Immunofluorescence-based detection of proteins in fixed cells is a powerful tool for research in cell and developmental biology. While a variety of immunofluorescence protocols exist, they can be time consuming or require expensive equipment which may not be accessible to all laboratories. A common challenge in these protocols is the numerous washing steps, particularly in experiments with numerous conditions. To address this, here we introduce the IF-CRIB device, a 3D-printable wash rack specifically designed for applications involving a high number of round coverslips with adherent cultured cells. We detail its design and the 3D printing process which can be easily used by any laboratory and we highlight that it facilitates the numerous washing steps. In addition, we present the IF-Express protocol, an optimized and effective method that enables fast and consistent immunofluorescence results. As an example of the utility of the IF-CRIB device and the IF-Express protocol, we describe their application in the screening and characterization of several NIH3T3 cell clones expressing a degradable form of ERK2 kinase (ERK2-dTAG) after treatment with the dTAG-13 compound. The generation of ERK2-dTAG clones involves a knock-in strategy. We provide a detailed methodology for clone selection, immunofluorescence screening, and characterization of ERK2-dTAG, including degradation kinetics, dose-response analysis, and nuclear translocation assays to assess ERK2-dTAG functionality. The IF-CRIB device and IF-Express protocol has been proven to be efficient for the obtention and characterization of ERK2dTAG-expressing clones thereby offering a powerful framework for studying ERK2 dynamics in cell biology and disease models.
Keywords: 3D-printing; ERK quantity; ERK2; FKPB12(F36V); IF-CRIB; IF-Express protocol; Immunofluorescence; PROTAC; dTAG; dTAG-13.
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