Team:Peking/secondtry/Degradation

From 2014.igem.org

(Difference between revisions)
 
(12 intermediate revisions not shown)
Line 2: Line 2:
{{:Team:Peking/tmp/inside1}}
{{:Team:Peking/tmp/inside1}}
<html>
<html>
-
 
+
<head>
 +
<style type="text/css">
 +
<sup { vertical-align: top; font-size: 0.6em; }
 +
</style>
 +
</head>
<div id="titlepic">
<div id="titlepic">
<!-- InstanceBeginEditable name="wcgtitlepic" -->
<!-- InstanceBeginEditable name="wcgtitlepic" -->
Line 15: Line 19:
<!--*******************导航栏*******************导航栏*******************导航栏*******************导航栏*******************导航栏**********************-->
<!--*******************导航栏*******************导航栏*******************导航栏*******************导航栏*******************导航栏**********************-->
-
<li><a href="https://2014.igem.org/Team:Peking/secondtry/project/degradation#decontamination01">Introduction</a></li>
+
<li><a href="https://2014.igem.org/Team:Peking/secondtry/degradation#decontamination01">Introduction</a></li>
-
<li><a href="https://2014.igem.org/Team:Peking/secondtry/project/degradation#decontamination02">Design</a></li>
+
<li><a href="https://2014.igem.org/Team:Peking/secondtry/degradation#decontamination02">Design</a></li>
-
<li><a href="https://2014.igem.org/Team:Peking/secondtry/project/degradation#decontamination03">Results</a></li>
+
<li><a href="https://2014.igem.org/Team:Peking/secondtry/degradation#decontamination03">Results</a></li>
<!--*******************导航栏结束*******************导航栏结束*******************导航栏结束*******************导航栏结束**********************-->
<!--*******************导航栏结束*******************导航栏结束*******************导航栏结束*******************导航栏结束**********************-->
Line 27: Line 31:
<h2 id="decontamination01">Introduction</h2>  
<h2 id="decontamination01">Introduction</h2>  
-
<p>Apart from lack of sunlight in the water and anoxia caused by cyanobacteria itself, the potential detrimental effect of alga secreted toxin should be noticed. One of the  
+
<p>Apart from lack of sunlight in the water and anoxia caused by cyanobacteria itself, the potential detrimental effect of alga secreted toxin should be noticed. One of the most harmful toxin is called microcystin (MC), which has severe hepatotoxicity. The work in this part is to degrade MCs in water environment during an algal bloom.</p>
-
most harmful toxin is called microcystin(MC), which has severe hepatotoxicity. The work in decontamination part is to degrade MCs in water environment during an algal
+
<p>To accomplish this work, the potent microcystin-degrading enzyme-MlrA, originally from <i>Sphingomonas</i> is utilized. This enzyme can cleavage the ring structure in microcystin, significantly reducing the toxicity of the protein. Since MCs is released into water by algae, secretion for MlrA is also necessary to facilitate the degradation of MCs.</p>
-
bloom. </p>
+
<p>Based on utility of MlrA, we measure its degradation efficiency expressed by <i>E. coli</i>. The results indicate that our engineered bacteria could express functional MlrA and degrade MC-LR to a certain extent. Moreover, secretion signal peptide is considered to be introduced for better degradation performance.</p>
-
<p>To accomplish this work, the potent microcystin-degrading enzyme-MlrA, originally from Sphingomonas is utilized. This enzyme can cleavage the ring structure in
+
-
microcystin, significantly reducing the toxicity of the protein. Since MCs is released into water by algae, secretion for MlrA is also necessary to facilitate the degradation of
 
-
 
-
MCs.</p>
 
-
<p>Based on utility of MlrA, we measure the degradation efficiency of the living bacteria, the periplasmic protein and the lysed whole cell production. The results indicate
 
