Circular RNAs: An emerging precise weapon for diabetic nephropathy diagnosis and therapy.

[1]  Yu Cai,et al.  CircLARP1B promotes pyroptosis of high glucose-induced renal mesangial cells by regulating the miR-578/TLR4 axis , 2023, International urology and nephrology.

[2]  X. Pei,et al.  Circular RNA COL1A2 Mediates High Glucose-Induced Oxidative Stress and Pyroptosis by Regulating MiR-424-5p/SGK1 in Diabetic Nephropathy. , 2023, Applied biochemistry and biotechnology.

[3]  D. Xu,et al.  Hsa_circ_0001162 Inhibition Alleviates High Glucose-Induced Human Podocytes Injury by the miR-149-5p/MMP9 Signaling Pathway , 2023, Applied biochemistry and biotechnology.

[4]  I. Berindan‐Neagoe,et al.  Investigating Circular RNAs Using qRT-PCR; Roundup of Optimization and Processing Steps , 2023, International journal of molecular sciences.

[5]  Cheng Liu,et al.  Cellular senescence of renal tubular epithelial cells in renal fibrosis , 2023, Frontiers in Endocrinology.

[6]  Jing Zhang,et al.  Regulation of NcRNA-protein binding in diabetic foot. , 2023, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[7]  Yuan Chen,et al.  Diabetic nephropathy: Focusing on pathological signals, clinical treatment, and dietary regulation. , 2023, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[8]  Y. Liang,et al.  Circular RNAs as emerging regulators in COVID-19 pathogenesis and progression , 2022, Frontiers in Immunology.

[9]  Hai-ying Lu,et al.  CircHOMER1 aggravates oxidative stress, inflammation and extracellular matrix deposition in high glucose‐induced human mesangial cells , 2022, Nephrology.

[10]  Yunfeng Zhu,et al.  Circ_0123996 promotes the proliferation, inflammation, and fibrosis of mesangial cells by sponging miR‐203a‐3p to upregulate SOX6 in diabetic nephropathy , 2022, Journal of biochemical and molecular toxicology.

[11]  Xing-ming Jiang,et al.  Circular RNAs regulate parental gene expression: A new direction for molecular oncology research , 2022, Frontiers in Oncology.

[12]  Honghua Lu,et al.  High Glucose-Induced Human Kidney Cell Apoptosis and Inflammatory Injury Are Alleviated by Circ_0008529 Knockdown via Circ_0008529-Mediated miR-485-5p/WNT2B Signaling , 2022, Applied Biochemistry and Biotechnology.

[13]  Fang Wei,et al.  Circ_0114428 promotes proliferation, fibrosis and EMT process of high glucose-induced glomerular mesangial cells through regulating the miR-185-5p/SMAD3 axis , 2022, Autoimmunity.

[14]  G. Wang,et al.  Circ_0068087 Promotes High Glucose-Induced Human Renal Tubular Cell Injury through Regulating miR-106a-5p/ROCK2 Pathway , 2022, Nephron.

[15]  Qin Zhao,et al.  Circ_0000064 knockdown attenuates high glucose-induced proliferation, inflammation and extracellular matrix deposition of mesangial cells through miR-424-5p-mediated WNT2B inhibition in cell models of diabetic nephropathy , 2022, Clinical and Experimental Nephrology.

[16]  G. Bakris,et al.  Molecular Mechanisms and Therapeutic Targets for Diabetic Kidney Disease. , 2022, Kidney international.

[17]  Xiang Liu,et al.  Circular RNA: An emerging frontier in RNA therapeutic targets, RNA therapeutics, and mRNA vaccines. , 2022, Journal of controlled release : official journal of the Controlled Release Society.

[18]  Wenlin An,et al.  Advances in Circular RNA and Its Applications , 2022, International journal of medical sciences.

[19]  Zhangsuo Liu,et al.  Mechanistic Pathogenesis of Endothelial Dysfunction in Diabetic Nephropathy and Retinopathy , 2022, Frontiers in Endocrinology.

[20]  Chao Tu,et al.  The role of circular RNA in Diabetic Nephropathy , 2022, International journal of medical sciences.

[21]  Sheng Chen circ_000166/miR-296 Aggravates the Process of Diabetic Renal Fibrosis by Regulating the SGLT2 Signaling Pathway in Renal Tubular Epithelial Cells , 2022, Disease markers.

