ABSTRACT
The broad host range fungal insect pathogen,
Beauveria bassiana
, has been commercialized as an alternative to chemical insecticides for pest control worldwide.
B. bassiana
represents a ...unique model system with which to examine host-pathogen interactions, and a wide range of genes and processes have been studied. However, significant aspects of virulence, particularly on the genomic scale, remain poorly studied. Here, we have combined available transcriptomes with three newly generated data sets for a combined total analysis of 76 deep-sequenced samples covering growth, development, stress responses, and infection during the life cycle of
B. bassiana
. Co-expression network analyses resulted in the identification of gene modules enriched during two critical stages of the infection process, namely (i) cuticle penetration and (ii)
in vivo
hyphal body (dimorphic transition) growth capable of avoiding innate and humoral immune defenses. These analyses identify unique signatures of metabolism, signaling, secondary metabolite production, host defense suppression, membrane reorganization, effector production, and secretion for each stage, including genetic regulators and epigenetic patterns. These data provide a comprehensive framework for understanding and probing fungal adaptations to its pathogenic life cycle and expand the candidate repertoire for continued dissection of the host-pathogen interaction.
IMPORTANCE
Insect fungal pathogens have evolved unique strategies for overcoming host structural and immunological defenses that span from the sclerotized cuticle to innate and humoral cellular responses. Two critical stages of the infection process involve (i) cuticle penetration and (ii) immune evasion within the insect hemocoel. A set of 76 global transcriptomic data for
B. bassiana
that include the cuticle penetration and hemocoel growth stages were analyzed for patterns (gene modules) of expression, yielding unique insights into these different life stages. These analyses integrate gene networks involved in fungal development, stress response and pathogenesis to further the systematic understanding of the global processes integral to the unique adaptation employed by fungal pathogens of insects.
Insect fungal pathogens have evolved unique strategies for overcoming host structural and immunological defenses that span from the sclerotized cuticle to innate and humoral cellular responses. Two critical stages of the infection process involve (i) cuticle penetration and (ii) immune evasion within the insect hemocoel. A set of 76 global transcriptomic data for
B. bassiana
that include the cuticle penetration and hemocoel growth stages were analyzed for patterns (gene modules) of expression, yielding unique insights into these different life stages. These analyses integrate gene networks involved in fungal development, stress response and pathogenesis to further the systematic understanding of the global processes integral to the unique adaptation employed by fungal pathogens of insects.
The use of entomopathogenic fungi (EPF) like Beauveria, Metarhizium, Lecanicillium, and Isaria is upsurging in recent years for the management of crop insect pests. EPF are considered better than ...synthetic insecticides as they are safe for humans, sustainable to the environment, and target-specific in nature. Many of these EPF are pathogenic to economically important insect pests and thus are capable of controlling them. They are cheaper in long run, show lesser residual effects, and are able to overcome the problem of resistance. EPF degrades the host cuticle and proliferates in hemolymph as hyphal bodies, secreting the toxins responsible for the death of host insects. The later saprophytic growth leads to the production of fungal spores capable of reinfecting other hosts. Different commercial formulations of EPF are available globally such as liquid formulation, wettable powder, suspensible granules, and so on. These available formulations under different trade names can be used for several crops and pests at the recommended dosage to obtain optimum results. The storage conditions should be maintained to retain the viability of EPF. Modern biotechnological interventions could be vital in enhancing the efficacy of these entomopathogens by manipulating their traits. Specialized researches are necessary to understand the interaction between EPF, host insects, crops, and their environment in order to explore the best formulation of mycoinsecticides. This review explores the overview of EPF, its mode of action, significance, commercial formulations, future prospects, and the summary of recent findings. Readers could realize the essence of EPF in sustainable agriculture through this review.
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•Beauveria bassiana isolates vary in their response to abiotic and biotic factors.•Tree secondary metabolites and low temperatures inhibit Beauveria bassiana growth.•Many isolates are ...pathogenic in the laboratory but not under in natura conditions.•Natural phloem substrate greatly influences Beauveria bassiana virulence.
Beauveria bassiana is a ubiquitous entomopathogen and widely used as a biological control agent for a variety of arthropod pests, including bark beetles. The North American spruce beetle (Dendroctonus rufipennis) is a major pest in forest landscapes and recent studies show that B. bassiana is pathogenic to beetles in the lab but successful field applications have been limited by abiotic and biotic factors within the study system. To understand how habitat conditions impact fungal ecology, we evaluated variation in B. bassiana radial growth across conditions representative of the spruce beetle habitat, incorporating a range of temperatures, competition with spruce beetle symbiotic fungi, as well as exposure to Engelmann spruce tree secondary metabolites, nutrient limitations, osmotic potentials, and sunlight. Pathogenicity to spruce beetle was subsequently quantified in tests varying beetle origin, temperature, and bioassay arena substrate. Three major findings emerged: (1) growth of genetically similar B. bassiana isolates varied considerably in response to abiotic conditions, suggesting significant within-haplotype phenotypic diversity; (2) low ambient temperatures and exposure to Engelmann spruce tree secondary metabolites, two conditions which are prevalent in spruce beetle habitat, strongly inhibit B. bassiana growth; and (3) pathogenicity varied across environments: all isolates appeared pathogenic under room conditions, but when beetles inhabited in planta bioassays under in natura conditions most isolates were not pathogenic. This is the first study to evaluate the inhibitory effects that a series of tree secondary metabolites have on B. bassiana growth, virulence and pathogenicity. These collective findings have implications for field applications of B. bassiana but also the interpretation of entomopathogenicity, and could help to explain discrepancies between laboratory and field tests.
