Life Cycle of the Heterotrophic Dinoflagellate Pfiesteria Piscicida (Dinophyceae)1

Litaker, R. Wayne; Vandersea, Mark W.; Kibler, Steven R.; Madden, Victoria J.; Noga, Edward J.; Tester, Patricia A.

doi:10.1046/j.1529-8817.2002.t01-1-01242.x

Cited by 72 publications

(54 citation statements)

References 41 publications

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“…These proteins also run the risk of being obscured by the autofluorescence and could potentially be indiscernible when viewed in conjunction with background autofluorescence. Excitation of fluorescent molecules and autofluorescent molecules that differ in their emission maxima, by using dual filters, could be a solution (Litaker et al 2002). This method could, however, still be influenced by the extent of autofluorescence, therefore making the choice of fluorescent molecule very complex.…”

Section: Discussionmentioning

confidence: 98%

Investigation of the Autofluorescence of Various Abalone (Haliotis midae) Tissues and the Implications for Future use of Fluorescent Molecules

Sandenbergh

Roodt‐Wilding

2012

Journal of Shellfish Research

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Fluorescent molecules have revolutionized the field of molecular biology and biotechnology, and could be of benefit to research conducted on economically important haliotid species (abalone) for applications such as protein analysis, cell metabolism studies, fluorescence resonance energy transfer, cell imaging, and reporter genes for gene transfer. Many marine organisms exhibit autofluorescence; therefore, this raises the question whether autofluorescence also occurs in abalone and whether it could hinder fluorescence studies. We examined ova, sperm, larvae, juveniles, and hemocyte cell cultures of the southern African abalone (Haliotis midae Linnaeus, 1758) and established that ova, larvae, and juveniles exhibited autofluorescence at most wavelengths tested, especially in the mid-wavelength range of the visible spectrum. Autofluorescence was particularly prominent at the same wavelengths as that of green fluorescent proteins. Therefore, we caution studies using fluorescent molecules with emissions in the mid-wavelength range and suggest the use of molecules with emissions at the extremes of the light spectra.

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Section: Discussionmentioning

confidence: 98%

Investigation of the Autofluorescence of Various Abalone (Haliotis midae) Tissues and the Implications for Future use of Fluorescent Molecules

Sandenbergh

Roodt‐Wilding

2012

Journal of Shellfish Research

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“…Cyanobacteria and microscopic eukaryotes were identified using classical taxonomic keys and previous works [20–23]. Phytoplankton counts (cells, colonies, and coenobia) were performed using the Utermöhl's sedimentation method [24].…”

Section: Methodsmentioning

confidence: 99%

Plankton Microorganisms Coinciding with Two Consecutive Mass Fish Kills in a Newly Reconstructed Lake

Oikonomou

Katsiapi

Karayanni

et al. 2012

The Scientific World Journal

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Lake Karla, Greece, was dried up in 1962 and its refilling started in 2009. We examined the Cyanobacteria and unicellular eukaryotes found during two fish kill incidents, in March and April 2010, in order to detect possible causative agents. Both microscopic and molecular (16S/18S rRNA gene diversity) identification were applied. Potentially toxic Cyanobacteria included representatives of thePlanktothrixandAnabaenagroups. Known toxic eukaryotes or parasites related to fish kill events werePrymnesium parvumandPfiesteriacf.piscicida, the latter being reported in an inland lake for the second time. Other potentially harmful microorganisms, for fish and other aquatic life, included representatives of Fungi, Mesomycetozoa, Alveolata, and Heterokontophyta (stramenopiles). In addition, Euglenophyta, Chlorophyta, and diatoms were represented by species indicative of hypertrophic conditions. The pioneers of L. Karla’s plankton during the first months of its water refilling process included species that could cause the two observed fish kill events.

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“…As originally described (1, 3), P. piscicida allegedly had up to 24 life-cycle stages. Using a variety of techniques, Litaker et al have challenged this assertion (52). Using species-specific hybridization probes, no evidence could be found for a chrysophyte-like cyst stage or the amoeba stages originally proposed.…”

Section: Fig 2 Gel (2% Agarose)mentioning

confidence: 97%

Are Pfiesteria species toxicogenic? Evidence against production of ichthyotoxins by Pfiesteria shumwayae

Berry

Reece

Rein

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

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The estuarine genus Pfiesteria has received considerable attention since it was first identified and proposed to be the causative agent of fish kills along the mid-Atlantic coast in 1992. The presumption has been that the mechanism of fish death is by release of one or more toxins by the dinoflagellate. In this report, we challenge the notion that Pfiesteria species produce ichthyotoxins. Specifically, we show that (i) simple centrifugation, with and without ultrasonication, is sufficient to ''detoxify'' water of actively fish-killing cultures of Pfiesteria shumwayae, (ii) organic extracts of lyophilized cultures are not toxic to fish, (iii) degenerate primers that amplify PKS genes from several polyketide-producing dinoflagellates failed to yield a product with P. shumwayae DNA or cDNA, and (iv) degenerate primers for NRPS genes failed to amplify any NRPS genes but (unexpectedly) yielded a band (among several) that corresponded to known or putative PKSs and fatty acid synthases. We conclude that P. shumwayae is able to kill fish by means other than releasing a toxin into bulk water. Alternative explanations of the effects attributed to Pfiesteria are suggested.

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Life Cycle of the Heterotrophic Dinoflagellate Pfiesteria Piscicida (Dinophyceae)1

Cited by 72 publications

References 41 publications

Investigation of the Autofluorescence of Various Abalone (Haliotis midae) Tissues and the Implications for Future use of Fluorescent Molecules

Investigation of the Autofluorescence of Various Abalone (Haliotis midae) Tissues and the Implications for Future use of Fluorescent Molecules

Plankton Microorganisms Coinciding with Two Consecutive Mass Fish Kills in a Newly Reconstructed Lake

Are Pfiesteria species toxicogenic? Evidence against production of ichthyotoxins by Pfiesteria shumwayae

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