Prospects for deploying microbes against tree-killing beetles (Coleoptera) in Anthropocene

Gupta, Sumanti; Chakraborty, Amrita; Roy, Amit

doi:10.3389/ffgc.2023.1182834

Cited by 6 publications

(6 citation statements)

References 255 publications

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“…Current data will facilitate further downstream studies (metatranscriptomics, metaproteomics, and culture-based bacterial functional characterization) to characterize the critical bacterial species aiding these Ips beetles thriving on defence-rich pine trees. Such essential bacterial partners can be used for microbiome-based sustainable pest management practices (91, 101, 102). Finally, such knowledge can serve as a primer to decipher the underlying microbial interactions at the tree-beetle interface and facilitate the integration of tree-beetle-microbiome interaction data into spatial models of forest ecosystem dynamics predictions.…”

Section: Discussionmentioning

confidence: 99%

“…Other core members such as Dyella, Pseudoxanthomonas, Sphingomonas, Saccharomonospora, Acidisoma have the enzymatic competency to help the beetle metabolize complex carbohydrates found in the conifer cell wall (21,69,(87)(88)(89)(90). Therefore, such microbes belonging to the core bacteriome can be further evaluated in beetlo for potential benefits and targeted for future microbesmediated sustainable beetle management practices (91).…”

Section: Discussionmentioning

confidence: 99%

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Comparative metagenomic study unveils bacterial communities and their putative involvement in ecological success of two pine-feedingIpsbeetle holobionts

Khara,

Chakraborty,

Modlinger

et al. 2024

Preprint

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Climate change has recently boosted the severity and frequency of the pine bark beetle attacks. The bacterial community associated with these beetles acts as “hidden players”, enhancing their ability to infest and thrive on defence-rich pine trees. There is limited understanding of the environmental acquisition of these hidden players and their life stage-specific association with different pine-feeding bark beetles. There is inadequate knowledge on novel bacterial introduction to pine trees after the beetle infestation. Hence, we conducted the first comparative bacterial metabarcoding study comprehensively revealing the bacterial communities in the pine trees before and after beetle feeding and in different life stages of two dominant pine-feeding bark beetles, namelyIps sexdentatusandIps acuminatus. We also evaluated the bacterial association between wild and lab-bred beetles to measure the deviation due to inhabiting a controlled environment. Significant differences in bacterial amplicon sequence variance (ASVs) abundance existed among different life stages within and between the pine beetles. Such observations endorsed that the bark beetle life stage shaped bacterial assemblage. Furthermore, lab-bred and wild-collected adult beetles had distinct bacterial assemblages, implying that the breeding environment induced crucial changes. Alteration of pine wood bacteriome after beetle feeding is an intriguing observation in the present study, which demands further investigation. We validated the relative abundances of selected bacterial taxa estimated by metagenomic sequencing with quantitative PCR. Functional predictions revealed that these bacterial genera might execute conserved functions, aiding the ecological success of these beetles. Nevertheless, these findings shed new insights into bacterial associations and their putative metabolic roles in pine beetles under the influence of various drivers such as environment, host, and life stages and provide the foundation for future downstream functional investigations.ImportanceThe current understanding of bark beetle as holobiont is restricted. Most studies lack information on microbial community assembly in bark beetle microhabitats. No data comprehensively reveals the influence of lab breeding on pine beetle microbial associations. It is unknown if there is any adaptive convergence in beetle microbial assemblage due to feeding on the same host. Such information is essential to developing a bark beetle management strategy to restore forests from beetle-mediated damage. Our study shows that lab-breeding considerably influences beetle bacterial community assembly. We documented that beetle feeding alters bacteriome at the microhabitat level, and the beetle life stage shapes the bacterial associations. Nevertheless, our study revisited the bark beetle symbiosis under the influence of different drivers and revealed intriguing insight into bacterial community assembly, facilitating future functional studies.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Comparative metagenomic study unveils bacterial communities and their putative involvement in ecological success of two pine-feedingIpsbeetle holobionts

Khara,

Chakraborty,

Modlinger

et al. 2024

Preprint

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“…Our colleagues from the United States are deploying fungal-induced gene silencing (FIGS) technology to manage bark beetles, i.e., genetically modifying the bark beetle-associated yeast Ogataea pini, to generate specific dsRNA molecules that target Ips calligraphus (information based on personal communication). Our team has also successfully identified and isolated insectsymbiotic bacteria and fungi (Chakraborty et al, 2020a(Chakraborty et al, ,b, 2023b and may use them as a CSMR for tropical application to control the bark beetles and termites (Gupta et al, 2023). Recently, our group identified 69 core bacterial genera and 19 fungal genera among six bark beetles (Ips typographus, Ips duplicatus, Ips cembrae; Ips sexdentatus, Ips acuminatus, and Polygraphus poligraphus).…”

