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~~<img class="fit-image" src="https://static.igem.org/mediawiki/2021/b/b1/T--BJ101ID--service_details.jpg" alt="Service Details Image">~~

<h2 class="">Background & Investigation</h2>

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<p>Paper plays an ~~utmost~~ important role in human daily life. No one could ever imagine what would happen without the presence of paper. In 2018, around 422 million metric tons of paper consumed globally. In the future, the amount of paper ~~consumes expect~~ to grow steadily ~~over the next decade~~, reaching approximately 461 million metric tons in 2030. ~~Papers~~ are made from ~~tons of~~ trees, which means that mammoth amount of trees will be ~~cutting~~ off. Loss of trees will cause many environmental issues such as climate change, flooding, increased greenhouse gases and a host of problems for indigenous people.</p>

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<p>Paper plays an extremely important role in human daily life. No one could ever imagine what would happen without the presence of paper. In 2018, around 422 million metric tons of paper were consumed globally. In the future, the amount of paper people consume is expected to grow steadily, reaching approximately 461 million metric tons in 2030. Paper are made from trees, which means that mammoth amount of trees will be cut off. Loss of trees will cause many environmental issues such as climate change, flooding, increased greenhouse gases and a host of problems for indigenous people.</p>

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<p>~~We use~~ the ~~same procedure when~~ pre-experiment ~~making recycle~~ paper ~~with Cai Lun~~ as ~~picture shown above~~. ~~Also~~, we ~~found essays online~~ that ~~sericin and chitosan~~ can enhance quality of paper ~~by adding them into~~ paper ~~pulp~~. ~~What’s more, there are also study shows that enzyme deinking is an environmentally friendly process~~. ~~So, we focus on putting genes of these materials into Escherichia coli in series~~.</p>

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<~~h2 style~~="~~color:#aa5500;~~">Design</h2>

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<h2 style="color:#00aaff;">Why we are doing this</h2>

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<p style="color:#aa5500;">~~First, as what~~ we already mentioned in abstract, although our technology has improved a lot, the quality of recycled paper ~~is still not as perfect as~~ first-hand paper. So, we ~~design~~ an experiment in order to test if we can improve the quality of recycled paper. The ~~materials~~ we chose to use are ~~additives~~ sericin and chitosan~~, because according~~ to ~~the online~~ research ~~we had done~~, sericin can make recycled paper softer and more resilient while chitosan can make recycled paper harder and ~~more~~ folding endurant.</p>

+

<p style="color:#00aaff;">While doing a geography project around school, part of our iGEM teams had discovered that there were many papers that had only been used one one-side and was thrown away into the recycle box. However, it is a really long process to recycle paper and it is also a burden for school to purchase paper from time to time. In a larger perspective, recycle paper can also provide environmental issues from happening. After doing the pre-experiment, we found out that recycled paper doesn’t not have a smooth surface and the recycling process needs to be more environmental-friendly as well.</p>

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<p style="color:#aa5500;">~~There are four groups in our experiment. One group~~ is ~~control group. The other three groups are experimental groups. The control group is original recycled paper made~~ by us. ~~The first experimental group is recycled paper with only~~ sericin. The ~~second one is recycled paper with only chitosan~~. ~~The third one is paper~~ with ~~both~~ sericin ~~and chitosan~~. ~~Here are~~ the ~~boxes~~ of ~~paper pulp with~~ sericin and ~~chitosan in it~~. ~~We use turbulator and paper already used~~ to ~~make paper pulp. Lastly~~, ~~We will test~~ the ~~strength~~, ~~capacity~~, ~~folding endurance and other measurements to see if~~ the ~~quality~~ of ~~recycled paper can be improved by~~ sericin ~~and chitosan~~.</p>

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<h2 style="color:#~~00aaff~~;">~~Why we are doing~~ this</h2>

+

<p>Based on these two problems, we are considering that whether we can use synthetic biology to enhance the quality of recycled paper.</p>

−

<p style="color:#~~00aaff~~;">~~While doing a geography project around school~~, ~~students in IGEM teams had discovered that there were many papers that~~ only ~~used~~ one~~-side had been throw away into the recycle box that provide~~ in the ~~hall~~. ~~However, it~~ is ~~a really long process to recycle paper and it is also a burden for school to purchase paper from time to time~~. ~~In a larger perspective, recycle paper can also provide environmental issues from happening~~. ~~After doing pre~~-~~experiment~~, we ~~found out that recycled paper do not contain smooth surface and more environmental friendly deinking process~~. ~~Base on these two problems~~, we ~~are considering that whether we can enhance quality and deinking process~~ of ~~recycle paper~~.</p>

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<p>Source:https://www.statista.com/statistics/1089078/demand-paper-globally-until-2030/</p>

−

</div>

+

<p>Image:https://blog.manetmobile.com/wp-content/uploads/2019/02/book-collection-education-159751-1.jpg</p>

