http://orcid.org/0000-0002-0742-6616
Figures
Abstract
The transcriptional coactivator Yorkie(Yki), is a critical downstream effector of the Hippo(Hpo) signaling pathway that controls organ size through the regulation of cell proliferation and apoptosis. During the past ten years the biological function of Yki has been studied extensively in Drosophila and a few other insects, however, little is known about it in the silkworm, Bombyx mori, a major research model of lepidopteran insect. Here, we describe the isolation, characterization and expression of the B. mori Yki ortholog, BmYki. The coding sequence of the BmYki was 1314 bp in length, encoding a protein of 437 amino acids containing two conserved WW domains. BmYki transcripts were ubiquitous but not abundant in all detected tissues and developmental stages. Comparatively, it was expressed at pretty high level in silk glands and at the stage of fifth-instar day-3 larvae. Overexpression of BmYki in cultured B. mori embryonic cells significantly promoted transcription of genes associated with cell proliferation and apoptosis, indicating that BmYki functions in the regulation of organ growth-related biological processes. Interestingly, transcription of silk protein-coding genes and transcription factors regulating the synthesis of silk proteins was downregulated remarkably, suggesting that BmYki was involved in the regulation of silk protein synthesis. This study provides new insights into the role of BmYki in Hpo pathway regulation in silkworm.
Citation: Zeng W, Wang R, Zhang T, Gong C, Zuo W, Liu R, et al. (2017) Cloning and expression analysis of BmYki gene in silkworm, Bombyx mori. PLoS ONE 12(8): e0182690. https://doi.org/10.1371/journal.pone.0182690
Editor: Amit Singh, University of Dayton, UNITED STATES
Received: April 27, 2017; Accepted: July 21, 2017; Published: August 9, 2017
Copyright: © 2017 Zeng et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by the Chongqing Research Program of Basic Research and Frontier Technology Award Number: cstc2017jcyjBX0041 to Hanfu Xu and the Science & Technology Innovation Fund of Southwest University Award Number: 20163107001 to Hanfu Xu. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Precise control of organ size is a key feature of metazoans and a crucial process during animal development and regeneration[1]. How the animal organs grow to be the right size is one of the central mysteries of biology. Developmental genetics over the past decade have revealed the size of functional organs is a consequence of regulation of cell number and/or cell size, which are generally achieved by coordinatly regulating cell growth, proliferation, and apoptosis[1–2]. Several signaling pathways have been implicated in such regulation, including the Wnt, Hedgehog, Transforming growth factor β(TGFβ), Notch, Wingless, Myc, Target of rapamycin(TOR), Jun N-terminal kinase(JNK), and Hippo(Hpo) pathway[3–10]. Studies on these pathways will provide important entry points for clarifying mechanisms of organ size control.
The Hpo pathway firstly discovered in Drosophila and subsequently found in mammals and a few other insects[11–16], is now appreciated as a key regulator of organ growth in flies and mammals. It also plays crucial roles in other biological processes, such as tissue homeostasis and regeneration, cell fate determination, stem cell proliferation, and innate immunity[1,17–18]. It has been defined that core to the Hpo pathway is a kinase cascade composed of tumor suppressors Hpo, Salvador(Sav), Mob-as-tumor-suppressor(Mats), and Warts(Wts)[11–12,19–22], which ultimately phosphorylates and inactivates the transcriptional coactivator Yorkie(Yki), the most critical downstream effector of the Hpo pathway[23–24]. In Drosophila, loss of Hpo signaling activated Yki and led to accumulation of it in the nucleus and therefore induced expression of target genes that positively regulate cell growth, survival, and proliferation[25–26]. Overexpression of Yki resulted in organ overgrowth characterized by excessive cell proliferation and diminished apoptosis, and rescued the phenotype of Hpo signaling activation[23,27]. In Helicoverpa armigera, knockdown of Yki in the epidermal cell line(HaEpi) induced increased activation of cell apoptosis-related genes, whereas overexpressed Yki in HaEpi cells promoted cell proliferation-related genes[28–29]. Taken together, these evidences hint that Yki is a pivotal "switch" to uncover the role of Hpo pathway in organ size control.
