Difference between revisions of "Part:BBa K3904401"
 
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__NOTOC__
 
__NOTOC__
  
 
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<partinfo>BBa_K3904401 short</partinfo>
  
  
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[[File:T--Vilnius-Lithuania--amebyeLogo dark.png|right|100px|AmeBye]]
 
[[File:T--Vilnius-Lithuania--amebyeLogo dark.png|right|100px|AmeBye]]
  
Vilnius-Lithuania iGEM 2021 project [https://2021.igem.org/Team:Vilnius-Lithuania <b>AmeBye</b>]looks at amebiasis holistically and comprehensively, therefor target <i>E. histolytica</i> from several angles: prevention and diagnostics. As a tool to prevent amebiasis, the team created probiotics capable of naringenin biosynthesis. For the diagnostic part, the project includes a rapid, point of care, user-friendly diagnostic test identifying extraintestinal amebiasis. The main components of this test are aptamers, specific to the <i>E. histolytica</i> secreted proteins. These single-stranded DNA sequences fold into tertiary structures for particular fit with target proteins.
+
Vilnius-Lithuania iGEM 2021 project [https://2021.igem.org/Team:Vilnius-Lithuania <b>AmeBye</b>]looks at amebiasis holistically and comprehensively, therefore target <i>E. histolytica</i> from several angles: prevention and diagnostics. Our team's preventive solution consists of probiotics engineered to produce naringenin - an antiprotozoal compound. Two strains of genetically modified microorganisms were chosen as the main chassis - world-renowned <i>Lactobacillus casei</i> BL23 (<i>Lactobacillus paracasei</i>) and <i>Escherichia coli</i>  Nissle 1917. Furthermore, the team made specific gene deletions to enhance naringenin production and adapted a novel toxin-antitoxin system to prevent GMO spreads into the environment. The diagnostic part includes a rapid, point of care, user-friendly diagnostic test identifying extraintestinal amebiasis. The main components of this test are aptamers specific to the <i>E. histolytica</i> secreted proteins. These single-stranded DNA sequences fold into tertiary structures for particular fit with target proteins.
  
 
__TOC__
 
__TOC__
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=Usage and Biology=
 
=Usage and Biology=
  
CRISPR-Cas9 is a versatile genome-editing technique. In our approach to editing <i>E. coli</i> Nissle 1917 genome, we have used two plasmid based system enabling to combine of Lambda Red recombination and CRISPR-Cas9 as counterselection tools - [https://www.addgene.org/62225/ pCas]) and [https://www.addgene.org/62226/ pTarget]).  
+
CRISPR-Cas9 is a versatile genome-editing technique. In our approach to editing <i>E. coli</i> Nissle 1917 genome, we have used two plasmid based system enabling to combine of Lambda Red recombination and CRISPR-Cas9 as counterselection tools encoded in [https://www.addgene.org/62225/ pCas] and [https://www.addgene.org/62226/ pTarget].  
  
 
==Mechanism of genome editing==
 
==Mechanism of genome editing==
  
pCas plasmid is used for Cas9, Lambda Red system expression, and plasmid curing of pTarget. Cas9 - the RNA-guided endonuclease - is expressed constitutively, while the expression of Lambda Red genes (Gam, Exo, Beta) is under the control of arabinose inducible promoter araBp. pTarget plasmid caries constitutively expressed single-guide RNA (sgRNA). This RNA molecule, as and in nature, is composed of two central parts: CRISPR RNA (crRNA) and tracrRNA. crRNA is 17-20 nt length RNA sequence complementary to the targeted DNA adjacent to the protospacer adjacent motif (PAM) and tracrRNA is the scaffold for the Cas (in this case Cas9) nuclease binding to guide RNA and forming the ribonucleoprotein complex (1). In nature those two parts exist as two separate RNA molecules, however, in laboratory experiments they are usually combined into one single-guide RNA (sgRNA). As both pCas and pTarget plasmids are in a cell, Cas9 nuclease and sgRNA are able to form ribonucleoprotein complex and perform a double-strand break in the chosen part of the DNA. However, if arabinose has been added to the cell culture and a double-stranded DNA repair template is present in the cell, the Lambda Red system performs homologous recombination. If this process is unsuccessful, the Cas9-sgRNA complex will cause a double-strand break and will cause cell death (2). This is employed as a counterselection in order to avoid the additional antibiotic as selection marker usage.
 
