Explant-derived human dental pulp stem cells enhance differentiation and proliferation potentials.

Numerous stem cell niches are present in the different tissues and organs of the adult human body. Among these tissues, dental pulp, entrapped within the 'sealed niche' of the pulp chamber, is an extremely rich site for collecting stem cells. In this study, we demonstrate that the isolation of human dental pulp stem cells by the explants culture method (hD-DPSCs) allows the recovery of a population of dental mesenchymal stem cells that exhibit an elevated proliferation potential. Moreover, we highlight that hD-DPSCs are not only capable of differentiating into osteoblasts and chondrocytes but are also able to switch their genetic programme when co-cultured with murine myoblasts. High levels of MyoD expression were detected, indicating that muscle-specific genes in dental pulp cells can be turned on through myogenic fusion, confirming thus their multipotency. A perivascular niche may be the potential source of hD-DPSCs, as suggested by the consistent Ca(2+) release from these cells in response to endothelin-1 (ET-1) treatment, which is also able to significantly increase cell proliferation. Moreover, response to ET-1 has been found to be superior in hD-DPSCs than in DPSCs, probably due to the isolation method that promotes release of stem/progenitor cells from perivascular structures. The ability to isolate, expand and direct the differentiation of hD-DPSCs into several lineages, mainly towards myogenesis, offers an opportunity for the study of events associated with cell commitment and differentiation. Therefore, hD-DPSCs display enhanced differentiation abilities when compared to DPSCs, and this might be of relevance for their use in therapy.

Determination, diversification and multipotency of mammalian myogenic cells.

In amniotes, myogenic commitment appears to be dependent upon signaling from neural tube and dorsal ectoderm, that can be replaced by members of the Wnt family and by Sonic hedgehog. Once committed, myoblasts undergo different fates, in that they can differentiate immediately to form the myotome, or later to give rise to primary and secondary muscle fibers. With fiber maturation, satellite cells are first detected; these cells contribute to fiber growth and regeneration during post-natal life. We will describe recent data, mainly from our laboratory, that suggest a different origin for some of the cells that are incorporated into the muscle fibers during late development. We propose the possibility that these myogenic cells are derived from the vasculature, are multi-potent and become committed to myogenesis by local signaling, when ingressing a differentiating muscle tissue. The implications for fetal and perinatal development of the whole mesoderm will also be discussed.

Differential expression of the Wnt putative receptors Frizzled during mouse somitogenesis.

The expression of eight murine Frizzled (1,3-9) genes was studied during mouse somitogenesis, in order to correlate the Wnt-dependent activation of myogenesis with the expression of specific Frizzled putative receptors. Frizzled 1, 3, 6, 7, 8, and 9 have specific expression in the forming and differentiating somites. The genes analyzed have a complex and partly overlapping pattern of expression in other regions of the embryo.

Differential activation of Myf5 and MyoD by different Wnts in explants of mouse paraxial mesoderm and the later activation of myogenesis in the absence of Myf5.

Activation of myogenesis in newly formed somites is dependent upon signals derived from neighboring tissues, namely axial structures (neural tube and notochord) and dorsal ectoderm. In explants of paraxial mesoderm from mouse embryos, axial structures preferentially activate myogenesis through a Myf5-dependent pathway and dorsal ectoderm preferentially through a MyoD-dependent pathway. Here we report that cells expressing Wnt1 will preferentially activate Myf5 while cells expressing Wnt7a will preferentially activate MyoD. Wnt1 is expressed in the dorsal neural tube and Wnt7a in dorsal ectoderm in the early embryo, therefore both can potentially act in vivo to activate Myf5 and MyoD, respectively. Wnt4, Wnt5a and Wnt6 exert an intermediate effect activating both Myf5 and MyoD equivalently in paraxial mesoderm. Sonic Hedgehog synergises with both Wnt1 and Wnt7a in explants from E8.5 paraxial mesoderm but not in explants from E9.5 embryos. Signaling through different myogenic pathways may explain the rescue of muscle formation in Myf5 null embryos, which do not form an early myotome but later develop both epaxial and hypaxial musculature. Explants of unsegmented paraxial mesoderm contain myogenic precursors capable of expressing MyoD in response to signaling from a neural tube isolated from E10.5 embryos, the developmental stage when MyoD is present throughout the embryo. Myogenic cells cannot activate MyoD in response to signaling from a less mature neural tube. Together these data suggest that different Wnt molecules can activate myogenesis through different pathways such that commitment of myogenic precursors is precisely regulated in space and time to achieve the correct pattern of skeletal muscle development.

