Relative roles of TGF‐β1 and Wnt in the systemic regulation and aging of satellite cell responses

Muscle stem (satellite) cells are relatively resistant to cell‐autonomous aging. Instead, their endogenous signaling profile and regenerative capacity is strongly influenced by the aged P‐Smad3, differentiated niche, and by the aged circulation. With respect to muscle fibers, we previously established that a shift from active Notch to excessive transforming growth factor‐beta (TGF‐β) induces CDK inhibitors in satellite cells, thereby interfering with productive myogenic responses. In contrast, the systemic inhibitor of muscle repair, elevated in old sera, was suggested to be Wnt. Here, we examined the age‐dependent myogenic activity of sera TGF‐β1, and its potential cross‐talk with systemic Wnt. We found that sera TGF‐β1 becomes elevated within aged humans and mice, while systemic Wnt remained undetectable in these species. Wnt also failed to inhibit satellite cell myogenicity, while TGF‐β1 suppressed regenerative potential in a biphasic fashion. Intriguingly, young levels of TGF‐β1 were inhibitory and young sera suppressed myogenesis if TGF‐β1 was activated. Our data suggest that platelet‐derived sera TGF‐β1 levels, or endocrine TGF‐β1 levels, do not explain the age‐dependent inhibition of muscle regeneration by this cytokine. In vivo, TGF‐β neutralizing antibody, or a soluble decoy, failed to reduce systemic TGF‐β1 and rescue myogenesis in old mice. However, muscle regeneration was improved by the systemic delivery of a TGF‐β receptor kinase inhibitor, which attenuated TGF‐β signaling in skeletal muscle. Summarily, these findings argue against the endocrine path of a TGF‐β1‐dependent block on muscle regeneration, identify physiological modalities of age‐imposed changes in TGF‐β1, and introduce new therapeutic strategies for the broad restoration of aged organ repair.     

Age-associated decrease in muscle precursor cell differentiation

Muscle precursor cells (MPCs) are required for the regrowth, regeneration, and/or hypertrophy of skeletal muscle, which are deficient in sarcopenia. In the present investigation, we have addressed the issue of age-associated changes in MPC differentiation. MPCs, including satellite cells, were isolated from both young and old rat skeletal muscle with a high degree of myogenic purity (>90% MyoD and desmin positive). MPCs isolated from skeletal muscle of 32-mo-old rats exhibited decreased differentiation into myotubes and demonstrated decreased myosin heavy chain (MHC) and muscle creatine kinase (CK-M) expression compared with MPCs isolated from 3-mo-old rats. p27^Kip1 is a cyclin-dependent kinase inhibitor that has been shown to enhance muscle differentiation in culture. Herein we describe our finding that p27^Kip1 protein was lower in differentiating MPCs from skeletal muscle of 32-mo-old rats than in 3-mo-old rat skeletal muscle. Although MHC and CK-M expression were 50% lower in differentiating MPCs isolated from 32-mo-old rats, MyoD protein content was not different and myogenin protein concentration was twofold higher. These data suggest that there are inherent differences in cell signaling during the transition from cell cycle arrest to the formation of myotubes in MPCs isolated from sarcopenic muscle. Furthermore, there is an age-associated decrease in muscle-specific protein expression in differentiating MPCs despite normal MyoD and elevated myogenin levels. satellite cells; skeletal muscle; p27^Kip1; myogenic regulatory factors     

Interleukin‐6 downregulation with mesenchymal stem cell differentiation results in loss of immunoprivilege

Allogeneic mesenchymal stem cell (MSC) transplantation improves cardiac function, but cellular differentiation results in loss of immunoprivilege and rejection. To explore the mechanism involved in this immune rejection, we investigated the influence of interleukin‐6 (IL‐6), a factor secreted by MSCs, on immune privilege after myogenic, endothelial and smooth muscle cell differentiation induced by 5‐azacytidine, VEGF, and transforming growth factor‐β (TGF‐β), respectively. Both RT‐PCR and ELISA showed that myogenic differentiation of MSCs was associated with significant downregulation of IL‐6 expression (P < 0.01), which was also observed following endothelial (P < 0.01) and smooth muscle cell differentiation (P < 0.05), indicating that IL‐6 downregulation was dependent on differentiation but not cell phenotype. Flow cytometry demonstrated that IL‐6 downregulation as a result of myogenic differentiation was associated with increased leucocyte‐mediated cell death in an allogeneic leucocyte co‐culture study (P < 0.01). The allogeneic reactivity associated with IL‐6 downregulation was also observed following MSC differentiation to endothelial and smooth muscle cells (P < 0.01), demonstrating that leucocyte‐mediated cytotoxicity was also dependent on differentiation but not cell phenotype. Restoration of IL‐6 partially rescued the differentiated cells from leucocyte‐mediated cell death. These findings suggest that rejection of allogeneic MSCs after implantation may be because of a reduction in cellular IL‐6 levels, and restoration of IL‐6 may be a new target to retain MSC immunoprivilege.     

