Difference between revisions of "Part:BBa K2740018"
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<partinfo>BBa_K2740018 parameters</partinfo> | <partinfo>BBa_K2740018 parameters</partinfo> | ||
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<h2>Parameter of Protein </h2> | <h2>Parameter of Protein </h2> | ||
<p align="left">Number of amino acids: 129</p> | <p align="left">Number of amino acids: 129</p> | ||
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<h2>Molecular modeling of nifX</h2> | <h2>Molecular modeling of nifX</h2> | ||
<p align="left">To learn more about the molecular structure of nitrogen fixation protein NifX that favors the insertion of molybdenum-iron protein cofactors into nitrogenase encoded by nifX, we use Swiss-Model to get the molecular model.</p> | <p align="left">To learn more about the molecular structure of nitrogen fixation protein NifX that favors the insertion of molybdenum-iron protein cofactors into nitrogenase encoded by nifX, we use Swiss-Model to get the molecular model.</p> | ||
| − | [[File:T--Nanjing-China--nifX-structure.png| | + | [[File:T--Nanjing-China--nifX-structure.png|400px|thumb|center]] |
<h2>Confirmation of Expression of nifX</h2> | <h2>Confirmation of Expression of nifX</h2> | ||
| − | <p | + | <p>We test expression profiles of each structure gene in the nif cluster that overexpressed in engineered E.coli JM109 (EJNC). E.coli JM109 (EJ) severs as control by conducting Real-time Quantitative PCR(qPCR). Relative expression compared to the housekeeping gene 16S rRNA is shown. So we can know the expression level of nifX in the E.coli JM109 (EJ).</p> |
| − | [[File:T--Nanjing-China--nifX.jpg|600px|thumb|center | + | [[File:T--Nanjing-China--nifX.jpg|600px|thumb|center|Figure 1. Expression profiles of each structure gene in the nif cluster that overexpressed in engineered E.coli JM109 (EJNC). E.coli JM109 (EJ) severs as control and relative expression compared to the housekeeping gene 16S rRNA is shown. N.D. represent not ditected.]] |
| − | + | <h2>Usage</h2> | |
| − | + | ||
| − | + | ||
| − | + | ||
<p>In our this year’s project, we intends to establish a sound and ideal whole-cell photocatalytic nitrogen fixation system. We use the engineered <em>E. coli</em> cells to express nitrogenase and in-situ synthesize of CdS semiconductors in the biohybrid system. Instead of ATP-hydrolysis, such system is able to photocatalytic N2(nitrogen) to NH3(ammonia). The biohybrid system based on engineered E. coli cells with biosynthesis inorganic materials will likely become an alternative approach for the convenient utilization of solar energy. So, certainly we need not only a powerful solar power transition system but also a strong nitrogen fixation system to improve the efficiency of our whole-cell photocatalytic nitrogen fixation system. According to the above requirements, we choose a different nif gene cluster from <em>Paenibacillus polymyxa</em> CR1 to test its expression level.</p> | <p>In our this year’s project, we intends to establish a sound and ideal whole-cell photocatalytic nitrogen fixation system. We use the engineered <em>E. coli</em> cells to express nitrogenase and in-situ synthesize of CdS semiconductors in the biohybrid system. Instead of ATP-hydrolysis, such system is able to photocatalytic N2(nitrogen) to NH3(ammonia). The biohybrid system based on engineered E. coli cells with biosynthesis inorganic materials will likely become an alternative approach for the convenient utilization of solar energy. So, certainly we need not only a powerful solar power transition system but also a strong nitrogen fixation system to improve the efficiency of our whole-cell photocatalytic nitrogen fixation system. According to the above requirements, we choose a different nif gene cluster from <em>Paenibacillus polymyxa</em> CR1 to test its expression level.</p> | ||
