Team:Cambridge/Parts

From 2012.igem.org

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== '''Parts designed and constructed ''' ==
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{| style="color:#1b2c8a;background-color:#3ae2e8;" cellpadding="3" cellspacing="0" border="1" bordercolor="#fff" width="62%" align="center"
 
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!align="center"|[[Team:Cambridge|Home]]
 
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!align="center"|[[Team:Cambridge/Team|Team]]
 
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!align="center"|[https://igem.org/Team.cgi?year=2012&team_name=Cambridge Official Team Profile]
 
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!align="center"|[[Team:Cambridge/Project|Project]]
 
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!align="center"|[[Team:Cambridge/Parts|Parts Submitted to the Registry]]
 
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!align="center"|[[Team:Cambridge/Modeling|Modeling]]
 
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!align="center"|[[Team:Cambridge/Notebook|Notebook]]
 
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!align="center"|[[Team:Cambridge/Safety|Safety]]
 
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!align="center"|[[Team:Cambridge/Attributions|Attributions]]
 
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!align="center"|[[Team:Cambridge/Sponsors|Sponsors]]
 
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|}
 
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911004<span style="color:#00000CD"><font size="4">1. Synthesised Ratiometric Luciferase construct in non-standard plasmid (Part:BBa_K911004) </font>]'''
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An important aspect of the iGEM competition is the use and creation of standard  biological parts. Each team will make new parts during iGEM and will place them in the [http://partsregistry.org Registry of Standard Biological Parts]. The iGEM software provides an easy way to present the parts your team has created . The "groupparts" tag will generate a table with all of the parts that your team adds to your team sandbox. Note that if you want to document a part you need to document it on the [http://partsregistry.org Registry], not on your team wiki.
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This part was designed as a ratiometric luciferase reporter. The first promoter, hyperSpank, is LacI - repressed and controls the transcription of a (vibrio harveyi) luxA gene that has been fused at the N-terminus to an mOrange gene via a flexible linker. This was described by Dachuan Ke and Shiao-Chun Tu (2011) as having an additional peak in its emission spectrum at 560 nm, whereas the normal peak is at 490 nm. This is terminated by b0015. Downstream, pVEG controls the translation of the entire normal lux operon, which is again terminated by b0015.
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The idea is that the normal luciferase output acts as an internal control signal, to which the output of the induced luciferase with the spectral shift can be normalised. We designed this to be compatible with our cheap open-source sensing hardware.
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This part has some toxicity issues preventing it from being assembled in pSB1C3. We contacted iGEM HQ and were granted exemption from the pSB1C3 standard for this part.
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911003<span style="color:#00000CD"><font size="4">2. Fluoride Sensitive Riboswitch (Part:BBa_K911003) </font>]'''
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Riboswitch that is highly sensitive to the F- ion. It forms a rho-independent transcriptional terminator in low fluoride concentrations and this structure is removed in the presence of fluoride, allowing transcription. It is sensitive from about 10&mu;M up to around 30mM. Above this concentration the levels of fluoride begin to become toxic and kill the cells. We have characterized this part in three different chassis: TOP10 e.coli, 168 strain bacillus subtilis and a strain of bacillus subtilis with its normal fluoride riboswitch, the crcB gene, knocked out (kindly provided by the Breaker lab in Yale). Results of Miller assays for these three chassis are also provided.
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911001<span style="color:#00000CD"><font size="4">3. Magnesium sensitive riboswitch (Part:BBa_K911001) </font>]'''
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Riboswitch that acts as a regulatory element, truncating transcripts when magnesium is not bound to the RNA. Four Mg2+ binding sites exist, giving this part significantly switch-like behavior. Binding of these sites by Mg2+ results in compaction of the regulatory region of the riboswitch, which in its unbound state acts as an anti-terminator. Loss of this anti-terminator activity results in the activity of a downstream terminator (included in this sequence) which terminates transcription of the gene. May also be affected by other divalent ions, such as manganese.
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911002<span style="color:#00000CD"><font size="4">4. Magnesium sensitive riboswitch (8 codon substitution)(Part:BBa_K911002) </font>]'''