-
 
-
that our engineered bacteria could degrade MC-LR to a certain extent.</p>
 
<h2 id="decontamination02">Design</h2>  
<h2 id="decontamination02">Design</h2>  
-
<p>MCs are widespread toxic cyclic heptapeptides produced by many species of algae with different variants(Fig. 1). MCs are synthesized by polyketide synthases (PKS) and  
+
<h3>Microcystin and MlrA enzyme</h3>
 +
<p>MCs are widespread toxic cyclic heptapeptides produced by many species of algae with different variants (Fig. 1). MCs are synthesized by polyketide synthases (PKS) and non-ribosomal peptide synthetases (NRPS) pathway. Among different variants, MC-LR is a widespread and deleterious one.</p>
-
non-ribosomal peptide synthetases (NRPS) pathway. Among different variants, MC-LR is a widespread and deleterious one.</p>
+
<figure><img src="https://static.igem.org/mediawiki/2014/b/ba/Peking2014jyj_1.png"/><figcaption>Fig. 1 Structure of MCs. MCs share cyclic structure of cyclo-(-D-Ala-L-X-MeAsp-L-Z-Adda-D-Glu-Mdha), where X and Z are variable.<sup>[1]</sup></figcaption></figure>
-
<figure><img src="https://static.igem.org/mediawiki/2014/b/ba/Peking2014jyj_1.png"/><figcaption>Fig. 1 Structure of MCs. MCs share cyclic structure of cyclo-(-D-Ala-L-X-
+
<p>The most known mechanism of its toxicity is that MCs can inhibit protein phosphatase 1(PP1) and 2A (PP2A) specifically and efficiently.<sup>[2]</sup> The inhibition can lead to a severe disorder of biochemical reaction and disorganization of cytoskeleton in many eukaryotic cell. Many routine tools of decontamination cannot significantly reduce activities of MCs. Here, we propose a new idea of biodegradation, which could degrade MCs effectively without apparent side effects.</p>
-
MeAsp-L-Z-Adda-D-Glu-Mdha), where X and Z are variable.[1]</figcaption></figure>
+
<p>Many bacterial species have been reported to have ability to degrade MCs. Among them, a gene cluster in <i>Sphingomonas</i> has been found and sequenced. The cluster includes four genes, mlrA, mlrB, mlrC and mlrD, which can hydrolyze MCs and facilitate absorption of the products as carbon source. During the degradation process, the first-step linearized product, which is catalyzed by MlrA, shows much weaker hepatoxin compared with MCs. In the experiment of mouse bioassay, up to 250 mg/kg of linearized MC-LR shows no toxicity to mouse, much higher than 50% lethal dose 50mg/kg of cyclic MC-LR. Furthermore, the linearization also raises the median inhibition concentration to 95nM, around 160 times higher than original 0.6nM. <sup>[3]</sup> (Fig. 2)</p>
-
<p>The most known mechanism of its toxicity is that MCs can inhibit protein phosphatase 1(PP1) and 2A (PP2A) specifically and efficiently.[2] The inhibition can lead to a
 
-
severe disorder of biochemical reaction and disorganization of cytoskeleton in many eukaryotic cell.</p>
+
<figure><img src="https://static.igem.org/mediawiki/2014/0/05/Peking2014jyj_2.png"/><figcaption>Fig. 2 First step of biodegradation of MC-LR. MlrA mediates breaking peptide bond between Adda and Arg, which leads to significant decrease of toxicity.[3]</figcaption></figure>
-
<p>Many routine tools of decontamination cannot significantly reduce activities of MCs. Here, we propose a new idea of biodegradation, which could degrade MCs
+
<h3>Secretion System</h3>
-
effectively without apparent side effects.</p>
+
<p>In order to enhance the degradation effect, location of MlrA should be considered. There are some porins proteins on the outer membrane of <i>E. coli</i>, which allow small molecules, including MCs, to penetrate the membrane. Consequently, it is sufficient to secret MlrA into periplasm for decontamination.</p>
-
<p>Many bacterial species have been reported to have ability to degrade MCs. Among them, a gene cluster in Sphingomonas has been found and sequenced. The cluster
+
-
includes four genes, mlrA, mlrB, mlrC and mlrD, which can hydrolysze MCs and facilitate absorption of the products as carbon source. During the degradation process, the  
+
<p>Sec pathway, which belongs to Type II secretion system that exports proteins to periplasm, enters our sight. During the exporting process, target protein is translocated across inner membrane in unfolded conformation and is refolded in the periplasm. [4] A signal peptide is required for the transportation system to recognize the target protein. After export, the peptide is cut off in the periplasm. Particularly, one of them from Pectate lyase B (PelB) holds little limitation to the following protein’s molecular weight and has been widely used in protein secretion. Consequently, we finally decide to use PelB signal peptide to secrete the MlrA protein.</p>
-
first-step linearized product, which is catalyzed by MlrA, shows much weaker hepatoxin compared with MCs. In the experiment of mouse bioassay, up to 250 mg/kg of
 
