Regulation of mitotic activity and the cell cycle in primary chick muscle cells by neurotransferrin

Transferrin as a muscle trophic factor

Muscle cells grow by proliferation and protein accumulation. During the initial stages of development the participation of nerves is not always required. Myoblasts and satellite cells proliferate, fusing to form myotubes which further differentiate to muscle fibers. Myotubes and muscle fibers grow by protein accumulation and fusion with other myogenic cells. Muscle fibers finally reach a quasi-steady state which is then maintained for a long period. The mechanism of maintenance is not well understood. However, it is clear that protein metabolism plays a paramount role. The role played by satellite cells in the maintenance of muscle fibers is not known. Growth and maintenance of muscle cells are under the influence of various tissues and substances. Among them are Tf and the motor nerve, the former being the main object of this review and essential for both DNA and protein synthesis. Two sources of Tf have been proposed, i.e., the motor nerve and the tissue fluid. The first proposal is that the nervous trophic influence on muscle cells is mediated by Tf which is released from the nerve terminals. In this model, the sole source of Tf which is donated to muscle cells should be the nerve, and Tf should not be provided for muscle fiber at sites other than the synaptic region; otherwise, denervation atrophy would not occur, since Tf provided from TfR located at another site would cancel the effect of denervation. The second proposal is that Tf is provided from tissue fluid. This implies that an adequate amount of Tf is transferred from serum to tissue fluid; in this case TfR may be distributed over the entire surface of the cells. The trophic effects of the motor neuron have been studied in vivo, but its effects of myoblast proliferation have not been determined. There are few experiments on its effects on myotubes. Most work has been made on muscle fibers, where innervation is absolutely required for their maintenance. Without it, muscle fibers atrophy, although they do not degenerate. In contrast, almost all the work on Tf has been performed in vitro. Its effects on myoblast proliferation and myotube growth and maintenance have been established; myotubes degenerate following Tf removal. But its effects on mature muscle fibers in vivo are not well understood. Muscle fibers possess TfR all over on their cell surface and contain a variety of Fe-binding proteins, such as myoglobin. It is entirely plausible that muscle fibers require an amount of Tf, and that this is provided by TfR scattered on the cell surface.(ABSTRACT TRUNCATED AT 400 WORDS)

Comparison of metabolic effects of EGF, TGF-alpha, and TGF-beta 1 in primary culture of fetal bovine myoblasts and rat L6 myoblasts

1. Comparative studies of EGF, TGF-alpha, and TGF-beta 1 action on the synthesis of DNA and cellular proteins in rat L6 myogenic cells and fetal bovine myoblasts demonstrated considerable differences between particular growth factors, dependent on dose and target cells. 2. Among examined growth factors only EGF exerted mitostimulatory action, more pronounced at lower concentrations. EGF, progressively with dose, stimulated protein synthesis much more effectively in fetal bovine myoblasts than in L6 cells. 3. The dynamics of stimulation of protein synthesis by TGF-alpha was greater than by EGF in both examined types of cell cultures. 4. The maximal response of fetal bovine myoblasts to TGF-alpha in a concentration of 100 ng/ml reached 370%, whereas EGF in a 10 times higher concentration stimulated protein synthesis only to 123% of control. 5. In contrast to EGF, TGF-alpha significantly inhibits DNA synthesis. Inhibition of the mitogenic response with simultaneous stimulation of protein synthesis by TGF-alpha may indicate changes toward cell differentiation. 6. TGF-beta 1 in smallest concentration inhibits both DNA and protein synthesis. The suppressive action of TGF-beta 1 was more distinct in fetal bovine myoblasts than in the L6 cell line. 7. Increasing concentrations of TGF-beta 1 diminished its inhibitory effect, even leading to stimulation of protein synthesis at higher doses in L6 myoblasts.

Monoclonal antibody detects embryonic epitope specific for nerve-derived transferrin

Monoclonal antibodies were generated against transferrin purified from chick embryo extract by fusing spleen cells from BALB/c mice immunized against embryonic transferrin, with myeloma cells. Antibodies produced by the selected hybridoma clones were all type IgG. Twelve clones were selected for secretion of antibodies to the embryo extract-derived transferrin, and three clones were studied extensively. Immunoblotting was used to demonstrate antibody binding to several avian transferrin proteins derived from adult chicken serum, adult chicken peripheral nerves, and ovotransferrin. Screening and detailed epitope analysis were accomplished by solid-phase immunoassay. The results indicated that two clones, 2G9.1 and 2B11.1, recognized the embryonic and egg antigens in preference to the adult proteins. However, a third clone, 6H2.1, recognized the nerve-derived transferrin preferentially to both the embryonic and adult serum antigens. None of the clones recognized the serum-derived transferrin in preference to the other antigens. These results indicate that embryonic epitope(s) are conserved in the nerve- but not the serum-derived transferrin. They also show that the neural antigen has site(s) distinct from the embryonic proteins. No changes in displacement curves were observed after these proteins were digested with neuraminidase, indicating that the epitope differences discovered are not intimately related to sialic acid residues on the various transferrins.

