Quantifying the microRNAs(miRNAs)levels in living cells,while essential for the study of fundamental biology and medical diagnostics,has barely been achieved due to insufficient probe delivery and unquantifiable signa...Quantifying the microRNAs(miRNAs)levels in living cells,while essential for the study of fundamental biology and medical diagnostics,has barely been achieved due to insufficient probe delivery and unquantifiable signals.We report a cell-anchored and self-calibrated DNA nanoplatform,a cholesterol-headed DNA nanowire that is capable of efficiently delivering to various cells and simultaneously detecting two target miRNAs.One miRNA target can be utilized as an endogenous control against cell-to-cell variations.Moreover,the photocleavable linkers inserted in the nanostructures allow us to precisely regulate the probe structure and fluorescence signaling at the desired time and location in vivo.As a second control,the maximum fluorescence can be elicited by UV light,which further facilitates the normalization of the absolute fluorescence signal.With two introduced internal controls,the maximum fluorescence and endogenous control gene,this approach displays excellent stability and self-calibration performance,effectively avoiding the interference from operating conditions and cellto-cell variations,such as the laser powers and intracellular probe concentrations.Importantly,this design is capable of unifying the output signal intensity between in vitro test and cell imaging,making the in vitro linear calibration curve appropriate for the quantification of miRNA expression in living cells.展开更多
基金This work was financially supported by the Project Fund for Shangdong Key R&D Program(no.2019GSF108169)the National Natural Science Foundation of China(no.21605091)+3 种基金the Taishan Scholar Program of Shandong Province of China(no.ts20110829)the State Key Laboratory of Analytical Chemistry for Life Science(no.SKLACLS2008)the Natural Science Foundation of Shandong Province of China(no.ZR2021YQ11)the Open Project of Chemistry Department of Qingdao University of Science and Technology(no.QUSTHX201926).
文摘Quantifying the microRNAs(miRNAs)levels in living cells,while essential for the study of fundamental biology and medical diagnostics,has barely been achieved due to insufficient probe delivery and unquantifiable signals.We report a cell-anchored and self-calibrated DNA nanoplatform,a cholesterol-headed DNA nanowire that is capable of efficiently delivering to various cells and simultaneously detecting two target miRNAs.One miRNA target can be utilized as an endogenous control against cell-to-cell variations.Moreover,the photocleavable linkers inserted in the nanostructures allow us to precisely regulate the probe structure and fluorescence signaling at the desired time and location in vivo.As a second control,the maximum fluorescence can be elicited by UV light,which further facilitates the normalization of the absolute fluorescence signal.With two introduced internal controls,the maximum fluorescence and endogenous control gene,this approach displays excellent stability and self-calibration performance,effectively avoiding the interference from operating conditions and cellto-cell variations,such as the laser powers and intracellular probe concentrations.Importantly,this design is capable of unifying the output signal intensity between in vitro test and cell imaging,making the in vitro linear calibration curve appropriate for the quantification of miRNA expression in living cells.
