Perspicacious insights into plant-virus-vector interactions applying omics.

Transmission of plant viruses by insect vectors is facilitated by unequivocal tri-partite interactions among host plants, viruses, and associated vectors. The advent of next-generation sequencing including whole genome sequencing, RNA/small RNA sequencing, proteomics, and metabolomics aided in elucidating the molecular mechanisms involved in virus transmission by insect vectors and infection in host plants.

Virus-vectoring thrips regulate the excessive multiplication of tomato spotted wilt virus using their antiviral immune responses.

The tomato spotted wilt virus (TSWV) is a member of the Tospoviridae family and has an negative/ambisense single-stranded RNA genome. Frankliniella occidentalis and F. intonsa are known to be dominant pests in Capsicum annuum (hot pepper) and can cause damage to the plant either directly by feeding, or indirectly by transmitting TSWV in a persistent and propagative manner, resulting in serious economic damage. This study compared the immune responses of two different thrips species against TSWV infection by transcriptome analysis, which then allowed the assessment of antiviral responses using RNA interference (RNAi). Both adult thrips shared about 90 % of the transcripts in non-viruliferous conditions. Most signal components of the immune pathways were shared by these two thrips species, and their expression levels fluctuated differentially in response to TSWV infection at early immature stages. The functional assays using RNAi treatments indicated that the Toll and JAK/STAT pathways were associated with the antiviral responses, but the IMD pathway was not. The upregulation of dorsal switch protein one supported its physiological role in recognizing TSWV infection and triggering the eicosanoid biosynthetic pathway, which mediates melanization and apoptosis in thrips. In addition, the signal components of the RNAi pathways fluctuated highly after TSWV infection. Individual RNAi treatments specific to the antiviral signalling and response components led to significant increases in the TSWV amount in the thrips, causing virus-induced mortality. These findings suggest that immune signalling pathways leading to antiviral responses are operating in the thrips to regulate TSWV litres to prevent a fatal viral overload. This study also indicates the differential antiviral responses between the TSWV-transmitting F. occidentalis and F. intonsa.

WIV, a protein domain found in a wide number of arthropod viruses, which probably facilitates infection.

The most powerful approach to detect distant homologues of a protein is based on structure prediction and comparison. Yet this approach is still inapplicable to many viral proteins. Therefore, we applied a powerful sequence-based procedure to identify distant homologues of viral proteins. It relies on three principles: (1) traces of sequence similarity can persist beyond the significance cutoff of homology detection programmes; (2) candidate homologues can be identified among proteins with weak sequence similarity to the query by using 'contextual' information, e.g. taxonomy or type of host infected; (3) these candidate homologues can be validated using highly sensitive profile-profile comparison. As a test case, this approach was applied to a protein without known homologues, encoded by ORF4 of Lake Sinai viruses (which infect bees). We discovered that the ORF4 protein contains a domain that has homologues in proteins from >20 taxa of viruses infecting arthropods. We called this domain 'widespread, intriguing, versatile' (WIV), because it is found in proteins with a wide variety of functions and within varied domain contexts. For example, WIV is found in the NSs protein of tospoviruses, a global threat to food security, which infect plants as well as their arthropod vectors; in the RNA2 ORF1-encoded protein of chronic bee paralysis virus, a widespread virus of bees; and in various proteins of cypoviruses, which infect the silkworm Bombyx mori. Structural modelling with AlphaFold indicated that the WIV domain has a previously unknown fold, and bibliographical evidence suggests that it facilitates infection of arthropods.

Orthotospovirus iridimaculaflavi (iris yellow spot virus): An emerging threat to onion cultivation and its transmission by Thrips tabaci in India.

