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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 <i>et al</i>., 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 <i>et al</i>., 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 <i>lac</i> operon increases the level of β‑galactosidase 1000‑fold (Müller <i>et al</i>., 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 <i>et al</i>., 1994). |
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| − | The transcription is constitutively activated by the CAP protein. <i>lacI</i> codes for the tetrameric Lac repressor and is expressed by the promoter <i>P<sub>i</sub></i>. The Lac repressor can bind to the lac operators O1, O2 or O3. O3 is located 92 bp upstream of O1 and O2 401 bp downstream of O1. The inter‑operator distances are counted from the center of O1 to the center of the distal operator. By binding simultaniously to O1 and O2 or to O1 and O3, the Lac repressor forms a DNA loop that negatively controlls the expression of <i>P<sub>lac</sub></i> (Oehler <i>et al</i>., 1994). | + | The transcription is constitutively activated by the CAP protein. <i>lacI</i> codes for the tetrameric Lac repressor and is expressed by the promoter <i>P<sub>i</sub></i>. The Lac repressor can bind to the <i>lac</i> operators O1, O2 or O3. O3 is located 92 bp upstream of O1 and O2 401 bp downstream of O1. The inter‑operator distances are counted from the center of O1 to the center of the distal operator. By binding simultaniously to O1 and O2 or to O1 and O3, the Lac repressor forms a DNA loop that negatively controlls the expression of <i>P<sub>lac</sub></i> (Oehler <i>et al</i>., 1994). |
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| | <img class="figure image" src="https://static.igem.org/mediawiki/2017/f/fd/T--Bielefeld-CeBiTec--DNA_fold_Lac-repressor.png"> | | <img class="figure image" src="https://static.igem.org/mediawiki/2017/f/fd/T--Bielefeld-CeBiTec--DNA_fold_Lac-repressor.png"> |
| − | <p class="figure subtitle"><b>Figure 4: The wild type lac operators.</b><br>The tetrameric Lac repressor can bind either the lac operators O1 and O3 or O1 and O2 to form a DNA loop. The DNA loops efficiently inhibit the transcription by the CAP protein (Oehler <i>et al</i>., 1994).</p> | + | <p class="figure subtitle"><b>Figure 4: The wild type <i>lac</i> operators.</b><br>The tetrameric Lac repressor can bind either the <i>lac</i> operators O1 and O3 or O1 and O2 to form a DNA loop. The DNA loops efficiently inhibit the transcription by the CAP protein (Oehler <i>et al</i>., 1994).</p> |
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| − | In 1994, Oehler <i>et al</i>. showed that an inactivated O2 in its natural position does not decrease the repression by low amounts of tetrameric Lac repressor. Based on this result, we designed our <i>P<sub>lac-tight</sub></i> without the lac operator O2. It was also shown that two weak operators result in a tighter repression than a single strong operator. This can be explained by the thermodynamic concept that a second operator increases the local concentration of the Lac repressor for the neighboring operator. As a consequence there is a higher probability of occupation for two operators by the Lac repressor leading to a tighter repression (Oehler <i>et al</i>., 1996). In 1983, Sadler <i>et al</i>. proposed a ideal lac operator O<sub>id</sub> that binds the Lac repressor 10‑fold tighter than the natural strong lac operator O1. O<sub>id</sub> is a inverted repeat of the left half of O1 (Figure 5). | + | In 1994, Oehler <i>et al</i>. showed that an inactivated O2 in its natural position does not decrease the repression by low amounts of tetrameric Lac repressor. Based on this result, we designed our <i>P<sub>lac-tight</sub></i> without the <i>lac</i> operator O2. It was also shown that two weak operators result in a tighter repression than a single strong operator. This can be explained by the thermodynamic concept that a second operator increases the local concentration of the Lac repressor for the neighboring operator. As a consequence there is a higher probability of occupation for two operators by the Lac repressor leading to a tighter repression (Oehler <i>et al</i>., 1996). In 1983, Sadler <i>et al</i>. proposed a ideal <i>lac</i> operator O<sub>id</sub> that binds the Lac repressor 10‑fold tighter than the natural strong <i>lac</i> operator O1. O<sub>id</sub> is a inverted repeat of the left half of O1 (Figure 5). |
