Abstract
Differential display (DD) is commonly used for identifying differentially expressed genes. However, each cDNA species identified by DD must be verified so a “real difference” can be differentiated from false positives. Although Northern blot analysis is the gold standard it is labor intensive, time-consuming and requires a significant amount of RNA. To speed up and streamline the confirmation process, we developed a new strategy: binary differential display (BDD) based on the binding kinetics of the arbitrary primers in DD. After determining a cDNA sequence of interest from a DD screen, two more 13mer primers derived from the original arbitrary primer used can be designed to target a corresponding cDNA sequence of interest: one with perfect 5′-base matches and the other with additional mismatches at the 5′-base to the corresponding mRNA being confirmed. A separate reverse transcription and FDD are then performed with the same RNA samples being compared. BDD can quickly and accurately determine if a cDNA sequence identified by DD corresponds to a truly differentially expressed gene. In addition, the method is especially useful when more than one cDNA sequence was recovered from a DD band where the masking effect of false-positives can be clearly resolved. Given its simplicity and limited RNA sample required, BDD can be used as a general strategy for rapid confirmation of differentially expressed genes discovered by DD.
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Cho, Yj., Meade, J.D., Shester, B.R. et al. Proof-reading signal accuracy of gene expression by binary differential display. Biotechnol Lett 32, 1039–1044 (2010). https://doi.org/10.1007/s10529-010-0268-y
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DOI: https://doi.org/10.1007/s10529-010-0268-y