Abstract
Sucking insects require a surface of plants on which the legs and the eggs of insects will adhere and to which insect mouthparts will access. The primary plant protection against insects is their surface property, which hinders the attachment of the insect’s legs and eggs. The epicuticular waxes chemistry influences the fine structure of the cuticular surface. In current study, an attempt was made to investigate the variation of chemical compounds in epicuticular waxes of four cotton species that classify them resistant or susceptible i.e., Gossypium abroreum, G. hirsutum, G. arboreum wax deficient mutant (GaWM3) and G. harknessi which were evaluated for their interaction with whitefly and CLCuV transmission. Gossypium hirsutum an insect and CLCuV susceptible cotton variety, was found to have four compounds namely Trichloroacetic acid, hexadecylester, P-xylenolpthalein, 2-cyclopentene-1-ol, 1-phenyl-and Phenol, 2,5-bis [1,1- dimethyl] which could interact with chitin of whitefly while only two compounds in Gossypium arboreum an insect and CLCuV resistant cotton variety could interact with chitin of whitefly. Similarly, GaWM3 and Gossypium harkasnessi were found to have only a single compound. Number of whiteflies found on leaves of G. hirsutum was much higher as compared to other cotton species. Keeping this fact in mind a wax biosynthetic gene CER3, from Arabidopsis thaliana was transformed into G. hirsutum and the plants were evaluated for their resistance against whitefly and CLCuV transmission. In microscopic analysis transgenic plants clearly showed higher amounts of leaf waxes as compared to non-transgenics. The least whitefly population and CLCuV titer of <10,000 units was found in transgenic plants compared to non-transgenic cotton where it was ≈4.5X106 units that confirmed the role of wax in insect interaction and ultimately to CLCuV transmission. This study provides novel insight on wax related compounds involved in cotton-whitefly interaction, which potentially can help in developing more efficient control strategies for this destructive pest.
Highlights
The first zone to which approaching insects come in contact with plant is the plant cuticular surface
Cotton species Gossypium abroreum, G. hirsutum, G. arboreum wax deficient mutant (GaWM3) and G. harknessi were subjected to isolation of wax compounds by following the method mentioned below
Comparative alignment of identified wax compounds of cotton species These compounds were aligned using PyMOL software version 2.3 which revealed a different structure for each genotype
Summary
The first zone to which approaching insects come in contact with plant is the plant cuticular surface. The testing of wax mutants along with genotype of plant species having different wax composition and chemistry are used to determine the influence of plant surface characteristics on insects and fungus attachment has been largely employed and still need to be done on a large scale [4]. The leaf waxes have been investigated by using the decoction method of wax extraction in which plants leaves are briefly immerged in organic solvent this organic solvent is evaporated to concentrate the waxes [5]. For this experiment, Chloroform–methanol extraction method for wax extraction was used as reported by [6]. Modern biochemistry techniques like Gas chromatography-Mass spectrometry are used to investigate the composition of extracted waxes [7]
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