Team:Tokyo-NoKoGen/bmc

From 2011.igem.org

(Difference between revisions)
Line 100: Line 100:
<p class="style6"><strong><span class="style53">1. Introduction</span></strong></p>
<p class="style6"><strong><span class="style53">1. Introduction</span></strong></p>
<p class="style6"> For our project EcoLion, we came up with an idea to localize and concentrate heavy metals captured by metallothioneins into a &#8220;bacterial micro compartment&#8221;. Bacterial micro compartments (BMCs) are proteinaceous internal compartments which particular bacterial naturally have and use to optimize metabolic reactions having toxic or volatile intermediates. BMCs are polyhedral structures with size of 100&#8211;150 nm in cross-section and built from several thousand polypeptides of 10&#8211;20 types. BMCs encapsulate specific metabolic enzymes within protein shells to function as natural bioreactors.</p>
<p class="style6"> For our project EcoLion, we came up with an idea to localize and concentrate heavy metals captured by metallothioneins into a &#8220;bacterial micro compartment&#8221;. Bacterial micro compartments (BMCs) are proteinaceous internal compartments which particular bacterial naturally have and use to optimize metabolic reactions having toxic or volatile intermediates. BMCs are polyhedral structures with size of 100&#8211;150 nm in cross-section and built from several thousand polypeptides of 10&#8211;20 types. BMCs encapsulate specific metabolic enzymes within protein shells to function as natural bioreactors.</p>
-
<p class="style6">  We focused on a propanediol-utilizing BMC (PduBMC) derived from Citrobacter freundii. It naturally works for utilization of 1,2-propanediol by localizing enzymes into the BMC shell. Figure 1 shows the overview of this reaction. It is known that only seven proteins, such as pduA, -B, B&#8217;, -J, -K, -N, and -U, are necessarily to form an empty micro compartment [1]. </p>
+
<p class="style6">  We focused on a propanediol-utilizing BMC (PduBMC) derived from <I>Citrobacter freundii</I>. It naturally works for utilization of 1,2-propanediol by localizing enzymes into the BMC shell. Figure 1 shows the overview of this reaction. It is known that only seven proteins, such as pduA, -B, B&#8217;, -J, -K, -N, and -U, are necessarily to form an empty micro compartment [1]. </p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/d/d9/BMCfig1.jpg" border=0 width=628 height=452 alt="BMCfig1" style="vertical-align:baseline"></p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/d/d9/BMCfig1.jpg" border=0 width=628 height=452 alt="BMCfig1" style="vertical-align:baseline"></p>
-
<p class="style6">It is also supposed that tag peptides work for localization specific enzymes in to PduBMC. The N-terminus short peptide of PduP (pduP1-18) is known to function for packaging proteins into PduBMC [2]. Fan et al. have reported that GFP fused to PduP1-18 were successfully localized into recombinant PduBMC in E. coli, while GFP without the localization tag PduP1-18 are distributed in cytoplasm.</p>
+
<p class="style6">It is also supposed that tag peptides work for localization specific enzymes in to PduBMC. The N-terminus short peptide of PduP (pduP1-18) is known to function for packaging proteins into PduBMC [2]. Fan et al. have reported that GFP fused to PduP1-18 were successfully localized into recombinant PduBMC in <i>E. coli</I>, while GFP without the localization tag PduP1-18 are distributed in cytoplasm.</p>
<p class="style6">We expect those BMCs and localization tags have much potential to construct artificial bioreactors (Figure 2). By fusing specific enzymes with localization-tag peptides, it supposed to localize the enzymes into BMCs, and such artificial BMCs are expected to be used as artificial bioreactors. Our team also came up with the idea to localize and concentrate small molecules captured by target-binding peptides into BMCs in order to collect useful or harmful compounds from the environment.</p>
