Larval development of a parasitoid depends on host ecdysteroids.

Parasitoids often exhibit high flexibility in their development depending on stages of their host at the parasitism, yet little is known about the mechanism underlying such flexibility. In the study, we evaluated the larval development time of the parasitoid Exorista sorbillans (Diptera: Tachinidae) on the lepidopteran model insect Bombyx mori (Lepidoptera: Bombycidae). We found that the development duration of E. sorbillans larvae parasitizing on the late-developmental silkworms was significantly shorter than that of the larvae parasitizing on the early-developmental hosts. Intriguingly, the 2nd-3rd instar molting of parasitoid always occurred when the ecdysteroid titers in the host were increased to higher levels. Furthermore, inhibiting the release of ecdysteroids to parasitic abdomen by thorax-abdomen ligation of the host only repressed the 2nd-instar growth and molting of E. sorbillans larvae, but had no effect on their pupation. Meanwhile, the ecdysone synthesis and 20-hydroxyecdysone (20 E) signaling in larval parasitoids were impeded after ligation treatment. Moreover, exogenous 20 E application could largely rescue the defect in 2nd instar growth and molting through stimulating ecdysone synthesis and signaling in E. sorbillans. Our results indicate that the parasitoid requires the host ecdysteroids to stimulate 20 E signaling and the subsequent 2nd-instar growth and molting. These findings will improve our understanding of the host utilization strategies of parasitoids, and contribute to the development of in vitro rearing procedures of tachinid parasitoids for biological control.

Construction of chitosan-derived porous nest-like C/SnO2 materials for microwave absorption.

Electromagnetic waves have an irreplaceable role as information carriers in civil and radar stealth fields, but they also lead to electromagnetic pollution and electromagnetic leakage. Therefore, electromagnetic wave absorbing materials that can reduce electromagnetic radiation have come into being. Especially, SnO2 has made a wave among many wave-absorbing materials as an easily tunable dielectric material, but it hardly has both broadband and powerful absorption properties. Here, the nested porous C/SnO2 composites derived from nitrogen-doped chitosan is obtained by freeze-drying and supplemented with carbonization treatment. The chitosan creates a nested cross-linked conductive network that can make part of the contribution to conduction loss. The amino groups contained in the molecule either help promote in situ nitrogen doping and trigger dipole polarization. The multiphase dissimilar interface between the nested carbon layer and the inner clad SnO2 formation is the major inducer of interfacial polarization. It reached intense absorption of -48.8 dB and bandwidth of 5.2 GHz at 3.46 mm. The interfacial polarization is confirmed to be the main force of dielectric loss by simulating the electromagnetic field distribution. In addition, the RCS simulation data assure the prospect of enticing applications of C/SnO2 composites in the field of radar stealth.