  
==<i>ackA</i> gene knockout==
+
[[File:T--Vilnius-Lithuania--crisprcas92.png|right|500px|CRISPRCas9]]
 +
 
 +
pCas plasmid is used for Cas9, Lambda Red system expression, and plasmid curing of pTarget. Cas9 - the RNA-guided endonuclease - is expressed constitutively, while the expression of Lambda Red genes (Gam, Exo, Beta) is under the control of arabinose inducible promoter araBp. pTarget plasmid caries constitutively expressed single-guide RNA (sgRNA). This RNA molecule, as and in nature, is composed of 17-20 nt length guide RNA (gRNA) sequence complementary to the targeted DNA adjacent to the protospacer adjacent motif (PAM) present at the 3' end, and the scaffold for the Cas9 nuclease binding to sgRNA and forming the ribonucleoprotein complex (1). Although in nature sgRNA exists as two separate RNA molecules, in laboratory experiments they are usually combined into one single-guide RNA (sgRNA) obviating additional maturation steps. As both pCas and pTarget plasmids are in a cell, Cas9 nuclease and sgRNA are able to form ribonucleoprotein complex, scan DNA for PAM sequences and perform a double-strand break in a part of the DNA which is complementary to the gRNA and adjacent to the PAM sequence - NGG. However, if arabinose has been added to the cell culture and a double-stranded DNA repair template is present in the cell, the Lambda Red system performs homology directed repair (HDR). If this process is unsuccessful, the Cas9-sgRNA complex will cause a double-strand break and will cause cell death (2). This is employed as a counter selection in order to avoid the additional antibiotic as selection marker usage.
 +
 
 +
 
 +
 
 +
<b>Table 1.</b> sgRNA collection for <i>E. coli</i> Nissle 1917 genome editing.
 +
 
 +
{| class="wikitable"
 +
|-
 +
|<b>Short description</b>
 +
|<b>Part number</b>
 +
|-
 +
|ackA-specific sgRNA
 +
|[https://parts.igem.org/Part:BBa_K3904401 BBa_K3904401]
 +
|-
 +
||pta-specific sgRNA
 +
|[https://parts.igem.org/Part:BBa_K3904402 BBa_K3904402]
 +
|-
 +
|colicin-specific sgRNA
 +
|[https://parts.igem.org/Part:BBa_K3904405 BBa_K3904405]
 +
|-
 +
|nupG-specific sgRNA
 +
|[https://parts.igem.org/Part:BBa_K3904426 BBa_K3904426]
 +
|}
 +
 
 +
 
 +
 
 +
<b>Table 2.</b> Parts collection for <i>ackA</i> knockout generation in <i>E. Coli</i> Nissle 1917.
 +
 
 +
{| class="wikitable"
 +
|-
 +
|<b>Short description</b>
 +
|<b>Part number</b>
 +
|-
 +
|ackA-specific sgRNA
 +
|[https://parts.igem.org/Part:BBa_K3904401 BBa_K3904401]
 +
|-
 +
|Recombination template for <i>ackA</i> knockout
 +
|[https://parts.igem.org/Part:BBa_K3904406 BBa_K3904406]
 +
|-
 +
|Forward <i>ackA</i> primer for homology template amplification
 +
|[https://parts.igem.org/Part:BBa_K3904412 BBa_K3904412]
 +
|-
 +
|Reverse <i>ackA</i> primer for homology template amplification
 +
|[https://parts.igem.org/Part:BBa_K3904413 BBa_K3904413]
 +
|}
 +
 
 +
 
 +
 
 +
==<i>ackA</i> gene knockout importance to AmeBye project==
 +
 
 +
This RNA sequence is designed to target acetate kinase (ackA) gene <i>ackA</i>. <i>ackA</i> is one of the ackA-pta operon and disruption of this genomic region is known to limit the acetate formation from acetyl-CoA, increasing the cellular concentration of acetyl-CoA up to 16% (3). Increased concentration of this molecule theoretically should result in enhanced malonyl-CoA formation and consequently more effective naringenin synthesis since the amount of malonyl-CoA available in the cell is the limiting step of naringenin production (4).
 +
 
 +
 
 +
 
 +
==Genome editing efficiency==
  
This 20 nt lenght RNA sequence is designed to target acetate kinase (ackA) gene. <i>ackA</i> gene is one of the ackA-pta operon and disruption of this genomic region is known to limit the acetate formation from acetyl-CoA, increasing the cellular concentration of acetyl-CoA up to 16% (3). Increased concentration of this molecule theoretically should result in enhanced malonyl-CoA formation and consequently more effective naringenin synthesis since the amount of malonyl-CoA available in the cell is the limiting step of naringenin production (4).
+
<i>ackA</i> knockout generation with this sgRNA have achieved 100 % efficiency (fig. 1).
  
