Team:Grenoble-EMSE-LSU/Project/Biology

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                <p>KillerRed is a 240 amino acid protein with a 3D structure similar to other fluorescent proteins, with an eleven-strand beta-barrel surrounding an alpha-helix containing the chromophore, source of the protein's fluorescence and photoxicity.<br>
                <p>KillerRed is a 240 amino acid protein with a 3D structure similar to other fluorescent proteins, with an eleven-strand beta-barrel surrounding an alpha-helix containing the chromophore, source of the protein's fluorescence and photoxicity.<br>
                KillerRed has a DsRed-type chromophore formed with residues 67Q (glutamine), 68Y (tyrosine), and 69G (glycine), to make QYG. The corresponding coding sequence can be found in the DNA coding sequence CAGTACGGC.<br><br>
                KillerRed has a DsRed-type chromophore formed with residues 67Q (glutamine), 68Y (tyrosine), and 69G (glycine), to make QYG. The corresponding coding sequence can be found in the DNA coding sequence CAGTACGGC.<br><br>
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                The interesting properties of the protein are directly related to a unique structural difference among fluorescent proteins, consisting in an open channel linking the chromophore to the environment outside the protein. According to litterature, this is the reason KillerRed is able to produce 1000-fold more reactive oxygen species compared to EGFP which is another ROS-producing fluorescent protein <a href="#ref_bio_1">[2]</a>.</p>
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                The interesting properties of the protein are directly related to a unique structural difference among fluorescent proteins, consisting in an open channel linking the chromophore to the environment outside the protein. According to litterature, this is the reason KillerRed is able to produce 1000-fold more reactive oxygen species compared to EGFP which is another ROS-producing fluorescent protein <a href="#ref_bio_1">[3]</a>.</p>
                <h3>Origin</h3>
                <h3>Origin</h3>
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                                         <p id="legend">Figure 7.<br>Results of OD610 <em>(A)</em>, fluorescence at 540/630 nm <em>(B)</em> and number of cells per µL <em>C</em> as a function of time for both the dark (blue) and illuminated (red) samples.<br>Cell plating was performed every 60-80 min during the kinetic experiment, using serial dilutions. Each agar plate was incubated 12-13 h at 37°C prior to count colonies. Only the plates displaying between 30 and 300 visible colonies were considered for cell counting.<br><br></p>
                                         <p id="legend">Figure 7.<br>Results of OD610 <em>(A)</em>, fluorescence at 540/630 nm <em>(B)</em> and number of cells per µL <em>C</em> as a function of time for both the dark (blue) and illuminated (red) samples.<br>Cell plating was performed every 60-80 min during the kinetic experiment, using serial dilutions. Each agar plate was incubated 12-13 h at 37°C prior to count colonies. Only the plates displaying between 30 and 300 visible colonies were considered for cell counting.<br><br></p>
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                                       <p>Results show that the amount of living cells of the illuminated sample decreases significantly in response to constant light illumination (Fig 7.C). However, cells are killed significantly slower than in the experiments performed by Bulina et al., where 96% of the E. coli bacterial cell population was shown to be killed after 10 min of irradiation [XXXX]. This could be due to the important difference between the light doses applied to the culture from one experiment to the other (0.03 µW/cm2 in our case, against 1 W/cm2 for Bulina et. al). <br><br></p>
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                                       <p>Results show that the amount of living cells of the illuminated sample decreases significantly in response to constant light illumination (Fig 7.C). However, cells are killed significantly slower than in the experiments performed by Bulina et al., where 96% of the E. coli bacterial cell population was shown to be killed after 10 min of irradiation [6]. This could be due to the important difference between the light doses applied to the culture from one experiment to the other (0.03 µW/cm2 in our case, against 1 W/cm2 for Bulina et. al). <br><br></p>
                                       <p>In our case, the number of living cells only starts decreasing at time point 300 min, that is to say 120 min after the light source is switched on (Fig 7.C). One hypothesis is that bacterial cells viability is only affected after a sufficient accumulation of ROS-induced intracellular damages. This idea is confirmed by the fact that OD610 and fluorescence of the illuminated sample are still increasing between 180 and 300 min (Fig 7.A and B), meaning that illuminated cells are still able to divide and produce the KillerRed protein. However, a decrease in the growth rate of the illuminated bacteria occurs at time point 180 min, which proves that ROS start being produced and react with intracellular compartments from the really beginning of illumination. Fluorescence also tends to stabilize from 180 to 300 min, due to degradation of the KillerRed chromophore by light, known as photobleaching.  This phenomenon progressively counterbalances the increase in fluorescence resulting from the production and maturation of KillerRed proteins between 180 and 300 min. From time point 300 min occurs a decrease in fluorescence, combined to progressive stabilization of OD610: cells are progressively killed and are not able to divide or produce KillerRed anymore. <br><br></p>
