Genome-wide analysis of circular RNA-mediated ceRNA regulation in porcine skeletal muscle development
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Chang Liu | Bugao Li | Xiaoyu Huang | Wen-Xi Li | Chunbo Cai | P. Gao | G. Cao | Chang Lu | Yang Yang | Xiaohong Guo | Mingyue Shi | Jiale Yun | Jin Niu | Pengfei Gao
[1] Song Jiang,et al. Comprehensive Analysis of Differentially Expressed CircRNAs in the Ovaries of Low- and High-Fertility Sheep , 2023, Animals : an open access journal from MDPI.
[2] O. Hanotte,et al. Transcriptome analysis of differentially expressed circRNAs miRNAs and mRNAs during the challenge of coccidiosis , 2022, Frontiers in Immunology.
[3] Tao Zhang,et al. Transcriptome Sequencing Analysis of circRNA in Skeletal Muscle between Fast- and Slow-Growing Chickens at Embryonic Stages , 2022, Animals : an open access journal from MDPI.
[4] M. Kanehisa,et al. KEGG for taxonomy-based analysis of pathways and genomes , 2022, Nucleic Acids Res..
[5] Xinran Yang,et al. A genome-wide landscape of mRNAs, lncRNAs, circRNAs and miRNAs during intramuscular adipogenesis in cattle , 2022, BMC Genomics.
[6] Bugao Li,et al. CircCSDE1 Regulates Proliferation and Differentiation of C2C12 Myoblasts by Sponging miR-21-3p , 2022, International journal of molecular sciences.
[7] Wei Chen,et al. Identification and Functional Prediction of Circular RNAs Related to Growth Traits and Skeletal Muscle Development in Duroc pigs , 2022, Frontiers in Genetics.
[8] L. Navegantes,et al. Urocortin 2 promotes hypertrophy and enhances skeletal muscle function through cAMP and insulin/IGF-1 signaling pathways , 2022, Molecular metabolism.
[9] Dongshan Zhang,et al. The mmu_circRNA_37492/hsa_circ_0012138 function as potential ceRNA to attenuate obstructive renal fibrosis , 2022, Cell Death & Disease.
[10] Z. Zeng,et al. Splicing factor derived circular RNA circCAMSAP1 accelerates nasopharyngeal carcinoma tumorigenesis via a SERPINH1/c-Myc positive feedback loop , 2022, Molecular Cancer.
[11] Q. Nie,et al. circPTPN4 regulates myogenesis via the miR-499-3p/NAMPT axis , 2022, Journal of Animal Science and Biotechnology.
[12] Xiaoyu Chen,et al. METTL14-mediated m6A modification of circORC5 suppresses gastric cancer progression by regulating miR-30c-2-3p/AKT1S1 axis , 2022, Molecular cancer.
[13] Yonghui Chen,et al. CircCYP24A1 hampered malignant phenotype of renal cancer carcinoma through modulating CMTM-4 expression via sponging miR-421 , 2022, Cell Death and Disease.
[14] C. Houchen,et al. Circular RNA ANAPC7 Inhibits Tumor Growth and Muscle Wasting via PHLPP2–AKT–TGF-β Signaling Axis in Pancreatic Cancer , 2022, Gastroenterology.
[15] Z. Yao,et al. Novel circular RNA circ_0086722 drives tumor progression by regulating the miR-339-5p/STAT5A axis in prostate cancer. , 2022, Cancer letters.
[16] Yanyan Li,et al. miR-214-5p Regulating Differentiation of Intramuscular Preadipocytes in Goats via Targeting KLF12 , 2021, Frontiers in Genetics.
[17] A. Panda,et al. Identification of Potential circRNA-microRNA-mRNA Regulatory Network in Skeletal Muscle , 2021, Frontiers in Molecular Biosciences.
[18] Da-Zhi Wang,et al. circRNAome profiling reveals circFgfr2 regulates myogenesis and muscle regeneration via a feedback loop , 2021, Journal of cachexia, sarcopenia and muscle.
[19] Yingke Liu,et al. Construction of circRNA-related ceRNA networks in longissimus dorsi muscle of Queshan Black and Large White pigs , 2021, Molecular Genetics and Genomics.
[20] H. Yin,et al. A Novel Circular RNA circITSN2 Targets the miR-218-5p/LMO7 Axis to Promote Chicken Embryonic Myoblast Proliferation and Differentiation , 2021, Frontiers in Cell and Developmental Biology.
[21] Y. Duan,et al. Spatiotemporal Regulation and Functional Analysis of Circular RNAs in Skeletal Muscle and Subcutaneous Fat during Pig Growth , 2021, Biology.