<p class="style6">We expect those BMCs and localization tags have much potential to construct artificial bioreactors (Figure 2). By fusing specific enzymes with localization-tag peptides, it supposed to localize the enzymes into BMCs, and such artificial BMCs are expected to be used as artificial bioreactors. Our team also came up with the idea to localize and concentrate small molecules captured by target-binding peptides into BMCs in order to collect useful or harmful compounds from the environment.</p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/4/4f/BMCfig2.jpg" border=0 width=455 height=375 alt="BMCfig2" style="vertical-align:baseline"></p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/4/4f/BMCfig2.jpg" border=0 width=455 height=375 alt="BMCfig2" style="vertical-align:baseline"></p>
-
<p class="style6">For our project, we attempted to localize and concentrate heavy metals into PduBMC because heavy metals are toxic to the cell itself, and it is required to isolate them from the cytoplasm. Localization of heavy metals also makes the further process for purification of heavy metals much simpler. The overview of localization of heavy metals into PduBMC is shown in Figure 3. In order to achieve this purpose, we also attempted to express empty PduBMC shells in E. coli and characterized PduBMC shell proteins. We used metallothioneins, heavy metal-binding peptide, to capture target heavy metals, and we constructed fusion protein of a metallothioneins and a localization-tag peptide PduP1-18. </p>
+
<p class="style6">For our project, we attempted to localize and concentrate heavy metals into PduBMC because heavy metals are toxic to the cell itself, and it is required to isolate them from the cytoplasm. Localization of heavy metals also makes the further process for purification of heavy metals much simpler. The overview of localization of heavy metals into PduBMC is shown in Figure 3. In order to achieve this purpose, we also attempted to express empty PduBMC shells in <i>E. coli</i> and characterized PduBMC shell proteins. We used metallothioneins, heavy metal-binding peptide, to capture target heavy metals, and we constructed fusion protein of a metallothioneins and a localization-tag peptide PduP1-18. </p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/1/14/BMCfig3.jpg" border=0 width=580 height=417 alt="BMCfig3" style="vertical-align:baseline"></p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/1/14/BMCfig3.jpg" border=0 width=580 height=417 alt="BMCfig3" style="vertical-align:baseline"></p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
Line 124: Line 124:
<p class="style72">&#65294;DpSB1K3-pduABJKNU</p>
<p class="style72">&#65294;DpSB1K3-pduABJKNU</p>
<p class="style73">&#65294;DpSB1A3-Ph-pduABJKNU</p>
<p class="style73">&#65294;DpSB1A3-Ph-pduABJKNU</p>
-
<p class="style67"> E. coli transformed one of the constructs shown above were grown in 100 mL of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, 1 mM IPTG was added and further incubated at 16 °C for 18 hours. The cells were harvested by centrifugation at 5,000 x g at 4 °C for 10 minutes, and resuspended in 30 ml 0.85 % NaCl twice. Moreover, they were resuspended by sonication buffer (50 mM Tris-HCl, 2 mM EDTA) and lysed by sonication (5minutes bursts with 5 minutes cooling intervals on ice for three times.) Subsequently, soluble fraction and insoluble fraction were separated by centrifugation at 12,000 x g for 20 min. In order to remove membrane fraction, soluble fraction was ultracentrifuged at 26,000 x g for 30 min. Moreover, the soluble fraction was purified by ultracentrifugation at 30,000 x g for 90 min then we recovered the pellet. After ultracentrifugation, the pellet was dissolved in 100 µl sonication buffer, and the protein concentration was measured by using DC protein assay. Each protein concentration was adjusted to 0.8 mg/ml and 10µl each were applied to the well. These proteins were stained by CBB stain solution. </p>
+