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Riboswitch that acts as a regulatory element, truncating transcripts when magnesium is not bound to the RNA. Four Mg2+ binding sites exist, giving this part significantly switch-like behavior. Binding of these sites by Mg2+ results in compaction of the regulatory region of the riboswitch, which in its unbound state acts as an anti-terminator. Loss of this anti-terminator activity results in the activity of a downstream terminator (included in this sequence) which terminates transcription of the gene. May also be affected by other divalent ions, such as manganese. This version also contains the first eight codons of the first downstream gene in the native ''Bacillus'' genome, MgtE. Substitution of the first eight codons of a reporter with these may improve reliability of change of reporter expression.
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911008<span style="color:#00000CD"><font size="4">5. Fast Germination (B.subtilis)(Part:BBa_K911008) </font>]'''
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This part upregulates an operon responsible for germination rate. Bacillus subtilis spores germinate in the presence of L-Alanine. Up-regulation of the spoVA operon increases germination rate in response to L-Alanine. The promoter for the B.subtilis sspB gene (PsspB) is more active than the endogenous spoVA promoter. It is also active during germination. Expression of the spoVA operon under PsspB increases the germination rate.
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This construct consists mainly of the sspB promoter followed by the first 354bp of the spoVA operon (first 354bp of the spoVAA gene). Since B.subtilis exhibits accurate and efficient homologous recombination, a single cross-over event between the spoVAA region in the BioBrick and the endogenous spoVAA sequence inserts the sspB promoter upstream of the spoVA operon.
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911009<span style="color:#00000CD"><font size="4">6. Fluorescent ratiometric construct for standardizing promoter output(Part:BBa_K911009) </font>]'''
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Biosensors may give unreliable outputs. This is due to differences in the number and state of the cells from test to test. By including an internal control signal, to which another inducible signal may be normalised, the reliability and reproducibility of a sensor may be significantly improved.
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The construct that uses an inducible eCFP (E0020) and a constitutively expressed eYFP (E0030) under the control of the constitutive promoter Pveg (K143012). The construct is optimized in both E. coli and B. subtilis, through the use of B. subtilis ribosome binding sites GsiB (K143020) and SpoVG (K143021).
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'''[http://partsregistry.org/wiki/index.php?title=Part:BBa_K911006<span style="color:#00000CD"><font size="4">7. Non-standard backbone for luciferase construct (Part:BBa_K911006) </font>]'''
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This is the sequence of the non-standard backbone that our luciferase construct, BBa_k911004, was synthesised in. It could not be assembled in the high copy number standard psb1c3 backbone due to toxicity issues. Attempts to assemble the 9kb insert into psb3c5, a low copy number biobrick plasmid have so far been unsuccessful.
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Remember that the goal of proper part documentation is to describe and define a part such that it can be used without a need to refer to the primary literature. The next iGEM team should be able to read your documentation and be able to use the part successfully. Also, you should provide proper references to acknowledge previous authors and to provide for  users who wish to know more.
 
<groupparts>iGEM012 Cambridge</groupparts>
<groupparts>iGEM012 Cambridge</groupparts>
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{{Template:Team:Cambridge/CAM_2012_TEMPLATE_FOOT}}

Latest revision as of 20:17, 26 September 2012

Previous iGEM teams have charaterised an impressive array of inducible promoters, along with other elements of biosensing circuitry... Read More






Parts designed and constructed

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110041. Synthesised Ratiometric Luciferase construct in non-standard plasmid (Part:BBa_K911004) ]

This part was designed as a ratiometric luciferase reporter. The first promoter, hyperSpank, is LacI - repressed and controls the transcription of a (vibrio harveyi) luxA gene that has been fused at the N-terminus to an mOrange gene via a flexible linker. This was described by Dachuan Ke and Shiao-Chun Tu (2011) as having an additional peak in its emission spectrum at 560 nm, whereas the normal peak is at 490 nm. This is terminated by b0015. Downstream, pVEG controls the translation of the entire normal lux operon, which is again terminated by b0015. The idea is that the normal luciferase output acts as an internal control signal, to which the output of the induced luciferase with the spectral shift can be normalised. We designed this to be compatible with our cheap open-source sensing hardware. This part has some toxicity issues preventing it from being assembled in pSB1C3. We contacted iGEM HQ and were granted exemption from the pSB1C3 standard for this part.

