Marine biotoxins are produced by aquatic microorganisms and accumulate in shellfish or finfish following the food web. These toxins usually reach human consumers by ingestion of contaminated seafood, although other exposure routes like inhalation or contact have also been reported and may cause serious illness. This review shows the current data regarding the symptoms of acute intoxication for several toxin classes, including paralytic toxins, amnesic toxins, ciguatoxins, brevetoxins, tetrodotoxins, diarrheic toxins, azaspiracids and palytoxins. The information available about chronic toxicity and relative potency of different analogs within a toxin class are also reported. The gaps of toxicological knowledge that should be studied to improve human health protection are discussed. In general, gathering of epidemiological data in humans, chronic toxicity studies and exploring relative potency by oral administration are critical to minimize human health risks related to these toxin classes in the near future.
Tetrodotoxin (TTX) is starting to appear in molluscs from the European waters and is a hazard to seafood consumers. This toxin blocks sodium channels resulting in neuromuscular paralysis and even death. As a part of the risk assessment process leading to a safe seafood level for TTX, oral toxicity data are required. In this study, a 4-level Up and Down Procedure was designed in order to determine for the first time the oral lethal dose 50 (LD50) and the No Observed Adverse Effect Level (NOAEL) in mice by using an accurate well-characterized TTX standard.
Azaspiracid-1 (AZA-1) is a marine toxin discovered 10 years ago. Since then, toxicologic studies have demonstrated that AZA-1 targets several organs in vivo, including the intestine, lymphoid tissues, lungs, and nervous system; however, the mechanism of action of AZA-1 remains unknown. Studies in vitro suggest that AZA-1 affects the actin cytoskeleton in nonadherent cells. We characterized the effects of AZA-1 on the cytoskeleton of adherent cells and on cell growth, an adhesion-dependent process in many cell types, and analyzed the structure dependency of this toxicity. Confocal and TIRF imaging of fluorescently labeled cytosketon showed that AZA-1 induced the rearrangement of stress fibers (actin filament bundles) and the loss of focal adhesion points in neuroblastoma and Caco-2 cells, without affecting the amount of polymerized actin. AZA-1 did not seem to alter the microtubule cytoskeleton, but it changed the cell shape and internal morphology observed by phase contrast imaging. Cell growth of lung carcinoma and neuroblastoma cells was inhibited by the toxin, as measured by a sulforhodamine B assay and BrdU incorporation to newly synthesized DNA. Fifteen different fragments and/or stereoisomers of AZA-1 were tested for cytoskeletal rearrangement and cell growth inhibition. Results showed that no fragment or stereoisomer had any activity, except for ABCD-epi-AZA-1, which conserved toxicity. AZA-1-induced reorganization of the actin cytoskeleton concurred with detachment and growth inhibition, three events that are probably related.
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