Team:SDU-Denmark/safety-d

From 2010.igem.org

(Difference between revisions)
(General use)
Line 89: Line 89:
-
==General use==
+
===General use===
 +
 
 +
 
 +
What type of lab should work with this BioBrick be done in? <br />
 +
Is any special care needed when working with this BioBrick in addition to ordinary laboratory work-safety protocols? <br />
 +
Potential pathogenicity <br />
 +
Does this BioBrick produce any product that is toxic to plants or animals? <br />
 +
Could a host with this BioBrick produce sufficient amounts of an otherwise non-toxic product to toxic levels? <br />
 +
Is the gene that the BioBrick codes for associated with disease processes or infection in humans? <br />
 +
Does the gene that the BioBrick codes for have homologs in known pathogenic bacteria? What are these genes’ functions? <br />
 +
Does this BioBrick produce any product that can regulate the immune system in animals or humans? <br />
 +
 
 +
===Environmental impact===
 +
 
 +
Does this BioBrick produce anything that plays an significant role in environmental processes? <br />
 +
Does this BioBricks increase it’s hosts ability to outmatch naturally occurring bacteria? Does it disrupt natural  occurring symbiosis? <br />
 +
Does this BioBrick increase it’s host’s ability to replicate? <br />
 +
Does this BioBrick increase it’s host’s ability to spread? <br />
 +
Does this BioBrick increase it’s host’s ability to survive outside laboratory conditions? <br />
 +
Does this BioBrick create something that might be toxic to it’s environment? <br />
 +
 
 +
===Possible malign use===
 +
 
 +
Can host’s with this BioBrick survive storage conditions (in pressured conditions, under alternative temperatures and in large containers?) <br />
 +
Can your chosen host be arosoled? <br />
 +
Does this BioBrick increase the host’s ability to vaporize?  <br />
 +
Does this BioBrick increase the host’s ability to create spores? <br />
 +
Does this BioBrick produce any product that can regulate the immune system in animals or humans? <br />
 +
Is this BioBrick in anyway pathogenic in animals or humans or towards plants? <br />
 +
 
 +
===Construct notes===
 +
 
 +
What is the origin of the genetic material used? What does the the genetic materiale do in this origin? Is there uncertainty about the genetical materials function?<br />
 +
What modifications were done on the genetic materiale before insertion? If anything was modified, what function do you hope to achieve?<br />
 +
What vector did you use? Which antibiotic resistance were involved? Which protocol was used to insert the vector? <br />
 +
What is the stability of the insert with respect to genetic traits? <br />
 +
How easily can the insert transfer to other bacteria or lifeforms? <br />
 +
Where there safer alternatives to achieve this function? Where there safer alternatives to the host organism and vector used? <br />
 +
Is your construct watermarked? <br />
-
What type of lab should work with this BioBrick be done in?
 
-
Is any special care needed when working with this BioBrick in addition to ordinary laboratory work-safety protocols?
 
-
Potential pathogenicity
 
-
Does this BioBrick produce any product that is toxic to plants or animals?
 
-
Could a host with this BioBrick produce sufficient amounts of an otherwise non-toxic product to toxic levels?
 
-
Is the gene that the BioBrick codes for associated with disease processes or infection in humans?
 
-
Does the gene that the BioBrick codes for have homologs in known pathogenic bacteria? What are these genes’ functions?
 
-
Does this BioBrick produce any product that can regulate the immune system in animals or humans?
 
-
Environmental impact
 
-
Does this BioBrick produce anything that plays an significant role in environmental processes?
 
-
Does this BioBricks increase it’s hosts ability to outmatch naturally occurring bacteria? Does it disrupt natural occurring symbiosis?
 
-
Does this BioBrick increase it’s host’s ability to replicate?
 
-
Does this BioBrick increase it’s host’s ability to spread?
 
-
Does this BioBrick increase it’s host’s ability to survive outside laboratory conditions?
 
-
Does this BioBrick create something that might be toxic to it’s environment?
 
-
Possible malign use
 
-
Can host’s with this BioBrick survive storage conditions (in pressured conditions, under alternative temperatures and in large containers?)
 
-
Can your chosen host be arosoled?
 
-
Does this BioBrick increase the host’s ability to vaporize? 
 
-
Does this BioBrick increase the host’s ability to create spores?
 
-
Does this BioBrick produce any product that can regulate the immune system in animals or humans?
 
-
Is this BioBrick in anyway pathogenic in animals or humans or towards plants?
 
-
Construct notes
 
-
What is the origin of the genetic material used? What does the the genetic materiale do in this origin? Is there uncertainty about the genetical materials function?
 
-
What modifications were done on the genetic materiale before insertion? If anything was modified, what function do you hope to achieve?
 
-
What vector did you use? Which antibiotic resistance were involved? Which protocol was used to insert the vector?
 
-
What is the stability of the insert with respect to genetic traits?
 
-
How easily can the insert transfer to other bacteria or lifeforms?
 
-
Where there safer alternatives to achieve this function? Where there safer alternatives to the host organism and vector used?
 