                                       <p>In our case, the number of living cells only starts decreasing at time point 300 min, that is to say 120 min after the light source is switched on (Fig 7.C). One hypothesis is that bacterial cells viability is only affected after a sufficient accumulation of ROS-induced intracellular damages. This idea is confirmed by the fact that OD610 and fluorescence of the illuminated sample are still increasing between 180 and 300 min (Fig 7.A and B), meaning that illuminated cells are still able to divide and produce the KillerRed protein. However, a decrease in the growth rate of the illuminated bacteria occurs at time point 180 min, which proves that ROS start being produced and react with intracellular compartments from the really beginning of illumination. Fluorescence also tends to stabilize from 180 to 300 min, due to degradation of the KillerRed chromophore by light, known as photobleaching.  This phenomenon progressively counterbalances the increase in fluorescence resulting from the production and maturation of KillerRed proteins between 180 and 300 min. From time point 300 min occurs a decrease in fluorescence, combined to progressive stabilization of OD610: cells are progressively killed and are not able to divide or produce KillerRed anymore. <br><br></p>
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<h3>Comparison with mCherry: Cellular Death is ROS-mediated</h3>
<h3>Comparison with mCherry: Cellular Death is ROS-mediated</h3>
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<p>We demonstrated in the previous section that KillerRed-expressing bacteria could be killed upon white light illumination. However, exposure to white light and incubation outside of the normal temperature range were shown to affect bacterial growth <a href="#ref_bio_1">[6]</a>. Therefore, we decided to perform additional kinetics, using mCherry-expressing bacteria as a negative control. Results of these experiments demonstrated that KillerRed is responsible for cell death in response to white light stimulations.<br><br></p>
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<p>We demonstrated in the previous section that KillerRed-expressing bacteria could be killed upon white light illumination. However, exposure to white light and incubation outside of the normal temperature range were shown to affect bacterial growth <a href="#ref_bio_1">[7]</a>. Therefore, we decided to perform additional kinetics, using mCherry-expressing bacteria as a negative control. Results of these experiments demonstrated that KillerRed is responsible for cell death in response to white light stimulations.<br><br></p>
<h4>Kinetics</h4>
<h4>Kinetics</h4>
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<p id="legend">Figure 8.<br>OD610 <em>(A)</em> and fluorescence <em>(B)</em> as a function of time of mCherry and KillerRed expressing M15 bacteria. Constant light illumination at maximum intensity was applied from 180 min to 535 min. Temperature was measured in each Erlenmeyer during illumination and was shown to stay constant and equal to 37°C. The error bars represent the standard errors of 2 independent measurements.<br><br></p>
<p id="legend">Figure 8.<br>OD610 <em>(A)</em> and fluorescence <em>(B)</em> as a function of time of mCherry and KillerRed expressing M15 bacteria. Constant light illumination at maximum intensity was applied from 180 min to 535 min. Temperature was measured in each Erlenmeyer during illumination and was shown to stay constant and equal to 37°C. The error bars represent the standard errors of 2 independent measurements.<br><br></p>
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<p>Both cell strains display similar growth dynamics in the dark, with growth rates of 1.39h<sup>-1</sup> and 0.57 h<sup>-1</sup> in early (0-120 min) and late (120-180 min) exponential phase, respectively. At t = 255 min occurs a strong decrease in the growth rate of KillerRed-expressing cells as compared to mCherry-expressing cells. This phenomenon, described in the previous section, is due to the killing of bacteria in response to light stimulations. Since the viability of mCherry-expressing cells is not affected, we conclude that KillerRed is responsible for the decrease in the number of living bacteria when illuminating the sample with white light. Cell death is coupled to a decrease in the amount of fluorescing KillerRed proteins. This phenomenon, known as photobleaching, was shown to be a good indicator of the amount of ROS produced by KillerRed upon light illumination <a href="#ref_bio_1">[7]</a>. Free radicals such as H<sub>2</sub>O<sub>2</sub> are highly reactive, and cause damage to endogenous proteins and DNA, ultimately leading to cell death. <em>E. coli</em> defense mechanisms against oxidative stress, including the superoxide dismutase and catalase enzymes <a href="#ref_bio_1">[8]</a>, seem insufficient in preventing significant and irreversible ROS-mediated damages inside bacteria.</p>
