MicroRNA expression profiles from eggs of different qualities associated with post-ovulatory ageing in rainbow trout (Oncorhynchus mykiss)
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- 作者:Hao Ma (1)
Gregory M Weber (2)
Mark A Hostuttler (2)
Hairong Wei (3)
Lei Wang (1)
Jianbo Yao (1)
1. Division of Animal and Nutritional Sciences ; West Virginia University ; Morgantown ; WV ; 26506 ; USA
2. National Center for Cool and Cold Water Aquaculture ; USDA/ARS ; Kearneysville ; WV ; 25430 ; USA
3. School of Forest Resources and Environmental Science ; Michigan Technological University ; Houghton ; MI ; 49931 ; USA - 关键词:microRNA ; Egg quality ; Post ovulation ; Rainbow trout
- 刊名:BMC Genomics
- 出版年:2015
- 出版时间:December 2015
- 年:2015
- 卷:16
- 期:1
- 全文大小:1,483 KB
- 参考文献:1. Bromage, N, Jones, J, Randall, C, Thrush, M, Davies, B, Springate, J (1992) Broodstock Management, Fecundity, Egg Quality and the Timing of Egg-Production in the Rainbow-Trout (Oncorhynchus-Mykiss). Aquaculture 100: pp. 141-66 CrossRef
2. Bobe, J, Labbe, C (2010) Egg and sperm quality in fish. Gen Comp Endocrinol 165: pp. 535-48 CrossRef
3. Bonnet, E, Fostier, A, Bobe, J (2007) Microarray-based analysis of fish egg quality after natural or controlled ovulation. BMC Genomics 8: pp. 55 CrossRef
4. Ciereszko, A, Wojtczak, M, Dietrich, GJ, Kuzminski, H, Dobosz, S (2009) A lack of consistent relationship between distribution of lipid droplets and egg quality in hatchery-raised rainbow trout, Oncorhynchus mykiss. Aquaculture 289: pp. 150-3 CrossRef
5. Brooks, S, Tyler, CR, Sumpter, JP (1997) Egg quality in fish: what makes a good egg?. Rev Fish Biol Fish 7: pp. 387-416 CrossRef
6. Tyler, CR, Sumpter, JP (1996) Oocyte growth and development in teleosts. Rev Fish Biol Fish 6: pp. 287-318 CrossRef
7. Bromage, NR, Cumaranatunga, PRT Egg production in the rainbow trout. In: Muir, JF, Roberts, RJ eds. (1988) Recent Advances in Aquaculture. Croom Helm, London, pp. 65-138
8. Crespo, D, Planas, JV, Bobe, J (2010) Lipopolysaccharide administration in preovulatory rainbow trout (Oncorhynchus mykiss) reduces egg quality. Aquaculture 300: pp. 240-2 CrossRef
9. Blom, JH, Dabrowski, K (1995) Reproductive Success of Female Rainbow-Trout (Oncorhynchus-Mykiss) in Response to Graded Dietary Ascorbyl Monophosphate Levels. Biol Reprod 52: pp. 1073-80 CrossRef
10. Washburn, BS, Frye, DJ, Hung, SSO, Doroshov, SI, Conte, FS (1990) Dietary-Effects on Tissue Composition, Oogenesis and the Reproductive-Performance of Female Rainbow-Trout (Oncorhynchus-Mykiss). Aquaculture 90: pp. 179-95 CrossRef
11. Sandnes, K, Ulgenes, Y, Braekkan, OR, Utne, F (1984) The Effect of Ascorbic-Acid Supplementation in Brood-Stock Feed on Reproduction of Rainbow-Trout (Salmo-Gairdneri). Aquaculture 43: pp. 167-77 CrossRef
12. Palace, VP, Werner, J (2006) Vitamins A and E in the maternal diet influence egg quality and early life stage development in fish: a review. Sci Mar 70: pp. 41-57 CrossRef