[22] S. Ju,et al. CircRNAs and their regulatory roles in cancers , 2021, Molecular Medicine.
[23] L. Niu,et al. LncMyoD Promotes Skeletal Myogenesis and Regulates Skeletal Muscle Fiber-Type Composition by Sponging miR-370-3p , 2021, Genes.
[24] Meng Li,et al. Comprehensive analysis of differentially expressed circRNAs and ceRNA regulatory network in porcine skeletal muscle , 2020, BMC genomics.
[25] Yan Wang,et al. Circular RNA CircFAM188B Encodes a Protein That Regulates Proliferation and Differentiation of Chicken Skeletal Muscle Satellite Cells , 2020, Frontiers in Cell and Developmental Biology.
[26] Yanfang Fu,et al. Long non-coding RNA TCONS_00814106 regulates porcine granulosa cell proliferation and apoptosis by sponging miR-1343 , 2020, Molecular and Cellular Endocrinology.
[27] Ligang Zhou,et al. Circular RNA expression profiles and features in NAFLD mice: a study using RNA-seq data , 2020, Journal of translational medicine.
[28] Y. Nakaya,et al. Differential regulation of Actn2 and Actn3 expression during unfolded protein response in C2C12 myotubes , 2020, Journal of Muscle Research and Cell Motility.
[29] N. Schreurs,et al. The Role of MicroRNAs in Muscle Tissue Development in Beef Cattle , 2020, Genes.
[30] Changchun Li,et al. Long Non-Coding RNA H19 Promotes Porcine Satellite Cell Differentiation by Interacting with TDP43 , 2020, Genes.
[31] C. Ren,et al. Roles of PTBP1 in alternative splicing, glycolysis, and oncogensis , 2020, Journal of Zhejiang University-SCIENCE B.
[32] Hong Chen,et al. Bta‐miR‐885 promotes proliferation and inhibits differentiation of myoblasts by targeting MyoD1 , 2020, Journal of cellular physiology.
[33] Daiwen Chen,et al. Procyanidin B2 promotes skeletal slow-twitch myofiber gene expression through AMPK signaling pathway in C2C12 myotubes. , 2020, Journal of agricultural and food chemistry.
[34] Mengli Zhao,et al. Identification and characterization of circular RNA in lactating mammary glands from two breeds of sheep with different milk production profiles using RNA-Seq. , 2019, Genomics.
[35] Xihui Sheng,et al. Comparative adipose transcriptome analysis digs out genes related to fat deposition in two pig breeds , 2019, Scientific Reports.
[36] J. Zhao,et al. Circular RNA profiling identified an abundant circular RNA circTMTC1 that inhibits chicken skeletal muscle satellite cell differentiation by sponging miR-128-3p , 2019, International journal of biological sciences.
[37] Jørgen Kjems,et al. The biogenesis, biology and characterization of circular RNAs , 2019, Nature Reviews Genetics.
[38] S. Hur,et al. Differential abundance of proteome associated with intramuscular variation of meat quality in porcine longissimus thoracis et lumborum muscle. , 2019, Meat science.
[39] T. Tong,et al. α-Ionone attenuates high-fat diet-induced skeletal muscle wasting in mice via activation of cAMP signaling. , 2019, Food & function.
[40] Q. Nie,et al. Circular RNA circHIPK3 Promotes the Proliferation and Differentiation of Chicken Myoblast Cells by Sponging miR-30a-3p , 2019, Cells.
[41] Shiqiang Zhang,et al. Molecular network of miR-1343 regulates the pluripotency of porcine pluripotent stem cells via repressing OTX2 expression , 2018, RNA biology.
[42] Q. Nie,et al. A Novel Circular RNA Generated by FGFR2 Gene Promotes Myoblast Proliferation and Differentiation by Sponging miR-133a-5p and miR-29b-1-5p , 2018, Cells.
[43] H. Taylor,et al. H19 lncRNA Promotes Skeletal Muscle Insulin Sensitivity in Part by Targeting AMPK , 2018, Diabetes.
[44] Xiang Li,et al. The Biogenesis, Functions, and Challenges of Circular RNAs. , 2018, Molecular cell.
[45] Hong Chen,et al. CircFUT10 reduces proliferation and facilitates differentiation of myoblasts by sponging miR‐133a , 2018, Journal of cellular physiology.
[46] Q. Nie,et al. Circular RNAs are abundant and dynamically expressed during embryonic muscle development in chickens , 2017, DNA research : an international journal for rapid publication of reports on genes and genomes.
[47] Hong Chen,et al. Circular RNA profiling reveals an abundant circLMO7 that regulates myoblasts differentiation and survival by sponging miR-378a-3p , 2017, Cell Death and Disease.
