Abstract
Bacterial therapies, designed to manufacture therapeutic proteins directly within tumors, could eliminate cancers that are resistant to other therapies. To be effective, a payload protein must be secreted, diffuse through tissue, and efficiently kill cancer cells. To date, these properties have not been shown for a single protein. The gene for Staphylococcus aureus α-hemolysin (SAH), a pore-forming protein, was cloned into Escherichia coli. These bacteria were injected into tumor-bearing mice and volume was measured over time. The location of SAH relative to necrosis and bacterial colonies was determined by immunohistochemistry. In culture, SAH was released and killed 93% of cancer cells in 24 hours. Injection of SAH-producing bacteria reduced viable tissue to 9% of the original tumor volume. By inducing cell death, SAH moved the boundary of necrosis toward the tumor edge. SAH diffused 6.8 ± 0.3 µm into tissue, which increased the volume of affected tissue from 48.6 to 3,120 µm(3). A mathematical model of molecular transport predicted that SAH efficacy is primarily dependent on colony size and the rate of protein production. As a payload protein, SAH will enable effective bacterial therapy because of its ability to diffuse in tissue, kill cells, and expand tumor necrosis.