,These are data on variation in host specificity and genetics among 16 populations of an aphid parasitoid, Aphelinus certus, 15 from Asia and one from North America. Host range was the same for all the parasitoid populations, but levels of parasitism varied among aphid species, suggesting adaptation to locally abundant aphids. Differences in host specificity did not correlate with geographical distances among parasitoid populations, suggesting that local adaption is mosaic rather than clinal, with a spatial scale of less than 50 kilometers. Analysis of reduced representation libraries for each population showed genetic differentiation among them. Differences in host specificity correlated with genetic distances among the parasitoid populations.,,

,The soybean aphid, Aphis glycines Matsumura (Hemiptera: Aphididae), is native to Asia where it is an occasional pest of soybean, Glycine max (L.). Aphis glycines was found during 2000 in North America and since then has spread throughout much of the area where soybean is grown. In Asia, A. glycines seldom reaches damaging levels; however in North America, it has become the most important insect pest of soybean, decreasing yields and incurring large control costs. Field surveys and exclosure experiments in China showed that natural enemies can limit soybean aphid abundance. A project to find, evaluate, and introduce Asian natural enemies into North America was initiated in 2001, with an emphasis on parasitoids. To ensure that introductions of exotic parasitoids would have minimum impact on non-target species, we tested host specificity of all candidates for introduction. These data sets provide results of no-choice laboratory experiments on host specificity of 13 populations in seven species from three species complexes in the genus Aphelinus (Hymenoptera: Aphelinidae). They also provide results of experiments on the mechanisms of host specificity in three parasitoid species with narrow host ranges.,See the included README file list for more details on methods and citations for these data files.,,

,Risks of post-introduction evolution in insects introduced to control invasive pests have been discussed for some time, but little is known about responses to selection or genetic architectures of host adaptation and thus about the likelihood or rapidity of evolutionary shifts. We report here results on the response to selection and genetic architecture of parasitism of a sub-optimal, low-preference host species by an aphid parasitoid, Aphelinus rhamni, a candidate for introduction against the soybean aphid, Aphis glycines. The parasitoid was collected in Beijing, China, from the soybean aphid on a Rhamnus species. In the laboratory at the USDA-ARS, Newark, Delaware, we selected A. rhamni for increased parasitism of Rhopalsiphum padi by rearing the parasitoid on this aphid for three generations. We measured parasitism of R. padi at generations two and three, and at generation three, crossed and backcrossed parasitoids from the populations reared on R. padi with those from populations reared on Aphis glycines and compared parasitism of both R. padi and Aphis glycines among F1 and backcross females. Aphelinus rhamni responded rapidly to selection for parasitism of R. padi. Selection for R. padi parasitism reduced parasitism of Aphis glycines, the original host of A. rhamni. However, parasitism of R. padi did not increase from generation two to generation three of selection, suggesting reduced variance available for selection, which was indeed found. We tested the associations between 184 single nucleotide polymorphisms (SNP) and increased parasitism of R. padi and found 28 SNP loci, some of which were associated with increased and others with decreased parasitism of R. padi. We assembled and annotated the A. rhamni genome, mapped all SNP loci to contigs, and tested whether genes on contigs with SNP loci associated with parasitism were enriched for candidate genes or gene functions. We identified 80 genes on these contigs that mapped to 1.2 Mb of the 483 Mb genome of A. rhamni but found little enrichment of candidate genes or gene functions.,,

