Difference between revisions of "Part:BBa K4273001"

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<partinfo>BBa_K4274000 short</partinfo>
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NOTOC__
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<partinfo>BBa_K4273017 short</partinfo>
  
<i>Cl</i>SS_S533A is an optimized biobrick part encoding the gene for alpha-santalene synthase from <i>Clausena lansium</i>. The enzyme catalyzes the conversion of the common isoprenoid intermediate farnesyl pyrophosphate (FPP) into the alpha-santelene in a single step. It is reported that <i>Cl</i>SS's basic amino acid residue S533’s mutation to typical nonpolar amino acid Ala could result in a 1.7-fold increase in production of alpha-santalene compared to the nonmutated strain (Jia Z.et al., 2022) .
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Xyl1 is a xylose assimilation gene encoding xylose reductase (XR) that can converts xylose to xylitol. Xyl1 can provides an alternative carbon source for the pentose phosphate pathway that can increase S7P production.  We selected Xyl1 genes from Scheffersomyces stipitis that proved to be successfully heterologous expressed for efficiently xylose-fermenting in S. Cerevisiae. We used yeast toolkit (Lee, 2015) to assemble the Level 1 plasmid including the promoter, coding sequence, and terminator. Xyl1 is under the control of promoter pTDH3 which provides a high and stable transcription efficiency (Apel, et. al, 2016). Then, we used PCR amplification to obtain the DNA fragment Xyl1 from Level1 plasmid, and two homology arms (LA and RA) from yeast genome.
  
<br>This year, we are using <i>Cl</i>SS_S533A to construct composite parts ptac-RiboJ-B0034-Cl</i>SS_S533A-B0034-ERG20-B0015 (part: BBa_K4274020), ptac-RiboJ-B0034-<i>Cl</i>SS_S533A-B0034-ERG20_F96W-B0015 (part: BBa_K4274021) and ptac-RiboJ-B0034-<i>Cl</i>SS_S533A-FL-ERG20_F96W-B0015 (part: BBa_K4274023). This will allow engineering <i>E.coli</i> DH5a (tnaA-) to heterologously express <i>Cl</i>SS_S533A. Other teams can utilize this part for <i>E. coli</i> alpha-santalene production.
 
  
 
==Usage and Biology==
 
==Usage and Biology==
<i>Cl</i>SS_S533A is an optimized biobrick part encoding the gene for alpha-santalene synthase from Clausena lansium. It was firstly characterized by Jia Z.in 2022, who mutated <i>Cl</i>SS's basic amino acid residue S533 to increase the production of alpha-santalene in <i>E. coli</i> (Jia Z.et al., 2022).
 
  
<br>
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We selected promoters pTDH3 and pPGK1 due to their stability expression in S. cerevisiae (Apel et. al., 2016). These promoters are shown to have stable and strong expression in YPD culture mediums. pTDH3 has highest stability and strength, followed by pPGK1. Therefore, we used pTDH3 for DDGS and pPGK1 for OMT. By introducing another copy of DDGS-OMT at position Nqm1 and inserting the genes into S. cerevisiae's genome, we were able to increase the production of shinorine and porphyra-334 to a great extent.
  
Natural <i>Cl</i>SS is an alpha-santalene synthase which could catalyze the conversion of the common isoprenoid intermediate farnesyl pyrophosphate (FPP) into the alpha-santelene in a single step. It has been successfully heterologously expressed to produce functional terpene product in both yeast (Wenlong Z.et al., 2020) and <i>E. coli</i> (Jia Z.et al., 2022). But the mutation of residue S533 to Ala led to the addition of two hydrogen bonds near this site (<4 Å), which resulted in a high α-santalene production <i>E.coli</i> strain.
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==Experiment==
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<b>Characterization</b>
 
<br>
 
<br>
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For our experiment, we used the strong promoters such as pTDH3 for DDGS and pPGK1 for OMT when we tried to convert S7P to 4DG efficiently, and selected DDGS(NpR5600) and OMT(NpR5599) for homologous recombination into SC.L2 genome.  Moreover, we chosed position 308 from chromosome III (Apel et. al., 2016) for genome recombinant. By using this method, we transformed pCRCT-308 plasmid, the DNA fragments of homologous arms, DDGS, and OMT into SC.L2. The recombinant strains were identified by PCR and sequencing (Fig.4C and D), demonstrating that SC.L3 was obtained in the experiment.
  
