Soluble fibrin augments spreading of fibroblasts by providing RGD sequences of fibrinogen in soluble fibrin

We previously reported that fibroblasts were found to spread far more avidly on NaBr-solubilized fibrin monomer (FM) monolayers than on immobilized fibrinogen (Fbg), indicating that removal of fibrinopeptides by thrombin is a prerequisite for the fibrin-mediated augmentation of cell spreading [J. Biol. Chem. 272 (1997) 8824-8829]. Soluble fibrin (SF), a 1:2 complex of fibrin-monomer and fibrinogen, is known to be present in the circulating blood under the pathological condition in which blood coagulation is activated. However, its physiological roles are still incompletely known. Fibroblasts spread on immobilized purified soluble fibrin. Cells spreading on immobilized soluble fibrin were blocked by the exogenous addition of soluble fibrin and glycine-arginine-glycine-aspartic acid-serine-phenylalanine (GRGDSP)-synthetic peptide but not by the addition of fibrinogen or fibrin monomer. However, cell spreading activity was decreased in the surfaces coated with fragment X, whose Aalpha-chains lack carboxyl-terminal segments including arginine-glycine-aspartic acid (RGD)-2 domain, fibrin monomer complexes. It suggests that the RGD-2 domain of fibrinogen after being complexed with fibrin monomer plays a pivotal role for soluble fibrin-dependent cell spreading. Soluble fibrin in plasma derived from the patients of disseminated intravascular coagulation (DIC) was immuno-purified using the monoclonal antibody (mAb) which specifically recognizes the Ca(++)-dependent conformer of fibrinogen. The purified soluble fibrin consisted of desAA-fibrin monomer and two fibrinogen molecules and did show the cell spreading activity. Thus, soluble fibrin in plasma plays a role as the modulator of thrombogenic process in vivo.     

Adult rat hippocampal slices as in vitro models for neurodegeneration: Studies on cell viability and apoptotic processes

Adult hippocampal slice cultures were used in the modeling of apoptotic aspects of neurodegeneration. Slice viability was determined by the use of trypan blue (TB) staining, and apoptosis was assessed by caspase-3 immunohistochemistry. A large number of pyramidal cells showed signs of degeneration 30 min after sectioning (58.4% of the total number of pyramidal cells), as they exhibited TB uptake, and about 71.6% of these neurons became stained by the third day in culture, when patches in the stratum oriens also demonstrated distinct TB staining. By the sixth day of culturing, almost all cells in the pyramidal cell layer became TB positive (88.4%). The caspase-3 immunoreactivity displayed a different pattern, as the most intense immunoreactivity, detected mainly in the pyramidal cells, peaked 6 h after culturing, and then decreased steadily. The present data show that in adult hippocampal slices a large number of pyramidal cells initiate apoptotic processes as a result of irreparable damage sustained during slice preparation and culture maintenance, and support the notion that apoptosis is an integral part of the neurodegenerative processes not only in vivo but also in vitro. Elucidation of mechanisms for the apoptotic processes in adult hippocampal slice cultures could lead to the development of new therapeutic strategies; moreover, the utilization of adult hippocampal slice cultures could be a viable alternative technique to in vivo experiments in studying the mechanisms responsible for neurodegeneration.     

Receptor-mediated uptake of labeled transferrin by embryonic chicken dorsal root ganglion neurons in culture

Transferrin is a growth-promoting plasma protein which is known to occur within developing neurons. Since little information exists on the process by which transferrin is internalized by neurons, we studied this process using dissociated embryonic chicken dorsal root ganglion neurons in culture. Cultured dorsal root ganglion neurons were incubated in the presence of 3.75 nM ¹²⁵I-transferrin at 37°C, the cultures were extensively washed, the neurons were solubilized in a Triton-containing buffer and internalized ¹²⁵I-transferrin was quantified with a gamma counter. ¹²⁵I-transferrin was internalized in a linear fashion for at least 60 min, and this uptake was abolished by the presence of 1.25 μM unlabeled transferrin. No competition for the uptake of ¹²⁵I-transferrin was observed in the presence of 1.25 μM ovalbumin, cytochrome c, hemoglobin, insulin, horseradish peroxidase, aldolase or the carboxyl-terminal fragment (‘half-site’) of transferrin. By contrast, uptake was inhibited by approximately 50% in the presence of the ammo-terminal fragment (‘half-site’) of transferrin (1.25 μM) or in the presence of concanavalin A (1.25 μM). The binding of transferrin conjugated to fluorescein isothiocyanate to neurons at 4°C and its subsequent internalization at 37°C was demonstrated by fluorescence microscopy of unfixed cells following incubation of the neurons in the presence of the fluorescently labeled protein. Furthermore, the transferrin receptors were visualized immunocytochemically on the surface membranes of dorsal root ganglion neurons using rabbit antibodies directed against transferrin receptors from chicken reticulocytes. From these data, we conclude that transferrin is internalized by neurons via receptor-mediated endocytosis, and suggest that this protein may serve an important role in the development and survival of dorsal root ganglion neurons.     

