Abstract
Bacillus subtilis is a bacterial cell factory with outstanding protein secretion capabilities that has been deployed as a workhorse for the production of industrial enzymes for more than a century. Nevertheless, the production of other proteins with B. subtilis, such as antibody formats, has thus far been challenging due to specific requirements that relate to correct protein folding and disulfide bond formation upon export from the cytoplasm. In the present study, we explored the possibility of producing functional antibody formats, such as scFvs and scFabs, using the genome-reduced Midi- and MiniBacillus strain lineage. The applied workflow included selection of optimal chassis strains, appropriate expression vectors, signal peptides, growth media, and analytical methods to verify the functionality of the secreted antibody fragments. The production of scFv fragments was upscaled to the 1 L bioreactor level. As demonstrated for a human C-reactive protein-binding scFv antibody by mass spectrometry, biolayer interferometry, circular dichroism, free thiol cross-linking with N-ethylmaleimide, and nano-differential scanning fluorimetry, MidiBacillus strains can secrete fully functional, natively folded, disulfide-bonded, and thermostable antibody fragments. We therefore conclude that genome-reduced B. subtilis chassis strains are capable of secreting high-quality antibody fragments.