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− | + | <h1>RNA Aggregation</h1>In synthetic biology, we are often introducing new pathways to bacteria that do not naturally express them. The novel pathway will produce exotic enzymes and proteins which the host bacteria will not necessarily have the internal environment to organise these macromolecular products, this could be detrimental to the performance of both the pathway and the organism itself. Additionally, depending on the organism used, the activity of the pathway can vary and be difficult to characterise against other models used. Thus, we aim to standardize the microenvironmental activity of different pathways within the cell by localising the associated enzymes/proteins in an RNA based structure, leading to the pathway to act in a predictable way, regardless of the organism. | |
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− | + | <div class=text4left><img id=img1 src="https://static.igem.org/mediawiki/2017/6/65/RNA_wiki_1.png"><!--An image or you can replace it by text--><span><strong>Fig. 1: </strong><strong>A.</strong>) Representation of single-stranded RNA that forms the liquid-liquid phase separated-like structure. <strong>B.</strong>) Images of RNA aggregates formed inside the nucleus of different mutant mammalian cells that express RNA containing either the repeats CUG or CAG</span></div> | |
− | + | <div class=text4right><!--Your text or you can replace it by an image-->In mammalian cells, RNA containing triplet repeats of nucleotides such as CAGCAGCAGCAG have been observed to aggregate in the nucleus. The properties of the RNA aggregation has been observed to be similar to those seen in liquid-liquid phase separated molecules, which can be visualized as oil droplets in water. The densely compact RNA strands will allow small molecules or substrates to pass through the structure while maintaining a different internal environment. Using this idea, we aimed to express RNA containing repeats in bacterial cells, in order to develop an intracellular scaffold.</div> | |
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− | + | <h1><i>In Vivo</i> Scaffolding</h1> | |
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− | + | <h2>Model Prediction</h2> | |
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− | + | The modelling of the organelle’s kinetics showed that when the rate of reaction (k) between A and B are low, the non-specific homogenous mixture would have a higher rate of production. Although, if k is at a high rate and more specific binding, the organelle would have an exponentially higher rate of production for the reaction of A and B. The model indicates that the organelle prefers a higher constant specific reactions. | |
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− | + | <img id=img1 src="https://static.igem.org/mediawiki/2017/a/ac/RNA_Modelling.png"><span><strong>Fig. 2. </strong>The rate of production against the rate of reaction of A and B. The model shows the expected performance of the organelle at different rates of reaction (<i>k</i>).</span> | |
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− | + | <div class=text2left><img id=img1 src="https://static.igem.org/mediawiki/2017/6/62/In_vivo_FAFB_System.png"><span><strong>Fig. 3: </strong><strong>A</strong>) A schematic of the construct use to generate RNA aggregates that contain MS2 aptamers. <strong>B</strong>) The specific binding of FA and FB will form a complete GFP. <strong>C</strong>) The production of FA with MS2 will will be in competition to either bind with FB or the RNA aggregation.</span></div> | |
− | + | <div class=text2right><h2>FA-FB System</h2>The FA-FB system is a visualisation method that uses two components of a split GFP, FA and FB, which can bind together to form a complete GFP. Usually, the two components are linked to specific aptamers which bind to their respective domains, allowing the GFP to be present at the site of interest. The FA component is expressed an MS2 aptamer, which is a specific bacteriophage binding site that connects an MS2 binding domain. By expressing the CAG repeat sequence with an MS2 binding domain (<strong>fig. 2A</strong>), specific binding can occur on the RNA aggregation. Thus, this creates a localization of FA in the cell.</div> | |
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+ | <h1><i>In Vivo</i> Results</h1> | ||
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+ | <img id=img1 src="https://static.igem.org/mediawiki/2017/4/48/RNA_organelle.png"> | ||
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+ | <span><strong>Fig. 4: </strong>The fluorescent data of FA and FB expression in the presence of the RNA organelle and without at different levels of arabinose induction.</span> | ||
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− | + | <div class=text2left><img id=img1 src="https://static.igem.org/mediawiki/2017/f/fa/Log_phase_Aggregates.png"><span><strong>Fig. 5: </strong><strong>A</strong>) GFP expression in overnight culture. <strong>B</strong>) Labelled areas of fluorscent intensity of a minimum of 3000 pixel value. <strong>C</strong>) The charted intensity of the regions of interest labelled in B</span></div> | |