The yellow spot disease caused by the virus species Orthotospovirus iridimaculaflavi (Iris yellow spot virus-IYSV), belonging to the genus Orthotospovirus, the family Tospoviridae, order Bunyavirales and transmitted by Thrips tabaci Lindeman. At present, emerging as a major threat in onion (Allium cepa) in Tamil Nadu, India. The yellow spot disease incidence was found to be 53-73 % in six districts out of eight major onion-growing districts surveyed in Tamil Nadu during 2021-2023. Among the onion cultivars surveyed, the cultivar CO 5 was the most susceptible to IYSV. The population of thrips was nearly 5-9/plant during vegetative and flowering stages. The thrips infestation was 34-60 %. The tospovirus involved was confirmed as IYSV through DAS-ELISA, followed by molecular confirmation through RT-PCR using the nucleocapsid (N) gene. The predominant thrips species present in onion crops throughout the growing seasons was confirmed as Thrips tabaci based on the nucleotide sequence of the MtCOI gene. The mechanical inoculation of IYSV in different hosts viz., Vigna unguiculata, Gomphrena globosa, Chenopodium amaranticolor, Chenopodium quinoa and Nicotiana benthamiana resulted in chlorotic and necrotic lesion symptoms. The electron microscopic studies with partially purified sap from onion lesions revealed the presence of spherical to pleomorphic particles measuring 100-230 nm diameter. The transmission of IYSV was successful with viruliferous adult Thrips tabaci in cowpea (Cv. CO7), which matured from 1st instar larva fed on infected cowpea leaves (24 h AAP). Small brown necrotic symptoms were produced on inoculated plants after an interval of four weeks. The settling preference of non-viruliferous and viruliferous T. tabaci towards healthy and infected onion leaves resulted in the increased preference of non-viruliferous thrips towards infected (onion-61.33 % and viruliferous thrips towards healthy onion leaves (75.33 %). The study isolates shared 99-100 % identity at a nucleotide and amino acid level with Indian isolates of IYSV in the N gene. The multiple alignment of the amino acid sequence of the N gene of IYSV isolates collected from different locations and IYSV isolates from the database revealed amino acid substitution in the isolate ITPR4. All the IYSV isolates from India exhibited characteristic amino acid substitution of serine at the 6th position in the place of threonine in the isolates from Australia, Japan and USA. The phylogenetic analysis revealed the monophyletic origin of the IYSV isolates in India.

Identification of Aggregation Pheromone as an Attractant for Odontothrips loti, A Serious Thrips Pest on Alfalfa.

Odontothrips loti (Haliday) (Thysanoptera: Thripidae) is one of the most serious pests on alfalfa, causing direct damage by feeding and indirect damage by transmitting plant viruses. This damage causes significant loss in alfalfa production. Semiochemicals offer opportunities to develop new approaches to thrips management. In this study, behavioral responses of female and male adults of O. loti to headspace volatiles from live female and male conspecifics were tested in a Y-tube olfactometer. The results showed that both male and female adults of O. loti were attracted to the odors released by conspecific males but not those released by females. Headspace volatiles released by female and male adults were collected using headspace solid-phase microextraction (HS-SPME). The active compound in the volatiles was identified by gas chromatography-mass spectrometry (GC-MS). The analysis showed that there was one major compound, (R)-lavandulyl (R)-2-methylbutanoate. The attractive activity of the synthetic aggregation pheromone compound was tested under laboratory and field conditions. In an olfactometer, both male and female adults showed significant preference for synthetic (R)-lavandulyl (R)-2-methylbutanoate at certain doses. Lures with synthetic (R)-lavandulyl (R)-2-methylbutanoate significantly increased the trap catches of sticky white traps at doses of 40-80 µg in the field. This study confirmed the production of aggregation pheromone by O. loti male adults and identified its active compound as (R)-lavandulyl (R)-2-methylbutanoate, providing a basis for population monitoring and mass trapping of this pest.

Multiple independent origins of duplicated mitochondrial control regions indicate an apomorphy in the Thysanoptera (Insecta).

The mitochondrial genome (mitogenome) of thrips is characterized by the presence of control region (CR) duplication. However, the evolution pattern of duplicated CRs in thrips is still unclear. In this study, the multiple independent origins of duplicated CR indicated that the CR duplication was not an ancestral state for Thysanoptera. The macroevolutionary pattern suggested that the earliest CR duplication event occurred in the middle Cretaceous (94.85 Ma) coincided with rearrangement events forming the ancestors of Aeolothripidae, but much later than that forming the ancestors of the suborder Terebrantia. The mitogenome with duplicated CRs showed a higher rate of gene rearrangement. The sequence similarity of the CR copies and divergence time were negatively correlated, indicating age-related deterioration of mitochondrial function. No significant differences were found in the mitochondrial DNA, the P123 and P4FD between the single and multiple-CR charactered mitogenomes, which suggested that the duplicated CRs may not affect the replication process in thrip mitogenome. The mitogenomes with duplicated CRs (mean: 0.0088 subs/s/my) show a significantly increased evolutionary rate than that with a single one (mean: 0.0058 subs/s/my). However, it seems that this higher evolutionary rate did not have adaptive mechanisms in Terebrantia. We speculated that the duplicated CRs may cause a more intense production of energy by mitochondria, and an accelerated mutation and substitution rate is expected in such mitogenomes. Our study provided new insights into the presence of CR duplications and their evolution in the mitogenomes of thrips.

First Report of Impatiens Necrotic Spot Virus (INSV) Infecting Lettuce in Mexico.