+

<p>Image:https://www.controlnroll.com/what-happens-to-paper-after-it-is-put-into-the-recycle-bin/</p>

+

</div>

+

</div>

+

+

<div class="title"><h2>Design</h2></div>

+

+

+

<h2 class="">First Part</h2>

+

<p style="color:#aa5500;">As we have already mentioned in abstract, although our technology has improved a lot, the quality of recycled paper cannot compete with first-hand paper. So, we designed an experiment in order to test if we can improve the quality of recycled paper. The additives we chose to use are sericin and chitosan. According to our research, sericin can make recycled paper softer and more resilient while chitosan can make recycled paper harder and increase folding endurant.</p>

+

<p style="color:#aa5500;">Sericin is a complex protein produced by silk moth. Two genes encode sericin, Ser1 and Ser2. The different molecular weight sericin are the products of different splicing events at the transcript level. Some conformation studies with sericin from the silk gland of B.mori or regenerated sericin from B. mori cocoons suggested a random coil structure. However, the samples used in these studies were mixtures of the various native sericin proteins, therefore the structure of the individual proteins is unknown and the contribution of specific sequences toward secondary structure is not confirmed. Therefore, to better understand sericin structure, interactions between sericin and fibroin, and the biological relevance of sericin in fiber structure, high molecular weight pure sericin-like proteins are required. One clue suggests that Ser1, the encoding of sericin consists of 70 repeats of the 38-amino acid motif: </p>

+

<p style="color:#ff0000; font-weight: bold;">SSTGSSSNTDSNSNSVGSSTSGGSSTYGYSSNSRDGSV. </p>

+

<p style="color:#aa5500;">The molecular mass of sericin 1 proteins is 76–284 kDa. Hence, a sericin-like protein can be synthesized based on this 38-amino acid motif. </p>

+

<p style="color:#aa5500;">We constructed the pET28a(+) plasmid for E.coli to express sericin. In the first test, we added only one repeat in the multiple cloning site of the plasmid to form pET-28a(+)-Ser-01. The functional part is composed of T7 promoter-6xHis-repeat-6xHis-T7 terminator.</p>

+

+

<h2 style="color:#aa5500;">In order to imitate the original protein with multiple repeat inside its sequence, we decided to add eight repeats in the multiple cloning site of the plasmid to form pET-28a(+)-Ser-08. Among each repeat, we used the previous linker part BBa_K243004 to link each repeat. The functional part is composed of T7 promoter-6xHis-[repeat-Linker BBa_K243004]( for 8 times )-6xHis-T7 terminator.</h2>

