HDACs control RUNX2 expression in cancer cells through redundant and cell context-dependent mechanisms.
Cell Communication
/ drug effects
Cell Line, Tumor
Core Binding Factor Alpha 1 Subunit
/ genetics
Gene Expression Regulation, Neoplastic
/ drug effects
Histone Deacetylase 6
/ metabolism
Histone Deacetylase Inhibitors
/ pharmacology
Histone Deacetylases
/ metabolism
Humans
Models, Biological
Multiprotein Complexes
Neoplasms
/ etiology
Protein Binding
RNA, Small Interfering
/ genetics
Thyroid Neoplasms
/ etiology
Transcription, Genetic
Cancer
Gene expression regulation
HDAC inhibitors
HDACs
RUNX2
Journal
Journal of experimental & clinical cancer research : CR
ISSN: 1756-9966
Titre abrégé: J Exp Clin Cancer Res
Pays: England
ID NLM: 8308647
Informations de publication
Date de publication:
08 Aug 2019
08 Aug 2019
Historique:
received:
14
06
2019
accepted:
29
07
2019
entrez:
10
8
2019
pubmed:
10
8
2019
medline:
17
1
2020
Statut:
epublish
Résumé
RUNX2 is a Runt-related transcription factor required during embryogenesis for skeletal development and morphogenesis of other organs including thyroid and breast gland. Consistent evidence indicates that RUNX2 expression is aberrantly reactivated in cancer and supports tumor progression. The mechanisms leading to RUNX2 expression in cancer has only recently began to emerge. Previously, we showed that suppressing the activity of the epigenetic regulators HDACs significantly represses RUNX2 expression highlighting a role for these enzymes in RUNX2 reactivation in cancer. However, the molecular mechanisms by which HDACs control RUNX2 are still largely unexplored. Here, to fill this gap, we investigated the role of different HDACs in RUNX2 expression regulation in breast and thyroid cancer, tumors that majorly rely on RUNX2 for their development and progression. Proliferation assays and evaluation of RUNX2 mRNA levels by qRT-PCR were used to evaluate the effect of several HDACi and specific siRNAs on a panel of cancer cell lines. Moreover, ChIP and co-IP assays were performed to elucidate the molecular mechanism underneath the RUNX2 transcriptional regulation. Finally, RNA-sequencing unveiled a new subset of genes whose transcription is regulated by the complex RUNX2-HDAC6. In this study, we showed that Class I HDACs and in particular HDAC1 are required for RUNX2 efficient transcription in cancer. Furthermore, we found an additional and cell-specific function of HDAC6 in driving RUNX2 expression in thyroid cancer cells. In this model, HDAC6 likely stabilizes the assembly of the transcriptional complex, which includes HDAC1, on the RUNX2 P2 promoter potentiating its transcription. Since a functional interplay between RUNX2 and HDAC6 has been suggested, we used RNA-Seq profiling to consolidate this evidence in thyroid cancer and to extend the knowledge on this cooperation in a setting in which HDAC6 also controls RUNX2 expression. Overall, our data provide new insights into the molecular mechanisms controlling RUNX2 in cancer and consolidate the rationale for the use of HDACi as potential pharmacological strategy to counteract the pro-oncogenic program controlled by RUNX2 in cancer cells.
Sections du résumé
BACKGROUND
BACKGROUND
RUNX2 is a Runt-related transcription factor required during embryogenesis for skeletal development and morphogenesis of other organs including thyroid and breast gland. Consistent evidence indicates that RUNX2 expression is aberrantly reactivated in cancer and supports tumor progression. The mechanisms leading to RUNX2 expression in cancer has only recently began to emerge. Previously, we showed that suppressing the activity of the epigenetic regulators HDACs significantly represses RUNX2 expression highlighting a role for these enzymes in RUNX2 reactivation in cancer. However, the molecular mechanisms by which HDACs control RUNX2 are still largely unexplored. Here, to fill this gap, we investigated the role of different HDACs in RUNX2 expression regulation in breast and thyroid cancer, tumors that majorly rely on RUNX2 for their development and progression.
METHODS
METHODS
Proliferation assays and evaluation of RUNX2 mRNA levels by qRT-PCR were used to evaluate the effect of several HDACi and specific siRNAs on a panel of cancer cell lines. Moreover, ChIP and co-IP assays were performed to elucidate the molecular mechanism underneath the RUNX2 transcriptional regulation. Finally, RNA-sequencing unveiled a new subset of genes whose transcription is regulated by the complex RUNX2-HDAC6.
RESULTS
RESULTS
In this study, we showed that Class I HDACs and in particular HDAC1 are required for RUNX2 efficient transcription in cancer. Furthermore, we found an additional and cell-specific function of HDAC6 in driving RUNX2 expression in thyroid cancer cells. In this model, HDAC6 likely stabilizes the assembly of the transcriptional complex, which includes HDAC1, on the RUNX2 P2 promoter potentiating its transcription. Since a functional interplay between RUNX2 and HDAC6 has been suggested, we used RNA-Seq profiling to consolidate this evidence in thyroid cancer and to extend the knowledge on this cooperation in a setting in which HDAC6 also controls RUNX2 expression.
CONCLUSIONS
CONCLUSIONS
Overall, our data provide new insights into the molecular mechanisms controlling RUNX2 in cancer and consolidate the rationale for the use of HDACi as potential pharmacological strategy to counteract the pro-oncogenic program controlled by RUNX2 in cancer cells.
