Abstract
The insect integument (exoskeleton) is an effective physiochemical barrier that limits disease-causing agents to a few portals of entry, including the gastrointestinal and reproductive tracts. The bacterial biopesticide Bacillus thuringiensis (Bt) enters the insect host via the mouth and must thwart gut-based defences to make its way into the body cavity (haemocoel) and establish infection. We sought to uncover the main antibacterial defences of the midgut and the pathophysiological features of Bt in a notable insect pest, the Colorado potato beetle Leptinotarsa decemlineata (CPB). Exposing the beetles to both Bt spores and their Cry3A toxins (crystalline δ-endotoxins) via oral inoculation led to higher mortality levels when compared to either spores or Cry3A toxins alone. Within 12 h post-exposure, Cry3A toxins caused a 1.5-fold increase in the levels of reactive oxygen species (ROS) and malondialdehyde (lipid peroxidation) within the midgut – key indicators of tissue damage. When Cry3A toxins are combined with spores, gross redox imbalance and ‘oxidation stress’ is apparent in beetle larvae. The insect detoxification system is activated when Bt spores and Cry3A toxins are administered alone or in combination to mitigate toxicosis, in addition to elevated mRNA levels of candidate defence genes (pattern-recognition receptor, stress-regulation, serine proteases, and prosaposin-like protein). The presence of bacterial spores and/or Cry3A toxins coincides with subtle changes in microbial community composition of the midgut, such as decreased Pseudomonas abundance at 48 h post inoculation. Both Bt spores and Cry3A toxins have negative impacts on larval health, and when combined, likely cause metabolic derangement, due to multiple tissue targets being compromised.
Highlights
Bacillus thuringiensis (Bt) is a widespread bacterium that has been developed as a biopesticide to control insect pests as well as arbovectors, e.g., mosquitoes [1]
We report on the repertoire of midgut defence reactions of Colorado potato beetle Leptinotarsa decemlineata (CPB) larvae that work to protect insects from Bt virulence factors
We examine antioxidant responses, humoral immunity, stress and toxin management, and changes in the gut microbiome in CPB larvae inoculated with Bt spores, Cry3A toxins and their mixture
Summary
Bacillus thuringiensis (Bt) is a widespread bacterium that has been developed as a biopesticide to control insect pests as well as arbovectors, e.g., mosquitoes [1]. The insecticidal activity of Bt is primarily due to crystalline endotoxins (Cry toxins) produced during sporulation and activated by proteases in the host’s gut [2]. Cry toxins can kill insects alone (when expressed in genetically modified plants), yet there are many virulence factors deployed by spores and vegetative cells that contribute to bacterial pathogenicity. Carbohydrates and enzymes associated with the bacterial exosporium help Bt to adhere to host tissues, germinate and protect the spores from elimination by insect defence systems [5]. Bt-associated virulence factors, which are transcribed in the vegetative cells by the PlcR-PapR quorum-sensing system, play an important role in the infection process [6]. There is evidence that bacteria could express some of these virulence and homeostatic factors during insect colonisation in order to overcome host defenses [11,12]
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