We have previously identified the Yki ortholog(designated as BmYki) from the lepidopteran model insect, the silkworm Bombyx mori, yet whether it functions in regulating organ size has not been fully defined. In this study, we isolated the BmYki gene from three strains of B. mori, and further investigated the expression of BmYki and its function in the regulation of its downstream targets related to organ growth. Finally, we provided evidences that BmYki is involved in the synthesis of silk proteins in B. mori.
Materials and methods
Animals and cell lines
Three B. mori strains, Dazao(diapaused strain), Nistari(non-diapaused strain) and LH(non-diapaused strain), were obtained from Silkworm Gene Bank of Southwest University and reared with fresh mulberry leaves in the laboratory at 25~27°C. The cultured B. mori embryo cells(BmE) and ovary-derived cells(BmN) were stored in our laboratory and grown in Grace’s insect medium containing 10% fetal bovine serum at 27°C.
Gene cloning and sequence analysis
The nucleotide sequence of BmYki(BGIBMGA003638) previously identified from the database of SilkDB(http://www.silkdb.org/silkdb/), was used to design the specific primers(Table 1) and perform real-time polymerase chain reaction(RT-PCR) using the cDNA template of three B. mori strains, respectively. The PCR products were subcloned into the pEASY-T5 vector(TransGen) and verified by DNA sequencing. Alignment of the sequences was carried out using software ClustalX[30]. Searches of CDS domain and exton/intron were carried out through the use of GENSCAN(http://genes.mit.edu/GENSCAN.html) and SMART(http://smart.embl-heidelberg.de/). The BmYki gene isolated from Dazao strain was used for subsequent experiments.
Construction of expression vectors
pSL[BmA4-BmYki/EGFP-Ser1pA](abbreviated as BmYki-EGFP). The coding sequence of the BmYki with the stop codon deleted was PCR-amplified using specific primers(Table 1), digested with BamH I and Not I, and inserted into the pSL[BmA4-BN/EGFP-Ser1pA] vector, to generate the vector pSL[BmA4-BmYki/EGFP-Ser1pA]. Expression of the BmYki-EGFP fusion protein was controlled by the promoter of B. mori actin4 gene(BmA4).
pB[UAS-BmYki,3×P3EGFP](abbreviated as UASBmYki). The coding sequence of BmYki was digested with BamH I and Not I, and inserted into the pUC57S[10×UAS-B/N-Ser1pA] vector, then the fragment UAS-BmYki-Ser1pA was subcloned into the Asc I site of the pB[3×P3EGFPafm][31], to generate the vector pB[UAS-BmYki,3×P3EGFP].
pB[BmA4-Gal4,3×P3DsRed](abbreviated as A4G4). The synthesized Gal4 sequence was digested with BamH I and Not I, and inserted into the pUC57S[BmA4-B/N-Ser1pA] vector, then the fragment BmA4-Gal4-Ser1pA was subcloned into the Asc I site of the pB[3×P3DsRedaf][31], to generate the vector pB[BmA4-Gal4,3×P3DsRed].
Subcellular localization analysis
A 100 μL mixture containing 3 μg of BmYki-EGFP plasmid DNA was mixed with 100 μL Grace’s insect medium(without antibiotics) and incubated for 20 min at room temperature, then mixed with BmN cells. After 72 h culture at 27°C, cells were harvested, washed three times with 1×PBS, fixed with 4% paraformaldehyde for 10 min, dyed with 0.1% DAPI for 20 min at room temperature, and then washed three times with 1×PBS. The fixed cells were mounted in slides and observed using an FV1000 confocal microscope(Olympus, Japan). Images were processed using Photoshop 5.0.
