Dodecanol, metabolite of entomopathogenic fungus Conidiobolus coronatus, affects fatty acid composition and cellular immunity of Galleria mellonella and Calliphora vicina.

One group of promising pest control agents are the entomopathogenic fungi; one such example is Conidiobolus coronatus, which produces a range of metabolites. Our present findings reveal for the first time that C. coronatus also produces dodecanol, a compound widely used to make surfactants and pharmaceuticals, and enhance flavors in food. The main aim of the study was to determine the influence of dodecanol on insect defense systems, i.e. cuticular lipid composition and the condition of insect immunocompetent cells; hence, its effect was examined in detail on two species differing in susceptibility to fungal infection: Galleria mellonella and Calliphora vicina. Dodecanol treatment elicited significant quantitative and qualitative differences in cuticular free fatty acid (FFA) profiles between the species, based on gas chromatography analysis with mass spectrometry (GC/MS), and had a negative effect on G. mellonella and C. vicina hemocytes and a Sf9 cell line in vitro: after 48 h, almost all the cells were completely disintegrated. The metabolite had a negative effect on the insect defense system, suggesting that it could play an important role during C. coronatus infection. Its high insecticidal activity and lack of toxicity towards vertebrates suggest it could be an effective insecticide.

Genome-wide study of saprotrophy-related genes in the basal fungus Conidiobolus heterosporus.

Conidiobolus spp. are important saprophytic basal fungi. However, to date, no genomic-level data for decaying plant materials in the genus Conidiobolus has been reported. Here, we report that the 33.4-Mb genome of Conidiobolus heterosporus encodes 10,857 predicted genes. Conidiobolus heterosporus harbors 394 CAZyme-encoding genes belonging to 4 major modules but does not encode a polysaccharide lyase (PL). Many carbohydrate esterases (CEs) belonging to the family CE12 play crucial roles as pectin acetylesterases, and 14 genes were upregulated in the IM (fungus grown on inducing medium) among 17 expressed CE12 family genes. In addition, most of the genes in the GH132 CAZyme family showed a greater than 5-fold increase in expression in the IM compared with that in the wild type. Furthermore, 122 P450-encoding genes grouped into 11 families were detected in the fungal genome, most of which belonged to the CYP547 family (36 genes) followed by CYP548 (27 genes) and CYP5856 (25 genes). Interestingly, members of the families CYP5014 and CYP5136 were identified, the first time such enzymes have been described in a fungus. Our findings provide new insights into the genomics and genomic features of the saprophytic basal fungus C. heterosporus.Key Points• Genome of the saprobiotic basal fungus C. heterosporus was sequenced and analyzed.• 394 CAZymes but no PL family genes were found and expression levels were determined.• CE12 and GH132 proteins may play roles in the pectin and plant material degradation.• A large number of P450s but few P450 families existed in the fungus.

Biotechnological Production of Methyl-Branched Aldehydes.

A number of methyl-branched aldehydes impart interesting flavor impressions, and especially 12-methyltridecanal is a highly sought after flavoring compound for savory foods. Its smell is reminiscent of cooked meat and tallow. For the biotechnological production of 12-methyltridecanal, the literature was screened for fungi forming iso-fatty acids. Suitable organisms were identified and successfully grown in submerged cultures. The culture medium was optimized to increase the yields of branched fatty acids. A recombinant carboxylic acid reductase was used to reduce 12-methyltridecanoic acid to 12-methyltridecanal. The efficiency of whole-cell catalysis was compared to that of the purified enzyme preparation. After lipase-catalyzed hydrolysis of the fungal lipid extracts, the released fatty acids were converted to the corresponding aldehydes, including 12-methyltridecanal and 12-methyltetradecanal.

Saprotrophy of Conidiobolus and Basidiobolus in leaf litter.

This study of the putative saprotrophs of Conidiobolus and Basidiobolus aids the understanding of their ecological roles in litter, and their relationship with the entomogenous fungi of the Entomophthorales. A total of 47 isolates (ten spp.) were screened for their ability to utilise pure compounds, arthropod cadavers, and plant leaf fragments as substrates. Isolates co-occurred in a larch plantation (Larix sp.) or were from adjacent habitats. Of the 21 isolates (nine spp.) tested on potential prime carbon sources, none could utilise common plant structural polymers. Conidiobolus adiaeretus, C. iuxtagenitus, and B. ranarum from litter and some soil isolates of C. heterosporus, C. pumilus, and C. firmipilleus could use starches and glycogen. In marked contrast, all could utilise animal chitin, gelatine, casein, N-acetyl glucosamine, and trehalose. The lipids tributyrin and sunflower oil also supported growth. Conidia on cadavers usually led to high levels of colonisation as was the case for 30 isolates (ten species). Collembola were more frequently and rapidly colonised than mites. Cadavers of many other arthropods were also internally colonised. The ability to utilise cadavers of diverse arthropods indicates that trophic competition between co-occurring test species may be minimal. Niche differentiation may depend more on non-trophic features of their life history. Negative correlation of performance with the presence of naturally occurring, non-test fungi suggests competition with (or antibiosis from) at least some of the other fungi. In washed or unwashed plant fragments of larch litter (F-layer) only occasional local growth and resting spore formation occurred. Extra nutrients did not facilitate colonisation. Alternative forms of repetitional conidia showed a strong association with plant fragments but not with cadavers.