摘要
Cell cycle progression is coordinated with metabolism, signaling and other complex cellular functions. The investigation of cellular processes in a cell cycle stage-dependent manner is often the subject of modern molecular and cell biological research. Cell cycle synchronization and immunostaining of cell cycle markers facilitate such analysis, but are limited in use due to unphysiological experimental stress, cell type dependence and often low flexibility. Here, we describe high-content microscopy-assisted cell cycle phenotyping(hi MAC), which integrates high-resolution cell cycle profiling of asynchronous cell populations with immunofluorescence microscopy. hi MAC is compatible with cell types from any species and allows for statistically powerful, unbiased, simultaneous analysis of protein interactions, modifications and subcellular localization at all cell cycle stages within a single sample. For illustration, we provide a hi MAC analysis pipeline tailored to study DNA damage response and genomic instability using a 3–4-day protocol,which can be adjusted to any other cell cycle stage-dependent analysis.
Cell cycle progression is coordinated with metabolism, signaling and other complex cellular functions. The investigation of cellular processes in a cell cycle stage-dependent manner is often the subject of modern molecular and cell biological research. Cell cycle synchronization and immunostaining of cell cycle markers facilitate such analysis, but are limited in use due to unphysiological experimental stress, cell type dependence and often low flexibility. Here, we describe high-content microscopy-assisted cell cycle phenotyping(hi MAC), which integrates high-resolution cell cycle profiling of asynchronous cell populations with immunofluorescence microscopy. hi MAC is compatible with cell types from any species and allows for statistically powerful, unbiased, simultaneous analysis of protein interactions, modifications and subcellular localization at all cell cycle stages within a single sample. For illustration, we provide a hi MAC analysis pipeline tailored to study DNA damage response and genomic instability using a 3–4-day protocol,which can be adjusted to any other cell cycle stage-dependent analysis.
基金
supported in part by the Deutsche Forschungsgemeinschaft (DFG
Grant Nos. WA2627/1-1 and WA2627/5-1) of Germany
