Team:Valencia/Parts/Characterization
From 2009.igem.org
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<div align="justify" style="position:relative; top:-5px; left:30px; width:700px; color:black; font-size:10pt; font-family: Verdana"> | <div align="justify" style="position:relative; top:-5px; left:30px; width:700px; color:black; font-size:10pt; font-family: Verdana"> | ||
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+ | ==Aequorin characterization== | ||
AEQ is a gene which encodes for aequorin, our luminiscent protein. | AEQ is a gene which encodes for aequorin, our luminiscent protein. | ||
[[Image:aequorin.GIF|300px|center]] | [[Image:aequorin.GIF|300px|center]] | ||
- | It's a photoprotein isolated from luminescent jellyfish (like various Aequorea species like Aequorea victoria) and a variety of other marine organisms. It was originally isolated from the coelenterate by Osamu Shimomura, and it has been used as a reporter gene in different | + | It's a photoprotein isolated from luminescent jellyfish (like various ''Aequorea species'' like ''Aequorea victoria'') and a variety of other marine organisms. It was originally isolated from the coelenterate by Osamu Shimomura, and it has been used as a reporter gene in different eukariotes. Nowadays, there are different aequorin types, depending on the target organism. <br> |
- | The aequorin which we are working with has been introduced in our yeasts by a plasmid called pEVP11/AEQ, | + | The aequorin which we are working with has been introduced in our yeasts by a plasmid called pEVP11/AEQ, which encondes the aequorin sequence showed below. Cells containing this plasmid are able to sintetize apoaequorin, the apoprotein of 22 kDa. That apoprotein cannot produce luminiscence by itself, but when it binds to its cofactor coelenterazine, in presence of Ca2+, full aequorin emits light.<br> |
The two components of aequorin reconstitute spontaneously, forming the functional protein. The protein bears three EF-hand motifs that function as binding sites for Ca2+ ions. When Ca2+ occupies such sites, the protein undergoes a conformational change and converts through oxidation its prosthetic group, coelenterazine, into excited coelenteramide and CO2 (as we explain in Wetlab overview). As the excited coelenteramide relaxes to the ground state, blue light (wavelength = 469 nm) is emitted.<br> | The two components of aequorin reconstitute spontaneously, forming the functional protein. The protein bears three EF-hand motifs that function as binding sites for Ca2+ ions. When Ca2+ occupies such sites, the protein undergoes a conformational change and converts through oxidation its prosthetic group, coelenterazine, into excited coelenteramide and CO2 (as we explain in Wetlab overview). As the excited coelenteramide relaxes to the ground state, blue light (wavelength = 469 nm) is emitted.<br> | ||
==Sequence== | ==Sequence== | ||
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Aequorin sequence is (primer binding sites are underlined in green):<br> | Aequorin sequence is (primer binding sites are underlined in green):<br> | ||
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==Characterization== | ==Characterization== | ||
- | + | The aequorin-coelenterazine complex needs calcium to produce light. In the process this calcium enters through a special type of calcium channels present in the cell’s plasma membrane which open or close in response to a change in the transmembrane potential, that is why they are called voltage-dependent calcium channels (VDCC). The equation which describes calcium current through these channels is the following: | |
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- | + | Where g is the conductance associated with the channel, V is the transmembrane potential and ECa is the Nernst potential, related to the different ionic concentration inside and outside the cell. | |
+ | Considering that these channels are only permeable to calcium and have two states -open or closed-, the total conductance associated with the population of VDCCs can be expressed as the maximal conductance ( ) times the fraction of all channels that are open. This fraction is determined by hypothetical activation and inactivation variables m and h, which depend on voltage and time: | ||
- | + | VDCCs are well characterized in excitable cells such as neurons, where the value of is known: | |
- | + | Budding yeast, Saccharomyces cerevisiae has homologous voltage-dependent channels in its plasma membrane. However, there is a lack of study of the properties of these channels. That is why we have determined their conductance according to our experimental results: | |
- | + | Having characterized calcium entry to the cell, we studied the aequorin production of light through a calcium-mediated response after two types of stimulation: | |
