Can proinflammatory cytokine gene expression explain multifidus muscle fiber changes after an intervertebral disc lesion?

STUDY DESIGN: Longitudinal case-controlled animal study. OBJECTIVE: To investigate the effect of an intervertebral disc (IVD) lesion on the proportion of slow, fast, and intermediate muscle fiber types in the multifidus muscle in sheep, and whether muscle fiber changes were paralleled by local gene expression of the proinflammatory cytokines tumor necrosis factor α (TNF-α) and interleukin 1-ß. SUMMARY OF BACKGROUND DATA: Structure and behavior of the multifidus muscle change in acute and chronic back pain, but the mechanisms are surprisingly poorly understood and the link between structure and behavior is tenuous. Although changes in muscle fiber types have the potential to unify the observations, the effect of injury on muscle fiber distribution has not been adequately tested, and understanding of possible mechanisms is limited. METHODS: The L1-L2, L3-L4, and L5-L6 IVDs of 11 castrated male sheep received anterolateral lesions. Six control sheep underwent no surgical procedures. Multifidus muscle tissue was harvested at L4 for muscle fiber analysis using immunohistochemistry and L2 for cytokine analysis with polymerase chain reaction for local gene expression of TNF-α and interleukin-1ß. RESULTS: The proportion of slow muscle fibers in multifidus was significantly less in the lesioned animals both ipsilateral and contralateral to the IVD lesion. The greatest reduction in slow fibers was in the deep medial muscle region. A greater prevalence of intermediate fibers on the uninjured side implies a delayed fiber-type transformation on that side. TNF-α gene expression in multifidus was greater on both sides in the lesion animals than in the muscle of control animals. Interleukin-1ß was increased only on the injured side. CONCLUSION: These data provide evidence of muscle fiber changes after induction of an IVD lesion and a parallel increase in TNF-α expression. Proinflammatory cytokine changes provide a novel mechanism to explain behavioral and structural changes in multifidus. LEVEL OF EVIDENCE: N/A.

mRNA expression of fatty acid transporters in rainbow trout: in vivo and in vitro regulation by insulin, fasting and inflammation and infection mediators.

In the present study, we analyzed endocrine and nutritional regulation of fatty acid (FA) transporters mRNA expression fatty acid transport protein (FATP1) and fatty acid translocase (CD36) in rainbow trout in vivo and in adipocytes and myocytes in vitro. The expression of FATP1 increased with adipocyte and that of CD36 with myocyte in vitro differentiation suggesting a different role for each transporter during the two cell differentiation programs. Food deprivation (15, 25 and 35 days) increased FATP1 and CD36 mRNA expression in white muscle, red muscle and adipose tissue while insulin administration decreased the FATP1 expression in adipose tissue in vivo (21.6 pmol/g body mass) and in vitro (1 µM) in adipocytes. In trout myotubes insulin (1 µM) decreased FATP1 and increased CD36 mRNA expression. Thus, regulation of FA transporters expression by insulin is complex and directed to specific tissue needs. Although FATP1 and CD36 mRNA levels are controlled by insulin, it appears that FATP1 respond more clearly to situations of hyper and hypo-insulinemia in trout muscle and adipose tissue than CD36. FATP1 and CD36 transcription was also modulated by growth hormone in cultured myotubes and isolated adipocytes. Lipopolysaccharide administration (E. coli, serotype O26:B6, 6 µg/g body mass) decreased FATP1 mRNA expression in red muscle, adipose tissue and liver after 24h according to changes in lipid metabolism during infection. Tumor necrosis factor (TNFα) (100 ng/ml) reduced FATP1 expression in isolated adipocytes. Further, insulin (1µM) and IGF-I (100 nM) increased the FA uptake in rainbow trout myotubes through the PI3K/Akt signaling pathway. Overall, we demonstrated not only that feeding condition regulates FATP1 and CD36 mRNA expression in a tissue-specific manner, but also that insulin is an important regulator of these genes in vivo and in vitro and also it stimulates FA uptake in trout muscle cells.

Nonuniform distribution of myosin light chains within the thick filaments of lobster slow muscle: Immunocytochemical study.

The in situ distribution of the alpha and beta myosin light chains was investigated at the subsarcomeric and subfilament levels in individual fibers of the superficial flexor muscle (SFM) of the lobster, Homarus americanus. Polyclonal antibodies were produced against the two classes of myosin light chains and used for subsequent immunolocalization on thin sections of sarcomeres and on isolated filaments from both the medial and lateral fiber bundles of the SFM. The beta myosin light chains were uniformly distributed within the crossbridge region of sarcomeres of both medial and lateral bundles. The alpha myosin light chains were uniformly distributed within the crossbridge region of sarcomeres from the medial bundle, but were nonuniformly distributed over the crossbridge region of lateral bundle sarcomeres. In the latter, the number of alpha myosin light chains was highest toward the center of the thick filaments, diminishing towards the ends. Similar distributions of alpha light chains were found in isolated myosin filaments. These data demonstrate that heterogeneity in protein composition extends to the level of the myosin filament and suggest that the myosin filament substructure in lobster may be different than that found in vertebrate skeletal muscle.