Surface plasmon resonance biosensor method for palytoxin detection based on Na+,K+-ATPase affinity

Surface plasmon resonance biosensor method for palytoxin detection based on Na+,K+-ATPase affinity

Palytoxin (PLTX), produced by dinoflagellates from the genus Ostreopsis was first discovered, isolated, and purified from zoanthids belonging to the genus Palythoa. The detection of this toxin in contaminated shellfish is essential for human health preservation. A broad range of studies indicate tha...

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Bibliographic Details
Published in:Toxins Vol. 6; no. 1; pp. 96 - 107
Main Authors: Alfonso, Amparo, Pazos, María-José, Fernández-Araujo, Andrea, Tobio, Araceli, Alfonso, Carmen, Vieytes, Mercedes R, Botana, Luis M
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 27-12-2013
MDPI
Subjects:
Acrylamides - analysis
Animals
Biosensing Techniques - methods
Biosensors
Dinoflagellida - metabolism
Dogs
Kidney - metabolism
Marine Toxins - analysis
Models, Animal
Na+,K+-ATPase
Open channels
Ostreopsis
Ostreopsis siamensis
Palythoa
palytoxin
Resonance
Shellfish
Shellfish - analysis
Sodium-Potassium-Exchanging ATPase - metabolism
Surface Plasmon Resonance - methods
surface plasmon resonance biosensor
Toxins
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Summary:Palytoxin (PLTX), produced by dinoflagellates from the genus Ostreopsis was first discovered, isolated, and purified from zoanthids belonging to the genus Palythoa. The detection of this toxin in contaminated shellfish is essential for human health preservation. A broad range of studies indicate that mammalian Na+,K+-ATPase is a high affinity cellular receptor for PLTX. The toxin converts the pump into an open channel that stimulates sodium influx and potassium efflux. In this work we develop a detection method for PLTX based on its binding to the Na+,K+-ATPase. The method was developed by using the phenomenon of surface plasmon resonance (SPR) to monitor biomolecular reactions. This technique does not require any labeling of components. The interaction of PLTX over immobilized Na+,K+-ATPase is quantified by injecting different concentrations of toxin in the biosensor and checking the binding rate constant (Kobs). From the representation of Kobs versus PLTX concentration, the kinetic equilibrium dissociation constant (K(D)) for the PLTX-Na+,K+-ATPase association can be calculated. The value of this constant is K(D) = 6.38 × 10-7 ± 6.67 × 10-8 M PLTX. In this way the PLTX-Na+,K+-ATPase association was used as a suitable method for determination of the toxin concentration in a sample. This method represents a new and useful approach to easily detect the presence of PLTX-like compounds in marine products using the mechanism of action of these toxins and in this way reduce the use of other more expensive and animal based methods.
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ISSN:2072-6651
2072-6651
DOI:10.3390/toxins6010096