Hyperkalemic periodic paralysis (HyperKPP) is characterized by myotonic discharges that occur between episodic attacks of paralysis. Individuals with HyperKPP rarely suffer respiratory distress even though diaphragm muscle expresses the same defective Na(+) channel isoform (NaV1.4) that causes symptoms in limb muscles. We tested the hypothesis that the extent of the HyperKPP phenotype (low force generation and shift toward oxidative type I and IIA fibers) in muscle is a function of 1) the NaV1.4 channel content and 2) the Na(+) influx through the defective channels [i.e., the tetrodotoxin (TTX)-sensitive Na(+) influx]. We measured NaV1.4 channel protein content, TTX-sensitive Na(+) influx, force generation, and myosin isoform expression in four muscles from knock-in mice expressing a NaV1.4 isoform corresponding to the human M1592V mutant. The HyperKPP flexor digitorum brevis muscle showed no contractile abnormalities, which correlated well with its low NaV1.4 protein content and by far the lowest TTX-sensitive Na(+) influx. In contrast, diaphragm muscle expressing the HyperKPP mutant contained high levels of NaV1.4 protein and exhibited a TTX-sensitive Na(+) influx that was 22% higher compared with affected extensor digitorum longus (EDL) and soleus muscles. Surprisingly, despite this high burden of Na(+) influx, the contractility phenotype was very mild in mutant diaphragm compared with the robust abnormalities observed in EDL and soleus. This study provides evidence that HyperKPP phenotype does not depend solely on the NaV1.4 content or Na(+) influx and that the diaphragm does not depend solely on Na(+)-K(+) pumps to ameliorate the phenotype.
The mechanisms responsible for the onset and progressive worsening of episodic muscle stiffness and weakness in hyperkalemic periodic paralysis (HyperKPP) are not fully understood. Using a knock‐in HyperKPP mouse model harboring the M1592V NaV1.4 channel mutant, we interrogated changes in physiological defects during the first year, including tetrodotoxin‐sensitive Na+ influx, hindlimb electromyographic (EMG) activity and immobility, muscle weakness induced by elevated [K+]e, myofiber‐type composition, and myofiber damage. In situ EMG activity was greater in HyperKPP than wild‐type gastrocnemius, whereas spontaneous muscle contractions were observed in vitro. We suggest that both the greater EMG activity and spontaneous contractions are related to periods of hyperexcitability during which fibers generate action potentials by themselves in the absence of any stimulation and that these periods are the cause of the muscle stiffness reported by patients. HyperKPP muscles had a greater sensitivity to the K+‐induced force depression than wild‐type muscles. So, an increased interstitial K+ concentration locally near subsets of myofibers as a result of the hyperexcitability likely produced partial loss of force rather than complete paralysis. NaV1.4 channel protein content reached adult level by 3 weeks postnatal in both wild type and HyperKPP and apparent symptoms did not worsen after the first month of age suggesting (i) that the phenotypic behavior of M1592V HyperKPP muscles results from defective function of mutant NaV1.4 channels rather than other changes in protein expression after the first month and (ii) that the lag in onset during the first decade and the progression of human HyperKPP symptoms during adolescence are a function of NaV1.4 channel content.
The single point mutation M1592V on the human skeletal muscle sodium channel, NaV1.4, causes Hyperkalemic Periodic Paralysis (HyperKPP). HyperKPP is associated with greater sodium influx and sensitivity to the potassium depressing effect on force. The objective of this study was to determine if introducing a missense substitution corresponding to a human familial HyperKPP mutation (Met1592Val) into the mouse gene (mice(+/M1592V)) encoding the skeletal muscle voltage‐gated Na+ channel NaV1.4 also results in greater sodium flux and potassium sensitivity. EDL and soleus muscles were exposed to either 4.7 mM (control) or 9–10 mM K+ while measuring either 22Na+ uptake or peak tetanic force. 22Na+ uptake was 3‐times greater in EDL and soleus muscles of mice(+/M1592V) when compared to the uptake in wild type muscles. The drop in peak tetanic force at 9–10 mM was much greater in EDL and soleus muscles of mice(+/M1592V) than in wild type muscles. Furthermore, adding 1–2 nM TTX, to partially block sodium channels, caused a decrease in peak tetanic force in wild type muscles but produced an increase in force in EDL and soleus muscles of mice(+/M1592V). However, the peak tetanic force of muscle(+/M1592V) in the presence of TTX was still less than that observed in wild type muscles. We conclude that the introduction of the M1592V mutation in the mouse genome increases sodium influx and the K+ sensitivity of skeletal muscle as observed in human suffering of HyperKPP. However, partially blocking Na+ channels with TTX failed to return the force back to the level observed in wild type muscles, which suggests that an increased intracellular sodium also contributes to the reduced force.
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