Sage Journals: Discover world-class research

Abstract

Hereditary gingival fibromatosis (HGF) is a highly genetically heterogeneous disease, and current therapeutic method is limited to surgical resection with a high recurrence rate. MicroRNAs (miRNAs) are able to fine-tune large-scale target genes. Here we established a simple but effective computational strategy based on available miRNA target prediction algorithms to pinpoint the most potent miRNA that could negatively regulate a group of functional genes. Based on this rationale, miR-335-3p was top ranked by putatively targeting 85 verified profibrotic genes and 79 upregulated genes in HGF patients. Experimentally, downregulation of miR-355-3p was demonstrated in HGF-derived gingival fibroblasts as well as in transforming growth factor β–stimulated normal human gingival fibroblasts (NHGFs) compared to normal control. Ectopic miR-335-3p attenuated, whereas knockdown of miR-335-3p promoted, the fibrogenic activity of human gingival fibroblasts. Mechanically, miR-335-3p directly targeted SOS1, SMAD2/3, and CTNNB1 by canonical and noncanonical base paring. In particular, different portfolios of fibrotic markers were suppressed by silencing SOS1, SMAD2/3, or CTNNB1, respectively. Thus, our study first proposes a novel miRNA screening approach targeting a functionally related gene set and identifies miR-335-3p as a novel target for HGF treatment. Mechanically, miR-335-3p suppresses the fibrogenic activity of human gingival fibroblasts by repressing multiple core molecules in profibrotic networks. Our strategy provides a new paradigm in the treatment for HGF as well as other diseases.

Keywords

gingiva microRNAs fibrosis bioinformatics extracellular matrix heterogeneity

Get full access to this article

View all access options for this article.

References

Akhmetshina

Palumbo

Dees

Bergmann

Venalis

Zerr

Horn

Kireva

Beyer

Zwerina

, et al. 2012. Activation of canonical wnt signalling is required for TGF-beta-mediated fibrosis. Nat Commun. 3:735.

Arvio

Kero

Pirinen

Lukinmaa

. 1999. Overgrowth of oral mucosa and facial skin, a novel feature of aspartylglucosaminuria. J Med Genet. 36(5):398–404.

Baek

Villen

Shin

Camargo

Gygi

Bartel

. 2008. The impact of microRNAs on protein output. Nature. 455(7209):64–71.

Bartel

. 2009. MicroRNAs: target recognition and regulatory functions. Cell. 136(2):215–233.

Bayram

White

Elcioglu

Cho

Zadeh

Gedikbasi

Palanduz

Ozturk

Cefle

Kasapcopur

, et al. 2017. Rest final-exon-truncating mutations cause hereditary gingival fibromatosis. Am J Hum Genet. 101(1):149–156.

Bitu

Sobral

Kellermann

Martelli-Junior

Zecchin

Graner

Coletta

. 2006. Heterogeneous presence of myofibroblasts in hereditary gingival fibromatosis. J Clin Periodontol. 33(6):393–400.

Brownstein

Towne

Luquette

Harris

Marinakis

Meinecke

Kutsche

Campeau

Margulies

, et al. 2013. Mutation of KCNJ8 in a patient with Cantu syndrome with unique vascular abnormalities—support for the role of K(ATP) channels in this condition. Eur J Med Genet. 56(12):678–682.

Caja

Dituri

Mancarella

Caballero-Diaz

Moustakas

Giannelli

Fabregat

. 2018. TGF-beta and the tissue microenvironment: relevance in fibrosis and cancer. Int J Mol Sci. 19(5):E1294.

Chen

Zhang

Yao

Zhu

. 2011. Loss of expression of miR-335 is implicated in hepatic stellate cell migration and activation. Exp Cell Res. 317(12):1714–1725.

10.

Chi

Hannon

Darnell

. 2012. An alternative mode of microRNA target recognition. Nat Struct Mol Biol. 19(3):321–327.

11.

de Andrade

Cotrin

Graner

Almeida

Sauk

Coletta

. 2001. Transforming growth factor–beta1 autocrine stimulation regulates fibroblast proliferation in hereditary gingival fibromatosis. J Periodontol. 72(12):1726–1733.

12.

Gawron

Lazarz-Bartyzel

Potempa

Chomyszyn-Gajewska

. 2016. Gingival fibromatosis: clinical, molecular and therapeutic issues. Orphanet J Rare Dis. 11:9.

13.

Hafner

Landthaler

Burger

Khorshid

Hausser

Berninger

Rothballer

Ascano

Jr Jungkamp

Munschauer

, et al. 2010. Transcriptome-wide identification of RNA-binding protein and microRNA target sites by par-clip. Cell. 141(1):129–141.

14.

Hakkinen

Csiszar

. 2007. Hereditary gingival fibromatosis: characteristics and novel putative pathogenic mechanisms. J Dent Res. 86(1):25–34.

15.

Hart

Zhang

Gorry

Hart

Cooper

Marazita

Marks

Cortelli

Pallos

. 2002. A mutation in the SOS1 gene causes hereditary gingival fibromatosis type 1. Am J Hum Genet. 70(4):943–954.

16.

Heindryckx

Binet

Ponticos

Rombouts

Lau

Kreuger

Gerwins

. 2016. Endoplasmic reticulum stress enhances fibrosis through IRE1alpha-mediated degradation of miR-150 and XBP-1 splicing. EMBO Mol Med. 8(7):729–744.