Impatiens necrotic spot virus (INSV; Order Bunyavirales, Family Tospoviridae) is transmitted by several thrips species and has emerged as an important pathogen of lettuce (Lactuca sativa) in several countries (Beris et al., 2020 and Hasegawa & Del Pozo-Valdivia, 2023). In 2023, a total of 22,092 hectares of lettuce were planted in Mexico, with a total production of 523,739 tons (Agri-Food and Fisheries Information Service, 2024). In the last several years, increased outbreaks of a disease showing virus-like symptoms have emerged in lettuce in central Mexico. In all cases, plants exhibited symptoms of yellowing, brown necrotic spots and ringspots on the leaves and midribs, and reduced growth. In fall 2023, symptoms were observed in 12 iceberg lettuce fields, with incidences between 5-70% in the municipality of Tenango del Valle, in the state of Mexico. 18 plants collected from 6 fields were initially tested for the presence of two thrips-transmitted viruses, INSV and tomato spotted wilt virus (TSWV) using ImmunoStrips (Agdia Inc., Elkhart, Indiana), which indicated positive results for INSV in 16 plants and TSWV in 2 plants. None of the plants tested positive for both viruses. Follow up sampling was conducted, which included a total of 17 symptomatic lettuce plants from three fields in October 2023, while an additional 11 lettuce plants were collected from Tepeaca, in the neighboring state of Puebla in March 2024. DAS-ELISA confirmed the presence of INSV in 13/17 plants and TSWV in 2/17 plants from Tenango del Valle, while only INSV was detected in the 11 plants from Tepeaca. Based on ELISA, none of the lettuce samples were co-infected by INSV and TSWV, which was similarly observed in California and Greece (Koike et al., 2008 and Beris et al., 2020). Initially, RNA was purified from 3 plants (two from Tenango del Valle, one from Tepeaca) reverse-transcribed, and PCR amplified with primers to the N gene of the INSV S RNA, as previously described (Hasegawa et al., 2022). All three reactions produced a single expected amplicon of 524 bp and were confirmed by bi-directional Sanger sequencing (MCLab, South San Francisco, CA). To obtain the full-length sequences for the N and NSm genes, RNA from a fourth sample (Tenango del Valle) was amplified with primers (Kuo et al., 2014), and Sanger sequenced. The 789 bp N gene (PP726902) shared >99% nucleotide and amino acid identity to the corresponding region of the INSV isolate from orchid in California (KF926828), while the 912 bp NSm gene (PP726901) shared >98% nucleotide and amino acid identity to the INSV isolate from basil in Washington (KX790322). Additionally, all four samples showed >99.5% similarity to one another. INSV was previously reported to affect other crops in Mexico, including tomatillo (Physalis ixocarpa) and pepper (Capsicum spp.) (González-Pacheco and Silva-Rosales, 2013), while TSWV has been reported to infect lettuce (Moreno et al., 2016). To our knowledge, this is the first report of INSV infecting lettuce in Mexico and was the dominant orthotospovirus in lettuce samples that were tested. INSV should be closely monitored throughout central Mexico, where majority of lettuce production occurs. Additional studies are warranted to identify the thrips vector species that are present, and to understand the role of crop and non-crop hosts in the epidemiology of INSV throughout the region.

First Report of Impatiens Necrotic Spot Virus (INSV) Infecting Tomatoes in North Carolina.