13. Contreras-Sanchez, WM, Schreck, CB, Fitzpatrick, MS, Pereira, CB (1998) Effects of stress on the reproductive performance of rainbow trout (Oncorhynchus mykiss). Biol Reprod 58: pp. 439-47 CrossRef
14. Campbell, PM, Pottinger, TG, Sumpter, JP (1992) Stress Reduces the Quality of Gametes Produced by Rainbow-Trout. Biol Reprod 47: pp. 1140-50 CrossRef
15. Campbell, PM, Pottinger, TG, Sumpter, JP (1994) Preliminary Evidence That Chronic Confinement Stress Reduces the Quality of Gametes Produced by Brown and Rainbow-Trout. Aquaculture 120: pp. 151-69 CrossRef
16. Bonnet, E, Fostier, A, Bobe, J (2007) Characterization of rainbow trout egg quality: A case study using four different breeding protocols, with emphasis on the incidence of embryonic malformations. Theriogenology 67: pp. 786-94 CrossRef
17. Hokanson, KE, Mccormic, JH, Jones, BR, Tucker, JH (1973) Thermal Requirements for Maturation, Spawning, and Embryo Survival of Brook Trout, Salvelinus-Fontinalis. J Fish Res Board Can 30: pp. 975
18. Aegerter, S, Jalabert, B (2004) Effects of post-ovulatory oocyte ageing and temperature on egg quality and on the occurrence of triploid fry in rainbow trout, Oncorhynchus mykiss. Aquaculture 231: pp. 59-71 CrossRef
19. Su, GS, Liljedahl, LE, Gall, AAE (1997) Genetic and environmental variation of female reproductive traits in rainbow trout (Oncorhynchus mykiss). Aquaculture 154: pp. 10 CrossRef
20. Craik, JCA, Harvey, SM (1984) Egg Quality in Rainbow-Trout - the Relation between Egg Viability, Selected Aspects of Egg Composition, and Time of Stripping. Aquaculture 40: pp. 115-34 CrossRef
21. Springate, JRC, Bromage, NR, Elliott, JAK, Hudson, DL (1984) The Timing of Ovulation and Stripping and Their Effects on the Rates of Fertilization and Survival to Eying, Hatch and Swim-up in the Rainbow-Trout (Salmo-Gairdneri R). Aquaculture 43: pp. 313-22 CrossRef
22. Lahnsteiner, F (2000) Morphological, physiological and biochemical parameters characterizing the over-ripening of rainbow trout eggs. Fish Physiol Biochem 23: pp. 107-18 CrossRef
23. Wojtczak, M, Kowalski, R, Dobosz, S, Goryczko, K, Kuzminski, H, Glogowski, J (2004) Assessment of water turbidity for evaluation of rainbow trout (Oncorhynchus mykiss) egg quality. Aquaculture 242: pp. 617-24 CrossRef
24. Lahnsteiner, F, Patzner, RA (2002) Rainbow trout egg quality determination by the relative weight increase during hardening: a practical standardization. J Appl Ichthyol 18: pp. 24-6 CrossRef
25. Aegerter, S, Jalabert, B, Bobe, J (2003) mRNA stockpile and egg quality in rainbow trout (Oncorhynchus mykiss). Fish Physiol Biochem 28: pp. 317-8 CrossRef
26. Rime, H, Guitton, N, Pineau, C, Bonnet, E, Bobe, J, Jalabert, B (2004) Post-ovulatory ageing and egg quality: a proteomic analysis of rainbow trout coelomic fluid. Reprod Biol Endocrinol 2: pp. 26 CrossRef
27. Bobe, J, Montfort, J, Nguyen, T, Fostier, A (2006) Identification of new participants in the rainbow trout (Oncorhynchus mykiss) oocyte maturation and ovulation processes using cDNA microarrays. Reprod Biol Endocrinol 4: pp. 39 CrossRef