- | + | • Chemical stimulation | |
+ | Alkali shock (performed by the addition of KOH) induced a calcium entry to cytoplasm (where aequorin is located) through voltage-dependent calcium channels. These calcium ions bind the aequorin-coelenterazine complex and photons –light- are emitted during a short period of time. This graph shows yeasts’ response to the addition of 30 µL of KOH: | ||
- | + | Furthermore, we made experiments with increasing KOH volumes (in microliters) and realized that light emission was higher: the more KOH arrives to cells, the more calcium ions get into the cytoplasm and more photons are emitted by aequorin. | |
- | + | It has to be noted that, in presence of suitable amounts of coelenterazine, the aequorin production of light can be repeated with several stimulations of 15 microliters each (where arrows show): | |
+ | Finally, we have proved that calcium enters through VDCCs, as yeast strains lacking this calcium channels (cch1 and mid1) emit less amount of light. Two negative controls (addition of EDTA, a quelant of calcium ions, and KCl, which do not perform alkali shock) are also included in this graph: | ||
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+ | • Electrical stimulation | ||
+ | Calcium entrance to cytosol –and the consequent aequorin light emission- can also be perfomed by applying electricity to the yeast culture. This response was characterized at different voltage values and times of application. Again, the stimulation was repeatable (stimulus applied where arrows): | ||
+ | *The following graph show data obtained with an ELISA plates reader which made discontinuous measures, one each 30 s. Therefore, we had not information about light production between dots. | ||
- | + | Although the previous graphs show that the second stimulation induces a lower amount of light, varying the time of stimulus application, higher peaks could be obtained: | |
- | + | ||
- | + | Similarly to chemical stimulation, yeast mutant strains lacking calcium channels had less light emission. Several negative controls were made to prove that light came from aequorin-transformed yeasts: | |
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+ | *The following graphs show data obtained with a continuous luminometer. It has to be noted the sharp peak of light produced when stimulation is applied (we were not able to detect it with the discontinuous measurements) | ||
+ | [[Image:eq1.jpg|center]] | ||
+ | [[Image:Comparació koh.jpg|center|520px]] | ||
+ | [[Image:Caracterització KOH.jpg|center|thumb|700px| Light emission under diferent concentrations of the chemical input]] | ||
[[Image:Repetibilitat KOH.jpg|700px]] | [[Image:Repetibilitat KOH.jpg|700px]] | ||
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===Electrical input=== | ===Electrical input=== | ||
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[[Image:1,5V 5st.jpg|center|thumb|700px| Light emitted when 1,5V are applicated during 5 seconds]] | [[Image:1,5V 5st.jpg|center|thumb|700px| Light emitted when 1,5V are applicated during 5 seconds]] | ||
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[[Image:24V 0,5s.jpg|center|thumb|700px| Light emitted when 24V are applicated during 0,5 seconds]] | [[Image:24V 0,5s.jpg|center|thumb|700px| Light emitted when 24V are applicated during 0,5 seconds]] | ||
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[[Image:6V variats disc.jpg|500px]] | [[Image:6V variats disc.jpg|500px]] | ||
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[[Image:Wt cont.jpg|center|thumb|700px| Our yeasts with coelentrazine ]] | [[Image:Wt cont.jpg|center|thumb|700px| Our yeasts with coelentrazine ]] | ||
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[[Image:Comparació disc.jpg|center|thumb|700px| Comparation of the results]] | [[Image:Comparació disc.jpg|center|thumb|700px| Comparation of the results]] | ||
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[[Image:Manteniment resposta disc.jpg|center|thumb|700px| Here, we can see that the process can be repeat consecutively]] | [[Image:Manteniment resposta disc.jpg|center|thumb|700px| Here, we can see that the process can be repeat consecutively]] | ||
[[Image:Combinació.jpg|center|thumb|700px| Comparation of the repetibility between our yeasts, our yeasts without coelenterazine, medium whit coelenterazine and mutants]] | [[Image:Combinació.jpg|center|thumb|700px| Comparation of the repetibility between our yeasts, our yeasts without coelenterazine, medium whit coelenterazine and mutants]] | ||
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Revision as of 20:28, 20 October 2009
Aequorin characterization
AEQ is a gene which encodes for aequorin, our luminiscent protein.
