Difference between revisions of "Team:Ionis Paris/GLuc"
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| − | + | <h5 class="smallHd">The Gaussia Luciferase</h5> | |
| − | + | <h2 class="secHd">A bit of chemistry</h2> | |
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| + | <p>The Gaussia luciferase (GLuc) was identified from the marine copepod Gaussia princeps. Discovered relatively recently, this luciferase has been attracting attention as a potential reporter protein [1] and as a useful tool for bio-imaging applications. However, its biophysical properties have yet to be fully characterized.[2]</p> | ||
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| + | <p>This luciferase is coelenterazine-dependent. It catalyzes the oxidation of its substrate, coelenterazine, into coelenteramide to emit blue light with a peak emission at 488 nm. This reaction does not require ATP or other co-factors for activity and follows a simple equation[2][3].</p> | ||
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<p>GLuc shows the strongest bioluminescence intensity (over 200 fold more than the firefly Photinus pyralis and the Renilla reniformis luciferase bioluminescence activity). Moreover, this luciferase shows narrow substrate specificity and is highly specific for coelenterazine. [4] Among all other luciferases, GLuc has the highest ability to catalyze the oxidation of coelenterazine for the luminescence reaction and this catalytic activity was found to be highly stable under a wide range of temperatures and in an acidic environment. However, its activity is salt dependent (with the highest activity at 50mM NaCl), strongly inhibited by heavy metal ions (Cu2+) and stimulated by monovalent ions (Cl−, I−, Br−).[2][4]</p> | <p>GLuc shows the strongest bioluminescence intensity (over 200 fold more than the firefly Photinus pyralis and the Renilla reniformis luciferase bioluminescence activity). Moreover, this luciferase shows narrow substrate specificity and is highly specific for coelenterazine. [4] Among all other luciferases, GLuc has the highest ability to catalyze the oxidation of coelenterazine for the luminescence reaction and this catalytic activity was found to be highly stable under a wide range of temperatures and in an acidic environment. However, its activity is salt dependent (with the highest activity at 50mM NaCl), strongly inhibited by heavy metal ions (Cu2+) and stimulated by monovalent ions (Cl−, I−, Br−).[2][4]</p> | ||
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| − | <p>GLuc's sequence was first reported in 1999 by isolated the cDNA from G. princeps and cloning it in E.coli cells. This protein is composed of 185 amino acid residues including a putative signal peptide sequence for secretion. [5] With a molecular mass of 19.9 kDa and a short coding sequence (555 bp), it is the smallest known luciferase.< | + | <!-- ====ABOUT US==== --> |
| − | This protein is composed of two domains (Domain 1: residues 27–97; Domain 2: 98–168) linked together and preceded by a pre-sequence (residues 1 – 26). GLuc is predicted to be a helical protein, and sequence alignment predicts that each domain contains two intra-domain disulfide bonds and an inter-domain disulfide bond between cysteines C59 and C120. </p> | + | |
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| + | <h5 class="smallHd">GLuc</h5> | ||
| + | <h2 class="secHd">Protein structure</h2> | ||
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| + | <p>GLuc's sequence was first reported in 1999 by isolated the cDNA from G. princeps and cloning it in E.coli cells. This protein is composed of 185 amino acid residues including a putative signal peptide sequence for secretion. [5] With a molecular mass of 19.9 kDa and a short coding sequence (555 bp), it is the smallest known luciferase.</p> | ||
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| + | <p>This protein is composed of two domains (Domain 1: residues 27–97; Domain 2: 98–168) linked together and preceded by a pre-sequence (residues 1 – 26). GLuc is predicted to be a helical protein, and sequence alignment predicts that each domain contains two intra-domain disulfide bonds and an inter-domain disulfide bond between cysteines C59 and C120. </p> | ||
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| + | <img src="https://static.igem.org/mediawiki/2016/b/bd/Gluc_photo_2.1.jpg" alt=""> | ||