28. Nagler, JJ, Cavileer, TD, Stoddard, JW, Parsons, JE (2008) Maternal mRNA differences in unfertilized rainbow trout (Oncorhynchus mykiss) eggs from batches exhibiting variable embryonic survival. Cybium 32: pp. 233
29. Jima, DD, Zhang, J, Jacobs, C, Richards, KL, Dunphy, CH, Choi, WW (2010) Deep sequencing of the small RNA transcriptome of normal and malignant human B cells identifies hundreds of novel microRNAs. Blood 116: pp. e118-27 CrossRef
30. Takacs, CM, Giraldez, AJ (2010) MicroRNAs as genetic sculptors: Fishing for clues. Semin Cell Dev Biol 21: pp. 760-7 CrossRef
31. Wienholds, E, Koudijs, MJ, Eeden, FJM, Cuppen, E, Plasterk, RHA (2003) The microRNA-producing enzyme Dicer1 is essential for zebrafish development. Nat Genet 35: pp. 12 CrossRef
32. Giraldez, AJ, Cinalli, RM, Glasner, ME, Enright, AJ, Thomson, JM, Baskerville, S (2005) MicroRNAs regulate brain morphogenesis in zebrafish. Science 308: pp. 833-8 CrossRef
33. Giraldez, AJ, Mishima, Y, Rihel, J, Grocock, RJ, Dongen, S, Inoue, K (2006) Zebrafish MiR-430 promotes deadenylation and clearance of maternal mRNAs. Science 312: pp. 75-9 CrossRef
34. Schier, AF, Giraldez, AJ (2006) MicroRNA function and mechanism: insights from zebra fish. Cold Spring Harb Symp Quant Biol 71: pp. 195-203 CrossRef
35. Ma, J, Flemr, M, Stein, P, Berninger, P, Malik, R, Zavolan, M (2010) MicroRNA Activity Is Suppressed in Mouse Oocytes. Curr Biol 20: pp. 265-70 CrossRef
36. Suh, N, Baehner, L, Moltzahn, F, Melton, C, Shenoy, A, Chen, J (2010) MicroRNA Function Is Globally Suppressed in Mouse Oocytes and Early Embryos. Curr Biol 20: pp. 271-7 CrossRef
37. Tang, F, Kaneda, M, O鈥機arroll, D, Hajkova, P, Barton, SC, Sun, YA (2007) Maternal microRNAs are essential for mouse zygotic development. Gene Dev 21: pp. 644-8 CrossRef
38. Medeiros, LA, Dennis, LM, Gill, ME, Houbaviy, H, Markoulaki, S, Fu, D (2011) Mir-290-295 deficiency in mice results in partially penetrant embryonic lethality and germ cell defects. Proc Natl Acad Sci U S A 108: pp. 14163-8 CrossRef
39. Farazi, TA, Spitzer, JI, Morozov, P, Tuschl, T (2011) miRNAs in human cancer. J Pathol 223: pp. 102-15 CrossRef
40. Xu, P, Guo, M, Hay, BA (2004) MicroRNAs and the regulation of cell death. Trends Genet 20: pp. 617-24 CrossRef
41. Kulshreshtha, R, Davuluri, RV, Calin, GA, Ivan, M (2008) A microRNA component of the hypoxic response. Cell Death Differ 15: pp. 667-71 CrossRef
42. Sachdeva, M, Mo, YY (2010) miR-145-mediated suppression of cell growth, invasion and metastasis. Am J Transl Res 2: pp. 170-80
43. Bizuayehu, TT, Babiak, I (2014) MicroRNA in teleost fish. Genome Biol Evol 6: pp. 1911-37 CrossRef
44. Ramachandra, RK, Salem, M, Gahr, S, Rexroad, CE, Yao, J (2008) Cloning and characterization of microRNAs from rainbow trout (Oncorhynchus mykiss): Their expression during early embryonic development. BMC Dev Biol 8: pp. 41 CrossRef
45. Ma, H, Hostuttler, M, Wei, H, Rexroad, CE, Yao, J (2012) Characterization of the Rainbow Trout Egg MicroRNA Transcriptome. PLoS One 7: pp. e39649 CrossRef
