Exploring the Role of CircRNA in Diabetic Kidney Disease from a Novel Perspective: Focusing on Both Glomeruli and Tubuli

Abstract

Diabetic kidney disease (DKD) is the leading cause of end-stage renal disease, but the molecular mechanisms of disease remain not very clear and there is no curative therapeutic strategy so far. This study was carried out to identify the expression profile of circular RNA (circRNA) in human DKD and explore circRNA regulatory function in glomeruli and tubuli simultaneously. As a result, a total of 40 upregulated and 23 downregulated differentially expressed circRNAs (DEcircRNAs) were detected. Six candidate DEcircRNAs were verified by quantitative real-time polymerase chain reaction in high glucose-treated human mesangial cells and human proximal renal tubular epithelial cells, respectively. Gene ontology and Kyoto Encyclopedia of Genes and Genomes pathway analysis revealed that both in glomeruli and in tubuli the DEcircRNAs-targeted genes participated in many pathophysiological processes of DKD. Correlation analysis with renal function showed that expression level of DEcircRNA-targeted hub gene was related to renal function. In conclusion, this is the first study to report expression profiles of circRNAs in kidney of DKD patients, and further analysis demonstrated that circRNA probably played a significant regulatory role, providing help for understanding the pathogenesis of DKD and investigating novel diagnostic and therapeutic strategy.

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References

Aufiero

, Reckman

Y.J.

, Pinto

Y.M.

, and Creemers

E.E.

(2019). Circular RNAs open a new chapter in cardiovascular biology. Nat Rev Cardiol, 16, 503–514.

Chen

S.J.

, Lv

L.L.

, Liu

B.C.

, and Tang

R.N.

(2020). Crosstalk between tubular epithelial cells and glomerular endothelial cells in diabetic kidney disease. Cell Prolif 53, e12763.

Chen

, and Wang

(2020). miRDB: an online database for prediction of functional microRNA targets. Nucleic Acids Res, 48, D127–D131.

Fang

, Wang

, Li

, Han

, Jin

, Su

, et al. (2018). Screening of circular RNAs and validation of circANKRD36 associated with inflammation in patients with type 2 diabetes mellitus. Int J Mol Med, 42, 1865–1874.

Gnudi

, Coward

R.J.M.

, and Long

D.A.

(2016). Diabetic Nephropathy: perspective on novel molecular mechanisms. Trends Endocrinol Metab, 27, 820–830.

Hanan

, Soreq

, and Kadener

(2017). CircRNAs in the brain. RNA Biol, 14, 1028–1034.

, Han

, Zhao

, and Wang

(2019). Circular RNA circRNA_15698 aggravates the extracellular matrix of diabetic nephropathy mesangial cells via miR-185/TGF-beta1. J Cell Physiol, 234, 1469–1476.

Kainz

, Hronsky

, Stel

V.S.

, Jager

K.J.

, Geroldinger

, Dunkler

, et al. (2015). Prediction of prevalence of chronic kidney disease in diabetic patients in countries of the European Union up to 2025. Nephrol Dial Transplant 30 Suppl 4, iv113–iv118.

Kato

, and Natarajan

(2014). Diabetic nephropathy—emerging epigenetic mechanisms. Nat Rev Nephrol, 10, 517–530.

10.

Kristensen

L.S.

, Andersen

M.S.

, Stagsted

L.V.W.

, Ebbesen

K.K.

, Hansen

T.B.

, and Kjems

(2019). The biogenesis, biology and characterization of circular RNAs. Nat Rev Genet, 20, 675–691.

11.

Kristensen

L.S.

, Hansen

T.B.

, Veno

M.T.

, and Kjems

(2018). Circular RNAs in cancer: opportunities and challenges in the field. Oncogene, 37, 555–565.

12.

Y.K.

, Chu

, Wang

, Sun

, Zhang

, Dong

, et al. (2021). Identification of circulating hsa_circ_0063425 and hsa_circ_0056891 as novel biomarkers for detection of type 2 diabetes. J Clin Endocrinol Metab, 106, e2688–e2699.

13.

Lytvyn

, Bjornstad

, van Raalte

D.H.

, Heerspink

H.L.

, and Cherney

D.Z.I.

(2020). The new biology of diabetic kidney disease-mechanisms and therapeutic implications. Endocr Rev, 41, 202–231.

14.