Section: Chitosan Encapsulated Microbes: New Hope Against Forest Inse...mentioning

confidence: 95%

“…Moreover, within termite-infested wood, fungal communities affiliated with the Eurotiales, Sordariales, Hypocreales, Trichospornales, and Ophiostomatales orders were identified, notably, the fungal genera Apiotrichum, Fusarium, Hawksworthiomyces, Lasiodiplodia, Sporothrix, Trichosporon, and Trichoderma displayed substantial prevalence in the termite-infested wood. As described thoroughly in our recent review, some identified microbial associates of bark beetle or termites can be good candidates for Symbiont-mediated RNAi or SMR (Gupta et al, 2023). Nevertheless, SMR technology can be considered for its potential in forest conservation; additional refinements are necessary before applications.…”

Section: Chitosan Encapsulated Microbes: New Hope Against Forest Inse...mentioning

confidence: 99%

RNAi-chitosan biopesticides for managing forest insect pests: an outlook

Mogilicherla,

Roy

2023

Front. For. Glob. Change

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The expanding world population demands superior forest protection to fulfil feasible environmental certainty. The persistent pest infestations negatively influence forest health and cause substantial economic losses. In contrast, the traditional use of conventional pesticides results in a loss of soil microbial biodiversity, a drop in the population of pollinators, and adverse effects on other non-target organisms, including humans. Global forestry is looking for solutions to reduce the adverse environmental effects of current chemical pesticides. RNAi-nanotechnology has recently drawn much attention for its use in pest management. The advantages of engineered RNAi-chitosan nano-formulations in terms of simple digestion and dissolution, non-toxicity, high adsorption power, potential biodegradation in nature, and widespread availability and cost-effectiveness, have been well documented for pest management in agroecosystems. However, deploying such control strategies in forest ecosystems is still pending and demands further research. Hence, we highlight the putative uses of RNAi-chitosan biopesticides and their preparation, characterization, and putative application methods for forest pest management. We also discussed potential environmental risks and plausible mitigation strategies.

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“…Recently, Mogilicherla and Roy (2023b) comprehensively reviewed chitosan-dsRNA nanopesticides and their applications in managing bark beetles. The bacteria and fungi that live symbiotically with bark beetles have been successfully isolated and identified and can be considered putative candidates for symbiont-mediated RNAi (SMT) for tropical application to control bark beetles (Chakraborty et al 2020a(Chakraborty et al , 2020b(Chakraborty et al , 2023Gupta et al 2023;Mogilicherla and Roy 2023b). These studies may pave the way for developing and using RNAi-biopesticides as a secure, efficient, and innovative method to safeguard forest trees.…”

Section: Rna Interference (Rnai)mentioning

confidence: 99%

Understanding bark beetle outbreaks: exploring the impact of changing temperature regimes, droughts, forest structure, and prospects for future forest pest management

Singh,

Naseer,

Mogilicherla

et al. 2024

Rev Environ Sci Biotechnol

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Climate change has increased the susceptibility of forest ecosystems, resulting in escalated forest decline globally. As one of the largest forest biomasses in the Northern Hemisphere, the Eurasian boreal forests are subjected to frequent drought, windthrow, and high-temperature disturbances. Over the last century, bark beetle outbreaks have emerged as a major biotic threat to these forests, resulting in extensive tree mortality. Despite implementing various management strategies to mitigate the bark beetle populations and reduce tree mortality, none have been effective. Moreover, altered disturbance regimes due to changing climate have facilitated the success of bark beetle attacks with shorter and multivoltine life cycles, consequently inciting more frequent bark beetle-caused tree mortality. This review explores bark beetle population dynamics in the context of climate change, forest stand dynamics, and various forest management strategies. Additionally, it examines recent advancements like remote sensing and canine detection of infested trees and focuses on cutting-edge molecular approaches including RNAi-nanoparticle complexes, RNAi-symbiotic microbes, sterile insect technique, and CRISPR/Cas9-based methods. These diverse novel strategies have the potential to effectively address the challenges associated with managing bark beetles and improving forest health in response to the changing climate.

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Prospects for deploying microbes against tree-killing beetles (Coleoptera) in Anthropocene

Cited by 6 publications

References 255 publications

Comparative metagenomic study unveils bacterial communities and their putative involvement in ecological success of two pine-feedingIpsbeetle holobionts

Comparative metagenomic study unveils bacterial communities and their putative involvement in ecological success of two pine-feedingIpsbeetle holobionts

RNAi-chitosan biopesticides for managing forest insect pests: an outlook

Understanding bark beetle outbreaks: exploring the impact of changing temperature regimes, droughts, forest structure, and prospects for future forest pest management

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