Difference between revisions of "Team:Amoy/Project/Background"

Line 122: Line 122:
 
<h1 class="main_h1">Ⅰ. The applications of L-<i>tert</i>-leucine</h1>
 
<h1 class="main_h1">Ⅰ. The applications of L-<i>tert</i>-leucine</h1>
  
<p class="main_p">L-<i>tert</i>-leucine is an important and attractive chiral building block. Owing to its bulky and hydrophobic tert-butyl side chain which would provide particularly great steric hindrance in the process of reaction, this unnatural amino acid is also widely used as chiral auxiliaries and catalysts in asymmetric synthesis in developing chiral pharmaceutically active chemicals <sup>[1]</sup>. What’s more, it also plays an important role in the industry of food additive and cosmetics.</br></p>
+
<p class="main_p">L-<i>tert</i>-leucine is an important and attractive chiral building block. Owing to its bulky and hydrophobic <i>tert</i>-butyl side chain which would provide particularly great steric hindrance in the process of reaction, this unnatural amino acid is also widely used as chiral auxiliaries and catalysts in asymmetric synthesisin developing chiral pharmaceutically active chemicals [1]. What’s more, it also plays an impotant role in the industry of food additive and cosmetics.</p>
  
<img class="main_img" src="https://static.igem.org/mediawiki/2015/b/bf/Amoy-Project_Background_fig1.jpg" style="width: 80%;" />
+
<img class="main_img" src="https://static.igem.org/mediawiki/2015/b/b7/Amoy-Project_Background_figure1.jpg" style="width: 80%;" />
  
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 1</strong> The application of L-<i>tert</i>-leucine</p>
+
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 1. </strong>The applications of L-<i>tert</i>-leucine</p>
  
<p class="main_p"></br></br>L-<i>tert</i>-leucine can apply in various Pharmaceutical fields. L-<i>tert</i>-leucine was introduced into new and more efficient protease inhibitors of many viral diseases, such as HIV, HCV, IL-l-induced cartilage degradation and so on.</br></br>
+
<h2 class="main_h2"></br>1. Pharmaceutical applications of L-<i>tert</i>-leucine</h2>
  
As we can see, AIDS is an awful disease which disturbed humans for many years. Lots of people suffered from AIDS for many years and died in pain. Investigations show that HIV-protease is an aspartic acid protease which is necessary for viral replication. So inhibition of this protease could make HIV non-infectious, which could be a useful approach against AIDS.</br></br>
+
<p class="main_p">L-<i>tert</i>-leucine can apply in various Pharmaceutical fields. L-<i>tert</i>-leucine was introduced into new and more efficient protease inhibitors of many viral diseases, such as HIV, HCV, IL-l-induced cartilage degradation and so on [2].</br></br>
  
Today, the most efficient HIV-protease inhibitor is Atazanavir (Figure 2) <sup>[2]</sup>. Atazanavir is distinguished from other protease inhibitors by reducing the dosage and enhance the pesticide effect. What we can see from the structure is that L-<i>tert</i>-leucine plays an important role. L-<i>tert</i>-leucine can stabilized the structure and enhance the effect. So L-<i>tert</i>-leucine is very important.</br></p>
+
As we can see, AIDS is an awful disease which disturbed humans for many years. Lots of people suffered from AIDS for many years and died in pain. Investigations show that HIV-protease is an aspartic acid protease which is necessary for viral replication. So inhibition of this protease could make HIV non-infectious, which could be a useful approach against AIDS [2]. Today, the basic structure of HIV-protease inhibitors is phenylnorstatine [(2R,3S)-3-amino-2-hydroxy-4-phenylbutyric acid (Figure 2) [3].</br></br>
 +
</p>
  
<img class="main_img" src="https://static.igem.org/mediawiki/2015/6/60/Amoy-Project_Background_fig2.png" style="width: 40%;" />
+
<img class="main_img" src="https://static.igem.org/mediawiki/2015/9/9f/Amoy-Project_Background_figure2.png" style="width: 80%;" />
  
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 2</strong> The structure of Atazanavir <sup>[4]</sup></p>
+
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 2.</strong> Structure of HIV-protease inhibitor [2]</p>
 +
 
