[HTML][HTML] Enhanced muscular dystrophy from loss of dysferlin is accompanied by impaired annexin A6 translocation after sarcolemmal disruption

AR Demonbreun, MV Allen, JL Warner… - The American Journal of …, 2016 - Elsevier
AR Demonbreun, MV Allen, JL Warner, DY Barefield, S Krishnan, KE Swanson, JU Earley…
The American Journal of Pathology, 2016Elsevier
Dysferlin is a membrane-associated protein implicated in membrane resealing; loss of
dysferlin leads to muscular dystrophy. We examined the same loss-of-function Dysf mutation
in two different mouse strains, 129T2/SvEmsJ (Dysf 129) and C57BL/6J (Dysf B6). Although
there are many genetic differences between these two strains, we focused on
polymorphisms in Anxa6 because these variants were previously associated with modifying
a pathologically distinct form of muscular dystrophy and increased the production of a …
Dysferlin is a membrane-associated protein implicated in membrane resealing; loss of dysferlin leads to muscular dystrophy. We examined the same loss-of-function Dysf mutation in two different mouse strains, 129T2/SvEmsJ (Dysf129) and C57BL/6J (DysfB6). Although there are many genetic differences between these two strains, we focused on polymorphisms in Anxa6 because these variants were previously associated with modifying a pathologically distinct form of muscular dystrophy and increased the production of a truncated annexin A6 protein. Dysferlin deficiency in the C57BL/6J background was associated with increased Evan's Blue dye uptake into muscle and increased serum creatine kinase compared to the 129T2/SvEmsJ background. In the C57BL/6J background, dysferlin loss was associated with enhanced pathologic severity, characterized by decreased mean fiber cross-sectional area, increased internalized nuclei, and increased fibrosis, compared to that in Dysf129 mice. Macrophage infiltrate was also increased in DysfB6 muscle. High-resolution imaging of live myofibers demonstrated that fibers from DysfB6 mice displayed reduced translocation of full-length annexin A6 to the site of laser-induced sarcolemmal disruption compared to Dysf129 myofibers, and impaired translocation of annexin A6 associated with impaired resealing of the sarcolemma. These results provide one mechanism by which the C57BL/6J background intensifies dysferlinopathy, giving rise to a more severe form of muscular dystrophy in the DysfB6 mouse model through increased membrane leak and inflammation.
Elsevier