<p> </p> | <p> </p> | ||
| − | <p | + | <h2>Reference</h2> |
| + | <p>1. Wang, L., et al., <em>A minimal nitrogen fixation gene cluster from Paenibacillus sp. WLY78 enables expression of active nitrogenase in Escherichia coli.</em> PLoS Genet, 2013. <strong>9</strong>(10): p. e1003865.<br /> | ||
| + | 2. Fixen, K.R., et al., <em>Light-driven carbon dioxide reduction to methane by nitrogenase in a photosynthetic bacterium.</em> Proc Natl Acad Sci U S A, 2016. <strong>113</strong>(36): p. 10163-7.<br /> | ||
| + | 3. Brown, K.A., et al., <em>Light-driven dinitrogen reduction catalyzed by a CdS:nitrogenase MoFe protein biohybrid.</em> Science, 2016. <strong>352</strong>(6284): p. 448-50.<br /> | ||
| + | 4. Kuypers, M.M.M., H.K. Marchant, and B. Kartal, <em>The microbial nitrogen-cycling network.</em> Nat Rev Microbiol, 2018. <strong>16</strong>(5): p. 263-276.<br /> | ||
| + | 5. Wei, W., et al., <em>A surface-display biohybrid approach to light-driven hydrogen production in air.</em> Sci Adv, 2018. <strong>4</strong>(2): p. eaap9253.<br /> | ||
| + | 6. Wang, X., et al., <em>Using synthetic biology to distinguish and overcome regulatory and functional barriers related to nitrogen fixation.</em> PLoS One, 2013. <strong>8</strong>(7): p. e68677.<br /> | ||
| + | 7. Yang, J., et al., <em>Modular electron-transport chains from eukaryotic organelles function to support nitrogenase activity.</em> Proc Natl Acad Sci U S A, 2017. <strong>114</strong>(12): p. E2460-E2465.<br /> | ||
| + | 8. Yang, J., et al., <em>Polyprotein strategy for stoichiometric assembly of nitrogen fixation components for synthetic biology.</em> Proc Natl Acad Sci U S A, 2018. <strong>115</strong>(36): p. E8509-E8517.<br /> | ||
| + | 9. Yang, J.G., et al., <em>Reconstruction and minimal gene requirements for the alternative iron-only nitrogenase in Escherichia coli.</em> Proceedings of the National Academy of Sciences of the United States of America, 2014. <strong>111</strong>(35): p. E3718-E3725.<br /> | ||
| + | 10. Howard, J.B. and D.C. Rees, <em>Structural basis of biological nitrogen fixation.</em> Chemical Reviews, 1996. <strong>96</strong>(7): p. 2965-2982.</p></body> | ||
| + | </html> | ||
Revision as of 11:05, 16 October 2018
CR1 nifX
CR1 nifX encodes nitrogen fixation protein NifX that favors the insertion of molybdenum-iron protein cofactors into nitrogenase.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Parameter of Protein
Number of amino acids: 129
Molecular weight: 14126.33
Theoretical pI: 6.51
Amino acid composition:
Ala (A) 16 12.4%
Arg (R) 7 5.4%
Asn (N) 4 3.1%
Asp (D) 3 2.3%
Cys (C) 1 0.8%
Gln (Q) 7 5.4%
Glu (E) 11 8.5%
Gly (G) 10 7.8%
His (H) 5 3.9%
Ile (I) 10 7.8%
Leu (L) 10 7.8%
Lys (K) 6 4.7%
Met (M) 5 3.9%
Phe (F) 7 5.4%
Pro (P) 4 3.1%
Ser (S) 7 5.4%
Thr (T) 5 3.9%
Trp (W) 1 0.8%
Tyr (Y) 0 0.0%
Val (V) 10 7.8%
Pyl (O) 0 0.0%
Sec (U) 0 0.0%
(B) 0 0.0%
(Z) 0 0.0%
(X) 0 0.0%
Total number of negatively charged residues (Asp + Glu): 14
Total number of positively charged residues (Arg + Lys): 13
Atomic composition:
Carbon C 627
Hydrogen H 1006
Nitrogen N 178
Oxygen O 181
Sulfur S 6
Formula: C627H1006N178O181S6
Total number of atoms: 1998
Extinction coefficients:
Extinction coefficients are in units of M-1 cm-1, at 280 nm measured in water.
Ext. coefficient 5500
Abs 0.1% (=1 g/l) 0.389, assuming all pairs of Cys residues form cystines
Ext. coefficient 5500
Abs 0.1% (=1 g/l) 0.389, assuming all Cys residues are reduced
Estimated half-life:
The N-terminal of the sequence considered is M (Met).
The estimated half-life is: 30 hours (mammalian reticulocytes, in vitro).
>20 hours (yeast, in vivo).
>10 hours (Escherichia coli, in vivo).
Instability index:
The instability index (II) is computed to be 47.67
This classifies the protein as unstable.