Quantitative RT-PCR(qRT-PCR) analysis
To analyze expression patterns of BmYki, total RNA from different tissues and developmental stages of Dazao strain were isolated and used to prepared cDNA templates using cDNA synthesis Kit Manual(Takara). qRT-PCR was carried out in 20 μL solution, which contains 5 ng of cDNA templates, 10 μL of 1×SYBR@ Green I taq(Takara) and 0.5 mM of each primer. The 7500FAST Real-Time PCR System(ABI, USA) was employed. The eukaryotic translation initiation factor 4A (silkworm microarray probe ID: sw22934) was used as an internal control[32].
To determine the mRNA level of target genes in BmE cells overexpressing BmYki, the cells transfected with 3 μg mixture of UASBmYki(400 ng/μL) and A4G4 plasmid DNA(400 ng/μL) were harvested after 72 h culture at 27°C and used to prepare cDNA templates. mRNA levels of each target gene were measured by qRT-PCR as described above. All primers used in qRT-PCR were summarized in Table 1.
Results and discussion
Isolation and sequence analysis of BmYki
To isolate the coding sequence of BmYki, the ~1300 bp fragment containing the putative BmYki gene was obtained by RT-PCR from three B. mori strains, respectively. Further sequence analysis showed that the coding sequence of each BmYki is 1314 bp in length, composed of six exons and five introns, and encodes a protein of 437 amino acids containing two conserved WW domains(Figs 1 and 2) that is capable of interacting with PPXY motifs found in Wts[21]. The amino acid sequence identity of the three BmYki genes was as high as 98.4%. It is worth noting that a ~1100 bp fragment was also amplified from each of the B. mori strain(S1 Fig), and nucleotide sequences of the fragment were almost identical to that of the BmYki gene, except for the lack of the third exon. We thus speculate that BmYki exists in multiple alternative splicing forms in B. mori, which is an interesting discovery that deserves further being investigated.
The exons(blue boxes) and introns(black lines) are shown. Double slashes indicate gaps in genomic sequences. The length of exon 1 ~ exon 6 is 473, 143, 141, 158, 303, and 96 bp, respectively.
Identical amino acid residues among Dazao, Nistari and LH strains are shaded in black. The WW domains are underlined in red.
Localization of BmYki-EGFP fusion proteins in BmN cells
It has been reported that Yki is mainly located in cytoplasm of Drosophila S2 cells[25]. To determine the subcellular localization of BmYki, the plasmid expressing BmYki-EGFP fusion proteins was transfected into BmN cells. The result showed that the BmYki-EGFP fusion protein was mainly cytoplasmic(Fig 3), which is similar to that observed in Drosophila S2 cells. The weak GFP fluorescence observed in the nucleus of BmN cells is thought to be the result of products working in the nucleus.
The coding sequence of the BmYki with the stop codon deleted was fused to EGFP and transiently transfected into the BmN cells. Subcelluar localization of the expressed BmYki-EGFP fusion proteins was observed by fluorescence microscopy.
Expression patterns of BmYki during development
To investigate the expression profile of BmYki, mRNA levels of BmYki gene in different tissues and various developmental stages of B. mori were determined by qRT-PCR. The results showed that BmYki transcripts were ubiquitous but less abundant in B. mori(Fig 4). Comparatively, BmYki was expressed higher in head, trachea, testis, ovary, and was particularly high in both the middle and posterior silk glands, and at the fifth-instar day-3 larvae—a developmental stage considered to be the beginning of mass synthesis of silk proteins, which strongly suggesting the involvement of BmYki in the regulation of silk protein synthesis. Further study is required to elucidate the meaning of BmYki in silk glands.
(A)mRNA levels of BmYki in different tissues of Dazao strain. HD(head); EP(epidermis); FB (fat body); TR (trachea); HA(hemocyte); MG(midgut); MT(malpighian tubule); TE(testis); OV(ovary); ASG(anterior silk gland); MSG(middle silk gland); PSG(posterior silk gland); SG (total silk gland). (B)mRNA levels of BmYki at different developmental stages of Dazao strain. 1L-1, 2L-1, 3L-1, and 4L-1(day-1 of the first, second, third, and fourth larval instar); 5L-1, 5L-3, 5L-5, and 5L-7(day-1, 3, 5, and 7 of the fifth instar), P-1(day-1 of the pupal stage), MM-1 and FM-1(day-1 of the male and female moth). Relative mRNA levels of BmYki against sw22934 are shown. Error bars represent mean ±SD of three samples.