It's a photoprotein isolated from luminescent jellyfish (like various Aequorea species like Aequorea victoria) and a variety of other marine organisms. It was originally isolated from the coelenterate by Osamu Shimomura, and it has been used as a reporter gene in different eukariotes. Nowadays, there are different aequorin types, depending on the target organism.
The aequorin which we are working with has been introduced in our yeasts by a plasmid called pEVP11/AEQ, which encondes the aequorin sequence showed below. Cells containing this plasmid are able to sintetize apoaequorin, the apoprotein of 22 kDa. That apoprotein cannot produce luminiscence by itself, but when it binds to its cofactor coelenterazine, in presence of Ca2+, full aequorin emits light.
The two components of aequorin reconstitute spontaneously, forming the functional protein. The protein bears three EF-hand motifs that function as binding sites for Ca2+ ions. When Ca2+ occupies such sites, the protein undergoes a conformational change and converts through oxidation its prosthetic group, coelenterazine, into excited coelenteramide and CO2 (as we explain in Wetlab overview). As the excited coelenteramide relaxes to the ground state, blue light (wavelength = 469 nm) is emitted.
Sequence
Aequorin sequence is (primer binding sites are underlined in green):
Characterization
The aequorin-coelenterazine complex needs calcium to produce light. In the process this calcium enters through a special type of calcium channels present in the cell’s plasma membrane which open or close in response to a change in the transmembrane potential, that is why they are called voltage-dependent calcium channels (VDCC). The equation which describes calcium current through these channels is the following:
Where g is the conductance associated with the channel, V is the transmembrane potential and ECa is the Nernst potential, related to the different ionic concentration inside and outside the cell. Considering that these channels are only permeable to calcium and have two states -open or closed-, the total conductance associated with the population of VDCCs can be expressed as the maximal conductance ( ) times the fraction of all channels that are open. This fraction is determined by hypothetical activation and inactivation variables m and h, which depend on voltage and time:
VDCCs are well characterized in excitable cells such as neurons, where the value of is known:
Budding yeast, Saccharomyces cerevisiae has homologous voltage-dependent channels in its plasma membrane. However, there is a lack of study of the properties of these channels. That is why we have determined their conductance according to our experimental results:
Having characterized calcium entry to the cell, we studied the aequorin production of light through a calcium-mediated response after two types of stimulation:
• Chemical stimulation Alkali shock (performed by the addition of KOH) induced a calcium entry to cytoplasm (where aequorin is located) through voltage-dependent calcium channels. These calcium ions bind the aequorin-coelenterazine complex and photons –light- are emitted during a short period of time. This graph shows yeasts’ response to the addition of 30 µL of KOH:
Furthermore, we made experiments with increasing KOH volumes (in microliters) and realized that light emission was higher: the more KOH arrives to cells, the more calcium ions get into the cytoplasm and more photons are emitted by aequorin.
It has to be noted that, in presence of suitable amounts of coelenterazine, the aequorin production of light can be repeated with several stimulations of 15 microliters each (where arrows show):
Finally, we have proved that calcium enters through VDCCs, as yeast strains lacking this calcium channels (cch1 and mid1) emit less amount of light. Two negative controls (addition of EDTA, a quelant of calcium ions, and KCl, which do not perform alkali shock) are also included in this graph:
• Electrical stimulation Calcium entrance to cytosol –and the consequent aequorin light emission- can also be perfomed by applying electricity to the yeast culture. This response was characterized at different voltage values and times of application. Again, the stimulation was repeatable (stimulus applied where arrows):
- The following graph show data obtained with an ELISA plates reader which made discontinuous measures, one each 30 s. Therefore, we had not information about light production between dots.
Although the previous graphs show that the second stimulation induces a lower amount of light, varying the time of stimulus application, higher peaks could be obtained:
Similarly to chemical stimulation, yeast mutant strains lacking calcium channels had less light emission. Several negative controls were made to prove that light came from aequorin-transformed yeasts:
- The following graphs show data obtained with a continuous luminometer. It has to be noted the sharp peak of light produced when stimulation is applied (we were not able to detect it with the discontinuous measurements)
Electrical input