[22]  Tao Hu,et al.  Circ_0000064 promotes high glucose-induced renal tubular epithelial cells injury to facilitate diabetic nephropathy progression through miR-532-3p/ROCK1 axis , 2022, BMC Endocrine Disorders.

[23]  Qiming Chen,et al.  Hsa_circ_0037128 aggravates high glucose-induced podocytes injury in diabetic nephropathy through mediating miR-31-5p/KLF9 , 2022, Autoimmunity.

[24]  Fang Wei,et al.  Exosomal circTAOK1 contributes to diabetic kidney disease progression through regulating SMAD3 expression by sponging miR-520h , 2022, International Urology and Nephrology.

[25]  Lifen Gao,et al.  Upregulation of TIPE1 in tubular epithelial cell aggravates diabetic nephropathy by disrupting PHB2 mediated mitophagy , 2022, Redox biology.

[26]  Xinyuan Gao,et al.  Exosomal ncRNAs: Novel Therapeutic Target and Biomarker for Diabetic Complications. , 2022, Pharmacological research.

[27]  Xiaozhong Peng,et al.  Circular RNA vaccines against SARS-CoV-2 and emerging variants , 2022, Cell.

[28]  Taotao Ma,et al.  Tubular epithelial cell-to-macrophage communication forms a negative feedback loop via extracellular vesicle transfer to promote renal inflammation and apoptosis in diabetic nephropathy , 2022, Theranostics.

[29]  Qiang He,et al.  A novel identified circular RNA, mmu_mmu_circRNA_0000309 involves in Germacrone-mediated the improvement of diabetic nephropathy through regulating ferroptosis by targeting miR-188-3p/GPX4 signaling axis. , 2021, Antioxidants & redox signaling.

[30]  Shoujun Bai,et al.  Exosomal hsa_circ_0125310 promotes cell proliferation and fibrosis in diabetic nephropathy via sponging miR‐422a and targeting the IGF1R/p38 axis , 2021, Journal of cellular and molecular medicine.

[31]  AiDong Sun,et al.  Circ-FBXW12 aggravates the development of diabetic nephropathy by binding to miR-31-5p to induce LIN28B , 2021, Diabetology & Metabolic Syndrome.

[32]  Rina Wu,et al.  CircSMAD4 alleviates high glucose-induced inflammation, extracellular matrix deposition and apoptosis in mouse glomerulus mesangial cells by relieving miR-377-3p-mediated BMP7 inhibition , 2021, Diabetology & Metabolic Syndrome.

[33]  Sufang Chen,et al.  Circular RNA_0037128 aggravates high glucose-induced damage in HK-2 cells via regulation of microRNA-497-5p/nuclear factor of activated T cells 5 axis , 2021, Bioengineered.

[34]  Juan Wang,et al.  CircTLK1 Downregulation Attenuates High Glucose-Induced Human Mesangial Cell Injury by Blocking the AKT/NF-κB Pathway Through Sponging miR-126-5p/miR-204-5p , 2021, Biochemical Genetics.

[35]  Xiu-juan Lei,et al.  CircR2Disease v2.0: An Updated Web Server for Experimentally Validated circRNA–disease Associations and Its Application , 2021, Genom. Proteom. Bioinform..

[36]  Liu Liang,et al.  Circular RNA detection methods: A minireview. , 2021, Talanta.

[37]  Sopida Thipsawat Early detection of diabetic nephropathy in patient with type 2 diabetes mellitus: A review of the literature , 2021, Diabetes & vascular disease research.

[38]  Kumar Ganesan,et al.  Role of circRNA-miRNA-mRNA interaction network in diabetes and its associated complications , 2021, Molecular therapy. Nucleic acids.

[39]  J. Vaughan,et al.  Podocyte Aging: Why and How Getting Old Matters. , 2021, Journal of the American Society of Nephrology : JASN.

[40]  N. Huang,et al.  Circular RNAs as Novel Diagnostic Biomarkers and Therapeutic Targets in Kidney Disease , 2021, Frontiers in Medicine.

[41]  A. Shaw,et al.  The Mesangial cell — the glomerular stromal cell , 2021, Nature Reviews Nephrology.