-
 
-
linearized MC-LR shows no toxicity to mouse, much higher than 50% lethal dose 50mg/kg of cyclic MC-LR. Furthermore, the linearization also raise the median inhibition
 
-
 
-
concentration to 95nM, around 160 times higher than original 0.6nM. [3] (Fig. 2)</p>
 
-
 
-
<figure><img src="https://static.igem.org/mediawiki/2014/0/05/Peking2014jyj_2.png"><figcaption>Fig. 2 First step of biodegradation of MC-LR. MlrA mediates breaking
 
-
 
-
peptide bond between Adda and Arg, which leads to significant decrease of toxicity.[3]</figcaption></figure>
 
-
 
-
 
-
<p>In order to enhance the degradation effect, location of MlrA should be considered. There are some porins proteins on the outer membrane of E. coli, which allow small
 
-
 
-
molecules, including MCs, to penetrate the membrane. Consequently, it is sufficient to secret MlrA into periplasm for decontamination. </p>
 
<h2 id="decontamination03">Result</h2>  
<h2 id="decontamination03">Result</h2>  
-
<p>We construct a vector for secretion using Sec pathway(Fig. 3), which belongs to Type II secretion system that exports proteins to periplasm. During the exporting process,
 
-
target protein is translocated across inner membrane in unfolded conformation and is refolded in the periplasm.[4]</p>
+
<h3>1. Constructing method for analysis of MC concentration</h3>
-
<p>A signal peptide called Pectate lyase B (PelB) in Sec pathway is required for the transportation system to recognize the protein to be export and the signal peptide can be  
+
<p>p-Nitrophenyl phosphate (pNPP) is a widely  used non-specific substrate to test protein phosphatase activity and it can be hydrolyzed to p-Nitrophenyl(pNP) with characteristic absorption at 405nm. The  measurement of PP1 activity is based on the accumulation of pNP. Considering  the microcystin (MC) is the inhibitor of PP1 and MlrA can disrupt MC’s  structure to disrupt its inhibitory effect, the MlrA activity can be detected  by quantification of absorption at 405nm. (Fig. 4) So the concentration of MCs  after degradation can be finally measured by absorption spectrophotometry  method with all the calibration curves for all the interactions above.</p>
-
cut off in the periplasm. Since the PelB signal peptide holds little limitation to the following protein’s molecular weight, we finally decide to use PelB to secrete the MlrA  
+
<figure><img src="https://static.igem.org/mediawiki/2014/f/f8/Peking2014jyj_3.png"/><figcaption>Fig. 3 Measurement of MlrA activity. The OD405 indicates the concentration of pNP, and the change of pNP level could reflect the PP1 activity(a). MC can strongly inhibit the PP1 activity(b), and the MlrA can cleave the MC and dampen its toxicity(c).</figcaption></figure>
-
protein. </p>
+
<p>Firstly a calibration curve of PP1 activity  was generated. The concentration of substrate pNP is sufficient overall so the  PP1 enzyme is saturated and proportion to the accumulation rate of product  pNPP. We could select a proper working concentration of PP1 in the range of  nearly linear relationship between PP1 and change rate of 405nm absorption.</p>
-
<figure><img src="https://static.igem.org/mediawiki/2014/f/f8/Peking2014jyj_3.png"><figcaption>Fig. 3 Secretion vector of mlrA. The fusion protein includes Type II
+
<figure><img src="https://static.igem.org/mediawiki/2014/2/26/Peking2014jyj_4.png"/><figcaption>Fig. 4 Calibration curve of PP1. p-Nitrophenyl Phosphate solution is treated with different concentration of PP1 solutions. Absorbance at 405nm was measured after 80 minutes. The absorbance increases in direct proportion to PP1 concentration between 0.02-0.1 unit/ul.</figcaption></figure>
-
