Genetic improvement of the nematicidal fungus Lecanicillium attenuatum against Heterodera glycines by expression of the Beauveria bassiana Cdep1 protease gene

Two novel entomopathogenic fungal species of Lecanicillium isolated from soil in China

The genus Lecanicillium was established in 2001 based on the type species Lecanicillium lecani (former, Verticillium lecani), which is an important entomopathogenic fungus. To date, more than thirty species in the genus have been reported, but much more are waiting to discover. In this study, two novel species isolated from soil in east China were identified. They differ from known closely related species primarily in sporulation structure, conidia and colony morphological characteristics, and sequence variations in the LSU, SSU, ITS, and TEF gene regions of the ribosomal DNA. Multigene phylogenetic analysis has provided strong molecular evidence supporting the classification of the strains, AH13B2 and JX15A210 within the genus Lecanicillium. The new species are formally named as follows: L. anqingense sp. nov. and L. renii sp. nov., respectively. Bioassays conducted on the greater wax moth, Galleria mellonella and crucifer aphid, Lipaphis erysimi showed that both fungal strains exhibit virulence. When treating with 1 × 108 spores/mL, the two strains gave mortality of > 60% and > 80% to G. mellonella and L. erysimi, respectively. Moreover, the median lethal times (LT50) of L. renii JX15A210 and L. anqingense AH13B2 against G. mellonella and L. erysimi were recorded as 8.06 d and 4.18 d, and 10.63 d and 5.07 d, respectively. This research enhances the species diversity within the genus Lecanicillium and provides valuable genetic resources for the biological control of pests and the development of biocontrol agents.

Harnessing Lecanicillium attenuatum: A novel strategy for combatting Nilaparvata lugens in rice fields

Nilaparvata lugens is a notorious rice pest causing significant annual yield and economic losses. The use of entomopathogenic fungi offers a promising and eco-friendly approach to sustainable pest management programs. However, research in this area is currently limited to a few specific types of insects and other arthropods. This study aimed to analyze the biocontrol potential of Lecanicillium attenuatum against N. lugens. Bioassays showed that L. attenuatum 3166 induced >80% mortality in N. lugens following 7 d exposure. Greenhouse and field investigations demonstrated that L. attenuatum 3166 application leads to a substantial reduction in N. lugens populations. Under greenhouse conditions, fluorescence was detected in GFP-labeled L. attenuatum 3166 hyphae enveloping the bodies of N. lugens. In field trials, L. attenuatum 3166 treatment exhibited a control efficacy of up to 68.94% at 14 d post-application, which was comparable to that of the commercial entomopathogenic fungal agent. Genomic sequencing of L. attenuatum 3166 revealed a comprehensive array of genes implicated in its infestation and lethality. Further, the transcriptome sequencing analysis highlighted the elevated expression levels of genes encoding proteases, chitinases, cutinases, and phospholipases. Our findings highlight the potential of L. attenuatum 3166 as an effective biological control agent against N. lugens.

Fungal insecticidal activity elevated by non-risky markerless overexpression of an endogenous cysteine-free protein gene in Beauveria bassiana

BACKGROUND

Fungal insecticides are notorious for slow kill action, an intrinsic trait that can be improved by the genetic engineering of an exogenous or endogenous virulence factor. However, transgenic insecticides expressing exogenous toxin and herbicide-resistant marker genes may cause unexpected ecological risks and are hardly permitted for field release due to strict regulatory hurdles. It is necessary to improve biotechnology that can speed up fungal insect-killing action and exclude ecological risk source.

RESULTS

A markerless transformation system of Beauveria bassiana, a main source of wide-spectrum fungal insecticides, was reconstructed based on the fungal uridine auxotrophy (Δura3). The system was applied for overexpression of the small cysteine-free protein (120 amino acids) gene cfp previously characterized as a regulator of the fungal virulence and gene expression. Three cfp-overexpressed strains showed much faster kill action to Galleria mellonella larvae than the parental wild-type via normal cuticle infection but no change in vegetative growth and aerial condition. The faster kill action was achieved due to not only significant increases in conidial adherence to insect cuticle and total activity of secreted cuticle-degrading Pr1 proteases and of antioxidant enzymes crucial for collapse of insect immune defense but acceleration of hemocoel localization, proliferation in vivo and host death from mummification.

CONCLUSION

The markerless system is free of any foreign DNA fragment as a source of ecologic risk and provides a novel biotechnological approach to enhancing fungal insecticidal activity with non-risky endogenous genes and striding over the regulatory hurdles. © 2022 Society of Chemical Industry.

