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RUDN Journal of Agronomy and Animal Industries Вестник РУДН. Серия: АГРОНОМИЯ И ЖИВОТНОВОДСТВО
2020; 15 (2): 134-141 http://agrojournal.rudn.ru
Защита растений Plant protection
DOI 10.22363/2312-797X-2020-15-2-134-141 UDC 595.772:577.21
Research article / Научная статья
Specific Identification Method based on PCR for Drosophila melanogaster
Yousef Naserzadeh1' 2*, Elena N. Pakina1, Abdorreza M. Nafchi3, Anvar Sh. Gadzhikurbanov1
Peoples' Friendship University of Russia, Moscow, Russian Federation 2All-Russian Plant Quarantine Centre, Moscow region, Russian Federation 3University Sains Malaysia, Penang, Malaysia Corresponding author: unaserzadeh@gmail.com
Abstract. D. melanogaster is one of the most harmful citrus fruit flies having a large number of host plants. The molecular diagnostic method has been created for identification the D. melanogaster from another non-quarantine species Drosophila spp. The proposed method for differentiation is to use the mitochondrial DNA cytochrome oxidase I gene region 709-bp. We amplified samples of DNA with primers Droso-S391 and Droso-A381 by D. melanogaster, D. suzukii, and D. Simulans collections in the laboratory samples from many countries and contrasted with sequences of other GenBank Drosophila taxa. The findings of a polymerase chain reaction (PCR) based on DNA sequence polymorphisms showed that these primers accurately identify the area of the gene as well as the unique primers of Drosophila melanogaster.
Keywords: Identification, diagnosis, Drosophila melanogaster, PCR, plant quarantine
Acknowledgment. Funding. The research has been conducted with the support of the RUDN University Program «5—100».
Article history:
Received: 15 February 2020. Accepted: 18 March 2020 For citation:
Naserzadeh Y, Pakina EN, Nafchi AM, Gadzhikurbanov ASh. Specific Identification Method based on PCR for Drosophila melanogaster. RUDN Journal of Agronomy and Animal Industries. 2020; 15(2):134—141. doi: 10.22363/2312-797X-2020-15-2-134-141
© Naserzadeh Y., Pakina E.N., Nafchi A.M., Gadzhikurbanov A.Sh., 2020.
|@ © I
IHBH This work is licensed under a Creative Commons Attribution 4.0 International License https://creativecommons.org/licenses/by/4.0/1
Introduction
The Drosophilidae family consists of more than 4200 species worldwide, of which more than 2000 are Drosophila species [1, 2]. Drosophila species are well known for their extensive use in genetic studies of Drosophila melanogaster and as common vinegar flies associated with over-ripe and rotting fruit. Many exotic species of fruit fly pose a serious threat to the union of Asia, Australia, the United States, Europe and Russia. Most fruit flies are able to infest and cause significant damage to a wide range of commercial and native fruits and vegetables, although the degree of infestation and damage varies between species. Fruit flies are important too [3—5]. On the positive side, they may act as agents for biological pest control, and the species Drosophila melanogaster, as a major research model organism, unlocks genetic and even certain disease-related secrets in humans. On the negative side, fruit flies can be a major agricultural threat, with the potential to destroy up to 100 percent of some crops. For the latter reason, countries without fruit fly infestations may enforce heavy quarantine restrictions or even bans in fruit imported from countries where fruit fly is endemic. Human responsibility in caring for nature extends to showing the utmost concern about introducing foreign species into new areas. History is full of cases of invasive species (Drosophila melanogaster, Drosophila suzukii, Mediterranean fruit fly, sea lamprey, ctenophore Mniopsis leidyi, gypsy moth, etc.) that wreak havoc in the habitats into which they were introduced, either intentionally or accidentally [6, 7]. Drosophila species are well-known pests in restaurants, grocery stores, and fruit and home markets. Drosophila spp. are also identified as a nuisance pest during winemaking and fruit fermentation. D. melanogaster identified as a major risk and poses a major challenge to the production of fruit. D. melanogaster is a major quarantine pest for growers, gardeners and researchers in Russia's quarantine centers and other farmers around the world. Since there are