secretion peptide pelB and mlrA. The construction as a whole is expressed in pET-21a(+) plasmid.</figcaption></figure>
+
<p>Based on the premise of linear relationship  between product and absorbance, we choose 0.05unit/ul as the working  concentration of PP1 and then test the inhibition efficiency of MC-LR. As a result, PP1 activity decreases after the addition of MC-LR and there is a  positive correlation between the reduction of absorbance and concentration of MC-LR.</p>
 +
<figure><img src="https://static.igem.org/mediawiki/2014/d/d4/Peking2014jyj_5.png"/><figcaption>Fig. 5 Inhibition efficiency of MC-LR. Working concentration of PP1 is 0.05 unit/ul. Different concentration of MC-LR samples are added to the reaction system. MC-LR shows strong inhibition of PP1 activity and a rapid change of PP1 activity is observed between 10ug/L to 30 ug/L of MC-LR concentration.</figcaption></figure>
-
<p>The concentration of MCs can be tested in PP1 inhibition assays. As mentioned, MCs can inhibit the activity of PP1 effectively. Thus we constructed a standard curve
+
<h3>2. Verifying the degradation effect of MlrA</h3>
 +
<p>To test the degradation efficiency of MlrA  expressed by <i>E. coli</i>, MlrA expression plasmid has been constructed and  transformed into <i>E. coli</i> strain BL21(DE3). (Fig. 6a) After induction, the bacteria are lysed by lysozyme and incubated with MC solution. Judged by PP1 activity treated by the mixture, the activity in experiment group expressing  MlrA is much higher than strain carrying blank vectors, suggesting that MC-LR  is degraded. (Fig. 6b) Therefore, it could be concluded that MlrA function well  in <i>E. coli</i> expression system.</p>
-
reflecting the relation between the concentration of MC and the relative activity of PP1. Therefore, the concentration of MCs in any solution could be quantified by measuring
+
<figure><img src="https://static.igem.org/mediawiki/2014/3/35/Peking2014jyj_6.png"/><figcaption>Fig. 6 Plasmid construction and results of degradation assays. (a) In our expression plasmid, MlrA is expressed in expression vector pET-21a, while blank vector is used as a negative control. (b) The result shows that MlrA expressed by <i>E. coli</i> has obvious function in degrading MC, which significantly reducing the inhibition effect of MC to PP1.</figcaption></figure>
-
corresponding PP1 relative activity.</p>
+
<h3>3. Attempting to secreting MlrA</h3>
-
<p>p-Nitrophenyl phosphate (pNPP) is a widely used non-specific substrate to test protein phosphatase activity and it can be hydrolyzed to p-Nitrophenyl(pNP) with
+
-
characteristic absorption at 405nm. The measurement of PP1 activity is based on the accumulation of pNP. Considering the microcystin(MC) is the inhibitor of PP1 and MlrA  
+
<p>MlrA exhibits high degradation activity in  lysis culture. Its activity, however, has no difference with control group.(Fig. 6b) The result suggests that our bacteria are unable to deal with MC immediately until they commit suicide. Thus, secretion system PelB is introduced. The PelB is linked to N-terminal of MlrA and the fusion protein is  inserted into expression vector. We hope this measure would improve degradation  effect largely in whole cell level.</p>
-
can disrupt MC’s structure to disrupt its inhibitory effect, the MlrA activity can be detected by quantification of absorption at 405nm. (Fig. 4)</p>
+
<figure><img src="https://static.igem.org/mediawiki/2014/7/77/Peking2014jyj_7.png"/><figcaption>Fig. 7 Secretion sequence of mlrA. The fusion protein includes Type II secretion peptide pelB and mlrA. The construction as a whole is expressed in pET-21a(+) plasmid.</figcaption></figure>
-
 
