Identifying Molecular-Based Trophic Interactions as a Resource for Advanced Integrated Pest Management

Schmidt, Jason M.; Acebes‐Doria, Angelita L.; Blaauw, Brett R.; Kheirodin, Arash; Pandey, Swikriti; Lennon, Kylie; Kaldor, A; Toledo, Pedro F.S.; Grabarczyk, Erin E.

doi:10.3390/insects12040358

Cited by 14 publications

(8 citation statements)

References 75 publications

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“…The high sensitivity and specificity of DNA‐based diagnostic tools led to a new field of ecological research, molecular trophic interactions (González‐Chang et al., 2016; King et al., 2008; Schmidt et al., 2021). The development of PCR‐based diagnostic tools revolutionized studies of trophic interactions, given their advantage over previous approaches (i.e., gut content dissection and field observations) in detecting small DNA remains in arthropod digestive parts (Pompanon et al., 2012).…”

Section: Introductionmentioning

confidence: 99%

“…The development of PCR‐based diagnostic tools revolutionized studies of trophic interactions, given their advantage over previous approaches (i.e., gut content dissection and field observations) in detecting small DNA remains in arthropod digestive parts (Pompanon et al., 2012). Given their efficacy in providing detailed information on trophic linkages among species, molecular gut content analysis (thereafter MGCA) has been employed to determine herbivore–plant interactions (Avanesyan et al., 2021; Kheirodin et al., 2021; Wallinger et al., 2012), predator–prey interactions (King et al., 2008; Schmidt et al., 2021; Symondson, 2012), parasitoid–host interactions (Gariepy & Messing, 2012; Grab et al., 2018), intraguild predation (Traugott et al., 2012; Traugott & Symondson, 2008), and more recently to study plant–pest–predator interactions (Da Silva et al., 2019; Guenay et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

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Rethinking trophic interactions in agricultural landscapes through tracking secondary feeding

Kheirodin,

Sayari,

Schmidt

2023

Environmental DNA

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Conservation biological control efforts depend on accurately estimating predator roles in crop fields, and knowledge of plant resources generalist predators utilize in agricultural landscapes. Generalist predators move among habitats to feed on insect prey and some predators feed on plants for non‐prey nutrients. Studying predation with molecular gut content analysis (MGCA), provides estimates of within field frequencies of predation on target pests and alternative prey. However, prey DNA takes time to move through the predator digestive system, so a portion of the observed predation likely occurs in adjacent crops or semi‐natural habitats. Therefore, we tested a strategy to estimate recent secondary feeding to help trace predation back to the source habitat. We selected the diamondback moth and three common predators with different mouthparts: Coccinella septempunctata, Geocoris punctipes, and Pardosa spiders, as model organisms for these proof‐of‐concept experiments. We estimated post‐feeding primary and secondary plant DNA detection time and compared it between these three predators using previously designed Lepidoptera primers and newly designed Brassica‐specific primers. Our results indicate secondary plant feeding detection largely depends on predator mouthparts. While secondary collard DNA detectability half‐life was 5.5 h and remained detectable for up to 30 h for the chewing predator, C. septempunctata, only 4% and 8.3% of G. punctipes and Pardosa spp. individuals, respectively, tested positive for collard DNA. However, more studies are required to confirm this mouthpart‐specific post‐feeding plant DNA detection time. Our feeding trials confirmed the possibility of primary and secondary plant feeding detection for chewing predators. Hence, when crops are not flowering (or anthesis), secondary plant feeding detection can be used to trace chewing predators to source habitats where they consumed sessile prey (e.g., nymphs and sessile adults). Such multitrophic linkage knowledge could unravel the landscape‐wise contribution of predators to pest control services.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rethinking trophic interactions in agricultural landscapes through tracking secondary feeding