Association of laminin and other basement membrane components with regions of high acetylcholine receptor density on cultured myotubes

The distribution of immunoreactivity to basement membrane components in cultures of rat skeletal myotubes was compared to acetylcholine receptor distribution by fluorescence microscopy. Laminin occurred in patches on the myotube surface, and most laminin patches coincided or overlapped with acetylcholine receptor aggregates. Almost all receptor aggregates coincided with laminin patches. Most of the heparan sulfate proteoglycan and fibronectin was associated with non-muscle cells, but some patches coincided with receptor aggregates on myotubes. In cultures treated with l-ascorbate, collagen types IV and V covered much of the myotube surface and receptor aggregates often coincided with intense collagen patches. When receptor aggregation was induced by treatment of cultures with soluble neural factors, the newly formed receptor aggregates coincided with laminin patches.The results suggest that each of the basement membrane components studied has a distinct distribution pattern in primary rat muscle cell cultures. The striking association of laminin immunoreactivity with receptor aggregates, together with the enhancement of receptor aggregation by laminin reported previously (Vogel et al., J. Neurosci. 3, 1058–1068, 1983) suggests that laminin could have a role in the organization of acetylcholine receptors on developing muscle fibers.     

Divergent effects of lithium and sodium valproate on brain-derived neurotrophic factor (BDNF) production in human astrocytoma cells at therapeutic concentrations

Mood stabilizers such as lithium (Li) or valproic acid (VPA) are used in the therapy of bipolar disorders, but the mechanisms by which these medicines work is unclear. Recently, neuroprotection has attracted attention as a potential action for VPA and Li. The close spatial relationship of the pre- and post-synapse with an astrocyte process within a 'tripartite synapse' suggests that mood stabilizer actions on astrocytes may be important. Therefore, we examined the effect of Li and VPA, at therapeutic concentrations, on brain-derived neurotrophic factor (BDNF) production in cultured human astrocytoma cells over an extended period of exposure. Released (extracellular) and intracellular BDNF was measured with sandwich-ELISA. Intracellular BDNF mRNA was also quantified using RT-PCR. VPA treatment potentiated the level of extracellular BDNF, whereas Li reduced it. Furthermore, VPA caused increased intracellular levels of BDNF protein and mRNA, while exposure to Li led to no significant differences compared to control cells. We suggest the possibility that VPA and Li have divergent effects on astrocyte BDNF production. Mood stabilizers play an essential role in regulating BDNF not only in neurons, but also in astrocytes. These findings could form the basis of a new astrocyte-targeted approach towards developing effective medications to treat bipolar disorders.     

A novel ENG mutation causing impaired co-translational processing of endoglin associated with hereditary hemorrhagic telangiectasia

Hereditary hemorrhagic telangiectasia (HHT) is an inherited autosomal dominant vascular dysplasia caused by mutations in mainly the endoglin gene (ENG) or activin-like kinase receptor 1 (ALK1) gene (ACVRL1). We investigated the molecular basis of HHT in a Japanese patient, and identified a novel missense mutation in ENG (c.38 T > A, p.Leu13Gln) located in the signal peptide's hydrophobic core, but not in ACVRL1. In experiments in COS-1 cells, the Leu13Gln (L13Q) mutant endoglin appeared to be expressed as a precursor form, probably due to impaired protein processing. Flow cytometry analyses of the COS-1 cells transiently expressing recombinant endoglins revealed that the wild-type endoglin was detected on the cell surface, but the L13Q mutant was not. We also analyzed expression patterns of the recombinant endoglins by immunofluorescent staining, and found that the wild-type co-localized with the endoplasmic reticulum (ER), but the L13Q mutant did not. These results implied that the L13Q mutant endoglin fails to insert into the ER, probably due to destruction of the hydrophobic core structure in the signal peptide to be recognized by signal recognition particles. Thus, the Leu13 in the signal peptide of endoglin might be essential for correct protein processing through the ER and cell-surface expression. Taken together, the novel c.38 T > A mutation in ENG would impair co-translational processing of the endoglin, and could be responsible for HHT in this patient.     