Conditional TGF‐β1 treatment increases stem cell‐like cell population in myoblasts

The limitation in successfully acquiring large populations of stem cell has impeded their application. A new method based on the dedifferentiation of adult somatic cells to generate induced multipotent stem cells would allow us to obtain a large amount of autologous stem cells for regenerative medicine. The current work was proposed to induce a sub‐population of cells with characteristics of muscle stem cells from myoblasts through conditional treatment of transforming growth factor (TGF)‐β₁. Our results show that a lower concentration of TGF‐β₁ is able to promote C2C12 myoblasts to express stem cell markers as well as to repress myogenic proteins, which involves a mechanism of dedifferentiation. Moreover, TGF‐β₁ treatment promoted the proliferation‐arrested C2C12 myoblasts to re‐enter the S‐phase. We also investigated the multi‐differentiation potentials of the dedifferentiated cells. TGF‐β₁ pre‐treated C2C12 myoblasts were implanted into mice to repair dystrophic skeletal muscle or injured bone. In addition to the C2C12 myoblasts, similar effects of TGF‐β₁ were also observed in the primary myoblasts of mice. Our results suggest that TGF‐β₁ is effective as a molecular trigger for the dedifferentiation of skeletal muscle myoblasts and could be used to generate a large pool of progenitor cells that collectively behave as multipotent stem cell‐like cells for regenerative medicine applications.     

Preparation of Primary Myogenic Precursor Cell/Myoblast Cultures from Basal Vertebrate Lineages

Due to the inherent difficulty and time involved with studying the myogenic program in vivo, primary culture systems derived from the resident adult stem cells of skeletal muscle, the myogenic precursor cells (MPCs), have proven indispensible to our understanding of mammalian skeletal muscle development and growth. Particularly among the basal taxa of Vertebrata, however, data are limited describing the molecular mechanisms controlling the self-renewal, proliferation, and differentiation of MPCs. Of particular interest are potential mechanisms that underlie the ability of basal vertebrates to undergo considerable postlarval skeletal myofiber hyperplasia (i.e. teleost fish) and full regeneration following appendage loss (i.e. urodele amphibians). Additionally, the use of cultured myoblasts could aid in the understanding of regeneration and the recapitulation of the myogenic program and the differences between them. To this end, we describe in detail a robust and efficient protocol (and variations therein) for isolating and maintaining MPCs and their progeny, myoblasts and immature myotubes, in cell culture as a platform for understanding the evolution of the myogenic program, beginning with the more basal vertebrates. Capitalizing on the model organism status of the zebrafish (Danio rerio), we report on the application of this protocol to small fishes of the cyprinid clade Danioninae. In tandem, this protocol can be utilized to realize a broader comparative approach by isolating MPCs from the Mexican axolotl (Ambystomamexicanum) and even laboratory rodents. This protocol is now widely used in studying myogenesis in several fish species, including rainbow trout, salmon, and sea bream^1-4.     