Functional analysis of BmYki in BmE cells
To investigate whether the BmYki is involved in the regulation of organ growth-related biological processes, mRNA levels of B. mori genes homologous to known targets of Drosophila Yki, including cell growth-promoting genes Myc and Ras1, cell cycle progression genes E2F1 and cyclinE, cell apoptosis-related genes Diap1, Diap2, Caspase1 and Caspase9, and Hpo pathway components Expanded and Kibra, were determined by qRT-PCR. As shown in Fig 5 and S2 Fig, nine of these ten genes were upregulated in BmE cells overexpressing BmYki, among which six targets Myc, Ras1, Diap1, Diap2, Caspase1 and Kibra were remarkably upregulated, indicating that BmYki has the function of regulating downstream target genes associated with cell growth, proliferation, and apoptosis.
Expression of B. mori genes homologous to known targets of Drosophila Yki. Relative mRNA levels are indicated as the ratios of mRNA levels between the target gene and sw22934. Error bars represent mean ±SD of three samples.
To further explore whether the BmYki is involved in silk protein synthesis, we examined the expression of genes responsible for synthesis of silk proteins, including fibroin protein-coding genes FibH, FibL and P25, sericin protein-coding genes Ser1, Ser2 and Ser3, and silk gland factors Sage, Dimm, SGF1, SGF2 and SGF3. The results showed that eight of eleven genes were significantly downregulated upon BmYki overexpression, while the other three genes were slightly upregulated(Fig 6), indicating that BmYki functions in the regulation of silk protein synthesis. We are now preparing to generate transgenic silkworms overexpressing BmYki specifically in the middle and posterior silk gland, to clarify the mechanism of BmYki in the regulation of silk protein synthesis.
Expression of silk protein synthesis-related genes in BmE cells were quantified by qRT-PCR. Relative mRNA levels are indicated as the ratios of mRNA levels between the target gene and sw22934. Error bars represent mean ±SD of three samples.
Conclusions
In conclusion, we isolated the coding sequence of BmYki with a length of 1314 bp from B. mori. Expression of the BmYki gene was comparatively high in both the middle and posterior silk gland, and at the fifth-instar day-3 larval stage. Furthermore, we showed that BmYki-EGFP fusion proteins were localized mainly in the cytoplasm of BmN cells. Finally, we demonstrated that overexpression of BmYki in BmE cells remarkably promoted the expression of genes homologous to known targets of Drosophila Yki, and significantly downregulated the expression of silk protein synthesis-related genes. This study provides new insights into the expression and function of BmYki. It would be very interesting to further elucidate the mechanism of BmYki in the regulation of silk protein synthesis.
Supporting information
S1 Fig. Agarose gel electrophoresis of the RT-PCR amplified BmYki gene products.
Lane M: DNA marker; Lanes 1~2: cDNA template of Dazao embryos; Lanes 3~4: cDNA template of LH embryos; Lanes 5~10: cDNA template of Nistari middle silk glands; Lanes 11~14: cDNA template of Nistari posterior silk glands. RT-PCR amplification was performed at least three replicates for each sample. The PCR products were detected on 1.2% agarose gel electrophoresis. Red arrows indicate the ~1300 and ~1100 bp fragments containing the putative BmYki gene.
https://doi.org/10.1371/journal.pone.0182690.s001
(TIF)
S2 Fig. Detection of overexpression of BmYki in BmE cells.
BmE cells transfected with UASBmYki and A4G4 plasmids were harvested to prepare cDNA templates. mRNA levels of BmYki were measured by qRT-PCR. Relative mRNA levels are indicated as the ratios of mRNA levels between the BmYki and sw22934. Error bars represent mean ±SD of three samples.
https://doi.org/10.1371/journal.pone.0182690.s002
(TIF)
Acknowledgments
We thank Prof. Hongjuan Cui and Dr. Hai Hu for providing cultured cells and B. mori strains, respectively.