many environments where opportunistic invasive species can flourish, there is a need to quarantine transported goods and items capable of carrying dormant or active pest species phases [8—12]. The quarantine strategies include regional and international import and export prohibitions, removal of potentially contaminated goods and decontamination in the form of fumigation, steam cleaning and chemical irradiation [13, 14]. Such pathogens and Drosophila melanogaster are a major concern and risk for the fruit industry as it is no longer possible to remove or contain them. To reduce the economic impact on fruit production in the Russian Federation, the implementation of targeted integrated pest management (IPM) is crucial. Besides, farmers need to quickly decide if the larvae in harvested berries are Drosophila melanogaster [15]. There is no way to distinguish D. melanogaster at the moment. The main objective of this research is to classify the molecular species Drosophila melanogaster [5, 16—20]. Our goal was to create an alternative identification technique for Drosophila melanogaster to improve morphological identification and allow for rapid identification of immature phases without the expense of sequencing DNA. The polymerase chain reaction was created to identify insects as a reliable and cost-effective method.
Materials and Methods
DNA extraction, amplification and sequencing. DNA was extracted from the material under study (insect and larvae) which was performed by treating the specimens with Proteinase K followed by removal of proteins with no extraction with organic solvents
and using DNA Ekstran-2 kit, set № NG-511—100 ("Synthol", Russian Federation) as per manufacturer's instructions. Since drosophilids are very small size, physical disruption of tissue was performed by finely chopping with sterile scissors. This is a rapid method of DNA extraction and provides a time advantage, especially for urgent diagnostic needs. DNA extracts were quantified on a NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific Inc., USA).
Polymerase chain reaction
Table 1
Qualitative time PCR assay for the identification of Drosophila melanogaster: Reaction composition and temperature cycling conditions
Target genes Primer Primer sequence (5'-3')
Drosophila melanogaster Droso-S391 AAATAACAATACAGGACTCATATcc Sint et al. 2014
Droso-A381 gTAATACG CTTACATACATaAAG G TATA Sint et al. 2014
A denotes the forward and S the reverse primer. Lower-case letters in the group primer sequences indicate modifications of the original primers [21]
Primer Droso-S391 (5'-AAATAACAATACAGGACTCATATcc -3) as a forward and Droso-A381 (5-gTAATACGCTTACATACATaAAGGTATA -3) as a reverse were used. In order to make PCR mix we used 0.5pl (10 p mol) of each primer, 5^l of screen-mix (HS-5x), 17^l H2O and DNA (table 2). The total volume should be 25^l. After that put tubes in PCR machine, in a VeritiTM thermocycler (Applied Biosystems, USA). The reaction mixture was as follows: ready-to-use PCR mixture Screen Mix-HS (Evrogen, Russia). PCR conditions: denaturation at 95 °C for 90 sec. followed by 40 cycles, including 15 sec. at 90 °C; primer annealing for 30 sec. at 63 °C; elongation for 30 sec. at 72 °C; final elongation for 5 min at 72 °C. The Drosophila spp. primers, Droso-S391 and Droso-A381, are targeting several Drosophila species and generate an amplicon of 220-bp length. PCR conditions were identical for both primer pairs: each 25 pL reaction included 2 pl of DNA extract (10 pmol), 5x PCR Master Mix, Screen-mix (HS-5x), 0.5 pM each primer, 17pl water.
PCR-products purification. Added a 1:1 volume of Binding Buffer to completed PCR mixture (e.g. for every100 pL of the reaction mixture, add 100 pL of Binding Buffer). Mixed thoroughly. Transferred up the solution to the GeneJET purification column. Centrifuged for 30—60 s. discarded the flow-through. Added 700 pL of Wash Buffer to the GeneJET purification column. Centrifuged for 30—60 s. discarded the flow-through and place the purification column back into the collection tube. Then centrifuged the empty GeneJET purification column for an additional 1 min after that transferred the GeneJET purification column to a clean 1.5 mL micro centrifuged tube. Added 50 pL of Elution Buffer to the center of the GeneJET purification column membrane and centrifuged for 1 min.