+

</div>

@@ Line 72: / Line 72: @@
      <div class="time"></div>
      <div class="txt">
-   <img class="fit-image" src="https://static.igem.org/mediawiki/2021/b/b1/T--BJ101ID--service_details.jpg" alt="Service Details Image">
     <h2 class="">Background &amp; Investigation</h2>
-     <p>Paper plays an utmost important role in human daily life. No one could ever imagine what would happen without the presence of paper. In 2018, around 422 million metric tons of paper consumed globally. In the future, the amount of paper consumes expect to grow steadily over the next decade, reaching approximately 461 million metric tons in 2030. Papers are made from tons of trees, which means that mammoth amount of trees will be cutting off. Loss of trees will cause many environmental issues such as climate change, flooding, increased greenhouse gases and a host of problems for indigenous people.</p>
+      <p>Paper plays an extremely important role in human daily life. No one could ever imagine what would happen without the presence of paper. In 2018, around 422 million metric tons of paper were consumed globally. In the future, the amount of paper people consume is expected to grow steadily, reaching approximately 461 million metric tons in 2030. Paper are made from trees, which means that mammoth amount of trees will be cut off. Loss of trees will cause many environmental issues such as climate change, flooding, increased greenhouse gases and a host of problems for indigenous people.</p>
-       <p>We use the same procedure when pre-experiment making recycle paper with Cai Lun as picture shown above. Also, we found essays online that sericin and chitosan can enhance quality of paper by adding them into paper pulp. What’s more, there are also study shows that enzyme deinking is an environmentally friendly process. So, we focus on putting genes of these materials into Escherichia coli in series.</p>
+      <img src="https://static.igem.org/mediawiki/2021/f/ff/T--BJ101ID--des1.jpg" alt="Blog Details Image" data-aos="fade-up" data-aos-duration="1800">
-      <h2 style="color:#aa5500;">Design</h2>
+	  <h2 style="color:#00aaff;">Why we are doing this</h2>
-       <p style="color:#aa5500;">First, as what we already mentioned in abstract, although our technology has improved a lot, the quality of recycled paper is still not as perfect as first-hand paper. So, we design an experiment in order to test if we can improve the quality of recycled paper. The materials we chose to use are additives sericin and chitosan, because according to the online research we had done, sericin can make recycled paper softer and more resilient while chitosan can make recycled paper harder and more folding endurant.</p>
+       <p style="color:#00aaff;">While doing a geography project around school, part of our iGEM teams had discovered that there were many papers that had only been used one one-side and was thrown away into the recycle box. However, it is a really long process to recycle paper and it is also a burden for school to purchase paper from time to time. In a larger perspective, recycle paper can also provide environmental issues from happening. After doing the pre-experiment, we found out that recycled paper doesn’t not have a smooth surface and the recycling process needs to be more environmental-friendly as well.</p>
-       <p style="color:#aa5500;">There are four groups in our experiment. One group is control group. The other three groups are experimental groups. The control group is original recycled paper made by us. The first experimental group is recycled paper with only sericin. The second one is recycled paper with only chitosan. The third one is paper with both sericin and chitosan. Here are the boxes of paper pulp with sericin and chitosan in it. We use turbulator and paper already used to make paper pulp. Lastly, We will test the strength, capacity, folding endurance and other measurements to see if the quality of recycled paper can be improved by sericin and chitosan.</p>
+      <img src="https://static.igem.org/mediawiki/2021/5/53/T--BJ101ID--des2.jpg" alt="Blog Details Image" width=800px>
-      <h2 style="color:#00aaff;">Why we are doing this</h2>
+	  <p>Based on these two problems, we are considering that whether we can use synthetic biology to enhance the quality of recycled paper.</p>
-      <p style="color:#00aaff;">While doing a geography project around school, students in IGEM teams had discovered that there were many papers that only used one-side had been throw away into the recycle box that provide in the hall. However, it is a really long process to recycle paper and it is also a burden for school to purchase paper from time to time. In a larger perspective, recycle paper can also provide environmental issues from happening. After doing pre-experiment, we found out that recycled paper do not contain smooth surface and more environmental friendly deinking process. Base on these two problems, we are considering that whether we can enhance quality and deinking process of recycle paper.</p>
+	  <p>Source:https://www.statista.com/statistics/1089078/demand-paper-globally-until-2030/</p>
-    </div>
+	  <p>Image:https://blog.manetmobile.com/wp-content/uploads/2019/02/book-collection-education-159751-1.jpg</p>
+	  <p>Image:https://www.controlnroll.com/what-happens-to-paper-after-it-is-put-into-the-recycle-bin/</p>
+	</div>
+  </div>
+  <div class="nr-box">
+    <div class="title"><h2>Design</h2></div>
+    <div class="time"></div>
+    <div class="txt">
+   <h2 class="">First Part</h2>
+       <p style="color:#aa5500;">As we have already mentioned in abstract, although our technology has improved a lot, the quality of recycled paper cannot compete with first-hand paper. So, we designed an experiment in order to test if we can improve the quality of recycled paper. The additives we chose to use are sericin and chitosan. According to our research, sericin can make recycled paper softer and more resilient while chitosan can make recycled paper harder and increase folding endurant.</p>
+       <p style="color:#aa5500;">Sericin is a complex protein produced by silk moth. Two genes encode sericin, Ser1 and Ser2. The different molecular weight sericin are the products of different splicing events at the transcript level. Some conformation studies with sericin from the silk gland of B.mori or regenerated sericin from B. mori cocoons suggested a random coil structure. However, the samples used in these studies were mixtures of the various native sericin proteins, therefore the structure of the individual proteins is unknown and the contribution of specific sequences toward secondary structure is not confirmed.  Therefore, to better understand sericin structure, interactions between sericin and fibroin, and the biological relevance of sericin in fiber structure, high molecular weight pure sericin-like proteins are required. One clue suggests that Ser1, the encoding of sericin consists of 70 repeats of the 38-amino acid motif: </p>
+	  <p style="color:#ff0000; font-weight: bold;">SSTGSSSNTDSNSNSVGSSTSGGSSTYGYSSNSRDGSV. </p>
+	  <p style="color:#aa5500;">The molecular mass of sericin 1 proteins is 76–284 kDa. Hence, a sericin-like protein can be synthesized based on this 38-amino acid motif.  </p>
+	  <p style="color:#aa5500;">We constructed the pET28a(+) plasmid for E.coli to express sericin. In the first test, we added only one repeat in the multiple cloning site of the plasmid to form pET-28a(+)-Ser-01. The functional part is composed of T7 promoter-6xHis-repeat-6xHis-T7 terminator.</p>
+	  <img src="https://static.igem.org/mediawiki/2021/3/34/T--BJ101ID--design.png" alt="Blog Details Image" data-aos="fade-up" data-aos-duration="1800">
+  	  <h2 style="color:#aa5500;">In order to imitate the original protein with multiple repeat inside its sequence, we decided to add eight repeats in the multiple cloning site of the plasmid to form pET-28a(+)-Ser-08. Among each repeat, we used the previous linker part BBa_K243004 to link each repeat. The functional part is composed of T7 promoter-6xHis-[repeat-Linker BBa_K243004]( for 8 times )-6xHis-T7 terminator.</h2>
+  	</div>
    </div>
 </div>