weakened and thereby not able to | |
- | survive in case of | + | survive in case of leakage. We have also been working with the Odor Free chassis E.coli YYC912, which is a |
modified strain, not able to produce indole. This strain is non-pathogen as | modified strain, not able to produce indole. This strain is non-pathogen as | ||
<span class="sourceReference">well.</span> | <span class="sourceReference">well.</span> | ||
Line 38: | Line 38: | ||
<a href="http://www.genoportal.org/bbdb/get.php?q=BBa_J45999" target="_blank">(Link)</a></span> | <a href="http://www.genoportal.org/bbdb/get.php?q=BBa_J45999" target="_blank">(Link)</a></span> | ||
- | Our parts, both basic parts and devices are all taken from | + | Our parts, both basic parts and devices, are all taken from |
- | risk group 1 organisms and | + | risk group 1 organisms and therefore do not contain nor mimic any virulence factors. This would be indicative of a |
very low hazardousness of our system. On the other hand, we have a self-designed protein and the safety of this | very low hazardousness of our system. On the other hand, we have a self-designed protein and the safety of this | ||
brick might need to be considered. To avoid toxicity, we have shuffled the amino acids until the obtained sequence | brick might need to be considered. To avoid toxicity, we have shuffled the amino acids until the obtained sequence | ||
didn’t resemble any known toxin or other disease causing protein. We have also assayed the toxicity by feeding | didn’t resemble any known toxin or other disease causing protein. We have also assayed the toxicity by feeding | ||
- | <i>C. elegans</i> bacteria producing OneProt (For more information see our <a href="https://2014.igem.org/Team:SDU-Denmark/Tour42">results page</a>).<br><br> | + | <i>C. elegans</i> bacteria producing OneProt (For more information, see our <a href="https://2014.igem.org/Team:SDU-Denmark/Tour42">results page</a>).<br><br> |
</p> | </p> | ||
<h4>Probability</h4> | <h4>Probability</h4> | ||
<p> | <p> | ||
- | <span class="intro">When analyzing the probability</span> | + | <span class="intro">When analyzing the probability</span> it is important to consider that there always will be an element of uncertainty in the |
- | results. The completion of our project implies the release of GMO to the environment. Even though our GMO will in | + | results. The completion of our project implies the release of GMO to the environment. Even though our GMO will be weakened in |
- | several ways | + | several ways, the environmental effect of this release cannot be completely foreseen.<br><br> |
</p> | </p> | ||
<h4>Risk</h4> | <h4>Risk</h4> | ||
<p> | <p> | ||
- | <span class="intro">Our final product would</span> | + | <span class="intro">Our final product would include</span> a group of cellulases, this could mean that there would be a remote risk that, in case of leakage, our bacteria could start to uncontrollably degrade cellulose into glucose for satisfying its |
- | own metabolic requirements. In this sense | + | own metabolic requirements. In this sense these bacteria could potentially become a threat for crops and other |
- | plants | + | plants. To manage this, our idea is to have the cellulases regulated by an inducible promoter, which will |
- | prevent the production of cellulase in the absence of the inducer. In a worst-case scenario | + | prevent the production of cellulase in the absence of the inducer. In a worst-case scenario this promoter could |
- | mutate to become constitutive active and thereby produce cellulase. Even if this was the case, | + | mutate to become constitutive active and thereby produce cellulase. Even if this was the case, other safety |
- | mechanisms still be active, such as the kill switch and the general low environmental stability of E.coli K12. The | + | mechanisms would still be active, such as the kill switch and the general low environmental stability of E.coli K12. The |
- | probability of all these factors randomly mutating/ failing at the same time is almost negligible. We can analyze the | + | probability of all these factors randomly mutating/failing at the same time is almost negligible. We can analyze the |
risk of this event by using a risk matrix:<br><br> | risk of this event by using a risk matrix:<br><br> | ||
- | <div class="popupImg alignCenter" style="width:600px" target="_blank" title="Risk matrix: This describes relation between the probability and the hazard of our project. According to this analysis is this risk “yellow”, which means that it is acceptable to work with this project, | + | <div class="popupImg alignCenter" style="width:600px" target="_blank" title="Risk matrix: This describes relation between the probability and the hazard of our project. According to this analysis is this risk “yellow”, which means that it is acceptable to work with this project, but some considerations, such as a kill switch, may be considered">Risk matrix: This describes relation between the probability and the hazard of our project. According to this analysis is this risk “yellow”, which means that it is acceptable to work with this project, but some considerations, such as a kill switch, may be considered. |
<img src="https://static.igem.org/mediawiki/2014/b/b7/2014SDUsafety3.PNG" style="width:600px" /> | <img src="https://static.igem.org/mediawiki/2014/b/b7/2014SDUsafety3.PNG" style="width:600px" /> | ||