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/2/26/Peking2014jyj_4.png"><figcaption>Fig. 4 Measurement of MlrA activity. The OD405 indicates the
+
-
 
+
-
concentration of pNP, and the change of pNP level could reflect the PP1 activity(a). MC can strongly inhibit the PP1 activity(b), and the MlrA can cleave the MC and dampen
+
-
 
+
-
its toxicity(c).</figcaption></figure>
+
-
 
+
-
 
+
-
 
+
-
<p>So the concentration of MCs after degradation can be finally measured by absorption spectrophotometry method with all the calibration curves for all the interactions
+
-
 
+
-
above.</p>
+
-
<p>Firstly a calibration curve of PP1 activity was generated. The concentration of substrate pNP is sufficient overall so the PP1 enzyme is saturated and proportion to the
+
-
 
+
-
accumulation rate of product pNPP. We could select a proper working concentration of PP1 in the range of nearly linear relationship between PP1 and change rate of 405nm
+
-
 
+
-
absorption.</p>
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/d/d4/Peking2014jyj_5.png"><figcaption>Fig. 5 Calibration curve of PP1. p-Nitrophenyl Phosphate solution is  
+
-
 
+
-
treated with different concentration of PP1 solutions. Absorbance at 405nm was measured after 80 minutes. The absorbance increases in direct proportion to PP1
+
-
 
+
-
concentration between 0.02-0.1 unit/ul.</figcaption></figure>
+
-
 
+
-
 
+
-
<p>We choose 0.05unit/ul as the working concentration of PP1 and then test the inhibition efficiency of MC-LR because in this region absorbance displays a nearly linear
+
-
 
+
-
relationship with PP1 concentration less than 0.05 unit/uL. As a result, PP1 activity decreases after the addition of MC-LR and there is a positive correlation between the
+
-
 
+
-
reduction of absorbance and concentration of MC-LR.</p>
+
-
 
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/3/35/Peking2014jyj_6.png"><figcaption>Fig. 6 Inhibition efficiency of MC-LR. Working concentration of PP1 is 0.05
+
-
 
+
-
unit/ul. Different concentration of MC-LR samples are added to the reaction system. MC-LR shows strong inhibition of PP1 activity and a rapid change of PP1 activity is
+
-
 
+
-
observed between 10ug/L to 30 ug/L of MC-LR concentration.
+
-
</figcaption></figure>
+
-
 
+
-
 
+
-
<p>To test the efficiency, a degradation assay is performed. MlrA coding sequence and PelB signal peptide is inserted into the pET-21a(+) plasmid. This plasmid is
+
-
 
+
-
transformed into E. coli strain BL21(DE3) as a secretion vector. Bacteria carrying a blank vector and an expression vector without the addition of signal peptide are used as
+
-
 
+
-
control.</p>
+
-
 
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/3/35/Peking2014jyj_7.png"><figcaption>Fig. 7 Expression vector for degradation assays. Vector (a) is our secretion
+
-
 
+
-
system. There are 2 negative controls. Blank Vector (b) is used as a negative control of MlrA expression system while vector (c) without any signal peptide is used as a negative
+
-
 