 +
<p class="main_p"></br></br>However, as Figure 2 shows, phenylnorstatine is not enough. In order to optimize protease inhibitors, numerous protected, deprotected and derivatized L-<i>tert</i>-leucines are used to modify phenylnorstatine. Modified compounds could be nice protease inhibitors with considerable antiviral activity.</br></br>
 +
 
 +
Today, the most efficient HIV-protease inhibitor is Atazanavir (Figure 3) [4]. Atazanavir is distinguished from other protease inhibitors by reducing the dosage and enhance the pesticide effect. What we can see from the structure is that L-<i>tert</i>-leucine plays an important role. L-<i>tert</i>-leucine can stabilized the structure and enhance the effect. So production of L-<i>tert</i>-leucine is necessary.</p>
 +
 
 +
<img class="main_img" src="https://static.igem.org/mediawiki/2015/7/77/Amoy-Project_Background_figure3.png" style="width: 30%;" />
 +
 
 +
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 3. </strong>The structure of Atazanavir [4]</p>
 +
 
 +
<p class="main_p"></br></br>As for Hepatitis C, it is also a severe public health issue [5]. In order to cure this disease, we also need a protease inhibitor. And the first option is Telaprevir [6]. The same as Atazanavior, the structure of Telaprevir shows that L-<i>tert</i>-leucine is also an important intermediate.</p>
 +
 
 +
<img class="main_img" src="https://static.igem.org/mediawiki/2015/b/b7/Amoy-Project_Background_figure4.png" style="width: 30%;" />
 +
 
 +
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 4. </strong>The structure of Telaprevir [6]</p>
 +
 
 +
<p class="main_p"></br></br>For the treatment of IL-l-induced cartilage degradation in tissue culture, L-<i>tert</i>-leucine plays an important role. Thirty years ago, Roche Company discovered an N-substituted Tle-N-methylamide (Ro 31-9790, Figure 5) to be a potent collagenase inhibitor which could prevent IL-l-induced cartilage degradation [2].</p>
 +
 
 +
<img class="main_img" src="https://static.igem.org/mediawiki/2015/e/ef/Amoy-Project_Background_figure5.png" style="width: 30%;" />
 +
 
 +
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 5. </strong>The structure of Ro 31-9790 [2]</p>
 +
 
 +
<p class="main_p"></br></br>L-<i>tert</i>-leucine is essential in many fields so that the large-scale production is indispensible.</br></br></p>
 +
 
 +
<h2 class="main_h2">2. Asymmetric synthesis by L-<i>tert</i>-leucine and its derivatives</h2>
 +
<p class="main_p">When L-<i>tert</i>-leucine or its derivatives were employed in asymmetric reactions, the results always showed high optical purity [2]. For example, the following reaction is a reported Michael additions of Grignard reagents to α,β-unsaturated aldimines derived from L-<i>tert</i>-leucine (Figure 6). After hydrolysis and hydrogenation, the finalist product shows high optical purity. Owing to the bulky <i>tert</i>-butyl side chain of compound 1, the side of stronger steric hindrance was locked. Grignard reagents could only attack compound 1 from the special side so that the product shows high enantiomerical purity.</p>
 +
 
 +
<img class="main_img" src="https://static.igem.org/mediawiki/2015/8/85/Amoy-Project_Background_figure6.png" style="width: 80%;" />
 +
 
 +
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 6.</strong> A Michael addition of L-<i>tert</i>-leucine derivatives</p>
 +
 
 +
<p class="main_p"></br></br>Enantiomerical pure L-<i>tert</i>-leucine are important in many fields. So the efficient production of it is significant.</br></br></p>
  
 
<h1 class="main_h1">Ⅱ. The synthesis of L-<i>tert</i>-leucine</h1>
 
<h1 class="main_h1">Ⅱ. The synthesis of L-<i>tert</i>-leucine</h1>
  
<p class="main_p">With its special importance, many methodologies, including chemical and biological resolutions, were developed for its preparation in the past decades. Chemical resolution could be easily carried out on a large scale, however, the complicated process in low yield and the difficulties in the racemization of the opposite enantiomer were also observed <sup>[3]</sup>.</p>
+
<p class="main_p">In recent years, many different technologies have been applied in the synthesis of L-<i>tert</i>-leucine. For example, Strecker synthesis, amidocarbonylation and Acetamidomalonic ester synthesis have already been applied in the production of L-<i>tert</i>-leucine (Figure 7, [1]). But from Figure 7, we could know that there are some bugs in these methods. And the most obvious bugs are low efficiency and pool charity of products. In order to get high optical pure products, chemical recemizations should be carried out after the reaction. Chemical recemization processes are sophisticated and costly and some chemical catalysts contain toxic elements. So these methods are gradually abandoned.</p>
  
