Difference between revisions of "Part:BBa K2014010"

(Usage and Biology)
 
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We designed <b>pxylS-E1_5’UTR->sfGFP_W</b> as a fluorescent marker to measure to what extent codon optimization may change the rate of heterologous protein production in <i>E. coli</i>. It is believed that by codon optimization one can substantially increase the gene expression and that the optimized gene will more effectively compete for cell resources and will be more accurately translated  [Kane JK, 1995]. We would like to check which approach to optimize a reading frame is the best and to what extent it can improve the expression of the optimized gene. We consider improvements of such traits like: codon usage, codon adaptation index, contexts of codons and secondary structures in coding sequences. We intentionally started our comparisons from implementing general optimization rules, which effects can be easily compared in simple induced expression experiments.  <br>
 
We designed <b>pxylS-E1_5’UTR->sfGFP_W</b> as a fluorescent marker to measure to what extent codon optimization may change the rate of heterologous protein production in <i>E. coli</i>. It is believed that by codon optimization one can substantially increase the gene expression and that the optimized gene will more effectively compete for cell resources and will be more accurately translated  [Kane JK, 1995]. We would like to check which approach to optimize a reading frame is the best and to what extent it can improve the expression of the optimized gene. We consider improvements of such traits like: codon usage, codon adaptation index, contexts of codons and secondary structures in coding sequences. We intentionally started our comparisons from implementing general optimization rules, which effects can be easily compared in simple induced expression experiments.  <br>
We have started from a simple optimization of sfGFP in which we changed every codon of sfGFP [Pedelacq JD, 2006] to the rarest synonymous codon in all reading frames of <i>E. coli</i> K12 orfeome, according to the codon usage table generated for us by Prof. W. Karłowski. At the N-terminus of coding sequence there is a stable 6-histidine tag (<b>Fig. 1</b>). The reporter gene is cloned under a strong xylose induced promoter - pxylS-E1_5’UTR, which is shorter and has exchanged the native downstream 5’UTR comparing to the wild-type pxylF-xylA from <i> E. coli </i>. Thus, in sfGFP-W coding sequence appeared 7 dispersed AGG codons, 10 isoleucine ATA codons, 15 leucine CTA codons, and two pairs of consecutive CTA codons (these codons represent 40% of all codons in coding sequence). While designing the ORF the priority was to select the rarest codons. As a result, even though it does not meet the iGEM requirements, due to having a restriction site, we decided not to change the sequence. At the N-terminus of coding sequence there is a stable 6-histidine tag (<b>Fig. 1.</b>). The reporter gene is cloned under arabinose promoter (AraC-pBAD) a wild-type <i>E. coli </i>promoter that is tightly controlled by L-arabinose and is used in pBAD expression vectors (Invitrogen, Thermo-Fischer).
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We have started from a simple optimization of sfGFP in which we changed every codon of sfGFP [Pedelacq JD, 2006] to the least frequent synonymous codon in all reading frames of <i>E. coli</i> K12 orfeome, according to the codon usage table generated for us by Prof. W. Karłowski. Thus, in sfGFP-W coding sequence appeared 7 dispersed AGG codons, 10 isoleucine ATA codons, 15 leucine CTA codons, and two pairs of consecutive CTA codons (these codons represent 40% of all codons in coding sequence). While designing the ORF the priority was to select the rarest codons. As a result, even though it does not meet the iGEM requirements, due to having a restriction site, we decided not to change the sequence. At the N-terminus of coding sequence there is a stable 6-histidine tag (<b>Fig. 1.</b>). The reporter gene is cloned under a strong xylose induced promoter - pxylS-E1_5’UTR, which is shorter and has exchanged the native downstream 5’UTR comparing to the wild-type pxylF-xylA from <i> E. coli </i>.
 
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{|align="center"
 
{|align="center"
 
  |-valign="top"
 
  |-valign="top"
  | colspan = 2 | [[Image:BBa K2014010-1.png|thumb|650px|center|<font size="2"><b>Fig. 1. </b>The scheme of the biobrick <b>BBa_K2014010</b>. W letters correspond to the rarest codons in <i>E.coli</i> K-12 orfeome.</font>]]
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  | colspan = 2 | [[Image:BBa K2014010-1.png|thumb|650px|center|<font size="2"><b>Fig. 1. </b>The scheme of the biobrick <b>BBa_K2014010</b>. W letters correspond to the rarest codons in <i>E. coli</i> <br>K-12 orfeome.</font>]]
 
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We have compared the translational efficiency of sfGFP_W ORF with its non-optimized ORF (<b>BBa_K2014002</b>) and optimized form – sfGFP_B (<b>BBa_K2014009</b>) by measuring the fluorescence intensity of sfGFPs encoded by three different ORFs, which are under control of an identical promoter with an identical 5’UTR.  Shortly, we compared the expression of sfGFP from three biobricks: <b>BBa_K2014002</b>, <b>BBaK2014009</b>, and <b>BBa_K2014010</b> in <i>E. coli </i> DH5α cells grown in two rich media, <b>LB and SB-PKB and in M9 minimal medium </b>upon induction with xylose (0,4% final concentration).
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We have compared the translational efficiency of sfGFP_W ORF with its non-optimized ORF (<b>[https://parts.igem.org/Part:BBa_K2014002 BBa_K2014002]</b>) and optimized form – sfGFP_B (<b>[https://parts.igem.org/Part:BBa_K2014009 BBa_K2014009]</b>) by measuring the fluorescence intensity of sfGFPs encoded by three different ORFs, which are under control of an identical promoter with an identical 5’UTR.  Shortly, we compared the expression of sfGFP from three biobricks: <b>BBa_K2014002</b>, <b>BBaK2014009</b>, and <b>BBa_K2014010</b> in <i>E. coli </i> DH5α cells grown in two rich media, <b>LB and SB-PKB and in M9 minimal medium </b>upon induction with xylose (0,4% final concentration).
  