Sequencing. Sequencing was done by the generally accepted protocol with the use of Genetic Analyzer AB-3500 (Applied Biosystems, USA). Primary comparison for the results of the sequence with the GeneBank genetic sequence database was performed by the NCBI BLAST web site (http://www.ncbi.nlm.nih.gov/BLAST). BioEdit v.7.0.5.3, sequence alignment editor was used for sequence checking, alignment, and editing.
Sanger Dideoxy directly sequenced PCR products in both directions. Sequences of forward and reverse DNA strands were then edited and aligned manually using SEAVIEW
software. MEGA6 and SEAVIEW were used for sequence analysis. Blast searches at NCBI were performed for species identification. For multiple sequence alignment, complete COI gene sequences of some dipteran insects were collected from NCBI and their list is shown in Table 2. Sequences were aligned using CLUSTAL W. For phylogenic analysis, MEGA6 and SEAVIEW were used. A neighbor-joining tree was constructed using MEGA6 to observe phylogenetic relationships of this fly with another dipteran genus. For protein coding nucleotide sequences, genetic code was selected for "invertebrate mitochondrial" and a number of bootstrap replicons was set to 100.
Table 2
A list of sequences for the present study
No Species and Accession number Country Data from laboratory of Russian quarantine Data from GenBank
1 1U.D. Melanogaster Turkey y
2 6U.1248F.D.melanogaster Egypt y
3 1.u3f.D.melanogaster Turkey y
4 2. u3f.D.melanogaster Egypt y
5 3. u3f.D.melanogaster Turkey y
6 4. u3f.D.melanogaster Turkey y
7 5. u3f.D.melanogaster Turkey y
8 6. u3f.D.melanogaster Mexico y
9 MG605127.D.melanogaster Switzerland y
10 LN867079.D.melanogaster Italy y
11 MG605129.D.melanogaster Switzerland y
12 FJ636124.D.melanogaster Switzerland y
13 1.u3f.ds.D.Simulans Turkey y
14 2.u3f.ds.D.Simulans Iran y
15 3.u3f.ds.D.Simulans Turkey y
16 4.u3f.ds.D.Simulans Mexico y
17 MG605144.u3f.ds.D.Simulans Mexico y
18 KJ767247.u3f.ds.D. Simulans USA y
19 KJ671606.u3f.ds.D.Simulans New Zealand y
20 1.u3f.dsuz.D.Suzukii Canada y
21 2.u3f.dsuz.D. Suzukii Turkey y
22 1.2010—19.u3f.ds.D.Suzukii Mexico y
23 AB824772D. Suzukii Japan y
24 KJ671597D. Suzukii Italy y
25 AB824766D.Suzukii Japan y
26 AB824752D. Suzukii Japan y
27 KF312626D.Suzukii China y
28 MG816102D.Suzukii Brazil y
29 MG816086D.Suzukii Brazil y
30 KJ671584D. Suzukii. USA y
31 6.u3f.zt.Zaprionus Tuberculatus Mexico y
Results and Discussion
Drosophila melanogaster is a small, common fly found near unripe and rotten fruit. It has been in use for over a century to study genetics and behavior [1, 22—27]. Thomas Hunt Morgan was the preeminent biologist studying Drosophila early in the 1900s. He was the first to discover sex linkage and genetic recombination, which placed the small fly at the forefront of genetic research. Due to its small size, ease of culture and short generation time, geneticists have been using Drosophila ever since. Fruit flies are easily obtained from the wild and many biological science companies carry a variety of different mutations [8—29]. In addition, these companies sell any equipment needed to culture