<img class="main_img" src="https://static.igem.org/mediawiki/2015/5/5e/Amoy-Project_Background_fig3.jpg" style="width: 80%;" />
+
<img class="main_img" src="https://static.igem.org/mediawiki/2015/0/01/Amoy-Project_Background_figure7.png" style="width: 80%;" />
  
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 1</strong> Comparison of biological method and chemical method of L-<i>tert</i>-leucine synthesis</p>
+
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 7.</strong> Synthesis of recemic amino acid [1]</p>
  
<p class="main_p"></br></br>Biocatalytic protocols, which can be conducted under mild conditions with high selectivity, usually offer greater benefits than chemical procedures and thus gain more and more attention from organic chemists. However, most of these biological resolution procedures are complicated and possess an inherent 50% yield limit <sup>[4-7]</sup>.</br></br>
+
<p class="main_p"></br></br>As a matter of fact, with the development of synthetic biology, enzymes become very efficient and important catalysts in production of L-<i>tert</i>-leucine. What is more, the production of L-<i>tert</i>-leucine was introduced into industrial production by applying enzymatic reductive amination as a method [7].</p>
  
Owing to different activity of leucine dehydrogenase and formate dehydrogenase, the NADH consumption rate does not equal to its regeneration. Therefore, it is necessary to add excess NADH. The cofactor-NADH is a pretty expensive raw material, which will make the mass production of L-<i>tert</i>-leucine not cost-effective.</br></br>
+
<img class="main_img" src="https://static.igem.org/mediawiki/2015/3/36/Amoy-Project_Background_figure8.png" style="width: 80%;" />
  
The circuits with <i>LeuDH</i> and with <i>FDH</i> were inserted into two <i>E.coli</i> separately. Then they added different wet biomass of two <i>E.coli</i> <sup>[8]</sup>. They hoped to keep the activity of two enzyme equal through this method. Researchers used isolated enzymes,and find it disadvantageous because enzymes are easily destabilized in the isolation and purification process.</br></p>
+
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 8.</strong> The synthesis of L-<i>tert</i>-leucine</p>
  
<img class="main_img" src="https://static.igem.org/mediawiki/2015/6/62/Amoy-Project_Background_fig4.png" style="width: 80%;" />
+
<p class="main_p"></br></br>Up to now, the most efficient enzyme is leucine dehydrogenase (LeuDH, from <i>Bacillus sp</i>). It can transform substrate trimethylpyruvate into L-<i>tert</i>-leucine in very good yields and excellent optical purities with the help of cofactor NADH. However, from the Figure 9, we could know that NADH is a rather expensive raw material [8]. As a result, NADH should be regenerated so that this system would commercial attractive. The regeneration of NADH is the so-called cofactor regeneration.</p>
  
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 4</strong> Circuits inserted into two <i>E.coli</i> cells separately</p>
+
<img class="main_img" src="https://static.igem.org/mediawiki/2015/a/ac/Amoy-Project_Background_figure9.png" style="width: 80%;" />
  
<p class="main_p"></br></br>Then researchers planned to use whole-cell biocatalyst to stabilize enzymes and reduce the need of cofactor NADH. They envisaged that a promising strategy for a successful coexpression could be based on the same inducible promoter for both genes but located on two <i>E.coli</i> plasmids with different copy numbers, producing LeuDH and FDH on a different level. <i>FDH</i> was inserted in the plasmid with the higher copy number, while <i>LeuDH</i> was inserted in the medium copy number plasmid. We hope to regulate the copy number of plasmid to ensure the continuous recycling of the cofactor NADH. Presumably, this was achieved by a higher production of FDH compared to LeuDH due to the higher copy number vector for the <i>FDH</i> gene. Furthermore, this <i>LeuDH/FDH</i>-strain is suitable for high-cell density fermentation. Compared with isolated enzymes,whole cell-catalyzed asymmetric process has many advantages, such as simple, efficient, environmentally and economically attractive. However, the trouble is that the activity of two enzymes are both inhibited. Obviously, successful coexpression of two genes is still a challenge for scientists.</br></p>
+
<p class="figure" style="text-align: center; width: 80%; margin-top: 20px;"><strong>Figure 9.</strong> Costs of redox equivalents in US [10]</p>
  
