Efficient detection of Frankliniella schultzei (Thysanoptera, Thripidae) by cytochrome oxidase I gene (mtCOI) direct sequencing and real-time PCR

Leão, Evelynne Urzêdo; Spadotti, David Marques de Almeida; Rocha, Kelly Cristina G.; Lima, Élison Fabricio B.; Tavella, Luciana; Turina, Massimo; Krause-Sakate, Renate

doi:10.1590/1678-4324-2017160425

ABSTRACT

Identification of Thysanoptera is based mainly on external morphology examination that can be time-consuming and difficult for non taxonomic experts. In this work, we propose a rapid and efficient molecular method to identify Frankliniella schultzei, an important and widespread pest thrips vector of tospoviruses in South America countries. Species-specific primers designed in the mitochondrial cytochrome oxidase I gene (mtCOI) were optimized for detection by conventional PCR and real-time PCR. The primers were tested on immature and adult thrips collected from crops and weeds found in São Paulo State. All samples collected were identified as F. schultzei, indicating the high prevalence of this species as vector of tospoviruses in Brazilian fields.

Key words:
molecular identification; real-time PCR; tospovirus vector

INTRODUCTION

Although the agricultural importance of thrips has increased considerably in the last decades, their identification, the first step for decision-making in pest management, remains as an obstacle. Currently, identification in Thysanoptera is based mainly on external morphology examination after a time-consuming slide preparation ¹⁷17 Mound LA, Marullo R. The thrips of Central and South America: an introduction (Insecta: Thysanoptera). Mem Entomol Intl. 1996; 6: 1-487.. Even with alternative and faster slide mounting methods ¹³13 Mirab-balou M; Chen XX. First description of the male of the wheat thrips, Anaphothrips obscurus (Thysanoptera: Thripidae). Zootaxa. 2010; 2540: 65-68.^,¹⁶16 Mound LA, Kibby G. Thysanoptera. An Identification Guide. 2nd Edition. Wallingford, UK, CABI International. 70 pp. 1998., morphological assessment of characters useful for determination of species is not trivial and requires a good level of expertise. While taxonomists are supposed to know how to access thrips morphology, it constitutes a real problem for economic entomologists that require named species for their works. For phytopathologists, this problem is even worse as thrips transmit tospoviruses during first and early second instars, and morphological identification of Thysanoptera larvae is even more limited.