<p class="style67"> <i>E. coli</I> transformed one of the constructs shown above were grown in 100 mL of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, 1 mM IPTG was added and further incubated at 16 °C for 18 hours. The cells were harvested by centrifugation at 5,000 x g at 4 °C for 10 minutes, and resuspended in 30 ml 0.85 % NaCl twice. Moreover, they were resuspended by sonication buffer (50 mM Tris-HCl, 2 mM EDTA) and lysed by sonication (5minutes bursts with 5 minutes cooling intervals on ice for three times.) Subsequently, soluble fraction and insoluble fraction were separated by centrifugation at 12,000 x g for 20 min. In order to remove membrane fraction, soluble fraction was ultracentrifuged at 26,000 x g for 30 min. Moreover, the soluble fraction was purified by ultracentrifugation at 30,000 x g for 90 min then we recovered the pellet. After ultracentrifugation, the pellet was dissolved in 100 µl sonication buffer, and the protein concentration was measured by using DC protein assay. Each protein concentration was adjusted to 0.8 mg/ml and 10µl each were applied to the well. These proteins were stained by CBB stain solution. </p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
<p class="style37"><strong>3-2. Confirmation of the expression of pET30c-pduABJKNU-Ph-pduP1-18-GFP by florescence microscopy</strong></p>
<p class="style37"><strong>3-2. Confirmation of the expression of pET30c-pduABJKNU-Ph-pduP1-18-GFP by florescence microscopy</strong></p>
Line 131: Line 131:
<p class="style6">1. pET30c-pduP1-18-GFP (T7 promoter)</p>
<p class="style6">1. pET30c-pduP1-18-GFP (T7 promoter)</p>
<p class="style6">2. pET30c-pduABJKNU-Ph-pduP1-18-GFP</p>
<p class="style6">2. pET30c-pduABJKNU-Ph-pduP1-18-GFP</p>
-
<p class="style6"> E. coli transformants were grown in 100 ml of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, protein expression was induced with 1 mM IPTG at 16 °C for 50 hours. Then we observed fluorescence from the E. coli cells using a fluorescence microscopy (Keyence).</p>
+
<p class="style6"> <i>E. coli</i> transformants were grown in 100 ml of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, protein expression was induced with 1 mM IPTG at 16 °C for 50 hours. Then we observed fluorescence from the E. coli cells using a fluorescence microscopy (Keyence).</p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
<p class="style6"><strong><span class="style53">4. Results and Discussion</span></strong></p>
<p class="style6"><strong><span class="style53">4. Results and Discussion</span></strong></p>
<p class="style67"><strong><span class="style53">4-1. Confirmation of the expression of pET30c-pduABJKNU by SDS-PAGE analysis</span></strong></p>
<p class="style67"><strong><span class="style53">4-1. Confirmation of the expression of pET30c-pduABJKNU by SDS-PAGE analysis</span></strong></p>
-
<p class="style6">We carried out purification of PduBMC shell proteins and SDS-PAGE analysis to confirm expression of the proteins. We tried to purify BMC shells according to a published paper (Figure 6) [1]. We expected to observe six bands as the result of SDS-PAGE that would indicate expression of PduBMC shells. As our results of SDS-PAGE analysis, those bands were not observed at the lanes 2 and 5 where samples purified from E. coli BL21(DE3)/pET30c-pduABJKNU and E. coli BL21(DE3)/PSB1K3-Ph-pduABJKNU (Figure 7). This might be due to the difference in the amount of culture we prepared, thus amounts of BMC proteins might not be enough for purifying BMC shells and analyzing by SDS-PAGE. We cultured transfromants in 100 mL of LB broth, while the referred research article performed those experiments with 2 L of E. coli cultures. </p>
+
<p class="style6">We carried out purification of PduBMC shell proteins and SDS-PAGE analysis to confirm expression of the proteins. We tried to purify BMC shells according to a published paper (Figure 6) [1]. We expected to observe six bands as the result of SDS-PAGE that would indicate expression of PduBMC shells. As our results of SDS-PAGE analysis, those bands were not observed at the lanes 2 and 5 where samples purified from <i>E. coli</I> BL21(DE3)/pET30c-pduABJKNU and <i>E. coli</i> BL21(DE3)/PSB1K3-Ph-pduABJKNU (Figure 7). This might be due to the difference in the amount of culture we prepared, thus amounts of BMC proteins might not be enough for purifying BMC shells and analyzing by SDS-PAGE. We cultured transfromants in 100 mL of LB broth, while the referred research article performed those experiments with 2 L of E. coli cultures. </p>