Senescence and odontoblastic differentiation of dental pulp cells

Cellular senescence has been suggested to be involved in physiological changes of cytokine production. Previous studies showed that the concentration of tumor necrosis factor-α (TNF-α) is higher in the blood of aged people compared with that of young people. So far, the precise effects of TNF-α on the odontoblastic differentiation of pulp cells have been controversial. Therefore, we aimed to clarify how this cytokine affected pulp cells during aging. Human dental pulp cells (HDPCs) were cultured until reaching the plateau of their growth, and the cells were isolated at actively (young HDPCs; yHDPCs) or inactively (senescent HDPCs; sHDPCs) proliferating stages. sHDPCs expressed senescence-related molecules while yHDPCs did not. When these HDPCs were cultured in an odontoblast-inductive medium, both young and senescent cells showed mineralization, but mineralization in sHDPCs was lower compared with yHDPCs. However, the administration of TNF-α to this culture medium altered these responses: yHDPCs showed downregulated mineralization, while sHDPCs exhibited significantly increased mineralization. Furthermore, the expression of tumor necrosis factor receptor 1 (TNFR1), a receptor of TNF-α, was significantly upregulated in sHDPCs compared with yHDPCs. Downregulation of TNFR1 expression led to decreased mineralization of TNF-α-treated sHDPCs, whereas restored the reduction in TNF-α-treated yHDPCs. These results suggested that sHDPCs preserved the odontoblastic differentiation capacity and TNF-α promoted odontoblastic differentiation of HDPCs with the progress of their population doublings through increased expression of TNFR1. Thus, TNF-α might exert a different effect on the odontoblastic differentiation of HDPCs depending on their proliferating activity. In addition, the calcification of pulp chamber with age may be related with increased reactivity of pulp cells to TNF-α.     

The Tocotrienol-Rich Fraction Is Superior to Tocopherol in Promoting Myogenic Differentiation in the Prevention of Replicative Senescence of Myoblasts

Aging results in a loss of muscle mass and strength. Myoblasts play an important role in maintaining muscle mass through regenerative processes, which are impaired during aging. Vitamin E potentially ameliorates age-related phenotypes. Hence, this study aimed to determine the effects of the tocotrienol-rich fraction (TRF) and α-tocopherol (ATF) in protecting myoblasts from replicative senescence and promoting myogenic differentiation. Primary human myoblasts were cultured into young and senescent stages and were then treated with TRF or ATF for 24 h, followed by an analysis of cell proliferation, senescence biomarkers, cellular morphology and differentiation. Our data showed that replicative senescence impaired the normal regenerative processes of myoblasts, resulting in changes in cellular morphology, cell proliferation, senescence-associated β-galactosidase (SA-β-gal) expression, myogenic differentiation and myogenic regulatory factors (MRFs) expression. Treatment with both TRF and ATF was beneficial to senescent myoblasts in reclaiming the morphology of young cells, improved cell viability and decreased SA-β-gal expression. However, only TRF treatment increased BrdU incorporation in senescent myoblasts, as well as promoted myogenic differentiation through the modulation of MRFs at the mRNA and protein levels. MYOD1 and MYOG gene expression and myogenin protein expression were modulated in the early phases of myogenic differentiation. In conclusion, the tocotrienol-rich fraction is superior to α-tocopherol in ameliorating replicative senescence-related aberration and promoting differentiation via modulation of MRFs expression, indicating vitamin E potential in modulating replicative senescence of myoblasts.     

TGF‐beta signalling in the adult neurogenic niche promotes stem cell quiescence as well as generation of new neurons

Members of the transforming growth factor (TGF)‐β family govern a wide range of mechanisms in brain development and in the adult, in particular neuronal/glial differentiation and survival, but also cell cycle regulation and neural stem cell maintenance. This clearly created some discrepancies in the field with some studies favouring neuronal differentiation/survival of progenitors and others favouring cell cycle exit and neural stem cell quiescence/maintenance. Here, we provide a unifying hypothesis claiming that through its regulation of neural progenitor cell (NPC) proliferation, TGF‐β signalling might be responsible for (i) maintaining stem cells in a quiescent stage, and (ii) promoting survival of newly generated neurons and their functional differentiation. Therefore, we performed a detailed histological analysis of TGF‐β1 signalling in the hippocampal neural stem cell niche of a transgenic mouse that was previously generated to express TGF‐β1 under a tetracycline regulatable Ca‐Calmodulin kinase promoter. We also analysed NPC proliferation, quiescence, neuronal survival and differentiation in relation to elevated levels of TGF‐β1 in vitro and in vivo conditions. Finally, we performed a gene expression profiling to identify the targets of TGF‐β1 signalling in adult NPCs. The results demonstrate that TGF‐β1 promotes stem cell quiescence on one side, but also neuronal survival on the other side. Thus, considering the elevated levels of TGF‐β1 in ageing and neurodegenerative diseases, TGF‐β1 signalling presents a molecular target for future interventions in such conditions.     

