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Identification and Functional Characterization of the Sex-Determining Gene Doublesex in the Sawfly, Athalia Rosae (Hymenoptera

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Identification and Functional Characterization of the Sex-Determining Gene Doublesex in the Sawfly, Athalia Rosae (Hymenoptera Identification and functional characterization of the sex-determining gene doublesex in the sawfly, Athalia rosae?(Hymenoptera: Tenthredinidae) journal or Applied Entomology and Zoology publication title volume 52 number 3 page range 497-509 year 2017-08 URL http://id.nii.ac.jp/1578/00002504/ doi: 10.1007/s13355-017-0502-3 Creative Commons : 表示 http://creativecommons.org/licenses/by/3.0/deed.ja Appl Entomol Zool (2017) 52:497–509 DOI 10.1007/s13355-017-0502-3 ORIGINAL RESEARCH PAPER Identifcation and functional characterization of the sex‑determining gene doublesex in the sawfy, Athalia rosae (Hymenoptera: Tenthredinidae) Shotaro Mine1 · Megumi Sumitani2 · Fugaku Aoki1 · Masatsugu Hatakeyama3 · Masataka G. Suzuki1 Received: 19 April 2017 / Accepted: 18 May 2017 / Published online: 3 June 2017 © The Author(s) 2017. This article is an open access publication Abstract Sexual fate of the sawfy, Athalia rosae (Hyme- showed abnormalities in testes and seminal vesicles and noptera: Tenthredinidae) is determined by the complemen- lacked mature sperm. The present study provides the frst tary sex determination (CSD) mechanism as is the case in direct evidence that dsx is essential for sexual development honeybees. However, to date, genes involved in sex deter- in hymenopteran species. mination have not been identifed in this species. In this study, we attempted to identify orthologs of complementary Keywords Hymenoptera · Athalia rosae · Sex sex-determiner (csd), feminizer (fem), and doublesex (dsx) determination · Doublesex · Genitalia from the A. rosae genome, all of which are crucial compo- nents of the sex determination cascade in the honeybee. As a result, we identifed a sawfy ortholog of dsx (designated Introduction as Ardsx). Rapid amplifcation of cDNA ends (RACE) using total RNA extracted from male and female larvae In several hymenopteran insects, sexual fate is determined identifed three male-specifc variants and three female- by the complementary sex determination (CSD) mecha- specifc variants. Comparison between the full-length nism, in which heterozygosity at a single locus (the CSD Ardsx cDNAs and the genomic sequence revealed that exon locus) determines femaleness in diploid individuals, while 5 was differentially spliced between the male- and female- haploid individuals are hemizygous for the CSD locus and specifc variants. RT-PCR analysis demonstrated that Ardsx thus develop into males (Whiting 1933). The CSD locus pre-mRNA was spliced alternatively in a sex-dependent was frst molecularly identifed in the honeybee Apis mel- manner at almost all the developmental stages. RNAi- lifera and found to be a homolog of transformer (tra) mediated knockdown of Ardsx in males caused severe (Beye et al. 2003). The tra gene is known to be a conserved defects in the reproductive organs and, notably, induced upstream component of the insect sex determination cas- development of the ovipository apparatus containing the cade and induces female development by regulating sex- dorsal pair of blades and the sheath. These males also specifc alternative splicing of downstream targets such as doublesex (dsx) (Gempe and Beye 2011; Hoshijima et al. 1991). A. mellifera has two copies of tra homologs (Has- * Masataka G. Suzuki [email protected]‑tokyo.ac.jp selmann et al. 2008). One copy is named complementary sex-determiner (csd) that is the primary signal for female- 1 Department of Integrated Biosciences, Graduate School ness. It activates the other copy, named feminizer (fem), of Frontier Sciences, The University of Tokyo, 5‑1‑5 which is more conserved and retains the ancestral function Kashiwanoha, Kashiwa‑shi, Chiba 277‑8562, Japan of regulating sex-specifc alternative splicing dsx. The csd 2 Genetically Modifed Organism Research Center, was considered to have arisen from duplication of the fem National Institute of Agrobiological Sciences, Owashi, Tsukuba 305‑8634, Japan gene (Schmieder et al. 2012). Orthologs of csd and fem have been identifed not only in 3 Division of Insect Sciences, National Institute of Agrobiological Sciences, Owashi, Tsukuba 305‑8634, honeybee species but also in bumblebees and ants (Privman Japan et al. 2013; Schmieder et al. 2012). Evolutional analyses 1 3 498 Appl Entomol Zool (2017) 52:497–509 demonstrate that the duplication of fem that yielded csd their gonads and genitalia (Hatakeyama et al. 1990a, b; occurred before the divergence of Aculeata species (bees Oishi et al. 1995). The male genitalia form a well-organ- and ants), and also provide evidence that these two genes ized capsule, in repose retracted within the apical segments evolved concertedly through gene conversion. On the basis of the abdomen, as those reported in other sawfy species of these fndings, it is supposed that csd likely represents (Schulmeister 2003). In particular, the genitalia of females the molecular