The common blossom thrips or tomato thrips, Frankliniella schultzei (Trybom) is native to South America ¹⁸18 Mound LA. Thysanoptera biodiversity in the Neotropics. Rev Biol Trop. 2002; 50 (2): 477-484. and is one of the major pests of various ornamental and vegetable crops in tropical regions ²¹21 Sakurai T. Transmission of Tomato spotted wilt virus by the dark form of Frankliniella schultzei (Thysanoptera: Thripidae) originating in tomato fields in Paraguay. Appl Entomol Zool. 2004; 39: 189-194.. Besides the direct damages to several crops, the indirect damages are becoming increasingly important with tospovirus transmission reports in crops such as tomato (Solanum lycopersicum L.), sweet pepper (Capsicum annum L.), watermelon Citrullus lanatus (Thunb.) Matsum. & Nakai, cucumber (Cucumis sativus L.) and peanuts (Arachis hypogaea L.), in Brazil ⁵5 Camelo-García VM, Lima EFB, Mansilla-Córdova PJ, Rezende JAM, Kitajima EW, Barreto M. Occurrence of Groundnut ringspot virus on Brazilian peanut crops. J Gen Plant Pathol. 2014; 80:282-286.^,¹¹11 Leão EU, Spadotti DMA, Rocha KCG, Pantoja KFC, Rezende JAM, Pavan MA, et al. Citrullus lanatus is a new natural host of Groundnut ringspot virus in Brazil. J Phytopathol. 2014; 165:1014-1018.^,¹⁴14 Monteiro RC, Mound LA, Zucchi RA. Espécies de Frankliniella (Thysanoptera: Thripidae) de importância agrícola no Brasil. Neotrop Entomol. 2001;1, 65-71.^,²²22 Spadotti DMA, Leão EU, Rocha KCG, Pavan MA, Krause-Sakate R. First report of Groundnut ringspot virus in cucumber fruits in Brazil. New Dis Rep. 2014; 29: 25-25.. Whereas there are a few molecular identification tools for some pest thrips ¹1 Asokan R, Krishna Kumar N, Kumar V, Ranganath H. Molecular differences in the mitochondrial cytochrome oxidase I (mtCOI) gene and development of a species-specific marker for onion thrips, Thrips tabaci Lindeman, and melon thrips, T. palmi Karny (Thysanoptera: Thripidae), vectors of tospoviruses (Bunyaviridae). Bull Entomol Res. 2007; 97: 461-470.^,⁴4 Brunner PC, Chatzivassiliou EK, Katis NI, Frey JE. Host-associated genetic differentiation in Thrips tabaci (Insecta; Thysanoptera), as determined from mtDNA sequence data. Heredity. 2004; 93:364-370.^,⁶6 Frey JE; Frey B. Origin of intra-individual variation in PCR-amplified mitochondrial cytochrome oxidase I of Thrips tabaci (Thysanoptera: Thripidae): mitochondrial heteroplasmy or nuclear integration? Hereditas. 2004:140: 92-98.^,⁹9 Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148.^,²⁴24 Timm AE, Stiller M, Frey JE. A molecular identification key for economically important thrips species (Thysanoptera: Thripidae) in southern Africa. Afr Entomol. 2008; 16:68-75.^,²⁶26 Zhang GF, Meng XQ, Min L, Qiao WN, Wan FH. Rapid Diagnosis of the Invasive Species, Frankliniella occidentalis (Pergande): A Species- Specific COI Marker. J Appl Entomol. 2011; 136: 410-420., only F. occidentalis (Pergande) and Thrips palmi Karny can be identified at present using real-time PCR technique ⁷7 Huang KS, Lee SE, Yeh Y, Shen GS, Mei E, Chang CM. Taqman real-time quantitative PCR for identification of western flower thrips (Frankliniella occidentalis) for plant quarantine. Biol Lett. 2010; 6:555-557.^,⁹9 Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148.. Tools for rapid molecular identification of F. schultzei are absent and the determination of this major pest is mainly based on traditional methods.

In this work, we designed a primer pair for F. schultzei based on the mitochondrial cytochrome oxidase I gene (mtCOI), a marker well suited for species discrimination within Thysanoptera ⁸8 Kadirvel P, Srinivasan R, Hsu YC, Su FC, La Peña R. Application of cytochrome oxidase I sequences for phylogenetic analysis and identification of thrips species occurring on vegetable crops. J Econ Entomol. 2013; 106 (1): 408-418.. The primer pair was optimized for PCR and real-time PCR detection. F. schultzei was the mainly thrips species found on vegetables and weeds collected in São Paulo State, indicating the high prevalence of this species as vector of tospoviruses.

MATERIALS AND METHODS

Adult and immatures of F. schultzei were collected on vegetables and weeds using a hand-held aspirator from 2012 to 2014 in several sites in the state of São Paulo, Brazil (table 1). The specimens were preserved immediately in 70% ethanol and stored at -20ºC prior to morphological and molecular analysis. For molecular analysis, adults of F. occidentalis (from Italy and Brazil), F. intonsa (Trybom) and T. tabaci Lindeman (from Northern Italy) were equally collected and stored. For morphological identification, adults of Brazilian specimens were prepared in microscope slides and identified following Mound and Marullo ¹⁷17 Mound LA, Marullo R. The thrips of Central and South America: an introduction (Insecta: Thysanoptera). Mem Entomol Intl. 1996; 6: 1-487.. The morphological features used in the identification of F. schultzei were the fore wing with two complete rows of setae; prothorax with five pairs of main setae; absence of companiforme sensilo in the metanotum; pedicel of the antenna is simple; abdomen showing an incomplete developed comb and head showing interocellar setae (data not shown). Italian specimens were identified under a stereomicroscope at 100× magnification using taxonomic keys Mound et al. ¹⁵15 Mound LA, Morison GD, Pitkin BR, Palmer JM. Thysanoptera. In: A. Watson A, Handbooks for the Identification of British Insects. Royal Entomological Society of London, London, UK; 1976. and Palmer et al. ¹⁹19 Palmer JM, Mound LA, du Heaume GJ. Thysanoptera, CIE Guides to Insects of Importance to Man. 2, Thysanoptera. CAB International Institute of Entomology, London, UK, 1-73p.1989..

