The two-dimensional crystallization of streptavidin at functionalized lipid interfaces is one of the best studied model systems for investigating molecular self-assembly processes. This system also provides an opportunity to elucidate the relationship between protein−protein molecular recognition, crystallization solution conditions, and crystal properties such as coherence, space group symmetry, and morphology. A better understanding of these relationships may aid in the design of rational strategies for promoting high-quality protein crystallization and for controlling protein assembly at interfaces in the biomaterials and nanotechnology fields. Here we show that two-dimensional streptavidin crystallization is kinetically controlled and that formation of a single electrostatic interaction at the crystal contact interfaces is a key energetic determinant of the kinetic barriers controlling crystal morphology. Our results also demonstrate that this electrostatic interaction at the streptavidin protein−prot...