Investigation of the role of insulin receptor genes in wing polyphenism using gene knockdown and differential gene expression analysis in the non-model organism Gerris buenoi

Iggström, Sofia

January 2019

Wing polyphenism is a type of phenotypic plasticity present in several insect species whereby a genotype have the ability to develop alternative wing morphs when exposed to different environmental cues. One organism demonstrating a clear case of wing polyphenism is the water strider species, Gerris buenoi, which develop long- or short wings depending on exposure to different photoperiods (the time the organism is exposed to light during a 24 h period). The molecular mechanism behind wing polyphenism in insects in general, and in water striders in particular, is largely unknown. From a study on wing polyphenism in the Brown planthopper (Nilaparvata lugens), some candidate genes have been identified and include two insulin receptor genes and the Forkhead transcription factor (FOXO). Since these genes have been demonstrated to affect wing polyphenism in Brown planthopper (BPH) and since G. buenoi contains an additional insulin receptor homolog, the potential role of these genes in regulating wing polyphenism in G. buenoi have in this project been investigated. The functional genetic technique RNA interference (RNAi) was used to evaluate the function of the genes. This method knock down gene expression in the genes mentioned above, one at a time, to investigate if they have a function in wing polyphenism in G. buenoi. DsRNA with specific homology to each target gene was successfully produced. However, when attempting to inject the dsRNA through micro injection all injected liquid leaked out from the body cavity, and the RNAi was therefore not successful. Further optimisation of the injection protocol has to be done to be able to perform RNAi properly in the future. Thereafter, RT-qPCR was used to evaluate whether the insulin receptor genes and FOXO are differentially expressed between the two photoperiods giving rise to the different wing morphs. The differential gene expression experiment showed differences between the mRNA levels of all target genes between G. buenoi being reared in the two different photoperiods. More specific upregulation of the genes FOXO and insulin receptor 2 in short winged G. buenoi were demonstrated. Further, insulin receptor 1-like, was also demonstrated to be upregulated in the short winged morph. Results presented in this project are in line with the previously identified regulation pattern in BPH, still the results need further evaluation. Since gene expression differences were present for all candidate genes between G. buenoi reared in the different photoperiods, theses genes could still be seen as potential candidate genes in wing polyphenism in water striders.

Phenotypic plasticity

RNAi

RT-qPCR

wing polyphenism

water striders

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Evolutionary Biology

Evolutionsbiologi

The Role of Juvenile Hormone and Ecdysone in Wing Morph Determination in the Wing Polyphenic Water Strider, Gerris buenoi

Nielsen, Kevin

January 2021

In this laboratory study, the role of juvenile hormone (JH) and ecdysone in regulating wing polyphenism was investigated in the non-model organism Gerris buenoi. Topical application of the JH analog methoprene elicited reduced pronotum, wing defects, and nymphal-adult intermediates but no changes to wing morph. Similarly, while microinjection of the ecdysone derivative 20-hydroxyecdysone (20E) elicited aberrant phenotypes there was again no influence on the wing morph. Using data from a transcriptomics experiment, RNAi knockdown of the differentially expressed 20E induced receptor gene, Hr4, caused high mortality rates (> 90 %) which resulted in a sample size too small to draw any inferences of Hr4’s involvement in G. buenoi wing polyphenism. My results indicate that both JH and ecdysone are involved in several developmental processes including wing development, but they do not seem to be important for determining wing polyphenism. However, several factors are important to consider in future research which means that the potential role of JH and ecdysone in G. buenoi wing polyphenism should not be dismissed at this stage.

Wing polyphenism

Phenotypic plasticity

Water striders

Gerris buenoi

Ecdysone

Juvenile hormone

RNAi

Biological Sciences

Biologiska vetenskaper

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Genetics

Genetik

Developing a protocol for RT-qPCR of wing-tissue gene expression and investigating the dynamics of photoperiodically induced polyphenism in the water strider Gerris buenoi

Andersson, Elin

January 2023

Wing polyphenism in insects is a type of phenotypic plasticity where environmental factors trigger the development of a set of discrete wing morphologies. In the water strider Gerris buenoi, photoperiods are the main environmental cue that trigger wing morph determination. The genetic mechanisms connecting environmental cues and the determination of wing morph in G. buenoi are not clear. However, recent experimental work suggests that engagement of the Hippo pathway via ecdysone signalling is a promising model for further investigation. In this study, a reverse-transcription quantitative PCR (RT-qPCR) protocol was developed, aimed at elucidating this potential transduction pathway by quantifying gene expression of Fat, Dachsous, Yorkie, EcR, E75 and E74. This was done using melt curve analysis, gel electrophoresis, sequencing of RT-qPCR products and qPCR standard curves. Additionally, wing morph distribution in extreme and intermediate photoperiods were examined. Wing morph proportions were significantly different between adults emerging in the intermediate photoperiods 15.30:8.30 and 15:9 (hours light : hours dark). An effect of sex was observed, with a higher probability of males becoming long-winged compared to females. This has likely evolved as a result of a dispersal-reproduction trade-off. Taken together, this study provided insight for future investigations of periodically induced wing morph determination and its genetic mechanisms in G. buenoi that will contribute to the understanding of phenotypic plasticity.

wing polyphenism

polyphenism

phenotypic plasticity

RT-qPCR

water strider

Gerris buenoi

Natural Sciences

Naturvetenskap

Biological Sciences

Biologiska vetenskaper

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Ecology

Ekologi

Genetics

Genetik

Evolutionary Biology

Evolutionsbiologi

Cell Biology

Cellbiologi