+
-
control of pelB signal peptide.</figcaption></figure>
+
-
 
+
-
 
+
-
<p>First we test if MlrA is expressed in E. coli correctly. We treat bacteria with lysozyme solution to accelerate periplasm protein release. MC-LR is then added to the solution. After co-cultivation we test MC concentration of the sample with by spectrophotometry described above. The absorbance of bacteria solutions carrying MlrA gene, regardless of the existence of PelB secretion peptide, is much higher than control group, indicating that MlrA is correctly expressed.</p>
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/3/35/Peking2014jyj_8.png"><figcaption>Fig. 8 Test of periplasm expression. Bacteria carryting vector (a), (b) and (c) are treated with same volume of lysozyme solution and MC-LR is then added, at a final concentration of 100ug/L. After 12 hours of co-cultivation, the sample is diluted and added to the reaction system as describe before. Absorbance of group (b) and (c) is much higher than that of group (a).</figcaption>
+
-
 
+
-
<p>MC-LR is co-cultivated with the bacteria and the sample was measured as before to test the degradation efficiency. The MC-LR rest can be tested by spectrophotometry
+
-
 
+
-
described above. The absorbance of bacteria carrying vector(b) is higher than that bacteria carrying blank vectors, suggesting that MlrA exhibits some activity towards MC-LR.
+
-
 
+
-
But there is no big difference between vector (b) and vector (c), which shows no evidence of effect of pelB signal peptide so far.</p>
+
-
 
+
-
<figure><img src="https://static.igem.org/mediawiki/2014/3/35/Peking2014jyj_8.png"><figcaption>Fig. 8 Degradation efficiency of MC-LR. MC-LR is added to E. coli culture
+
-
 
+
-
at a final concentration of 100ug/L. After 12, 36 and 72 hours of co-cultivation, the sample is sterilized, diluted and added to the reaction system as describe before.
+
-
 
+
-
2 Vector described in Fig. 7 are used as control experiment. The result shows that MlrA has some degradation activity toward MCs, while the secretion system seem to be
+
-
 
+
-
ineffective.</figcaption></figure>
+
-
 
+
-
<br><br><br><br><br>
+
<p>References</p>
<p>References</p>
-
<p>[1] Gehringer, M. M., Milne, P., Lucietto, F., &amp; Downing, T. G. (2005). Comparison of the structure of key variants of microcystin to vasopressin.Environmental toxicology  
+
<p>[1] Gehringer, M. M., Milne, P., Lucietto, F., &amp; Downing, T. G. (2005). Comparison of the structure of key variants of microcystin to vasopressin.Environmental toxicology and pharmacology, 19(2), 297-303.</p>
-
 
+
<p>[2] Runnegar, M., Berndt, N., Kong, S. M., Lee, E. Y., &amp; Zhang, L. F. (1995). In vivo and in vitro binding of microcystin to protein phosphatase 1 and 2A.Biochemical and biophysical research communications, 216(1), 162-169.</p>
-
and pharmacology, 19(2), 297-303.</p>
+
<p>[3] Bourne, D. G., Jones, G. J., Blakeley, R. L., Jones, A., Negri, A. P., &amp; Riddles, P. (1996). Enzymatic pathway for the bacterial degradation of the cyanobacterial cyclic peptide toxin microcystin LR. Applied and environmental microbiology, 62(11), 4086-4094.</p>
-
<p>[2] Runnegar, M., Berndt, N., Kong, S. M., Lee, E. Y., &amp; Zhang, L. F. (1995). In vivo and in vitro binding of microcystin to protein phosphatase 1 and 2A.Biochemical and  
+
-
 
+
-
biophysical research communications, 216(1), 162-169.</p>
+
-
<p>[3] Bourne, D. G., Jones, G. J., Blakeley, R. L., Jones, A., Negri, A. P., &amp; Riddles, P. (1996). Enzymatic pathway for the bacterial degradation of the cyanobacterial cyclic  
+
-
peptide toxin microcystin LR. Applied and environmental microbiology, 62(11), 4086-4094.</p>
 
-
<p>[4] Choi, J. H., &amp; Lee, S. Y. (2004). Secretory and extracellular production of recombinant proteins using Escherichia coli. Applied Microbiology and Biotechnology, 64(5),
 
625-635.</p>
625-635.</p>

Latest revision as of 22:49, 17 October 2014

Introduction

Apart from lack of sunlight in the water and anoxia caused by cyanobacteria itself, the potential detrimental effect of alga secreted toxin should be noticed. One of the most harmful toxin is called microcystin (MC), which has severe hepatotoxicity. The work in this part is to degrade MCs in water environment during an algal bloom.