References
- 1. Tumaneng K, Russell RC, Guan KL. Organ size control by Hippo and TOR pathways. Curr Biol. 2012; 22(9):R368–379. pmid:22575479
- 2. Pan D. Hippo signaling in organ size control. Genes Dev. 2007; 21(8):886–897. pmid:17437995
- 3. Forsthoefel DJ, Newmark PA. Emerging patterns in planarian regeneration. Curr Opin Genet Dev. 2009; 19(4):412–420. pmid:19574035
- 4. Rink JC, Gurley KA, Elliott SA, Sánchez Alvarado A. Planarian Hh signaling regulates regeneration polarity and links Hh pathway evolution to cilia. Science. 2009; 326(5958):1406–1410. pmid:19933103
- 5. Yazawa S, Umesono Y, Hayashi T, Tarui H, Agata K. Planarian Hedgehog/Patched establishes anterior-posterior polarity by regulating Wnt signaling. Proc Natl Acad Sci U S A. 2009; 106(52):22329–22334. pmid:20018728
- 6. Micchelli CA, Blair SS. Dorsoventral lineage restriction in wing imaginal discs requires Notch. Nature. 1999; 401(6752):473–476. pmid:10519549
- 7. Zhang H, Stallock JP, Ng JC, Reinhard C, Neufeld TP. Regulation of cellular growth by the Drosophila target of rapamycin dTOR. Genes Dev. 2000; 14(21):2712–2724. pmid:11069888
- 8. Smith-Bolton RK, Worley MI, Kanda H, Hariharan IK. Regenerative growth in Drosophila imaginal discs is regulated by Wingless and Myc. Dev Cell. 2009; 16(6):797–809. pmid:19531351
- 9. Bosch M, Serras F, Martín-Blanco E, Baguñà J. JNK signaling pathway required for wound healing in regenerating Drosophila wing imaginal discs. Dev Biol. 2005; 280(1):73–86. pmid:15766749
- 10. Grusche FA, Degoutin JL, Richardson HE, Harvey KF. The Salvador/Warts/Hippo pathway controls regenerative tissue growth in Drosophila melanogaster. Dev Biol. 2011; 350(2):255–266. pmid:21111727
- 11. Justice RW, Zilian O, Woods DF, Noll M, Bryant PJ. The Drosophila tumor suppressor gene warts encodes a homolog of human myotonic dystrophy kinase and is required for the control of cell shape and proliferation. Genes Dev. 1995; 9(5):534–546. pmid:7698644
- 12. Xu T, Wang W, Zhang S, Stewart RA, Yu W. Identifying tumor suppressors in genetic mosaics: the Drosophila lats gene encodes a putative protein kinase. Development. 1995; 121(4):1053–1063. pmid:7743921
- 13. Yu FX, Guan KL. The Hippo pathway: regulators and regulations. Genes Dev. 2013; 27(4):355–371. pmid:23431053
- 14. Bando T, Mito T, Maeda Y, Nakamura T, Ito F, Watanabe T, Ohuchi H, Noji S. Regulation of leg size and shape by the Dachsous/Fat signalling pathway during regeneration. Development. 2009; 136(13):2235–2245. pmid:19474149
- 15. Gotoh H, Hust JA, Miura T, Niimi T, Emlen DJ, Lavine LC. The Fat/Hippo signaling pathway links within-disc morphogen patterning to whole-animal signals during phenotypically plastic growth in insects. Dev Dyn. 2015; 244(9):1039–1045. pmid:25997872
- 16. Elshaer N, Piulachs MD. Crosstalk of EGFR signalling with Notch and Hippo pathways to regulate cell specification, migration and proliferation in cockroach panoistic ovaries. Biol Cell. 2015; 107(8):273–285. pmid:25907767
- 17. Hong AW, Meng Z, Guan KL. The Hippo pathway in intestinal regeneration and disease. Nat Rev Gastroenterol Hepatol. 2016; 13(6):324–337. pmid:27147489
