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Plumbagin-induced ultrastructural haemocytic response of Dysdercus koenigii F.

Published online by Cambridge University Press:  19 September 2011

K. Tikku
Affiliation:
Division of Insect Physiology, Regional Research Laboratory, Jarnmu 180 001, India
Bhaskar P. Saxena*
Affiliation:
Division of Insect Physiology, Regional Research Laboratory, Jarnmu 180 001, India
N. K. Satti
Affiliation:
Division of Natural Products Chemistry
K. A. Suri
Affiliation:
Division of Natural Products Chemistry
*
* To whom correspondence should be addressed.
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Abstract

The phytochemical ptumbagin, isolated from Plumbago zeylanica L., was applied in 2 and 5 μl doses of 0.1% concentration on the surface of Dysdercus koenigii F. adults and its effect on the haemocytes of the bug, studied by transmission electron microscopy. All the five haemocyte types viz. the prohaemocyte, plasmatocyte, granular haemocyte, oenocytoid, and the adipohaemocyte are affected within a period of 24–48 hr. The effect begins with an acute state of vacuolization of the cells and a gradual destruction of the organelles, followed by dissolution of the plasma membrane and passing out of the internal organelles, like the mitochondria and the endoplasmic reticulum. This phenomenon is responsible for a consistent elimination of the haemocytes from the blood, leading to lowering of the resistance and mortality of the insects.

Résumé

La substance phytochimique plumbagin, extraite de Plumbago zeylanica L. a été appliquée à des doses de 2 et 5 microlitres dans une concentration de 0.1% sur des adultes de Dysdercus koenigii F.; et ses effets sur les hémocytes de la punaise sont observés au microscope électronique à transmission. Tous les cinq types, hemocytes, prohémocytes, plasmatocytes, granulocytes, oenocytoides et adipohémocytes sont affectés en l'espace de 24–48 heures. L'effet commence par un état de vacuolisation sévère des cellules et une destruction graduelles des organelles suivies par la dissolution de la membrane plasmique et celle des organelles internes telles que les mitochondries et le reticulum endoplasmique. Ce phénomène est responsable de l'hémolyse avec pour résultats l'abaissement de la résistance de l'insecte suivi de sa mort.

Type
Research Articles
Copyright
Copyright © ICIPE 1992

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References

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