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110032. Fluoride Sensitive Riboswitch (Part:BBa_K911003) ]

Riboswitch that is highly sensitive to the F- ion. It forms a rho-independent transcriptional terminator in low fluoride concentrations and this structure is removed in the presence of fluoride, allowing transcription. It is sensitive from about 10μM up to around 30mM. Above this concentration the levels of fluoride begin to become toxic and kill the cells. We have characterized this part in three different chassis: TOP10 e.coli, 168 strain bacillus subtilis and a strain of bacillus subtilis with its normal fluoride riboswitch, the crcB gene, knocked out (kindly provided by the Breaker lab in Yale). Results of Miller assays for these three chassis are also provided.

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110013. Magnesium sensitive riboswitch (Part:BBa_K911001) ]

Riboswitch that acts as a regulatory element, truncating transcripts when magnesium is not bound to the RNA. Four Mg2+ binding sites exist, giving this part significantly switch-like behavior. Binding of these sites by Mg2+ results in compaction of the regulatory region of the riboswitch, which in its unbound state acts as an anti-terminator. Loss of this anti-terminator activity results in the activity of a downstream terminator (included in this sequence) which terminates transcription of the gene. May also be affected by other divalent ions, such as manganese.


[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110024. Magnesium sensitive riboswitch (8 codon substitution)(Part:BBa_K911002) ]

Riboswitch that acts as a regulatory element, truncating transcripts when magnesium is not bound to the RNA. Four Mg2+ binding sites exist, giving this part significantly switch-like behavior. Binding of these sites by Mg2+ results in compaction of the regulatory region of the riboswitch, which in its unbound state acts as an anti-terminator. Loss of this anti-terminator activity results in the activity of a downstream terminator (included in this sequence) which terminates transcription of the gene. May also be affected by other divalent ions, such as manganese. This version also contains the first eight codons of the first downstream gene in the native Bacillus genome, MgtE. Substitution of the first eight codons of a reporter with these may improve reliability of change of reporter expression.


[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110085. Fast Germination (B.subtilis)(Part:BBa_K911008) ]

This part upregulates an operon responsible for germination rate. Bacillus subtilis spores germinate in the presence of L-Alanine. Up-regulation of the spoVA operon increases germination rate in response to L-Alanine. The promoter for the B.subtilis sspB gene (PsspB) is more active than the endogenous spoVA promoter. It is also active during germination. Expression of the spoVA operon under PsspB increases the germination rate. This construct consists mainly of the sspB promoter followed by the first 354bp of the spoVA operon (first 354bp of the spoVAA gene). Since B.subtilis exhibits accurate and efficient homologous recombination, a single cross-over event between the spoVAA region in the BioBrick and the endogenous spoVAA sequence inserts the sspB promoter upstream of the spoVA operon.


[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110096. Fluorescent ratiometric construct for standardizing promoter output(Part:BBa_K911009) ]

Biosensors may give unreliable outputs. This is due to differences in the number and state of the cells from test to test. By including an internal control signal, to which another inducible signal may be normalised, the reliability and reproducibility of a sensor may be significantly improved. The construct that uses an inducible eCFP (E0020) and a constitutively expressed eYFP (E0030) under the control of the constitutive promoter Pveg (K143012). The construct is optimized in both E. coli and B. subtilis, through the use of B. subtilis ribosome binding sites GsiB (K143020) and SpoVG (K143021).

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K9110067. Non-standard backbone for luciferase construct (Part:BBa_K911006) ]

This is the sequence of the non-standard backbone that our luciferase construct, BBa_k911004, was synthesised in. It could not be assembled in the high copy number standard psb1c3 backbone due to toxicity issues. Attempts to assemble the 9kb insert into psb3c5, a low copy number biobrick plasmid have so far been unsuccessful.


<groupparts>iGEM012 Cambridge</groupparts>