Enhanced alleviation of aGVHD by TGF‐β1‐modified mesenchymal stem cells in mice through shifting MΦ into M2 phenotype and promoting the differentiation of Treg cells

Allogeneic haematopoietic stem cell transplantation (allo‐HSCT) is the only curative method in treating haematologic malignant diseases. Graft‐versus‐host disease (GVHD) is a common complication post–allo‐HSCT, which can be life‐threatening. Mesenchymal stem cells (MSCs) as an adult stem cell with immunoregulatory function have demonstrated efficacy in steroid resistant acute GVHD (aGVHD). However, the outcome of aGVHD treated with MSCs in clinical trials varied and its underlying mechanism is still unclear. TGF‐β1 is a potent cytokine, which plays a key role in immunoregulation. In the present study, we firstly transduced the lentivirus vector containing TGF‐β1 gene with mouse bone marrow‐derived MSCs. Then, we investigated the immunosuppressive effect of TGF‐β1 gene‐modified MSCs on lymphocytes in vitro and its preventive and therapeutical effects on murine aGVHD model in vivo. Murine MSC was successfully isolated and identified. TGF‐β1 was efficiently transduced into mouse MSCs, and high level TGF‐β1 was detected. MSC‐TGF‐β1 shared the same morphology and immunotypic features of normal MSC. In vitro, MSC‐TGF‐β1 showed enhanced immunosuppressive function on lymphocyte proliferation. In vivo, MSC‐TGF‐β1 showed enhanced amelioration on the severity of aGVHD both in prophylactic and therapeutic murine models. Finally, the macrophages (MØs) derived from MSC‐TGF‐β1–treated mice showed a remarkably increasing of anti‐inflammatory M2‐like phenotype. Furthermore, the differentiation of CD4+ CD25+ Foxp3+ Treg cells was significantly increased in MSC‐TGF‐β1–treated group. Taken together, we proved that MSC‐TGF‐β1 showed enhanced alleviation of aGVHD severity in mice by skewing macrophages into a M2 like phenotype or increasing the proportion of Treg cells, which opens a new frontier in the treatment of aGVHD.     

IGF-I and vitamin C promote myogenic differentiation of mouse and human skeletal muscle cells at low temperatures

In a previous study investigating the effects of low temperature on skeletal muscle differentiation, we demonstrated that C2C12 mouse myoblasts cultured at 30 °C do not express myogenin, a myogenic regulatory factor (MRF), or fuse into multinucleated myotubes. At this low temperature, the myoblasts continuously express Id3, a negative regulator of MRFs, and do not upregulate muscle-specific microRNAs. In this study, we examined if insulin-like growth factor-I (IGF-I) and a stable form of vitamin C (L-ascorbic acid phosphate) could alleviate the low temperature-induced inhibition of myogenic differentiation in C2C12 cells. Although the addition of either IGF-I or vitamin C alone could promote myogenin expression in C2C12 cells at 30 °C, elongated multinucleated myotubes were not formed unless both IGF-I and vitamin C were continuously administered. In human skeletal muscle cells, low temperature-induced blockage of myogenic differentiation was also ameliorated by exogenous IGF-I and vitamin C. In addition, we demonstrated that satellite cells of IGF-I overexpressing transgenic mice in single-fiber culture expressed myogenin at a higher level than those of wild-type mice at 30 °C. This study suggests that body temperature plays an important role in myogenic differentiation of endotherms, but the sensitivity to low temperature could be buffered by certain factors in vivo, such as IGF-I and vitamin C.     

Soluble factors from ASCs effectively direct control of chondrogenic fate

Background and objectives: Adipose tissue‐derived stem cells (ASCs) have great potential for regenerative medicine. For molecular understanding of specific functional molecules present in ASCs, we analysed 756 proteins including specific chondrogenic functional factors, using high‐throughput nano reverse‐phase liquid chromatography–electrospray ionization–tandem mass spectrometry. Materials, methods and results: Of these proteins, 33 were identified as chondrogenic factors or proteins including type 2 collagen, biglycan, insulin‐like growth factor‐binding protein and transforming growth factor‐beta 1 (TGF‐β1). ASCs are a possible cell source for cartilage regeneration as they are able to secrete a number of functional cytokines including chondrogenesis‐inducing molecules such as TGF‐β1 and bone morphogenetic protein 4 (BMP4). The chondrogenic phenotype of cultured ASCs was effectively induced by ASC‐culture media (CM) containing BMP4 and TGF‐β1, and maintained after pre‐treatment for 14 days in vitro and subcutaneous implantation in vivo. Chondrogenic differentiation efficiency of cultured ASCs and cultured mouse skin‐derived progenitor cells (SPCs) depended absolutely on ASC CM‐fold concentration. Cell density was also a very important factor for chondrogenic behaviour development during differentiation of ASCs and SPCs. Conclusion: ASC CM‐derived TGF‐β1‐induced chondrogenic differentiation of ASCs resulted in significant reduction in chondrogenic activity after inhibition of the p38 pathway, revealing involvement of this MAPK pathway in TGF‐β1 signalling. On the other hand, TGF‐β1 signalling also led to SMAD activation that could directly increase chondrogenic activity of ASCs.     