Subtilisin-like Pr1 proteases marking the evolution of pathogenicity in a wide-spectrum insect-pathogenic fungus

Subtilisin-like Pr1 proteases of insect-pathogenic fungi are a large family of extracellular cuticle-degrading enzymes that presumably determine a capability of hyphal invasion into insect hemocoel through normal cuticle infection, but remain poorly understood although often considered as virulence factors for genetic improvement of fungal potential against pests. Here, we report that not all of 11 Pr1 family members necessarily function in Beauveria bassiana, an ancient wide-spectrum pathogen evolved insect pathogenicity ~200 million years ago. These Pr1 proteases are phylogenetically similar to or distinct from 11 homologues (Pr1A–K) early named in Metarhizium anisopliae complex, a young entomopathogen lineage undergoing molecular evolution toward Pr1 diversification, and hence renamed Pr1A1/A2, Pr1B1–B3, Pr1 C, Pr1F1–F4,4 and Pr1 G, respectively. Multiple analyses of all single gene-deleted and rescued mutants led to the recognition of five conserved members (Pr1C, Pr1G, Pr1A2, Pr1B1, and Pr1B2) contributing significantly to the fungal pathogenicity to insect. The conserved Pr1 proteases were proven to function only in cuticle degradation, individually contribute 19–29% to virulence, but play no role in post-infection cellular events critical for fungal killing action. Six other Pr1 proteases were not functional at all in either cuticle degradation during host infection or virulence-related cellular events post-infection. Therefore, only the five conserved proteases are collectively required for, and hence mark evolution of, insect pathogenicity in B. bassiana. These findings provide the first referable base for insight into the evolution of Pr1 family members in different lineages of fungal insect pathogens.

Extracellular peptidases of insect-associated fungi and their possible use in biological control programs and as pathogenicity markers

This review deals with characteristics of peptidases of fungi whose life cycles are associated with insects to varying degrees. The review examines the characteristic features of the extracellular peptidases of entomopathogenic fungi, the dependence of the specificity of these peptidases on the ecological characteristics of the fungi, and the role of peptidases in the development of the pathogenesis. Data on the properties and physiological role of hydrolytic enzymes of symbiotic fungi in "fungal gardens" are also considered in detail. For the development of representations about mechanisms of control over populations of insect pests, special attention is given to analysis of possibilities of genetic engineering for the creation of entomopathogens with enhanced virulence. Clarification of the role of fungi and their secreted enzymes and careful environmental studies are still required to explain their significance in the composition of the biota and to ensure widespread adoption of these organisms as effective biological control agents. The systematization and comparative analysis of the existing data on extracellular peptidases of insect-associated fungi will help in the planning of further work and the search for markers of pathogenesis and symbiosis.

Expression of spider toxin in entomopathogenic fungus Lecanicillium muscarium and selection of the strain showing efficient secretion of the recombinant protein

Beta/delta-agatoxin-1 of spider Agelena orientalis was expressed in entomopathogenic fungus Lecanicillium muscarium. To ensure secretion of the recombinant product by the fungus, the signal secretory peptide of the Metarhizium anisopliae Mcl1 protein was inserted into the sequence. For detection of the recombinant product and selection of transformants, the toxin sequence was also fused with eGFP at the C-terminus. The gene encoding the A. orientalis toxin with the Mcl1 protein signal peptide was commercially synthesized, amplified and cloned into the vector pBARGPE1 designed for heterologous expression under the control of the PgpdA promoter and the trpC terminator of Aspergillus nidulans. A double selection on selective medium and microscopic analysis of transformants allowed obtaining a mitotically stable recombinant strain of L. muscarium. The recognition of the Mcl1 derived signal peptide in the cells of transformants and effective secretion of the hybrid product was confirmed by immunoblotting.

Effects of a NTG-based chemical mutagenesis on the propamocarb-tolerance of the nematophagous fungus Lecanicillium attenuatum

Lecanicillium attenuatum is an important nematophagous fungus with potential as a biopesticide for control of plant-pathogenic nematodes. However, relatively low fungicide-tolerance limits its application in the field. To improve the propamocarb-tolerance of L. attenuatum, a NTG-based mutagenesis system was established. Among different combinations of NTG concentration and treatment time in the first-round NTG treatment, the treatment of 1.0mg/ml NTG for 60min gave a proper conidial lethality rate of 84.6% and the highest positive mutation rate of 7.7%, and then produced the highest propamocarb-tolerant mutant LA-C-R1-T4-M whose EC₅₀ value reached to 1050.0μg/ml. The positive mutation range was 105.1% in the first-round NTG treatment. Multiple-round NTG treatment was further employed to enhance the propamocarb tolerance of L. attenuatum. The positive mutation range was significantly accumulated to 179.3% on the third-round NTG treatment, and then appeared to level-off and remained constant. These results indicated that multiple-round NTG treatment had a significant accumulative effect on fungal tolerance to propamocarb. Among all chemical-mutants, the LA-C-R3-M was the highest tolerant to propamocarb, whose EC₅₀ value was increased 2.79-fold compared to the wild-type strain, and it was mitotic stable after 20 passages on PDA medium. Colony growth, conidia yield and conidial germination on plates, and parasitism of nematode eggs of M. incognita and H. glycines were not significantly changed by the NTG-based mutagenesis compared to the wild-type strain in either single- or multiple-round NTG treatment. In conclusion, we succeeded in improving the propamocarb tolerance of L. attenuatum via the optimized NTG-based mutagenesis system. The improved strain LA-C-R3-M could be potentially applied with propamocarb in the field.