Identifiants
pubmed: 31395086
doi: 10.1186/s13046-019-1350-5
pii: 10.1186/s13046-019-1350-5
pmc: PMC6686443
doi:
Substances chimiques
Core Binding Factor Alpha 1 Subunit
0
Histone Deacetylase Inhibitors
0
Multiprotein Complexes
0
RNA, Small Interfering
0
RUNX2 protein, human
0
HDAC6 protein, human
EC 3.5.1.98
Histone Deacetylase 6
EC 3.5.1.98
Histone Deacetylases
EC 3.5.1.98
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
346Subventions
Organisme : Associazione Italiana per la Ricerca sul Cancro
ID : IG 2018-21772
Références
Curr Biol. 2000 Jun 15;10(12):747-9
pubmed: 10873806
Mol Cell Biol Res Commun. 2000 Apr;3(4):218-23
pubmed: 10891395
Mech Dev. 2001 Aug;106(1-2):97-106
pubmed: 11472838
Endocrinology. 2001 Sep;142(9):4026-39
pubmed: 11517182
Nature. 2002 May 23;417(6887):455-8
pubmed: 12024216
Mol Cell Biol. 2002 Nov;22(22):7982-92
pubmed: 12391164
EMBO J. 2002 Dec 16;21(24):6820-31
pubmed: 12486003
EMBO J. 2003 Mar 3;22(5):1168-79
pubmed: 12606581
Trends Genet. 2003 May;19(5):286-93
pubmed: 12711221
J Biol Chem. 2003 Dec 5;278(49):48684-9
pubmed: 14506237
Int J Oncol. 2004 Apr;24(4):773-95
pubmed: 15010814
J Biol Chem. 2004 Oct 1;279(40):41998-2007
pubmed: 15292260
J Biol Chem. 2004 Nov 12;279(46):48246-54
pubmed: 15347674
Osteoarthritis Cartilage. 2004 Dec;12(12):963-73
pubmed: 15564063
Oncogene. 2005 Jul 21;24(31):4894-907
pubmed: 15870696
Mol Cell Biol. 2005 Oct;25(19):8581-91
pubmed: 16166639
J Biol Chem. 2005 Dec 9;280(49):40589-98
pubmed: 16195230
J Biol Chem. 2006 Jul 14;281(28):18973-82
pubmed: 16670084
Med Hypotheses. 2007;68(1):169-75
pubmed: 16901655
Nat Rev Drug Discov. 2006 Sep;5(9):769-84
pubmed: 16955068
Br J Cancer. 2007 Oct 22;97(8):1106-15
pubmed: 17876328
J Biol Chem. 2009 Aug 14;284(33):21881-90
pubmed: 19509297
Cell. 2009 Sep 4;138(5):1019-31
pubmed: 19698979
Lab Invest. 2010 Feb;90(2):222-33
pubmed: 19949374
Mol Endocrinol. 2010 Jun;24(6):1267-73
pubmed: 20375239
Cancer Res. 2010 Jul 1;70(13):5577-86
pubmed: 20530675
Lab Invest. 2012 Aug;92(8):1181-90
pubmed: 22641097
J Clin Endocrinol Metab. 2012 Oct;97(10):E2006-15
pubmed: 22821892
J Cell Physiol. 2013 Jun;228(6):1137-42
pubmed: 23169547
Mol Cell Endocrinol. 2013 Apr 30;369(1-2):150-60
pubmed: 23403054
Tumour Biol. 2013 Jun;34(3):1807-12
pubmed: 23471668
Cell Death Dis. 2013 Apr 25;4:e610
pubmed: 23618908
Curr Pharm Des. 2014;20(17):2843-8
pubmed: 23944365
J Transl Med. 2014 Sep 30;12:257
pubmed: 25266482
Cancer Res. 2015 May 1;75(9):1868-82
pubmed: 25769725
Cell Biochem Funct. 2015 Jul;33(5):257-65
pubmed: 26153649
Mol Cancer Res. 2016 Oct;14(10):994-1008
pubmed: 27358110
Oncogene. 2017 Feb 2;36(5):667-677
pubmed: 27375021
Cancer Sci. 2017 Jul;108(7):1293-1302
pubmed: 28417530
Nucleic Acids Res. 2017 Nov 2;45(19):11249-11267
pubmed: 28981843
Cancer Cell. 2017 Nov 13;32(5):590-607.e4
pubmed: 29136505
Histochem Cell Biol. 2018 Apr;149(4):313-323
pubmed: 29356961
BMC Cancer. 2018 Mar 20;18(1):309
pubmed: 29558908
Front Oncol. 2018 Mar 29;8:92
pubmed: 29651407
J Cell Biochem. 2018 Aug;119(8):6623-6632
pubmed: 29665050
World J Stem Cells. 2018 Jul 26;10(7):78-81
pubmed: 30079129
Neurochem Res. 2018 Nov;43(11):2047-2054
pubmed: 30203400
Onco Targets Ther. 2018 Sep 28;11:6305-6316
pubmed: 30319270
Curr Top Med Chem. 2018;18(28):2429-2447
pubmed: 30499393
Cancers (Basel). 2019 Mar 05;11(3):null
pubmed: 30841549
Cell Death Dis. 2019 May 16;10(6):378
pubmed: 31097689
Tumour Biol. 2019 May;41(5):1010428319851014
pubmed: 31109257
Cell. 1997 May 30;89(5):755-64
pubmed: 9182763
Nat Genet. 1997 Jul;16(3):307-10
pubmed: 9207800
Oncogene. 1998 Sep 24;17(12):1517-25
pubmed: 9794229