Study of the Effect of A366 (A G9a ‎Methyltransferase Inhibitor) on ‎Osteogenic Potential of Rat Bone ‎Marrow-Derived Mesenchymal ‎Stem Cells

Talkhabi, Mahmood; Khanban, Hedieh

doi:10.30473/eab.2020.49855.1756

Document Type : Article

Authors

Mahmood Talkhabi ¹
Hedieh Khanban ²

¹ Assistant Professor, in Cell and Developmental ‎Biology, Department of Animal Sciences and ‎Biotechnology, Faculty of Life Sciences and ‎Biotechnology, Shahid Beheshti University, Tehran, ‎Iran

² Ph.D. in Cell and Developmental Biology, Department ‎of Biology, Ayatollah Amoli Branch, Islamic Azad ‎University, Amol, Iran

https://doi.org/10.30473/eab.2020.49855.1756

Abstract

Mesenchymal stem cells (MSCs) are multipotent stem cells that have potential to differentiate into connective tissue lineages. They also have special properties such as immunomodulation and secretion of growth factors. Histone methyltransferase G9a is one of the factors that control stem cells behaviors and features. Hence, it is important to study the role of G9a in MSCs biological behaviors and potentials. MSCs were isolated from rat bone marrow and cultured in vitro. Then, the expression of positive markers (CD90 and CD 73) and negative markers (CD45) were analyzed using flowcytometry. BM-MSCs were treated with different doses of A366, and then were differentiated to osteocyte. Osteogenesis were analyzed using oil red staining and real time-PCR. BM-MSCs were expanded as adherent cells with fibroblastic morphology. More than 85% of cells were positive for CD73 and CD90, and negative for CD45. The treatment of BM-MSCs with A366 reduced osteogenesis as evaluated by oil red staining and gene expression analysis. A366, as an epigenetic regulator decreases the osteogenic potential of BM-MSCs. Use of these regulators for cancer therapy, might influence tissue regeneration and homeostasis.

Keywords

20.1001.1.23222387.1399.8.4.3.9

References

Afanasyev, B.V.; Elstner, E.E.; Zander, A.R.; Friedenstein, A.J. (2009). Founder of the ‎mesenchymal stem cell concept. Cell Ther Transplant; 1(3): 35-38.‎

Baghaban Eslaminejad, M.; Talkhabi, M.; Zeynali, B. (2008). Effect of Lithium chloride on ‎proliferation and bone differentiation of rat marrow-derived mesenchymal stem cells in culture. ‎Iranian journal of basic medical sciences; 11(3): 143-151.‎

Caplan, A. (2009). Why are MSCs therapeutic? New data: new insight. The Journal of ‎Pathology: A Journal of the Pathological Society of Great Britain and Ireland; 217(2): ‎‎318-324.‎

Djouad, F.; et al. (2009). Mesenchymal stem cells: innovative therapeutic tools for rheumatic ‎diseases. Nature Reviews Rheumatology; 5(7): 392.‎

Dominici, M.; et al. (2006). Minimal criteria for defining multipotent mesenchymal stromal ‎cells. The International Society for Cellular Therapy position statement. Cytotherapy; ‎‎8(4): 315-317.‎

Eisenberg, C.A.; Eisenberg, L.M. (2019). G9a and G9a-Like Histone Methyltransferases and ‎Their Effect on Cell Phenotype, Embryonic Development, and Human Disease, in The DNA, ‎RNA, and Histone Methylomes. Springer. p. 399-433.‎

Fabrizio, P.; Garvis, S.; Palladino, F. (2019). Histone methylation and memory of ‎environmental stress. Cells; 8(4): 339.‎

Freitag, J.; et al. (2016). Mesenchymal stem cell therapy in the treatment of osteoarthritis: ‎reparative pathways, safety and efficacy-a review. BMC musculoskeletal disorders; ‎‎17(1): 230.‎

Gazit, Z.; et al. (2019). Mesenchymal stem cells, in Principles of regenerative medicine. ‎Elsevier. p. 205-218.‎

Hemming, S.; et al. (2014). EZH2 and KDM6A act as an epigenetic switch to regulate ‎mesenchymal stem cell lineage specification. Stem cells; 32(3): 802-815.‎

Higashihori, N.; et al. (2017). Methyltransferase G9A Regulates Osteogenesis via Twist Gene ‎Repression. Journal of dental research; 96(10): 1136-1144.‎

Husmann, D.: Gozani, O. (2019). Histone lysine methyltransferases in biology and disease. ‎Nature structural & molecular biology; 26(10): 880-889.‎

Khanban, H.; Fattahi, E.; Talkhabi, M. (2019). In vivo administration of G9a inhibitor A366 ‎decreases osteogenic potential of bone marrow-derived mesenchymal stem cells. EXCLI ‎journal; 18: 300.‎

Liu, N.; et al. (2015). Recognition of H3K9 methylation by GLP is required for efficient ‎establishment of H3K9 methylation, rapid target gene repression, and mouse viability. Genes & ‎development; 29(4): 379-393.‎

Nicetto, D.; Zaret, K.S. (2019). Role of H3K9me3 heterochromatin in cell identity ‎establishment and maintenance. Current opinion in genetics & development; 55: 1-10.‎

Purcell, D.J.; et al. (2012). Recruitment of coregulator G9a by Runx2 for selective enhancement ‎or suppression of transcription. Journal of cellular biochemistry; 113(7): 2406-2414.‎

Teven, C.M.; et al. (2011). Epigenetic regulation of mesenchymal stem cells: a focus on ‎osteogenic and adipogenic differentiation. Stem cells international.‎

‏Yin, B.; et al. (2019). Epigenetic Control of Mesenchymal Stem Cell Fate Decision via Histone ‎Methyltransferase Ash1l. ‏Stem Cells; 37(1): 115-127.‎

Experimental animal Biology

Study of the Effect of A366 (A G9a ‎Methyltransferase Inhibitor) on ‎Osteogenic Potential of Rat Bone ‎Marrow-Derived Mesenchymal ‎Stem Cells

References

References

Volume 8, Issue 4 - Serial Number 4
May 2020
Pages 33-41

Study of the Effect of A366 (A G9a ‎Methyltransferase Inhibitor) on ‎Osteogenic Potential of Rat Bone ‎Marrow-Derived Mesenchymal ‎Stem Cells

References

References

Volume 8, Issue 4 - Serial Number 4May 2020Pages 33-41

Volume 8, Issue 4 - Serial Number 4
May 2020
Pages 33-41