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| | <p class="figure subtitle"><b>Figure 1: UBP conservation system using Cas9.</b><br> sgRNAs are targeted against every possible DNA sequence that had lost the UBP, which was incorporated on a plasmid. A: The UBP gets lost, which leads to a point mutation. One of the sgRNAs can bind to the DNA target sequence. Cas9 is recruited and cleaves the plasmid, which is followed by its degradation. B: Plasmids that contain a UBP in the DNA target sequence lead to a mismatch with every sgRNA. Cas9 does not cleave the plasmid, leading to a retention of the UBP.</p> | | <p class="figure subtitle"><b>Figure 1: UBP conservation system using Cas9.</b><br> sgRNAs are targeted against every possible DNA sequence that had lost the UBP, which was incorporated on a plasmid. A: The UBP gets lost, which leads to a point mutation. One of the sgRNAs can bind to the DNA target sequence. Cas9 is recruited and cleaves the plasmid, which is followed by its degradation. B: Plasmids that contain a UBP in the DNA target sequence lead to a mismatch with every sgRNA. Cas9 does not cleave the plasmid, leading to a retention of the UBP.</p> |
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| − | For this conservation system, we integrated the <i>cas9</i> gene into the genome of <i>E. coli</i> BL21(DE3). This new strain is called X1. To be able to strictly regulate the expression of <i>cas9</i> we used the optimized IPTG-inducible promoter <i>P<sub>lac-tight</sub></i>. The genomic knock in was done according to the protocol by Cobb et al., 2014 using the pCRISPomyces plasmid system. A sgRNA was designed searching for a reverse sequence with the constraint N(16)R(4)NGG (Cobb et al., 2004) inside the coding sequence of the arsB gene (Zhang et al., 2017) of the <i>E. coli</i> genome. <i>arsB</i> is coding for an arsenic efflux pump membrane protein. As a result, 5‘‑TATTGTTCATAATAGAAGAGAGG ‑ 3‘ turned out to be the suggested guiding sequence with the highest on-target activity score with being unique within the complete genome. Furthermore, a repair template is necessary for the knock in. Therefore, a composite BioBrick was assembled using 1 kb long flanking sequences, two times the terminator BBa_B0015 flanking the <i>P<sub>lac-tight</sub></i> and the <i>cas9</i> coding sequence (Figure 2). | + | For this conservation system, we integrated the <i>cas9</i> gene into the genome of <i>E. coli</i> BL21(DE3). This new strain is called X1. To be able to strictly regulate the expression of <i>cas9</i> we used the optimized IPTG-inducible promoter <i>P<sub>lac-tight</sub></i>. The genomic knock in was done according to the protocol by Cobb et al., 2014 using the pCRISPomyces plasmid system. A sgRNA was designed searching for a reverse sequence with the constraint N(16)R(4)NGG (Cobb et al., 2004) inside the coding sequence of the arsB gene (Zhang et al., 2017) of the <i>E. coli</i> genome. <i>arsB</i> is coding for an arsenic efflux pump membrane protein. As a result, 5‘‑TATTGTTCATAATAGAAGAGAGG‑3‘ turned out to be the suggested guiding sequence with the highest on-target activity score with being unique within the complete genome. Furthermore, a repair template is necessary for the knock in. Therefore, a composite BioBrick was assembled using 1 kb long flanking sequences, two times the terminator BBa_B0015 flanking the <i>P<sub>lac-tight</sub></i> and the <i>cas9</i> coding sequence (Figure 2). |
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| − | We designed a <i>lac</i> operon for a tight repression called <i>P<sub>lac-tight</sub></i> to achieve a low transcription rate. The induction of the wild type lac operon increases the level of β ‑ galactosidase 1000-fold (Müller et al., 1996). As part of the <i>lac</i> operon the <i>lac</i> repressor was the first repressor isolated and sequenced in 1966 by Gilbert and Müller-Hill. The wild type <i>lac</i> operon consists of the genes <i>lacZ</i>, <i>lacY</i> and <i>lacA</i> that are transcribed from the lac promoter <i>P<sub>lac</sub></i> into a polycistronic mRNA (Figure 4). These genes code for the proteins β ‑ galactosidase, Lac permease and Lac transacetylase (Oehler et al., 1994). | + | We designed a <i>lac</i> operon for a tight repression called <i>P<sub>lac-tight</sub></i> to achieve a low transcription rate. The induction of the wild type lac operon increases the level of β‑galactosidase 1000-fold (Müller et al., 1996). As part of the <i>lac</i> operon the <i>lac</i> repressor was the first repressor isolated and sequenced in 1966 by Gilbert and Müller-Hill. The wild type <i>lac</i> operon consists of the genes <i>lacZ</i>, <i>lacY</i> and <i>lacA</i> that are transcribed from the lac promoter <i>P<sub>lac</sub></i> into a polycistronic mRNA (Figure 4). These genes code for the proteins β‑galactosidase, Lac permease and Lac transacetylase (Oehler et al., 1994). |
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| | <div class="figure medium"> | | <div class="figure medium"> |
| | <img class="figure image" src="https://static.igem.org/mediawiki/2017/c/c5/T--Bielefeld-CeBiTec--Oid_o1_bp_distance.png"> | | <img class="figure image" src="https://static.igem.org/mediawiki/2017/c/c5/T--Bielefeld-CeBiTec--Oid_o1_bp_distance.png"> |
| − | <p class="figure subtitle"><b>Figure 6: Repression values dependent on inter-operator distances between O1 and O<sub>id</sub>.</b><br>The repression values refer to the repression of the chromosomal <i>lacZ</i> gene under the control of O1 at its natural positon and O<sub>id</sub> at the indicated position. With 50 tetrameric Lac repressors per cell the repression value is calculated by the specific activity of β ‑galactosidase in absence of active Lac repressor devided by the specific activity of β ‑galactosidase in the presence of active Lac repressor. The dashed line shows the repression value for a single natural O1 operator (Mueller et al., 1996).</p> | + | <p class="figure subtitle"><b>Figure 6: Repression values dependent on inter-operator distances between O1 and O<sub>id</sub>.</b><br>The repression values refer to the repression of the chromosomal <i>lacZ</i> gene under the control of O1 at its natural positon and O<sub>id</sub> at the indicated position. With 50 tetrameric Lac repressors per cell the repression value is calculated by the specific activity of β‑galactosidase in absence of active Lac repressor devided by the specific activity of β‑galactosidase in the presence of active Lac repressor. The dashed line shows the repression value for a single natural O1 operator (Mueller et al., 1996).</p> |
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