<h1 class="main_h1">Reference:</h1>
+
<p class="main_p"></br></br>Cofactor regeneration could be carried out by means of many different enzymes whose cofactors are NAD+. As for synthesis of L-<i>tert</i>-leucine, cofactor regeneration is acomplished by formate dehydrogenase (FDH, from <i>Candida boidinii</i>) [1]. This process has been introduced into industrial production in ton scale for many years.</br></br>
  
<p class="main_p">[1] Shioiri, T., Izawa, K. & Konoike, T. Application of Whole‐Cell Biocatalysts in the Manufacture of Fine Chemicals. <i>Pharmaceutical Process Chemistry</i>.184-205 (2011)</br>
+
But it is not excellent. There are still some bugs should be amended. And the most interesting aspect is the different activities of LeuDH and FDH. The result caused by different activities is that the different consuming and regenerating rates of NADH. Owing to that the activity of LeuDH is significantly higher than FDH. NADH would be consumed to a low level before the synthesis finished, which results in stopping of production and need excess NADH to support these reactions. Up to now, many scientists have devoted themselves in it and have created many different methods. But this bug is still here, because there are no efficient methods.</br></br>
  
[2] <a href="https://en.m.wikipedia.org/wiki/Atazanavir">https://en.m.wikipedia.org/wiki/Atazanavir</a></br>
+
This year, what we want to do is providing a method to solve this problem.</br></br>
 +
</p>
  
[3] Jin, Jian-Zhong, Chang, Dong-Liang, Zhang, Jie. Discovery and application of new bacterial strains for asymmetric synthesis of L-tert-butyl leucine in high enantioselectivity. Applied Biochemistry and Biotechnology.2011</br>
+
<h1 class="main_h1">Reference:</h1>
  
[4] Eun young Hong,Minho Cha,Hyungdon Yun,Byung-Gee Kim. Asymmetric synthesis of L-tert-leucine and L-3-hydroxyadamantyglycine using branched chain aminotransferase.   Journal of Molecular Catalysis B:Enzymatic 66(2010)228-233</br>
+
<p class="main_p">[1] Shioiri, T., Izawa, K. & Konoike, T. Application of Whole‐Cell Biocatalysts in the Manufacture of Fine Chemicals. <i>Pharmaceutical Process Chemistry</i>.184-205 (2011)</br>
 +
[2] Bommarius, A., S., Schwarm, M., Stingl, K., Kottenhahn, M., Huthmacherand, K. & Drauz, K. Synthesis and use of enantiomerically pure tert-leucine. <i>Tetrahedron: Asymmetry</i>. <strong>6</strong>, 2851-2888 (1995)</br>
  
 +
[3] Ettmayer, P., Hübner, M., Billich, A., Rosenwirth, B. & Gstach, H. Design and synthesis of potent &beta;-secretase (BACE1) inhibitors with P’1 carboxylic acid bioisosteres. <i>Bioorg. Med. Chem. Lett.</i> <strong>4</strong>, 2851-2856 (1994)</br>
 +
[4] <a href="https://en.m.wikipedia.org/wiki/Atazanavir">https://en.m.wikipedia.org/wiki/Atazanavir</a></br>
  
[5] Jing Li, Jiang Pan, Jie Zhang, Jian-He Xu  Stereoselective synthesis of L-tert-leucine by a newly cloned leucine dehydrogenase from Exiguobacterium sibiricum.</br>Journal of Molecular Catalysis B:Enzymatic 105(2014)11-17</br>
+
[5] <a href="https://en.m.wikipedia.org/wiki/Hepatitis_C">https://en.m.wikipedia.org/wiki/Hepatitis_C</a></br>
  