Memczak

, Jens

, Elefsinioti

, Torti

, Krueger

, Rybak

, et al. (2013). Circular RNAs are a large class of animal RNAs with regulatory potency. Nature, 495, 333–338.

15.

Meng

, Li

, Zhang

, Wang

, Zhou

, and Chen

(2017). Circular RNA: an emerging key player in RNA world. Brief Bioinform, 18, 547–557.

16.

Peng

, Gong

, Li

, Yin

, Zhao

, Liu

, et al. (2021). circRNA_010383 acts as a sponge for miR-135a, and its downregulated expression contributes to renal fibrosis in diabetic nephropathy. Diabetes, 70, 603–615.

17.

Piwecka

, Glazar

, Hernandez-Miranda

L.R.

, Memczak

, Wolf

S.A.

, Rybak-Wolf

, et al. (2017). Loss of a mammalian circular RNA locus causes miRNA deregulation and affects brain function. Science 357, eaam8526.

18.

Reidy

, Kang

H.M.

, Hostetter

, and Susztak

(2014). Molecular mechanisms of diabetic kidney disease. J Clin Invest, 124, 2333–2340.

19.

Saeedi

, Petersohn

, Salpea

, Malanda

, Karuranga

, Unwin

, et al. (2019). Global and regional diabetes prevalence estimates for 2019 and projections for 2030 and 2045: results from the International Diabetes Federation Diabetes Atlas, 9th edition. Diabetes Res Clin Pract 157, 10, 7843.

20.

Slyne

, Slattery

, McMorrow

, and Ryan

M.P.

(2015). New developments concerning the proximal tubule in diabetic nephropathy: in vitro models and mechanisms. Nephrol Dial Transplant 30 Suppl , 4, iv60–iv67.

21.

Stevens

P.E.

, and Levin

, for Kidney Disease: Improving Global Outcomes Chronic Kidney Disease Guideline Development Work Group

Members.

(2013). Evaluation and management of chronic kidney disease: synopsis of the kidney disease: improving global outcomes 2012 clinical practice guideline. Ann Intern Med, 158, 825–830.

22.

Sticht

, De La Torre

, Parveen

, and Gretz

(2018). miRWalk: an online resource for prediction of microRNA binding sites. PLoS One 13, e0206239.

23.

Szklarczyk

, Gable

A.L.

, Lyon

, Junge

, Wyder

, Huerta-Cepas

, et al. (2019). STRING v11: protein-protein association networks with increased coverage, supporting functional discovery in genome-wide experimental datasets. Nucleic Acids Res, 47, D607–D613.

24.

Tervaert

T.W.

, Mooyaart

A.L.

, Amann

, Cohen

A.H.

, Cook

H.T.

, Drachenberg

C.B.

, et al. (2010). Pathologic classification of diabetic nephropathy. J Am Soc Nephrol, 21, 556–563.

25.

Vallon

, and Thomson

S.C.

(2020). The tubular hypothesis of nephron filtration and diabetic kidney disease. Nat Rev Nephrol, 16, 317–336.

26.

Wang

, Zhang

, Tan

, Xin

, Yuan

, Xu

, et al. (2021). Circular RNAs in body fluids as cancer biomarkers: the new frontier of liquid biopsies. Mol Cancer 20, 13.

27.

Wang

, Shen

, Wang

, Li

, Cheng

, Chen

, et al. (2016). Cross talk between miR-214 and PTEN attenuates glomerular hypertrophy under diabetic conditions. Sci Rep 6, 31506.

28.

Warren

A.M.

, Knudsen

S.T.

, and Cooper

M.E.

(2019). Diabetic nephropathy: an insight into molecular mechanisms and emerging therapies. Expert Opin Ther Targets, 23, 579–591.

29.

, Wang

L.G.

, Han

, and He

Q.Y.

(2012). clusterProfiler: an R package for comparing biological themes among gene clusters. OMICS, 16, 284–287.

30.

Zhang

, Zhang

X.O.

, Chen

, Xiang

J.F.

, Yin

Q.F.

, Xing

Y.H.

, et al. (2013). Circular intronic long noncoding RNAs. Mol Cell, 51, 792–806.

31.

Zheng

, Bao

, Guo

, Li

, Chen

, et al. (2016). Circular RNA profiling reveals an abundant circHIPK3 that regulates cell growth by sponging multiple miRNAs. Nat Commun 7, 11215.

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