Activation of DNA demethylases attenuates aging‐associated arterial stiffening and hypertension

DNA methylation increases with age. The objective of this study was to investigate whether compound H, a potential activator of DNA demethylases, attenuates aging‐related arterial stiffness and hypertension. Aged mice (24–27 months) and adult mice (12 months) were used. Pulse wave velocity (PWV), a direct measure of arterial stiffness, and blood pressure (BP) were increased significantly in aged mice. Notably, daily treatments with compound H (15 mg/kg, IP) for 2 weeks significantly attenuated the aging‐related increases in PWV and BP. Compound H abolished aging‐associated downregulation of secreted Klotho (SKL) levels in both kidneys and serum likely by enhancing DNA demethylase activity and decreasing DNA methylation. Aging‐related arterial stiffness was associated with accumulation of stiffer collagen and degradation of compliant elastin which are accompanied by increased expression of MMP2, MMP9, TGF‐β1, and TGF‐β3. These changes were effectively attenuated by compound H, suggesting rejuvenation of aged arteries. Compound H also rescued downregulation of Sirt1 deacetylase, AMPKα, and eNOS activities in aortas of aged mice. In cultured smooth muscle cells (SMCc) Klotho‐deficient serum upregulated expression of MMPs and TGFβ which, however, was not affected by compound H. In conclusion, compound H attenuates aging‐associated arterial stiffness and hypertension by activation of DNA demethylase which increases renal SKL expression and consequently circulating SKL levels leading to activation of the Sirt1‐AMPK‐eNOS pathway in aortas of aged mice.     

Quercetin handles cellular oxidant/antioxidant systems and mitigates immunosenescence hallmarks in human PBMCs: An in vitro study

Immunosenescence, oxidative stress, and low vaccine efficacy are important symptoms of aging. The goal of our study was to test if quercetin had antiaging and stimulating effects on peripheral blood mononuclear cell (PBMC) immune cells in vitro in the presence of concanavalin a, PBMCs were isolated from healthy elderly and young people and cultured in a complete Roswell Park Memorial Institute 1640 medium supplemented with quercetin. Cell proliferation was assessed using the 3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H-tetrazolium bromide colorimetric assay after a 48-h incubation period. Spectrophotometric assays were used to assess oxidative biomarkers (proteins carbonyl [PC], malondialdehydes [MDA], and reduced glutathione [GSH]). The enzyme-linked immunosorbent assay method was used to determine the amount of interleukin (IL)-2 released. A Griess reagent was used to investigate inducible nitrite oxide synthase (iNOS) activity. When compared to young control cells, aged PBMCs had lower proliferation potency, lower IL-2 and NO release, and higher MDA and PC levels. Importantly, quercetin-treated aged PBMCs have a high proliferative response comparable to young cells, restored iNOS activity, and increased levels of GSH antioxidant defences. In comparison to untreated aged PBMCs, treated PBMCs have lower lipo-oxidative damage but higher PC levels. Quercetin may be used as a promising dietary vaccinal adjuvant in the elderly, it has significant effects in reducing immunosenescence hallmarks, as well as mitigating the lipo-oxidative stress in PBMCs cells.     

