Activity, Motor Control & Coordination
Pain - Thermal Allodynia / Hyperalgesia
Pain - Spontaneous Pain - Postural Deficit
Pain - Mechanical Allodynia / Hyperalgesia
Anxiety & Depression Disorder
Learning/Memory - Attention - Addiction
Physiology & Respiratory Research
Metabolism - Food & Drink Intake
Pain
Central Nervous System (CNS)
Neurodegeneration
Sensory system
Motor control
Mood Disorders
Other disorders
Muscular system
Joints
Metabolism
Cross-disciplinary subjects
SFN2024: Meet our team in Chicago on booth #876 Authors
P Pathak, Y Blech-Hermoni, K Subedi ET AL
Lab
Neurogenetics Branch, National Institute of Neurological Disorders and Stroke, Bethesda, MD, USA
Journal
Communications Biology
Abstract
Mechanical stress induced by contractions constantly threatens the integrity of muscle Z[1]disc, a crucial force-bearing structure in striated muscle. The PDZ-LIM proteins have been proposed to function as adaptors in transducing mechanical signals to preserve the Z-disc structure, however the underlying mechanisms remain poorly understood. Here, we show that LDB3, a well-characterized striated muscle PDZ-LIM protein, modulates mechanical stress signaling through interactions with the mechanosensing domain in filamin C, its chaperone HSPA8, and PKC_ in the Z-disc of skeletal muscle. Studies of Ldb3Ala165Val/+ mice indicate that the myopathy-associated LDB3 p.Ala165Val mutation triggers early aggregation of filamin C and its chaperones at muscle Z-disc before aggregation of the mutant protein. The mutation causes protein aggregation and eventually Z-disc myofibrillar disruption by impairing PKCalpha and TSC2-mTOR, two important signaling pathways regulating protein sta[1]bility and disposal of damaged cytoskeletal components at a major mechanosensor hub in the Z-disc of skeletal muscle.
BIOSEB Instruments Used:
Grip strength test (BIO-GS3)