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<p>Both cell strains display similar growth dynamics in the dark, with growth rates of 1.39h<sup>-1</sup> and 0.57 h<sup>-1</sup> in early (0-120 min) and late (120-180 min) exponential phase, respectively. At t = 255 min occurs a strong decrease in the growth rate of KillerRed-expressing cells as compared to mCherry-expressing cells. This phenomenon, described in the previous section, is due to the killing of bacteria in response to light stimulations. Since the viability of mCherry-expressing cells is not affected, we conclude that KillerRed is responsible for the decrease in the number of living bacteria when illuminating the sample with white light. Cell death is coupled to a decrease in the amount of fluorescing KillerRed proteins. This phenomenon, known as photobleaching, was shown to be a good indicator of the amount of ROS produced by KillerRed upon light illumination <a href="#ref_bio_1">[8]</a>. Free radicals such as H<sub>2</sub>O<sub>2</sub> are highly reactive, and cause damage to endogenous proteins and DNA, ultimately leading to cell death. <em>E. coli</em> defense mechanisms against oxidative stress, including the superoxide dismutase and catalase enzymes <a href="#ref_bio_1">[9]</a>, seem insufficient in preventing significant and irreversible ROS-mediated damages inside bacteria.</p>
<h3>Cell Growth Recovery after Stopping Illumination</h3>
<h3>Cell Growth Recovery after Stopping Illumination</h3>
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                                           <strong>[2]</strong> Sergei Pletnev et al., Structural Basis for Phototoxicity of the Genetically Encoded Photosensitizer KillerRed, <em>The Journal of Biological Chemistry</em>, November 2009.<br>
                                           <strong>[2]</strong> Sergei Pletnev et al., Structural Basis for Phototoxicity of the Genetically Encoded Photosensitizer KillerRed, <em>The Journal of Biological Chemistry</em>, November 2009.<br>
                                           <strong>[3]</strong> Russell B. Vegh et al., Reactive oxygen species in photochemistry of the red fluorescent protein ‘‘Killer Red’’, <em>Chem. Commun.</em>, 2011.<br>
                                           <strong>[3]</strong> Russell B. Vegh et al., Reactive oxygen species in photochemistry of the red fluorescent protein ‘‘Killer Red’’, <em>Chem. Commun.</em>, 2011.<br>
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                                           <strong>[4]</strong> 1] N C Shaner et al., Improved monomeric red, orange and yellow fluorescent proteins derived from <em>Discosomasp.</em> red fluorescent protein, <em>Nature Biotechnology</em>, 2004.<br>
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                                           <strong>[4]</strong> N C Shaner et al., Improved monomeric red, orange and yellow fluorescent proteins derived from <em>Discosomasp.</em> red fluorescent protein, <em>Nature Biotechnology</em>, 2004.<br>
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                                           <strong>[5]</strong> [2] W Waldeck et al., ROS-mediated killing efficiency with visible light of bacteria carrying different red fluorochrome proteins, <em>Journal of Photochemistry and Photobiology</em>, 2012.<br>
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                                           <strong>[5]</strong> W Waldeck et al., ROS-mediated killing efficiency with visible light of bacteria carrying different red fluorochrome proteins, <em>Journal of Photochemistry and Photobiology</em>, 2012.<br>
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                                           <strong>[6]</strong> J D Oliver, Recent findings on the viable but nonculturable state in pathogenic bacteria, <em>FEMS Microbiol. Rev.</em>, 2010.<br>
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                                           <strong>[6]</strong> <br>
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                                           <strong>[7]</strong> M E Bulina et al., Chromophore-assisted light inactivation (CALI) using the phototoxic fluorescent protein KillerRed, <em>Nature Protocol</em>, 2006.<br>
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                                          <strong>[7]</strong> J D Oliver, Recent findings on the viable but nonculturable state in pathogenic bacteria, <em>FEMS Microbiol. Rev.</em>, 2010.<br>
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                                           <strong>[8]</strong> E Cabiscol et al. Oxidative stress in bacteria and protein damage by reactive oxygen species, <em>International Microbiology</em>, 2000.<br></p>
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                                           <strong>[8]</strong> M E Bulina et al., Chromophore-assisted light inactivation (CALI) using the phototoxic fluorescent protein KillerRed, <em>Nature Protocol</em>, 2006.<br>
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                                           <strong>[9]</strong> E Cabiscol et al. Oxidative stress in bacteria and protein damage by reactive oxygen species, <em>International Microbiology</em>, 2000.<br></p>
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