Mir-33: miR-acles in cardiac fibrosis?

Heart diseases (HDs) are the primary cause of death in the world (1). An estimated 17.3 million people died from HDs in 2015 (1), representing about 30% of all global deaths. Heart failure is the clinical manifestation of numerous forms of HDs. It is a destructive disorder characterized by ventricular remodeling and reduced compliance. In nearly all etiologies of HDs, the progression toward failure is accelerated by fibrosis, i.e., the improper deposition of extracellular matrix (ECM) proteins by cardiac fibroblasts (CFs) resulting in the reduction of tissue compliance. Physiologically, fibroblasts are the major cell type implicated in the construction and maintenance of connective tissue. The ECM, a highly organized collagen­rich meshwork, provides a structural and flexible scaffold for cardiac cells populations, dispenses mechanical forces through the myocardium, and mediates mechanical conduction of cells in the environment (2-4). CFs are fundamentally involved into the heart response to injury and tackle the limited regenerative capacity of the heart after injury. Fibrotic scar tissues preserve cardiac tissue structure and function. Upon injury, CFs within the connective tissue are activated, and secrete high levels of ECM to generate a pro-fibrotic environment. This environment enhances stiffness of the cardiac tissue and inhibits ventricular contraction and relaxation, which lead to abnormal heart architecture and function. Excessive ECM deposition and fibrosis have been clearly associated with myocardial diastolic and systolic dysfunctions (5). Inhibiting or reversing fibrosis and its damaging repercussions is an established strategy used in many clinical interventions aiming to treat HDs.

Recently, Nishiga et al. (Circulation Research) found, in clinical samples, that the cardiac level of miR-33a was modestly but significantly correlated with ejection fraction (EF) and inversely correlated with pulmonary capillary wedge pressure, obtained by catheterization in 33 patients with dilated cardiomyopathy. miR-33a levels in patients with high-stage HF were significantly lower than in patients with low-stage HF. Therefore, miR-33 was considered to worsen cardiac function and to play a role in the development of HF. In genetic models, miR-33 deficiency resulted in reduced fibrotic response to transverse aortic constriction (TAC) induced-pressure overload in vivo, but despite the reduction in fibrosis, cardiac function deteriorated in miR-33KO hearts. This observation underline the fact that the association between increased fibrosis and decreased cardiac function might not be as linear as originally thought. Several others reports are in keeping with these findings. Inhibition of miR-15b by subcutaneous injections of LNA-based anti-miRs in C57BL/6 mice subjected to transverse aorta constriction seems to aggravate fibrosis but to have less effect on hypertrophy (6). Treatment with antagomiRs to miR-29b has been shown to induce excess fibrosis after aortic constriction without overt deterioration in cardiac function (7). miR-33 adds up to the long list of miRNA described to target cardiac fibrosis (see Table 1 for a non-exhaustive list of miRNAs that have been implicated in cardiac fibrosis), increasing the insight into the pathophysiology of this syndrome. miR-29, miR-133, miR-26a, miR-24, miR-19a-3p/19b-3p, and miR-101a are major antifibrotic miRs. However, the main profibrogenic miRs include miR-21, miR-15 and miR-1. Loss- and gain-of-function experiments revealed an important role for miR mimics and inhibitors for patients with HF. In vivo silencing of miR-21 by a specific antagomir in a mouse pressure-overload-induced disease model reduces cardiac ERK-MAP kinase activity, inhibits interstitial fibrosis and attenuates cardiac dysfunction (8). Four weeks after adenovirus-mediated overexpression of miR-101a in rats with chronic myocardial infarction, echocardiography and hemodynamic measurements indicated remarkable improvement of the cardiac performance (9). Furthermore, the interstitial fibrosis was alleviated and the expression of c-Fos and transforming growth factor-β1 was inhibited (9). Intramyocardial injection of Lentiviruses expressing miR-24 improves heart function and attenuates fibrosis in the infarct border zone of the heart two weeks after MI (10). Systemic neutralization of miR-433 or adeno-associated virus 9 (AAV9)-mediated cardiac transfer of a miR-433 sponge attenuates also cardiac fibrosis and ventricular dysfunction following myocardial infarction (11). On the other hand, cardiac fibrosis is significantly reduced in infarcted heart when treated with miR-328 antisense (12). It is unclear whether the dissociation between fibrosis and heart function is due to different methodologies, to specific pathways studied but it will be important to clarify this in future studies and to determine whether reversing fibrosis is still a clinical intervention of interest.

