Difference between revisions of "Part:BBa K2289003"
 
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<partinfo>BBa_K2289003 short</partinfo>
 
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{{Template:ssDNA}}<br/>
 
{{Template:ssDNA}}<br/>
  
This part is a noncoding single-stranded DNA Aptazyme, this molecule combines 3 modules, an aptamer for recognition of Saxitoxin (related to the red tide), a HRP-mimicking DNAzyme for report the presence of the toxin, and linkers.
+
This part is an Aptazyme, a noncoding single-stranded DNA molecule that combines 3 modules, an aptamer for the recognition of Saxitoxin (related to the red tide),  
 +
a HRP-mimicking DNAzyme as a reporter for the presence of the toxin, and linkers that conect both domains (Aptamer and DNAzyme).
  
  
 
==Aptazyme==
 
==Aptazyme==
An aptazyme is a ssDNA molecule that can recognize a ligand and catalyze a reaction. The funcionality of this molecule depends on three modules; an aptamer, for  
+
Aptazyme is a ssDNA molecule that can recognize a ligand and catalyze a reaction. The funcionality of this molecule depends on three modules; an aptamer, for the
recognition of the ligand, a DNAzyme, for catalize the reaction and linkers, fundamental parts that can bind specific zones of the Aptazyme, and with that those
+
recognition of a ligand, a DNAzyme, htat catalize a reaction and linkers, fundamental parts that can be complementary to specific zones of the Aptazyme, sequestring
can act as kidnappers of the catalytic zone of the molecule. The linkers are fundamental, because they are placed in such a way that when the aptamer is not
+
the catalytic zone of the molecule. The linkers are eseential, because they are placed in such a way that when the aptamer is not interacting with the ligand,  
interacting with the ligand, the linkers are kidnapping the DNAzyme, altering the conformation of the DNAzyme (see Figure 1A).  
+
the linkers are capturing the DNAzyme and altering the conformation of the DNAzyme (see Figure 1A).  
  
When the aptamer interacts with the ligand, a conformational change takes place in the molecule, this conformational change promote the movement of the linkers
+
When the aptamer interacts with the ligand, a conformational change takes place in the molecule, this conformational change promotes the movement of the linkers
from the original place, and in consecuense the DNAzyme is released, with that the DNAzyme can take the catalytic conformation and can catalyse the reaction (see
+
from the original place, and consequently the DNAzyme is released. Then, the DNAzyme can structure the catalytic conformation and catalyze the reaction (see
 
Figure 1B).
 
Figure 1B).
  
[[File:UchileBiotec2017Figure1.png|thumb|500 px|center|'''Fig.1 Aptazyme.''']]
+
[[File:UchileBiotec2017Figure1.png|thumb|500 px|center|'''Fig.1 Aptazyme Conformational Changes.''' Each circle corresponds to a nucleotide. '''(A)''' Expected
 +
structure in an inactive conformation of the Aptazyme, you may notice that the linkers are sequestering the DNAzyme module, impeding its correct catalytic conformation. '''(B)'''
 +
In the presence of the ligand, the Aptamer module adopts its conformation with the ligand; consequently the linkers move releasing the DNAzyme that now can adopt
 +
its catalytic conformation. All this process leaves de Aptazyme on its active conformation.]]
  
This part consists on an Aptazyme that can recognise Saxitoxin (STX) and that can catalyse a chromogenic reaction.
+
This part (BBa_K2289003) consists on an Aptazyme that can recognise Saxitoxin (STX) and that can catalyse a chromogenic reaction with HRP-like enzymatic activity.
  
 
==Modules==
 
==Modules==
  
<b> STX M30f Aptamer ([https://parts.igem.org/Part:BBa_K2289004 Part:BBa_K2289004]): </b>  
+
*<b> STX M30f Aptamer ([https://parts.igem.org/Part:BBa_K2289004 Part:BBa_K2289004]): </b>  
 
It is an aptamer for saxitoxin, developed by Zheng et. al. 2015, this aptamer was selected by apool of aptamers. It has a dissociation constant (Kd)  
 
It is an aptamer for saxitoxin, developed by Zheng et. al. 2015, this aptamer was selected by apool of aptamers. It has a dissociation constant (Kd)  
of 0,133 uM. The aptamer's secondary structure is on Figure 2A.
+
of 0.133 µM. The aptamer's secondary structure is on Figure 2A.
  