basis for the CSD mechanism in the Aculeata consist of a unique ovipository apparatus with a saw tooth- species and, possibly, in the entire Hymenoptera order. like structure, which is characteristic for the sawfy species To verify this hypothesis, it is quite important to know (Ross 1945). Classical genetic analysis demonstrates that whether hymenopteran species, which are more primitive sexual fate in this species is also determined by the single- than Aculeata species, also have csd and fem orthologs. locus CSD system (Naito and Suzuki 1991). The number The sawfy, Athalia rosae (Hymenoptera: Tenthredinidae), of alleles at this locus in a feld population calculated by belongs to the Symphyta infra-order, which is the most random crossing is 40–50 (Fujiwara et al. 2004). However, primitive infra-order in Hymenoptera (Fig. 1a, b). Adults to date, genes involved in sex determination and sexual dif- of this species show signifcant sexual dimorphisms in ferentiation have not been identifed in this species. Fig. 1 Identifcation of a dsx ortholog from A. rosae. Photographs of of six blast hits on the query sequence is described. One predicted a last-instar larva (a) and adult male (b) of Athalia rosae. Scale bars gene (NCBI accession number XM_012406840.1) showed signifcant indicate 2 mm. A tblastn search of the NCBI database was performed, similarities to female-specifc AmDSX isoform, AmDSXF1 (c) and specifying an A. rosae dataset, using the full amino acid sequence of male-specifc AmDSX isoform, AmDSXM (d) DSX in Apis mellifera (AmDSX) as a query sequence. Distribution 1 3 Appl Entomol Zool (2017) 52:497–509 499 The whole genome sequencing (WGS) and assem- provided by the manufacture. A homogenization pestle bly of Athalia rosae were conducted by the i5K Initiative (Funakoshi) was used for homogenizing samples. Total (Baylor College of Medicine, https://www.hgsc.bcm.edu/ RNA extracted from samples during embryonic stage to arthropods/turnip-sawfy-genome-project) and the assem- young larval stages (2 days after hatching) were precipi- bled data was submitted to the NCBI database in 2013 tated by addition of 1 μl of glycogen (20 mg/mL, Wako (GenBank assembly accession number GCA_000344095.1 Junyaku) per sample. RT-PCR reactions were performed Aros_1.0). Sequencing depth and coverage are highly according to the protocol described previously (Suzuki suffcient (genome coverage 467.2 ), and statistics of et al. 2012). The ArEF1-LP and ArEF1-RP primers were × the assembly (number of scaffolds 522; number of con- used to amplify A. rosae elongation factor-1 alpha (EF-1) tigs 7588; contig N50, 51,418; contig L50, 825) shows (NCBI accession number AB253792) as a positive con- that the quality of the Athalia rosae genome assembly is trol for the RT-PCR reaction. The primer sequences uti- good enough for sequence analyses. By using this Ath- lized in this study are indicated in Table 1. PCR products alia rosae WGS data, here, we attempted to identify csd, were analyzed on a 2% agarose gel and visualized with fem, and dsx orthologs from the A. rosae genome to gain ethidium bromide. insights into whether the molecular mechanism for the sex determination observed in Aculeata species is conserved in Quantitative real‑time RT‑PCR Symphytan species. As a result, we successfully identifed a sawfy ortholog of dsx, but failed to fnd genes homolo- qRT-PCR assays were performed according to the pro- gous to csd and fem in the honeybee, Apis mellifera. The tocol described previously (Suzuki et al. 2012). The dsx ortholog was designated as Ardsx and its functions in ArEF1-LP and ArEF1-RP primers were used to amplify sexual differentiation were assayed by RNAi analysis. Here elongation factor-1 alpha (EF-1) as an internal standard we provide several lines of evidence that Ardsx is necessary for quantifcation. All primer sequences used in the qRT- for male development in the sawfy. PCR assays are listed in Table 2. Rapid amplifcation of cDNA ends (RACE) Materials and methods RACE was performed on the basis of previous protocols Insect (Suzuki et al. 2010), except that the cDNA templates were prepared from whole bodies of pupae. All primer The wild-type sawfies (Athalia rosae) and several mutant sequences used in RACE are listed in Table 3. strains cream eye color (cec), short wing (sw), and yellow fat body (yfb), which had been kept at the National Agri- Preparation of dsRNAs culture and Food Research Organization, were used in this study. General biology of A. rosae is described in Oishi Two sequences conserved between the Ardsx isoforms were et al. (1993). Animals were reared continuously at 25 °C amplifed with primer pairs ArdsxdsRNAF1-ArdsxdsR- under 16 h light, 8 h dark conditions. The eggs were stored NAR1 and ArdsxdsRNAF2-ArdsxdsRNAR2 (Table 4), and in plastic containers with suffcient humidity, and we used they served as a DNA template for double-stranded RNA Japanese radish leaves (Sakata no tane) for larval feed. A (dsRNA) synthesis. Each primer contained a T7 promoter hydroponic culture kit (Green Farm) was used for cultiva- site. The dsRNA synthesis was performed according to the tion of the Japanese radish leaves.
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