<p class="style6">Moreover, we noticed that there was difference between sequences of our constructed device for PduBMC (pduABB&#8217;JKNU) and the one reported in the reference [1]. The alignment between DNA sequences of pduB of our constructs and pduB derived from Citrobacter freundii which was used in the article [1] were shown in Figure 8. In pduB gene sequence, two amino acids were different from that of expected sequence. In addition, the start codon of pduK gene was replaced to valine from methionine. This could be a cause of low expression levels of pduK and low amounts of whole PduBMC shell structures. There were also other difference in the sequence of pduK as indicated in Figure 9 with red boxes. Mutation works to match the sequences of our construct to the reported genes are currently undergoing by inverse PCR and Quikchange® methods.</p>
<p class="style6">Moreover, we noticed that there was difference between sequences of our constructed device for PduBMC (pduABB&#8217;JKNU) and the one reported in the reference [1]. The alignment between DNA sequences of pduB of our constructs and pduB derived from Citrobacter freundii which was used in the article [1] were shown in Figure 8. In pduB gene sequence, two amino acids were different from that of expected sequence. In addition, the start codon of pduK gene was replaced to valine from methionine. This could be a cause of low expression levels of pduK and low amounts of whole PduBMC shell structures. There were also other difference in the sequence of pduK as indicated in Figure 9 with red boxes. Mutation works to match the sequences of our construct to the reported genes are currently undergoing by inverse PCR and Quikchange® methods.</p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/9/99/BMCfig7.jpg" border=0 width=442 height=392 alt="BMCfig7" style="vertical-align:baseline"></p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/9/99/BMCfig7.jpg" border=0 width=442 height=392 alt="BMCfig7" style="vertical-align:baseline"></p>
Line 143: Line 143:
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>
<p class="style37"><strong>4-2. Confirmation of localization pduP1-18-GFP into the PduBMC by florescence microscopy</strong></p>
<p class="style37"><strong>4-2. Confirmation of localization pduP1-18-GFP into the PduBMC by florescence microscopy</strong></p>
-
<p class="style6">We carried out fluorescence microscopic analysis to confirm the co-expression of pduABJKNU and pduP1-18-GFP. The fluorescence microscopic image of E. coli cells co-expressing PduP1-18-GFP and PduBMC are shown in Figure 10. From this image PduP1-18-GFP likely localized into BMC, however this image was looked similar to a fluorescence image of E. coli BL21(DE3)/pET30c-pduP1-18-GFP which did not have PduBMC genes as a control (data not shown).</p>
+
<p class="style6">We carried out fluorescence microscopic analysis to confirm the co-expression of pduABJKNU and pduP1-18-GFP. The fluorescence microscopic image of <i>E. coli</i> cells co-expressing PduP1-18-GFP and PduBMC are shown in Figure 10. From this image PduP1-18-GFP likely localized into BMC, however this image was looked similar to a fluorescence image of <i>E. coli</i> BL21(DE3)/pET30c-pduP1-18-GFP which did not have PduBMC genes as a control (data not shown).</p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/f/f0/BMCfig10.jpg" border=0 width=437 height=284 alt="BMCfig10" style="vertical-align:baseline"></p>
<p class="style6"><img src="https://static.igem.org/mediawiki/2011/f/f0/BMCfig10.jpg" border=0 width=437 height=284 alt="BMCfig10" style="vertical-align:baseline"></p>
<p class="style6">&nbsp;</p>
<p class="style6">&nbsp;</p>