,Description: This dataset consists of field data (arthropods, nematodes and NDVI) collected over the course of 6 field excursions in 2015 and 2016 near TyTy, GA, in a field used for growing Miscanthus x giganteus. It also includes interpolated values of soil measurements collected in 2015 and meteorological data collected on an adjacent farm. Point-in-time measurements include all meteorological, NDVI, arthropod and nematode measurements and their derivatives. Fixed values were measurements that were held constant across all sampling dates, including location, terrain and soils measurements and their derivatives.,Dawn Olson and Jason Schmidt collected and processed arthropod count data. Jason Schmidt collected and processed spider count data and computed spider diversity. Richard Davis collected and processed nematode count data. Alisa Coffin collected and processed NDVI data and positional locations. Tim Strickland collected and processed soils data and Alisa Coffin interpolated soils values using kriging to derive values at arthropod sample locations. David Bosch collected and processed meteorological data. Lynne Seymour provided statistical expertise in deriving any estimated values (phloem feeders, parasitoids, spiders, and natural enemies). Alisa Coffin derived terrain data (elevation, slope, aspect, and distances) from publicly available datasets, transformed values (SI, WI, etc), carried out the geographically weighted regression analysis and calculated C:SE values, harmonized the full dataset, and compiled it using Esri's ArcGIS Pro 2.5. Methods for most data are published in the accompanying paper and associated supplements.,Questions about dataset development and management should be directed to Alisa Coffin (alisa.coffin@usda.gov). This work was accomplished as a joint USDA and University of Georgia project funded by a cooperative agreement (#6048-13000-026-21S). This research was a contribution from the Long-Term Agroecosystem Research (LTAR) network. LTAR is supported by the United States Department of Agriculture.,At request of the author, the data resources are under embargo. The embargo will expire on Fri, Jan 01, 2021.,

,Supplementary raw data, R scripts, and results underpinning analyses of geometric morphometric and linear data derived from scale insects; includes source code for all analyses, raw data for ostiole, leg, and body shape analyses, and alpha tables for body size analysis and ostioles analyses. Abbreviations are defined in the R script file. See README for list of resources.,

,A high-quality reference genome is an essential tool for applied and basic research on arthropods. Long-read sequencing technologies may be used to generate more complete and contiguous genome assemblies than alternate technologies, however, long-read methods have historically had greater input DNA requirements and higher costs than next generation sequencing, which are barriers to their use on many samples. Here, we present a 2.3 Gb de novo genome assembly of a field-collected adult female Spotted Lanternfly (Lycorma delicatula) using a single PacBio SMRT Cell. The Spotted Lanternfly is an invasive species recently discovered in the northeastern United States, threatening to damage economically important crop plants in the region. The DNA from one individual female specimen collected in Reading, Berks County, Pennsylvania was used to make one standard, size-selected library with an average DNA fragment size of ~20 kb. The library was run on one Sequel II SMRT Cell 8M, generating a total of 132 Gb of long-read sequences, of which 82 Gb were from unique library molecules, representing approximately 38x coverage of the genome. The assembly had high contiguity (contig N50 length = 1.5 Mb), completeness, and sequence level accuracy as estimated by conserved gene set analysis (96.8% of conserved genes both complete and without frame shift errors). Further, it was possible to segregate more than half of the diploid genome into the two separate haplotypes. The assembly also recovered two microbial symbiont genomes known to be associated with L. delicatula, each microbial genome being assembled into a single contig. We demonstrate that field-collected arthropods can be used for the rapid generation of high-quality genome assemblies, an attractive approach for projects on emerging invasive species, disease vectors, or conservation efforts of endangered species.,Supporting files for the manuscript "A High-Quality Genome Assembly from a Single, Field-collected Spotted Lanternfly (Lycorma delicatula) using the PacBio Sequel II System", include several intermediate versions of the assembly (raw output from Falcon, raw output from Falcon unzip, etc.) as well as the final assembly primary contigs and haplotigs (for the regions of the genome that were phased).,,