- 18. Liu B, Zheng Y, Yin F, Yu J, Silverman N, Pan D. Toll Receptor-Mediated Hippo Signaling Controls Innate Immunity in Drosophila. Cell. 2016; 164(3):406–419. pmid:26824654
- 19. Tapon N, Harvey KF, Bell DW, Wahrer DC, Schiripo TA, Haber D, Hariharan IK. Salvador promotes both cell cycle exit and apoptosis in Drosophila and is mutated in human cancer cell lines. Cell. 2002; 110(4):467–478. pmid:12202036
- 20. Wu S, Huang J, Dong J, Pan D. Hippo encodes a Ste-20 family protein kinase that restricts cell proliferation and promotes apoptosis in conjunction with salvador and warts. Cell. 2003; 114(4):445–456. pmid:12941273
- 21. Harvey KF, Pfleger CM, Hariharan IK. The Drosophila Mst ortholog, hippo, restricts growth and cell proliferation and promotes apoptosis. Cell. 2003; 114(4):457–467. pmid:12941274
- 22. Lai ZC, Wei X, Shimizu T, Ramos E, Rohrbaugh M, Nikolaidis N, Ho LL, Li Y. Control of cell proliferation and apoptosis by mob as tumor suppressor, mats. Cell. 2005; 120(5):675–685. pmid:15766530
- 23. Staley BK, Irvine KD. Hippo signaling in Drosophila: recent advances and insights. Dev Dyn. 2012; 241(1):3–15. pmid:22174083
- 24. Huang J, Wu S, Barrera J, Matthews K, Pan D. The Hippo signaling pathway coordinately regulates cell proliferation and apoptosis by inactivating Yorkie, the Drosophila Homolog of YAP. Cell. 2005; 122(3):421–434. pmid:16096061
- 25. Goulev Y, Fauny JD, Gonzalez-Marti B, Flagiello D, Silber J, Zider A. SCALLOPED interacts with YORKIE, the nuclear effector of the hippo tumor-suppressor pathway in Drosophila. Curr Biol. 2008; 18(6):435–441. pmid:18313299
- 26. Oh H, Irvine KD. Cooperative regulation of growth by Yorkie and Mad through bantam. Dev Cell. 2011; 20(1):109–122. pmid:21238929
- 27. Dong J, Feldmann G, Huang J, Wu S, Zhang N, Comerford SA, Gayyed MF, Anders RA, Maitra A, Pan D. Elucidation of a universal size-control mechanism in Drosophila and mammals. Cell. 2007; 130(6):1120–1133. pmid:17889654
- 28. Dong DJ, Jing YP, Liu W, Wang JX, Zhao XF. The Steroid Hormone 20-Hydroxyecdysone Up-regulates Ste-20 Family Serine/Threonine Kinase Hippo to Induce Programmed Cell Death. J Biol Chem. 2015; 290(41):24738–24746. pmid:26272745
- 29. Wang D, Li XR, Dong DJ, Huang H, Wang JX, Zhao XF. The steroid hormone 20-hydroxyecdysone promotes the cytoplasmic localization of Yorkie to suppress cell proliferation and induce apoptosis. J Biol Chem. 2016; 291(41):21761–21770. pmid:27551043
- 30. Thompson JD, Gibson TJ, Plewniak F, Jeanmougin F, Higgins DG. The ClustalX windows interface: Xexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Res. 1997; 25(24):4876–4882. pmid:9396791
- 31. Horn C, Wimmer EA. A versatile vector set for animal transgenesis. Dev Genes Evol. 2000; 210(12):630–637. pmid:11151300
- 32. Wang GH, Xia QY, Cheng DJ, Duan J, Zhao P, Chen J, Zhu L. Reference genes identified in the silkworm Bombyx mori during metamorphism based on oligonucleotide microarray and confirmed by qRT-PCR. Insect Sci. 2008; 15(5):405–413.