PRELIMINARY EXTRACTION AND SEQUENCING

For the first PCR assay, total DNA was extracted from each individual thrips following a modified Chelex method ²2 Boonham N, Smith P, Walsh K, Tame J, Morris J, Spence N. et al. The detection of Tomato spotted wilt virus (TSWV) in individual thrips using real-time fluorescent RT-PCR (TaqMan). J Virol Methods. 2002; 101:37-48.. Briefly, adults thrips were crushed and homogenized in a 50 µl of Chelex 5% solution in a 0.5 ml Eppendorf tube and then incubated at 94°C for 5 min. After centrifugation at 14,000 g for 5 min, the supernatant was collected and used as template for PCR amplification.

DNA samples were subjected to PCR analysis with the primers mtD-7.2F and mtD-9.2R (table 1)³3 Brunner PC, Fleming C, Frey JE. A molecular identification key for economically important thrips species (Thysanoptera: Thripidae) using direct sequencing and a PCR-RFLP-based approach. Agric Forest Entomol. 2002; 4:127-136.. Amplification was performed in 25 μl total reaction volumes, contained 3 μl of DNA, 12.5 μl Taq DNA Polymerase Master Mix Ampliqon III (Ampliqon ApS, Copenhagen, Denmark), and 0.25 µl of each primer. This solution was submitted in thermal cycler with the following parameters: 3 min at 94° C, 35 cycles of 30 s at 95 °C, 30 s at 55 °C, 45 s at 72 °C, and a final extension of 5 min at 72 °C. After amplification, 6 μl of the PCR products were subjected to electrophoresis on a 1 % agarose gel stained with Neotaq Brilliant Green Plus DNA Stain (Neobio, Brazil).

PCR products amplified from mtCOI of thrips were purified (QIAquick Gel Extraction Kit Qiagen) and sequenced (Macrogen, South Korea) using the primer mtD-7.2F. Sequence chromatograms were manually checked and edited in BioEdit software (version 7.1). DNA sequences were compared with the corresponding sequences of other thrips species deposited in GenBank and aligned using Clustal W in MEGA software ²³23 Tamura K, Peterson D, Peterson N, Stecher G, Nei M. et al. MEGA5: Molecular Evolutionary Genetics Analysis using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Mol Biol Evol. 2011; 28:2731-273.. A phylogenetic tree was constructed using the neighbour-joining method with 2000 bootstrap replications through MEGA software.

SPECIES SPECIFIC ASSAY DESIGN AND VALIDATION

In the PCR assays with species-specific primers, individuals thrips were crushed and homogenized in a 10 µl of a Milli-Q water in a 0.5 ml Eppendorf tube. The tube was incubated in boiling water for 5 min, stored at 20 °C for 10 min and centrifuged at 8,000 g for 5 min. Three micro liters of the supernatant were used as template for real time PCR and 5 µl were used for specific primer PCR analysis.

One set of primers targeted on the region of mtCOI gene specifically for F. schultzei was designed and called FS.rev and FS.for primers (Table 1). The specificity of the F. schultzei-specific COI primers was evaluated performing PCR assays on four thrips species (table 1). PCR assays were performed for each thrips sample with a total volume of 25 µl as follows: 5 µl of DNA, 2.5 µl of 10x Buffer, 1.0 µl of MgCl₂ (50 mM), 2.5 µl of dNTP’s (2 mM each), 0.5 µl of each primer (final primer concentration of 10 µM each), and 0.125 µl of Polytaq (Polymed, Florence, Italy). The reaction was performed in thermal cycler using the following parameters: 3 min at 94 °C, 35 cycles of 30 s at 95 °C, 30 s at 55 °C, and 40 s at 72 °C, followed by a final extension for 5 min at 72 °C. After amplification, the PCR products were subjected to electrophoresis.