Myogenic conversion of mammalian fibroblasts induced by differentiating muscle cells.

Somite-derived skeletal myoblasts are supposed to be the sole source of muscle fibre nuclei during pre- and postnatal development, but evidence is accumulating for unorthodox contributions to muscle fibre nuclei from other cell types. For example, in tissue culture, fibroblasts can fuse with dysgenic myoblasts and restore correct membrane function. We report here the results of a series of experiments investigating this phenomenon and its possible mechanism. 10T1/2 cells, infected with a replication defective retrovirus encoding the bacterial enzyme beta-galactosidase, fused to form beta-galactosidase positive, differentiated myotubes when cocultured with differentiating uninfected C2C12 or primary myogenic cells, but this did not occur when they were cocultured with other cells such as 3T3 fibroblasts or PC12 pheochromocytoma cells. Myogenic conversion ranged from 1 to 10% of the 10T1/2 cell population and required close cell interaction between the different cells types: it was not induced by conditioned medium or extracellular matrix deposited by C2C12 cells. Myogenic conversion was also observed in vivo, after injection of similarly infected 10T1/2 cells into regenerating muscle. Conversion was seen also after coculture of uninfected 10T1/2 cells with primary chick myoblasts, thus demonstrating that it was not dependent upon viral infection and that there is no species or class barrier in this phenomenon. Primary fibroblasts, isolated from different organs of transgenic mice carrying a Lac Z marker under the control of a muscle-specific promoter, restricting beta-galactosidase expression to striated muscle cells, also underwent myogenic conversion, when cocultured with C2C12 myoblasts.(ABSTRACT TRUNCATED AT 250 WORDS)

Myoblast differentiation during mammalian somitogenesis is dependent upon a community effect.

The differentiation potential of early mammalian myogenic cells was tested under clonal culture conditions. Cells were isolated from paraxial mesoderm and limb buds of transgenic mouse embryos at 9.5 days after conception and grown in culture at clonal density either on collagen-coated dishes or on various feeder cell layers. The transgene used contained a reporter gene encoding beta-galactosidase with a nuclear localization signal under the control of regulatory sequences from the gene for fast myosin light chain 3, so that beta-galactosidase staining indicated the presence of differentiated muscle cells. After 5 days in culture, the number and size of beta-galactosidase-positive (beta-gal+) clones were recorded. Cells isolated from somites I-V (the last five somites to have formed) or from unsegmented paraxial mesoderm did not give rise to any beta-gal+ clones. Cells isolated from somites VI-X or from the forelimb bud gave rise to beta-gal+ clones, but only on feeder cells. Cells from somites XI or older gave rise to beta-gal+ clones independently of the substrate. However, when cells isolated from unsegmented paraxial mesoderm or somites I-V were cultured with nontransgenic cells from the trunk (including neural tube and notochord), differentiation occurred on condition that the cells were in a three-dimensional aggregate, even though their specific position in the somite had been lost. By culturing explants ranging in size from 1 to < 100 cells in the presence of an inhibitor of cell division, we determined that a minimal number of 30-40 cells is required for mesodermal cells to differentiate.

MyoD, myogenin independent differentiation of primordial myoblasts in mouse somites.