[42]  R. MacIsaac,et al.  Novel Therapies for Kidney Disease in People with Diabetes. , 2021, The Journal of clinical endocrinology and metabolism.

[43]  Jing Chen,et al.  Catalpol ameliorates endothelial dysfunction and inflammation in diabetic nephropathy via suppression of RAGE/RhoA/ROCK signaling pathway. , 2021, Chemico-biological interactions.

[44]  Chun Guo,et al.  The lncRNA CASC9 alleviates lipopolysaccharide-induced acute kidney injury by regulating the miR-424-5p/TXNIP pathway , 2021, The Journal of international medical research.

[45]  H. Lan,et al.  TGF-Beta as a Master Regulator of Diabetic Nephropathy , 2021, International journal of molecular sciences.

[46]  N. Samsu Diabetic Nephropathy: Challenges in Pathogenesis, Diagnosis, and Treatment , 2021, BioMed research international.

[47]  Jiang Liu,et al.  CircRNA circ-ITCH improves renal inflammation and fibrosis in streptozotocin-induced diabetic mice by regulating the miR-33a-5p/SIRT6 axis , 2021, Inflammation Research.

[48]  Jinyu Ren,et al.  Circ-ACTR2 aggravates the high glucose-induced cell dysfunction of human renal mesangial cells through mediating the miR-205-5p/HMGA2 axis in diabetic nephropathy , 2021, Diabetology & Metabolic Syndrome.

[49]  Yan Zeng,et al.  Circular RNA circ_0000712 regulates high glucose-induced apoptosis, inflammation, oxidative stress, and fibrosis in (DN) by targeting the miR-879-5p/SOX6 axis. , 2021, Endocrine journal.

[50]  Tang Liu,et al.  Functions and mechanisms of circular RNAs in regulating stem cell differentiation , 2021, RNA biology.

[51]  Huiwen Ren,et al.  Non-Coding RNA and Diabetic Kidney Disease. , 2021, DNA and cell biology.

[52]  Zhangsuo Liu,et al.  Determining the influence of high glucose on exosomal lncRNAs, mRNAs, circRNAs and miRNAs derived from human renal tubular epithelial cells , 2021, Aging.

[53]  X. Pei,et al.  CircHIPK3 Alleviates High Glucose Toxicity to Human Renal Tubular Epithelial HK-2 Cells Through Regulation of miR-326/miR-487a-3p/SIRT1 , 2021, Diabetes, metabolic syndrome and obesity : targets and therapy.

[54]  Bojin Xu,et al.  Circular RNA circEIF4G2 aggravates renal fibrosis in diabetic nephropathy by sponging miR‐218 , 2020, Journal of cellular and molecular medicine.

[55]  Xiaowen Chen,et al.  circRNA_010383 Acts as a Sponge for miR-135a, and Its Downregulated Expression Contributes to Renal Fibrosis in Diabetic Nephropathy , 2020, Diabetes.

[56]  Ling-Ling Zheng,et al.  deepBase v3.0: expression atlas and interactive analysis of ncRNAs from thousands of deep-sequencing data , 2020, Nucleic Acids Res..

[57]  Shoujun Bai,et al.  Exosomal circ_DLGAP4 promotes diabetic kidney disease progression by sponging miR-143 and targeting ERBB3/NF-κB/MMP-2 axis , 2020, Cell Death & Disease.

[58]  Xiaofeng Yang,et al.  Circular RNAs are a novel type of non-coding RNAs in ROS regulation, cardiovascular metabolic inflammations and cancers. , 2020, Pharmacology & therapeutics.

[59]  Dan Zhou,et al.  Tumor suppressor miR-424-5p abrogates ferroptosis in ovarian cancer through targeting ACSL4. , 2020, Neoplasma.

[60]  Shoujun Bai,et al.  Circ_LARP4 regulates high glucose-induced cell proliferation, apoptosis, and fibrosis in mouse mesangial cells. , 2020, Gene.

[61]  Danyang Zhou,et al.  A novel identified circular RNA, circ_0000491, aggravates the extracellular matrix of diabetic nephropathy glomerular mesangial cells through suppressing miR-101b by targeting TGFβRI , 2020, Molecular medicine reports.