46. Gotz, S, Garcia-Gomez, JM, Terol, J, Williams, TD, Nagaraj, SH, Nueda, MJ (2008) High-throughput functional annotation and data mining with the Blast2GO suite. Nucleic Acids Res 36: pp. 3420-35 CrossRef
47. Salem, M, Rexroad, CE, Wang, JN, Thorgaard, GH, Yao, JB (2010) Characterization of the rainbow trout transcriptome using Sanger and 454-pyrosequencing approaches. BMC Genomics 11: pp. 564 CrossRef
48. Aegerter, S, Jalabert, B, Bobe, J (2005) Large scale real-time PCR analysis of mRNA abundance in rainbow trout eggs in relationship with egg quality and post-ovulatory ageing. Mol Reprod Dev 72: pp. 377-85 CrossRef
49. Suen, DF, Norris, KL, Youle, RJ (2008) Mitochondrial dynamics and apoptosis. Genes Dev 22: pp. 1577-90 CrossRef
50. Gao, P, Tchernyshyov, I, Chang, TC, Lee, YS, Kita, K, Ochi, T (2009) c-Myc suppression of miR-23a/b enhances mitochondrial glutaminase expression and glutamine metabolism. Nature 458: pp. 762-5 CrossRef
51. Nakagawa, Y, Iinuma, M, Naoe, T, Nozawa, Y, Akao, Y (2007) Characterized mechanism of alpha-mangostin-induced cell death: Caspase-independent apoptosis with release of endonuclease-G from mitochondria and increased miR-143 expression in human colorectal cancer DLD-1 cells. Bioorg Med Chem 15: pp. 5620-8 CrossRef
52. Lazarou, M, Smith, SM, Thorburn, DR, Ryan, MT, McKenzie, M (2009) Assembly of nuclear DNA-encoded subunits into mitochondrial complex IV, and their preferential integration into supercomplex forms in patient mitochondria. FEBS J 276: pp. 6701-13 CrossRef
53. Lize, M, Klimke, A, Dobbelstein, M (2011) MicroRNA-449 in cell fate determination. Cell Cycle 10: pp. 2874-82 CrossRef
54. Sonkoly, E, Lov茅n, J, Xu, N, Meisgen, F, Wei, T, Brodin, P (2012) MicroRNA-203 functions as a tumor suppressor in basal cell carcinoma. Oncogenesis 1: pp. e3 CrossRef
55. O鈥橠onnell, KA, Wentzel, EA, Zeller, KI, Dang, CV, Mendell, JT (2005) c-Myc-regulated microRNAs modulate E2F1 expression. Nature 435: pp. 839-43 CrossRef
56. Tang, R, Li, L, Zhu, D, Hou, D, Cao, T, Gu, H (2012) Mouse miRNA-709 directly regulates miRNA-15a/16-1 biogenesis at the posttranscriptional level in the nucleus: evidence for a microRNA hierarchy system. Cell Res 22: pp. 504-15 CrossRef
57. Weber, GM, Hostuttler, MA (2012) Factors affecting the first cleavage interval and effects of parental generation on tetraploid production in rainbow trout (Oncorhynchus mykiss). Aquaculture 344: pp. 231-8 CrossRef
58. Hershberger, WK, Hostuttler, MA (2005) Variation in time to first cleavage in rainbow trout Oncorhynchus mykiss embryos: A major factor in induction of tetraploids. J World Aquacult Soc 36: pp. 96-102 CrossRef
59. Buchold, GM, Coarfa, C, Kim, J, Milosavljevic, A, Gunaratne, PH, Matzuk, MM (2010) Analysis of microRNA expression in the prepubertal testis. PLoS One 5: pp. e15317 CrossRef
60. Griffiths-Jones S. miRBase: microRNA sequences and annotation. Curr Protoc Bioinformatics. 2010; Chapter 12:Unit 12 19 11鈥?0. doi:10.1002/0471250953.bi1209s29.