The accumulation of two myogenic regulatory proteins, MyoD and myogenin, was investigated by double-immunocytochemistry and correlated with myosin heavy chain expression in different classes of myoblasts in culture and during early myogenesis in vivo. During in vitro differentiation of fetal myoblasts, MyoD-positive cells were detected first, followed by the appearance of cells positive for both MyoD and myogenin and finally by the appearance of differentiated myocytes and myotubes expressing myosin heavy chain (MHC). A similar pattern of expression was observed in cultures of embryonic and satellite cells. In contrast, most myogenic cells isolated from newly formed somites, expressed MHC in the absence of detectable levels of myogenin or MyoD. In vivo, the appearance of both myogenin and MyoD proteins was only detected at 10.5 d postcoitum (d.p.c.), when terminally differentiated muscle cells could already be identified in the myotome. Parasagittal sections of the caudal myotomes of 10.5-d-old embryos showed that expression of contractile proteins preceded the expression of myogenin or MyoD and, when coexpressed, MHC and myogenin did not co-localize within all the cells of the myotome. In the limb bud, however, many myogenin (or MyoD) positive/MHC negative cells could be observed in the proximal region at day 11. During further embryonic development the expression of these proteins remained constant in all the muscle anlagens examined, decreasing to a low level during the late fetal period. Western and Northern analysis confirmed that the myogenin protein could only be detected after 10.5 d.p.c. while the corresponding message was clearly present at 9.5 d.p.c., strongly suggesting a posttranscriptional regulation of myogenin during this stage of embryonic development. These data show that the first myogenic cells which appear in the mouse myotome, and can be cultured from it, accumulate muscle structural proteins in their cytoplasm without expressing detectable levels of myogenin protein (although the message is clearly accumulated). Neither MyoD message or protein are detectable in these cells, which may represent a distinct myogenic population whose role in development remains to be established.

Adrenocorticotropin is a specific mitogen for mammalian myogenic cells.

Peptides derived from proopiomelanocortin (POMC) have been found to stimulate the proliferation of murine myogenic cells. Among these peptides, adrenocorticotropin (ACTH) and alpha-, beta-, and gamma-melanocyte-stimulating hormones (MSH) were found to be active, whereas the opioid peptides were not. At clonal density, both ACTH and MSH caused a three- to fourfold increase in the average number of cells per clone in myogenic but not in fibroblast colonies. At high cell density, ACTH and MSH caused a three- to fourfold increase in proliferation of myogenic cells, reflected by an increased accumulation of skeletal myosin. On the other hand mouse embryo skin or muscle fibroblasts or vertebral chondroblasts did not increase proliferation in response to POMC-derived peptides. The half-maximal dose at which ACTH stimulated myoblast proliferation was around 5 nM, and the mitogenic effect was doubled by suboptimal doses of fibroblast growth factor. The possible physiological significance of the mitogenic effect of ACTH on myogenic cells is discussed.

The expression of slow myosin during mammalian somitogenesis and limb bud differentiation.

The developmental pattern of slow myosin expression has been studied in mouse embryos from the somitic stage to the period of secondary fiber formation and in myogenic cells, cultured from the same developmental stages. The results obtained, using a combination of different polyclonal and monoclonal antibodies, indicate that slow myosin is coexpressed in virtually all the cells that express embryonic (fast) myosin in somites and limb buds in vivo as well as in culture. On the contrary fetal or late myoblasts (from 15-d-old embryos) express in culture only embryonic (fast) myosin. At this stage, muscle cells in vivo, as already shown (Crow, M.T., and F.A. Stockdale. 1986. Dev. Biol. 113:238-254; Dhoot, G.K. 1986. Muscle & Nerve. 9:155-164; Draeger, A., A.G. Weeds, and R.B. Fitzsimons. 1987. J. Neurol. Sci. 81:19-43; Miller, J.B., and F.A. Stockdale. 1986. J. Cell Biol. 103:2197-2208), consist of primary myotubes, which express both myosins, and secondary myotubes, which express preferentially embryonic (fast) myosin. Under no circumstance neonatal or adult fast myosins were detected. Western blot analysis confirmed the immunocytochemical data. These results suggest that embryonic myoblasts in mammals are all committed to the mixed embryonic-(fast) slow lineage and, accordingly, all primary fibers express both myosins, whereas fetal myoblasts mostly belong to the embryonic (fast) lineage and likely generate fibers containing only embryonic (fast) myosin. The relationship with current models of avian myogenesis are discussed.

'Early' mammalian myoblasts are resistant to phorbol ester-induced block of differentiation.

