Fatty acids derived from oviposition systems guide female black soldier flies (Hermetia illucens) toward egg deposition sites.

The black soldier fly, Hermetia illucens, comes with big promises for industrial purposes since its larvae feed polyphagously on a broad spectrum of organic substrates. However, research focusing on adult flies is scarce, which is inconsistent with their reproductive relevance within the rearing cycle. In particular, directed oviposition is a challenge in artificial systems. Currently, decomposing organic matter is commonly used as oviposition substrate, which has extensive potential for improvement in view of the lack of standardization and the risk of microbial contamination. Here, we identified three fatty acids and one fatty acid methyl ester derived from the surface of old oviposition sites and targeted to elucidate their effect on preference behavior and oviposition site selection using Y-olfactometry and prepared oviposition sites, respectively. Exposure to tetradecanoic acid attracted gravid females and stimulated oviposition most strongly, while decanoic acid demonstrated a repulsive effect. Females kept in mixed-sex populations were attracted by tetradecanoic acid, resulting in a higher egg mass found in the compound box (3.0-11.4 fold), a ≥ 2.3 fold reduction of nonspecifically deposited eggs, and the highest total egg mass. Conversely, decanoic and dodecanoic acid caused females to lay a greater proportion of eggs nonspecifically outside both boxes. Our data suggest that fatty acids, especially tetradecanoic acid, are important cues for oviposition site selection in black soldier flies. In order to achieve a directed oviposition behavior, the role of further short- and long-chain fatty acids as attractants should be examined.

Effect of bacterial volatiles on the mycelial growth of mushrooms.

Bacteria play an important role in the life cycle of fungi by influencing positively or negatively morphological features, mycelial growth and/or fruiting body induction. However, little is known about the underlying mechanisms and their species-dependence, especially among fungi of the phylum Basidiomycota. Hence, we analyzed the effects of seven bacterial isolates, that were previously obtained from Pleurotus ostreatus HK35, on the mycelial growth of P. ostreatus HK35, Pleurotus eryngii DSMZ 8264, Pleurotus sapidus DSMZ 8266, Pleurotus citrinopileatus DSMZ 5341, Cyclocybe aegerita AAE-3, Lentinula edodes CBS 389.89 and Kuehneromyces mutabilis DSMZ 1013 during eight days. Notably, the bacterial isolates only showed significant mycelial growth-promoting effects when co-cultivated on Petri dishes with Pleurotus species, except for P. citrinopileatus. In particular, Paenibacillus peoriae strain M48F induced remarkably the mycelial growth in P. ostreatus (∼47 %), P. eryngii (∼32 %) and P. sapidus (∼27 %) during the early cultivation stages, but with ongoing cultivation this strain inhibited the growth of all fungi. To investigate the impact of bacterial volatile organic compounds (VOCs) on the mycelial growth, P. ostreatus and P. eryngii were co-cultivated with the bacteria on bi-plates. No growth inhibition on bi-plates was observed while bacterial isolates and mycelia were separated by a physical barrier, assuring that late mycelial growth inhibition was not caused by bacterial volatile compounds. VOCs from strain M48F induced the strongest growth of P. ostreatus (∼50 %) and P. eryngii (∼20 %) mycelia compared to controls. Furthermore, we analyzed the VOCs of strain M48F alone and in combination with P. ostreatus, P. eryngii, P. sapidus and L. edodes using bi-plates and SPME-GC-MS. Strain M48F triggered the formation of ß-bisabolene when co-cultivated with P. ostreatus or P. eryngii, which may indicate a fungal defense reaction. Additionally, 2,5-diisopropylpyrazine dominated the volatilome of strain M48F on all eight sampling days. In samples of strain M48F, alone and co-cultivated with L. edodes, the amount of 2,5-diisopropylpyrazine remained quite constant. In contrast, the quantity of this substance declined substantially in co-cultures with P. ostreatus. Interestingly, 2,5-diisopropylpyrazine enhanced P. ostreatus mycelial growth significantly although the growth-promoting effect was not as pronounced as during co-cultivation with strain M48F. Our results show that the mycelial growth-promoting effects of bacteria are remarkably species-dependent, and that bacterial VOCs such as 2,5-diisopropylpyrazine can enhance mycelial growth.