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Table 1
Primers used in PCR assays.

To select the optimal primer concentration, a 10-fold dilution series of positive DNA from F. schultzei was tested in a real-time PCR using concentrations of 50, 150, 300 or 900 nM of primers FS.rev and FS.for. After that, real-time PCR reactions were performed in a 96 well plates (Bio-Rad, California, USA) containing 3 μl DNA, 0.3 μl of primers FS.rev and FS.for (10 µM each), and 5 μl of iTaq™ Universal SYBR^® Green Supermix (Bio-Rad), in a final volume of 10 μl. The SYBR Green PCR amplifications were undertaken in a CFX Connect™ Real-Time PCR detection system (Bio-Rad) with a CFX Manage Software (Bio-Rad). The reactions were run at least in triplicate. The thermal profile for SYBR PCR was 95 °C for 3 min followed by 40 cycles of 95 °C for 10 s and 60 °C for 30 sec.

RESULTS

The thrips specimens collected from watermelon, pumpkin (Cucurbita sp. L.), tomato, sweet pepper, lettuce (Lactuca sativa L.), cucumber, Tridax procumbens and Emilia sonchifolia were identified as F. schultzei by molecular and morphological methods (Table 2). The PCR amplification with the primers mtD7.2F and mtD-9.2R produced only a single band of 450 bp. Two sequences of F. schultzei mtCOI gene were deposited in GenBank (under accession numbers KJ175069 and KJ175070, respectively). BLAST results showed significant identity (95-100%) between the sequences of the mtCOI gene of F. schutzei with the corresponding nucleotide sequences of F. schutzei deposited in GenBank (accession number KF560548). The phylogenetic tree (Fig. 1) shows that the sequences of F. schultzei obtained in this study are close to those reported in Florida (USA) (accession number KF560548). The other thrips species, F. occidentalis (KC008075), F. intonsa (AB277215) and T. tabaci (FN546159) were clustered into separate branches.

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Table 2
Samples and localities of thrips specimens collected and results of DNA based methods for molecular identification.

Figure 1
Phylogenetic relationships of Frankliniella schultzei mtCOI gene sequences (450bp) of samples (in bold) collected from different crops and weeds in São Paulo state. The tree was constructed by neighbor-joining method with the MEGA 5.0 software. Numbers at the nodes indicate the frequency of the cluster after bootstrap analysis (2000 replicates). Only bootstrap values above 50% are shown. KF560548 - F. schultzei from USA; KC008075 - F. occidentalis from New Zealand; AB277215 - F. intonsa from China; FN546159 - Thrips tabaci from USA.

The specificity of the PCR with the F. schultzei-specific COI primers (FS.rev and FS.for) was tested by performing PCR using DNA isolated from the thrips listed in table 2. The single amplicon (145 bp) was only obtained from F. schultzei specimens, and the others three species were negative in our PCR assay. The PCR was checked twice to make sure that the negative results were not caused by inhibition or inefficient DNA extraction.

At 300 nM of primer concentration, cycle threshold (Ct) values were optimal and the DNA positive final dilution end was 1:100 (data not shown). All F. schultzei specimens were positive in the real-time PCR assay with the Ct- values ranging from 16.05 - 19.65 (Fig. 2A). Adult and immature stages were positives, demonstrating the sensitivity of the assay and validating the specificity of the primers. The DNA of F. occidentalis, F. intonsa and T. tabaci were no amplified by the primers. These species were used because they are closely related to F. schultzei, and are also commonly found associated with several crops in Brazil and worldwide. The corresponding dissociation curves of the samples are showed in Figure 2B.

Figure 2
(A) Specific amplification curve of Frankliniella schultzei, collected at young stage (larvae - red line) and adult in differents crops (watermelon - pink, purple and green lines; pumpkin - blue; cucumber - orange line). Other four thrips species including F. occidentalis (Brazil), F. occidentalis (Italy), F. intonsa and Thrips tabaci did not show any positive signal (black lines). The mean Ct-values for each samples are given in a Table. (B) The corresponding dissociation curves of F. schultzei. The melting temperature (Tm) of each amplicon is shown alongside its dissociation curve.