Mesenchymal cells were isolated from somites and limbs of mouse embryos at different developmental stages. When grown in tissue culture, some of the cells underwent muscle differentiation as indicated by synthesis of sarcomeric myosin, acetylcholine receptor and, in the case of limb cells, fusion into multinucleated myotubes. When the tumour promoter 12-O-tetradecanoyl phorbol 13-acetate (TPA) was added to these cultures, it caused differential effects, depending upon the age of the embryo from which cells were isolated. In cultures of somites or limb bud from embryos up to 12 days post coitum, TPA did not interfere with the appearance of differentiated muscle cells. When TPA was added to cultures from older embryos, it inhibited muscle differentiation with an efficiency which increased with the age of the embryo, reaching about 90% inhibition at 15 days. After this period, a new population of myogenic cells appeared in the limb, which were able to differentiate in the presence of TPA and represented the great majority of myoblasts after day 18 of embryonic development. The simplest interpretation of these data can be based on the existence of three major classes of myogenic cell precursors, which appear sequentially during muscle histogenesis: 'early' myoblasts, which appear resistant to tumour promoters; 'late' myoblasts, whose differentiation is inhibited by tumour promoters and 'satellite' cells which, like early myoblasts, show no sensitivity to TPA.

Neural control of early myogenic differentiation in cultures of mouse somites.

Neural tubes, with flanking somite streaks, were isolated from mouse embryos ranging in age from 8 to 11 days post coitus (dpc). The somites were further dissected along the neural tube to obtain one somite streak associated with the neural tube and the other free of nerve cells. The two groups of somites (with and without neural tubes) were dissociated to single cell suspension by a brief incubation with EDTA. High-density micro-mass cultures were established from these two groups of cells and the extent of cell differentiation was assayed by staining the cultures with an anti-myosin antibody. The results obtained indicated that during early somitogenesis (8.5 dpc) the presence of cells from neural tube is necessary for the emergence of myosin-positive cells in culture. At later stages (10.5 dpc), however, the total number of myosin-positive cells appearing in culture is largely independent from the presence of nerve cells. At these later stages, the presence of nerve cells inhibited the occurrence of fusion in myogenic cells. Many multinucleated myotubes appeared in cultures of somitic cells in the absence of nerve cells, but very few in their presence. The possible relationship of these data with the appearance of mononucleated differentiated cells in myotomes in vivo and the possible neural control of this stage of myogenesis are discussed.

Pyruvate and lactate production by cultured Sertoli cells, fibroblasts and muscle satellite cells, and the effect of hormonal and dcAMP stimulation.

Isolated male germ cells survive in culture if medium is supplemented with adequate energy substrates such as lactate or pyruvate. The purpose of the present study was to investigate if cultured Sertoli cells release in the medium lactate or pyruvate and if this production is affected by FSH or dcAMP treatment. We have also studied if the ability to produce lactate and pyruvate is shared by other cell types. The results show that 1) the two metabolites are released from germ-cell-free rat Sertoli cell monolayers, and their release is stimulated by hormone or dcAMP 2) other cell types of mesodermic origin release more lactate and pyruvate than Sertoli cells, but are not stimulated by FSH or dcAMP.

Meiotic resumption and intracellular cAMP levels in mouse oocytes treated with compounds which act on cAMP metabolism.

We have studied the effect of agents known to stimulate adenylate cyclase on spontaneous meiotic resumption in vitro by mouse oocytes. We have found that cholera toxin (CT) (up to 1 microM) and prostaglandin E1 (PGE1) (up to 160 microM) are not able to prevent meiotic resumption, but a clear dose-dependent delay in meiosis resumption was observed during the first 3 h of incubation in medium containing CT or PGE1. The effect became clearer when a small concentration of isobutylmethylxanthine (MIX) (1 microM) was added to the medium. We have also measured the cAMP content of the oocyte: the basal content is 2.1 fmol; this value drops to 0.9 fmol during a 2-h culture period. The decrease is partially prevented if CT is present in the incubation medium, while total cAMP content increases to 3.1 fmol in the presence of 1 mM MIX. The results suggest that isolated mouse oocytes contain toxin and prostaglandin sensitive adenylate cyclase and also an active phosphodiesterase system.