Replicative aging down-regulates the myogenic regulatory factors in human myoblasts

Background information. Aging of human skeletal muscle results in a decline in muscle mass and force, and excessive turnover of muscle fibres, such as in muscular dystrophies, further increases this decline. Although it has been shown in rodents, by cross‐age transplantation of whole muscles, that the environment plays an important role in this process, the implication of proliferating aging of the muscle progenitors has been poorly investigated, particularly in humans, since the regulation of cell proliferation differs between rodents and humans. The myogenic differentiation of human myoblasts is regulated by the muscle‐specific regulatory factors. Cross‐talk between the muscle‐specific regulatory factors and the cell cycle regulators is essential for differentiation. The aim of the present study was to determine the effects of replicative senescence on the myogenic programme of human myoblasts. Results. We showed that senescent myoblasts, which could not re‐enter the cell cycle, are still able to differentiate and form multinucleated myotubes. However, these myotubes are significantly smaller. The expression of muscle‐specific regulatory factors and cell cycle regulators was analysed in proliferating myoblasts and compared with senescent cells. We have observed a delay and a decrease in the muscle‐specific regulatory factors and the cyclin‐dependent kinase inhibitor p57 during the early step of differentiation in senescent myoblasts, as well as an increase in the fibroblastic markers. Conclusions. Our results demonstrate that replicative senescence alters the expression of the factors triggering muscle differentiation in human myoblasts and could play a role in the regenerative defects observed in muscular diseases and during normal skeletal‐muscle aging.     

SIRT1 reduction causes renal and retinal injury in diabetes through endothelin 1 and transforming growth factor β1

In diabetes, hyperglycaemia causes up‐regulation of endothelin 1 (ET‐1) and transforming growth factor beta 1 (TGF‐β1). Previously we showed glucose reduces sirtuin1 (SIRT1), a class III histone deacetylase. Here, we investigated the regulatory role of SIRT1 on ET‐1 and TGF‐β1 expression. Human microvascular endothelial cells were examined following incubation with 25 mmol/l glucose (HG) and 5 mmol/l glucose (NG) with or without SIRT1 or histone acetylase p300 overexpression or knockdown. mRNA expressions of ET‐1, TGF‐β1, SIRT1, p300 and collagen 1α(I) were examined. SIRT1 enzyme activity, ET‐1 and TGF‐β1 protein levels were measured. Histone acetylation and endothelial permeability were further investigated. Similar analyses were performed in the kidneys and retinas of SIRT1 overexpressing transgenic mice with or without streptozotocin induced diabetes. Renal functions were evaluated. In the endothelial cells (ECs), HG caused increased permeability and escalated production of ET‐1, TGF‐β1, collagen Iα(I). These cells also showed increased p300 expression, histone acetylation and reduced SIRT1 levels. These changes were rectified in the ECs following p300 silencing or by SIRT1 overexpression, whereas SIRT1 knockdown or p300 overexpression in NG mimicked the effects of HG. High ET‐1 and TGF‐β1 levels were seen in the kidneys and retinas of diabetic mice along with micro‐albuminuria and increased fibronectin protein (marker of glucose‐induced cell injury) levels. Interestingly, these detrimental changes were blunted in SIRT1 overexpressing transgenic mice with diabetes. This study showed a novel SIRT1 mediated protection against renal and retinal injury in diabetes, regulated through p300, ET‐1 and TGF‐β1.     

Growth and differentiation of permanent and secondary mouse myogenic cell lines on microcarriers

Myogenesis involves the determination of progenitor cells to myoblasts, their fusion to yield multinuclear myotubes, and the maturation of myotubes to muscle fibres. This development is reflected in a time pattern of gene expression, e.g. of genes coding for desmin, the myogenic factors myogenin and myoD, the acetylcholine receptor alpha-subunit and the muscular chloride channel CIC-1. We attempted to improve yields and myogenic differentiation in culture by using three-dimensional microcarrier systems. Out of a variety of carriers tested in stationary cultures, collagen-coated dextran Cytodex3 beads proved optimal for the proliferation and differentiation of the murine myogenic cell line C2C12. With C2C12 myoblasts in stationary and stirred systems (Spinner- and SuperSpinner flasks), surface adherence, differentiation into myotubes and expression of muscle-specific mRNAs on Cytodex3 beads were the same as in conventional cultures. Other carriers tested (DEAE cellulose, glass, plastic, cellulose, polyester) did not support growth and differentiation of C2C12 cells. The secondary mouse myogenic stem cells M12 and M2.7-MDX proliferated and differentiated well in stationary Cytodex3 cultures, but no differentiation occurred in Spinner flasks. As indicated by light and scanning electron microscopy, C2C12 myotubes formed not only on but also in between Cytodex beads. The secondary cell lines may succumb to shear forces under these conditions.     