Impatiens necrotic spot virus (INSV) (Orthotospovirus impatiensnecromaculae) is a virus in the Order Bunyavirales and Family Tospoviridae. The virus is vectored by several species of thrips and is a serious pathogen of ornamentals and lettuce in the United States (Hasegawa & Del Pozo-Valdivia 2023; Daughtrey, M. L., et al. 1997; Webster, C. G., et al. 2015). In January 2023, tomato plants (Solanum lycopersicum,'Big Dena') with viral symptoms of reduced vigor, wilting, necrotic spots on leaves, and sunken lesions on the stem were observed in one greenhouse in Guilford County, North Carolina (NC) (Figure 1A-C). Disease incidence was low (2%), with only three symptomatic plants in the single greenhouse. Affected plants also had signs of thrips feeding (dead thrips, frass, and feeding scars) present across the whole plant (Figure 1D). Samples were submitted to the NC State Plant Disease and Insect Clinic and tested positive for INSV, but negative for TSWV, using Agdia ImmunoStrips®. RNA was extracted from symptomatic leaf tissue using the IBI Total RNA Mini kit (Plant), and complementary DNA (cDNA) was generated using the ThermoFisher Verso cDNA synthesis kit. A reverse transcriptase (RT)-PCR with INSV nucleocapsid (N) primers (F:5'-ATGAACAAAGCAAAGATTACC-3' and R:5'- TTAAATAGAATCATTTTTCCC-3') was used to confirm INSV presence (Hassani-Mehraban et al. 2016). Full length N cDNA amplicon sequencing [GenBank No. PP658213] revealed 99.62% nucleotide identity to NCBI GenBank accessions KF926828 (orchid in California), MH453554.1 (hosta from NY), and MH453552.1 (foxglove from NY), all of which are INSV N sequences. The infected leaf samples were used to mechanically inoculate Emilia sonchifolia and tomato (cv.'Moneymaker') using standard virological methods. We successfully infected E. sonchifolia with INSV (confirmed with visual mosaic symptoms and positive INSV ImmunoStrip). However, mechanical inoculation of the tomato plants proved unsuccessful. Using the INSV infected E. sonchifolia leaves as an inoculum source, we generated a viruliferous Frankliniella occidentalis (Western flower thrips) cohort and challenged three week old tomatoes using thrips mediated inoculation (adapted from Aramburu et al. 2009 and Rotenberg et al., 2009). Twenty days post-inoculation, tomatoes with thrips feeding scars were symptomatic for INSV infection with chlorotic and necrotic spots, stunting, and reduced vigor. INSV infection of these tomato plants was verified with a positive INSV ImmunoStrip® result, two-step RT-PCR amplification of N, and Sanger sequencing of N. Samples from thrips-inoculated tomato plants did not test positive for TSWV. Sequence alignment showed that the recovered virus sequence was 99.85% identical to the original INSV sequence from the diagnostic sample (a single nucleotide difference). To the best of our knowledge, this is the first instance of INSV infecting tomato in NC production systems. Although TSWV is more common in vegetable production in NC (253 cases of TSWV compared to 1 case of INSV in vegetable crops based on NC State Plant Disease and Insect Clinic records since 2008), INSV incursion into tomato producing areas is concerning and should be closely monitored, especially at the transplant stage. This report also underscores the importance of using thrips vectors to transmit virus in screening for susceptibility to orthotospoviruses.

Spatiotemporal Patterns of Iris Yellow Spot Virus and Its Onion Thrips Vector, Thrips tabaci, in Transplanted and Seeded Onion Fields in New York.

Onion thrips, Thrips tabaci (Lindeman), transmits iris yellow spot virus (IYSV) and is one of the most important pests of Allium crops. IYSV is a member of the species Tospovirus iridimaculaflavi in the genus Orthotospovirus of the family Tospoviridae. This virus typically reduces overall onion bulb quality and weight but can also prematurely kill onion plants. IYSV is neither seed nor mechanically transmitted. Onion fields are typically established via seeds and transplants. A decade ago, onion thrips tended to colonize transplanted fields before seeded fields because plants in transplanted fields were larger and more attractive to thrips than smaller onions in seeded fields. Therefore, we hypothesized that the incidence of IYSV in transplanted fields would be detected early in the season and be spatially aggregated, whereas IYSV would be absent from seeded fields early in the season and initial epidemic patterns would be spatially random. In 2021 and 2022, IYSV incidence and onion thrips populations were quantified in 12 onion fields (four transplanted fields and eight seeded fields) in New York. Fields were scouted four times throughout the growing season (n = 96 samples), and a geospatial and temporal analysis of aggregation and incidence was conducted to determine spatiotemporal patterns in each field type. Results indicated that spatial patterns of IYSV incidence and onion thrips populations were similar early in the season, indicating that transplanted onion fields are no longer the dominant early-season source of IYSV in New York. These findings suggest the need to identify other important early-season sources of IYSV that impact New York onion fields.

Identifying Onion Fields at Risk of Iris Yellow Spot Virus in New York.

Iris yellow spot virus (IYSV) poses a significant threat to dry bulb onion, Allium cepa L., production and can lead to substantial yield reductions. IYSV is transmitted by onion thrips, Thrips tabaci (Lindeman), but not via seed. Transplanted onion fields have been major early season sources of IYSV epidemics. As onion thrips tend to disperse short distances, seeded onion fields bordering transplanted onion fields may be at greater risk of IYSV infection than seeded fields isolated from transplanted ones. Additionally, seeded onion fields planted early may be at greater risk of IYSV infection than those seeded later. In a 2-year study in New York, we compared IYSV incidence and onion thrips populations in seeded onion fields relative to their proximity to transplanted onion fields. In a second study, we compared IYSV incidence in onion fields with either small or large plants during midseason. Results showed similar IYSV incidence and onion thrips populations in seeded onion fields regardless of their proximity to transplanted onion fields, while IYSV incidence was over four times greater in large onion plants than in small ones during midseason. These findings suggest a greater risk of onion thrips-mediated IYSV infection in onion fields with large plants compared with small ones during midseason and that proximity of seeded fields to transplanted ones is a poor indicator of IYSV risk. Our findings on IYSV spread dynamics provided valuable insights for developing integrated pest and disease management strategies for New York onion growers.