− | + | <div class=text2right><img id=img1 src="https://static.igem.org/mediawiki/2017/e/e6/20h_RNA_Aggregates.png"><span><strong>Fig. 6: </strong>A</strong>) GFP expression in 20h culture. <strong>B</strong>) Labelled areas of fluorscent intensity of a minimum of 3000 pixel value. <strong>C</strong>) The charted intensity of the regions of interest labelled in B</span></div> | |
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− | + | <p>Fig 4 shows that as the expression of FA and FB are increased through arabinose induction, we see an increase in the overall GFP signal, which indicates the performance of the non-specific binding of the FA-FB. For the cultures that were also induced with formation of the RNA organelle with the FA and FB components, we can see that there is a much lower background signal. This could be explained by the low affinity of FA and FB aggregation. When RNA organelle rapidly recruit all the FA, FB in cytoplasm is unable to find its substrate. As predicted by our model, the RNA organlle removes non-specific reactions in synthetic systems.</p> | |
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− | + | <p>Fig. 5 and fig. 6 both a log phase and 20h time points respectively, showing that the aggregations are long-living as they can still be seen at the 20h point. Additionally, this is evidence that the system is irreversible. The data adds more evidence that the synthetic organelle could be used in a cell-free system.</p> | |
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+ | <h1>Synthesis of CAG Repeats</h1> | ||
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+ | <div><img id=img1 src="https://static.igem.org/mediawiki/2017/d/db/RNA_wiki_2.png"></div> | ||
+ | <!--An image or you can replace it by text--><span><strong>Fig. 7: </strong>A) The resulting product of the repeat synthesis from random assembly of 10xCAG and 10xCTG nucleotides at initial concentrations of 0μl, 2μl, 3μl and 4μl. B) A schematic representation of the random assembly of the 10xCAG and 10xCTG sequences.</span></div> | ||
+ | <div class=text4right>A collection of repeat sequences was built using two oligonucleotides: 10xCAG and 10xCTG. Through testing a variety of oligonucleotide concentrations and testing a different of PCR conditions, a specific protocol was built to synthesise various lenths of DNA containing CAG repeats. The resulting product appeared as a smear, indicating a range of lengths was created, the product was subsequently transformed into a T7 containing vector in order to produce RNA containing CAG repeats. | ||
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Revision as of 01:08, 2 November 2017
RNA Aggregation
In synthetic biology, we are often introducing new pathways to bacteria that do not naturally express them. The novel pathway will produce exotic enzymes and proteins which the host bacteria will not necessarily have the internal environment to organise these macromolecular products, this could be detrimental to the performance of both the pathway and the organism itself. Additionally, depending on the organism used, the activity of the pathway can vary and be difficult to characterise against other models used. Thus, we aim to standardize the microenvironmental activity of different pathways within the cell by localising the associated enzymes/proteins in an RNA based structure, leading to the pathway to act in a predictable way, regardless of the organism.In Vivo Scaffolding
Model Prediction
The modelling of the organelle’s kinetics showed that when the rate of reaction (k) between A and B are low, the non-specific homogenous mixture would have a higher rate of production. Although, if k is at a high rate and more specific binding, the organelle would have an exponentially higher rate of production for the reaction of A and B. The model indicates that the organelle prefers a higher constant specific reactions.
FA-FB System
The FA-FB system is a visualisation method that uses two components of a split GFP, FA and FB, which can bind together to form a complete GFP. Usually, the two components are linked to specific aptamers which bind to their respective domains, allowing the GFP to be present at the site of interest. The FA component is expressed an MS2 aptamer, which is a specific bacteriophage binding site that connects an MS2 binding domain. By expressing the CAG repeat sequence with an MS2 binding domain (fig. 2A), specific binding can occur on the RNA aggregation. Thus, this creates a localization of FA in the cell.In Vivo Results
Fig 4 shows that as the expression of FA and FB are increased through arabinose induction, we see an increase in the overall GFP signal, which indicates the performance of the non-specific binding of the FA-FB. For the cultures that were also induced with formation of the RNA organelle with the FA and FB components, we can see that there is a much lower background signal. This could be explained by the low affinity of FA and FB aggregation. When RNA organelle rapidly recruit all the FA, FB in cytoplasm is unable to find its substrate. As predicted by our model, the RNA organlle removes non-specific reactions in synthetic systems.
Fig. 5 and fig. 6 both a log phase and 20h time points respectively, showing that the aggregations are long-living as they can still be seen at the 20h point. Additionally, this is evidence that the system is irreversible. The data adds more evidence that the synthetic organelle could be used in a cell-free system.
Synthesis of CAG Repeats