Difference between revisions of "Part:BBa K2350022"

 
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<partinfo>BBa_K2350022 short</partinfo>
 
<partinfo>BBa_K2350022 short</partinfo>
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== Part description ==
 
== Part description ==
  
Zeaxanthin belongs to carotenoid family and is widely found in the nature. It is also a natural color making corns, carrots and marigolds yellow. Moreover, zeaxanthin is an essential nutrient substance to human’s eyes, and some healthy supplements are made of it. Most of green plants produce zeaxanthin as an intermediate in carotenoid pathway. However, some cyanobacteria lack some genes and cannot produce zeaxanthin, such as Synechococcus elongatus PCC 7942. PCC7942 lacks only one gene making zeaxanthin, that is beta-carotene hydroxylase (CrtZ). To make Synechococcus elongatus PCC 7942 produce zeaxanthin, we construct a plasmid BBa_K2320022 under the control of PrbcL. After the expression of CrtZ, PCC 7942 can then be yellow.
+
Zeaxanthin belongs to carotenoid family and is widely found in nature. It is also a natural yellow color making of corns, carrots and marigolds. Moreover, zeaxanthin is an essential nutrient substance to human eyes, and some healthy supplements are made of it. Most of the green plants produce zeaxanthin as an intermediate in carotenoid pathway. However, some cyanobacteria lack some genes and cannot produce zeaxanthin, such as Synechococcus elongatus PCC 7942. PCC7942 lacks only one gene making zeaxanthin, that is beta-carotene hydroxylase (CrtZ). To make Synechococcus elongatus PCC 7942 produce zeaxanthin, we constructed a plasmid BBa_K2320022 under the control of PrbcL. After the expression of CrtZ, PCC 7942 can then be yellow.
  
And the crtZ what we use was a part released in iGEM (BBa_I742158) .We have successfully construct this part on our special design backbone pPIGBACK so that it can express in our microalgae and result in yellow microalgae.
+
And the crtZ what we used was a part released in iGEM (BBa_I742157) .We have successfully constructed this part on our special designed backbone pPIGBACK so that it can be expressed in our microalgae and resulted in yellow microalgae.
  
  
  
 
== Details ==
 
== Details ==
1. We studied Professor Chuan-Hsiung Chang’s paper(Energy Environ. Sci., 2012, 5, 8318: Enhancing CO2 bio-mitigation by genetic engineering of cyanobacteria) and decided to construct pigment plasmid with the same promotor. The natural ribosome binding site is also referred to it.
+
1. We studied Professor Chuan-Hsiung Chang’s paper(Energy Environ. Sci., 2012, 5, 8318: Enhancing CO2 bio-mitigation by genetic engineering of cyanobacteria) and decided to construct pigment plasmid with the same promotor. The natural ribosome binding site was also referred to it.
<br>2. The intrinsic promoter of Rubisco large subunit (PrbcL) can overexpress foreign genes in the cyanobacteria. Many plants’ protens in photosynthesis are under regulation of PrbcL. And the high activity to express foreign genes has been provrn.
+
<br>2. The intrinsic promoter of Rubisco large subunit (PrbcL) can overexpress foreign genes in cyanobacteria. Many plants’ proteins in photosynthesis are under regulation of PrbcL. And the high activity to express foreign genes has been proven.
<br>3. CrtZ from Pantoea ananatis is a coding sequence of igem released part (BBa_I742158). It can lead to zeaxanthin and astaxanthin. However, the wild type Synechococcus elongatus PCC 7942 lacks of it and cannot make zeaxanthin naturally.  
+
<br>3. CrtZ from Pantoea ananatis is a coding sequence of igem released part (BBa_I742157). It can lead to zeaxanthin and astaxanthin. However, the wild type Synechococcus elongatus PCC 7942 lacks it and cannot make zeaxanthin naturally.
  
  
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==Result==
 
==Result==
  
The left one of Figure 1 is wild type Synechococcus elongatus PCC 7942, the right one was transforment with BBa_K2320022. Obviously, the right one was more yellow than the left one. It proved that CrtZ was successfully transformed to PCC7942 and lead to zeaxantin. See Figure 1.  
+
We used spectrophotometer to measure the absorbance of CrtZ and wild type at 400 to 700 nm. The outcome was that the OD value of CrtZ at 400 to 500 nm was higher than wild type.  Not only this, the change of wavelength absorbance was at 400 to 500 nm, which was blue light. This indicated CrtZ absorbed blue light and reflected yellow light, so CrtZ was more yellow than wild type. The measurement matched what we saw intuitively.
 +
<br>The right one of Figure 1 was wild type Synechococcus elongatus PCC 7942, the left one was transformant with BBa_K2320022. Obviously, the left one was more yellow than the right one. It proved that CrtZ was successfully transformed to PCC7942 and lead to zeaxanthin. See Figure 1.  
  
