Abstract
A glutamate-to-lysine substitution at position 1014 within the selectivity filter of the skeletal muscle L-type Ca2+ channel (CaV1.1) abolishes Ca2+ flux through the channel pore. Mice engineered to exclusively express the mutant channel display accelerated muscle fatigue, changes in muscle composition, and altered metabolism relative to wildtype littermates. By contrast, mice expressing another mutant CaV1.1 channel that is impermeable to Ca2+ (CaV1.1 N617D) have shown no detectable phenotypic differences from wildtype mice to date. The major biophysical difference between the CaV1.1 E1014K and CaV1.1 N617D mutants elucidated thus far is that the former channel conducts robust Na+ and Cs+ currents in patch-clamp experiments, but neither of these monovalent conductances seems to be of relevance in vivo Thus, the basis for the different phenotypes of these mutants has remained enigmatic. We now show that CaV1.1 E1014K readily conducts 1,4-dihydropyridine-sensitive K+ currents at depolarizing test potentials, whereas CaV1.1 N617D does not. Our observations, coupled with a large body of work by others regarding the role of K+ accumulation in muscle fatigue, raise the possibility that the introduction of an additional K+ flux from the myoplasm into the transverse-tubule lumen accelerates the onset of fatigue and precipitates the metabolic changes observed in CaV1.1 E1014K muscle. These results, highlighting an unexpected consequence of a channel mutation, may help define the complex mechanisms underlying skeletal muscle fatigue and related dysfunctions.
Highlights
During excitation– contraction (EC)2 coupling in skeletal muscle, the L-type Ca2ϩ channel (CaV1.1 or 1,4-dihydropyridine receptor) activates Ca2ϩ release from the sarcoplasmic reticulum via the type 1 ryanodine receptor in response to depolarization of the plasma membrane [1,2,3]
The amplitude of myoplasmic Ca2ϩ release evoked by low-frequency stimulation (LFS; 1 Hz) was virtually identical in flexor digitorum brevis (FDB) fibers obtained from wildtype and homozygous CaV1.1 E1014K mice, CaV1.1 E1014K FDB fibers displayed a pronounced fatigue phenotype because the amplitudes of successive Ca2ϩ transients decayed more rapidly than in wildtype fibers during high-frequency stimulation (HFS; 50 or 100 Hz)
We first examined whether the CaV1.1 E1014K mutant could be functionally expressed in tsA-201 cells with similar biophysical properties as previously reported for CaV1.1 E1014K expressed in dysgenic myotubes
Summary
We first examined whether the CaV1.1 E1014K mutant could be functionally expressed in tsA-201 cells with similar biophysical properties as previously reported for CaV1.1 E1014K expressed in dysgenic myotubes. Because YFP-CaV1.1 N617D displayed slightly larger charge movement than YFP-CaV1.1 or YFP-CaV1.1 E1014K (p Ͼ 0.05, one way-ANOVA; Fig. S1), the lack of Kϩ current in cells expressing CaV1.1 N617D could not be attributed to fewer channels present in the membrane. Under these conditions, YFP-CaV1.1 produced L-type currents similar in amplitude and voltage dependence to the experiments shown in Fig. 1 in which Csϩ was used as the predominant intracellular monovalent cation (Fig. 3, C and D). To determine whether the outward Kϩ current is sensitive to inhibition by DHP antago-
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