Top

Published in:

Open Access 01-12-2018 | Primary research

miR-133a function in the pathogenesis of dedifferentiated liposarcoma

Authors: Peter Y. Yu, Gonzalo Lopez, Danielle Braggio, David Koller, Kate Lynn J. Bill, Bethany C. Prudner, Abbie Zewdu, James L. Chen, O. Hans Iwenofu, Dina Lev, Anne M. Strohecker, Joelle M. Fenger, Raphael E. Pollock, Denis C. Guttridge

Published in: Cancer Cell International | Issue 1/2018

Abstract

Background

Sarcomas are malignant heterogeneous tumors of mesenchymal derivation. Dedifferentiated liposarcoma (DDLPS) is aggressive with recurrence in 80% and metastasis in 20% of patients. We previously found that miR-133a was significantly underexpressed in liposarcoma tissues. As this miRNA has recently been shown to be a tumor suppressor in many cancers, the objective of this study was to characterize the biological and molecular consequences of miR-133a underexpression in DDLPS.

Methods

Real-time PCR was used to evaluate expression levels of miR-133a in human DDLPS tissue, normal fat tissue, and human DDLPS cell lines. DDLPS cells were stably transduced with miR-133a vector to assess the effects in vitro on proliferation, cell cycle, cell death, migration, and metabolism. A Seahorse Bioanalyzer system was also used to assess metabolism in vivo by measuring glycolysis and oxidative phosphorylation (OXPHOS) in subcutaneous xenograft tumors from immunocompromised mice.

Results

miR-133a expression was significantly decreased in human DDLPS tissue and cell lines. Enforced expression of miR-133a decreased cell proliferation, impacted cell cycle progression kinetics, decreased glycolysis, and increased OXPHOS. There was no significant effect on cell death or migration. Using an in vivo xenograft mouse study, we showed that tumors with increased miR-133a expression had no difference in tumor growth compared to control, but did exhibit an increase in OXPHOS metabolic respiration.

Conclusions

Based on our collective findings, we propose that in DDPLS, loss of miR-133a induces a metabolic shift due to a reduction in oxidative metabolism favoring a Warburg effect in DDLPS tumors, but this regulation on metabolism was not sufficient to affect DDPLS.

Available only for authorised users

Coindre JM, Pedeutour F, Aurias A. Well-differentiated and dedifferentiated liposarcomas. Virchows Arch. 2010;456:167–79.CrossRefPubMed

Tseng WW, Somaiah N, Lazar AJ, Lev DC, Pollock RE. Novel systemic therapies in advanced liposarcoma: a review of recent clinical trial results. Cancers. 2013;5:529–49.CrossRefPubMedPubMedCentral

Pedeutour F, Maire G, Pierron A, Thomas DM, Garsed DW, Bianchini L, Duranton-Tanneur V, Cortes-Maurel A, Italiano A, Squire JA, Coindre JM. A newly characterized human well-differentiated liposarcoma cell line contains amplifications of the 12q12-21 and 10p11-14 regions. Virchows Arch. 2012;461:67–78.CrossRefPubMed

Jansson MD, Lund AH. MicroRNA and cancer. Mol Oncol. 2012;6:590–610.CrossRefPubMedPubMedCentral

Hayes J, Thygesen H, Tumilson C, Droop A, Boissinot M, Hughes TA, Westhead D, Alder JE, Shaw L, Short SC, Lawler SE. Prediction of clinical outcome in glioblastoma using a biologically relevant nine-microRNA signature. Mol Oncol. 2015;9:704–14.CrossRefPubMed

Kent OA, Mendell JT. A small piece in the cancer puzzle: microRNAs as tumor suppressors and oncogenes. Oncogene. 2006;25:6188–96.CrossRefPubMed

Bianchini L, Saada E, Gjernes E, Marty M, Haudebourg J, Birtwisle-Peyrottes I, Keslair F, Chignon-Sicard B, Chamorey E, Pedeutour F. Let-7 microRNA and HMGA2 levels of expression are not inversely linked in adipocytic tumors: analysis of 56 lipomas and liposarcomas with molecular cytogenetic data. Genes Chromosomes Cancer. 2011;50:442–55.CrossRefPubMed