61. Berthelot, C, Brunet, F, Chalopin, D, Juanchich, A, Bernard, M, Noel, B (2014) The rainbow trout genome provides novel insights into evolution after whole-genome duplication in vertebrates. Nat Commun 5: pp. 3657 CrossRef
62. Garmire, LX, Subramaniam, S (2012) Evaluation of normalization methods in mammalian microRNA-Seq data. RNA 18: pp. 1279-88 CrossRef
63. Kal, AJ, Zonneveld, AJ, Benes, V, Berg, M, Koerkamp, MG, Albermann, K (1999) Dynamics of gene expression revealed by comparison of serial analysis of gene expression transcript profiles from yeast grown on two different carbon sources. Mol Biol Cell 10: pp. 1859-72 CrossRef
64. Enright, AJ, John, B, Gaul, U, Tuschl, T, Sander, C, Marks, DS (2003) MicroRNA targets in Drosophila. Genome Biol 5: pp. R1 CrossRef
65. Kertesz, M, Iovino, N, Unnerstall, U, Gaul, U, Segal, E (2007) The role of site accessibility in microRNA target recognition. Nat Genet 39: pp. 1278-84 CrossRef
66. Zardoya, R, GarridoPertierra, A, Bautista, JM (1995) The complete nucleotide sequence of the mitochondrial DNA genome of the rainbow trout, Oncorhynchus mykiss. J Mol Evol 41: pp. 942-51 CrossRef
67. Betel, D, Koppal, A, Agius, P, Sander, C, Leslie, C (2010) Comprehensive modeling of microRNA targets predicts functional non-conserved and non-canonical sites. Genome Biol 11: pp. R90 CrossRef
68. Wei, HR, Yordanov, YS, Georgieva, T, Li, X, Busov, V (2013) Nitrogen deprivation promotes Populus root growth through global transcriptome reprogramming and activation of hierarchical genetic networks. New Phytol 200: pp. 483-97 CrossRef - 刊物主题:Life Sciences, general; Microarrays; Proteomics; Animal Genetics and Genomics; Microbial Genetics and Genomics; Plant Genetics & Genomics;
- 出版者:BioMed Central
- ISSN:1471-2164
文摘
Background Egg quality is an important aspect in rainbow trout farming. Post-ovulatory aging is one of the most important factors affecting egg quality. MicroRNAs (miRNAs) are the major regulators in various biological processes and their expression profiles could serve as reliable biomarkers for various pathological and physiological conditions. The objective of this study was to identify miRNAs that are associated with egg qualities in rainbow trout using post-ovulatory aged eggs. Results Egg samples from females on day 1, day 7, and day 14 post-ovulation (D1PO, D7PO and D14PO), which had the fertilization rates of 91.8%, 73.4% and less than 50%, respectively, were collected and small RNAs isolated from these samples were subjected to deep sequencing using the Illumina platform. The massive sequencing produced 27,342,477, 26,910,438 and 29,185,371 reads from the libraries of D1PO, D7PO and D14PO eggs, respectively. A three-way comparison of the miRNAs indicated that the egg samples shared 392 known and 236 novel miRNAs, and a total of 414, 481, and 470 known and 243, 298, and 296 novel miRNAs were identified from D1PO, D7PO and D14PO eggs, respectively. Four known miRNAs (omy-miR-193b-3p, omy-miR-203c-3p, omy-miR-499-5p and omy-miR-7550-3p) and two novel miRNAs (omy-miR-nov-95-5p and omy-miR-nov-112-5p) showed significantly higher expression in D1PO eggs relative to D14PO eggs as revealed by both deep sequencing and real time quantitative PCR analysis. GO analysis of the predicted target genes of these differentially expressed miRNAs revealed significantly enriched GO terms that are related to stress response, cell death, DNA damage, ATP generation, signal transduction and transcription regulation. Conclusions Results indicate that post-ovulatory ageing affects miRNA expression profiles in rainbow trout eggs, which can in turn impact egg quality. Further characterization of the differentially expressed miRNAs and their target genes may provide valuable information on the role of these miRNAs in controlling egg quality, and ultimately lead to the development of biomarkers for prediction of egg quality in rainbow trout.