<b> HRP-Mimicking DNAzyme ([https://parts.igem.org/Part:BBa_K1614007 Part:BBa_K1614007]): </b>  
+
*<b> HRP-Mimicking DNAzyme ([https://parts.igem.org/Part:BBa_K1614007 Part:BBa_K1614007]): </b>  
 
It is a DNAzyme developed by Travascio et. al. 1998. This DNAzyme, just as its name says, imitates the horseradish peroxidase catalytic activity, using  
 
It is a DNAzyme developed by Travascio et. al. 1998. This DNAzyme, just as its name says, imitates the horseradish peroxidase catalytic activity, using  
hydrogen peroxide as a substrate and a reducting agent, it has been demonstrated that works well with a chromogenic reactant, ABTS. This DNAzyme needs Hemin  
+
hydrogen peroxide as a substrate and a reducing agent, it has been demonstrated that works well with a chromogenic reactant, ABTS. This DNAzyme needs Hemin  
to act as a catalyst, it adopts a G-cuadruplex conformation that allows to form a complex with Hemin, that, at the same time enables the DNAzyme to catalyse  
+
to act as a catalyst, and when adopts a G-cuadruplex conformation allows the formation of a complex with Hemin, that, at the same time enables the DNAzyme to catalyse  
 
the reaction (see Figure 2B).
 
the reaction (see Figure 2B).
  
<b> J_4 linkers: </b>  
+
*<b> J_4 linkers: </b>  
 
These are linkers generated by the JAWS software developed by Team Heidelberg 2015. Each linker binds to a specific zone of the molecule, allowing the  
 
These are linkers generated by the JAWS software developed by Team Heidelberg 2015. Each linker binds to a specific zone of the molecule, allowing the  
 
inactive conformation of the Aptazyme. Those were calculated by the software to allow both conformations of the Aptazyme, the inactive one, and the active
 
inactive conformation of the Aptazyme. Those were calculated by the software to allow both conformations of the Aptazyme, the inactive one, and the active
in the presence of the ligand.
+
in the presence of the ligand. According to the software analysis, the DNAzyme with J_4 linkers has an inactive free energy of -12.87 Kcal/mol, and an active
 +
free energy of -6.32 Kcal/mol, with a free energy difference of 6.55 Kcal/mol.
  
[[File:UchileBiotec2017Figure2.png|thumb|500 px|center|'''Fig.2 Aptamer and DNAzyme.''']]
+
[[File:UchileBiotec2017Figure2.png|thumb|500 px|center|'''Fig.2 STX M30f Aptamer and HRP-mimicking DNAzyme. (A)''' The structure of the M30f aptamer, developed by Zhen
 +
et. al. (2015). '''(B)''' Reaction used in our lab studies with Aptazymes, the DNAzyme in the G-cuadruplex conformation forms a complex with Hemin, so it can catalyse
 +
the reaction of oxidation of ABTS, hydrogen peroxide mediated, the ABTS*- resulting is a chromogenic molecule that allows the optical detection by eye or by
 +
spectrophotometer at λ=414 nm.]]
  
 
==All in one==
 
==All in one==
  
<b> Inactive fold: </b> <b> Inactive fold: </b> We expect that the molecule folding in the absence of the toxin is the same as predicted by the [http://rna.tbi.univie.ac.at/cgi-bin/RNAWebSuite/RNAfold.cgi RNAfold WebServer]  
+
*<b> Inactive fold: </b> <b> Inactive fold: </b> We expect that the molecule folding in the absence of the toxin is the same as predicted by the  
 +
[http://rna.tbi.univie.ac.at/cgi-bin/RNAWebSuite/RNAfold.cgi RNAfold WebServer] (see Figure 3A), this prediction comes with a minimum free energy
 +
of -20.70 Kcal/mol. You may notice that the structure in the figure does not emulate well the kiddnaping system described above, this happens exclusively
 +
in this molecule, we decided to recalculate that in another server, [http://unafold.rna.albany.edu/?q=mfold/DNA-Folding-Form mfold WebServer], just to be
 +
sure that the structure was well predicted. The mfold WebServer structure prediction results were similar to the predicted structure by RNAfold WebServer
 
 
 +
*<b> In the presence of the toxin: </b> The expected conformation of the Aptazyme is on Figure 3B, we expect that when the toxin is present, the aptamer adopts
 +
other conformation so the J_4 linkers can move releasing the DNAzyme just as described above.
  
