Bioluminescent biosensors useful for monitoring and/or quantifying, in vitro or in vivo, activity of the Hippo signaling pathway. The biosensors monitor LATS kinase activity or YAP-TEAD interaction. The biosensors may be used in methods for monitoring and/or quantifying in real-time, in vitro or in vivo, activity of the Hippo signaling pathway, wherein the activity may be LATS kinase activity and/or YAP-TEAD interaction. The biosensors may be provided in kits for monitoring and/or quantifying in real-time, in vitro or in vivo, activity of the Hippo signaling pathway, wherein the activity may be LATS kinase activity and/or YAP-TEAD interaction.

The present invention concerns a nucleic acid molecule capable of expressing, in at least one plant tissue, a chimeric protein comprising a polygalacturonase (PG) of fungal, bacterial or insect origin and a plant polygalacturonase inhibitor protein (PGIP) plant capable of inhibiting said PG. The present invention also relates to transgenic plants that express said chimeric protein.

The invention relates to chitin, a hydrolysate and a method for the production of at least one desired product from insects. More specifically, the invention relates to a method for the production of chitin and/or chitosan from insect cuticles, comprising a step in which insect cuticles are treated with an oxidising agent, followed by a step involving the enzymatic hydrolysis of the insect cuticles using a proteolytic enzyme.

The invention provides compositions and methods for preventing and treating infection by Plasmodium sporozoites.

Described herein are expression vectors encoding the Wolbachia protein WalE1. Also described are insects transformed with an expression vector of the present disclosure, and progeny thereof. Also described are methods for improving Wolbachia replication and transmission in its insect host by overexpressing WalE1 in the insect host. Improved Wolbachia replication and transmission provides for insect population control and pathogen resistance in insects, which can reduce disease transmission.

Computational systems and methods are described for identifying new α-helical antimicrobial peptides using a systemic consensus formula. Newly identified α-helical antimicrobial peptides are tested experimentally and show potent microbiocidal activities.

This document relates to materials and methods for the production of protein. For example, proteins having a low flavor or low color profile and food products comprising the same.

Insect control nanobodies are provided. Accordingly there is provided a nanobody which specifically binds to an insect polypeptide selected from the group consisting of: a polypeptide comprising a chitin binding domain (CBD), V-ATPase subunit c, trehalase, cytochrome p450 monooxygenase, chitin deacetylase, chitin synthase and NPC1 sterol transporter, wherein binding of the nanobody to the insect polypeptide confers an insect control activity to the nanobody. Also provided are polynucleotides encoding the nanobody, host cells expressing the nanobody and methods of using it.

Provided are a novel polypeptide having endolysin activity, a fusion protein comprising the polypeptide and an antibiotic active protein, and an antibiotic use against a gram-negative pathogen of the polypeptide and/or fusion protein and/or a use for prevention and/or treatment of gram-negative pathogen infection and/or disease or symptoms related to gram negative pathogen infection.

The disclosure relates to insecticidal toxin resistance management and screening of novel insecticidal toxins. One embodiment relates to the isolation, characterization, compositions, and methods of use relating to polynucleotides encoding novel insecticidal toxin receptors and the polypeptides encoded thereby. The polynucleotides and polypeptides are useful in identifying or designing novel insecticidal toxin receptor ligands including novel insecticidal toxins.