User:Isabela de Aquino Zogbi/Sandbox1
From Proteopedia
(Difference between revisions)
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===Structure=== | ===Structure=== | ||
| - | <scene name='91/915204/Secondary_structure_dysf/4'>Dysferlin</scene> has seven tandem C2 domains (<scene name='91/915204/C2adomain/1'>C2A</scene>, B, C, D, E and G), three Fer domains (FerA, FerB and FerI) which are short conserved regions found only in the ferlin protein family and are not yet shown to be folded domains <ref> https://link.springer.com/article/10.1186/1472-6807-14-3 </ref> , two <scene name='91/915204/Inner_dysf/1'>Dysf domains</scene> and a C-terminal transmembrane domain with a helix embedded in a patching vesicle. | + | <scene name='91/915204/Secondary_structure_dysf/4'>Dysferlin</scene> has seven tandem C2 domains (<scene name='91/915204/C2adomain/1'>C2A</scene>, B, C, D, E and G), three Fer domains (FerA, FerB and FerI) which are short conserved regions found only in the ferlin protein family and are not yet shown to be folded domains <ref name="ref2"> https://link.springer.com/article/10.1186/1472-6807-14-3 </ref> , two <scene name='91/915204/Inner_dysf/1'>Dysf domains</scene> and a C-terminal transmembrane domain with a helix embedded in a patching vesicle. |
[[Image:Schema_of_the_human_dysferlin_domain_structures_(2).png]] | [[Image:Schema_of_the_human_dysferlin_domain_structures_(2).png]] | ||
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====DysF Domain==== | ====DysF Domain==== | ||
| - | One Dysf domain is inserted into the other Dysf domain forming an inner Dysf domain (not represented in the image below) and a two part outer Dysf domain (N-terminal DysFN and C-terminal DysFC), and it is woth mentioning that the Dysf domain is held together by arginine/ aromatic sidechain stacking. The crystal structure of the human dysferlin inner DysF domain with a resolution of 1.9 Ångstroms by X-Ray diffraction | + | One Dysf domain is inserted into the other Dysf domain forming an inner Dysf domain (not represented in the image below) and a two part outer Dysf domain (N-terminal DysFN and C-terminal DysFC), and it is woth mentioning that the Dysf domain is held together by arginine/ aromatic sidechain stacking. The crystal structure of the human dysferlin inner DysF domain with a resolution of 1.9 Ångstroms by X-Ray diffraction <ref name="ref2">. |
===Function=== | ===Function=== | ||
| - | Many dysferlinopathy causing mutations fall in the DysF domains | + | Many dysferlinopathy causing mutations fall in the DysF domains. It's important to notice that dysferlin function is linked with calcium-activated membrane repair caused by fusing aggregated intracellular vesicles with the sarcolemma at the site of injury <ref name="ref2">. |
It has been shown that dysferlin deficiency delays myoblast (undifferentiated mononuclear muscle cells) fusion/maturation in vitro, suggesting that dysferlin may also participate in muscle differentiation and regeneration process <ref name="omim"/>. | It has been shown that dysferlin deficiency delays myoblast (undifferentiated mononuclear muscle cells) fusion/maturation in vitro, suggesting that dysferlin may also participate in muscle differentiation and regeneration process <ref name="omim"/>. | ||
====C2 Domains function==== | ====C2 Domains function==== | ||
| - | C2 domains are calcium sensitive phospholipid binding domains with an approximate length of 130 amino acids <ref name="ref5"/>, while the function of the Dysf domain remains unclear <ref name="ref1"/> | + | C2 domains are calcium sensitive phospholipid binding domains with an approximate length of 130 amino acids <ref name="ref5"/>, while the function of the Dysf domain remains unclear <ref name="ref1"/> <ref name="ref2">. The presence of the C2 domains is common to ferlin-like proteins, in which only the C2A domain binds strongly to lipids in a calcium dependent way. The other domains have weaker bonds or are calcium independent. Also, C2A, E and F domains have shown a relevant function in the protein activity <ref name="ref5"/>. In response to elevated calcium concentrations, these domains target a protein to a particular membrane compartment based upon preference for an organelle specific lipid headgroup. After binding, some C2 domains actively cluster lipids or bend the membrane, actively perturbing membrane structure in helping to facilitate cellular processes (8). |
== Disease == | == Disease == | ||
| - | Dysferlinopathies are caused by mutations in dysferlin and most of these mutations are part of aromatic/arginine stacks that hold the Dysf domain in a folded conformation | + | Dysferlinopathies are caused by mutations in dysferlin and most of these mutations are part of aromatic/arginine stacks that hold the Dysf domain in a folded conformation <ref name="ref2">. LGMDs (Limb-girdle muscular dystrophies) are a group of muscular dystrophies characterized by predominant weakness and wasting of muscles of the pelvic and shoulder girdle (4). LGMD2B (Limb-girdle muscular dystrophy type 2B) is a predominantly proximal muscular dystrophy with an onset in the late teens, in which are identified mutations in the N terminus of Dysf gene that results in dysferlin-reactive amyloid fibrils in the muscle fibers, as a result of a destabilization of the protein (3). |
As for Miyoshi Myopathy (MM), it is a predominantly distal muscular dystrophy with early involvement of the posterior compartments of the lower limb and the disease onset is generally in the late teens with an initial involvement of the muscles of the distal lower limbs. Thus, in both diseases, muscles of the limb and girdle are primarily affected, the symptoms usually appear in the late teens, the diseases progress slowly and high levels of creatine kinase, a skeletal-muscle-specific enzyme, are detected in the serum of the patients (4). It is suggested that both diseases could be a result of the same mutations in the Dysf gene, and the phenotypic differences would be accounted for by modifier genes or other factors that could vary its expression (3). With the association of both dystrophies and dysferlin, and its known function of maintaining the integrity of the cells, it is suggested that it also plays an important role in facilitating the repair of cell membranes in skeletal tissues <ref name="ref5"/>. | As for Miyoshi Myopathy (MM), it is a predominantly distal muscular dystrophy with early involvement of the posterior compartments of the lower limb and the disease onset is generally in the late teens with an initial involvement of the muscles of the distal lower limbs. Thus, in both diseases, muscles of the limb and girdle are primarily affected, the symptoms usually appear in the late teens, the diseases progress slowly and high levels of creatine kinase, a skeletal-muscle-specific enzyme, are detected in the serum of the patients (4). It is suggested that both diseases could be a result of the same mutations in the Dysf gene, and the phenotypic differences would be accounted for by modifier genes or other factors that could vary its expression (3). With the association of both dystrophies and dysferlin, and its known function of maintaining the integrity of the cells, it is suggested that it also plays an important role in facilitating the repair of cell membranes in skeletal tissues <ref name="ref5"/>. | ||
Revision as of 16:12, 19 June 2022
Dysferlin
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References
- ↑ OMIM: https://www.omim.org/entry/603009?search=dysferlin&highlight=dysferlin; https://www.sciencedirect.com/science/article/pii/S0955067407000993
- ↑ https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0013854
- ↑ 3.0 3.1 https://www.sciencedirect.com/science/article/pii/S0022283619301883
- ↑ 4.0 4.1 https://link.springer.com/article/10.1186/1472-6807-14-3
- ↑ 5.0 5.1 https://onlinelibrary.wiley.com/doi/full/10.1111/j.1600-0854.2011.01267.x
- ↑ https://www.sciencedirect.com/science/article/pii/S0005273614000108?via%3Dihub
