Team:Berkeley/Safety
From 2011.igem.org
Gabriellopez (Talk | contribs) |
Gabriellopez (Talk | contribs) |
||
(4 intermediate revisions not shown) | |||
Line 53: | Line 53: | ||
<p> | <p> | ||
The genetic materials used in our project pose no safety or health concerns to members in the lab. There are certain chemicals and solvents we use in lab that are known to be toxic, but all are treated with proper caution and care. If released by accident, our parts and materials would do no negative damage to the general public. No substances could be used maliciously because the bacteria we use is in no way capable of causing wide-spread harm or harm to individuals. They are all benign by nature and pose no realistic danger to anyone. | The genetic materials used in our project pose no safety or health concerns to members in the lab. There are certain chemicals and solvents we use in lab that are known to be toxic, but all are treated with proper caution and care. If released by accident, our parts and materials would do no negative damage to the general public. No substances could be used maliciously because the bacteria we use is in no way capable of causing wide-spread harm or harm to individuals. They are all benign by nature and pose no realistic danger to anyone. | ||
- | <p>The environment is also in no danger from such a hypothetical release for reasons stated previously. Also, most of the source DNAs used in our project are either from the E. coli MG1655 genome, are commonly used materials in E. coli, or are known genes from RG1 organisms. Though in common use, one of our coding sequences is from RG2 organism: Tox R and the Pctx promoter are from a virulence island from Vibrio cholerae.1 However, they only encode a transcription factor and a promoter, respectively. Only the N-terminal half of the open reading frame sequence of ToxR was taken from the source sequence, and the Pctx promoter does not include any open reading frames or known coding RNAs. As there is no function to these features except their ability to act as a transcriptional activator and promoter pair, we believe these materials to be RG1. Based on current knowledge of molecular function of these source DNAs there are no specific anticipated risks associated with any combination of these materials beyond the fact that they are derived from RG1 E. coli. The largest single volume used in these studies will be 2 liters, though most experiments involve between 1ul and 40mL of liquid medium.</p><p>Although none of our parts require extensive precaution, we have been sure to take proper care when working with E. Coli. However, none of our parts require special safety documentation beyond general precaution when dealing with bacteria and recombinant DNA. </p | + | <p>The environment is also in no danger from such a hypothetical release for reasons stated previously. Also, most of the source DNAs used in our project are either from the E. coli MG1655 genome, are commonly used materials in E. coli, or are known genes from RG1 organisms. Though in common use, one of our coding sequences is from RG2 organism: Tox R and the Pctx promoter are from a virulence island from Vibrio cholerae.1 However, they only encode a transcription factor and a promoter, respectively. Only the N-terminal half of the open reading frame sequence of ToxR was taken from the source sequence, and the Pctx promoter does not include any open reading frames or known coding RNAs. As there is no function to these features except their ability to act as a transcriptional activator and promoter pair, we believe these materials to be RG1. Based on current knowledge of molecular function of these source DNAs there are no specific anticipated risks associated with any combination of these materials beyond the fact that they are derived from RG1 E. coli. The largest single volume used in these studies will be 2 liters, though most experiments involve between 1ul and 40mL of liquid medium.</p><p>Although none of our parts require extensive precaution, we have been sure to take proper care when working with E. Coli. However, none of our parts require special safety documentation beyond general precaution when dealing with bacteria and recombinant DNA. </p> |
</div> | </div> | ||
</div> | </div> | ||
Line 99: | Line 99: | ||
</div> | </div> | ||
+ | |||
+ | <br><br> | ||
Line 112: | Line 114: | ||
biosafety regulations into general design workflow would improve adherence to biosafety | biosafety regulations into general design workflow would improve adherence to biosafety | ||
regulations.</p> | regulations.</p> | ||
+ | <img src="https://static.igem.org/mediawiki/2011/3/3c/Dualuseheader.jpg" width="480"> | ||
+ | <p> | ||
+ | The majority of the materials used in these studies are in common use or are derived from E. coli with the exception of ToxR. Therefore, they present no new risks of dual use. ToxR in theory could be used to change the regulation of the cholera toxin pathway in Vibrio cholerae, but would require additional cloning into a diffferent expression system and replicons for Vibrio. Since anyone working with Vibrio would alread have access to the ToxR ORF via its genomic DNA, the existence of our part does not facilitate such experiments. | ||
+ | </P> | ||
+ | |||
</div> | </div> | ||
</div> | </div> |
Latest revision as of 17:42, 28 September 2011
The genetic materials used in our project pose no safety or health concerns to members in the lab. There are certain chemicals and solvents we use in lab that are known to be toxic, but all are treated with proper caution and care. If released by accident, our parts and materials would do no negative damage to the general public. No substances could be used maliciously because the bacteria we use is in no way capable of causing wide-spread harm or harm to individuals. They are all benign by nature and pose no realistic danger to anyone.
The environment is also in no danger from such a hypothetical release for reasons stated previously. Also, most of the source DNAs used in our project are either from the E. coli MG1655 genome, are commonly used materials in E. coli, or are known genes from RG1 organisms. Though in common use, one of our coding sequences is from RG2 organism: Tox R and the Pctx promoter are from a virulence island from Vibrio cholerae.1 However, they only encode a transcription factor and a promoter, respectively. Only the N-terminal half of the open reading frame sequence of ToxR was taken from the source sequence, and the Pctx promoter does not include any open reading frames or known coding RNAs. As there is no function to these features except their ability to act as a transcriptional activator and promoter pair, we believe these materials to be RG1. Based on current knowledge of molecular function of these source DNAs there are no specific anticipated risks associated with any combination of these materials beyond the fact that they are derived from RG1 E. coli. The largest single volume used in these studies will be 2 liters, though most experiments involve between 1ul and 40mL of liquid medium.
Although none of our parts require extensive precaution, we have been sure to take proper care when working with E. Coli. However, none of our parts require special safety documentation beyond general precaution when dealing with bacteria and recombinant DNA.
We believe that integrating the safety concerns into new software tools as well as integrating biosafety regulations into general design workflow would improve adherence to biosafety regulations.
The majority of the materials used in these studies are in common use or are derived from E. coli with the exception of ToxR. Therefore, they present no new risks of dual use. ToxR in theory could be used to change the regulation of the cholera toxin pathway in Vibrio cholerae, but would require additional cloning into a diffferent expression system and replicons for Vibrio. Since anyone working with Vibrio would alread have access to the ToxR ORF via its genomic DNA, the existence of our part does not facilitate such experiments.