Team:Heidelberg/Project/Capsid Shuffling/ViroBytes
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==Introduction== | ==Introduction== | ||
- | ViroBytes is a modified BioBytes method for "shuffling" of AAV Cap genes. Main motivation for the new protocol is the insufficient incorporation of certain serotypes (especially AAV 5) observed in standard shuffling techniques [ | + | ViroBytes is a modified [https://2009.igem.org/Team:Alberta BioBytes] method for "shuffling" of AAV Cap genes. Main motivation for the new protocol is the insufficient incorporation of certain serotypes (especially AAV 5) observed in standard shuffling techniques ([https://2010.igem.org/Team:Heidelberg/Project/References#Capsid_Shuffling Grimm et al., 2008]). The principle of Biobyte formation and annealing persists ie. the sticky overhangs are still used for selective combination of the bytes but different method is used for the production of individual Virobytes. |
Five AAV serotypes (1,2,5,6,8 and 9) were selected and the Cap genes sequences were compared. The analysis revealed multiple homology regions which were used for rational fragment formation. Total number of fragments per Cap gene is eight in our case and all fragments have similar length around ~250bp to assure similar behaviour in the ligation reaction. The Bytes are created and amplified with PCR using Cap- and FragmentX-specific primers. These primers contain flanking recognition sequence for Bsa1 precisely positioned in front of/behind the homology regions so that the enzyme cuts in the homology regions and forms unique 4nt long sticky ends. The sticky ends are 4nt long. This procedure allows us to avoid arduous design of overhangs with incorporated uracils further used for USER<sup>TM</sup> digestion. Also for the purposes of shuffling, the homology regions need to be exploited in order to avoid frame shifts which cannot be easily accomplished using standard BioByte protocol. | Five AAV serotypes (1,2,5,6,8 and 9) were selected and the Cap genes sequences were compared. The analysis revealed multiple homology regions which were used for rational fragment formation. Total number of fragments per Cap gene is eight in our case and all fragments have similar length around ~250bp to assure similar behaviour in the ligation reaction. The Bytes are created and amplified with PCR using Cap- and FragmentX-specific primers. These primers contain flanking recognition sequence for Bsa1 precisely positioned in front of/behind the homology regions so that the enzyme cuts in the homology regions and forms unique 4nt long sticky ends. The sticky ends are 4nt long. This procedure allows us to avoid arduous design of overhangs with incorporated uracils further used for USER<sup>TM</sup> digestion. Also for the purposes of shuffling, the homology regions need to be exploited in order to avoid frame shifts which cannot be easily accomplished using standard BioByte protocol. | ||
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==Important facts== | ==Important facts== |
Revision as of 11:09, 26 October 2010
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