To accomplish this work, the potent microcystin-degrading enzyme-MlrA, originally from Sphingomonas is utilized. This enzyme can cleavage the ring structure in microcystin, significantly reducing the toxicity of the protein. Since MCs is released into water by algae, secretion for MlrA is also necessary to facilitate the degradation of MCs.

Based on utility of MlrA, we measure its degradation efficiency expressed by E. coli. The results indicate that our engineered bacteria could express functional MlrA and degrade MC-LR to a certain extent. Moreover, secretion signal peptide is considered to be introduced for better degradation performance.

Design

Microcystin and MlrA enzyme

MCs are widespread toxic cyclic heptapeptides produced by many species of algae with different variants (Fig. 1). MCs are synthesized by polyketide synthases (PKS) and non-ribosomal peptide synthetases (NRPS) pathway. Among different variants, MC-LR is a widespread and deleterious one.

Fig. 1 Structure of MCs. MCs share cyclic structure of cyclo-(-D-Ala-L-X-MeAsp-L-Z-Adda-D-Glu-Mdha), where X and Z are variable.[1]

The most known mechanism of its toxicity is that MCs can inhibit protein phosphatase 1(PP1) and 2A (PP2A) specifically and efficiently.[2] The inhibition can lead to a severe disorder of biochemical reaction and disorganization of cytoskeleton in many eukaryotic cell. Many routine tools of decontamination cannot significantly reduce activities of MCs. Here, we propose a new idea of biodegradation, which could degrade MCs effectively without apparent side effects.

Many bacterial species have been reported to have ability to degrade MCs. Among them, a gene cluster in Sphingomonas has been found and sequenced. The cluster includes four genes, mlrA, mlrB, mlrC and mlrD, which can hydrolyze MCs and facilitate absorption of the products as carbon source. During the degradation process, the first-step linearized product, which is catalyzed by MlrA, shows much weaker hepatoxin compared with MCs. In the experiment of mouse bioassay, up to 250 mg/kg of linearized MC-LR shows no toxicity to mouse, much higher than 50% lethal dose 50mg/kg of cyclic MC-LR. Furthermore, the linearization also raises the median inhibition concentration to 95nM, around 160 times higher than original 0.6nM. [3] (Fig. 2)

Fig. 2 First step of biodegradation of MC-LR. MlrA mediates breaking peptide bond between Adda and Arg, which leads to significant decrease of toxicity.[3]

Secretion System

In order to enhance the degradation effect, location of MlrA should be considered. There are some porins proteins on the outer membrane of E. coli, which allow small molecules, including MCs, to penetrate the membrane. Consequently, it is sufficient to secret MlrA into periplasm for decontamination.

Sec pathway, which belongs to Type II secretion system that exports proteins to periplasm, enters our sight. During the exporting process, target protein is translocated across inner membrane in unfolded conformation and is refolded in the periplasm. [4] A signal peptide is required for the transportation system to recognize the target protein. After export, the peptide is cut off in the periplasm. Particularly, one of them from Pectate lyase B (PelB) holds little limitation to the following protein’s molecular weight and has been widely used in protein secretion. Consequently, we finally decide to use PelB signal peptide to secrete the MlrA protein.

Result

1. Constructing method for analysis of MC concentration

p-Nitrophenyl phosphate (pNPP) is a widely used non-specific substrate to test protein phosphatase activity and it can be hydrolyzed to p-Nitrophenyl(pNP) with characteristic absorption at 405nm. The measurement of PP1 activity is based on the accumulation of pNP. Considering the microcystin (MC) is the inhibitor of PP1 and MlrA can disrupt MC’s structure to disrupt its inhibitory effect, the MlrA activity can be detected by quantification of absorption at 405nm. (Fig. 4) So the concentration of MCs after degradation can be finally measured by absorption spectrophotometry method with all the calibration curves for all the interactions above.

