The ACTN3 gene encodes for the α-actinin-3 protein, which has an important structural function in the Z line of the sarcomere in fast muscle fibers. A premature stop codon (R577X) polymorphism in the ACTN3 gene causes a complete loss of the protein in XX homozygotes. This study investigates a possible role for the α-actinin-3 protein in protecting the fast fiber from eccentric damage and studies repair mechanisms after a single eccentric exercise bout. Nineteen healthy young men (10 XX, 9 RR) performed 4 series of 20 maximal eccentric knee extensions with both legs. Blood (creatine kinase; CK) and muscle biopsy samples were taken to study differential expression of several anabolic (MyoD1, myogenin, MRF4, Myf5, IGF-1), catabolic (myostatin, MAFbx, and MURF-1), and contraction-induced muscle damage marker genes [cysteine- and glycine-rich protein 3 (CSRP3), CARP, HSP70, and IL-6] as well as a calcineurin signaling pathway marker (RCAN1). Baseline mRNA content of CSRP3 and MyoD1 was 49 ± 12 and 67 ± 25% higher in the XX compared with the RR group ( P = 0.01–0.045). However, satellite cell number was not different between XX and RR individuals. After eccentric exercise, XX individuals tended to have higher serum CK activity ( P = 0.10) and had higher pain scores than RR individuals. However, CSRP3 ( P = 0.058) and MyoD1 ( P = 0.08) mRNA expression tended to be higher after training in RR individuals compared with XX α-actinin-3-deficient subjects. This study suggests a protective role of α-actinin-3 protein in muscle damage after eccentric training and an improved stress-sensor signaling, although effects are small.
The Role of the Innate and Adaptive Immunity in Exercise Induced Muscle Damage and Repair