[6] Jian-Zhong, JinDong-Liang, Chang Jie Zhang  Discovery and application of new bacterial strains for asymmetric synthesis of L-tert-butyl leucine in high enantioselectivity.   Appl Biochem Biotechnol (2011) 164:376-385</br>
+
[6] <a href="https://en.m.wikipedia.org/wiki/Telaprevir">https://en.m.wikipedia.org/wiki/Telaprevir</a></br>
[7] Weiming Liu, Jixing Luo, Xiaojian Zhuang, Wenhe Shen, Yang Zhang, SHuang Li, Yi Hu, He Huang  Efficient preparation of enantiopure L-tert-leucine through immobilized penicillin G acylase catalyzed kinetic resolution in aqueous medium. Biochemical Engineering Journal 83(2014) 116-120</br>
+
[7] Gröger, H., May, O., Werner, H., Menzel, A., & Altenbuchner, J. A “second-generation process” for the synthesis of L-neopentylglycine: asymmetric reductive amination using a recombinant whole cell catalysis. <i>Org. Process Res. & Dev.</i>. <strong>10</strong>, 666−669 (2006)</br>
  
[8] Menzel, A., Werner, H., Altenbuchner, J., Gröger, H. From enzymes to "designer bugs" in reductive amination: A new process for the synthesis of L-tert-leucine using a whole cell-catalyst. Eng. Life Sci. 4, 573-576, (2004)</br></br>
+
[8] Wandrey, C. Biochemical reaction engineering for redox reactions. <i> Chem. Rec.</i> <strong>4</strong>, 254-265 (2004)</br></br>
  
  

Revision as of 12:32, 17 September 2015

Aomy/Project

BACKGROUND
The Application of L-tert-leucine

Ⅰ. The applications of L-tert-leucine

L-tert-leucine is an important and attractive chiral building block. Owing to its bulky and hydrophobic tert-butyl side chain which would provide particularly great steric hindrance in the process of reaction, this unnatural amino acid is also widely used as chiral auxiliaries and catalysts in asymmetric synthesisin developing chiral pharmaceutically active chemicals [1]. What’s more, it also plays an impotant role in the industry of food additive and cosmetics.

Figure 1. The applications of L-tert-leucine


1. Pharmaceutical applications of L-tert-leucine

L-tert-leucine can apply in various Pharmaceutical fields. L-tert-leucine was introduced into new and more efficient protease inhibitors of many viral diseases, such as HIV, HCV, IL-l-induced cartilage degradation and so on [2].

As we can see, AIDS is an awful disease which disturbed humans for many years. Lots of people suffered from AIDS for many years and died in pain. Investigations show that HIV-protease is an aspartic acid protease which is necessary for viral replication. So inhibition of this protease could make HIV non-infectious, which could be a useful approach against AIDS [2]. Today, the basic structure of HIV-protease inhibitors is phenylnorstatine [(2R,3S)-3-amino-2-hydroxy-4-phenylbutyric acid (Figure 2) [3].

Figure 2. Structure of HIV-protease inhibitor [2]



However, as Figure 2 shows, phenylnorstatine is not enough. In order to optimize protease inhibitors, numerous protected, deprotected and derivatized L-tert-leucines are used to modify phenylnorstatine. Modified compounds could be nice protease inhibitors with considerable antiviral activity.

Today, the most efficient HIV-protease inhibitor is Atazanavir (Figure 3) [4]. Atazanavir is distinguished from other protease inhibitors by reducing the dosage and enhance the pesticide effect. What we can see from the structure is that L-tert-leucine plays an important role. L-tert-leucine can stabilized the structure and enhance the effect. So production of L-tert-leucine is necessary.

Figure 3. The structure of Atazanavir [4]



As for Hepatitis C, it is also a severe public health issue [5]. In order to cure this disease, we also need a protease inhibitor. And the first option is Telaprevir [6]. The same as Atazanavior, the structure of Telaprevir shows that L-tert-leucine is also an important intermediate.

Figure 4. The structure of Telaprevir [6]



For the treatment of IL-l-induced cartilage degradation in tissue culture, L-tert-leucine plays an important role. Thirty years ago, Roche Company discovered an N-substituted Tle-N-methylamide (Ro 31-9790, Figure 5) to be a potent collagenase inhibitor which could prevent IL-l-induced cartilage degradation [2].

Figure 5. The structure of Ro 31-9790 [2]



L-tert-leucine is essential in many fields so that the large-scale production is indispensible.

2. Asymmetric synthesis by L-tert-leucine and its derivatives

When L-tert-leucine or its derivatives were employed in asymmetric reactions, the results always showed high optical purity [2]. For example, the following reaction is a reported Michael additions of Grignard reagents to α,β-unsaturated aldimines derived from L-tert-leucine (Figure 6). After hydrolysis and hydrogenation, the finalist product shows high optical purity. Owing to the bulky tert-butyl side chain of compound 1, the side of stronger steric hindrance was locked. Grignard reagents could only attack compound 1 from the special side so that the product shows high enantiomerical purity.