DISCUSSION

The small size and cryptic behaviour of thrips make their monitoring and the identification processes difficult. In such a huge and biodiverse country as Brazil, where the Thysanoptera diversity is high, the correct thrips identification can be even more challenging. Our PCR assay using a F. schultzei-specific COI primer was accurate, demonstrating that can be used in other studies of molecular identification. The development of species-specific primers from PCR assays is an important tool to assist and speed up the correct identification of thrips species. Species-specific primers require only conventional PCR, which is readily available, rapid and inexpensive. The species-specific primers that have been identified in this study will enable even a non-specialist to identify F. schultzei. Apart from this, molecular identification has the obvious advantage of making possible the identification when only immature stages are available. However, these primers should be applied cautiously among populations of F. schultzei outside South and North America, as there may be the existence of other variants that may misidentify other thrips species. At present, pale and dark coloured specimens of F. schultzei are considered conspecific, but we did not include pale individuals in our study.

The real-time PCR assay as described here is rapid, specific and sensitive, easy and quick to perform for identification of F. schultzei in institutions research. The time necessary to obtain definitive results with this method is less than one working day. At present, only three real-time PCR assays have been developed for the identification of thrips species: two specific for T. palmi⁹9 Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148.^,²⁵25 Walsh K, Boonham N, Barker I, Collins DW. Development of a sequence-specific real-time PCR to the melon thrips Thrips palmi (Thysanoptera: Thripidae). J Appl Entomol 2005; 129:272-279. and one specific to F. occidentalis⁷7 Huang KS, Lee SE, Yeh Y, Shen GS, Mei E, Chang CM. Taqman real-time quantitative PCR for identification of western flower thrips (Frankliniella occidentalis) for plant quarantine. Biol Lett. 2010; 6:555-557.. All these assays are based on TaqMan chemistry and just in the study of Kox et al. ⁹9 Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148. is used the mtCOI gene as target gene.

Although the equipment is expensive, the use of real-time PCR is rapid, accurate, can be applied in large-scale process of identifying species that are found in plants and / or plant material derived from trade, and is suitable with insects caught on sticky traps ¹²12 Mehle N; Trdan S. Traditional and modern methods for the identification of thrips (Thysanoptera) species. J Pest Sci. 2012; 85:179-190., when morphological identification is sometimes difficult due to the loss of several strucutres.

Due to F. schultzei prevalence in many countries ¹⁷17 Mound LA, Marullo R. The thrips of Central and South America: an introduction (Insecta: Thysanoptera). Mem Entomol Intl. 1996; 6: 1-487., this method can be essential for the control of plant material to prevent further spread of this vector thrips in areas where it is not yet present or even in the entrance of new tospoviruses in Brazil. As we known F. schultzei also can transmitted Capsicum chlorosis virus (CaCV) and Groundnut bud necrosis virus (GBNV) ¹⁰10 Lakshmi KV, Wightman JA, Reddy DVR, Rao GVR, Buiel AAM, Reddy DDR. Transmission of peanut bud necrosis virus by Thrips palmi in India. Thrips biology and management: proceedings of the 1993 International Conference on Thysanoptera. Ed Parker BL, Skinner M and Lewis T. 1995. p. 179-184^,²⁰20 Persley DM, Thomas JE, Sharman M. Tospoviruses -an Australian perspective. Australas Plant Pathol. 2006; 35:161-180., that by the time has not been reported in Brazil.

CONCLUSIONS

In this study we got sequencing several specimens of F. schultzei and we confirmed the presence of this species in different crops and regions in the São Paulo state. This result may lead us to believe that F. schultzei is the largest tospovirus vector in these regions. We also observed that in plants infected with GRSV, the presence of this insect was high.