=Importance to AmeBye project=
+
[[File:T--Vilnius-Lithuania--ackA-knockout.png|left|450px]]
 +
<b>Fig. 1.</b> Restriction of cPCR product representing ackA knockout generation. Colony PCR product is 300 bp long and restriction by BcuI generates two separate fragments -  131 bp and 108 bp, which in this gel are seen as one line. L - GeneRuler 1 kbp DNA Ladder, 1 - <i>ackA</i> knockout (1), 2 - <i>ackA</i> knockout (2), 3 - <i>ackA</i> knockout (3), 4 - <i>ackA</i> knockout (4), 5 - <i>ackA</i> knockout (5), 6 - <i>ackA</i> knockout (6), 7 - <i>ackA</i> knockout (7), 8 - <i>ackA</i> knockout (8), 9 - <i>ackA</i> knockout (9), 10 - <i>ackA</i> knockout (10), 11 - <i>ackA</i> knockout (11), 12 - <i>ackA</i> knockout (12), 13 - <i>ackA</i> knockout (13), 14 - <i>ackA</i> knockout (14), 15 - negative control (wild type <i>E. coli</i> Nissle 1917).
  
Increased concentration of this molecule theoretically should result in enhanced malonyl-CoA formation and consequently more effective naringenin synthesis since the amount of malonyl-CoA available in the cell is the limiting step of naringenin production (5).
 
  
 
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  <ol>
 
  <ol>
 
   <li>Doudna, J. A., & Charpentier, E. (2014). The new frontier of genome engineering with CRISPR-Cas9. Science, 346(6213).</li>
 
   <li>Doudna, J. A., & Charpentier, E. (2014). The new frontier of genome engineering with CRISPR-Cas9. Science, 346(6213).</li>
   <li>Jiang, Y., Chen, B., Duan, C., Sun, B., Yang, J., & Yang, S. (2015). Multigene editing in the Escherichia coli genome via the CRISPR-Cas9 system. Applied and environmental microbiology, 81(7), 2506-2514.
+
   <li>Jiang, Y., Chen, B., Duan, C., Sun, B., Yang, J., & Yang, S. (2015). Multigene editing in the Escherichia coli genome via the CRISPR-Cas9 system. Applied and environmental microbiology, 81(7), 2506-2514.</li>
  </li>
+
 
   <li>Ku, J. T., Chen, A. Y., & Lan, E. I. (2020). Metabolic engineering design strategies for increasing acetyl-CoA flux. Metabolites, 10(4), 166.</li>
 
   <li>Ku, J. T., Chen, A. Y., & Lan, E. I. (2020). Metabolic engineering design strategies for increasing acetyl-CoA flux. Metabolites, 10(4), 166.</li>
 
   <li>Wu, J., Du, G., Chen, J., & Zhou, J. (2015). Enhancing flavonoid production by systematically tuning the central metabolic pathways based on a CRISPR interference system in Escherichia coli. Scientific reports, 5(1), 1-14.</li>
 
   <li>Wu, J., Du, G., Chen, J., & Zhou, J. (2015). Enhancing flavonoid production by systematically tuning the central metabolic pathways based on a CRISPR interference system in Escherichia coli. Scientific reports, 5(1), 1-14.</li>

Latest revision as of 01:09, 22 October 2021


ackA-specific sgRNA


Introduction

AmeBye

Vilnius-Lithuania iGEM 2021 project AmeByelooks at amebiasis holistically and comprehensively, therefore target E. histolytica from several angles: prevention and diagnostics. Our team's preventive solution consists of probiotics engineered to produce naringenin - an antiprotozoal compound. Two strains of genetically modified microorganisms were chosen as the main chassis - world-renowned Lactobacillus casei BL23 (Lactobacillus paracasei) and Escherichia coli Nissle 1917. Furthermore, the team made specific gene deletions to enhance naringenin production and adapted a novel toxin-antitoxin system to prevent GMO spreads into the environment. The diagnostic part includes a rapid, point of care, user-friendly diagnostic test identifying extraintestinal amebiasis. The main components of this test are aptamers specific to the E. histolytica secreted proteins. These single-stranded DNA sequences fold into tertiary structures for particular fit with target proteins.

Usage and Biology

CRISPR-Cas9 is a versatile genome-editing technique. In our approach to editing E. coli Nissle 1917 genome, we have used two plasmid based system enabling to combine of Lambda Red recombination and CRISPR-Cas9 as counterselection tools encoded in pCas and pTarget.