  
 
<b>Figure 1 </b>   
 
<b>Figure 1 </b>   
  
[[File:T--NYMU-Taipei--partsregistry CrtZ.jpg |400px]]
+
[[Image:T--NYMU-Taipei--pigments_func_CrtZ.png|500px|center]]
  
  
  
  
Figure 2 is pPIGBACK-CrtZ transformants electrophoresis result. C1~C20 represents the pPIGBACK-CrtZ transformant clone 1 to clone 20, and M represnets 1 kb marker. Transformation efficiency of pPIGBACK-CrtZ is 11.4 transformants per μg DNA, and correctness is 52% (10/19), which is quite efficient because the successful rate of gene double-crossingover homologous recombination is low. See Figure 2.
+
 
 +
Figure 2 is pPIGBACK-CrtZ transformants electrophoresis result. C1~C20 represent the pPIGBACK-CrtZ transformants clone 1 to clone 20, and M represents 1 Kb marker. Transformation efficiency of pPIGBACK-CrtZ is 11.4 transformants per μg DNA, and correctness is 52% (10/19), which is quite efficient because the successful rate of gene double-crossingover homologous recombination is low. See Figure 2.
  
  
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To test whether the photosynthetic efficiency of CrtZ is better than wild type, we then used iodine to measure starch concentration. First, the initial concentration of microalgae of CrtZ and wild type should be the same, so that the measurement could be fair. We measured the OD value at 730 nm, which represented the concentration of microalgae. Then we calculated how much microalgae and BG11 (the medium) we should add to make same amount of microalgae in each plate. Second, we started to measure starch concentration. We measured the OD value of each plate at 730 nm, which represented the cell number. Then we added 50 μl iodine into each cuvette, waited for five minutes, and measured the OD value at 620 nm, which represented the starch content. We repeated this step for seven days. Here are our results.
Figure 3 is cell number, and Figure 4 is the starch content. See Figure 3 and Figure 4.
+
<br>Figure 3 is the cell number, and Figure 4 is the starch content. See Figure 3 and Figure 4.
  
  
 
<b> Figure 3 </b>
 
<b> Figure 3 </b>
  
[[File:T--NYMU-Taipei--partsregistry CrtZ--3.png |500px]]
+
[[File:T--NYMU-Taipei--pigments func cell number.png |500px|center]]
  
  
 
<b> Figure 4 </b>
 
<b> Figure 4 </b>
  
[[File:T--NYMU-Taipei--partsregistry CrtZ--4.png |500px]]
+
[[File:T--NYMU-Taipei--pigments func I2.png |500px|center]]
  
  
  
  
Figure 5 is starch content per cell, and Figure 6 is delta starch content compared with days. On Figure 5 and Figure 6, the starch of transforment are more than wild type, and proved that photosynthesis of transforment was more efficient than wild type. See Figure 5 and Figure 6.  
+
Figure 5 is the starch content per cell, and Figure 6 is the delta starch content compared with days. In Figure 6, the starch content changed per cell of transformants were more than wild type, and proved that photosynthesis of some transformants were comparable to or more efficient than wild type. See Figure 5 and Figure 6.  
  
  
<b>Fifure 5 </b>
 
  
[[File:T--NYMU-Taipei--partsregistry CrtZ--5.png |500px]]
+
<b>Figure 5 </b>
 +
 
 +
[[File:T--NYMU-Taipei--pigments func starch.png |500px|center]]
  
  
 
<b>Figure 6 </b>
 
<b>Figure 6 </b>
  
[[File:T--NYMU-Taipei--partsregistry CrtZ--6.png |500px]]
+
[[File:T--NYMU-Taipei--pigments func starch increase.png |500px|center]]
 
