Increased Phenoloxidase Activity Constitutes the Main Defense Strategy of Trichoplusia ni Larvae against Fungal Entomopathogenic Infections

Increased Phenoloxidase Activity Constitutes the Main Defense Strategy of Trichoplusia ni Larvae against Fungal Entomopathogenic Infections

The cabbage looper Trichoplusia ni is an important agricultural pest worldwide and is frequently used as a model organism for assessing entomopathogenic fungi virulence, though few studies have measured the host response repertoire to fungal biocontrol agents. Here, we quantified the immune response...

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Bibliographic Details
Published in:Insects (Basel, Switzerland) Vol. 14; no. 8; p. 667
Main Authors: Duffield, Kristin R., Rosales, Alayna M., Muturi, Ephantus J., Behle, Robert W., Ramirez, José L.
Format: Journal Article
Language:English
Published: Basel MDPI AG 25-07-2023
MDPI
Subjects:
Antiinfectives and antibacterials
Biological control
Biological effects
Brassica oleracea
Butterflies & moths
Cecropin
Defense
Effectors
Entomopathogenic fungi
entomopathogenic fungi (EPF)
Enzymes
Exposure
Fungal infections
Fungi
Fungicides
Gene expression
Genes
host immune response
host–fungal interactions
Humidity
Immune response
Immune system
insect immunity
Insects
Kinases
Larvae
Lysozyme
Melanization
Microorganisms
Pathogens
Pest control
Pesticides
Pests
Phenoloxidase
phenoloxidase cascade
Prophenoloxidase
Signal transduction
Survival analysis
Transcription activation
Trichoplusia ni
Virulence
United States > US
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Summary:The cabbage looper Trichoplusia ni is an important agricultural pest worldwide and is frequently used as a model organism for assessing entomopathogenic fungi virulence, though few studies have measured the host response repertoire to fungal biocontrol agents. Here, we quantified the immune response of T. ni larvae following exposure to two entomopathogenic fungal species: Beauveria bassiana and Cordyceps javanica. Results from our study demonstrate that T. ni larvae exposed to fungal entomopathogens had higher total phenoloxidase activity compared to controls, indicating that the melanization cascade is one of the main immune components driving defense against fungal infection and contrasting observations from other insect–fungi interaction studies. We also observed differences in host response depending on the species of entomopathogenic fungi, with significantly higher induction observed during infections with B. bassiana than with C. javanica. Larvae exposed to B. bassiana had an increased expression of genes involved in prophenoloxidase response and the Imd, JNK, and Jak/STAT immune signaling pathways. Our results indicate a notable absence of Toll pathway-related responses, further contrasting results to other insect–fungi pathosystems. Important differences were also observed in the induction of antimicrobial effectors, with B. bassiana infections eliciting three antimicrobial effectors (lysozyme, gloverin, and cecropin), while C. javanica only induced cecropin expression. These results provide insight into the host response strategies employed by T. ni for protection against entomopathogenic fungi and increase our understanding of insect–fungal entomopathogen interactions, aiding in the design of more effective microbial control strategies for this important agricultural pest.
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ISSN:2075-4450
2075-4450
DOI:10.3390/insects14080667