<b> In the presence of the toxin: </b>
 
  
<b> Dynamics and kinetics: </b>
+
[[File:UchileBiotec2017Figure3J 4.png|thumb|500 px|center|'''Fig.3 STX Aptazyme J_4 conformational changes.''' Each circle corresponds to a nucleotide. '''(A)''' Predicted
 +
structure of the Aptazyme on its inactive conformation. '''(B)''' We expect that in the presence of the toxin, the Aptazyme changes its inactive conformation to its active
 +
conformation, the structure of the aptamer interacting with the toxin that you can see is only representative because it is unknown.]]
 +
 
 +
==<b> Kinetics </b>==
 +
 
 +
*<b>Conditions:</b> In order to evaluate the kinetics of our parts, we determined the amounts of each reactive present in the reaction, see table I
 +
concentrations.
 +
 
 +
[[File:UchileBiotec2017Figure4.png|thumb|500 px|center|'''Table I ''' List of reactants and their concentrations in a total volume of reaction of 100 µL. We also used
 +
HEPES buffer 10 mM with 10 mM NaCl pH 7.1.]]
 +
 
 +
For more information about the methods used for these experiments, please visit [http://2017.igem.org/Team:UChile_Biotec/Experiments Protocols] in the Experiments section of our Wiki.
 +
 
 +
*<b>Results:</b>  
 +
 
 +
The experiments with this Aptazyme were done, but we could not have signifficant information about it. Anyway if you want so see the results related with this aptazyme
 +
you may go to [http://2017.igem.org/Team:UChile_Biotec/Results Results] section in our [http://2017.igem.org/Team:UChile_Biotec Wiki].
  
 
<!-- Add more about the biology of this part here
 
<!-- Add more about the biology of this part here
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<!-- -->
 
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 +
 
==<b>Sequence and Features</b>==
 
==<b>Sequence and Features</b>==
 
<partinfo>BBa_K2289000 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K2289000 SequenceAndFeatures</partinfo>
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P. Travascio, Y. Li, D. Sen. (1998). DNA-enghanced peroxidase activity of a DNA-aptamer-hemin complex. Chemistry and Biology, Vol 5 No 9. 505-517.
 
P. Travascio, Y. Li, D. Sen. (1998). DNA-enghanced peroxidase activity of a DNA-aptamer-hemin complex. Chemistry and Biology, Vol 5 No 9. 505-517.
 +
 +
C. Teller, C Shimnron, I. Willner. (2009). Aptamer-DNAzyme Hairpins for Amplified Biosensing. Anal. Chem., 81. 9114-9119.
  
 
<!-- Uncomment this to enable Functional Parameter display  
 
<!-- Uncomment this to enable Functional Parameter display  

Latest revision as of 00:52, 2 November 2017

STX Aptazyme J_4

Notice: Functional DNA

This part is a sequence of a functional ssDNA. It is only active as single-stranded DNA. It can not be cloned into a plasmid. For use order it as a DNA oligo.


This part is an Aptazyme, a noncoding single-stranded DNA molecule that combines 3 modules, an aptamer for the recognition of Saxitoxin (related to the red tide), a HRP-mimicking DNAzyme as a reporter for the presence of the toxin, and linkers that conect both domains (Aptamer and DNAzyme).


Aptazyme

Aptazyme is a ssDNA molecule that can recognize a ligand and catalyze a reaction. The funcionality of this molecule depends on three modules; an aptamer, for the recognition of a ligand, a DNAzyme, htat catalize a reaction and linkers, fundamental parts that can be complementary to specific zones of the Aptazyme, sequestring the catalytic zone of the molecule. The linkers are eseential, because they are placed in such a way that when the aptamer is not interacting with the ligand, the linkers are capturing the DNAzyme and altering the conformation of the DNAzyme (see Figure 1A).

When the aptamer interacts with the ligand, a conformational change takes place in the molecule, this conformational change promotes the movement of the linkers from the original place, and consequently the DNAzyme is released. Then, the DNAzyme can structure the catalytic conformation and catalyze the reaction (see Figure 1B).

Fig.1 Aptazyme Conformational Changes. Each circle corresponds to a nucleotide. (A) Expected structure in an inactive conformation of the Aptazyme, you may notice that the linkers are sequestering the DNAzyme module, impeding its correct catalytic conformation. (B) In the presence of the ligand, the Aptamer module adopts its conformation with the ligand; consequently the linkers move releasing the DNAzyme that now can adopt its catalytic conformation. All this process leaves de Aptazyme on its active conformation.

This part (BBa_K2289003) consists on an Aptazyme that can recognise Saxitoxin (STX) and that can catalyse a chromogenic reaction with HRP-like enzymatic activity.