Mitochondrial Genome Characteristics and Phylogenetic Analysis of Fulmekiola serrata (Kobus) (Thysanoptera: Thripidae).

Sugarcane thrips, Fulmekiola serrata (Kobus) (Thysanoptera: Thripidae), is a common foliar pest that infests sugarcane and is found throughout tropical and subtropical countries. In this study, we obtained and analyzed the complete mitochondrial genome of F. serrata for the first time and explored the phylogenetic relationships of the higher-order elements of Thysanoptera members at the mitochondrial level. The complete mitochondrial genome of F. serrata is 16,596 bp in length and includes 13 protein-coding genes (PCGs), 22 transfer RNA (tRNA) genes, 2 ribosomal RNA (rRNA) genes, and 1 noncoding control region. A+T accounted for 75% of the total bases in the mitochondrial genome of F. serrata, revealing an obvious AT bias. Among the 13 PCGs, except for nad5, which had a start codon of TTG, the remaining genes had ATNs typical of insects (ATA, ATT, ATC, and ATG); nad1, nad2, nad3, and atp8 had incomplete termination codons of TA or T. The remaining nine PCGs were complete with the termination codon TAA. Of the 22 tRNA secondary structures, all were typical cloverleaf secondary structures except for trnS1, which was missing the DHU arm. Compared with the hypothetical ancestral gene arrangement of arthropods, F. serrata presented extensive gene rearrangement, with 23 translocated genes, 8 inverted genes, and 5 shuffled genes. Both maximum likelihood (ML) and Bayesian inference (BI) phylogenetic trees resulted in similar topologies: ((Thripidae + (Stenurothripidae + Aeolothripidae)) + Phlaeothripidae), with Thripidae, Aeolothripidae and Phlaeothripidae being monophyletic groups, whereas F. serrata is closely related to Thrips palmi, and the two are sister groups.

Pest status, molecular evolution, and epigenetic factors derived from the genome assembly of Frankliniella fusca, a thysanopteran phytovirus vector.

BACKGROUND: The tobacco thrips (Frankliniella fusca Hinds; family Thripidae; order Thysanoptera) is an important pest that can transmit viruses such as the tomato spotted wilt orthotospovirus to numerous economically important agricultural row crops and vegetables. The structural and functional genomics within the order Thysanoptera has only begun to be explored. Within the > 7000 known thysanopteran species, the melon thrips (Thrips palmi Karny) and the western flower thrips (Frankliniella occidentalis Pergrande) are the only two thysanopteran species with assembled genomes. RESULTS: A genome of F. fusca was assembled by long-read sequencing of DNA from an inbred line. The final assembly size was 370 Mb with a single copy ortholog completeness of ~ 99% with respect to Insecta. The annotated genome of F. fusca was compared with the genome of its congener, F. occidentalis. Results revealed many instances of lineage-specific differences in gene content. Analyses of sequence divergence between the two Frankliniella species' genomes revealed substitution patterns consistent with positive selection in ~ 5% of the protein-coding genes with 1:1 orthologs. Further, gene content related to its pest status, such as xenobiotic detoxification and response to an ambisense-tripartite RNA virus (orthotospovirus) infection was compared with F. occidentalis. Several F. fusca genes related to virus infection possessed signatures of positive selection. Estimation of CpG depletion, a mutational consequence of DNA methylation, revealed that F. fusca genes that were downregulated and alternatively spliced in response to virus infection were preferentially targeted by DNA methylation. As in many other insects, DNA methylation was enriched in exons in Frankliniella, but gene copies with homology to DNA methyltransferase 3 were numerous and fragmented. This phenomenon seems to be relatively unique to thrips among other insect groups. CONCLUSIONS: The F. fusca genome assembly provides an important resource for comparative genomic analyses of thysanopterans. This genomic foundation allows for insights into molecular evolution, gene regulation, and loci important to agricultural pest status.

Comparative analysis of the two suborders of Thysanoptera and characterization of the complete mitochondrial genome of Thrips parvispinus.

Thrips parvispinus is a serious sucking pest on a number of economically important crops in the oriental region. It has gained importance recently for its drastic range extension distribution as an invasive pest. Here, the complete mitochondrial genome (15,067 bp) of Thrips parvispinus was sequenced and characterized. It possesses 37 genes and the putative noncoding region is duplicated. Comparative analyses of nucleotide diversity, skewness, codon usage bias, and selection pressure in mitochondrial protein-coding genes of the available 31 thrips mitogenomes (24 Terebrantia + 7 Tubulifera) were performed. Phylogenetic analysis showed a sister relationship of T. parvispinus to the clade (T. florum + T. hawaiiensis). Phylogenetic analyses formed the monophyly of subfamilies Phlaeothripinae and Idolothripinae within the family Phlaeothripidae (Suborder Tubulifera). Low nucleotide diversity was indicative of reversal of strand asymmetry in the Tubulifera. Neutrality analysis showed that directional mutation plays a major role in shaping codon usage bias in both suborders. Principal component analysis indicated distinct codon usage patterns in each suborder. Our data suggested weaker selection constrains on Terebrantia than in the Tubulifera. More tubuliferan mitogenomes are required to resolve previous classification hypotheses and elucidate genome evolution in these two suborders.

