The large-conductance calcium-activated potassium channel holds the key to the conundrum of familial hypokalemic periodic paralysis.

PURPOSE: Familial hypokalemic periodic paralysis (HOKPP) is an autosomal dominant channelopathy characterized by episodic attacks of muscle weakness and hypokalemia. Mutations in the calcium channel gene, CACNA1S, or the sodium channel gene, SCN4A, have been found to be responsible for HOKPP; however, the mechanism that causes hypokalemia remains to be determined. The aim of this study was to improve the understanding of this mechanism by investigating the expression of calcium-activated potassium (KCa) channel genes in HOKPP patients. METHODS: We measured the intracellular calcium concentration with fura-2-acetoxymethyl ester in skeletal muscle cells of HOKPP patients and healthy individuals. We examined the mRNA and protein expression of KCa channel genes (KCNMA1, KCNN1, KCNN2, KCNN3, and KCNN4) in both cell types. RESULTS: Patient cells exhibited higher cytosolic calcium levels than normal cells. Quantitative reverse transcription polymerase chain reaction analysis showed that the mRNA levels of the KCa channel genes did not significantly differ between patient and normal cells. However, western blot analysis showed that protein levels of the KCNMA1 gene, which encodes KCa1.1 channels (also called big potassium channels), were significantly lower in the membrane fraction and higher in the cytosolic fraction of patient cells than normal cells. When patient cells were exposed to 50 mM potassium buffer, which was used to induce depolarization, the altered subcellular distribution of BK channels remained unchanged. CONCLUSION: These findings suggest a novel mechanism for the development of hypokalemia and paralysis in HOKPP and demonstrate a connection between disease-associated mutations in calcium/sodium channels and pathogenic changes in nonmutant potassium channels.

Altered levels of α-synuclein and sphingolipids in Batten disease lymphoblast cells.

Batten disease (juvenile neuronal ceroid lipofuscinosis) is a neurodegenerative disorder characterized by blindness, seizures, cognitive decline, and early death due to the inherited mutation of the CLN3 gene. Although α-synuclein and sphingolipids are relevant for the pathogenesis of some neuronal disorders, little attention has been paid to their role in Batten disease. To identify the molecular factors linked to autophagy and apoptotic cell death in Batten disease, the levels of α-synuclein, sphingomyelin, and gangliosides were examined. We observed enhanced levels of α-synuclein oligomers and gangliosides GM1, GM2, and GM3 and reduced levels of sphingomyelin and autophagy in Batten disease lymphoblast cells compared with normal lymphoblast cells, possibly resulting in a higher rate of apoptosis typically found in Batten disease lymphoblast cells.

Batten disease is linked to altered expression of mitochondria-related metabolic molecules.

Batten disease (BD)--also known as juvenile neuronal ceroid lipofuscinoses-is an inherited neurodegenerative disorder caused by CLN3 gene mutations. Although CLN3-related oxidative and mitochondrial stresses have been studied in BD, the pathologic mechanism of the disease is not clearly understood. To address the molecular factors linked to high levels of oxidative stress in BD, we examined the expression of mitochondria-related metabolic molecules, including pyruvate dehydrogenase (PDH), ATP citrate lyase (ACL), and phosphoenolpyruvate carboxykinase (PEPCK), as well as the apoptosis-related ganglioside, acetyl-GD3. We observed an increased expression of PDH and a decreased expression of ACL, PEPCK, and acetyl-GD3 in BD lymphoblast cells compared to normal cells, possibly resulting in the high ROS levels, mitochondrial membrane depolarization, and apoptosis typically found in BD.

Cell cycle arrest in Batten disease lymphoblast cells.

Batten disease is an inherited neurodegenerative disorder caused by a CLN3 gene mutation. Batten disease is characterized by blindness, seizures, cognitive decline, and early death. Although apoptotic cell death is one of the pathological hallmarks of Batten disease, little is known about the regulatory mechanism of apoptosis in this disease. Since the CLN3 gene is suggested to be involved in the cell cycle in a yeast model, we investigated the cell cycle profile and its regulatory factors in lymphoblast cells from Batten disease patients. We found G1/G0 cell cycle arrest in Batten disease cells, with overexpression of p21, sphingosine, glucosylceramide, and sulfatide as possible cell cycle regulators.

Possible therapeutic effects of myxobacterial metabolites on type I Gaucher disease.

Gaucher disease (GD) is the most prevalent lysosomal storage disorder caused by an inherited deficiency of glucocerebrosidase. In the present study, we aimed to determine whether myxobacterial metabolites exhibit a potential therapeutic effect in the cells from a patient with type I GD. We screened 288 bioactive compounds of myxobacteria in the skin fibroblasts from a patient with type I GD. MTT assays were performed to determine their effects on cell viability. The expression levels of Bcl-2-associated X protein (Bax), ATP-citrate synthase (ATP-CS), E3-binding protein (E3BP), and acetyl-coenzyme A acetyltransferase 1 (ACAT1) were determined by western blotting to understand the molecular mechanisms of myxobacterial metabolites in cells. Thin-layer chromatography (TLC) was carried out to measure changes in glucosylceramide levels in the cultured fibroblasts. This screening process identified 4 compounds that increased cell viability more than 1.45 times. After exposure to these compounds, the expression level of Bax decreased, whereas those of ATP-CS, E3BP, and ACAT1 increased. TLC revealed reduced amounts of intracellular glucosylceramides in patient cells. Here we suggest that myxobacterial metabolites can relieve the stress due to glucosylceramide accumulation, and that it may be utilized as a new therapeutic approach.