Lee DH, Amanat S, Goff C, Weiss LM, Said JW, Doan NB, Sato-Otsubo A, Ogawa S, Forscher C, Koeffler HP. Overexpression of miR-26a-2 in human liposarcoma is correlated with poor patient survival. Oncogenesis. 2013;2:e47.CrossRefPubMedPubMedCentral

Gits CM, van Kuijk PF, Jonkers MB, Boersma AW, Smid M, van Ijcken WF, Coindre JM, Chibon F, Verhoef C, Mathijssen RH, den Bakker MA, Verweij J, Sleijfer S, Wiemer EA. MicroRNA expression profiles distinguish liposarcoma subtypes and implicate miR-145 and miR-451 as tumor suppressors. Int J Cancer. 2014;135:348–61.CrossRefPubMed

10.

Zhang P, Bill K, Liu J, Young E, Peng T, Bolshakov S, Hoffman A, Song Y, Demicco EG, Terrada DL, Creighton CJ, Anderson ML, Lazar AJ, Calin GG, Pollock RE, Lev D. miR-155 is a liposarcoma oncogene that targets casein kinase-1alpha and enhances beta-catenin signaling. Cancer Res. 2012;72:1751–62.CrossRefPubMedPubMedCentral

11.

Casadei L, Calore F, Creighton CJ, Guescini M, Batte K, Iwenofu OH, Zewdu A, Braggio DA, Bill KL, Fadda P, Lovat F, Lopez G, Gasparini P, Chen JL, Kladney RD, Leone G, Lev D, Croce CM, Pollock RE. Exosome-derived miR-25-3p and miR-92a-3p stimulate liposarcoma progression. Cancer Res. 2017;77:3846–56.CrossRefPubMedPubMedCentral

12.

Yu PY, Balkhi MY, Ladner KJ, Alder H, Yu L, Mo X, Kraybill WG, Guttridge DC, Iwenofu OH. A selective screening platform reveals unique global expression patterns of microRNAs in a cohort of human soft-tissue sarcomas. Lab Invest. 2016;96:481–91.CrossRefPubMed

13.

Chen JF, Mandel EM, Thomson JM, Wu Q, Callis TE, Hammond SM, Conlon FL, Wang DZ. The role of microRNA-1 and microRNA-133 in skeletal muscle proliferation and differentiation. Nat Genet. 2006;38:228–33.CrossRefPubMed

14.

Trajkovski M, Ahmed K, Esau CC, Stoffel M. MyomiR-133 regulates brown fat differentiation through Prdm16. Nat Cell Biol. 2012;14:1330–5.CrossRefPubMed

15.

Liu W, Bi P, Shan T, Yang X, Yin H, Wang YX, Liu N, Rudnicki MA, Kuang S. miR-133a regulates adipocyte browning in vivo. PLoS Genet. 2013;9:e1003626.CrossRefPubMedPubMedCentral

16.

Yin H, Pasut A, Soleimani VD, Bentzinger CF, Antoun G, Thorn S, Seale P, Fernando P, van Ijcken W, Grosveld F, Dekemp RA, Boushel R, Harper ME, Rudnicki MA. MicroRNA-133 controls brown adipose determination in skeletal muscle satellite cells by targeting Prdm16. Cell Metab. 2013;17:210–24.CrossRefPubMedPubMedCentral

17.

Li P, Wei X, Guan Y, Chen Q, Zhao T, Sun C, Wei L. MicroRNA-1 regulates chondrocyte phenotype by repressing histone deacetylase 4 during growth plate development. FASEB J. 2014;28:3930–41.CrossRefPubMedPubMedCentral

18.

Stumpfova Z, Hezova R, Meli AC, Slaby O, Michalek J. MicroRNA profiling of activated and tolerogenic human dendritic cells. Mediators Inflamm. 2014;2014:259689.CrossRefPubMedPubMedCentral

19.

Zhang X, Zuo X, Yang B, Li Z, Xue Y, Zhou Y, Huang J, Zhao X, Zhou J, Yan Y, Zhang H, Guo P, Sun H, Guo L, Zhang Y, Fu XD. MicroRNA directly enhances mitochondrial translation during muscle differentiation. Cell. 2014;158:607–19.CrossRefPubMedPubMedCentral

20.

Mitchelson KR, Qin WY. Roles of the canonical myomiRs miR-1, -133 and -206 in cell development and disease. World J Biol Chem. 2015;6:162–208.CrossRefPubMedPubMedCentral

21.