the flies. Costs are relatively low and most equipment can be used year after year. There is a variety of laboratory exercises one could purchase, although the necessity to do so is questionable. Compared to GenBank entries using BLAST, the sequences produced from PCR products obtained by testing Feld-collected predators were used to verify target DNA amplification. All matches for the Drosophila spp [30]. Primers consisted of Dro-sophila sequences with a similarity of 98...100 %. As mentioned, correct identification of them is almost unlikely unless they are brought up to adults. This can be a high-risk operation, as many facilities around the world may not have the quarantine protection needed to rear pests like D. melanogaster and egg rearing failure may be very high. However, the long-term portion of identification rearing may be challenging when fresh produce worth hundreds of thousands to millions of dollars is at stake. In such cases, the solution may be given by molecular recognition techniques [7, 31, 32]. For several decades, polymerase chain reaction (PCR)-based approaches have been used to classify pests and diseases worldwide. Results showed that these primers accurately identify the area of the gene as well as the particular region of D. melanogaster. When samples are too poorly maintained for adequate morphological identification or when only immature specimens are available, the suggested PCR molecular diagnosis can be used as a quick and efficient identification method. For this economically important invasive species, a different identification strategy may allow for more precise monitoring and detection and may prevent misidentification (fig.).
AB 824766D.suzukN Japan AB824752D. suzukii. J apan KJ671597D. Suzuki l Italy
AB824772D. suzu ki i. J apan
98
M G816086D suzu ki i В rasi I — 1. u 3f. d suz. D. suzukii
1.2010-19. u3f.d s. D. suzukii 2. u3f.d s uz. D _ suzukii KF312626D. suzukii. С h i n a
22 MG8161D2D suzukii Brazil
KJ6715B4D.suzukN.USA 4. u3f. D. melanog aster 6. u3f.D. melanogaster
35
' 5. u3f.D. melanogaster
EE M G60512 7. D. melanog aster. Switzerland
LN867079.D.melanog aster. Italy
M G605129 D melanog aster Switzerland
21
-6. ui3f.zt.Zapri о nus_tu berc ulatus
I > : mi jImi v .
21 2.u3f.ds.D.simulans 31 i! ; I.' mijl.irv.
4.u3f.ds.D.simulans M G605144. u3f.d s. D. si m ulans. M exi с о KJ767247_u3f.ds_D.simulans.USA К J671606. u3f. d s. D. si mulans. N ew_Zeal an d
1U. D. melanog aster FJ636124-.D.melanog aster 6U 1248F D melanog aster
100 1 _u3f.D.melanogaster 2. u3f.D. melanog aster 3 _ u3f. D. melanog aster
0.50
Phylogenetic tree for Drosophila sp
Conclusion
In conclusion, with our selection of DNA, we optimized the PCR process with Russian chemistry. Created here is suitable for regular use by diagnostic and research organizations to promote exports and imports, as well as globally reducing and monitoring the spread of this pest by border security organizations. This assay provides a quick, accurate and precise alternative methods to the identification D. melanogaster. Because PCR machines are accessible in a 96-well or other configuration, this technique is suitable for high-performance applications that are often needed during large-scale studies of infestation during an incursion. This assay has been fully optimized for instant jobs in the Russian Federation. We recommend pre-deployment testing in places outside Moscow to guarantee that no false positive is detected, although this would be extremely unlikely.