In our study, <i>Cl</i>SS_S533A could be heterologously expressed in <i>E. coli</i>, and allows for fused proteins to be bound to ERG20 (Part: BBa_K849001) and ERG20_F96W (Part: BBa_K4274002)
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[[Image:t-links-china-figure100.png|thumb|left|900px|'''Figure 1: Insertion of DDGS and OMT at 308 position. By transforming CRISPR-308 plasmid pCRCT-308, LA, DDGS, OMT and RA, the two genes should be inserted at 308 position (A). We expanded the homogenous arms, DDGS and OMT genes through PCR and transformed them into L2 strains for it to be assembled in the genome. We performed colony PCR on the yeast colonies to determine the existence of LA-DDGS and OMT (C) and verified this result through the sequencing testing (D), obtaining the L3 strain.''']]
  
==Source==
 
  
<i>Scheffersomyces stipitis</i>
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<br>
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<b>Optimization</b>
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<br>
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To increase the quantity of MAAs production, we further optimized the SC.L3 strains. We notice that Nqm1 has similar functions as TAL1 in shunting S7P into glycolytic pathway. So, to increase the S7P pool, we decided to remove this gene and insert an extra copy of DDGS-OMT simultaneously. The result shows that gene expression can be enhanced by using multiple promoters for increasing MAAs production (Yang et. al., 2018). For modification, pTDH3 was used to express OMT and pPGK1 was used to express DDGS, making the total transcription rate of the two copie roughly equal. Then, we inserted DNA fragments of LA, OMT, DDGS, RA and the pCRCT-Nqm1 plasmid into SC.L3. After PCR, DNA sequencing, and selection of recombinant colonies, we removed the pCRCT-Nqm1 plasmid, obtaining SC.L6 in the end.
  
==Characterization==
 
  
After engineering, <i>E. coli</i> could utilize both MEP pathway and MVA pathway for the universal precursors isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP), then synthesize santalene with the help of FPP Synthase (FPPS) and santalene synthase (SS). Except heterologously expressed MVA pathway and ERG20 of <i>Saccharomyces cerevisiae</i> and santalene synthase of <i>Clausena lansium</i> (<i>Cl</i>SS), several modifications upon ERG20 or <i>Cl</i>SS by amino acid mutation, binding to a hydrophillic tag and the construction of fusion protein were tested for the higher yield of santalene. Therefore, with the help of the co-transformation of pMVA plasmid with various pW1 plasmids, including pW1_CE, pW1_CEM, pW1_TCEM and pW1_CEM_FL, different strains like CE, CEM, TCEM, CEM_FL were successfully constructed (Figure 1). The complete pathway we designed for producing santalene in <i>E. coli</i> is illustrated in Figure 1.
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[[Image:t-links-china-figure51.png|thumb|left|900px|'''Figure 2: Optimizing production by inserting OMT-DDGS and deleting Nqm1 gene. Nqm1 function similarly as TAL1, which reduces S7P concentrations. By transforming CRISPR-Nqm1 plasmid pCRCT-Nqm1, LA, OMT, DDGS, and RA, the two genes should be inserted at Nqm1 position; we switched the promoter of DDGS to pPGK1 and OMT to pTDH3 in order to have equal net transcription rate of DDGS and OMT genes. We expanded the homogenous arms, OMT, DDGS genes through PCR and transformed them into L5 strains for it to be assembled in the genome. We performed colony PCR on the yeast colonies to determine the existence of LA-OMT, and DDGS (C) and verified this result through the sequencing testing (D), obtaining the L6 strain.''']]
  
[[Image:t-links-china-figure1.png|750px|center|'''Figure 1:'''
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<br>
Construction and expression of santalene. (a) Enzymes and some of the reaction intermediates necessary for the production of santalene through the MEP pathway and MVA pathway. (b) Schematic representing the structure of pMVA, pW1_CE, pW1_CEM, pW1_TCEM and pW1_CEM_FL transformed into <i>E.coli</i> DH5α ∆TnaA. ]]
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<b>For the production of shinorine and porphyra-334</b>
  
