TNF‑α treatment increases DKK1 protein levels in primary osteoblasts via upregulation of DKK1 mRNA levels and downregulation of miR‑335‑5p.
3' Untranslated Regions
Animals
Cell Differentiation
Cell Lineage
/ drug effects
Cells, Cultured
Down-Regulation
/ drug effects
Female
Intercellular Signaling Peptides and Proteins
/ genetics
Male
Mice
Mice, Inbred C57BL
MicroRNAs
/ drug effects
NF-kappa B p50 Subunit
/ metabolism
Osteoblasts
/ cytology
RNA Processing, Post-Transcriptional
/ drug effects
RNA, Messenger
/ metabolism
Skull
/ metabolism
Tumor Necrosis Factor-alpha
/ pharmacology
Up-Regulation
tumor necrosis factor-α
Dickkopf WNT signaling pathway inhibitor 1
NF‑κB signaling
miR‑335‑5p
primary osteoblasts
MC3T3‑E1 cells
post‑transcriptional regulation
Journal
Molecular medicine reports
ISSN: 1791-3004
Titre abrégé: Mol Med Rep
Pays: Greece
ID NLM: 101475259
Informations de publication
Date de publication:
08 2020
08 2020
Historique:
received:
08
01
2020
accepted:
28
04
2020
pubmed:
30
5
2020
medline:
10
4
2021
entrez:
30
5
2020
Statut:
ppublish
Résumé
Elucidation of the underlying mechanisms governing osteogenic differentiation is of significant importance to the improvement of therapeutics for bone‑related inflammatory diseases. Tumor necrosis factor‑α (TNF‑α) is regarded as one of the major agents during osteogenic differentiation in an inflammatory environment. miR‑335‑5p post‑transcriptionally downregulates the Dickkopf WNT signaling pathway inhibitor 1 (DKK1) protein level by specifically binding to the DKK1 3'UTR and activating Wnt signaling. The role of miR‑335‑5p in TNF‑α‑induced post‑transcriptional regulation of DKK1 remains to be elucidated. In the present study, the mRNA and protein levels of DKK1 and the level of miR‑335‑5p were determined in MC3T3‑E1 cells and the primary calvarial osteoblasts treated with or without TNF‑α. The role of NF‑κB signaling in TNF‑α‑induced post‑transcriptional regulation of DKK1 was also evaluated. The present study determined that although TNF‑α treatment exhibited cell‑specific effects on DKK1 mRNA expression, the stimulation of TNF‑α time‑ and concentration‑dependently upregulated the protein levels of DKK1. In primary calvarial osteoblasts, the decreased miR‑335‑5p level induced by TNF‑α‑activated NF‑κB signaling served an important role in mediating the post‑transcriptional regulation of DKK1 by TNF‑α treatment. In MC3T3‑E1 cells, the post‑transcriptional regulation of DKK1 by TNF‑α treatment was more complicated and involved other molecular signaling pathways in addition to the NF‑κB signaling. In conclusion, TNF‑α treatment served an important role in the post‑transcriptional regulation of DKK1 expression, which requires further investigation. The results of the present study not only provided new insights into the regulatory effects of miR‑335‑5p on osteogenic differentiation in an inflammatory microenvironment, but may also promote the development of potential therapeutic strategies for the treatment of bone‑related inflammatory diseases.
Identifiants
pubmed: 32468044
doi: 10.3892/mmr.2020.11152
pmc: PMC7339467
doi:
Substances chimiques
3' Untranslated Regions
0
Dkk1 protein, mouse
0
Intercellular Signaling Peptides and Proteins
0
MicroRNAs
0
Mirn335 microRNA, mouse
0
NF-kappa B p50 Subunit
0
RNA, Messenger
0
Tumor Necrosis Factor-alpha
0
Nfkb1 protein, mouse
147257-52-1
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
1017-1025Références
Bone. 2015 Sep;78:87-93
pubmed: 25959413
Cell Physiol Biochem. 2012;30(4):974-86
pubmed: 23221481
Blood. 2000 Oct 1;96(7):2537-42
pubmed: 11001908
Dev Growth Differ. 2015 Apr;57(3):264-73
pubmed: 25846459
N Engl J Med. 2016 Jun 30;374(26):2563-74
pubmed: 27355535
Ann Rheum Dis. 2010 Dec;69(12):2152-9
pubmed: 20858621
J Biol Chem. 2012 Dec 7;287(50):42084-92
pubmed: 23060446
Methods. 2001 Dec;25(4):402-8
pubmed: 11846609
Cell Death Dis. 2014 Apr 17;5:e1187
pubmed: 24743742
Toxicol Pathol. 2017 Oct;45(7):911-924
pubmed: 29046115
FEBS Lett. 2016 Feb;590(3):396-407
pubmed: 26785690
Calcif Tissue Int. 2018 Oct;103(4):400-410
pubmed: 29804160
Sci Rep. 2019 Jan 18;9(1):208
pubmed: 30659232
Trends Immunol. 2013 Jun;34(6):282-9
pubmed: 23434408
J Bone Miner Res. 2013 Mar;28(3):559-73
pubmed: 23074166
J Bone Miner Res. 1992 Jun;7(6):683-92
pubmed: 1414487
Arthritis Rheum. 2013 Jun;65(6):1530-40
pubmed: 23529662
J Biol Chem. 2010 Mar 26;285(13):9792-802
pubmed: 20093358
Cell Prolif. 2017 Feb;50(1):
pubmed: 27726217
Curr Rheumatol Rep. 2017 Apr;19(4):17
pubmed: 28361330
Nat Rev Genet. 2012 Apr 18;13(5):358-69
pubmed: 22510765
Biomaterials. 2018 Sep;177:88-97
pubmed: 29886386
J Bone Miner Res. 2019 Jan;34(1):123-134
pubmed: 30151888
Cell Physiol Biochem. 2018;48(1):339-347
pubmed: 30016774
Diabetes. 2019 Oct;68(10):2016-2023
pubmed: 31391172
Arthritis Rheum. 2012 May;64(5):1540-50
pubmed: 22139865
Immunol Rev. 2010 Jan;233(1):301-12
pubmed: 20193007
Cell Prolif. 2011 Oct;44(5):420-7
pubmed: 21951285
Front Immunol. 2014 Feb 13;5:48
pubmed: 24592264
J Inflamm. 1995-1996;47(1-2):1-7
pubmed: 8913924
J Bone Miner Res. 2011 Aug;26(8):1953-63
pubmed: 21351149
J Bone Miner Metab. 2018 Nov;36(6):648-660
pubmed: 29234953
Nat Biotechnol. 2019 Jun;37(6):667-675
pubmed: 30962542
Bone. 2016 Mar;84:78-87
pubmed: 26723579
Nat Med. 2007 Feb;13(2):156-63
pubmed: 17237793
Nat Rev Drug Discov. 2012 Mar 01;11(3):234-50
pubmed: 22378270
Curr Osteoporos Rep. 2017 Jun;15(3):126-134
pubmed: 28477234
Microsc Res Tech. 2000 Aug 1;50(3):184-95
pubmed: 10891884
J Bone Miner Res. 2017 Mar;32(3):461-472
pubmed: 27676131
Cell Res. 2009 Jan;19(1):71-88
pubmed: 19002158