Peng T, Zhang P, Liu J, Nguyen T, Bolshakov S, Belousov R, Young ED, Wang X, Brewer K, Terrada LL, Oliveira AM, Lazar AJ, Lev D. An experimental model for the study of well differentiated and dedifferentiated liposarcoma; deregulation of targetable tyrosine kinase receptors. Lab Invest. 2011;91(3):392–403CrossRefPubMed

22.

Duisters RF, Tijsen AJ, Schroen B, Leenders JJ, Lentink V, van der Made I, Herias V, van Leeuwen RE, Schellings MW, Barenbrug P, Maessen JG, Heymans S, Pinto YM, Creemers EE. miR-133 and miR-30 regulate connective tissue growth factor: implications for a role of microRNAs in myocardial matrix remodeling. Circ Res. 2009;104:170–8.CrossRefPubMed

23.

Willems PH, Rossignol R, Dieteren CE, Murphy MP, Koopman WJ. Redox homeostasis and mitochondrial dynamics. Cell Metab. 2015;22:207–18.CrossRefPubMed

24.

Sebastian D, Hernandez-Alvarez MI, Segales J, Sorianello E, Munoz JP, Sala D, Waget A, Liesa M, Paz JC, Gopalacharyulu P, Oresic M, Pich S, Burcelin R, Palacin M, Zorzano A. Mitofusin 2 (Mfn2) links mitochondrial and endoplasmic reticulum function with insulin signaling and is essential for normal glucose homeostasis. Proc Natl Acad Sci USA. 2012;109:5523–8.CrossRefPubMedPubMedCentral

25.

Bill KL, Garnett J, Ma X, May CD, Bolshakov S, Lazar AJ, Lev DC, Pollock RE. The hepatocyte growth factor receptor as a potential therapeutic target for dedifferentiated liposarcoma. Lab Invest. 2015;95:951–61.CrossRefPubMedPubMedCentral

26.

Bill KL, Garnett J, Meaux I, Ma X, Creighton CJ, Bolshakov S, Barriere C, Debussche L, Lazar AJ, Prudner BC, Casadei L, Braggio D, Lopez G, Zewdu A, Bid H, Lev D, Pollock RE. SAR405838: a novel and potent inhibitor of the MDM2:p53 axis for the treatment of dedifferentiated liposarcoma. Clin Cancer Res. 2016;22:1150–60.CrossRefPubMed

27.

Cui W, Zhang S, Shan C, Zhou L, Zhou Z. microRNA-133a regulates the cell cycle and proliferation of breast cancer cells by targeting epidermal growth factor receptor through the EGFR/Akt signaling pathway. FEBS J. 2013;280:3962–74.CrossRefPubMed

28.

Chiyomaru T, Enokida H, Tatarano S, Kawahara K, Uchida Y, Nishiyama K, Fujimura L, Kikkawa N, Seki N, Nakagawa M. miR-145 and miR-133a function as tumour suppressors and directly regulate FSCN1 expression in bladder cancer. Br J Cancer. 2010;102:883–91.CrossRefPubMedPubMedCentral

29.

Wang H, An H, Wang B, Liao Q, Li W, Jin X, Cui S, Zhang Y, Ding Y, Zhao L. miR-133a represses tumour growth and metastasis in colorectal cancer by targeting LIM and SH3 protein 1 and inhibiting the MAPK pathway. Eur J Cancer. 2013;49:3924–35.CrossRefPubMed

30.

Dong Y, Zhao J, Wu CW, Zhang L, Liu X, Kang W, Leung WW, Zhang N, Chan FK, Sung JJ, Ng SS, Yu J. Tumor suppressor functions of miR-133a in colorectal cancer. Mol Cancer Res. 2013;11:1051–60.CrossRefPubMed

31.

Cheng Z, Liu F, Wang G, Li Y, Zhang H, Li F. miR-133 is a key negative regulator of CDC42-PAK pathway in gastric cancer. Cell Signal. 2014;26:2667–73.CrossRefPubMed

32.

Horie T, Ono K, Nishi H, Iwanaga Y, Nagao K, Kinoshita M, Kuwabara Y, Takanabe R, Hasegawa K, Kita T, Kimura T. MicroRNA-133 regulates the expression of GLUT4 by targeting KLF15 and is involved in metabolic control in cardiac myocytes. Biochem Biophys Res Commun. 2009;389:315–20.CrossRefPubMed

33.