miR-33 in the heart was predominantly expressed in CFs, and miR-33 deficiency impaired cell proliferation. miR-33 was found to preserve the lipid raft cholesterol content in fibroblasts by regulating genes involved in cholesterol metabolism, including ABCA1, ABCG1, and NPC1. This is a well-known and not surprising role for miR-33 as miR-33a and miR-33b are expressed as intronic miRNAs along with SREBF2 and SREBF1, their host genes coding for transcription factors that regulate the synthesis/uptake of cholesterol and fatty acid (13-15). miR-33a/b have been shown to inhibit genes implicated in pathways opposed to functions driven by SREBP, including cholesterol efflux (ABCA1, ABCG1, NPC1) (13-15) and FAO (HADHB, CROT, CPT1A, PRKAA1) (16-18). Several other properties have been attributed to miR-33. Interestingly, several mitochondrial genes [i.e., PGC-1α (19), PDK4 and SLC25A (20)] has been determined as direct and specific miR-33 targets, with conserved binding sites in the 3'UTR of both human and mouse transcripts. Anti-miR33, by de-repressing PGC-1α levels and enhancing downstream factors, can indirectly stimulate NRF1 and OXPHOS complexes expressions, promoting respectively mitochondrial biogenesis and efficient production of ATP (21,22). Therefore, miR-33 inhibition promotes mitochondrial biogenesis, aerobic respiration and activity. In addition, miR-33a and miR-33b have also been shown to control the expression of Ampkα1 and sirtuin 6 (Sirt6), altering the balance of cellular glycolysis/FAO. AMPK increases FAO via phosphorylation and inhibition of acetyl-CoA carboxylase (22,23), and via SIRT1 and PGC-1α expression (24,25). This is of great importance because the failing heart normally adapts using changes in enzymatic and signaling pathways, ultimately resulting in a metabolic switch, away from FAO toward greater glucose metabolism to maximize efficiency (26,27). This is in keeping with the results presented by Nishiga et al. showing that the expression level of miR-33 was significantly upregulated in response to TAC and suggesting a metabolic switch toward glycolysis during the hypertrophic phase in this model.

Given its broad range of implications, including in metabolism, miR-33 cannot be only considered as an anti-fibrotic miR. The dissociation between improvement of cardiac fibrosis and still the deterioration in cardiac function in miR-33 KO mice might be explained by the fact that miR-33 is possibly needed for a proper metabolic adaptation of the heart during the compensatory phase. It will be interesting to further investigate the role of miR-33 in cardiac failure. Moreover, although being an aberrant wound healing process, fibrosis is an adaptive response to injury and attempts to inhibit it may not be beneficial at certain stages of the disease.

Acknowledgments

Funding: R Paulin is supported by the Heart and Stroke Foundation and the Canadian Institutes of Health Research.

Footnote

Provenance and Peer Review: This article was commissioned and reviewed by the Section Editor Yongqin Li (School of Life Sciences, Shanghai University, Shanghai, China).

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/ncri.2017.10.01). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