  
 
{|align="center"
 
{|align="center"
 
  |-valign="top"
 
  |-valign="top"
  | colspan = 2 | [[Image:BBa K2014009-2.png|thumb|600px|center|<font size="2"><b>Fig. 2.</b> Comparison of three different variants of sfGFP ORFs during 6h culture of <i>E.coli </i> DH5α in the rich medium – <b>SB/PKB</b> and <b>LB</b>upon induction with D-xylose (0h) (0,4% final concentration).  </font>]]
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  | colspan = 2 | [[Image:BBa K2014009-2.png|thumb|600px|center|<font size="2"><b>Fig. 2.</b> Comparison of three different variants of sfGFP ORFs during 6h culture of <i>E. coli </i> DH5α in the rich medium – <b>SB/PKB</b> and <b>LB</b> upon induction with D-xylose (0h) (0,4% final concentration).  </font>]]
 
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{|align="center"
 
{|align="center"
 
  |-valign="top"
 
  |-valign="top"
  | colspan = 2 | [[Image:BBa K2014009-3.png|thumb|600px|center|<font size="2"><b>Fig. 3.</b> Comparison of three different variants of sfGFP ORFs during 6h culture of <i>E.coli</i> DH5α in <b>M9 minimal medium</b> upon induction with D-xylose (0h) (0,4% final concentration). Protein expression was induced at OD<sub>600</sub>= 0,8.</font>]]
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  | colspan = 2 | [[Image:BBa K2014009-3.png|thumb|600px|center|<font size="2"><b>Fig. 3.</b> Comparison of three different variants of sfGFP ORFs during 6h culture of <i>E. coli</i> DH5α in <b>M9 minimal medium</b> upon induction with D-xylose (0h) (0,4% final concentration). Protein expression was induced at OD<sub>600</sub>= 0,8.</font>]]
 
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Latest revision as of 23:59, 21 October 2016

pxylS-E1_5'UTR->sfGFP_W


Usage and Biology

We designed pxylS-E1_5’UTR->sfGFP_W as a fluorescent marker to measure to what extent codon optimization may change the rate of heterologous protein production in E. coli. It is believed that by codon optimization one can substantially increase the gene expression and that the optimized gene will more effectively compete for cell resources and will be more accurately translated [Kane JK, 1995]. We would like to check which approach to optimize a reading frame is the best and to what extent it can improve the expression of the optimized gene. We consider improvements of such traits like: codon usage, codon adaptation index, contexts of codons and secondary structures in coding sequences. We intentionally started our comparisons from implementing general optimization rules, which effects can be easily compared in simple induced expression experiments.
We have started from a simple optimization of sfGFP in which we changed every codon of sfGFP [Pedelacq JD, 2006] to the least frequent synonymous codon in all reading frames of E. coli K12 orfeome, according to the codon usage table generated for us by Prof. W. Karłowski. Thus, in sfGFP-W coding sequence appeared 7 dispersed AGG codons, 10 isoleucine ATA codons, 15 leucine CTA codons, and two pairs of consecutive CTA codons (these codons represent 40% of all codons in coding sequence). While designing the ORF the priority was to select the rarest codons. As a result, even though it does not meet the iGEM requirements, due to having a restriction site, we decided not to change the sequence. At the N-terminus of coding sequence there is a stable 6-histidine tag (Fig. 1.). The reporter gene is cloned under a strong xylose induced promoter - pxylS-E1_5’UTR, which is shorter and has exchanged the native downstream 5’UTR comparing to the wild-type pxylF-xylA from E. coli .

Fig. 1. The scheme of the biobrick BBa_K2014010. W letters correspond to the rarest codons in E. coli
K-12 orfeome.


We have compared the translational efficiency of sfGFP_W ORF with its non-optimized ORF (BBa_K2014002) and optimized form – sfGFP_B (BBa_K2014009) by measuring the fluorescence intensity of sfGFPs encoded by three different ORFs, which are under control of an identical promoter with an identical 5’UTR. Shortly, we compared the expression of sfGFP from three biobricks: BBa_K2014002, BBaK2014009, and BBa_K2014010 in E. coli DH5α cells grown in two rich media, LB and SB-PKB and in M9 minimal medium upon induction with xylose (0,4% final concentration).


Fig. 2. Comparison of three different variants of sfGFP ORFs during 6h culture of E. coli DH5α in the rich medium – SB/PKB and LB upon induction with D-xylose (0h) (0,4% final concentration).


Our results (Fig. 2.) indicate that in E. coli cells growing in rich media the difference in translation rate between reading frames composed of the most common and the rarest codons increases with the promoter strength.


Fig. 3. Comparison of three different variants of sfGFP ORFs during 6h culture of E. coli DH5α in M9 minimal medium upon induction with D-xylose (0h) (0,4% final concentration). Protein expression was induced at OD600= 0,8.


In M9 minimal medium the codon optimization based on codon usage seems to be more important than in rich media. It is likely that in E. coli cells grown in minimal media tRNA pool and translational apparatus cannot be efficiently adjusted to translate mRNA molecules with reading frames composed of rare codons.




Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal SpeI site found at 203
    Illegal SpeI site found at 338
    Illegal SpeI site found at 515
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal SpeI site found at 203
    Illegal SpeI site found at 338
    Illegal SpeI site found at 515
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal SpeI site found at 203
    Illegal SpeI site found at 338
    Illegal SpeI site found at 515
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal SpeI site found at 203
    Illegal SpeI site found at 338
    Illegal SpeI site found at 515
  • 1000
    COMPATIBLE WITH RFC[1000]