Double sodium channel mutation, I265T/L1014F, is possibly related to pyrethroid-resistant in Thrips palmi.

Thrips palmi Karny (Thysanoptera: Thripidae) can harm a variety of agricultural crops and transmit plant viruses, causing heavy economic losses. In the Hainan province of China, pyrethroids were sprayed widely to control T. palmi, which leaded to resistance to pyrethroids in T. palmi. The bioassay has shown that the resistance ratio of T. palmi to pyrethroids increases annually. Resistance ratio to λ-cyhalothrin has increased from 10.711 to 23.321 and to cypermethrin has increased from 5.507 to 23.051 for 3 years, 2020-2022. The double mutation (I265T/L1014F) was identified from the field strain for the first time, which were located in the domains I and II of the voltage-gated sodium channel of T. palmi, respectively. The double mutation is probably the reason for the higher resistance of T. palmi in Hainan. The frequencies of the double mutation were 53.33% in HN2020, 70.00% in HN2021, and 96.67% in HN2022. Results indicated that T. palmi had developed different degrees of resistance to pyrethroids in Hainan. This study provides theoretical guidance for the use of insecticides in the field control of thrips.

Comparison of the biology of Frankliniella intonsa and Megalurothrips usitatus on cowpea pods under natural regimes through an age-stage, two-sex life table approach.

Two thrips, Megalurothrips usitatus (Bagnall) and Frankliniella intonsa (Trybom) are major pests of cowpea in South China. To realistically compare the growth, development and reproductive characteristics of these two thrips species, we compared their age-stage, two-sex life tables on cowpea pods under summer and winter natural environmental regimes. The results showed that the total preadult period of M. usitatus was 8.09 days, which was significantly longer than that of F. intonsa (7.06 days), while the adult female longevity of M. usitatus (21.14 days) was significantly shorter than that of F. intonsa (25.77 days). Significant differences were showed in male adult longevity (10.68 days for F. intonsa and 16.95 days for M. usitatus) and the female ratio of offspring (0.67 for F. intonsa and 0.51 for M. usitatus), and the total preadult period of M. usitatus (16.20 days) was significantly longer than that of F. intonsa (13.66 days) in the winter regime. The net reproductive rate (summer: R0 = 85.62, winter: R0 = 105.22), intrinsic rate of increase (summer: r = 0.3020 day-1, winter: r = 0.2115 day-1), finite rate of increase (summer: λ = 1.3526 day-1, winter: λ = 1.2356 day-1) and gross reproduction rate (summer: GRR = 139.34, winter: GRR = 159.88) of F. intonsa were higher than those of M. usitatus (summer: R0 = 82.91, r = 0.2741, λ = 1.3155, GRR = 135.71; winter: R0 = 80.62, r = 0.1672, λ = 1.1820, GRR = 131.26), and the mean generation times (summer: T = 14.73 days, winter: T = 22.01 days) of F. intonsa were significantly shorter than those of M. usitatus (summer: T = 16.11 days, winter: T = 26.25 days). These results may contribute to a better understanding of the bioecology of different thrips species, especially the interspecific competition between two economically important cowpea thrips with the same ecological niche in a changing environment.

Molecular, biochemical, and toxicological characterization of two acetylcholinesterases from the Western flower thrips, Frankliniella occidentalis.

We investigated the molecular and biochemical properties of two acetylcholinesterases (FoAChE1 and FoAChE2) from the Western flower thrips, Frankliniella occidentalis. Polyacrylamide gel electrophoresis and western blotting confirmed the membrane-anchored nature of both FoAChE1 and FoAChE2, which was further supported by hydrophobicity and glycophosphatidylinositol anchor predictions. High expression levels of both enzymes were observed in the head, indicating their predominant distribution in neuronal tissues. FoAChE1 exhibited significantly higher expression levels in all examined tissues compared to FoAChE2, suggesting its major role as a synaptic enzyme. Nonetheless, both recombinant enzymes displayed robust catalytic activity toward acetylthiocholine iodide, and FoAChE1 demonstrated nearly identical catalytic efficiency compared to FoAChE2. FoAChE1 exhibited slightly lower sensitivities to the cholinesterase inhibitors tested, including organophosphates (OPs) and carbamates (CBs), compared to FoAChE2. Field populations of F. occidentalis exhibited polymorphism of alanine vs. serine at position 197 of FoAChE1 within the conserved oxyanion hole. Contrary to common belief, however, functional analysis using recombinant enzymes revealed that neither A197 nor S197 residue was associated with FoAChE1 insensitivity to OPs and CBs. FoAChE2 did not exhibit any polymorphic amino acid substitutions at the positions known to be associated with resistance. Due to the absence of apparent resistance-associated mutations in field populations of F. occidentalis, the judicious use of some OPs or CBs can be suggested for controlling the highly resistant populations to other insecticides. Overall, our findings highlight the significance of both FoAChE1 and FoAChE2 as targets for toxicity assessment, while the specific contribution of each enzyme to toxicity remains unclear.