[48] Jing Zhou,et al. Quantifying circular RNA expression from RNA‐seq data using model‐based framework , 2017, Bioinform..
[49] Kui Li,et al. Genome-wide profiling of Sus scrofa circular RNAs across nine organs and three developmental stages , 2017, DNA research : an international journal for rapid publication of reports on genes and genomes.
[50] Hui Li,et al. Control of muscle formation by the fusogenic micropeptide myomixer , 2017, Science.
[51] N. Rajewsky,et al. Circ-ZNF609 Is a Circular RNA that Can Be Translated and Functions in Myogenesis , 2017, Molecular cell.
[52] Julia Salzman,et al. Circular RNAs: analysis, expression and potential functions , 2016, Development.
[53] Christoph Dieterich,et al. Profiling and Validation of the Circular RNA Repertoire in Adult Murine Hearts , 2016, Genom. Proteom. Bioinform..
[54] I. Kettelhut,et al. Calcitonin gene-related peptide inhibits autophagic-lysosomal proteolysis through cAMP/PKA signaling in rat skeletal muscles. , 2016, The international journal of biochemistry & cell biology.
[55] E. Kang,et al. Exogenous administration of DLK1 ameliorates hepatic steatosis and regulates gluconeogenesis via activation of AMPK , 2016, International Journal of Obesity.
[56] J. Bienertová-Vašků,et al. Muscle-specific microRNAs in skeletal muscle development. , 2016, Developmental biology.
[57] Y. Xiong,et al. Molecular characterization, expression patterns, and promoter activity analysis of PGM1 in pigs. , 2015, Genetics and molecular research : GMR.
[58] G. Shan,et al. Exon-intron circular RNAs regulate transcription in the nucleus , 2015, Nature Structural &Molecular Biology.
[59] E. Westhof,et al. Biogenesis of Circular RNAs , 2014, Cell.
[60] L. Niu,et al. A feedback circuit between miR-133 and the ERK1/2 pathway involving an exquisite mechanism for regulating myoblast proliferation and differentiation , 2013, Cell Death and Disease.
[61] Shanshan Zhu,et al. Circular intronic long noncoding RNAs. , 2013, Molecular cell.
[62] Sebastian D. Mackowiak,et al. Circular RNAs are a large class of animal RNAs with regulatory potency , 2013, Nature.
[63] Yoshiaki Ito,et al. A Systems Approach and Skeletal Myogenesis , 2012, Comparative and functional genomics.
[64] J. Holaska,et al. Emerin inhibits Lmo7 binding to the Pax3 and MyoD promoters and expression of myoblast proliferation genes , 2011, Journal of Cell Science.
[65] N. Verma,et al. Recent advances in the use of Sus scrofa (pig) as a model system for proteomic studies , 2011, Proteomics.
[66] L. Goodyear,et al. AMP-activated protein kinase in skeletal muscle: From structure and localization to its role as a master regulator of cellular metabolism , 2008, Cellular and Molecular Life Sciences.
[67] M. Buckingham,et al. The role of Pax genes in the development of tissues and organs: Pax3 and Pax7 regulate muscle progenitor cell functions. , 2007, Annual review of cell and developmental biology.
[68] M. Rudnicki,et al. Asymmetric Self-Renewal and Commitment of Satellite Stem Cells in Muscle , 2007, Cell.
[69] B. Brand-Saberi. Genetic and epigenetic control of skeletal muscle development. , 2005, Annals of anatomy = Anatomischer Anzeiger : official organ of the Anatomische Gesellschaft.
[70] Barbara Gayraud-Morel,et al. Mrf4 determines skeletal muscle identity in Myf5:Myod double-mutant mice , 2004, Nature.
[71] E. Olson,et al. MyoD cannot compensate for the absence of myogenin during skeletal muscle differentiation in murine embryonic stem cells. , 2001, Developmental biology.
[72] M. Rudnicki,et al. The molecular regulation of myogenesis , 2000, Clinical genetics.
[73] M. Rudnicki,et al. MyoD or Myf-5 is required for the formation of skeletal muscle , 1993, Cell.
[74] William H. Klein,et al. Muscle deficiency and neonatal death in mice with a targeted mutation in the myogenin gene , 1993, Nature.
[75] D. Riesner,et al. Viroids are single-stranded covalently closed circular RNA molecules existing as highly base-paired rod-like structures. , 1976, Proceedings of the National Academy of Sciences of the United States of America.
[76] Feodor Price,et al. Satellite cells and the muscle stem cell niche. , 2013, Physiological reviews.
[77] Hilde van der Togt,et al. Publisher's Note , 2003, J. Netw. Comput. Appl..