,A colony of Ganaspis near brasiliensis from Yunnan was started from field collections in Kunming, Yunnan, China in 2016. Wild berries of Rubus foliosus Weihe, Rubus niveus Thunberg, Fragaria moupinensis Cardot (Rosaceae), and Sambucus adnate Wallich (Adoxaceae) were collected in the suburbs of Kuming. The berries were often infested by D. suzukii and the closely related Drosophila pulchrella. Initially, about 600 adult parasitoids emerged from imported puparia at the quarantine facility of University of California Berkeley (UCB). These specimens were assigned to two lineages, G1 and G3, based on COI sequences. A colony of the G3 lineage from Yunnan was started at USDA-ARS Beneficial Insects Introduction Research Unit (BIIRU), Newark, Delaware, USA, from about 100 females and 50 males received from UCB in 2018. A colony of parasitoids from Tokyo (referred to as Ganaspis cf. brasiliensis in Girod et al. (2018a); Seehausen et al. (2020) was started from collections in 2016 from D. suzukii on wild cherry Prunus serrulata in Naganuma Park,Hachioji, Tokyo (Girod et al. 2018a). This population was assigned to the G1 lineage based on its COI sequence (Nomano et al. 2017; Seehausen et al. 2020). The colony is maintained in the quarantine laboratory at CABI in Delémont, Switzerland (Girod et al. 2018a). An Italian colony of the parasitoids from Tokyo was started in 2020 from 150 wasps from the CABI colony, and the BIIRU colony was established from about 500 wasps from Italy in 2021. A colony of D. suzukii was started with field collections of infested cherries during 2010 in Davis, California. Some of the material from British Columbia was identified as G3 in the present study. In the rest of this paper, we will refer to the material from these six populations as G1-BC, G1-Tokyo, G1-Yunnan, G3-BC, G3-Nagano, and G3-Yunnan.,The parasitoids were reared and crosses made in plant growth chambers (23 ± 1°C, 146: 10D, 40–60% RH) at the containment facility at BIIRU. Colonies of D. suzukii and the two COI lineages were maintained using the methods decribed by Rossi-Stacconi et al. (2022). Briefly, D. suzukii was maintained on artificial diet in 250 ml flasks. The parasitoid populations were maintained on blueberries infested by D. suzukii. Fruits were exposed to D. suzukii for 1-2 days for oviposition in screen cage (30 x 30 x 30 cm). The parasitoids were reared in clear plastic containers (9.2 x 11.7 x 7.6 cm) by exposing 5–10 female wasps to 10–20 infested blueberries for 4–5 days, with droplets of honey streaked on the container’s screen as food source. Following the exposure, infested fruits were removed from the cage and kept in new plastic containers with filter paper at the bottom to absorb leaking fruit juice. Newly emerged wasps were collected in plastic vials (95 × 25 mm) and honey provided.,We did crosses to test reproductive compatibility between G3-Yunnan and G1-Tokyo. For these crosses, parasitized D. suzukii puparia from the parasitoid colonies were isolated in plastic vials (95 × 25 mm). A piece of moisturized tissue paper was placed in each vial to provide humidity. When individuals emerged, they were supplied with a streak of honey on the bottom of the vial plug and paired within 48-72h with an individual of either the same or different population with the same emergence date. We made four crosses, two within populations and two between populations: G1♀ × G1♂, G3♀ × G3♂, G1♀ × G3♂, and G3♀ × G1♂. To control for thelytoky, that is females developing from unfertilized eggs (e.g., from Wolbachia infection), virgin females were also tested for each parasitoid population. For all crosses and controls, each female was provided with two infested blueberries containing approximately 10 first and second instar D. suzukii larvae, based on counts of initial host eggs laid in berries. After three days, females were removed and placed in 95% ethanol. Exposed host larvae were kept for 6 weeks during which adult flies should emerge (about

,Data are from a laboratory experiment conducted to examine the potential effects of honeydew from six different aphid species by crop species combinations on the longevity of Bracon cephi Gahan (Hymenoptera: Braconidae), the most important biological control of the wheat stem sawfly, Cephus cinctus Norton (Hymenoptera: Cephidae), a major pest of wheat in the northern Great Plains of North America. We quantified the number of days parasitoids lived on each honeydew type.,Abstract from published manuscript: The absence of sugar resources can be an important factor in limiting the success of parasitoids as biological control agents. Restoring vegetation complexity within agricultural landscapes has thus become a major focus of conservation biological control efforts, with a traditional emphasis on nectar resources. Aphid honeydew is also an important source of sugars that is infrequently considered. We carried out a laboratory experiment to examine the potential effects of honeydew from six different aphid species by crop species combinations on the longevity of Bracon cephi Gahan (Hymenoptera: Braconidae), the most important biological control of the wheat stem sawfly, Cephus cinctus Norton (Hymenoptera: Cephidae), a major pest of wheat in the northern Great Plains of North America. The benefits of honeydew for parasitoid longevity varied significantly among different aphid and crop species, illustrating the complexity of these interactions. However, honeydew produced by four aphid species commonly found in wheat, pea, and canola crops significantly increased the longevity (by two- to threefold) of the parasitoid. The study suggests that honeydew provisioning could be an important mechanism underlying the benefits of crop diversification to support biological control that merits further research.,Resources in this dataset:,