Proteins regulate biological functions through formation of distinct protein complexes. Identification and characterization of these protein-protein interactions are critical to decipher their mechanism of action. Different antibody- or crosslinking-based methods have been developed to identify the protein-protein interactions. However, these methods require genetic engineering and/or other means to disrupt the native environments. To circumvent this limitation, we introduce here SMAP3-ID (Small Molecule Assisted identification of Protein-Protein interactions through Proximity) method to identify protein-protein interactions in native cells. This method entails a selective ligand for binding to a protein of interest for photocrosslinking, a live-cell compatible bioorthogonal click reaction with a trifunctional chemical probe and a final photocrosslinking reaction to covalently capture the interacting proteins. Using SMAP3-ID method and nuclear lamin as an example, we identified lamin-interactors in native cells. Significantly, we identified a number of mitochondrial enzymes as novel lamin A (LA)-interactors. The interactions between mitochondrial enzymes and LA were further validated, which provides mechanistic insights underlying the metabolic alterations caused by mutations in LA. We conclude that SMAP3-ID is a powerful and generalizable method to identify protein-protein interactions in the native cellular environment.