Among the management and control tactics of the coffee berry borer Hypothenemus hampei (Ferrari), there is the use of entomopathogenic fungi. Due to the importance of prospecting isolates of ...entomopathogenic fungi for the control of the coffee berry borer, the objective of this study was to evaluate the efficiency of 26 isolates of entomopathogenic fungi in the control of this insect pest in the laboratory. The coffee berry borers were immersed in a solution adjusted to the concentration of 1 to 3 × 108 conidia/mL of each isolate and the control treatment (sterilized water). After seven days total mortality and confirmed mortality were evaluated. The isolates that caused the highest mortality and two commercial isolates were selected for evaluation of lethal concentration (LC50 and LC90) and lethal time (LT50 and LT90). Coffee berry borers were treated at different conidia concentrations for lethal concentration to assess total and confirmed mortality. For a lethal time, the coffee berry borers were treated at the concentration of 108 conidia/mL of the selected isolates, and, after two days and every 24 hours until the eighth day, the number of dead individuals was verified. Among the 26 isolates evaluated, 24 presented mortality higher than the control treatment, and three presented mortality higher than 85%. In the LC50 and LC90 assays, the IBCB 353 and IBCB 364 isolates were more lethal to H. hampei. In the LT50 and LT90 assays, the IBCB 66 and IBCB 353 isolates caused lethality in a shorter time.
Red pepper is seriously damaged by thrips (Thrips palmi) and anthracnose caused by Colletotrichum acutatum throughout its development. Because of biotic constraints, producers often depend on ...chemicals that are expensive and have adverse effects on the environment, operator, and beneficial insects. In addition, resistance is developed because of the repeated use of chemicals. In recent decades, the use of microorganisms in crop protection has become a credible alternative because it is eco-friendly. In this study, we aimed to select isolates with insecticidal and fungicidal activities against the pathogens that cause anthracnose and thrips. We treated T. palmi adults and juveniles with 13 strains of entomopathogenic fungi (isolated from the soil by using the insect-bait method), and 6 strains showed excellent insecticidal activity (70-100%) 5 days after the treatment. The selected isolates were cultured with C. acutatum to screen for the strain with excellent anti-fungal activities, among which an isolate FT333 showed more than 95% control efficacy against C. acutatum in vitro. The isolate was identified as Isaria javanica through its morphological characteristics and phylogenetic analysis of the ITS and β-tubulin nucleotide sequences. The Isaria javanica FT333 isolate could be used effectively for dual bio-control of thrips and anthracnose during red pepper cultivation.
The recent arrival of Drosophila suzukii, an invasive pest of soft‐skinned fruit with a wide host range, has resulted in increased production costs for growers and the need for additional insecticide ...applications each growing season. There are few effective organic insecticides for D. suzukii, and insecticide use in conventional farms may be disruptive to natural enemies, suggesting a need for effective biological control to combat D. suzukii. Commercially available natural enemies were evaluated for their potential use in augmentative releases, including: the predators Orius insidiosus and Dalotia coriaria; the entomopathogenic fungi Metarhizium anisopliae, Beauveria bassiana and Paecilomyces fumosoroseus; and the entomopathogenic nematodes Heterorhabditis bacteriophora, Steinernema feltiae and S. carpocapsae. This suite of natural enemies was chosen to target D. suzukii adults as well as larvae in hanging or dropped fruit. Of the cultured fungal strains tested, only M. anisopliae significantly decreased D. suzukii survival, but it had low residual activity and no effect on D. suzukii fecundity. O. insidiosus decreased D. suzukii survival in simple laboratory arenas but not on potted blueberries or bagged blueberry branches outdoors. D. coriaria did not decrease D. suzukii survival in infested blueberries in simple laboratory arenas. The nematodes tested showed low infection rates and were not able to affect D. suzukii survival. Although this suite of natural enemies showed limited ability to suppress D. suzukii under the tested conditions, these and related natural enemies are present as part of the endemic natural enemy community in agricultural fields, where they may contribute to D. suzukii suppression.
Sinapigladioside is a rare isothiocyanate‐bearing natural product from beetle‐associated bacteria (Burkholderia gladioli) that might protect beetle offspring against entomopathogenic fungi. The ...biosynthetic origin of sinapigladioside has been elusive, and little is known about bacterial isothiocyanate biosynthesis in general. On the basis of stable‐isotope labeling, bioinformatics, and mutagenesis, we identified the sinapigladioside biosynthesis gene cluster in the symbiont and found that an isonitrile synthase plays a key role in the biosynthetic pathway. Genome mining and network analyses indicate that related gene clusters are distributed across various bacterial phyla including producers of both nitriles and isothiocyanates. Our findings support a model for bacterial isothiocyanate biosynthesis by sulfur transfer into isonitrile precursors.
Alternative pathways: Genetic analyses and labeling studies provide the first insights into the biosynthesis of the rare isothiocyanate natural product sinapigladioside from beetle‐associated bacteria that might protect the beetle offspring against entomopathogenic fungi. Contrary to known isothiocyanate biosynthetic pathways, sinapigladioside assembly involves an isonitrile synthase.
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