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| | <img class="figure image" src="https://static.igem.org/mediawiki/2017/c/ce/T--Bielefeld-CeBiTec--Oid_and_O1_compared2.png"> | | <img class="figure image" src="https://static.igem.org/mediawiki/2017/c/ce/T--Bielefeld-CeBiTec--Oid_and_O1_compared2.png"> |
| − | <p class="figure subtitle"><b>Figure 5: The <i>lac</i> operator O<sub>id</sub>.</b><br>The inversion is indicated by the arrow for the perfectly symmetric lac operator O<sub>id</sub>. It is the inverted repeat of the left half of O1 (Sadler <i>et al</i>. 1983).</p> | + | <p class="figure subtitle"><b>Figure 5: The <i>lac</i> operator O<sub>id</sub>.</b><br>The inversion is indicated by the arrow for the perfectly symmetric <i>lac</i> operator O<sub>id</sub>. It is the inverted repeat of the left half of O1 (Sadler <i>et al</i>. 1983).</p> |
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| − | The operator‑DNA‑operator complex requires energy for the bending process in order to form a DNA loop. Additional energy for a torsion is required when the two <i>lac</i> operators lay on opposite sites of the helical DNA surface. Therefore, the DNA loop formation is energetically favoured for lac operators in phase (Müller <i>et al</i>., 1996). In 1996, Mueller <i>et al</i>. investigated the strength of repression for an inter‑operator distance of O<sub>id</sub> and O1 from 57.5 bp up to 1493.5 bp. The repression values were compared to the repression by a single O1 at its natural position. A shorter spacing than 57.5 bp could not be examined due to the 35 box of the promoter. Phase dependency for the repression was observed for a spacing around 200 bp. That leads to the observation of periodically maxima for repression values (Figure 6). | + | The operator‑DNA‑operator complex requires energy for the bending process in order to form a DNA loop. Additional energy for a torsion is required when the two <i>lac</i> operators lay on opposite sites of the helical DNA surface. Therefore, the DNA loop formation is energetically favoured for <i>lac</i> operators in phase (Müller <i>et al</i>., 1996). In 1996, Mueller <i>et al</i>. investigated the strength of repression for an inter‑operator distance of O<sub>id</sub> and O1 from 57.5 bp up to 1493.5 bp. The repression values were compared to the repression by a single O1 at its natural position. A shorter spacing than 57.5 bp could not be examined due to the 35 box of the promoter. Phase dependency for the repression was observed for a spacing around 200 bp. That leads to the observation of periodically maxima for repression values (Figure 6). |
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| | The distance of 70.5 bp showed the strongest repression value which is 50‑fold higher than the natural repression. Repression drops sharply to 15‑fold at a 150.5 bp spacing and to threefold at around 600 bp. All inter-operator distances beyond 600 bp kept a twofold increased repression value (Müller <i>et al</i>., 1996). | | The distance of 70.5 bp showed the strongest repression value which is 50‑fold higher than the natural repression. Repression drops sharply to 15‑fold at a 150.5 bp spacing and to threefold at around 600 bp. All inter-operator distances beyond 600 bp kept a twofold increased repression value (Müller <i>et al</i>., 1996). |
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| − | According to these results, our <i>P<sub>lac‑tight</sub></i> consists of the auxiliary operator O<sub>id</sub> with a 70.5 bp spacing to O1 at its natural position. The residuray sequence like the P lac was kept as the natural lac operon taken from <i>E. coli</i> BL21(DE3) (Figure 7). | + | According to these results, our <i>P<sub>lac‑tight</sub></i> consists of the auxiliary operator O<sub>id</sub> with a 70.5 bp spacing to O1 at its natural position. The residuray sequence like the P lac was kept as the natural <i>lac</i> operon taken from <i>E. coli</i> BL21(DE3) (Figure 7). |
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