Vitellogenin RNAi Halts Ovarian Growth and Diverts Reproductive Proteins and Lipids in Young Grasshoppers

Reduced reproduction extends lifespan of females in many animals. To test the effects of reproduction on storage of macronutrients, we block reproductive output in the lubber grasshopper by injecting RNAi against the precursor to egg-yolk protein, vitellogenin, in early adulthood. Controls were inje...

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Bibliographic Details
Published in:Integrative and comparative biology 2014-11, Vol.54 (5), p.931-941
Main Authors: Tokar, Derek R., Veleta, Katherine A., Canzano, Joseph, Hahn, Daniel A., Hatle, John D.
Format: Article
Language:English
Subjects:
Amino Acids - metabolism
Animal reproduction
Animals
Biochemistry
Cockroaches
Fat Body - growth & development
Fat Body - metabolism
Female
Gene Knockdown Techniques
Grasshoppers - genetics
Grasshoppers - growth & development
Grasshoppers - physiology
Hemolymph - metabolism
Insect Proteins - genetics
Insect Proteins - metabolism
Insects
Lipid Metabolism
Lipids
Molecular Sequence Data
Nymph - genetics
Nymph - growth & development
Nymph - physiology
Ovary - growth & development
Ovary - metabolism
Real-Time Polymerase Chain Reaction
RNA Interference
RNA, Messenger - genetics
RNA, Messenger - metabolism
RNA-protein interactions
Sequence Analysis, DNA
The Micro and Macro of Nutrient Effects in Animal Physiology and Ecology
Vitellogenins - genetics
Vitellogenins - metabolism
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Summary:Reduced reproduction extends lifespan of females in many animals. To test the effects of reproduction on storage of macronutrients, we block reproductive output in the lubber grasshopper by injecting RNAi against the precursor to egg-yolk protein, vitellogenin, in early adulthood. Controls were injected with either buffer or RNAi against the major storage protein in the hemolymph, hexamerin-90. Vitellogenin RNAi greatly reduced both levels of mRNA for vitellogenin and ovarian growth, in comparison to both controls. Fat body mass was increased upon vitellogenin RNAi, but concentrations of the three hexameric storage proteins from the hemolymph were not. Surprisingly, hemolymph vitellogenin levels were increased upon vitellogenin RNAi. Total reproductive protein (hemolymph vitellogenin plus ovarian vitellin) was unchanged by vitellogenin RNAi, as reproductive protein was diverted to the hemolymph. Similarly, the increased lipid storage upon vitellogenin RNAi was largely attributable to the reduction in lipid in the ovary, due to decreased ovarian growth. A BLAST search revealed that the 515 bp sequence of vitellogenin used for RNAi had three 11 bp regions identical to the vitellogenin receptor of the cockroach Leucophaea maderae. This suggests that our treatment, in addition to reducing levels of vitellogenin transcript, may have also blocked transport of vitellogenin from the hemolymph to the ovary. This would be consistent with halted ovarian growth simultaneous with high levels of vitellogenin in the hemolymph. Nonetheless, the accumulation of vitellogenin, instead of hexameric storage proteins, is inconsistent with a simple model of the trade-off between reproduction and storage. This was observed in young females; future studies will address whether investment of proteins may shift to the soma as individuals age. Overall, our results suggest that blockage of reproduction in young grasshoppers redirects lipids to storage and reproductive proteins to the hemolymph.
ISSN:1540-7063
1557-7023
DOI:10.1093/icb/icu068