References

1. Mozaffarian D, Benjamin EJ, Go AS, et al. Heart disease and stroke statistics--2015 update: a report from the American Heart Association. Circulation 2015;131:e29-322. [Crossref] [PubMed]
2. Camelliti P, Borg TK, Kohl P. Structural and functional characterisation of cardiac fibroblasts. Cardiovasc Res 2005;65:40-51. [Crossref] [PubMed]
3. Souders CA, Bowers SL, Baudino TA. Cardiac fibroblast: the renaissance cell. Circ Res 2009;105:1164-76. [Crossref] [PubMed]
4. Porter KE, Turner NA. Cardiac fibroblasts: at the heart of myocardial remodeling. Pharmacol Ther 2009;123:255-78. [Crossref] [PubMed]
5. Diez J, Querejeta R, Lopez B, et al. Losartan-dependent regression of myocardial fibrosis is associated with reduction of left ventricular chamber stiffness in hypertensive patients. Circulation 2002;105:2512-7. [Crossref] [PubMed]
6. Tijsen AJ, van der Made I, van den Hoogenhof MM, et al. The microRNA-15 family inhibits the TGFbeta-pathway in the heart. Cardiovasc Res 2014;104:61-71. [Crossref] [PubMed]
7. Abonnenc M, Nabeebaccus AA, Mayr U, et al. Extracellular matrix secretion by cardiac fibroblasts: role of microRNA-29b and microRNA-30c. Circ Res 2013;113:1138-47. [Crossref] [PubMed]
8. Thum T, Gross C, Fiedler J, et al. MicroRNA-21 contributes to myocardial disease by stimulating MAP kinase signalling in fibroblasts. Nature 2008;456:980-4. [Crossref] [PubMed]
9. Pan Z, Sun X, Shan H, et al. MicroRNA-101 inhibited postinfarct cardiac fibrosis and improved left ventricular compliance via the FBJ osteosarcoma oncogene/transforming growth factor-beta1 pathway. Circulation 2012;126:840-50. [Crossref] [PubMed]
10. Wang J, Huang W, Xu R, et al. MicroRNA-24 regulates cardiac fibrosis after myocardial infarction. J Cell Mol Med 2012;16:2150-60. [Crossref] [PubMed]
11. Tao L, Bei Y, Chen P, et al. Crucial Role of miR-433 in Regulating Cardiac Fibrosis. Theranostics 2016;6:2068-83. [Crossref] [PubMed]
12. Du W, Liang H, Gao X, et al. MicroRNA-328, a Potential Anti-Fibrotic Target in Cardiac Interstitial Fibrosis. Cell Physiol Biochem 2016;39:827-36. [Crossref] [PubMed]
13. Marquart TJ, Allen RM, Ory DS, et al. miR-33 links SREBP-2 induction to repression of sterol transporters. Proc Natl Acad Sci U S A 2010;107:12228-32. [Crossref] [PubMed]
14. Rayner KJ, Suarez Y, Davalos A, et al. MiR-33 contributes to the regulation of cholesterol homeostasis. Science 2010;328:1570-3. [Crossref] [PubMed]
15. Najafi-Shoushtari SH, Kristo F, Li Y, et al. MicroRNA-33 and the SREBP host genes cooperate to control cholesterol homeostasis. Science 2010;328:1566-9. [Crossref] [PubMed]
16. Davalos A, Goedeke L, Smibert P, et al. miR-33a/b contribute to the regulation of fatty acid metabolism and insulin signaling. Proc Natl Acad Sci U S A 2011;108:9232-7. [Crossref] [PubMed]
17. Gerin I, Clerbaux LA, Haumont O, et al. Expression of miR-33 from an SREBP2 intron inhibits cholesterol export and fatty acid oxidation. J Biol Chem 2010;285:33652-61. [Crossref] [PubMed]
18. Rottiers V, Najafi-Shoushtari SH, Kristo F, et al. MicroRNAs in metabolism and metabolic diseases. Cold Spring Harb Symp Quant Biol 2011;76:225-33. [Crossref] [PubMed]
19. Ramirez CM, Goedeke L, Rotllan N, et al. MicroRNA 33 regulates glucose metabolism. Mol Cell Biol 2013;33:2891-902. [Crossref] [PubMed]
20. Rayner KJ, Esau CC, Hussain FN, et al. Inhibition of miR-33a/b in non-human primates raises plasma HDL and lowers VLDL triglycerides. Nature 2011;478:404-7. [Crossref] [PubMed]
21. Wu Z, Puigserver P, Andersson U, et al. Mechanisms controlling mitochondrial biogenesis and respiration through the thermogenic coactivator PGC-1. Cell 1999;98:115-24. [Crossref] [PubMed]
22. Karunakaran D, Thrush AB, Nguyen MA, et al. Macrophage Mitochondrial Energy Status Regulates Cholesterol Efflux and Is Enhanced by Anti-miR33 in Atherosclerosis. Circ Res 2015;117:266-78. [Crossref] [PubMed]
23. McGarry JD, Leatherman GF, Foster DW. Carnitine palmitoyltransferase I. The site of inhibition of hepatic fatty acid oxidation by malonyl-CoA. J Biol Chem 1978;253:4128-36. [PubMed]
24. Lin J, Handschin C, Spiegelman BM. Metabolic control through the PGC-1 family of transcription coactivators. Cell Metab 2005;1:361-70. [Crossref] [PubMed]
25. O'Neill HM, Holloway GP, Steinberg GR. AMPK regulation of fatty acid metabolism and mitochondrial biogenesis: implications for obesity. Mol Cell Endocrinol 2013;366:135-51. [Crossref] [PubMed]
26. Witteles RM, Fowler MB. Insulin-resistant cardiomyopathy clinical evidence, mechanisms, and treatment options. J Am Coll Cardiol 2008;51:93-102. [Crossref] [PubMed]
27. Davila-Roman VG, Vedala G, Herrero P, et al. Altered myocardial fatty acid and glucose metabolism in idiopathic dilated cardiomyopathy. J Am Coll Cardiol 2002;40:271-7. [Crossref] [PubMed]