-
Is your construct watermarked?
 
The above list of question is more or less derived from a more throughout list of questions relevant to assessing the safety and securty of the parts, see appendix II  
The above list of question is more or less derived from a more throughout list of questions relevant to assessing the safety and securty of the parts, see appendix II  
-
Risk-assessment in conjunction with the use of this part in a particular organism
+
 
 +
 
 +
==Risk-assessment in conjunction with the use of this part in a particular organism==
 +
 
 +
 
Should the part, or a number of parts, be inserted into an organism the team should perform a risk-assessment and make it available on the parts-registry. In some countries, it is mandatory to submit a risk-assessment prior to engaging in a project involving synthetic biology, so we believe that any risk-assessments should be made public through parts-registry.
Should the part, or a number of parts, be inserted into an organism the team should perform a risk-assessment and make it available on the parts-registry. In some countries, it is mandatory to submit a risk-assessment prior to engaging in a project involving synthetic biology, so we believe that any risk-assessments should be made public through parts-registry.
-
Inclusion of copyright information?
+
 
 +
==Inclusion of copyright information?==
 +
 
We do not believe in any form of copyright prohibition. We believe in an open-source approach to the field of synthetic biology, as in iGEM. Any copy-right prohibitions would only stall the progress in this most vital field of science. We believe that any and all information on created parts, and experience with these parts in particular organisms, should be shared freely.
We do not believe in any form of copyright prohibition. We believe in an open-source approach to the field of synthetic biology, as in iGEM. Any copy-right prohibitions would only stall the progress in this most vital field of science. We believe that any and all information on created parts, and experience with these parts in particular organisms, should be shared freely.
Information on how to neutralize bacteria
Information on how to neutralize bacteria
This clause is intended as security measure. Should the bacteria be released into the environment, the parts-registry site should contain information on how to neutralize the bacteria. If the bacteria has an kill-code inserted, the site should describe how to enact the self-destruct mechanism.
This clause is intended as security measure. Should the bacteria be released into the environment, the parts-registry site should contain information on how to neutralize the bacteria. If the bacteria has an kill-code inserted, the site should describe how to enact the self-destruct mechanism.
-
Anticipated problems
+
 
-
Code deterioration
+
==Anticipated problems==
 +
 
 +
===Code deterioration===
 +
 
The code will deteriorate over time due to mutation. This could prove to be a serious problem should watermarking become an integrated part of synthetic biology. Should the genetic watermark deteriorate to the point where one is no longer able to read it, it would not constitute any kind of safety measure, being able to tell that the part was likely to have been made artificially being the only thing we would be able to tell.
The code will deteriorate over time due to mutation. This could prove to be a serious problem should watermarking become an integrated part of synthetic biology. Should the genetic watermark deteriorate to the point where one is no longer able to read it, it would not constitute any kind of safety measure, being able to tell that the part was likely to have been made artificially being the only thing we would be able to tell.
Knowing that data will deteriorate, it may be impossible to determine whether the watermark found in rogue bacteria is authentic or a degenerate. The deterioration is however slow and arbitrary. Our code is so small, that the change that any nucleotide associated with the watermark is going to mutate is very limited. The chances of finding the authentic code intact should be very good.
Knowing that data will deteriorate, it may be impossible to determine whether the watermark found in rogue bacteria is authentic or a degenerate. The deterioration is however slow and arbitrary. Our code is so small, that the change that any nucleotide associated with the watermark is going to mutate is very limited. The chances of finding the authentic code intact should be very good.
-
The open source approach
+
 
 +
===The open source approach===
 +
 
Sharing all this information on creating new synthetic parts that can be inserted into living organisms, also means that people with harmful agendas have access to this knowledge. This naturally means that wrongful actions are possible by use of synthetic biology, but we do not think that this should stand in the way of all the possibilities synthetic biology holds. Also, the more we know about how to create synthetic DNA strands, the better we are equipped if any harmful incident should occur. As of now, it might also just be easier to drop a bomb or send out letters of anthrax.
Sharing all this information on creating new synthetic parts that can be inserted into living organisms, also means that people with harmful agendas have access to this knowledge. This naturally means that wrongful actions are possible by use of synthetic biology, but we do not think that this should stand in the way of all the possibilities synthetic biology holds. Also, the more we know about how to create synthetic DNA strands, the better we are equipped if any harmful incident should occur. As of now, it might also just be easier to drop a bomb or send out letters of anthrax.
Should a bacteria be used for a malign purpose it would be quite easy to insert a false watermark to blame others. So we need to keep in mind that a plot could be made against someone. However, if anyone was interested in harming as many as possible, this person probably wouldn’t care about watermarking at all. This also means that we cannot expect watermarking to play a part in any legal case.
Should a bacteria be used for a malign purpose it would be quite easy to insert a false watermark to blame others. So we need to keep in mind that a plot could be made against someone. However, if anyone was interested in harming as many as possible, this person probably wouldn’t care about watermarking at all. This also means that we cannot expect watermarking to play a part in any legal case.

Revision as of 11:39, 26 October 2010