REFERENCES

¹
Asokan R, Krishna Kumar N, Kumar V, Ranganath H. Molecular differences in the mitochondrial cytochrome oxidase I (mtCOI) gene and development of a species-specific marker for onion thrips, Thrips tabaci Lindeman, and melon thrips, T. palmi Karny (Thysanoptera: Thripidae), vectors of tospoviruses (Bunyaviridae). Bull Entomol Res. 2007; 97: 461-470.
²
Boonham N, Smith P, Walsh K, Tame J, Morris J, Spence N. et al. The detection of Tomato spotted wilt virus (TSWV) in individual thrips using real-time fluorescent RT-PCR (TaqMan). J Virol Methods. 2002; 101:37-48.
³
Brunner PC, Fleming C, Frey JE. A molecular identification key for economically important thrips species (Thysanoptera: Thripidae) using direct sequencing and a PCR-RFLP-based approach. Agric Forest Entomol. 2002; 4:127-136.
⁴
Brunner PC, Chatzivassiliou EK, Katis NI, Frey JE. Host-associated genetic differentiation in Thrips tabaci (Insecta; Thysanoptera), as determined from mtDNA sequence data. Heredity. 2004; 93:364-370.
⁵
Camelo-García VM, Lima EFB, Mansilla-Córdova PJ, Rezende JAM, Kitajima EW, Barreto M. Occurrence of Groundnut ringspot virus on Brazilian peanut crops. J Gen Plant Pathol. 2014; 80:282-286.
⁶
Frey JE; Frey B. Origin of intra-individual variation in PCR-amplified mitochondrial cytochrome oxidase I of Thrips tabaci (Thysanoptera: Thripidae): mitochondrial heteroplasmy or nuclear integration? Hereditas. 2004:140: 92-98.
⁷
Huang KS, Lee SE, Yeh Y, Shen GS, Mei E, Chang CM. Taqman real-time quantitative PCR for identification of western flower thrips (Frankliniella occidentalis) for plant quarantine. Biol Lett. 2010; 6:555-557.
⁸
Kadirvel P, Srinivasan R, Hsu YC, Su FC, La Peña R. Application of cytochrome oxidase I sequences for phylogenetic analysis and identification of thrips species occurring on vegetable crops. J Econ Entomol. 2013; 106 (1): 408-418.
⁹
Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148.
¹⁰
Lakshmi KV, Wightman JA, Reddy DVR, Rao GVR, Buiel AAM, Reddy DDR. Transmission of peanut bud necrosis virus by Thrips palmi in India. Thrips biology and management: proceedings of the 1993 International Conference on Thysanoptera. Ed Parker BL, Skinner M and Lewis T. 1995. p. 179-184
¹¹
Leão EU, Spadotti DMA, Rocha KCG, Pantoja KFC, Rezende JAM, Pavan MA, et al. Citrullus lanatus is a new natural host of Groundnut ringspot virus in Brazil. J Phytopathol. 2014; 165:1014-1018.
¹²
Mehle N; Trdan S. Traditional and modern methods for the identification of thrips (Thysanoptera) species. J Pest Sci. 2012; 85:179-190.
¹³
Mirab-balou M; Chen XX. First description of the male of the wheat thrips, Anaphothrips obscurus (Thysanoptera: Thripidae). Zootaxa. 2010; 2540: 65-68.
¹⁴
Monteiro RC, Mound LA, Zucchi RA. Espécies de Frankliniella (Thysanoptera: Thripidae) de importância agrícola no Brasil. Neotrop Entomol. 2001;1, 65-71.
¹⁵
Mound LA, Morison GD, Pitkin BR, Palmer JM. Thysanoptera. In: A. Watson A, Handbooks for the Identification of British Insects. Royal Entomological Society of London, London, UK; 1976.
¹⁶
Mound LA, Kibby G. Thysanoptera. An Identification Guide. 2nd Edition. Wallingford, UK, CABI International. 70 pp. 1998.
¹⁷
Mound LA, Marullo R. The thrips of Central and South America: an introduction (Insecta: Thysanoptera). Mem Entomol Intl. 1996; 6: 1-487.
¹⁸
Mound LA. Thysanoptera biodiversity in the Neotropics. Rev Biol Trop. 2002; 50 (2): 477-484.
¹⁹
Palmer JM, Mound LA, du Heaume GJ. Thysanoptera, CIE Guides to Insects of Importance to Man. 2, Thysanoptera. CAB International Institute of Entomology, London, UK, 1-73p.1989.
²⁰
Persley DM, Thomas JE, Sharman M. Tospoviruses -an Australian perspective. Australas Plant Pathol. 2006; 35:161-180.
²¹
Sakurai T. Transmission of Tomato spotted wilt virus by the dark form of Frankliniella schultzei (Thysanoptera: Thripidae) originating in tomato fields in Paraguay. Appl Entomol Zool. 2004; 39: 189-194.
²²
Spadotti DMA, Leão EU, Rocha KCG, Pavan MA, Krause-Sakate R. First report of Groundnut ringspot virus in cucumber fruits in Brazil. New Dis Rep. 2014; 29: 25-25.
²³
Tamura K, Peterson D, Peterson N, Stecher G, Nei M. et al. MEGA5: Molecular Evolutionary Genetics Analysis using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Mol Biol Evol. 2011; 28:2731-273.
²⁴
Timm AE, Stiller M, Frey JE. A molecular identification key for economically important thrips species (Thysanoptera: Thripidae) in southern Africa. Afr Entomol. 2008; 16:68-75.
²⁵
Walsh K, Boonham N, Barker I, Collins DW. Development of a sequence-specific real-time PCR to the melon thrips Thrips palmi (Thysanoptera: Thripidae). J Appl Entomol 2005; 129:272-279.
²⁶
Zhang GF, Meng XQ, Min L, Qiao WN, Wan FH. Rapid Diagnosis of the Invasive Species, Frankliniella occidentalis (Pergande): A Species- Specific COI Marker. J Appl Entomol. 2011; 136: 410-420.