Fig. 3 Measurement of MlrA activity. The OD405 indicates the concentration of pNP, and the change of pNP level could reflect the PP1 activity(a). MC can strongly inhibit the PP1 activity(b), and the MlrA can cleave the MC and dampen its toxicity(c).

Firstly a calibration curve of PP1 activity was generated. The concentration of substrate pNP is sufficient overall so the PP1 enzyme is saturated and proportion to the accumulation rate of product pNPP. We could select a proper working concentration of PP1 in the range of nearly linear relationship between PP1 and change rate of 405nm absorption.

Fig. 4 Calibration curve of PP1. p-Nitrophenyl Phosphate solution is treated with different concentration of PP1 solutions. Absorbance at 405nm was measured after 80 minutes. The absorbance increases in direct proportion to PP1 concentration between 0.02-0.1 unit/ul.

Based on the premise of linear relationship between product and absorbance, we choose 0.05unit/ul as the working concentration of PP1 and then test the inhibition efficiency of MC-LR. As a result, PP1 activity decreases after the addition of MC-LR and there is a positive correlation between the reduction of absorbance and concentration of MC-LR.

Fig. 5 Inhibition efficiency of MC-LR. Working concentration of PP1 is 0.05 unit/ul. Different concentration of MC-LR samples are added to the reaction system. MC-LR shows strong inhibition of PP1 activity and a rapid change of PP1 activity is observed between 10ug/L to 30 ug/L of MC-LR concentration.

2. Verifying the degradation effect of MlrA

To test the degradation efficiency of MlrA expressed by E. coli, MlrA expression plasmid has been constructed and transformed into E. coli strain BL21(DE3). (Fig. 6a) After induction, the bacteria are lysed by lysozyme and incubated with MC solution. Judged by PP1 activity treated by the mixture, the activity in experiment group expressing MlrA is much higher than strain carrying blank vectors, suggesting that MC-LR is degraded. (Fig. 6b) Therefore, it could be concluded that MlrA function well in E. coli expression system.

Fig. 6 Plasmid construction and results of degradation assays. (a) In our expression plasmid, MlrA is expressed in expression vector pET-21a, while blank vector is used as a negative control. (b) The result shows that MlrA expressed by E. coli has obvious function in degrading MC, which significantly reducing the inhibition effect of MC to PP1.

3. Attempting to secreting MlrA

MlrA exhibits high degradation activity in lysis culture. Its activity, however, has no difference with control group.(Fig. 6b) The result suggests that our bacteria are unable to deal with MC immediately until they commit suicide. Thus, secretion system PelB is introduced. The PelB is linked to N-terminal of MlrA and the fusion protein is inserted into expression vector. We hope this measure would improve degradation effect largely in whole cell level.

Fig. 7 Secretion sequence of mlrA. The fusion protein includes Type II secretion peptide pelB and mlrA. The construction as a whole is expressed in pET-21a(+) plasmid.

References

[1] Gehringer, M. M., Milne, P., Lucietto, F., & Downing, T. G. (2005). Comparison of the structure of key variants of microcystin to vasopressin.Environmental toxicology and pharmacology, 19(2), 297-303.

[2] Runnegar, M., Berndt, N., Kong, S. M., Lee, E. Y., & Zhang, L. F. (1995). In vivo and in vitro binding of microcystin to protein phosphatase 1 and 2A.Biochemical and biophysical research communications, 216(1), 162-169.

[3] Bourne, D. G., Jones, G. J., Blakeley, R. L., Jones, A., Negri, A. P., & Riddles, P. (1996). Enzymatic pathway for the bacterial degradation of the cyanobacterial cyclic peptide toxin microcystin LR. Applied and environmental microbiology, 62(11), 4086-4094.

625-635.