[62]  JianRong Wang,et al.  Interference of Hsa_circ_0003928 Alleviates High Glucose-Induced Cell Apoptosis and Inflammation in HK-2 Cells via miR-151-3p/Anxa2 , 2020, Diabetes, metabolic syndrome and obesity : targets and therapy.

[63]  Min Zhang,et al.  Circular RNA HIPK3 Exacerbates Diabetic Nephropathy and Promotes Proliferation by Sponging miR-185. , 2020, Gene.

[64]  Bojin Xu,et al.  circ_0037128/miR-17-3p/AKT3 axis promotes the development of diabetic nephropathy. , 2020, Gene.

[65]  Hai-Jian Sun,et al.  Roles of circular RNAs in diabetic complications: from molecular mechanisms to therapeutic potential. , 2020, Gene.

[66]  Dongmei Zhang,et al.  Circ_WBSCR17 aggravates inflammatory responses and fibrosis by targeting miR-185-5p/SOX6 regulatory axis in high glucose-induced human kidney tubular cells. , 2020, Life sciences.

[67]  Qi Li,et al.  Circ_0123996 promotes cell proliferation and fibrosisin mouse mesangial cells through sponging miR-149-5p and inducing Bach1 expression. , 2020, Gene.

[68]  Shan Huang,et al.  Circular RNA Circ_0000064 promotes the proliferation and fibrosis of mesangial cells via miR-143 in diabetic nephropathy. , 2020, Gene.

[69]  Shoujun Bai,et al.  Circ‐AKT3 inhibits the accumulation of extracellular matrix of mesangial cells in diabetic nephropathy via modulating miR‐296‐3p/E‐cadherin signals , 2020, Journal of cellular and molecular medicine.

[70]  Yu Wu,et al.  Noncoding RNAs in Diabetic Nephropathy: Pathogenesis, Biomarkers, and Therapy , 2020, Journal of diabetes research.

[71]  Huifang Liu,et al.  Circ_0080425 inhibits cell proliferation and fibrosis in diabetic nephropathy via sponging miR‐24‐3p and targeting fibroblast growth factor 11 , 2020, Journal of cellular physiology.

[72]  F. Zhao,et al.  CircAtlas: an integrated resource of one million highly accurate circular RNAs from 1070 vertebrate transcriptomes , 2020, Genome Biology.

[73]  D. Michael,et al.  Liraglutide as adjunct to insulin treatment in patients with type 1 diabetes: A systematic review and meta-analysis. , 2020, Current diabetes reviews.

[74]  Xiao-ming Meng,et al.  Circular RNA in renal diseases , 2020, Journal of cellular and molecular medicine.

[75]  Xiaoyan Wu,et al.  Circ_0000285 promotes podocyte injury through sponging miR-654-3p and activating MAPK6 in diabetic nephropathy. , 2020, Gene.

[76]  M. Lewandowska,et al.  Use of Fluorescence In Situ Hybridization (FISH) in Diagnosis and Tailored Therapies in Solid Tumors , 2020, Molecules.

[77]  X. Weng,et al.  Direct detection of circRNA in real samples using reverse transcription-rolling circle amplification. , 2020, Analytica chimica acta.

[78]  R. Jamal,et al.  Interactions Among Non-Coding RNAs in Diabetic Nephropathy , 2020, Frontiers in Pharmacology.

[79]  Yan Wang,et al.  The bioinformatics toolbox for circRNA discovery and analysis , 2020, Briefings Bioinform..

[80]  Yuguo Chen,et al.  LncRNA MEG3 targeting miR-424-5p via MAPK signaling pathway mediates neuronal apoptosis in ischemic stroke , 2020, Aging.

[81]  Qianqian Ning,et al.  Translation and functional roles of circular RNAs in human cancer , 2020, Molecular Cancer.

[82]  Jie Gu,et al.  The circular RNA HIPK3 (circHIPK3) and its regulation in cancer progression: Review. , 2020, Life sciences.

[83]  Anding Xu,et al.  The interaction of circRNAs and RNA binding proteins: An important part of circRNA maintenance and function , 2020, Journal of neuroscience research.

[84]  Zhonggao Xu,et al.  circLRP6 regulates high glucose‐induced proliferation, oxidative stress, ECM accumulation, and inflammation in mesangial cells , 2019, Journal of cellular physiology.

