BAG3 and Hsc70 interact with actin capping protein CapZ to maintain myofibrillar integrity under mechanical stress

A Hishiya, T Kitazawa, S Takayama - Circulation research, 2010 - Am Heart Assoc
A Hishiya, T Kitazawa, S Takayama
Circulation research, 2010Am Heart Assoc
Rationale: A homozygous disruption or genetic mutation of the bag 3 gene, a member of the
Bcl-2–associated athanogene (BAG) family proteins, causes cardiomyopathy and
myofibrillar myopathy that is characterized by myofibril and Z-disc disruption. However, the
detailed disease mechanism is not yet fully understood. Objective: bag3−/− mice exhibit
differences in the extent of muscle degeneration between muscle groups with muscles
experiencing the most usage degenerating at an accelerated rate. Usage-dependent …
Rationale:
A homozygous disruption or genetic mutation of the bag3 gene, a member of the Bcl-2–associated athanogene (BAG) family proteins, causes cardiomyopathy and myofibrillar myopathy that is characterized by myofibril and Z-disc disruption. However, the detailed disease mechanism is not yet fully understood.
Objective:
bag3−/− mice exhibit differences in the extent of muscle degeneration between muscle groups with muscles experiencing the most usage degenerating at an accelerated rate. Usage-dependent muscle degeneration suggests a role for BAG3 in supporting cytoskeletal connections between the Z-disc and myofibrils under mechanical stress. The mechanism by which myofibrillar structure is maintained under mechanical stress remains unclear. The purpose of the study is to clarify the detailed molecular mechanism of BAG3-mediated muscle maintenance under mechanical stress.
Methods and Results:
To address the question of whether bag3 gene knockdown induces myofibrillar disorganization caused by mechanical stress, in vitro mechanical stretch experiments using rat neonatal cardiomyocytes and a short hairpin RNA–mediated gene knockdown system of the bag3 gene were performed. As expected, mechanical stretch rapidly disrupts myofibril structures in bag3 knockdown cardiomyocytes. BAG3 regulates the structural stability of F-actin through the actin capping protein, CapZβ1, by promoting association between Hsc70 and CapZβ1. BAG3 facilitates the distribution of CapZβ1 to the proper location, and dysfunction of BAG3 induces CapZ ubiquitin–proteasome–mediated degradation. Inhibition of CapZβ1 function by overexpressing CapZβ2 increased myofibril vulnerability and fragmentation under mechanical stress. On the other hand, overexpression of CapZβ1 inhibits myofibrillar disruption in bag3 knockdown cells under mechanical stress. As a result, heart muscle isolated from bag3−/− mice exhibited myofibrillar degeneration and lost contractile activity after caffeine contraction.
Conclusions:
These results suggest novel roles for BAG3 and Hsc70 in stabilizing myofibril structure and inhibiting myofibrillar degeneration in response to mechanical stress. These proteins are possible targets for further research to identify therapies for myofibrillar myopathy or other degenerative diseases.
Am Heart Assoc