Venus Kinase Receptors at the Crossroads of Insulin Signaling: Their Role in Reproduction for Helminths and Insects

Venus kinase receptors (VKRs) are invertebrate receptor tyrosine kinases (TKs) first discovered in the human parasite Schistosoma. They contain an extracellular Venus FlyTrap module similar to the ligand-binding domain of G protein-coupled receptors of class C and an intracellular TK domain similar to that of insulin receptors. VKRs are present from cnidarians to echinoderms. They were shown to be activated by amino-acids, to induce insulin-like intracellular pathways, and to be highly expressed in larvae and in gonads of helminths and insects. The function of VKR in gametogenesis was demonstrated in schistosomes by VKR silencing and recent studies in Aedes aegypti have confirmed the importance of VKR in mosquito egg formation. AaeVKR was shown to bind to ovary ecdysteroidogenic hormone and to activate the production of ecdysteroids by the ovary, independently of signaling mediated by insulin-like peptides. These new data confirm and specify the function of VKRs in the reproduction of helminths and insects and they open interesting perspectives for elucidating the role of VKRs in other models. VKR targeting would also provide opportunities for the control of parasites and various vector-borne infectious diseases.

Modelling of the human papillomavirus type 16 E5 protein

The product of the E5 oncogene in human papillomaviruses (HPVs) participates in cellular transformation. The sequences of E5 from high-risk HPV types are closely related, and the ability to transform is thought to be associated with their structure. Structural determination by standard biophysical methods has proved impossible due to the extreme hydrophobicity of the gene product. We have achieved limited solubility by dividing the sequence into three, structurally distinct domains. Synthetic peptides corresponding to these domains have been examined using circular dichroism (CD) spectroscopy, a method that can detect secondary structure elements in highly dilute protein solutions. Using data on the secondary structure content of these domains under different conditions and in systematic combination to detect constructive domain interactions, a model of HPV E5 structure and position in the membrane is proposed that is consistent with what is known of the larger family of leucine-rich repeat (LRR) proteins to which it belongs.