[85]  L. Wu,et al.  Circ_0000064 adsorption of microRNA-143 promotes malignant progression of hepatocellular carcinoma. , 2019, European review for medical and pharmacological sciences.

[86]  J. Kjems,et al.  The biogenesis, biology and characterization of circular RNAs , 2019, Nature Reviews Genetics.

[87]  V. Liakopoulos,et al.  Oxidative Stress in the Pathogenesis and Evolution of Chronic Kidney Disease: Untangling Ariadne’s Thread , 2019, International journal of molecular sciences.

[88]  J. Hadfield,et al.  RNA sequencing: the teenage years , 2019, Nature Reviews Genetics.

[89]  Shasha Li,et al.  Microarray is an efficient tool for circRNA profiling , 2019, Briefings Bioinform..

[90]  Liang Ming,et al.  Exosomal circRNAs: biogenesis, effect and application in human diseases , 2019, Molecular Cancer.

[91]  Leighton J. Core,et al.  Promoter-proximal pausing of RNA polymerase II: a nexus of gene regulation , 2019, Genes & development.

[92]  Qian Wang,et al.  Circbank: a comprehensive database for circRNA with standard nomenclature , 2019, RNA biology.

[93]  Hui Wang,et al.  Circular RNAs in Cancer: emerging functions in hallmarks, stemness, resistance and roles as potential biomarkers , 2019, Molecular Cancer.

[94]  J. Shang,et al.  Chemerin/ChemR23 axis promotes inflammation of glomerular endothelial cells in diabetic nephropathy , 2019, Journal of cellular and molecular medicine.

[95]  Chunbo Chen,et al.  Circular RNA involved in the protective effect of losartan on ischemia and reperfusion induced acute kidney injury in rat model. , 2019, American journal of translational research.

[96]  Q. Ye,et al.  Comprehensive circRNA expression profile during ischemic postconditioning attenuating hepatic ischemia/reperfusion injury , 2019, Scientific Reports.

[97]  Ming Chen,et al.  CircFunBase: a database for functional circular RNAs , 2019, Database J. Biol. Databases Curation.

[98]  Ruolan Bai,et al.  Application of droplet digital PCR to detect the pathogens of infectious diseases , 2018, Bioscience reports.

[99]  Zhen Yang,et al.  LncRNADisease 2.0: an updated database of long non-coding RNA-associated diseases , 2018, Nucleic Acids Res..

[100]  Yung-Chien Hsu,et al.  Glomerular mesangial cell and podocyte injuries in diabetic nephropathy , 2018, Nephrology.

[101]  Chenchen Feng,et al.  TRCirc: a resource for transcriptional regulation information of circRNAs , 2018, Briefings Bioinform..

[102]  J. Kjems,et al.  Enzyme-free digital counting of endogenous circular RNA molecules in B-cell malignancies , 2018, Laboratory Investigation.

[103]  Li Yang,et al.  CIRCpedia v2: An Updated Database for Comprehensive Circular RNA Annotation and Expression Comparison , 2018, Genom. Proteom. Bioinform..

[104]  Lei Zhao,et al.  Circular RNA circRNA_15698 aggravates the extracellular matrix of diabetic nephropathy mesangial cells via miR‐185/TGF‐β1 , 2018, Journal of cellular physiology.

[105]  S. Dewanjee,et al.  MicroRNA: A new generation therapeutic target in diabetic nephropathy , 2018, Biochemical pharmacology.

[106]  J. Lewis,et al.  Update on Diabetic Nephropathy: Core Curriculum 2018. , 2018, American journal of kidney diseases : the official journal of the National Kidney Foundation.

[107]  T. Jiang,et al.  circRNA disease: a manually curated database of experimentally supported circRNA-disease associations , 2018, Cell Death & Disease.

[108]  J. Shaw,et al.  IDF Diabetes Atlas: Global estimates of diabetes prevalence for 2017 and projections for 2045. , 2018, Diabetes research and clinical practice.

[109]  M. Gorospe,et al.  Detection and Analysis of Circular RNAs by RT-PCR. , 2018, Bio-protocol.

[110]  J. Long,et al.  Values and Limitations of Targeting lncRNAs in Diabetic Nephropathy , 2018, Diabetes.

