Project name: Bemisia tabaci isolate:MEAM1 Ashalim

Description: Although generalist insect herbivores can migrate and rapidly adapt to a broad range of host plants, they can face significant difficulties when accidentally migrating to novel and marginally-suitable hosts. What happens, at both the performance and transcriptional levels, if these marginally-suitable hosts must be used for multiple generations before migration to a suitable host can take place, largely remains unknown. Using the whitefly Bemisia tabaci, a generalist phloem-feeding species, we established a multi-generational experimental setup that allowed us to explore the evolved differences between two populations that were subjected to cotton (a suitable host) and habanero-pepper (a marginally-suitable host) on which the initial survival is 5%. We used reciprocal host tests to estimate the differences in performance of the populations on both hosts under optimal (30 oC) and mild-stressful (24 oC) temperature conditions, and documented the associated transcriptomic changes. The habanero-pepper adapted population greatly improved its performance on habanero-pepper but did not reach its performance level on cotton, the original host. It also showed reduced performance on cotton, relative to the non-adapted population, and an antagonistic effect of the lower-temperature stressor. The transcriptomic data revealed that most of the expression changes, associated with long-term adaptation to habanero-pepper, can be categorized as "evolved" with no initial plastic response. Three molecular functions dominated: enhanced formation of cuticle structural constituents, enhanced activity of oxidation-reduction processes involved in neutralization of phytotoxins and reduced production of proteins from the cathepsin B family. The molecular regulatory mechanism/s that putatively control these distinct transcriptional changes are discussed.

Data type: transcriptome

Sample scope: Multiisolate

Relevance: Evolution

Last updated: 2021-04-15