Dynamically cross-linked polypropylene/ethylene-methyl acrylate copolymer (PP/EMA) blends were prepared by reactive extrusion in a twin-screw extruder. A transesterification reaction catalyzed by an organotin compound and involving the acrylic moieties of EMA with the hydroxyl functions of pentanediol was used to cross-link the elastomeric EMA. The extent of cross-linking was estimated through the insoluble content of the blend. The alcohol-to-acrylic ratio and the dibutyltin oxide content were both found to increase the extent of EMA cross-linking. Processing conditions such as screw rotation rate and extrusion temperature profile also had large effects on the reaction extent. Conditions leading to improved pentanediol dispersion were found to generate larger insoluble fraction. Gel contents of EMA phase as high as 75% to 85% were obtained. Interestingly, the stress-strain curves of the cross-linked PP/EMA TPV are very well represented by a single master curve. Dynamically cross-linked blends show systematically better tensile properties than the non-reactive system. Blends with higher insoluble content show strain at break in the 650%-750% range. Material processability was maintained, even for the systems with high insoluble content.