17.

Kim

Nikoloudaki

Michelsons

Creber

Hamilton

. 2019. Fibronectin synthesis, but not alpha-smooth muscle expression, is regulated by periostin in gingival healing through FAK/JNK signaling. Sci Rep. 9(1):2708.

18.

Koo

Lee

Kim

. 2016. Endoplasmic reticulum stress in hepatic stellate cells promotes liver fibrosis via PERK-mediated degradation of HNRNPA1 and up-regulation of SMAD2. Gastroenterology. 150(1):181–193.e8.

19.

Lenna

Trojanowska

. 2012. The role of endoplasmic reticulum stress and the unfolded protein response in fibrosis. Curr Opin Rheumatol. 24(6):663–668.

20.

Liang

Zhang

Cui

Quan

Yang

. 2015. The anti-fibrotic effects of microRNA-153 by targeting TGFBR-2 in pulmonary fibrosis. Exp Mol Pathol. 99(2):279–285.

21.

Lino Cardenas

Henaoui

Courcot

Roderburg

Cauffiez

Aubert

Copin

Wallaert

Glowacki

Dewaeles

, et al. 2013. miR-199a-5p is upregulated during fibrogenic response to tissue injury and mediates TGFbeta-induced lung fibroblast activation by targeting caveolin-1. PLoS Genet. 9(2):e1003291.

22.

Liu

Friggeri

Yang

Milosevic

Ding

Thannickal

Kaminski

Abraham

. 2010. Mir-21 mediates fibrogenic activation of pulmonary fibroblasts and lung fibrosis. J Exp Med. 207(8):1589–1597.

23.

Liu

Sun

Zhao

. 2017. Ongene: a literature-based database for human oncogenes. J Genet Genomics. 44(2):119–121.

24.

Liu

Liang

Zhou

Wang

Zhao

. 2016. Mir-335 functions as a tumor suppressor and regulates survivin expression in osteosarcoma. Eur Rev Med Pharmacol Sci. 20(7):1251–1257.

25.

Martin

Conger

Yan

Hoang

Miller

Buechlein

Rusch

Nephew

Collins-Burow

Burow

. 2017. MicroRNA-335-5p and -3p synergize to inhibit estrogen receptor alpha expression and promote tamoxifen resistance. FEBS Lett. 591(2):382–392.

26.

O’Sullivan

Bitu

Daly

Urquhart

Barron

Bhaskar

Martelli-Junior

Dos

SNPE

Mansilla

Murray

, et al. 2011. Whole-exome sequencing identifies FAM20A mutations as a cause of amelogenesis imperfecta and gingival hyperplasia syndrome. Am J Hum Genet. 88(5):616–620.

27.

Piersma

Bank

Boersema

. 2015. Signaling in fibrosis: TGF-beta, WNT, and YAP/TAZ converge. Front Med (Lausanne). 2:59.

28.

Rodriguez

Griffiths-Jones

Ashurst

Bradley

. 2004. Identification of mammalian microRNA host genes and transcription units. Genome Res. 14(10A):1902–1910.

29.

Selbach

Schwanhausser

Thierfelder

Fang

Khanin

Rajewsky

. 2008. Widespread changes in protein synthesis induced by microRNAs. Nature. 455(7209):58–63.

30.

Shi

Lin

Zhang

Hong

. 2011. Hereditary gingival fibromatosis: a three-generation case and pathogenic mechanism research on progress of the disease. J Periodontol. 82(7):1089–1095.

31.

Shin

Nam

Farh

Chiang

Shkumatava

Bartel

. 2010. Expanding the microRNA targeting code: functional sites with centered pairing. Mol Cell. 38(6):789–802.

32.

Weber

Baxter

Zhang

Huang

Lee

Galas

Wang

. 2010. The microRNA spectrum in 12 body fluids. Clin Chem. 56(11):1733–1741.

33.

Wilson

Sunley

Smith

Pope

Bromhead

Fitzpatrick

Di Rocco

van Steensel

Coman

Leventer

, et al. 2014. Mutations in SH3PXD2B cause Borrone dermato-cardio-skeletal syndrome. Eur J Hum Genet. 22(6):741–747.

34.

Shi

Cheng

Peng

Huang

Liu

Huang

Peng

Bian

. 2005. A novel locus for autosomal dominant hereditary gingival fibromatosis, GINGF3, maps to chromosome 2p22.3-p23.3. Clin Genet. 68(3):239–244.

35.

Shi

Yin

Meng

Wang

Bian

. 2009. Further evidence of genetic heterogeneity segregating with hereditary gingival fibromatosis. J Clin Periodontol. 36(8):627–633.

36.

Zhou

Liu

Kahn

Ann

Han

Wang

Nguyen

Flodby

Zhong

Krishnaveni

, et al. 2012. Interactions between beta-catenin and transforming growth factor-beta signaling pathways mediate epithelial-mesenchymal transition and are dependent on the transcriptional co-activator camp-response element-binding protein (CREB)–binding protein (CBP). J Biol Chem. 287(10):7026–7038.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

1.21 MB

Antifibrotic Potential of MiR-335-3p in Hereditary Gingival Fibromatosis

Abstract

Keywords

Get full access to this article

References

Supplementary Material