IgM-containing fraction suppressed voltage-gated potassium channels in acquired neuromyotonia.

OBJECTIVES: Acquired neuromyotonia (ANM) is an autoimmune disorder caused by antibodies to voltage-gated potassium channels (VGKC). Previously, we reported a patient with immunoglobulin M (IgM), instead of immunoglobulin G (IgG), anti-VGKC antibody. The purpose of this study was to determine the function of IgM-containing fraction in ANM patients. MATERIALS AND METHODS: We determined whether anti-VGKC antibodies in the IgG or IgM-containing fractions suppressed outward potassium current (OKC) using the patch clamp method in three patients with ANM. Whole sera from all patients suppressed OKCs. RESULT: Only the purified IgG, not the IgM-containing fractions from two patients suppressed VGKCs, whereas in a patient with IgM anti-VGKC antibody, only the IgM-containing fractions, not the IgG-containing fractions suppressed VGKCs. CONCLUSION: Anti-VGKC antibodies belonging to the IgM subclass should be determined in seronegative ANM patients.

Potassium current suppression in patients with peripheral nerve hyperexcitability.

Acquired neuromyotonia (Isaac's syndrome) is considered to be an autoimmune disease, and the pathomechanism of nerve hyperexcitability in this syndrome is correlated with anti-voltage-gated K(+) channel (VGKC) antibodies. The patch-clamp technique was used to investigate the effects of immunoglobulins from acquired neuromyotonia patients on VGKCs and voltage-gated Na(+) channels in a human neuroblastoma cell line (NB-1). K(+) currents were suppressed in cells that had been co-cultured with acquired neuromyotonia patients' immunoglobulin for 3 days but not for 1 day. The activation and inactivation kinetics of the outward K(+) currents were not altered by these immunoglobulins, nor did the immunoglobulins significantly affect the Na(+) currents. Myokymia or myokymic discharges, with peripheral nerve hyperexcitability, also occur in various neurological disorders such as Guillain-Barré syndrome and idiopathic generalized myokymia without pseudomyotonia. Immuno-globulins from patients with these diseases suppressed K(+) but not Na(+) currents. In addition, in hKv 1.1- and 1.6-transfected CHO (Chinese hamster ovary)-K1 cells, the expressed VGKCs were suppressed by sera from acquired neuromyotonia patients without a change in gating kinetics. Our findings indicate that nerve hyperexcitability is mainly associated with the suppression of voltage-gated K(+) currents with no change in gating kinetics, and that this suppression occurs not only in acquired neuromyotonia but also in Guillain-Barré syndrome and idiopathic generalized myokymia without pseudomyotonia.

[A case of pleuritis caused by strongyloides in a carrier of T-cell lymphoma virus type I (HTLV-I)].

A 73-year-old woman was admitted to our hospital complaining of dyspnea, fever and general edema. Chest roentgenogram showed bilateral pleural effusion and cardiomegaly. Cardiovascular examination demonstrated atrial tachycardia and left ventricle dysfunction, suggesting congestive heart failure. She was sero-positive for human T-cell lymphoma virus I (HTLV-I). The dyspnea and general edema improved after therapy for heart failure. Because the pleural effusion persisted after therapy, thoracentesis was performed. The pleural effusion was an exudate, and Strongyloides sterocoralis was detected by microscopy. Two courses of thiabendazole (1,500 mg/day, 3 days) were given orally. After this therapy, the pleural effusion improved markedly. This case suggests that Strongyloides stercoralis may be a causative agent of pleuritis in HTLV-I endemic areas.

Serum of Isaacs' syndrome suppresses potassium channels in PC-12 cell lines.

Blockage of K+ channels in nerve terminals by immunoglobulin is the speculated pathomechanism of Isaacs' syndrome. Using patch-clamp technique (whole-cell clamp), we investigated the effects on K+ current of serum taken from 2 patients with Isaacs' syndrome employing the clonal cell line PC-12. The addition of a patient's serum to the perfusion solution had little effect on the K+ current of P-12 cells. In contrast, K+ current was reduced by 25-80% when cells were cultured for 3-6 days with 2% serum as compared to control serum values. Suppression of the K+ current appears to develop gradually over the period of culture. Our results suggest that the pathomechanism of Isaacs' syndrome is caused by K+ channel suppression via a humoral factor(s) in the serum, which subsequently induces nerve hyperexcitability.