192 Identification of Fos and FosB as Transcriptional Regulators of Bovine Satellite Cell Differentiation

Transcription factors (TFs) are key regulators of gene expression during cell differentiation. Four TFs including Myf5, MyoD, MyoG and Myf6 have been identified as key myogenic regulatory factors (MYFs) that regulate gene transcription during myogenesis. Satellite cells (SCs) are the myogenic precursor cells in adult skeletal muscle. The objective of this study was to identify additional TFs that control the differentiation of bovine satellite cells. Bovine satellite cells (bSCs) were isolated from 4 crossbred steers and were initially cultured in growth medium for 12 days to expand and then in differentiation medium for 48 hours to differentiate. Chromatin immunoprecipitation followed by sequencing (ChIP-seq) was performed to identify chromatin regions marked with acetylation of histone H3 on lysine 27 (H3K27ac). This ChIP-seq analysis revealed 3,348 and 38,800 H3K27ac-associated chromatin regions in bSCs before and after differentiation, respectively. A motif enrichment analysis of the H3K27ac-marked chromatin regions from the differentiated bSCs indicated the enrichment of binding sites for the 4 MYFs and many other TFs including Fos and FosB. RNA-sequencing revealed the upregulation of Fos and FosB mRNAs in bSCs from growth to differentiation. To verify the roles of Fos and FosB in bSC differentiation, their expressions in bSCs were reduced by siRNA-induced knockdown. Based on qRT-PCR analyses, expressions of MYH2, MYH3, MYOG, and CKM mRNAs, which were selected as markers of muscle cell differentiation, were increased (P < 0.05) in bSCs from growth to differentiation, but the increases in at least three of them were reversed (P < 0.05) by Fos or FosB knockdown. Taken together, these results establish Fos and FosB as transcriptional regulators of bovine satellite cell differentiation.

Identification of the Myogenetic Oligodeoxynucleotides (myoDNs) That Promote Differentiation of Skeletal Muscle Myoblasts by Targeting Nucleolin

Herein we report that the 18-base telomeric oligodeoxynucleotides (ODNs) designed from the Lactobacillus rhamnosus GG genome promote differentiation of skeletal muscle myoblasts which are myogenic precursor cells. We termed these myogenetic ODNs (myoDNs). The activity of one of the myoDNs, iSN04, was independent of Toll-like receptors, but dependent on its conformational state. Molecular simulation and iSN04 mutants revealed stacking of the 13–15th guanines as a core structure for iSN04. The alkaloid berberine bound to the guanine stack and enhanced iSN04 activity, probably by stabilizing and optimizing iSN04 conformation. We further identified nucleolin as an iSN04-binding protein. Results showed that iSN04 antagonizes nucleolin, increases the levels of p53 protein translationally suppressed by nucleolin, and eventually induces myotube formation by modulating the expression of genes involved in myogenic differentiation and cell cycle arrest. This study shows that bacterial-derived myoDNs serve as aptamers and are potential nucleic acid drugs directly targeting myoblasts.

Identification of the myogenetic oligodeoxynucleotides (myoDNs) that promote differentiation of skeletal muscle myoblasts by targeting nucleolin

Herein we report that the 18-base telomeric oligodeoxynucleotides (ODNs) designed from the Lactobacillus rhamnosus GG genome promote differentiation of skeletal muscle myoblasts which are myogenic precursor cells. We termed these myogenetic ODNs (myoDNs). The activity of one of the myoDNs, iSN04, was independent of Toll-like receptors, but dependent on its conformational state. Molecular simulation and iSN04 mutants revealed stacking of the 13-15th guanines as a core structure for iSN04. The alkaloid berberine bound to the guanine stack and enhanced iSN04 activity, probably by stabilizing and optimizing iSN04 conformation. We further identified nucleolin as an iSN04-binding protein. Results showed that iSN04 antagonizes nucleolin, increases the levels of p53 protein translationally suppressed by nucleolin, and eventually induces myotube formation by modulating the expression of genes involved in myogenic differentiation and cell cycle arrest. This study shows that bacterial-derived myoDNs serve as aptamers and are potential nucleic acid drugs directly targeting myoblasts.

Differentiation of Human Embryonic Stem Cells into Engrafting Myogenic Precursor Cells

Degenerative muscle diseases affect muscle tissue integrity and function. Human embryonic stem cells (hESC) are an attractive source of cells to use in regenerative therapies due to their unlimited capacity to divide and ability to specialize into a wide variety of cell types. A practical way to derive therapeutic myogenic stem cells from hESC is lacking. In this study, we demonstrate the development of two serum-free conditions to direct the differentiation of hESC towards a myogenic precursor state. Using TGFß and PI3Kinase inhibitors in combination with bFGF we showed that one week of differentiation is sufficient for hESC to specialize into PAX3+/PAX7+ myogenic precursor cells. These cells also possess the capacity to further differentiate in vitro into more specialized myogenic cells that express MYOD, Myogenin, Desmin and MYHC, and showed engraftment in vivo upon transplantation in immunodeficient mice. Ex vivo myomechanical studies of dystrophic mouse hindlimb muscle showed functional improvement one month post-transplantation. In summary, this study describes a promising system to derive engrafting muscle precursor cells solely using chemical substances in serum-free conditions and without genetic manipulation.

Cellular function of satellite cells does not play a role in muscle weakness of adult Ts1Cje mice

Down syndrome (DS) is a genetic condition resulting from triplication of human chromosome (HSA)21. Besides intellectual disability, DS is frequently associated with hypotonia. Satellite cells are the resident cells that provides robust and remarkable regenerative capacity to the skeletal muscles, and its population size has been reported to be disease-associated. However, little is known about the population size of satellite cells in DS and the association of its intrinsic cellular functionality and hypotonia seen in DS. Here, we studied the Ts1Cje mouse, a DS murine model displays the muscle weakness characteristic. Satellite cell populations were immunostained with Pax7 and myonuclei numbers in the Ts1Cje extensor digitorum longus muscle were assessed. Their cellular function was further determined via in vitro assay in high-serum conditioned medium. Subsequently, the in vitro self-renewal, proliferative, and differentiation activities of these myogenic precursor cells were assessed after 24, 48, and 72h using Pax7, MyoD, and Ki67 immunomarkers. Our results showed that the population and functionality of Ts1Cje satellite cell did not differ significantly when compared to the wildtype cells isolated from disomic littermates. In conclusion, our findings indicate that intrinsic cellular functionality of the satellite cells, do not contribute to muscle weakness in Ts1Cje mouse.