Effect of denervation on limb growth

This study used Rana pipiens tadpoles to assess the effect of complete and partial sciatic denervation on tibial bone growth and foot growth. Complete sciatic denervation was performed in R. pipiens at Stages XIV, XVII, and XX and they were killed at Stages XVII, XX, and XXIV. Partial denervation consisted of peroneal or tibial nerve sectioning at Stages XVII and XX with killing at Stages XX and XXIV. Analysis of experimental animals and controls consisted of (a) quantitative axon counts, (b) tibial length, (c) midtibial cross-sectional area, (d) midtibial cortical thickness, (e) midtibial cartilage anlage cross-sectional area, (f) foot silhouette area, and (g) osteocyte number and osteocyte density. Both complete and partial denervation resulted in significant effects on bone and foot growth: (a) decreased bone length, (b) decreased cross-sectional bone area without cortical thinning, (c) increased cartilage anlage cross-sectional area, and (d) decreased foot size. This experiment demonstrated a trophic effect of nerve on bone growth and development and foot growth. The mechanism of this action is unknown but the data suggests a slowed rate of maturation in denervated bones. The possibility exists that defective peripheral nerve-limb tissue interactions may cause human deformities such as idiopathic clubfoot and idiopathic limb length discrepancy.

Transferrin and the growth-promoting effect of nerves

In addition to its role in the activity of specialized proteins such as hemoglobin and myoglobin, iron is required as a cofactor in several important enzymes common to most animal cells. One such enzyme, ribonucleotide reductase, which regulates the production of deoxyribonucleotides during DNA synthesis, requires a continuous supply of iron to maintain its activity throughout the process of DNA replication. The mechanism by which animal cells normally acquire iron involves receptor-mediated uptake of iron-loaded transferrin, followed by release of apotransferrin. The density of transferrin receptors on the cell surface is greatly increased in rapidly dividing normal and neoplastic cells. Various mitogens and certain organogenic tissue interactions have been shown to induce the appearance of transferrin receptors, signalling the onset of DNA replication. Interference with this process of iron delivery causes the rapid arrest of cell cycling, frequently during the S phase itself, which underscores the importance of iron for DNA replication. Although most circulating transferrin is synthesized in the liver and embryonic yolk sac, smaller quantities are produced in several other embryonic organs and certain other adult tissues. It has been suggested that local synthesis and/or release of transferrin supplies the iron required by rapidly growing cells in situations where the cells do not have ready access to adequate amounts of plasma transferrin due to incomplete development of the vasculature or the presence of blood-tissue barriers (Ekblom and Thesleff, 1985; Meek and Adamson, 1985). Oligodendrocytes and Schwann cells have been shown to synthesize and/or contain high concentrations of transferrin and these cells therefore may constitute a local source of this factor for neurons, whose growth and survival in vitro require transferrin. Transferrin in central and peripheral nervous tissues may be significant for the trophic or growth-promoting effect neurons exert on cells of certain tissues. Transferrin duplicates the activity of neural tissue or neural extracts on growth and development of cultured skeletal myoblasts from chick embryos and on proliferation of mesenchymal cells in blastemas from regenerating amphibian limbs, two systems that have been widely used in investigations of the growth-promoting influence of nerves. Moreover, removal of active transferrin from neural extracts, either with antibodies to transferrin or chelation of the iron, inhibits reversibly the effect of the extract in these developing systems. While the physiological significance of the extract in these developing systems.(ABSTRACT TRUNCATED AT 400 WORDS)

The regulation by low-density lipoproteins of the activation of oxidative enzyme-primed lymphocytes is governed by transferrin

The activation of T lymphocytes was regulated in vitro by low-density lipoproteins (LDL). Not all prereplicative events induced by the oxidative enzymatic mitogens neuraminidase and galactose oxidase (NAGO) were susceptible to inhibition by LDL. The accessory cell-independent early blastogenic response was not suppressed. LDL suppressed accessory cell-dependent responses, and the extent of LDL suppression, depended on the concentration of transferrin. A gradient of transferrin determined the point in the cell cycle at which NAGO-primed lymphocytes were suppressed by LDL. When transferrin was low (0-10 micrograms/ml) and in serum-free medium (SFM), LDL suppressed the expression of cell surface receptors for interleukin-2 (IL-2R) and transferrin (TfR), the late blastogenic response prior to DNA replication (72 hr), and DNA replication. At higher levels of transferrin, about 100 micrograms/ml, the LDL-suppressed cells were IL-2R+, TfR+ and responsive to IL-2, but did not enter S phase. LDL suppression could be ablated by IL-2 and by high levels of transferrin (250-1000 micrograms/ml). In RPMI medium containing serum (FBS), the pattern of LDL suppression was different from that in SFM: fully activated IL-2R+, TfR+ lymphocytes were unresponsive to exogenous IL-2, suggesting that they were blocked at the G1/S boundary. This block was also relieved by transferrin (greater than 100 micrograms/ml). The data suggest that the interplay between transferrin and LDL is a critical factor in the NAGO-induced stimulation of T lymphocytes. LDL and transferrin exert negative and positive control of lymphocyte activation, respectively. In SFM, LDL appear to alter transferrin utilization by accessory cells; in RPMI-FBS, by fully activated T lymphocytes.