<br>Afterwards, the various engineering of <i>E.coli</i> DH5α ∆TnaA mentioned above were used for santalene production. After rapid centrifugation, the supernatant of dodecane was spiked with with 0.475 g/L a-humulene as an internal standard, and then injected into GC/MS for verification of α-santalene production. It turned out that all samples from four strains appeared a significant peak at the retention time of 26-27 min, and various peak area of different samples exhibited santalene production with differing levels, indicating the general success of <i>E. coli</i> engineering. It can be concluded that the <i>E. coli</i> strain CEM (with pW1_CEM plasmid) produces the maximal level of α-santalene compared to other strains (73.93 mg/L). Furthermore, our study elucidates that the mutation of 96th amino acid into tryptophan could increase the yield of α-santalene by about 20%, substantiating the prominent performance of ERG20_F96W in enhancing the supply of FPP and α-santalene production in E. coli (Figure 2).  
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The production of shinorine and porphyra-334 as our main experimental goal after S7P is converted to 4DG by DDGS and OMT. Shinorine and porphyra-334 are produced by ATP-grasp ligase (AGL) and D-Ala-D-Ala ligase (ALAL) with two enzymatic steps. First, 4DG is converted to mycosporine-glycine(MG) by conjugating glycine to 4DG under the action of AGL. Then, another amino acid is attached to MG by AGL to produce shinorine or porphyra-334, and L-serine for shinorine and L-threonine for porphyra-334. However, due to the fact that there are variety types of AGL and ALAL with different efficiency and amino acid preference in the enviromnment, we selected ligases from three different marine organisms: Nostoc punctiform(Np5598 and Np5597), Nostoc linckia(NlmysC and NImysD) and Actinosynnema mirum(Am4257 and Am4256, expecting to create nine combinations of AGL-AlaL. For results, we found that NlmysD has a strong selective preference toward the amino acid Threonine. Thus, it will mainly produce porphyra-334 if both Threonine and Serine are present in the environment, marking our first successful case of producing only 334. Np5597, on the other hand, shows shinorine's absorption peak, meaning it has preference toward serine.  
  
[[Image:]t-links-china-figure1.png|thumbnail|750px|center|'''Figure 1:'''
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[[Image:t-links-china-figure52.png|thumb|left|900px|'''Figure 3: Shinorine and porphyra-334 production after optimization. We transformed porphyra-334 producing plasmid Np5598-NlmysD and shinorine producing plasmid Np5598-Np5597 into the L3 and L6 strains (A) and compared the absorption spectrum after 72 hours of fermentation. The absorption peak at 334nm of L7 strains displayed significant improvement compared to L5 strains (B) . From OD334, we concluded that in comparison with the L5 assembly, porphyra-334 production in L6 yeast increased by 91.8%, and shinorine production increased by 70.9% (C).''']]
Quantification analysis of α-santalene production. (a) Measurement santalene production of different strains by GC/MS results. (b) Quantification of α-santalene is analyzed with 0.475 g/L α-humulene as an internal standard. And the GC/MS results demonstrate that the peaks at the retention time of 26-27 min and 28-29 min respectively were α-santalene and α-humulene. (c) GC/MS results of samples originated from CE, CEM, TCEM and CEM-FL strains. ]]
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==Sequence and Features==
 
<partinfo>BBa_K4274000 SequenceAndFeatures</partinfo>
 
  
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===Functional Parameters===
 
<partinfo>BBa_K4274000 parameters</partinfo>
 
 
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<span class='h3bb'>Sequence and Features</span>
==Reference==
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<partinfo>BBa_K4273019 SequenceAndFeatures</partinfo>
[1] Wenlong Z., Tianyue A., Ting L., et al. Reconstruction of the Biosynthetic Pathway of Santalols under Control of the GAL Regulatory System in Yeast. ACS Synth. Biol. 9 (2), 449-456 (2020). https://doi.org/10.1021/acssynbio.9b00479
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<br>[2] Jia Z., Xun W., Xinyi Z., et al. Sesquiterpene Synthase Engineering and Targeted Engineering of α-Santalene Overproduction in Escherichia coli. J. Agric. Food Chem. 70 (17), 5377-5385 (2022). https://doi.org/10.1021/acs.jafc.2c00754
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Revision as of 13:49, 12 October 2022

NOTOC__ pTDH3-DDGS-tTDH1-pPGK1-OMT-tPGK1

Xyl1 is a xylose assimilation gene encoding xylose reductase (XR) that can converts xylose to xylitol. Xyl1 can provides an alternative carbon source for the pentose phosphate pathway that can increase S7P production. We selected Xyl1 genes from Scheffersomyces stipitis that proved to be successfully heterologous expressed for efficiently xylose-fermenting in S. Cerevisiae. We used yeast toolkit (Lee, 2015) to assemble the Level 1 plasmid including the promoter, coding sequence, and terminator. Xyl1 is under the control of promoter pTDH3 which provides a high and stable transcription efficiency (Apel, et. al, 2016). Then, we used PCR amplification to obtain the DNA fragment Xyl1 from Level1 plasmid, and two homology arms (LA and RA) from yeast genome.


Usage and Biology

We selected promoters pTDH3 and pPGK1 due to their stability expression in S. cerevisiae (Apel et. al., 2016). These promoters are shown to have stable and strong expression in YPD culture mediums. pTDH3 has highest stability and strength, followed by pPGK1. Therefore, we used pTDH3 for DDGS and pPGK1 for OMT. By introducing another copy of DDGS-OMT at position Nqm1 and inserting the genes into S. cerevisiae's genome, we were able to increase the production of shinorine and porphyra-334 to a great extent.