- | |||
</div><br><br> | </div><br><br> | ||
- | <span class="intro">As for the risk</span> for the safety and health | + | <span class="intro">As for the risk</span> for the safety and health of the general public, it is of great concern to avoid the spread of antibiotic |
resistance. All our constructs are made on antibiotic-resistant bacteria, which could, potentially, transfer resistance | resistance. All our constructs are made on antibiotic-resistant bacteria, which could, potentially, transfer resistance | ||
- | genes to other bacteria, in case of | + | genes to other bacteria, in case of leakage. This would contribute to the increasing difficulty in fighting so far |
- | controlled infections. To avoid this, we | + | controlled infections. To avoid this, we think that in the future these genes could be transferred into a plasmid |
developed in our university, which contains the proteins needed to make ribosomes and use <i>E. coli</i> knocked down | developed in our university, which contains the proteins needed to make ribosomes and use <i>E. coli</i> knocked down | ||
- | for these genes. In this way | + | for these genes. In this way the bacteria is completely dependent of the plasmid in order to survive, which can be |
used as an alternative method of selection.<br><br> | used as an alternative method of selection.<br><br> | ||
</p> | </p> | ||
Line 80: | Line 79: | ||
<h4>Dual use</h4> | <h4>Dual use</h4> | ||
<p> | <p> | ||
- | <span class="intro">If the product was</span> | + | <span class="intro">If the product was to be misused</span> by individuals, groups or countries, they could potentially use this bacterium to |
induce the right combination of mutations, in order to get a plant-destruction weapon. We evaluate that the risk | induce the right combination of mutations, in order to get a plant-destruction weapon. We evaluate that the risk | ||
- | involved in the | + | involved in the misuse of our project is actually smaller than the misuse of the cellulase biobrick itself (because |
- | of the | + | of the kill switch, need of mutation of the promoter, etc.)<br><br> |
- | <span class="intro">The | + | <span class="intro">The misuse of our protein</span> might be aimed at mutating the protein to make it harmful. We consider, though, that if the aim is to create a harmful protein there are other easier ways, such as starting with a pathogenic protein |
or simply designing a protein.<br><br> | or simply designing a protein.<br><br> | ||
- | The best way to fight dual use | + | <span class="intro">The best way to fight</span> dual use is to try to prevent it by taking biosecurity measures in consideration, like limited |
access to laboratories and tracking of orders of gene synthesis.<br><br> | access to laboratories and tracking of orders of gene synthesis.<br><br> | ||
</p> | </p> | ||
- | <h4>Risk | + | <h4>Risk perspectives: including others</h4> |
<p> | <p> | ||
- | <span class="intro">It is our conviction | + | <span class="intro">It is our conviction</span> that a good synthetic biologist (and scientist) is one that, besides evaluating the safety of his projects, can include the general public into the discussion. Public opinion has an enormous effect on the feasibility |
of a project to succeed, both because the acceptance of the general public can make it easier to receive funding, | of a project to succeed, both because the acceptance of the general public can make it easier to receive funding, | ||
but also because of the valuable feedback that can come as a result of the interaction between the general public | but also because of the valuable feedback that can come as a result of the interaction between the general public | ||
- | and the synthetic biologist. Therefore it is important to <b>communicate</b> effectively and <b>considerate</b>, what might | + | and the synthetic biologist. Therefore it is important to <b>communicate</b> effectively and <b>considerate</b>, what might be |
- | perceived as a risk factor. In our case, | + | perceived as a risk factor. In our case, bacteria and GMOs are often considered as hazardous and not as a food |
- | resource. The fact many people are not familiar with bacteria and GMO | + | resource. The fact that many people are not familiar with bacteria and GMO could make the risk perception very high. |
- | To cope with this issue | + | To cope with this issue we made our interactive video adventure as an attempt to share the message, inform the |
general public and, hopefully, reduce the risk perception of our project.<br><br> | general public and, hopefully, reduce the risk perception of our project.<br><br> | ||
- | <span class="intro">All in all</span> | + | <span class="intro">All in all, we believe</span> that, even though there could potentially be some risks related to our project, it is safe enough to continue with our project, especially in the light of the potential and more probable benefits. |
<br><br><br> | <br><br><br> |
Latest revision as of 01:37, 18 October 2014
Safety
"With great power comes great responsibility!" - Voltaire
The role of a synthetic biologist involves the analysis of the biosafety of the systems designed. Biosafety is the prevention of an accidental or unintentional exposure to pathogens, and to analyze this it is useful to evaluate the risk involved in the project which can be expressed as
“Risk= Hazard x Probability”.
