The structure, processing, morphology, and property relationships of biaxially drawn isotactic polypropylene (BOPP) film of mixed metallocene isotactic PP (m-iPP) and Ziegler-Natta iPP (ZN-iPP) homopolymer compositions are developed. The DSC and film drawing behavior show cocrystallization of the ZN-iPP and m-iPP components. The structure, processing, morphology, and property relations of ZN-iPP/ m-iPP blends are compared with ZN-iPP of varying isotacticities. The ZN-iPP/m-iPP blends exhibit reduced biaxial yield stress [sigma (y)(T)]. A fractional crystallinity model collapses the sigma (y)(T) data into a common normalized form over a range of draw temperatures, ZN-iPP tacticities, and blend compositions. The simplified model is extended to define the interrelationships of yield activation and strain hardening behavior into regimes differentiated by characteristic draw stress (crystallinity) levels. Structure-property models are developed to explain the effect of draw temperature and resin-blend microstructure on the draw behavior, film stiffness, barrier, elongation, and synergies of the BOPP film processing-property balance.