Experiment

Characterization
For our experiment, we used the strong promoters such as pTDH3 for DDGS and pPGK1 for OMT when we tried to convert S7P to 4DG efficiently, and selected DDGS(NpR5600) and OMT(NpR5599) for homologous recombination into SC.L2 genome. Moreover, we chosed position 308 from chromosome III (Apel et. al., 2016) for genome recombinant. By using this method, we transformed pCRCT-308 plasmid, the DNA fragments of homologous arms, DDGS, and OMT into SC.L2. The recombinant strains were identified by PCR and sequencing (Fig.4C and D), demonstrating that SC.L3 was obtained in the experiment.

Figure 1: Insertion of DDGS and OMT at 308 position. By transforming CRISPR-308 plasmid pCRCT-308, LA, DDGS, OMT and RA, the two genes should be inserted at 308 position (A). We expanded the homogenous arms, DDGS and OMT genes through PCR and transformed them into L2 strains for it to be assembled in the genome. We performed colony PCR on the yeast colonies to determine the existence of LA-DDGS and OMT (C) and verified this result through the sequencing testing (D), obtaining the L3 strain.



Optimization
To increase the quantity of MAAs production, we further optimized the SC.L3 strains. We notice that Nqm1 has similar functions as TAL1 in shunting S7P into glycolytic pathway. So, to increase the S7P pool, we decided to remove this gene and insert an extra copy of DDGS-OMT simultaneously. The result shows that gene expression can be enhanced by using multiple promoters for increasing MAAs production (Yang et. al., 2018). For modification, pTDH3 was used to express OMT and pPGK1 was used to express DDGS, making the total transcription rate of the two copie roughly equal. Then, we inserted DNA fragments of LA, OMT, DDGS, RA and the pCRCT-Nqm1 plasmid into SC.L3. After PCR, DNA sequencing, and selection of recombinant colonies, we removed the pCRCT-Nqm1 plasmid, obtaining SC.L6 in the end.


Figure 2: Optimizing production by inserting OMT-DDGS and deleting Nqm1 gene. Nqm1 function similarly as TAL1, which reduces S7P concentrations. By transforming CRISPR-Nqm1 plasmid pCRCT-Nqm1, LA, OMT, DDGS, and RA, the two genes should be inserted at Nqm1 position; we switched the promoter of DDGS to pPGK1 and OMT to pTDH3 in order to have equal net transcription rate of DDGS and OMT genes. We expanded the homogenous arms, OMT, DDGS genes through PCR and transformed them into L5 strains for it to be assembled in the genome. We performed colony PCR on the yeast colonies to determine the existence of LA-OMT, and DDGS (C) and verified this result through the sequencing testing (D), obtaining the L6 strain.


For the production of shinorine and porphyra-334

The production of shinorine and porphyra-334 as our main experimental goal after S7P is converted to 4DG by DDGS and OMT. Shinorine and porphyra-334 are produced by ATP-grasp ligase (AGL) and D-Ala-D-Ala ligase (ALAL) with two enzymatic steps. First, 4DG is converted to mycosporine-glycine(MG) by conjugating glycine to 4DG under the action of AGL. Then, another amino acid is attached to MG by AGL to produce shinorine or porphyra-334, and L-serine for shinorine and L-threonine for porphyra-334. However, due to the fact that there are variety types of AGL and ALAL with different efficiency and amino acid preference in the enviromnment, we selected ligases from three different marine organisms: Nostoc punctiform(Np5598 and Np5597), Nostoc linckia(NlmysC and NImysD) and Actinosynnema mirum(Am4257 and Am4256, expecting to create nine combinations of AGL-AlaL. For results, we found that NlmysD has a strong selective preference toward the amino acid Threonine. Thus, it will mainly produce porphyra-334 if both Threonine and Serine are present in the environment, marking our first successful case of producing only 334. Np5597, on the other hand, shows shinorine's absorption peak, meaning it has preference toward serine.

Figure 3: Shinorine and porphyra-334 production after optimization. We transformed porphyra-334 producing plasmid Np5598-NlmysD and shinorine producing plasmid Np5598-Np5597 into the L3 and L6 strains (A) and compared the absorption spectrum after 72 hours of fermentation. The absorption peak at 334nm of L7 strains displayed significant improvement compared to L5 strains (B) . From OD334, we concluded that in comparison with the L5 assembly, porphyra-334 production in L6 yeast increased by 91.8%, and shinorine production increased by 70.9% (C).


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 3423
    Illegal XhoI site found at 2075
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 2321
    Illegal BsaI.rc site found at 3433