Molecular Biology

Regulation of microtubule stability is crucial for diverse biological processes, including cell division, morphogenesis, and signaling. Various in vitro assays for microtubule stability have been developed to identify and characterize proteins involved in controlling microtubule stability. Here, we introduce a simple ex-vivo assay for identifying potential microtubule regulators in the wing imaginal disc of Drosophila melanogaster. This assay utilizes silicon rhodamine-tubulin (SiR-Tub) as a cell-permeable fluorogenic dye for labeling microtubules. In an attempt to increase the sensitivity of the screen, we designed an assay using a sensitized microtubule condition. Wing discs are treated with SiR-Tub followed by demecolcine, a microtubule inhibitor, to partially label impaired microtubules. Under this sensitized condition, we can test whether overexpression or downregulation of a gene can enhance or suppress the weakened SiR-Tub labeling. This assay allows highly sensitive detection of microtubules in developing larval tissues. Hence, it provides a useful tool for identifying new microtubule regulators in both unfixed and fixed imaginal discs in Drosophila. This strategy may also be applied to characterize microtubule regulators in tissues from other model organisms.

Graphic abstract:

Graphical summary of Ex-vivo microtubule stability assay using Drosophila wing disc.

The Sec translocon, consisting of a heterotrimeric transmembrane channel (SecYEG) and an associated ATPase (SecA), catalyzes the export of unfolded proteins from the cytosol in bacteria. Kinetically resolving protein translocation at high resolution yields mechanistic insight into the process. Translocation is typically followed by measuring the protection of proteins transported into lipid vesicles, which only allows visualization of translocation after it has already been completed and limits time resolution. Here, we describe the implementation of an assay for measuring translocation in real-time. By priming the reconstituted translocon with suitably engineered substrate proteins, the kinetics of the actual translocation process can be resolved at high resolution. To analyze translocation kinetics, we developed a detailed kinetic model of the process that includes on-pathway and off-pathway processes. Together, this experimental protocol and model permit detailed mechanistic analyses of Sec-dependent protein translocation.

Graphic abstract:

Synchronized real-time measurements, combined with a detailed kinetic model, enable a mechanistic analysis of protein transport.