Pelicano H, Xu RH, Du M, Feng L, Sasaki R, Carew JS, Hu Y, Ramdas L, Hu L, Keating MJ, Zhang W, Plunkett W, Huang P. Mitochondrial respiration defects in cancer cells cause activation of Akt survival pathway through a redox-mediated mechanism. J Cell Biol. 2006;175:913–23.CrossRefPubMedPubMedCentral

34.

Parks SK, Chiche J, Pouyssegur J. Disrupting proton dynamics and energy metabolism for cancer therapy. Nat Rev Cancer. 2013;13:611–23.CrossRefPubMed

35.

Vander Heiden MG, Cantley LC, Thompson CB. Understanding the Warburg effect: the metabolic requirements of cell proliferation. Science. 2009;324:1029–33.CrossRef

36.

Warburg O. On the origin of cancer cells. Science. 1956;123:309–14.CrossRefPubMed

37.

Zheng J. Energy metabolism of cancer: glycolysis versus oxidative phosphorylation (Review). Oncol Lett. 2012;4:1151–7.CrossRefPubMedPubMedCentral

38.

Zhang Y, Yang JM. Altered energy metabolism in cancer: a unique opportunity for therapeutic intervention. Cancer Biol Ther. 2013;14:81–9.CrossRefPubMedPubMedCentral

39.

Moreno-Sanchez R, Rodriguez-Enriquez S, Marin-Hernandez A, Saavedra E. Energy metabolism in tumor cells. FEBS J. 2007;274:1393–418.CrossRefPubMed

40.

Shintaku J, Guttridge DC. Analysis of aerobic respiration in intact skeletal muscle tissue by microplate-based respirometry. Methods Mol Biol. 2016;1460:337–43.CrossRefPubMed

41.

Bi P, Yue F, Karki A, Castro B, Wirbisky SE, Wang C, Durkes A, Elzey BD, Andrisani OM, Bidwell CA, Freeman JL, Konieczny SF, Kuang S. Notch activation drives adipocyte dedifferentiation and tumorigenic transformation in mice. J Exp Med. 2016;213:2019–37.CrossRefPubMedPubMedCentral

Title: miR-133a function in the pathogenesis of dedifferentiated liposarcoma
Authors: Peter Y. Yu
Gonzalo Lopez
Danielle Braggio
David Koller
Kate Lynn J. Bill
Bethany C. Prudner
Abbie Zewdu
James L. Chen
O. Hans Iwenofu
Dina Lev
Anne M. Strohecker
Joelle M. Fenger
Raphael E. Pollock
Denis C. Guttridge
Publication date: 01-12-2018
Publisher: BioMed Central
Published in: Cancer Cell International / Issue 1/2018
Electronic ISSN: 1475-2867
DOI: https://doi.org/10.1186/s12935-018-0583-2

Webinar | 19-02-2024 | 17:30 (CET)

Keynote webinar | Spotlight on antibody–drug conjugates in cancer

Watch now

Antibody–drug conjugates (ADCs) are novel agents that have shown promise across multiple tumor types. Explore the current landscape of ADCs in breast and lung cancer with our experts, and gain insights into the mechanism of action, key clinical trials data, existing challenges, and future directions.

Dr. Véronique Diéras

Prof. Fabrice Barlesi

Developed by: Springer Medicine

At a glance: The STEP trials

Springer Medicine

Abstract

Background

Methods

Results

Conclusions

Please log in to get access to this content

Other articles of this Issue 1/2018

Identification of four differentially methylated genes as prognostic signatures for stage I lung adenocarcinoma

Nanostructured lipid carriers for MicroRNA delivery in tumor gene therapy

Arachidonic acid-induced Ca2+ entry and migration in a neuroendocrine cancer cell line

B7-H4 overexpression contributes to poor prognosis and drug-resistance in triple-negative breast cancer

Assessment of intratumor immune-microenvironment in colorectal cancers with extranodal extension of nodal metastases

Circ-ZEB1.33 promotes the proliferation of human HCC by sponging miR-200a-3p and upregulating CDK6

Keynote webinar | Spotlight on antibody–drug conjugates in cancer