First Report of Tomato Spotted Wilt Virus infecting Lettuce in Yuma, Arizona.

Tomato spotted wilt virus (TSWV, family Tospoviridae, genus Orthotospovirus) is a thrips-vectored pathogen that infects lettuce (Lactuca sativa) and many vegetable crops (Kuo et al. 2014, Hasegawa et al. 2022). Another thrips-borne pathogen of lettuce, impatiens necrotic spot virus (INSV, Tospoviridae, Orthotospovirus), was first reported in 2021 in Yuma, Arizona (Hasegawa et al. 2022). Symptoms of both viruses in lettuce are similar and include necrotic spotting, leaf chlorosis and plant stunting (Kuo et al. 2014). Beginning February through April of 2022, lettuce displaying symptoms of orthotospovirus infection was collected from romaine lettuce (var. longifolia) fields in three regions of Yuma County. A total of 96 plants were collected (5 from Tacna on 2/21, 5 from Wellton on 2/21, 15 from Wellton on 3/23, 30 from Tacna on 4/4, 20 from Wellton on 4/4, and 21 from Yuma Valley on 4/4). The area of the fields ranged from 10 to 18 acres, and the percent disease incidence ranged from 0.8% (Tacna on 4/4) to 2.75% (Tacna on 2/21). Thrips vector were present in all fields were symptomatic plants were observed. One leaf disk per plant (8 mm in diameter) was sampled with a cork borer and grounded individually with a micro pestle in a 1.7 ml microcentrifuge tube with 150 ul of Tri-reagent (Molecular Research Center). Total RNA was extracted from each sample using the Zymo Direct-zol-96 kit (Zymo Research). Samples were diluted with water to a ratio of 1:10 after RNA extraction. RT-qPCR was performed in 20 ul reactions with 5 ul of input RNA using the PCR Biosystems qPCRBIO Probe 1-Step Go No-ROX for the cDNA/qPCR master mix. RT-qPCR assays were carried out in multiplex reactions using primers specific for TSWV and INSV, in addition to a lettuce internal control gene (LOC111918243), along with negative controls. Primer and probe sequence details are reported in supplemental Table 1. We used a cycle threshold (ct) < 40 to indicate a positive result for both INSV and TSWV (Chen et al. 2013; Boonham et al. 2002). RT-qPCR successfully amplified INSV in 90 out of 96 samples and TSWV in 8 out of 96 samples. These 8 samples tested positive for both TSWV and INSV, showing that INSV and TSWV co-infected lettuce plants. Thus overall, ∼ 95% of symptomatic plants were infected with INSV alone, and ∼ 8% were co-infected with TSWV and INSV. Amplicons of 4 samples testing positive for TSWV were sent for Sanger sequencing (Eurofins Genomics, Louisville, KY). All were identified as TSWV. One amplicon with TSWV was sequenced for INSV and double infection was confirmed. BLAST results from the NCBI nt database show 100% (138 bp) identity to TWSV (MW519211) for the 4 TWSV amplicons and 99.22% (137 bp) identity to INSV (KX790323) for the INSV amplicon. Sanger sequence data are in the GenBank (accession: OQ685940-OQ685944). Based on RT-qPCR results, all TSWV infected plants were also infected with INSV. INSV may have been introduced to Yuma by infected plants or thrips from lettuce transplants produced in California (Hasegawa et al. 2022). TSWV could have been introduced similarly. To our knowledge, this is the first report of TSWV infecting lettuce in Yuma and the first report of INSV and TSWV co-infecting lettuce. TSWV and INSV infections have remained low since their discovery in Yuma, in part due to effective cultural and chemical management by lettuce growers (Palumbo, 2022). However, an increase in disease incidence and severity in the future could have a significant negative impact on production of romaine lettuce in the region.

Epidemiology and Economic Impact of Impatiens Necrotic Spot Virus: A Resurging Pathogen Affecting Lettuce in the Salinas Valley of California.