Kheirodin,

Sayari,

Schmidt

2023

Environmental DNA

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“…Metabarcoding has yet to be fully integrated in CBC research, but some component techniques, such as multiplex PCR (polymerase chain reaction) assays with species-specific primers and DNA barcoding, are already used in biological control research more generally (Gariepy et al, 2007(Gariepy et al, , 2019Schmidt et al, 2021;Ye et al, 2017). Moreover, it is becoming increasingly apparent that metabarcoding can be a powerful tool for detecting and monitoring the presence of non-native insect species (Batovska et al, 2021;Comtet et al, 2015), their host-parasitoid interactions (Kitson et al, 2018;Sow et al, 2019), and characterizing the trophic interaction networks that form around them in invaded areas and their areas of origin (Brown et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Metabarcoding and applied ecology with hyperdiverse organisms: Recommendations for biological control research

et al. 2022

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Metabarcoding is revolutionizing fundamental research in ecology by enabling large‐scale detection of species and producing data that are rich with community context. However, the benefits of metabarcoding have yet to be fully realized in fields of applied ecology, especially those such as classical biological control (CBC) research that involve hyperdiverse taxa. Here, we discuss some of the opportunities that metabarcoding provides CBC and solutions to the main methodological challenges that have limited the integration of metabarcoding in existing CBC workflows. We focus on insect parasitoids, which are popular and effective biological control agents (BCAs) of invasive species and agricultural pests. Accurately identifying native, invasive and BCA species is paramount, since misidentification can undermine control efforts and lead to large negative socio‐economic impacts. Unfortunately, most existing publicly accessible genetic databases cannot be used to reliably identify parasitoid species, thereby limiting the accuracy of metabarcoding in CBC research. To address this issue, we argue for the establishment of authoritative genetic databases that link metabarcoding data to taxonomically identified specimens. We further suggest using multiple genetic markers to reduce primer bias and increase taxonomic resolution. We also provide suggestions for biological control‐specific metabarcoding workflows intended to track the long‐term effectiveness of introduced BCAs. Finally, we use the example of an invasive pest, Drosophila suzukii, in a reflective “what if” thought experiment to explore the potential power of community metabarcoding in CBC.

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“…For instance, Wu et al (2017) used transcriptome sequencing technology to analyze the T. papillosa olfaction gene families. Moreover, targeted acquisition of pest control strategies based on molecular targeting technology offers a viable alternative approach to mitigating pests ( Delye et al, 2020 ; Schmidt et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Transcriptome Analysis for Identification of Genes Related to Growth and Development, Digestion and Detoxification, Olfaction in the Litchi Stink Bug Tessaratoma papillosa

et al. 2022

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Tessaratoma papillosa is a major pest of Litchi chinensis and Dimocarpus longan. Adult and nymph secretions are not only harmful to plants but also to humans. At present, there are not a lot of research on T. papillosa, especially omics research. We used high-throughput sequencing technology to sequence the T. papillosa transcriptome and obtained 67,597 unigenes homologous to Halyomorpha halys (88.03%). Subsequently, RNA-SEQ and comparative analyses were performed on the 14 different developmental stages and tissues. A total of 462 unigenes related to growth and development, 1,851 unigenes related to digestion and detoxification, and 70 unigenes related to olfaction were obtained. Moreover, expression analysis showed that the T. papillosa major life activities genes are uniformly expressed across all developmental states. However, the adult midgut gene expression patterns were utterly different from that of the nymphs. Similarly, female fat body genes exhibited distinct expression patterns compared to that of males and nymphs. Thus, different developmental stages and physiological functions affect gene expression patterns. We also found that most of the differential genes were associated with cellular maintenance. This study will help understand the growth and development of litchi stink bugs, their choice of host plants, food digestion and detoxification, and their reproductive behavior. In addition, this result can provide reference information for some target genes in the process of control of T. papillosa.

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Identifying Molecular-Based Trophic Interactions as a Resource for Advanced Integrated Pest Management

Cited by 14 publications

References 75 publications

Rethinking trophic interactions in agricultural landscapes through tracking secondary feeding

Rethinking trophic interactions in agricultural landscapes through tracking secondary feeding

Metabarcoding and applied ecology with hyperdiverse organisms: Recommendations for biological control research

Transcriptome Analysis for Identification of Genes Related to Growth and Development, Digestion and Detoxification, Olfaction in the Litchi Stink Bug Tessaratoma papillosa

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