Vacuolar aminopeptidase 1 is transported to the vacuole by cytoplasmic double-membrane vesicles, the nonclassic Cvt pathway. The cytosolic protein dodecamerizes and is enclosed in a double-membrane vesicle, which is transported to and fuses with the vacuole releasing a single-membrane autophagic body into the vacuolar lumen. This is degraded and the precursor sequence of aminopeptidase 1 is removed. This pathway resembles autophagy, and most proteins identified to function in the Cvt pathway are also required for autophagy and vice versa. The cytosolic precursor protein and the matured vacuolar protein form a homododecameric complex, and only this complex has enzymatic activity. We developed a new genetic screen to isolate mutants in the biogenesis of vacuolar aminopeptidase 1 based on its enzymatic activity. The sensitivity of this assay made it possible for us to search for mutants under conditions where autophagy is down-regulated, and we describe two new mutants defective in the biogenesis pathway of vacuolar aminopeptidase 1. Mutants are defective in dodecamerization of pApe1p and in Cvt vesicle formation. Complex assembly and transport vesicle formation appear to be linked processes. This mechanism can control the potentially harmful cytoplasmic proteolytic activity and could be the driving force for this nonclassic mechanism of vacuolar enzyme transport.