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Cytoplasmic dynein is a motor protein that plays a role in a number of cellular processes including retrograde transport. In many cases, dynein needs to interact with another protein, dynactin, to be fully active. An important step in the assembly of the dynein/dynactin complex is the interaction between the N‐terminal portion of the intermediate chain (IC) subunit of dynein and the coiled‐coil 1B (CC1B) region of the p150^Glued subunit of dynactin. Despite evidence for this interaction from binding studies, the exact location of where these proteins bind has remained elusive due to the dynamic nature of the interaction and the presence of intrinsically disordered regions in IC. By using intermolecular paramagnetic relaxation enhancements, we have been able to constrain the location of IC binding on p150^Glued to a position that is different from what has recently been hypothesized in a model of the dynein/dynactin complex based on cryo‐electron microscopy (cryo‐EM) data and AlphaFold predictions. In addition, although phosphorylation is important for regulating dynein/dynactin interactions, we show that a phosphomimetic mutation of IC is not sufficient to alter binding with p150^Glued. 

Here we show that a combination of previously suggested mutations for tobacco etch virus (TEV) protease results in a TEV protease mutant that maintains the same catalytic efficiency as previously described mutants but has enhanced stability and solubility. Another advantage of this new variant of TEV protease is that it does not need the inclusion of a reducing agent to maintain its effectiveness, making it easier to generate, store, and use in cleavage reactions compared to previous TEV protease mutants and, in particular, makes it a good choice for cleaving proteins that contain disulfide bonds that would otherwise be altered by the inclusion of a reducing agent. We also provide a straightforward purification protocol for generating this new version of TEV protease.