Toxicity, transfer and depuration of anatoxin-a (cyanobacterial neurotoxin) in medaka fish exposed by single-dose gavage

Abstract: 9The proliferations of cyanobacteria are increasingly prevalent in warm and nutrient-enriched 10 waters and occur in many rivers and water bodies due especially to eutrophication. The aim of 11 this work is to study in female medaka fish the toxicity, the transfer and the depuration of the 12 anatoxin-a, a neurotoxin produced by benthic cyanobacterial biofilms. This work will provide 13 answers regarding acute toxicity induced by single gavage by anatoxin-a and to the risks of 14 exposure by ingestion of conta… Show more

“…Rainbow trout immersed in an unspecified enantiomeric mixture of 129-499 µg/L antx-a led to multiple abnormal behaviors after 5 min including irregular/erratic swimming, jaw spasms, air gulping, and difficulty in maintaining equilibrium, though these fish largely recovered by 3 h [32]. Japanese medaka fish exposed to (±) antx-a through oral gavage from 200 to 20,000 µg/kg showed immediate neurotoxic effects including altered opercular movement, abnormal swimming, and muscle rigidity [62]. Since antx-a producing cultures of cyanobacteria may contain other biologically active molecules, studies examining behavioral responses to cyanobacteria were not included in Table 1, but remain necessary to understand behavioral toxicity of antx-a-producing cyanobacterial blooms in aquatic systems [15,16,21,30,[63][64][65].…”

Differential influences of (±) anatoxin-a on photolocomotor behavior and gene transcription in larval zebrafish and fathead minnows

“…Rainbow trout immersed in an unspecified enantiomeric mixture of 129-499 µg/L antx-a led to multiple abnormal behaviors after 5 min including irregular/erratic swimming, jaw spasms, air gulping, and difficulty in maintaining equilibrium, though these fish largely recovered by 3 h [32]. Japanese medaka fish exposed to (±) antx-a through oral gavage from 200 to 20,000 µg/kg showed immediate neurotoxic effects including altered opercular movement, abnormal swimming, and muscle rigidity [62]. Since antx-a producing cultures of cyanobacteria may contain other biologically active molecules, studies examining behavioral responses to cyanobacteria were not included in Table 1, but remain necessary to understand behavioral toxicity of antx-a-producing cyanobacterial blooms in aquatic systems [15,16,21,30,[63][64][65].…”

Differential influences of (±) anatoxin-a on photolocomotor behavior and gene transcription in larval zebrafish and fathead minnows