Contractile properties, fiber types, and myosin isoforms in fast and slow muscles of hyperactive Japanese waltzing mice.

This study focuses on the effects of neuromuscular hyperactivity on the contractile properties, fiber type composition, and myosin heavy chain (MHC) isoform expression of fast-twitch extensor digitorum longus (EDL) and slow-twitch soleus (SOL) muscles in Japanese waltzing mice (JWM) of the C57BL/6J-v2J strain. The same properties were studied in the homologous muscle of control CBA/J mice (CM). In comparison to CM, the JWM exhibited (i) longer activity periods, prolonged bouts of running and a higher food intake, (ii) slower twitch and tetanic contractions of both EDL and SOL muscles, decreased cold and post-tetanic potentiation of the EDL, as well as increased cold and post-tetanic depressions of the SOL. Electrophoretic analyses of MHC isoform revealed a shift toward slower isoforms in both EDL and SOL muscles of JWM as compared to the homologous muscles of CM, namely, a shift from the fastest MHCIIb to the MHCIId/x isoform in the EDL muscle and a shift from MHCIIa to MHCI in the SOL muscle. The latter also contained a higher percentage of type I fibers and displayed a higher capillary density than the SOL muscle of CM. These findings show that the inherently enhanced motor activity of the JWM leads to fiber type transitions in the direction of slower phenotypes. JWM thus represent a suitable model for studying fast-to-slow fiber transitions under the influence of spontaneous motor hyperactivity.

Activation-induced resetting of cerebral metabolism and flow is abolished by beta-adrenergic blockade with propranolol.

BACKGROUND AND PURPOSE: It has previously been shown that activation will increase cerebral blood flow (CBF) and cerebral glucose uptake (CMR(glc)) in excess of cerebral oxygen uptake (CMRO(2)). Our purpose was to investigate the influence of beta-adrenergic blockade with propranolol on the activation-induced uncoupling of cerebral glucose and oxygen metabolism. METHODS: Using awake rats, we determined the cerebral arteriovenous differences of oxygen [(a-v)(O2)], glucose [(a-v)(glc)], and lactate [(a-v)(lac)] both under baseline conditions and during activation. The molar ratio between CMRO(2) and CMR(glc), the oxygen-glucose index (OGI), was calculated. RESULTS: Without beta-adrenergic blockade, activation decreased the (a-v)(O2) but not the (a-v)(glc), reducing the OGI from 6.1 during baseline conditions to 4.0 under activation (P<0.01). The (a-v)(O2) decreased, indicating that the ratio CBF/CMRO(2) had increased. Under baseline conditions, a slight flux of lactate from the brain was observed. Activation increased the arterial lactate concentration, and during this condition, the lactate flux from the brain was reversed into a slight lactate uptake. Propranolol administration did not change the behavior of the animals during activation. After administration of propranolol, baseline values were unaffected, but beta-adrenergic blockade totally abolished the activation-induced uncoupling of (a-v)(O2) from (a-v)(glc), because both remained constant with an unchanged OGI. The unchanged (a-v)(O2) indicates that CBF remained unchanged compared with CMRO(2). CONCLUSIONS: beta-Adrenergic blockade by propranolol abolishes the activation-induced uncoupling of cerebral oxygen to glucose metabolism and the changes in (a-v)(O2). This may be of most significance to studies of cerebral activation by the blood oxygen level-dependent fMRI method.