Abstract
Polymeric (p) immunoglobulins (Igs) play critical roles in vertebrate immunity. IgM is the evolutionarily oldest pIg and functions both in circulation and in the mucosa. pIgM typically comprises between four and six IgM monomers and up to one joining chain (JC), which in mammals facilitates pIg assembly and promotes delivery to mucosal secretions. Bony fish (teleosts) lack JC and assemble tetrameric IgM whereas humans can express JC-containing pentamers and JC-free hexamers. Here we report cryo-electron microscopy structures of two JC-free chimeric IgM, comprising bony fish and human sequences, and the structure of human hexameric IgM. Chimeric IgM structures adopted unique pentameric geometry distinct from both human and fish pIgM whereas the human hexameric IgM structure adopted hexagonal geometry similar to JC-containing pentameric IgM, albeit with structural differences in center of the molecule. Together results provide new insights on how IgM heavy chain motifs contribute to JC-free pIgM assembly and reveal plasticity of this process, which can be manipulated to create pIg structures not observed in nature. Moreover, we found that antigen-targeting chimeric IgM could neutralize C. difficile toxin cytotoxicity, indicating potential to engineer uniquely structured pIgs to prevent or treat disease.