Source:
iGEM, 2013: Safety form Resources.
(Link)
Hazard
To evaluate the potential hazardousness of our project, we started by looking at the components of the system.
Our main chassis, E.coli K12 MG1655 is a non-pathogen E.coli
strain.
Source:
NIH GUIDELINES FOR RESEARCH INVOLVING RECOMBINANT OR SYNTHETIC NUCLEIC ACID MOLECULES. 2013.
(Link)
Further more, it is weakened and thereby not able to
survive in case of leakage. We have also been working with the Odor Free chassis E.coli YYC912, which is a
modified strain, not able to produce indole. This strain is non-pathogen as
well.
Source:
Genportal, 2006.
(Link)
Our parts, both basic parts and devices, are all taken from
risk group 1 organisms and therefore do not contain nor mimic any virulence factors. This would be indicative of a
very low hazardousness of our system. On the other hand, we have a self-designed protein and the safety of this
brick might need to be considered. To avoid toxicity, we have shuffled the amino acids until the obtained sequence
didn’t resemble any known toxin or other disease causing protein. We have also assayed the toxicity by feeding
C. elegans bacteria producing OneProt (For more information, see our results page).
Probability
When analyzing the probability it is important to consider that there always will be an element of uncertainty in the
results. The completion of our project implies the release of GMO to the environment. Even though our GMO will be weakened in
several ways, the environmental effect of this release cannot be completely foreseen.
Risk
Our final product would include a group of cellulases, this could mean that there would be a remote risk that, in case of leakage, our bacteria could start to uncontrollably degrade cellulose into glucose for satisfying its
own metabolic requirements. In this sense these bacteria could potentially become a threat for crops and other
plants. To manage this, our idea is to have the cellulases regulated by an inducible promoter, which will
prevent the production of cellulase in the absence of the inducer. In a worst-case scenario this promoter could
mutate to become constitutive active and thereby produce cellulase. Even if this was the case, other safety
mechanisms would still be active, such as the kill switch and the general low environmental stability of E.coli K12. The
probability of all these factors randomly mutating/failing at the same time is almost negligible. We can analyze the
risk of this event by using a risk matrix:
As for the risk for the safety and health of the general public, it is of great concern to avoid the spread of antibiotic resistance. All our constructs are made on antibiotic-resistant bacteria, which could, potentially, transfer resistance genes to other bacteria, in case of leakage. This would contribute to the increasing difficulty in fighting so far controlled infections. To avoid this, we think that in the future these genes could be transferred into a plasmid developed in our university, which contains the proteins needed to make ribosomes and use E. coli knocked down for these genes. In this way the bacteria is completely dependent of the plasmid in order to survive, which can be used as an alternative method of selection.
Dual use
If the product was to be misused by individuals, groups or countries, they could potentially use this bacterium to
induce the right combination of mutations, in order to get a plant-destruction weapon. We evaluate that the risk
involved in the misuse of our project is actually smaller than the misuse of the cellulase biobrick itself (because
of the kill switch, need of mutation of the promoter, etc.)
The misuse of our protein might be aimed at mutating the protein to make it harmful. We consider, though, that if the aim is to create a harmful protein there are other easier ways, such as starting with a pathogenic protein
or simply designing a protein.
The best way to fight dual use is to try to prevent it by taking biosecurity measures in consideration, like limited
access to laboratories and tracking of orders of gene synthesis.
Risk perspectives: including others
It is our conviction that a good synthetic biologist (and scientist) is one that, besides evaluating the safety of his projects, can include the general public into the discussion. Public opinion has an enormous effect on the feasibility
of a project to succeed, both because the acceptance of the general public can make it easier to receive funding,
but also because of the valuable feedback that can come as a result of the interaction between the general public
and the synthetic biologist. Therefore it is important to communicate effectively and considerate, what might be
perceived as a risk factor. In our case, bacteria and GMOs are often considered as hazardous and not as a food
resource. The fact that many people are not familiar with bacteria and GMO could make the risk perception very high.
To cope with this issue we made our interactive video adventure as an attempt to share the message, inform the
general public and, hopefully, reduce the risk perception of our project.
All in all, we believe that, even though there could potentially be some risks related to our project, it is safe enough to continue with our project, especially in the light of the potential and more probable benefits.