Within cells, proteins can co-assemble into functionally-integrated and spatially restricted multicomponent complexes. Often, the affinities between individual proteins are relatively weak, and proteins within such clusters may interact only indirectly with many of their other protein neighbors. This makes proteomic characterization difficult using methods such as immunoprecipitation or crosslinking. Recently, several groups have described the use of enzymecatalyzed proximity-labeling reagents that covalently tag the neighbors of a targeted protein with a small molecule such as fluorescein or biotin. The modified proteins can then be isolated by standard pull-down methods, and identified by mass spectrometry. Here we will describe the techniques, as well as their similarities and differences. We discuss their applications, both to study protein assemblies, and to provide a new way for characterizing organelle proteomes. We stress the importance of proteomic quantitation and independent target validation in such experiments. Furthermore, we suggest that there are biophysical and cell-biological principles that dictate the appropriateness of enzyme-catalyzed proximity-labeling methods to address particular biological questions of interest.