Aged‐senescent cells contribute to impaired heart regeneration

Aging leads to increased cellular senescence and is associated with decreased potency of tissue‐specific stem/progenitor cells. Here, we have done an extensive analysis of cardiac progenitor cells (CPCs) isolated from human subjects with cardiovascular disease, aged 32–86 years. In aged subjects (>70 years old), over half of CPCs are senescent (p16^INK4A, SA‐β‐gal, DNA damage γH2AX, telomere length, senescence‐associated secretory phenotype [SASP]), unable to replicate, differentiate, regenerate or restore cardiac function following transplantation into the infarcted heart. SASP factors secreted by senescent CPCs renders otherwise healthy CPCs to senescence. Elimination of senescent CPCs using senolytics abrogates the SASP and its debilitative effect in vitro. Global elimination of senescent cells in aged mice (INK‐ATTAC or wild‐type mice treated with D + Q senolytics) in vivo activates resident CPCs and increased the number of small Ki67‐, EdU‐positive cardiomyocytes. Therapeutic approaches that eliminate senescent cells may alleviate cardiac deterioration with aging and restore the regenerative capacity of the heart.     

Transforming growth factor-beta1 regulates the fate of cultured spinal cord-derived neural progenitor cells

Abstract. Objectives: We have evaluated the physiological roles of transforming growth factor‐β1 (TGF‐β1) on differentiation, migration, proliferation and anti‐apoptosis characteristics of cultured spinal cord‐derived neural progenitor cells. Methods: We have used neural progenitor cells that had been isolated and cultured from mouse spinal cord tissue, and we also assessed the relevant reaction mechanisms using an activin‐like kinase (ALK)‐specific inhibitory system including an inhibitory RNA, and found that it involved potential signalling molecules such as phosphatidylinositol‐3‐OH kinase (PI3K)/Akt and mitogen‐activated protein kinase (MAPK)/extracellular signal‐regulated kinase (ERK1/2). Results and Conclusions: Transforming growth factor‐β1‐mediated cell population growth was activated after treatment and was also effectively blocked by an ALK41517‐synthetic inhibitor (4‐(5‐benzo(1,3) dioxol‐5‐yl‐4‐pyridine‐2‐yl‐1H‐imidazole‐2‐yl) benzamide (SB431542) and ALK siRNA, thereby indicating the involvement of SMAD2 in the TGF‐β1‐mediated growth and migration of these neural progenitors cells (NPC). In the present study, TGF‐β1 actively induced NPC migration in vitro. Furthermore, TGF‐β1 demonstrated extreme anti‐apoptotic behaviour against hydrogen peroxide‐mediated apoptotic cell death. At low dosages, TGF‐β1 enhanced (by approximately 76%) cell survival against hydrogen peroxide treatment via inactivation of caspase‐3 and ‐9. TGF‐β1‐treated NPCs down‐regulated Bax expression and cytochrome c release; in addition, the cells showed up‐regulated Bcl‐2 and thioredoxin reductase 1. They also had increased p38, Akt and ERK1/2 phosphorylation, showing the involvement of both the PI3K/Akt and MAPK/ERK1/2 pathways in the neuroprotective effects of TGF‐β1. Interestingly, these effects operate on specific subtypes of cells, including neurones, neural progenitor cells and astrocytes in cultured spinal cord tissue‐derived cells. Lesion sites of spinal cord‐overexpressing TGF‐β1‐mediated prevention of cell death, cell growth and migration enhancement activity have been introduced as a possible new basis for therapeutic strategy in treatment of neurodegenerative disorders, including spinal cord injuries.     

β‐Catenin and Rho GTPases as downstream targets of TGF‐β1 during pulp repair

TGF‐β1 (transforming growth factor‐β1) plays a central role in regulating proliferation, migration and differentiation of dental pulp cells during the repair process after tooth injury. Our previous study showed that p38 mitogen‐activated protein kinase may act downstream of TGF‐β1 signalling to effect the differentiation of dental pulp cells. However, the molecular mechanisms that trigger and regulate the process remain to be elucidated. TGF‐β1 interacts with signalling pathways such as Wnt/β‐catenin and Rho to induce diverse biological effects. TGF‐β1 activates β‐catenin signalling, increases β‐catenin nuclear translocation and interacts with LEF/TCF to regulate gene expression. Morphologic changes in response to TGF‐β1 are associated with activation of Rho GTPases, but are abrogated by inhibitors of Rho‐associated kinase, a major downstream target of Rho. These results suggest that the Wnt/β‐catenin and Rho pathways may mediate the downstream events of TGF‐β1 signalling.