Revision as of 12:21, 5 October 2011

<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN" "http://www.w3.org/TR/html4/loose.dtd"> BMC

Tokyo-NokoGen 2011

Department of Biotechnology and Life Science, Tokyo University of Agriculture and Technology

 

Home

Team

Members

Project: EcoLion

BioBricks

Notebook

Protocols

Attribution

Safety

Sponsors

BMC (Bacterial micro compartment) – localizing target proteins into BMC

 

1. Introduction

For our project EcoLion, we came up with an idea to localize and concentrate heavy metals captured by metallothioneins into a “bacterial micro compartment”. Bacterial micro compartments (BMCs) are proteinaceous internal compartments which particular bacterial naturally have and use to optimize metabolic reactions having toxic or volatile intermediates. BMCs are polyhedral structures with size of 100–150 nm in cross-section and built from several thousand polypeptides of 10–20 types. BMCs encapsulate specific metabolic enzymes within protein shells to function as natural bioreactors.

We focused on a propanediol-utilizing BMC (PduBMC) derived from Citrobacter freundii. It naturally works for utilization of 1,2-propanediol by localizing enzymes into the BMC shell. Figure 1 shows the overview of this reaction. It is known that only seven proteins, such as pduA, -B, B’, -J, -K, -N, and -U, are necessarily to form an empty micro compartment [1].

BMCfig1

It is also supposed that tag peptides work for localization specific enzymes in to PduBMC. The N-terminus short peptide of PduP (pduP1-18) is known to function for packaging proteins into PduBMC [2]. Fan et al. have reported that GFP fused to PduP1-18 were successfully localized into recombinant PduBMC in E. coli, while GFP without the localization tag PduP1-18 are distributed in cytoplasm.

We expect those BMCs and localization tags have much potential to construct artificial bioreactors (Figure 2). By fusing specific enzymes with localization-tag peptides, it supposed to localize the enzymes into BMCs, and such artificial BMCs are expected to be used as artificial bioreactors. Our team also came up with the idea to localize and concentrate small molecules captured by target-binding peptides into BMCs in order to collect useful or harmful compounds from the environment.

BMCfig2

For our project, we attempted to localize and concentrate heavy metals into PduBMC because heavy metals are toxic to the cell itself, and it is required to isolate them from the cytoplasm. Localization of heavy metals also makes the further process for purification of heavy metals much simpler. The overview of localization of heavy metals into PduBMC is shown in Figure 3. In order to achieve this purpose, we also attempted to express empty PduBMC shells in E. coli and characterized PduBMC shell proteins. We used metallothioneins, heavy metal-binding peptide, to capture target heavy metals, and we constructed fusion protein of a metallothioneins and a localization-tag peptide PduP1-18.

BMCfig3

 

 

2. Constructs

BMCfig4

 

 

3. Method

SDS-PAGE analysis and fluorescence microscopic analysis were performed to confirm the expression of PduBMC shells and PduP1-18-GFP fusion proteins supposed to be localized in the BMC.

3-1. Confirmation of the expression of pET30c-pduABJKNU by SDS-PAGE analysis

BMCfig5

BMCfig6

Ⅰ. Constructs for characterizing PduBMC expression (1-5)

.DpET30c-pduABJKNU (T7 promoter)

.DpSB1C3-PLlaco-1-pduABJKNU

.DpET30c

.DpSB1K3-pduABJKNU

.DpSB1A3-Ph-pduABJKNU

E. coli transformed one of the constructs shown above were grown in 100 mL of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, 1 mM IPTG was added and further incubated at 16 °C for 18 hours. The cells were harvested by centrifugation at 5,000 x g at 4 °C for 10 minutes, and resuspended in 30 ml 0.85 % NaCl twice. Moreover, they were resuspended by sonication buffer (50 mM Tris-HCl, 2 mM EDTA) and lysed by sonication (5minutes bursts with 5 minutes cooling intervals on ice for three times.) Subsequently, soluble fraction and insoluble fraction were separated by centrifugation at 12,000 x g for 20 min. In order to remove membrane fraction, soluble fraction was ultracentrifuged at 26,000 x g for 30 min. Moreover, the soluble fraction was purified by ultracentrifugation at 30,000 x g for 90 min then we recovered the pellet. After ultracentrifugation, the pellet was dissolved in 100 µl sonication buffer, and the protein concentration was measured by using DC protein assay. Each protein concentration was adjusted to 0.8 mg/ml and 10µl each were applied to the well. These proteins were stained by CBB stain solution.