Aliphatic index: 95.35
Grand average of hydropathicity (GRAVY): 0.051
Design Notes
Nitrogenase is a complex enzyme system consisting of nine protein components. Additionally, to maintain stoichiometry of these protein components is an essential requirement for nitrogenase biosynthesis and activity. However, there is only one copy of each structure gene present in the nif gene cluster. Therefore, cloning each of these nif genes and setting as independent part can facilitate the regulation of balancing expression ratios from the transcription and/or translation level(s) when they are heterogeneously expressed in non-diazotrophic hosts.
Molecular modeling of nifX
To learn more about the molecular structure of nitrogen fixation protein NifX that favors the insertion of molybdenum-iron protein cofactors into nitrogenase encoded by nifX, we use Swiss-Model to get the molecular model.
[[File:T--Nanjing-China--nifX-structure.png|400px|thumb|center]]Confirmation of Expression of nifX
We test expression profiles of each structure gene in the nif cluster that overexpressed in engineered E.coli JM109 (EJNC). E.coli JM109 (EJ) severs as control by conducting Real-time Quantitative PCR(qPCR). Relative expression compared to the housekeeping gene 16S rRNA is shown. So we can know the expression level of nifX in the E.coli JM109 (EJ).
[[File:T--Nanjing-China--nifX.jpg|600px|thumb|center|Figure 1. Expression profiles of each structure gene in the nif cluster that overexpressed in engineered E.coli JM109 (EJNC). E.coli JM109 (EJ) severs as control and relative expression compared to the housekeeping gene 16S rRNA is shown. N.D. represent not ditected.]]Usage
In our this year’s project, we intends to establish a sound and ideal whole-cell photocatalytic nitrogen fixation system. We use the engineered E. coli cells to express nitrogenase and in-situ synthesize of CdS semiconductors in the biohybrid system. Instead of ATP-hydrolysis, such system is able to photocatalytic N2(nitrogen) to NH3(ammonia). The biohybrid system based on engineered E. coli cells with biosynthesis inorganic materials will likely become an alternative approach for the convenient utilization of solar energy. So, certainly we need not only a powerful solar power transition system but also a strong nitrogen fixation system to improve the efficiency of our whole-cell photocatalytic nitrogen fixation system. According to the above requirements, we choose a different nif gene cluster from Paenibacillus polymyxa CR1 to test its expression level.
Reference
1. Wang, L., et al., A minimal nitrogen fixation gene cluster from Paenibacillus sp. WLY78 enables expression of active nitrogenase in Escherichia coli. PLoS Genet, 2013. 9(10): p. e1003865.
2. Fixen, K.R., et al., Light-driven carbon dioxide reduction to methane by nitrogenase in a photosynthetic bacterium. Proc Natl Acad Sci U S A, 2016. 113(36): p. 10163-7.
3. Brown, K.A., et al., Light-driven dinitrogen reduction catalyzed by a CdS:nitrogenase MoFe protein biohybrid. Science, 2016. 352(6284): p. 448-50.
4. Kuypers, M.M.M., H.K. Marchant, and B. Kartal, The microbial nitrogen-cycling network. Nat Rev Microbiol, 2018. 16(5): p. 263-276.
5. Wei, W., et al., A surface-display biohybrid approach to light-driven hydrogen production in air. Sci Adv, 2018. 4(2): p. eaap9253.
6. Wang, X., et al., Using synthetic biology to distinguish and overcome regulatory and functional barriers related to nitrogen fixation. PLoS One, 2013. 8(7): p. e68677.
7. Yang, J., et al., Modular electron-transport chains from eukaryotic organelles function to support nitrogenase activity. Proc Natl Acad Sci U S A, 2017. 114(12): p. E2460-E2465.
8. Yang, J., et al., Polyprotein strategy for stoichiometric assembly of nitrogen fixation components for synthetic biology. Proc Natl Acad Sci U S A, 2018. 115(36): p. E8509-E8517.
9. Yang, J.G., et al., Reconstruction and minimal gene requirements for the alternative iron-only nitrogenase in Escherichia coli. Proceedings of the National Academy of Sciences of the United States of America, 2014. 111(35): p. E3718-E3725.
10. Howard, J.B. and D.C. Rees, Structural basis of biological nitrogen fixation. Chemical Reviews, 1996. 96(7): p. 2965-2982.