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<p>The highly conserved regions comprised of residues 52–77 in Domain 1 and 123–148 in Domain 2 seems to overlap with the active site. [2][4] Gaussia luciferase possesses a natural secretory signal (residues 1-16) composed of an N-terminal basic residue linked to a stretch of amino acids containing a hydrophobic core. [5] Upon expression, the luciferase is secreted into the cell medium. Therefore, lysing cells in order to assay GLuc activity is not necessary. [2] </p> | <p>The highly conserved regions comprised of residues 52–77 in Domain 1 and 123–148 in Domain 2 seems to overlap with the active site. [2][4] Gaussia luciferase possesses a natural secretory signal (residues 1-16) composed of an N-terminal basic residue linked to a stretch of amino acids containing a hydrophobic core. [5] Upon expression, the luciferase is secreted into the cell medium. Therefore, lysing cells in order to assay GLuc activity is not necessary. [2] </p> | ||
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| + | <!-- ====ABOUT US==== --> | ||
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| + | <p><b>References (Links are provided when available):</b></p> | ||
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<li><p><a href="http://www.sciencedirect.com/science/article/pii/S0006291X0702308X">S. Inouye, Y. Sahara, Identification of two catalytic domains in a luciferase secreted by the copepod Gaussia princeps, Biochem. Biophys. Res. Commun. 365 (2008) 96–101.</a></p> | <li><p><a href="http://www.sciencedirect.com/science/article/pii/S0006291X0702308X">S. Inouye, Y. Sahara, Identification of two catalytic domains in a luciferase secreted by the copepod Gaussia princeps, Biochem. Biophys. Res. Commun. 365 (2008) 96–101.</a></p> | ||
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Revision as of 12:10, 17 October 2016
The Gaussia luciferase (GLuc) was identified from the marine copepod Gaussia princeps. Discovered relatively recently, this luciferase has been attracting attention as a potential reporter protein [1] and as a useful tool for bio-imaging applications. However, its biophysical properties have yet to be fully characterized.[2] This luciferase is coelenterazine-dependent. It catalyzes the oxidation of its substrate, coelenterazine, into coelenteramide to emit blue light with a peak emission at 488 nm. This reaction does not require ATP or other co-factors for activity and follows a simple equation[2][3]. GLuc shows the strongest bioluminescence intensity (over 200 fold more than the firefly Photinus pyralis and the Renilla reniformis luciferase bioluminescence activity). Moreover, this luciferase shows narrow substrate specificity and is highly specific for coelenterazine. [4] Among all other luciferases, GLuc has the highest ability to catalyze the oxidation of coelenterazine for the luminescence reaction and this catalytic activity was found to be highly stable under a wide range of temperatures and in an acidic environment. However, its activity is salt dependent (with the highest activity at 50mM NaCl), strongly inhibited by heavy metal ions (Cu2+) and stimulated by monovalent ions (Cl−, I−, Br−).[2][4] GLuc's sequence was first reported in 1999 by isolated the cDNA from G. princeps and cloning it in E.coli cells. This protein is composed of 185 amino acid residues including a putative signal peptide sequence for secretion. [5] With a molecular mass of 19.9 kDa and a short coding sequence (555 bp), it is the smallest known luciferase. This protein is composed of two domains (Domain 1: residues 27–97; Domain 2: 98–168) linked together and preceded by a pre-sequence (residues 1 – 26). GLuc is predicted to be a helical protein, and sequence alignment predicts that each domain contains two intra-domain disulfide bonds and an inter-domain disulfide bond between cysteines C59 and C120. The highly conserved regions comprised of residues 52–77 in Domain 1 and 123–148 in Domain 2 seems to overlap with the active site. [2][4] Gaussia luciferase possesses a natural secretory signal (residues 1-16) composed of an N-terminal basic residue linked to a stretch of amino acids containing a hydrophobic core. [5] Upon expression, the luciferase is secreted into the cell medium. Therefore, lysing cells in order to assay GLuc activity is not necessary. [2] References (Links are provided when available):The Gaussia Luciferase
A bit of chemistry
GLuc
Protein structure
