While the antigen binding site structure of the mIgM BCR is identical to other common soluble antibodies, there are several intracellular interactions between the heavy chains and Igα/β subunits that make it unique. In the Fc portion of the structure, the two heavy chains interact via a disulfide bond and form an <scene name='95/952700/O-shaped_ring/3'>O-shaped ring</scene>. Additionally, the Fc portion binds the <scene name='95/952700/O-shaped_ring/2'>Ig α/β heterodimer</scene> with 1:1 stoichiometry (reference link Pavel and Susan). Due to the orientation of the heavy chains in the O-shaped ring, only Heavy chain 1 (Hc1) forms direct interactions with the Igα/β heterodimer. Furthermore, <scene name='95/952700/Ig-a_and_hc_1/3'>Hc1 and Igα interact</scene> through two hydrogen bonds (T75-Q487 and N73-Q493) which are stabilized by sandwiching of aromatic residues (W76 sandwiched between F358 and F485). Similarly, <scene name='95/952700/Igb_and_hc/1'>Hc1 and Igβ interact</scene> through three hydrogen bonds (Y66-R491, K62-T530, and R55-T533,). The residues involved in the interactions at the heavy chain and Igα/β interface are highly conserved across all species, suggesting a conserved mode of interaction (reference link Qiang "IgM B cell receptor").  The Igα/β heterodimer is an obligate component of all BCRs. Igα and Igβ non-covalently associate with mIgM, and are crucial components for initiating biochemical signaling inside the B cell upon antigen binding (reference link Pavel and Susan). Igα and Igβ are associated by a disulfide bond between cystine residues. The disulfide bond is stabilized by π-π stacking and a hydrogen bond. These residues are highly conserved across species, suggesting conservation of the Igα/β interface.