Difference between revisions of "Team:Uppsala/Transcriptomics/PolyA Tailing"

 
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<p>The purified RNA sample retrieved from previous mRNA purification step is dissolved in nuclease free water and ready to use. The key reagent is the poly(A) polymerase, an enzyme that attach the adenosine nucleotides onto the mRNA that is directly added into the sample. <br><br>
 
<p>The purified RNA sample retrieved from previous mRNA purification step is dissolved in nuclease free water and ready to use. The key reagent is the poly(A) polymerase, an enzyme that attach the adenosine nucleotides onto the mRNA that is directly added into the sample. <br><br>
  
As you might already know no work is done for free, and that is the case for the poly(A) polymerase. Thereby ATP is added, which is an energy molecule that activates the poly(A) polymerase. The mRNA is then analyzed with gel-electrophoresis to confirm that the poly(A) tail attachment was a success. It can be noted that we had some difficulties in acquiring good results initially from this step, which included degradation and apparent non-existing tailing of the samples. After several attempts however, and a complete change in Poly(A)-tailing reagents, the procedure started to work properly.</p>
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As you might already know, no work is done for free and that is the case for the poly(A) polymerase. Thereby ATP is added, which is an energy molecule that activates the poly(A) polymerase. The mRNA is then analyzed with gel-electrophoresis to confirm that the poly(A) tail attachment was a success. It can be noted that we had some difficulties in acquiring good results initially from this step, which included degradation and apparent non-existing tailing of the samples. After several attempts however, and a complete change in Poly(A)-tailing reagents, the procedure started to work properly.</p>
 
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    <p>A successful poly(A) tailed mRNA has a complete chain of adenosines connected to the 3’UTR of the mRNA strand. Initially, the adition of polyA has been very inefficient due to among other reasons low enzyme concentrations. Using double the recommended amount of enzyme, we managed to successfully attach of polyA tail to RNA. To be able to clearly illustrate the polyadenylation, we have added polyA tails to RNA ladder as can be seen in <b>Figure 1 </b>. The shift in size is especially well visible for the lowest 200 bp band.</p><br><br>
 
 
    <p>Equal enzyme concentrations as those used in the RNA ladder polyadenylation were used to attach polyA tails to the isolated mRNA. The increase in polyA polymerase concentration has resulted in significantly higher cDNA yields, as decribed <a href="https://2018.igem.org/Team:Uppsala/Transcriptomics/cDNA_Conversion">here</a></p><br><br>
 
 
                    
 
                    
 
                            
 
                            
 
                          
 
                          
 
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                        <h2 id="Resu">Result</h2>
  
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                                <p>A successful poly(A) tailed mRNA has a complete chain of adenosines connected to the 3’UTR of the mRNA strand. Initially, the adition of polyA has been very inefficient due to among other reasons low enzyme concentrations. Using double the recommended amount of enzyme, we managed to successfully attach polyA tail to RNA. To be able to clearly illustrate the polyadenylation, we have added polyA tails to RNA ladder as can be seen in <b>Figure 1 </b>. The shift in size is especially visible for the lowest 200 bp band.</p><br><br>
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    <p>Equal enzyme concentrations as those used in the RNA ladder polyadenylation were used to attach polyA tails to the isolated mRNA. The increase in polyA polymerase concentration has resulted in significantly higher cDNA yields, as decribed <a href="https://2018.igem.org/Team:Uppsala/Transcriptomics/cDNA_Conversion">here</a></p><br><br>
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  <p><b>Figure 1.</b> A successful poly(A) tail attachment onto RiboRuler High Range RNA Ladder (Thermo Fisher Scientific). The polyadnenylation is clearly visible on the bottom 200 bp band.</p>
 
  <p><b>Figure 1.</b> A successful poly(A) tail attachment onto RiboRuler High Range RNA Ladder (Thermo Fisher Scientific). The polyadnenylation is clearly visible on the bottom 200 bp band.</p>
 
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<p><b>Primers:</b> A primer is a short sequence of DNA or RNA, that will work as a starting point for DNA synthesis. The DNA polymerase used to catalyze this process can only add new nucleotides to an already existing strand of DNA. The polymerase attaches to the primer and progressing the synthesis at the 3’end, while copying the opposite strand.<br><br>
 
<p><b>Primers:</b> A primer is a short sequence of DNA or RNA, that will work as a starting point for DNA synthesis. The DNA polymerase used to catalyze this process can only add new nucleotides to an already existing strand of DNA. The polymerase attaches to the primer and progressing the synthesis at the 3’end, while copying the opposite strand.<br><br>
  
<b>Poly(A) polymerase:</b> Polyadenylate polymerase uses ATP to build the poly(A) tail, consisting of adenosine monophosphate. Adenosine is usually found in its triphosphate form, where the polymerase cleaving off pyrophosphate using monophosphate units to ad to the tail.<br><br>
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<b>Poly(A) polymerase:</b> Polyadenylate polymerase uses ATP to build the poly(A) tail, consisting of adenosine monophosphate. Adenosine is usually found in its triphosphate form, where the polymerase cleaves off pyrophosphate using monophosphate units to add to the tail.<br><br>
  
 
<b>ATP:</b> Adenosine triphosphate (ATP) is an organic chemical that is capable of providing energy to e.g. chemical reactions. When used in metabolic processes, it is converted either to adenosine diphosphate (ADP) or to adenosine monophosphate (AMP).<br><br>
 
<b>ATP:</b> Adenosine triphosphate (ATP) is an organic chemical that is capable of providing energy to e.g. chemical reactions. When used in metabolic processes, it is converted either to adenosine diphosphate (ADP) or to adenosine monophosphate (AMP).<br><br>
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<h2 id="References">References</h2>
 
<h2 id="References">References</h2>
  
<p><b>[1]</b> Wu X, Brewer G. 2012. The regulation of mRNA stability in Mammalian Cells: 2.0. Gene 500(1): 10-21.</p><br>
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<p><b>[1]</b> Wu X, Brewer G. 2012. The regulation of mRNA stability in Mammalian Cells: 2.0. Gene 500(1): 10-21.</p>
<p><b>[2]</b> Hunt AG, Xu R, Addepalli B, Rao S, Forbe KP, Meeks LR, Xing D, Mo M, Zhao H, Bandyopadhyay A, Dampanaboina L, Marion A, Von Lanken C, Quinn Li Q. Arabidopsis mRNA polyadenylation machinery: comprehensive analysis of protein-protein interaction and gene expression profiling. 2008. BMC Genomics 9:220. doi: 10.1186/1471-2164-9.220</p><br>
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<p><b>[2]</b> Hunt AG, Xu R, Addepalli B, Rao S, Forbe KP, Meeks LR, Xing D, Mo M, Zhao H, Bandyopadhyay A, Dampanaboina L, Marion A, Von Lanken C, Quinn Li Q. Arabidopsis mRNA polyadenylation machinery: comprehensive analysis of protein-protein interaction and gene expression profiling. 2008. BMC Genomics 9:220. doi: 10.1186/1471-2164-9.220</p>
 
<p><b>[3]</b> Sarkar N. 1997. Polyadenylation of mRNA in prokaryotes. Annual Review of Biochemistry. 66(1):173-97  
 
<p><b>[3]</b> Sarkar N. 1997. Polyadenylation of mRNA in prokaryotes. Annual Review of Biochemistry. 66(1):173-97  
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Latest revision as of 15:12, 3 December 2018