Publication Dates

Publication in this collection
2017

History

Received
03 Feb 2016
Accepted
14 July 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Asokan R, Krishna Kumar N, Kumar V, Ranganath H. Molecular differences in the mitochondrial cytochrome oxidase I (mtCOI) gene and development of a species-specific marker for onion thrips, Thrips tabaci Lindeman, and melon thrips, T. palmi Karny (Thysanoptera: Thripidae), vectors of tospoviruses (Bunyaviridae). Bull Entomol Res. 2007; 97: 461-470.

[2] ²
Boonham N, Smith P, Walsh K, Tame J, Morris J, Spence N. et al. The detection of Tomato spotted wilt virus (TSWV) in individual thrips using real-time fluorescent RT-PCR (TaqMan). J Virol Methods. 2002; 101:37-48.

[3] ³
Brunner PC, Fleming C, Frey JE. A molecular identification key for economically important thrips species (Thysanoptera: Thripidae) using direct sequencing and a PCR-RFLP-based approach. Agric Forest Entomol. 2002; 4:127-136.

[4] ⁴
Brunner PC, Chatzivassiliou EK, Katis NI, Frey JE. Host-associated genetic differentiation in Thrips tabaci (Insecta; Thysanoptera), as determined from mtDNA sequence data. Heredity. 2004; 93:364-370.

[5] ⁵
Camelo-García VM, Lima EFB, Mansilla-Córdova PJ, Rezende JAM, Kitajima EW, Barreto M. Occurrence of Groundnut ringspot virus on Brazilian peanut crops. J Gen Plant Pathol. 2014; 80:282-286.

[6] ⁶
Frey JE; Frey B. Origin of intra-individual variation in PCR-amplified mitochondrial cytochrome oxidase I of Thrips tabaci (Thysanoptera: Thripidae): mitochondrial heteroplasmy or nuclear integration? Hereditas. 2004:140: 92-98.

[7] ⁷
Huang KS, Lee SE, Yeh Y, Shen GS, Mei E, Chang CM. Taqman real-time quantitative PCR for identification of western flower thrips (Frankliniella occidentalis) for plant quarantine. Biol Lett. 2010; 6:555-557.

[8] ⁸
Kadirvel P, Srinivasan R, Hsu YC, Su FC, La Peña R. Application of cytochrome oxidase I sequences for phylogenetic analysis and identification of thrips species occurring on vegetable crops. J Econ Entomol. 2013; 106 (1): 408-418.

[9] ⁹
Kox LFF, van den Beld HE, Zijlstra C,Vierbergen G. Real-time PCR assay for the identification of Thrips palmi. EPPO Bulletin. 2005; 35:141-148.