Islet neoformation in tissue culture

We have devised a tissue culture system that permits de novo formation of islets. Neonatal rat pancreata are enzymatically dissociated into single cells. The cell suspension is filtered through polyester cloth with 20 microns pores to exclude cell aggregates as well as preformed islets and a single cell suspension is then plated into tissue culture dishes at a density precluding reaggregation. Pancreatic cells proliferate forming numerous colonies of epithelioid cells. After a confluent monolayer, cells proliferate into a third dimension, the space occupied by the culture medium. Third dimensional proliferation occurs from basal monolayers of epithelioid colonies. At about 9 days in culture, numerous hillocks are visible that are spaced at about 1 mm from one another. Islets are observed to bud from the hillock surfaces. In 1 micron-thick sections, secretion granules are detected with the light microscope in some islet cells. With the electron microscope three basic cell types are seen. One peripherally located cell type is sparsely granulated and appears to be a precursor cell. The other peripherally located cell type shows a homogeneous population of secretion granules characteristic of A-cells. The third cell type is found in the interior of islets containing granules characteristic of B-cells. Islet cells, but not hillock cells, react immunocytochemically for insulin and glucagon. The cultures secrete 2 to 10-fold the amounts of glucagon present in fresh medium. It is concluded that differentiation of A- and B-cells occurs in neoformed islets.

The distribution of transferrin immunoreactivity in the rat central nervous system

Recent studies have demonstrated receptors in the nervous system for transferrin, the iron binding and transport protein in the blood. This study using immunohistochemistry at the light and electron microscopic levels demonstrates that transferrin (Tf) is found predominantly in oligodendrocytes in both the gray and white matter of the cerebral cortex, cerebellum and spinal cord. Within the cerebral cortex, layer V has more Tf-labeled cells than the other cortical layers. In the spinal cord, lamina VII has the highest density of Tf-positive cells. Based on location, 3 types of oligodendrocytes can be described: perineuronal, interfascicular and perivascular. In addition to oligodendrocytes, endothelial cells and possibly some neuronal membranes of layer V pyramidal and anterior horn cells label with Tf antiserum. Ultrastructurally, Tf reaction product is homogeneously distributed throughout the perinuclear cytoplasm of both oligodendrocytes and endothelial cells. The importance of iron in motor and behavior function is well established although the mechanism of action of iron in the CNS is not well understood. The presence of Tf in oligodendrocytes implies that these neuroglia are involved in iron mobilization and storage in the CNS. Stored quantities of iron and the ability to mobilize the iron through stored transferrin may be the reason for the extreme dietary restrictions necessary to induce iron-deficient CNS disorders.

Partial purification and characterization of the calcium-dependent and phospholipid-dependent protein kinase C from chick oviduct

The calcium-dependent and phospholipid-dependent protein kinase C is partially purified (2000-fold) from chick oviduct cytosol by chromatography on DEAE-cellulose, Sephadex G150 and (after affinity binding of the enzyme to phosphatidylserine-diolein liposomes) on Bio-Gel A-0.5m. The enzyme is activated by phosphatidylserine and calcium ions. Diolein increases the affinity of the enzyme for both cofactors and can be replaced by the tumour-promoting phorbol ester 12-O-tetradecanoyl-phorbol 13-acetate. Phosphatidylserine can be replaced by unsaturated long-chain fatty acids. Quercetin and phloretin inhibit the kinase reversibly competing with ATP. Several oviduct proteins are found to be phosphorylated by the partially purified enzyme. One of the substrates, a 78-kDa protein, appears to be ovotransferrin.

Specificity of chicken and mammalian transferrins in myogenesis

Chicken transferrins isolated from eggs, embryo extract, serum or ischiatic-peroneal nerves are able to stimulate incorporation of [3H]thymidine, and promote myogenesis by primary chicken muscle cells in vitro. Mammalian transferrins (bovine, rat, mouse, horse, rabbit, and human) do not promote [3H]thymidine incorporation or myotube development. Comparison of the peptide fragments obtained after chemical or limited proteolytic cleavage demonstrates that the four chicken transferrins are all indistinguishable, but they differ considerably from the mammalian transferrins. The structural differences between chicken and mammalian transferrins probably account for the inability of mammalian transferrins to act as mitogens for, and to support myogenesis of, primary chicken muscle cells.