+
 
+
 
+
  
 +
==Conclusion==
 +
From the results, CrtZ was surely transformed to PCC7942 and elevated the photosynthetic efficiency of transformants.
 +
<br>
 +
<br>
 +
==Discussion==
 +
1.The 2011 NCTU Formosa inspired us to transform photosynthetic pigments to cyanobacteria. NCTU Formosa used zeaxanthin synthesis pathway for temperature sensory. They used E.coli and we used Synechococcus elongatus PCC7942. Furthermore, we focused on the photosynthetic efficiency.
 +
<br>2.There are two yellow pigments in carotenoid pathway, zeaxanthin and lutein. The reason why we did not choose lutein was that PCC7942 lacked almost every gene on α-carotene pathway. Moreover, the only gene that PCC7942 lacks on zeaxanthin pathway is an IGEM released part. So we preferred zeaxanthin to lutein.
 +
<br>3. We assumed that our modified cyanobacteria are able to promote photosynthetic efficiency from our modeling. Maybe they can slow down the greenhouse effect efficiently.
 +
<br>4.Scientists usually use knockout to change color of microalgae. For example, Kwangryul Baek blocked  Chlamydomonas reinhardtii's epoxidation step from zeaxanthin to violaxanthin. They afterwards accumulated zeaxanthin in Chlamydomonas reinhardtii. However, we did not follow the mainstream method. We rather added gene to Synechococcus elongtus PCC7942.
 +
<br>5.Often, altering color of cyanobacteria can protract exposures to strong light, low temperatures and drought. In the future, we can test whether CrtZ transformant can bear such harsh conditions.
 +
<br>6.Microalgae are versatile organisms. Morning Glory Pool is one of the main attractions of Yellowstone National Park. The hot spring contains a variety of bacteria and archae that can bear different temperatures and salts. We may foresee that more microalgae will be changed to other colors for the purpose of adapting to various conditions.
 +
<br>
 +
<br>
 +
==Reference==
 +
1.Shinichi Takaichi(2011). Carotenoids in Algae: Distributions, Biosyntheses and Functions. Mar Drugs. 2011; 9(6): 1101–1118.
 +
<br>2.Chuan-Hsiung Chang(2012). Enhancing CO2 bio-mitigation by genetic engineering of cyanobacteria. Energy Environ. Sci., 2012, 5, 8318.
 +
<br>3.NCBI (https://www.ncbi.nlm.nih.gov/nuccore/CP000100)
 +
<br>4.Kwangryul Baek, Duk Hyoung Kim, Jooyeon Jeong, Sang Jun Sim, Anastasios Melis, Jin-Soo Kim, EonSeon Jin & Sangsu Bae(2016).DNA-free two-gene knockout in Chlamydomonas reinhardtii via CRISPR-Cas9 ribonucleoproteins. Scientific Reports 6, Article number: 30620 (2016)
 +
<br>5.Jean-Hugues B. Hatier, Michael J. Clearwater, Kevin S. Gould(2013)The Functional Significance of Black-Pigmented Leaves: Photosynthesis, Photoprotection and Productivity in Ophiopogon planiscapus ‘Nigrescens’(https://doi.org/10.1371/journal.pone.0067850)
  
  

Latest revision as of 15:24, 1 November 2017

pPIGBACK-PrbcL-CrtZ


Part description

Zeaxanthin belongs to carotenoid family and is widely found in nature. It is also a natural yellow color making of corns, carrots and marigolds. Moreover, zeaxanthin is an essential nutrient substance to human eyes, and some healthy supplements are made of it. Most of the green plants produce zeaxanthin as an intermediate in carotenoid pathway. However, some cyanobacteria lack some genes and cannot produce zeaxanthin, such as Synechococcus elongatus PCC 7942. PCC7942 lacks only one gene making zeaxanthin, that is beta-carotene hydroxylase (CrtZ). To make Synechococcus elongatus PCC 7942 produce zeaxanthin, we constructed a plasmid BBa_K2320022 under the control of PrbcL. After the expression of CrtZ, PCC 7942 can then be yellow.

And the crtZ what we used was a part released in iGEM (BBa_I742157) .We have successfully constructed this part on our special designed backbone pPIGBACK so that it can be expressed in our microalgae and resulted in yellow microalgae.


Details

1. We studied Professor Chuan-Hsiung Chang’s paper(Energy Environ. Sci., 2012, 5, 8318: Enhancing CO2 bio-mitigation by genetic engineering of cyanobacteria) and decided to construct pigment plasmid with the same promotor. The natural ribosome binding site was also referred to it.
2. The intrinsic promoter of Rubisco large subunit (PrbcL) can overexpress foreign genes in cyanobacteria. Many plants’ proteins in photosynthesis are under regulation of PrbcL. And the high activity to express foreign genes has been proven.
3. CrtZ from Pantoea ananatis is a coding sequence of igem released part (BBa_I742157). It can lead to zeaxanthin and astaxanthin. However, the wild type Synechococcus elongatus PCC 7942 lacks it and cannot make zeaxanthin naturally.


Result

We used spectrophotometer to measure the absorbance of CrtZ and wild type at 400 to 700 nm. The outcome was that the OD value of CrtZ at 400 to 500 nm was higher than wild type. Not only this, the change of wavelength absorbance was at 400 to 500 nm, which was blue light. This indicated CrtZ absorbed blue light and reflected yellow light, so CrtZ was more yellow than wild type. The measurement matched what we saw intuitively.
The right one of Figure 1 was wild type Synechococcus elongatus PCC 7942, the left one was transformant with BBa_K2320022. Obviously, the left one was more yellow than the right one. It proved that CrtZ was successfully transformed to PCC7942 and lead to zeaxanthin. See Figure 1.