[111]  L. Lv,et al.  Renal tubule injury: a driving force toward chronic kidney disease. , 2018, Kidney international.

[112]  Paulo A. S. Nuin,et al.  Use of multicolor fluorescence in situ hybridization to detect deletions in clinical tissue sections , 2018, Laboratory Investigation.

[113]  Qing Jing,et al.  Application of droplet digital PCR in quantitative detection of the cell-free circulating circRNAs , 2018 .

[114]  Qian Zhang,et al.  Emerging roles of circular RNA hsa_circ_0000064 in the proliferation and metastasis of lung cancer. , 2017, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[115]  Po-Jung Huang,et al.  circlncRNAnet: an integrated web-based resource for mapping functional networks of long or circular forms of noncoding RNAs , 2017, GigaScience.

[116]  Bing Chen,et al.  exoRBase: a database of circRNA, lncRNA and mRNA in human blood exosomes , 2017, Nucleic Acids Res..

[117]  Jingnan Shen,et al.  Microarray Expression Profile and Functional Analysis of Circular RNAs in Osteosarcoma , 2017, Cellular Physiology and Biochemistry.

[118]  Shenmin Zhang,et al.  Circular Noncoding RNA HIPK3 Mediates Retinal Vascular Dysfunction in Diabetes Mellitus , 2017, Circulation.

[119]  Haoran Dai,et al.  Research Progress on Mechanism of Podocyte Depletion in Diabetic Nephropathy , 2017, Journal of diabetes research.

[120]  Dawood B. Dudekula,et al.  High-purity circular RNA isolation method (RPAD) reveals vast collection of intronic circRNAs , 2017, Nucleic acids research.

[121]  N. Rajewsky,et al.  Circ-ZNF609 Is a Circular RNA that Can Be Translated and Functions in Myogenesis , 2017, Molecular cell.

[122]  Alessio Colantoni,et al.  FUS affects circular RNA expression in murine embryonic stem cell-derived motor neurons , 2017, Nature Communications.

[123]  Amaresh C Panda,et al.  Identification of HuR target circular RNAs uncovers suppression of PABPN1 translation by CircPABPN1 , 2017, RNA biology.

[124]  K. Kaestner,et al.  PAX6 maintains &bgr; cell identity by repressing genes of alternative islet cell types , 2017, The Journal of clinical investigation.

[125]  M. Cooper,et al.  Diabetes and Kidney Disease: Role of Oxidative Stress. , 2016, Antioxidants & redox signaling.

[126]  Yan Li,et al.  circRNADb: A comprehensive database for human circular RNAs with protein-coding annotations , 2016, Scientific Reports.

[127]  Jun Wang,et al.  Comprehensive characterization of tissue-specific circular RNAs in the human and mouse genomes , 2016, Briefings Bioinform..

[128]  Dong-Eun Kim,et al.  Rolling circle amplification as isothermal gene amplification in molecular diagnostics , 2016, BioChip Journal.

[129]  Yan Li,et al.  Circular RNA profiling reveals an abundant circHIPK3 that regulates cell growth by sponging multiple miRNAs , 2016, Nature Communications.

[130]  Yang Zhang,et al.  CircRNA-derived pseudogenes , 2016, Cell Research.

[131]  M. Miyajima,et al.  Ultra–sensitive droplet digital PCR for detecting a low–prevalence somatic GNAQ mutation in Sturge–Weber syndrome , 2016, Scientific Reports.

[132]  F. S. Foster,et al.  Foxo3 circular RNA promotes cardiac senescence by modulating multiple factors associated with stress and senescence responses , 2016, European heart journal.

[133]  J. Bonventre,et al.  Acute Kidney Injury. , 2016, Annual review of medicine.

[134]  Dawood B. Dudekula,et al.  CircInteractome: A web tool for exploring circular RNAs and their interacting proteins and microRNAs , 2016, RNA biology.

[135]  Igor Ulitsky,et al.  Circular RNAs are long-lived and display only minimal early alterations in response to a growth factor , 2015, Nucleic acids research.

[136]  G. Manda,et al.  Redox Signaling in Diabetic Nephropathy: Hypertrophy versus Death Choices in Mesangial Cells and Podocytes , 2015, Mediators of inflammation.

