AdE-1, a new inotropic Na(+) channel toxin from Aiptasia diaphana, is similar to, yet distinct from, known anemone Na(+) channel toxins.

Heart failure is one of the most prevalent causes of death in the western world. Sea anemone contains a myriad of short peptide neurotoxins affecting many pharmacological targets, several of which possess cardiotonic activity. In the present study we describe the isolation and characterization of AdE-1 (ion channel modifier), a novel cardiotonic peptide from the sea anemone Aiptasia diaphana, which differs from other cnidarian toxins. Although AdE-1 has the same cysteine residue arrangement as sea anemone type 1 and 2 Na(+) channel toxins, its sequence contains many substitutions in conserved and essential sites and its overall homology to other toxins identified to date is low (<36%). Physiologically, AdE-1 increases the amplitude of cardiomyocyte contraction and slows the late phase of the twitch relaxation velocity with no induction of spontaneous twitching. It increases action potential duration of cardiomyocytes with no effect on its threshold and on the cell's resting potential. Similar to other sea anemone Na(+) channel toxins such as Av2 (Anemonia viridis toxin II), AdE-1 markedly inhibits Na(+) current inactivation with no significant effect on current activation, suggesting a similar mechanism of action. However, its effects on twitch relaxation velocity, action potential amplitude and on the time to peak suggest that this novel toxin affects cardiomyocyte function via a more complex mechanism. Additionally, Av2's characteristic delayed and early after-depolarizations were not observed. Despite its structural differences, AdE-1 physiologic effectiveness is comparable with Av2 with a similar ED(50) value to blowfly larvae. This finding raises questions regarding the extent of the universality of structure-function in sea anemone Na(+) channel toxins.

Calcium-induced exocytosis from actomyosin-driven, motile varicosities formed by dynamic clusters of organelles.

Varicosities are ubiquitous neuronal structures that appear as local swellings along neurites of invertebrate and vertebrate neurons. Surprisingly little is known about their cell biology. We use here cultured Aplysia neurons and demonstrate that varicosities are motile compartments that contain large clusters of organelles. The content of varicosities propagate along neurites within the plasma membrane "sleeve", split and merge, or wobble in place. Confocal imaging, retrospective immunolabeling, electron microscopy and pharmacological perturbations reveal that the motility of the varicosities' organelle content occurs in concert with an actin scaffold and is generated by actomyosin motors. Despite the motility of these organelle clusters within the cytoplasm along the neurites, elevation of the free intracellular calcium concentration within varicosities by trains of action potentials induces exocytosis followed by membrane retrieval. Our observations demonstrate that varicosities formed in the absence of postsynaptic cells behave as "ready to go" prefabricated presynaptic terminals. We suggest that the varicosities' motility serves to increase the probability of encountering a postsynaptic cell and to rapidly form a functional synapse.

Effect of colchicine and cytokines on MEFV expression and C5a inhibitor activity in human primary fibroblast cultures.

BACKGROUND: Familial Mediterranean fever is an autosomal recessive disease characterized by sporadic attacks of inflammation affecting the serosal spaces. The gene associated with FMF (MEFV), mainly expressed in neutrophils, was recently found to be expressed also in primary cultures of serosal origin (peritoneal and synovial fibroblasts). A C5a inhibitor, previously detected in normal serosal fluids, was recently identified in serosal cultures as well, and was found to be deficient in serosal fluids and cultures obtained from FMF patients. OBJECTIVE: To investigate the effect of colchicine (the main therapeutic agent for FMF patients) and certain inflammatory cytokines (IL-1 beta, TNF-alpha, IFN-alpha, IFN-gamma) on MEFV expression and C5a inhibitor activity in neutrophils and primary peritoneal fibroblast cultures. METHODS: Human primary peritoneal fibroblast cultures and neutrophils were studied for MEFV expression and C5a inhibitor activity, using reverse transcription-polymerase chain reaction and C5a-induced myeloperoxidase assay, respectively, in the presence and absence of colchicine and cytokines. RESULTS: MEFV expression in neutrophils was high and could not be induced further. Its expression in the peritoneal fibroblasts was lower than in neutrophils and could be induced using colchicine and cytokines parallel with induction of C5a inhibitor activity. Semi-quantitative RT-PCR assays enabled estimation of MEFV induction by the cytokines at 10-100-fold and could not be further increased by concomitant addition of colchicine. CONCLUSION: Serosal tissues, which are afflicted in FMF, express colchicine and cytokine-inducible MEFV and contain inducible C5a inhibitor activity. The relation between the ability of colchicine to induce MEFV and C5a inhibitor activity, and its efficacy in FMF treatment, require further investigation.

Mutations in NPHS2 encoding podocin are a prevalent cause of steroid-resistant nephrotic syndrome among Israeli-Arab children.

Steroid-resistant nephrotic syndrome (SRNS) represents a heterogeneous group of kidney disorders that are often resistant to other immunosuppressive agents and tend to progress to end-stage renal failure. Mutations in the gene NPHS2 that encode a protein named podocin have recently been found in a recessive form of SRNS. Ten children from two inbred families of Israeli-Arab descent presented with SRNS. Renal histologic findings were of diffuse mesangial proliferation. Six patients reached end-stage renal failure, but nephrotic syndrome did not recur after renal transplantation. Mutation analysis of NPHS2 revealed that they were homozygous for the C412T mutation (R138X). Eighteen children were subsequently analyzed with SRNS due to biopsy-proven focal segmental glomerulosclerosis (FSGS) from unrelated families of Israeli-Arab descent. Analysis disclosed six additional patients (33%) bearing the same mutation in a homozygous pattern. Three of them had no affected relatives, although they came from large families. Taken together, of the 27 patients tested (familial and nonfamilial), 15 patients (55%) were homozygous for the mutation (R138X). They all shared the same haplotype and were homozygous for the A1023G polymorphism, thus pointing to a possible founder effect. Thirteen children of Israeli-Jewish origin with SRNS and biopsy-proven FSGS and 15 children of both ethnic groups with steroid-responsive FSGS were tested, and none was found to have mutations in NPHS2. The results of this study demonstrate that mutations in NPHS2 are a common cause of SRNS in Israeli-Arab children. Mutations in NPHS2 may cause SRNS in nonfamilial cases. The interethnic differences in the occurrence of NPHS2 mutations may explain, in part, the previous observation that Arab patients with FSGS in Israel have a worse prognosis as compared with Jewish patients, despite similar presenting symptoms and medical management. Identifying the causing mutation will enable clinicians to avoid unnecessary immunosuppressive therapeutic trials in newly diagnosed patients and to provide prenatal diagnosis to families at risk.