Figure 1

T--NYMU-Taipei--pigments func CrtZ.png



Figure 2 is pPIGBACK-CrtZ transformants electrophoresis result. C1~C20 represent the pPIGBACK-CrtZ transformants clone 1 to clone 20, and M represents 1 Kb marker. Transformation efficiency of pPIGBACK-CrtZ is 11.4 transformants per μg DNA, and correctness is 52% (10/19), which is quite efficient because the successful rate of gene double-crossingover homologous recombination is low. See Figure 2.


Figure 2

CrtZ Parts.jpg


To test whether the photosynthetic efficiency of CrtZ is better than wild type, we then used iodine to measure starch concentration. First, the initial concentration of microalgae of CrtZ and wild type should be the same, so that the measurement could be fair. We measured the OD value at 730 nm, which represented the concentration of microalgae. Then we calculated how much microalgae and BG11 (the medium) we should add to make same amount of microalgae in each plate. Second, we started to measure starch concentration. We measured the OD value of each plate at 730 nm, which represented the cell number. Then we added 50 μl iodine into each cuvette, waited for five minutes, and measured the OD value at 620 nm, which represented the starch content. We repeated this step for seven days. Here are our results.
Figure 3 is the cell number, and Figure 4 is the starch content. See Figure 3 and Figure 4.


Figure 3

T--NYMU-Taipei--pigments func cell number.png


Figure 4

T--NYMU-Taipei--pigments func I2.png



Figure 5 is the starch content per cell, and Figure 6 is the delta starch content compared with days. In Figure 6, the starch content changed per cell of transformants were more than wild type, and proved that photosynthesis of some transformants were comparable to or more efficient than wild type. See Figure 5 and Figure 6.


Figure 5

T--NYMU-Taipei--pigments func starch.png


Figure 6

T--NYMU-Taipei--pigments func starch increase.png

Conclusion

From the results, CrtZ was surely transformed to PCC7942 and elevated the photosynthetic efficiency of transformants.

Discussion

1.The 2011 NCTU Formosa inspired us to transform photosynthetic pigments to cyanobacteria. NCTU Formosa used zeaxanthin synthesis pathway for temperature sensory. They used E.coli and we used Synechococcus elongatus PCC7942. Furthermore, we focused on the photosynthetic efficiency.
2.There are two yellow pigments in carotenoid pathway, zeaxanthin and lutein. The reason why we did not choose lutein was that PCC7942 lacked almost every gene on α-carotene pathway. Moreover, the only gene that PCC7942 lacks on zeaxanthin pathway is an IGEM released part. So we preferred zeaxanthin to lutein.
3. We assumed that our modified cyanobacteria are able to promote photosynthetic efficiency from our modeling. Maybe they can slow down the greenhouse effect efficiently.
4.Scientists usually use knockout to change color of microalgae. For example, Kwangryul Baek blocked Chlamydomonas reinhardtii's epoxidation step from zeaxanthin to violaxanthin. They afterwards accumulated zeaxanthin in Chlamydomonas reinhardtii. However, we did not follow the mainstream method. We rather added gene to Synechococcus elongtus PCC7942.
5.Often, altering color of cyanobacteria can protract exposures to strong light, low temperatures and drought. In the future, we can test whether CrtZ transformant can bear such harsh conditions.
6.Microalgae are versatile organisms. Morning Glory Pool is one of the main attractions of Yellowstone National Park. The hot spring contains a variety of bacteria and archae that can bear different temperatures and salts. We may foresee that more microalgae will be changed to other colors for the purpose of adapting to various conditions.

Reference

1.Shinichi Takaichi(2011). Carotenoids in Algae: Distributions, Biosyntheses and Functions. Mar Drugs. 2011; 9(6): 1101–1118.
2.Chuan-Hsiung Chang(2012). Enhancing CO2 bio-mitigation by genetic engineering of cyanobacteria. Energy Environ. Sci., 2012, 5, 8318.
3.NCBI (https://www.ncbi.nlm.nih.gov/nuccore/CP000100)
4.Kwangryul Baek, Duk Hyoung Kim, Jooyeon Jeong, Sang Jun Sim, Anastasios Melis, Jin-Soo Kim, EonSeon Jin & Sangsu Bae(2016).DNA-free two-gene knockout in Chlamydomonas reinhardtii via CRISPR-Cas9 ribonucleoproteins. Scientific Reports 6, Article number: 30620 (2016)
5.Jean-Hugues B. Hatier, Michael J. Clearwater, Kevin S. Gould(2013)The Functional Significance of Black-Pigmented Leaves: Photosynthesis, Photoprotection and Productivity in Ophiopogon planiscapus ‘Nigrescens’(https://doi.org/10.1371/journal.pone.0067850)


pPIGBACK-PrbcL-CrtZ



Assembly Compatibility:
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    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]