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The IgM BCR is anchored to [https://en.wikipedia.org/wiki/B_cell B-cell] membranes through the <scene name='95/952714/Integral_region/11'>transmembrane region</scene> which is broken up into both extracellular and integral domains which sit on top of or span through the membrane, respectively. IgM BCR assembly requires dimerization of the <b><span class="text-brown">Ig alpha</span></b> and <b><span class="text-orange">Ig beta</span></b> subunits which embed within the B-cell membrane. The <scene name='95/952714/Ig_alpha_beta/5'>Ig alpha and beta heterodimer</scene> dimerizes within the extracellular region with a <scene name='95/952714/Extracellular_disulfide_bridge/6'>disulfide bridge</scene>. Additional dimerization is believed to occur within the integral region via a hydrogen bond; the involved residues and interaction have not been confirmed. Although the mechanism of disulfide bridge formation is still unknown, it is believed that <scene name='95/952714/Extracellular_glycosylation/2'>extracellular glycosylation</scene> via <b><span class="text-lightgreen">N-linked glycosylation</span></b> (NAGs) on various asparagine residues in the extracellular region of both the <b><span class="text-brown">alpha</span></b> and <b><span class="text-orange">beta</span></b> chains help to facilitate this process. [https://en.wikipedia.org/wiki/Chaperone_(protein) Chaperone proteins] remain bound to the alpha and beta subunits until both dimerizations occur; at this point the rest of the BCR complex can be recruited. | The IgM BCR is anchored to [https://en.wikipedia.org/wiki/B_cell B-cell] membranes through the <scene name='95/952714/Integral_region/11'>transmembrane region</scene> which is broken up into both extracellular and integral domains which sit on top of or span through the membrane, respectively. IgM BCR assembly requires dimerization of the <b><span class="text-brown">Ig alpha</span></b> and <b><span class="text-orange">Ig beta</span></b> subunits which embed within the B-cell membrane. The <scene name='95/952714/Ig_alpha_beta/5'>Ig alpha and beta heterodimer</scene> dimerizes within the extracellular region with a <scene name='95/952714/Extracellular_disulfide_bridge/6'>disulfide bridge</scene>. Additional dimerization is believed to occur within the integral region via a hydrogen bond; the involved residues and interaction have not been confirmed. Although the mechanism of disulfide bridge formation is still unknown, it is believed that <scene name='95/952714/Extracellular_glycosylation/2'>extracellular glycosylation</scene> via <b><span class="text-lightgreen">N-linked glycosylation</span></b> (NAGs) on various asparagine residues in the extracellular region of both the <b><span class="text-brown">alpha</span></b> and <b><span class="text-orange">beta</span></b> chains help to facilitate this process. [https://en.wikipedia.org/wiki/Chaperone_(protein) Chaperone proteins] remain bound to the alpha and beta subunits until both dimerizations occur; at this point the rest of the BCR complex can be recruited. | ||
| - | After <b><span class="text-brown">Ig alpha</span></b>/<b><span class="text-orange">Ig beta</span></b> dimerization the transmembrane helices of the heavy chains can embed within the B-cell membrane as well. The side chains of this <scene name='95/952714/Integral_helices_2/ | + | After <b><span class="text-brown">Ig alpha</span></b>/<b><span class="text-orange">Ig beta</span></b> dimerization the transmembrane helices of the heavy chains can embed within the B-cell membrane as well. The side chains of this <scene name='95/952714/Integral_helices_2/2'>4-pass integral helix structure</scene> are primarily hydrophobic side chains that allow for interactions with the hydrophobic tails in the [https://en.wikipedia.org/wiki/Lipid_bilayer phospholipid bilayer]. The 4 helices are primarily held together through hydrophobic interactions (Figure___); however, a total of 9 polar residues (picture that zooms in here??) between each of the heavy chains are included on the interior of the helix structure which interact with a few polar residues on the <b><span class="text-brown">Ig alpha</span></b> and <b><span class="text-orange">Ig beta</span></b> chains. Additional interactions between the <b><span class="text-brown">Ig alpha</span></b>/<b><span class="text-orange">Ig beta</span></b> dimer and the heavy chains occur in the constant region. |
===Fc Region=== | ===Fc Region=== | ||
Revision as of 02:46, 3 April 2023
Human B-cell Antigen Receptor: IgM BCR
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References
Student Contributors
Detonyeá Dickson Allison Goss Jackson Payton