 

3-2. Confirmation of the expression of pET30c-pduABJKNU-Ph-pduP1-18-GFP by florescence microscopy

BMCfig6a

Ⅰ. Constructs for characterizing localization of PduP1-18 fused GFP into PduBMC (1-2)

1. pET30c-pduP1-18-GFP (T7 promoter)

2. pET30c-pduABJKNU-Ph-pduP1-18-GFP

E. coli transformants were grown in 100 ml of Luria-Bertani medium at 37 °C. When OD600 reached 0.8, protein expression was induced with 1 mM IPTG at 16 °C for 50 hours. Then we observed fluorescence from the E. coli cells using a fluorescence microscopy (Keyence).

 

 

4. Results and Discussion

4-1. Confirmation of the expression of pET30c-pduABJKNU by SDS-PAGE analysis

We carried out purification of PduBMC shell proteins and SDS-PAGE analysis to confirm expression of the proteins. We tried to purify BMC shells according to a published paper (Figure 6) [1]. We expected to observe six bands as the result of SDS-PAGE that would indicate expression of PduBMC shells. As our results of SDS-PAGE analysis, those bands were not observed at the lanes 2 and 5 where samples purified from E. coli BL21(DE3)/pET30c-pduABJKNU and E. coli BL21(DE3)/PSB1K3-Ph-pduABJKNU (Figure 7). This might be due to the difference in the amount of culture we prepared, thus amounts of BMC proteins might not be enough for purifying BMC shells and analyzing by SDS-PAGE. We cultured transfromants in 100 mL of LB broth, while the referred research article performed those experiments with 2 L of E. coli cultures.

Moreover, we noticed that there was difference between sequences of our constructed device for PduBMC (pduABB’JKNU) and the one reported in the reference [1]. The alignment between DNA sequences of pduB of our constructs and pduB derived from Citrobacter freundii which was used in the article [1] were shown in Figure 8. In pduB gene sequence, two amino acids were different from that of expected sequence. In addition, the start codon of pduK gene was replaced to valine from methionine. This could be a cause of low expression levels of pduK and low amounts of whole PduBMC shell structures. There were also other difference in the sequence of pduK as indicated in Figure 9 with red boxes. Mutation works to match the sequences of our construct to the reported genes are currently undergoing by inverse PCR and Quikchange® methods.

BMCfig7

BMCfig8

BMCfig9

 

4-2. Confirmation of localization pduP1-18-GFP into the PduBMC by florescence microscopy

We carried out fluorescence microscopic analysis to confirm the co-expression of pduABJKNU and pduP1-18-GFP. The fluorescence microscopic image of E. coli cells co-expressing PduP1-18-GFP and PduBMC are shown in Figure 10. From this image PduP1-18-GFP likely localized into BMC, however this image was looked similar to a fluorescence image of E. coli BL21(DE3)/pET30c-pduP1-18-GFP which did not have PduBMC genes as a control (data not shown).

BMCfig10

 

5. Summary

pending pending pending

 

 

 

6. Reference

[1] Parsons et al. (2010) Synthesis of empty bacterial microcompartments, directed organelle protein incorporation, and evidence of filament-associated organelle movement. Molecular Cell, 38, 305–315.

[2] Fan et al. (2010) Short N-terminal sequences package proteins into bacterial microcompartments PNAS 107, 7509-7514.

[3] Havemann and Bobik. (2003) Protein content of polyhedral organelles involved in coenzyme B12-dependent degradation of 1,2-propanediol in Salmonella enterica serovar Typhimurium LT2. J. Bacteriol., 185, 5086–5095.