[137]  Trees-Juen Chuang,et al.  Biogenesis, identification, and function of exonic circular RNAs , 2015, Wiley interdisciplinary reviews. RNA.

[138]  Wei Li,et al.  The circular RNA Cdr1as, via miR-7 and its targets, regulates insulin transcription and secretion in islet cells , 2015, Scientific Reports.

[139]  Andreas W. Schreiber,et al.  The RNA Binding Protein Quaking Regulates Formation of circRNAs , 2015, Cell.

[140]  Li Yang,et al.  Regulation of circRNA biogenesis , 2015, RNA biology.

[141]  Zhihong Liu,et al.  Glomerular endothelial cell injury and cross talk in diabetic kidney disease. , 2015, American journal of physiology. Renal physiology.

[142]  G. Shan,et al.  Exon-intron circular RNAs regulate transcription in the nucleus , 2015, Nature Structural &Molecular Biology.

[143]  D. Zhou,et al.  Losartan Reduces Insulin Resistance by Inhibiting Oxidative Stress and Enhancing Insulin Signaling Transduction , 2014, Experimental and Clinical Endocrinology & Diabetes (Barth).

[144]  S. Celniker,et al.  Genome-wide analysis of drosophila circular RNAs reveals their structural and sequence properties and age-dependent neural accumulation. , 2014, Cell reports.

[145]  Jane Kuypers,et al.  A multiplexed droplet digital PCR assay performs better than qPCR on inhibition prone samples. , 2014, Diagnostic microbiology and infectious disease.

[146]  Petar Glažar,et al.  circBase: a database for circular RNAs , 2014, RNA.

[147]  N. Sharpless,et al.  Detecting and characterizing circular RNAs , 2014, Nature Biotechnology.

[148]  Shaoli Das,et al.  Circ2Traits: a comprehensive database for circular RNA potentially associated with disease and traits , 2013, Front. Genet..

[149]  Q. Cui,et al.  Genome-Wide Analysis of Human MicroRNA Stability , 2013, BioMed research international.

[150]  Shanshan Zhu,et al.  Circular intronic long noncoding RNAs. , 2013, Molecular cell.

[151]  Schraga Schwartz,et al.  Transcriptome-wide discovery of circular RNAs in Archaea , 2011, Nucleic acids research.

[152]  R. Veitia,et al.  Reverse transcriptase template switching and false alternative transcripts. , 2006, Genomics.

[153]  K. Ina,et al.  Glomerular podocyte endocytosis of the diabetic rat. , 2002, Journal of electron microscopy.

[154]  Kathleen R. Cho,et al.  Scrambled exons , 1991, Cell.

[155]  C. Mogensen,et al.  The Stages in Diabetic Renal Disease: With Emphasis on the Stage of Incipient Diabetic Nephropathy , 1983, Diabetes.

[156]  P. Sharp,et al.  Spliced segments at the 5′ terminus of adenovirus 2 late mRNA* , 1977, Proceedings of the National Academy of Sciences.

[157]  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.

[158]  OUP accepted manuscript , 2021, Nucleic Acids Research.

[159]  B. Akgül,et al.  Endogenous miRNA Sponges. , 2021, Methods in molecular biology.

[160]  M. Morlando,et al.  Study of Circular RNA Expression by Nonradioactive Northern Blot Procedure. , 2021, Methods in molecular biology.

[161]  Meiyi Song,et al.  Circular RNAs as Biomarkers for Cancer. , 2018, Advances in experimental medicine and biology.

[162]  O. Rossbach,et al.  Northern Blot Analysis of Circular RNAs. , 2018, Methods in molecular biology.

[163]  Junming Guo,et al.  Plasma circular RNA profiling of patients with gastric cancer and their droplet digital RT-PCR detection , 2017, Journal of Molecular Medicine.

[164]  B. Tian,et al.  RNA‐Seq methods for transcriptome analysis , 2017, Wiley interdisciplinary reviews. RNA.

[165]  Kotb Abdelmohsen,et al.  RT-qPCR Detection of Senescence-Associated Circular RNAs. , 2017, Methods in molecular biology.

[166]  P. Johnsson,et al.  Pseudogene-Expressed RNAs: Emerging Roles in Gene Regulation and Disease. , 2016, Current topics in microbiology and immunology.