Figure 6. A Michael addition of L-tert-leucine derivatives



Enantiomerical pure L-tert-leucine are important in many fields. So the efficient production of it is significant.

Ⅱ. The synthesis of L-tert-leucine

In recent years, many different technologies have been applied in the synthesis of L-tert-leucine. For example, Strecker synthesis, amidocarbonylation and Acetamidomalonic ester synthesis have already been applied in the production of L-tert-leucine (Figure 7, [1]). But from Figure 7, we could know that there are some bugs in these methods. And the most obvious bugs are low efficiency and pool charity of products. In order to get high optical pure products, chemical recemizations should be carried out after the reaction. Chemical recemization processes are sophisticated and costly and some chemical catalysts contain toxic elements. So these methods are gradually abandoned.

Figure 7. Synthesis of recemic amino acid [1]



As a matter of fact, with the development of synthetic biology, enzymes become very efficient and important catalysts in production of L-tert-leucine. What is more, the production of L-tert-leucine was introduced into industrial production by applying enzymatic reductive amination as a method [7].

Figure 8. The synthesis of L-tert-leucine



Up to now, the most efficient enzyme is leucine dehydrogenase (LeuDH, from Bacillus sp). It can transform substrate trimethylpyruvate into L-tert-leucine in very good yields and excellent optical purities with the help of cofactor NADH. However, from the Figure 9, we could know that NADH is a rather expensive raw material [8]. As a result, NADH should be regenerated so that this system would commercial attractive. The regeneration of NADH is the so-called cofactor regeneration.

Figure 9. Costs of redox equivalents in US [10]



Cofactor regeneration could be carried out by means of many different enzymes whose cofactors are NAD+. As for synthesis of L-tert-leucine, cofactor regeneration is acomplished by formate dehydrogenase (FDH, from Candida boidinii) [1]. This process has been introduced into industrial production in ton scale for many years.

But it is not excellent. There are still some bugs should be amended. And the most interesting aspect is the different activities of LeuDH and FDH. The result caused by different activities is that the different consuming and regenerating rates of NADH. Owing to that the activity of LeuDH is significantly higher than FDH. NADH would be consumed to a low level before the synthesis finished, which results in stopping of production and need excess NADH to support these reactions. Up to now, many scientists have devoted themselves in it and have created many different methods. But this bug is still here, because there are no efficient methods.

This year, what we want to do is providing a method to solve this problem.

Reference:

[1] Shioiri, T., Izawa, K. & Konoike, T. Application of Whole‐Cell Biocatalysts in the Manufacture of Fine Chemicals. Pharmaceutical Process Chemistry.184-205 (2011)
[2] Bommarius, A., S., Schwarm, M., Stingl, K., Kottenhahn, M., Huthmacherand, K. & Drauz, K. Synthesis and use of enantiomerically pure tert-leucine. Tetrahedron: Asymmetry. 6, 2851-2888 (1995)
[3] Ettmayer, P., Hübner, M., Billich, A., Rosenwirth, B. & Gstach, H. Design and synthesis of potent β-secretase (BACE1) inhibitors with P’1 carboxylic acid bioisosteres. Bioorg. Med. Chem. Lett. 4, 2851-2856 (1994)
[4] https://en.m.wikipedia.org/wiki/Atazanavir
[5] https://en.m.wikipedia.org/wiki/Hepatitis_C
[6] https://en.m.wikipedia.org/wiki/Telaprevir
[7] Gröger, H., May, O., Werner, H., Menzel, A., & Altenbuchner, J. A “second-generation process” for the synthesis of L-neopentylglycine: asymmetric reductive amination using a recombinant whole cell catalysis. Org. Process Res. & Dev.. 10, 666−669 (2006)
[8] Wandrey, C. Biochemical reaction engineering for redox reactions. Chem. Rec. 4, 254-265 (2004)

CONTACT US

Email: igemxmu@gmail.com

Website: 2015.igem.org/Team:Amoy

Address: Xiamen University, No. 422, Siming South Road, Xiamen, Fujian, P.R.China 361005