Modules

It is an aptamer for saxitoxin, developed by Zheng et. al. 2015, this aptamer was selected by apool of aptamers. It has a dissociation constant (Kd) of 0.133 µM. The aptamer's secondary structure is on Figure 2A.

It is a DNAzyme developed by Travascio et. al. 1998. This DNAzyme, just as its name says, imitates the horseradish peroxidase catalytic activity, using hydrogen peroxide as a substrate and a reducing agent, it has been demonstrated that works well with a chromogenic reactant, ABTS. This DNAzyme needs Hemin to act as a catalyst, and when adopts a G-cuadruplex conformation allows the formation of a complex with Hemin, that, at the same time enables the DNAzyme to catalyse the reaction (see Figure 2B).

  • J_4 linkers:

These are linkers generated by the JAWS software developed by Team Heidelberg 2015. Each linker binds to a specific zone of the molecule, allowing the inactive conformation of the Aptazyme. Those were calculated by the software to allow both conformations of the Aptazyme, the inactive one, and the active in the presence of the ligand. According to the software analysis, the DNAzyme with J_4 linkers has an inactive free energy of -12.87 Kcal/mol, and an active free energy of -6.32 Kcal/mol, with a free energy difference of 6.55 Kcal/mol.

Fig.2 STX M30f Aptamer and HRP-mimicking DNAzyme. (A) The structure of the M30f aptamer, developed by Zhen et. al. (2015). (B) Reaction used in our lab studies with Aptazymes, the DNAzyme in the G-cuadruplex conformation forms a complex with Hemin, so it can catalyse the reaction of oxidation of ABTS, hydrogen peroxide mediated, the ABTS*- resulting is a chromogenic molecule that allows the optical detection by eye or by spectrophotometer at λ=414 nm.

All in one

  • Inactive fold: Inactive fold: We expect that the molecule folding in the absence of the toxin is the same as predicted by the

[http://rna.tbi.univie.ac.at/cgi-bin/RNAWebSuite/RNAfold.cgi RNAfold WebServer] (see Figure 3A), this prediction comes with a minimum free energy of -20.70 Kcal/mol. You may notice that the structure in the figure does not emulate well the kiddnaping system described above, this happens exclusively in this molecule, we decided to recalculate that in another server, [http://unafold.rna.albany.edu/?q=mfold/DNA-Folding-Form mfold WebServer], just to be sure that the structure was well predicted. The mfold WebServer structure prediction results were similar to the predicted structure by RNAfold WebServer

  • In the presence of the toxin: The expected conformation of the Aptazyme is on Figure 3B, we expect that when the toxin is present, the aptamer adopts

other conformation so the J_4 linkers can move releasing the DNAzyme just as described above.


Fig.3 STX Aptazyme J_4 conformational changes. Each circle corresponds to a nucleotide. (A) Predicted structure of the Aptazyme on its inactive conformation. (B) We expect that in the presence of the toxin, the Aptazyme changes its inactive conformation to its active conformation, the structure of the aptamer interacting with the toxin that you can see is only representative because it is unknown.

Kinetics

  • Conditions: In order to evaluate the kinetics of our parts, we determined the amounts of each reactive present in the reaction, see table I

concentrations.

Table I List of reactants and their concentrations in a total volume of reaction of 100 µL. We also used HEPES buffer 10 mM with 10 mM NaCl pH 7.1.

For more information about the methods used for these experiments, please visit [http://2017.igem.org/Team:UChile_Biotec/Experiments Protocols] in the Experiments section of our Wiki.

  • Results:

The experiments with this Aptazyme were done, but we could not have signifficant information about it. Anyway if you want so see the results related with this aptazyme you may go to [http://2017.igem.org/Team:UChile_Biotec/Results Results] section in our [http://2017.igem.org/Team:UChile_Biotec Wiki].


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]

References

X. Zheng, B. Hu, SX. Gao, D.J. Liu, M.J. Sun, B.H. Jiao, L.H. Wang. (2015). A saxitoxin-binding aptamer whith higher affinity and inhibitory activity optimized by rational site-directed mutagenesis and truncation. Toxicon 101. 41-47.

P. Travascio, Y. Li, D. Sen. (1998). DNA-enghanced peroxidase activity of a DNA-aptamer-hemin complex. Chemistry and Biology, Vol 5 No 9. 505-517.

C. Teller, C Shimnron, I. Willner. (2009). Aptamer-DNAzyme Hairpins for Amplified Biosensing. Anal. Chem., 81. 9114-9119.