Marine brevetoxin induces IgE-independent mast cell activation.

Brevetoxins (PbTx) are sodium channel neurotoxins produced by the marine dinoflagellate Karenia brevis during red tide blooms. Inhalation of PbTx in normal individuals and individuals with pre-existing airways disease results in adverse airway symptoms including bronchoconstriction. In animal models of allergic inflammation, inhalation of PbTx results in a histamine H₁-mediated bronchoconstriction suggestive of mast cell activation.

Brevetoxin 2 alters expression of apoptotic, DNA damage, and cytokine genes in Jurkat cells.

Brevetoxins are potent neurotoxins that exert their toxicity through activation of voltage-gated sodium channels. Exposure to brevetoxins cause severe respiratory inflammation in marine mammals and humans. Brevetoxin activation of voltage-gated sodium channels on immune cells can lead to several biological responses including cell proliferation, gene transcription, cytokine production and even apoptosis.

Brevetoxins 2, 3, 6, and 9 show variability in potency and cause significant induction of DNA damage and apoptosis in Jurkat E6-1 cells.

Brevetoxins (PbTx) are potent lipid soluble polyether neurotoxins produced by the marine dinoflagellate Karenia brevis, an organism linked to periodic red tide blooms. Brevetoxins exert their toxicity by interacting with neurotoxin receptor site five associated with domain IV of the alpha subunit of the voltage gated sodium channel. Brevetoxin binding to tissues that contain voltage gated sodium channels on excitable cells results in membrane depolarization, repetitive firing, and increase in sodium currents.

Effects of storage, RNA extraction, genechip type, and donor sex on gene expression profiling of human whole blood.

Background: Gene expression profiling of whole blood may be useful for monitoring toxicological exposure and for diagnosis and monitoring of various diseases. Several methods are available that can be used to transport, store, and extract RNA from whole blood, but it is not clear which procedures alter results. In addition, characterization of interindividual and sex-based variation in gene expression is needed to understand sources and extent of variability.

Metabolism of myclobutanil and triadimefon by human and rat cytochrome P450 enzymes and liver microsomes.

Metabolism of two triazole-containing antifungal azoles was studied using expressed human and rat cytochrome P450s (CYP) and liver microsomes. Substrate depletion methods were used due to the complex array of metabolites produced from myclobutanil and triadimefon. Myclobutanil was metabolized more rapidly than triadimefon, which is consistent with metabolism of the n-butyl side-chain in the former and the t-butyl group in the latter compound.