[10] ¹⁰
Lakshmi KV, Wightman JA, Reddy DVR, Rao GVR, Buiel AAM, Reddy DDR. Transmission of peanut bud necrosis virus by Thrips palmi in India. Thrips biology and management: proceedings of the 1993 International Conference on Thysanoptera. Ed Parker BL, Skinner M and Lewis T. 1995. p. 179-184

[11] ¹¹
Leão EU, Spadotti DMA, Rocha KCG, Pantoja KFC, Rezende JAM, Pavan MA, et al. Citrullus lanatus is a new natural host of Groundnut ringspot virus in Brazil. J Phytopathol. 2014; 165:1014-1018.

[12] ¹²
Mehle N; Trdan S. Traditional and modern methods for the identification of thrips (Thysanoptera) species. J Pest Sci. 2012; 85:179-190.

[13] ¹³
Mirab-balou M; Chen XX. First description of the male of the wheat thrips, Anaphothrips obscurus (Thysanoptera: Thripidae). Zootaxa. 2010; 2540: 65-68.

[14] ¹⁴
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name	sequence 5’ - to - 3’	Orientation	specificity
mtD-7.2F	ATTAGGAGCHCCHGAYATAGCATT	Forward	Generic
mtD-9.2R	CAGGCAAGATTAAAATATAAACTTCTG	Reverse	Generic
FS_for	ATACCTGCTAAATGAAGGG	Forward	F. schultzei - specific
FS_rev	TTCCACCTTCAATAACTTTAC	Reverse	F. schultzei - specific

Species	Location	Host plant	Cropping system	Year of collection	Molecular identification (PCR) ^(b)
Species	Location	Host plant	Cropping system	Year of collection	DS^(c)	SP	RT
Frankliniella schutzei	Presidente Prudente, SP (S22°7′33″/W51°23′20″)	Watermelon	Open field	2012/2013	+	+	16.05
	Marília, SP (S22°12'50"/W49º56'45")		Open field	2012/2013	+	+	18.13
	Botucatu, SP(adult) (S22º53'09"/W48º26'42")		Greenhouse^(a)	2013/2014	+	nt	18.17
	Botucatu, SP, (larvae) (S22º53'09"/W48º26'42")		Greenhouse	2013/2014	nt	+	16.05
	São Manuel, SP (S22º43'52"/W48º34'14")		Greenhouse	2013/2014	+	+	17.98
	Borborema, SP (S21º37'11"/W49º04'25")		Open field	2014	+	+	15.90
	Presidente Prudente, SP (S22°7′33″/W51°23′20″)	Pumpkin	Open field	2013	+	+	14.58
	Botucatu, SP (S22º53'09"/W48º26'42")	Tomato	Greenhouse	2013/2014	+	+	nt
	São Manuel, SP (S22º43'52"/W48º34'14")	Tomato	Greenhouse	2013/2014	+	+	19.65
	Campinas, SP (S22º54′21”/W 47º03′39”)	Sweet Pepper	Greenhouse	2014	+	nt	nt
	Campinas, SP (S22º54′21”/W 47º03′39”)	Lettuce	Greenhouse	2014	+	+	18.51
	Campinas, SP (S22º54′21”/W 47º03′39”)	Cucumber	Greenhouse	2014	+	nt	16.03
	Botucatu, SP (S22º53'09"/W48º26'42")	Emilia sonchifolia	Greenhouse	2012/2013	+	+	17.59
	São Manuel, SP (S22º43'52"/W48º34'14")	Tridax procumbens	Open field	2014	+	nt	nt
F. occidentalis	Andradas, MG (S22º04'05”/W46º34'04”)	Chrysanthemum	Greenhouse	2014	nt	-	nd
F. occidentalis	Piedmont, Italy (N45°3’/ E7°40’)	Sweet Pepper	Greenhouse	2011	nt	-	nd
F. intonsa	Piedmont, Italy (N45°3’/ E7°40’)	Strawberry	Greenhouse	2011	nt	-	nd
Thrips tabaci	Piedmont, Italy (N45°3’/ E7°40’)	Sweet Pepper	Greenhouse	2011	nt	-	nd