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About authors:
Naserzadeh Yousef — Researcher, Agro-Biotechnological Department, Agrarian and Technological Institute, Peoples' Friendship University of Russia, 8 Miklukho-Maklaya st., Moscow, 117198, Russian Federation; All-Russian Plant Quarantine Centre, 32, Pogranichnaya st., Bykovo vil., Ramensky district, Moscow region, 140150, Russian Federation; e-mail: unaserzadeh@gmail.com
Pakina Elena Nikolaevna — Associate Professor, Candidate of Biological Sciences, Agro-Biotechnological Department, Agrarian and Technological Institute, Peoples' Friendship University of Russia, 8 Miklukho-Maklaya st., Moscow, 117198, Russian Federation; e-mail: e-pakina@yandex.ru
Nafchi Abdorreza Mohammadi — Professor, University Sains Malaysia, E42, Chancellory II st., Penang, 11800, Malaysia; e-mail: amohammadi@usm.my
Gadzhikurbanov Anvar Shikhragimovich — Agroengineering Department, Agrarian and Technological Institute, Peoples' Friendship University of Russia, 8/2 Miklukho-Maklaya st., Moscow, 117198, Russian Federation; e-mail: gadcgikurbanow@mail.ru
Идентификация Drosophila melanogaster методом полимеразной цепной реакции
Ю. Насерзаде1' 2 *, Е.Н. Пакина1, А.М. Нафчи3, А.Ш. Гаджикурбанов1
Российский университет дружбы народов, г. Москва, Российская Федерация 2Всероссийский центр карантина растений, Московская область, Российская Федерация 3Научный университет Малайзии, Пенанг, Малайзия *unaserzadeh@gmail.com
Аннотация. D. melanogaster — одна из наиболее вредоносных плодовых мух, повреждающих цитрусовые и многие другие сельскохозяйственные растения. Молекулярный метод диагностики был создан для идентификации D. melanogaster от другого некарантинного вида Drosophila spp. Предложенный метод дифференциации заключается в использовании фрагмента гена цитохромоксидазы субъединицы 1 митохондриальной ДНК размером 709 п.н. С помощью праймеров Droso-S391 и Droso-A381 были амплифицированы образцы ДНК D. melanogaster, D. suzukii и D. Simulans в лабораторных образцах из разных стран, далее их сравнили с последовательностями других таксонов Drosophila из базы GenBank. Результаты проведения полимеразной цепной реакции (ПЦР) на основе полиморфизма нуклеотидных последовательностей показали, что данные праймеры точно идентифицируют участок гена, также как и специфические праймеры Drosophila melanogaster.
Ключевые слова: идентификация, диагностика, Drosophila melanogaster, полимеразная цепная реакция, ПЦР, карантин растений
Финансирование. Благодарности: Исследование проведено при финансовой поддержке Программы РУДН «5—100».
История статьи:
Поступила в редакцию: 15 февраля 2020 г. Принята к публикации: 18 марта 2020 г. Для цитирования:
Naserzadeh Y., Pakina E.N., Nafchi A.M., Gadzhikurbanov A.Sh. Specific Identification Method based on PCR for Drosophila melanogaster // Вестник Российского университета дружбы народов. Серия: Агрономия и животноводство. 2020. Т. 15. № 2. С. 134—141. doi: 10.22363/2312-797X-2020-15-2-134-141
Об авторах:
Насерзаде Юсеф—научный сотрудник агробиотехнологического департамента, Аграрно-технологический институт, Российский университет дружбы народов, Российская Федерация, 117198, г. Москва, ул. Миклухо-Маклая, д. 8; Всероссийский центр карантина растений, Российская Федерация, 140150, Московская область, Раменский район, с. Быково, ул. Пограничная, д. 32; e-mail: unaserzadeh@gmail.com; Пакина Елена Николаевна — кандидат биологических наук, доцент, агробиотехнологический департамент, Аграрно-технологический институт, Российский университет дружбы народов, Российская Федерация, 117198, г. Москва, ул. Миклухо-Маклая, д. 8; e-mail: e-pakina@yandex.ru
Нафчи Абдорреза Мохаммади — профессор, Научный университет Малайзии, Малайзия, 11800, Пенанг, ул. Канцлера II, E42; e-mail: amohammadi@usm.my
Гаджикурбанов Анвар Шихрагимович — агроинженерный департамент, Аграрно-технологический институт, Российский университет дружбы народов, Российская Федерация, 117198, г. Москва, ул. Миклухо-Маклая, д. 8; e-mail: gadcgikurbanow@mail.ru