The Orthotospovirus impatiens necrotic spot virus (INSV) is a thrips-transmitted pathogen of lettuce that has rapidly emerged as a serious threat to production in the Salinas Valley of Monterey County, California. As a first step toward understanding the severity of the virus, we utilized Spatial Analysis by Distance IndicEs (SADIE) to characterize the distribution and progression of INSV outbreaks and thrips infestations in two commercial lettuce fields. In both fields, INSV incidence rapidly increased from 15.86% ± 1.77 to 80.24% ± 2.60 over the course of 7 weeks and aggregated at specific edges in both fields as early as 3 weeks after planting (Ia = 1.63, Pa = 0.0100, and Ia = 1.53, Pa = 0.0300). In one of the fields, thrips populations aggregated in areas that also experienced the most INSV (Ia = 1.2435, Pa = 0.0400, week 3; Ia = 1.4815, Pa < 0.0001, week 6; Ia = 1.5608, Pa < 0.0001, week 9), while in the second field, thrips were distributed randomly despite the aggregated effects that were observed for INSV incidence. Economic analysis estimated that the virus accounted for over $475,000 in losses for the two fields, while stakeholder surveys documented over 750 fields that experienced INSV infection during the 2021 season in Monterey County alone. These studies enhance our knowledge on the epidemiology of thrips and INSV under current lettuce production practices in the Salinas Valley, while elucidating the economic consequences and broader challenges that are associated with managing thrips-transmitted viruses.

Multigenerational variation in the nutrients and digestion of western flower thrips (Frankliniella occidentalis) depends on the nutritive quality of different foods.

Western flower thrips (WFTs), Frankliniella occidentalis (Thysanoptera, Thripidae), is one of the most serious pests that attack rose flowers. Little is known about the effect of different parts of the rose flower on nutritional contents and digestive enzyme activities in thrips. This study assessed variations in the nutritional contents and digestive enzyme activities in the second-instar larvae and adults WFTs fed on 3 food types (rose petals, rose flowers, and honey solution + kidney bean pods) for multiple generations. The highest contents of soluble sugar (in 10% honey solution + kidney bean pods), amino acid (in rose flowers), and protein (in rose flowers) were observed, respectively. Soluble sugar and protein contents in the second-instar larvae and adults fed on rose petals decreased in the F1 generation but increased in the F2 generation and remained at higher levels until the F7 generation. Feeding of thrips with 3 food types increased the lipid content in the F1 generation, which peaked in the F2 generation and remained high until the F7 generation. In most cases, α-amylase and trypsin activities significantly decreased in the F1 generation after feeding on rose petals and then prominently increased in the F2 generation. In contrast, chymotrypsin activity remarkably increased and peaked in the F1 generation after second-instar larvae thrips fed on rose petals. There were correlations among the contents of 3 nutrient related positively with the activities of α-amylase and trypsin in WFTs second-instar larvae and adults, respectively. Overall, variations in the nutrient properties of the 3 food types caused changes in nutrient contents and digestive enzyme activities in thrips.

Sublethal effects of emamectin benzoate on development, reproduction, and vitellogenin and vitellogenin receptor gene expression in Thrips hawaiiensis (Thysanoptera: Thripidae).

Thrips hawaiiensis (Morgan) (Thysanoptera: Thripidae) is a sap-sucking pest that seriously damages several crops and reduces their economic value. Exposure to low concentrations of insecticides may have a sublethal effect on surviving insects. In order to provide a reference for the rational application of emamectin benzoate, its sublethal effects on the development and reproduction of T. hawaiiensis were evaluated. Pupal development time was significantly shorter in T. hawaiiensis treated with sublethal concentrations of emamectin benzoate (LC10 and LC20) than in control. Female adult longevity and female total longevity were significantly longer following LC20 treatment than in the control and LC10 treatment groups. Nevertheless, male adult longevity and male total longevity were significantly shorter in the LC10 treatment group than in the control and LC20 treatment groups. The sublethal concentration of emamectin benzoate (LC20) significantly shortened the preadult stages and the mean generation. Meanwhile, it significantly increased the finite rate of increase, intrinsic rate of increase, and net reproductive rate. The fecundity was significantly higher after LC20 treatment than after LC10 and control treatments. Compared with the control group, the LC10 and LC20 groups of T. hawaiiensis adults showed a significantly higher expression of the vitellogenin (Vg) and vitellogenin receptor (VgR) genes, which played a key role in increasing their fecundity. These findings suggest that short-term exposure to sublethal concentrations of emamectin benzoate may lead to a resurgence and secondary outbreak of T. hawaiiensis infestation. The results have practical applications for the management of this important and noxious pest.