Mechanism of genome editing

CRISPRCas9

pCas plasmid is used for Cas9, Lambda Red system expression, and plasmid curing of pTarget. Cas9 - the RNA-guided endonuclease - is expressed constitutively, while the expression of Lambda Red genes (Gam, Exo, Beta) is under the control of arabinose inducible promoter araBp. pTarget plasmid caries constitutively expressed single-guide RNA (sgRNA). This RNA molecule, as and in nature, is composed of 17-20 nt length guide RNA (gRNA) sequence complementary to the targeted DNA adjacent to the protospacer adjacent motif (PAM) present at the 3' end, and the scaffold for the Cas9 nuclease binding to sgRNA and forming the ribonucleoprotein complex (1). Although in nature sgRNA exists as two separate RNA molecules, in laboratory experiments they are usually combined into one single-guide RNA (sgRNA) obviating additional maturation steps. As both pCas and pTarget plasmids are in a cell, Cas9 nuclease and sgRNA are able to form ribonucleoprotein complex, scan DNA for PAM sequences and perform a double-strand break in a part of the DNA which is complementary to the gRNA and adjacent to the PAM sequence - NGG. However, if arabinose has been added to the cell culture and a double-stranded DNA repair template is present in the cell, the Lambda Red system performs homology directed repair (HDR). If this process is unsuccessful, the Cas9-sgRNA complex will cause a double-strand break and will cause cell death (2). This is employed as a counter selection in order to avoid the additional antibiotic as selection marker usage.


Table 1. sgRNA collection for E. coli Nissle 1917 genome editing.

Short description Part number
ackA-specific sgRNA BBa_K3904401
pta-specific sgRNA BBa_K3904402
colicin-specific sgRNA BBa_K3904405
nupG-specific sgRNA BBa_K3904426


Table 2. Parts collection for ackA knockout generation in E. Coli Nissle 1917.

Short description Part number
ackA-specific sgRNA BBa_K3904401
Recombination template for ackA knockout BBa_K3904406
Forward ackA primer for homology template amplification BBa_K3904412
Reverse ackA primer for homology template amplification BBa_K3904413


ackA gene knockout importance to AmeBye project

This RNA sequence is designed to target acetate kinase (ackA) gene ackA. ackA is one of the ackA-pta operon and disruption of this genomic region is known to limit the acetate formation from acetyl-CoA, increasing the cellular concentration of acetyl-CoA up to 16% (3). Increased concentration of this molecule theoretically should result in enhanced malonyl-CoA formation and consequently more effective naringenin synthesis since the amount of malonyl-CoA available in the cell is the limiting step of naringenin production (4).


Genome editing efficiency

ackA knockout generation with this sgRNA have achieved 100 % efficiency (fig. 1).

T--Vilnius-Lithuania--ackA-knockout.png

Fig. 1. Restriction of cPCR product representing ackA knockout generation. Colony PCR product is 300 bp long and restriction by BcuI generates two separate fragments - 131 bp and 108 bp, which in this gel are seen as one line. L - GeneRuler 1 kbp DNA Ladder, 1 - ackA knockout (1), 2 - ackA knockout (2), 3 - ackA knockout (3), 4 - ackA knockout (4), 5 - ackA knockout (5), 6 - ackA knockout (6), 7 - ackA knockout (7), 8 - ackA knockout (8), 9 - ackA knockout (9), 10 - ackA knockout (10), 11 - ackA knockout (11), 12 - ackA knockout (12), 13 - ackA knockout (13), 14 - ackA knockout (14), 15 - negative control (wild type E. coli Nissle 1917).


Sequence and Features


Assembly Compatibility:
  • 10
    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]


References

  1. Doudna, J. A., & Charpentier, E. (2014). The new frontier of genome engineering with CRISPR-Cas9. Science, 346(6213).
  2. Jiang, Y., Chen, B., Duan, C., Sun, B., Yang, J., & Yang, S. (2015). Multigene editing in the Escherichia coli genome via the CRISPR-Cas9 system. Applied and environmental microbiology, 81(7), 2506-2514.
  3. Ku, J. T., Chen, A. Y., & Lan, E. I. (2020). Metabolic engineering design strategies for increasing acetyl-CoA flux. Metabolites, 10(4), 166.
  4. Wu, J., Du, G., Chen, J., & Zhou, J. (2015). Enhancing flavonoid production by systematically tuning the central metabolic pathways based on a CRISPR interference system in Escherichia coli. Scientific reports, 5(1), 1-14.