A culture model for neurite regeneration of human spinal cord neurons

Effective therapeutic interventions for injuries of the central nervous system such as spinal cord injury are still unavailable, having a great impact on the quality of life of victims and their families, as well as high costs in medical care. Animal models of spinal cord injury are costly, time-consuming and labor-intensive, making them unsuitable for screening large numbers of experimental conditions. Thus, culture models that recapitulate key aspects of neuronal changes in central nervous system injuries are needed to gain further understanding of the pathological and regenerative mechanisms involved, as well as to accelerate the screening of potential therapeutic agents. In this study we differentiated adherent cultures of dissociated human fetal spinal cord neural precursors into postmitotic neurons which we could then detach from culture plates and successfully freeze down in a viable state. When replated in neuronal medium without neurodifferentiating factors, these ready-to-use human spinal cord neurons remained viable, postmitotic and regenerated neurites in a cell density-dependent manner. Insulin-like growth factor 1 and growth hormone had no effect on neurite regeneration while brain-derived neurotrophic factor increased both the number of cells with neurites as well as the average neurite length. Our model can be applied to investigate factors involved in neuroregeneration of the human spinal cord and since adherent dissociated cell cultures are used, this system has significant potential as a screening platform for therapeutic agents to treat spinal cord injury.     

Effect of acidosis on IL-8 and MCP-1 during hypoxia and reoxygenation in human NT2-N neurons

Inflammation probably plays a significant role in perinatal brain injury. To study the contribution of locally produced cytokines, the effect on cell death of addition of IL-8 and MCP-1 or antibodies to these, and the impact of acidosis, human postmitotic NT2-N neurons were exposed to 3 h of hypoxia and glucose deprivation and reoxygenated for 21 h. After 3 h of hypoxia with neutral medium, IL-8 was significantly increased compared to controls (150 (100-250)% vs. 100 (85-115)%, p=0.023). After 21 h of neutral reoxygenation, both IL-8 (380 (110-710)% vs. 150 (85-260)%, p=0.041) and monocyte chemoattractant protein-1 (MCP-1) (650 (440-2000)% vs. 310 (230-340)%, p=0.007) were significantly increased compared to controls. After 3 h of hypoxia, both IL-8 (p=0.002) and MCP-1 (p=0.008) were significantly lower in cells with acidotic compared with cells with neutral medium. Acidosis during reoxygenation, however, significantly increased IL-8 release, whereas MCP-1 release was diminished. Similar effects of acidosis were seen in normoxic controls. The cells also secreted RANTES and IP-10, but not 8 other cytokines tested. We found no effect on cell death, measured by MTT assay, of addition of IL-8, MCP-1 or antibodies to these. We conclude that human NT2-N neurons release IL-8 and MCP-1 during 21 h of reoxygenation after 3 h of hypoxia. Acidosis led to a differential effect on IL-8 and MCP-1, with increased IL-8 and decreased MCP-1, both during reoxygenation and in normoxic controls. IL-8 and MCP-1 had no effect on cell death.     

Characterization of the domains of zRICH, a protein induced during optic nerve regeneration in zebrafish

Teleost fish show a remarkable capability of nerve regeneration in their CNS, while injuries to axon fibers in the CNS of mammals result in degeneration and loss of function. Understanding this difference has biomedical consequences to humans. Both extrinsic factors from the neuronal environment and intrinsic neuronal factors seem to play a role in successful nerve regeneration. Among the intrinsic factors, a number of proteins termed axonal growth associated proteins (GAPs) are strongly induced during axon regeneration. RICH proteins are axonal GAPs that show homology to mammalian myelin marker proteins termed CNPases. Sequence analysis distinguishes three domains in these proteins. In this report, mutant versions of zebrafish RICH proteins were generated to study the roles of the domains of the protein at biochemical and cellular levels. The central CNPase homology domain was sufficient for catalytic activity. The amino terminal acidic domain causes the anomalous electrophoretic migration observed for RICH proteins. The small C-terminal domain bears an isoprenylation motif and is necessary for the interaction of zRICH with cellular membranes. At the cellular level, expression of wild-type zRICH protein in PC12 cells did not induce neurite generation. Additionally, neither the expression of wild-type zRICH nor the expression of mutant versions of the protein interfered with the levels of differentiation of PC12 cells induced by nerve growth factor, suggesting that, at least in this model of neuronal differentiation, zRICH proteins do not participate in the process of generation of neurites.     

Identification and functional characterization of mouse TPO1 as a myelin membrane protein

TPO1 is a member of the AIGP family, a unique group of proteins that contains 11 putative transmembrane domains. Expression of the rat TPO1 gene is upregulated in cultured oligodendrocytes (OLs) during development from pro-oligodendroblasts to postmitotic OLs. However, the distribution of native TPO1 protein in cultured OLs and in the brain has not been elucidated. We investigated the distribution and cellular function of TPO1 in myelinating cells of the nervous system. In mice, TPO1 gene expression was detected in the central (CNS) and peripheral (PNS) nervous systems and was markedly upregulated at postnatal days 10-20, an early phase of myelination in the mouse brain. To investigate TPO1 localization, we generated affinity-purified antibodies to synthetic peptides derived from mouse TPO1. Immunohistochemical analysis showed that TPO1 was expressed in OLs and Schwann cells but not in neurons and astrocytes. Schwann cells from trembler mice, which lack PNS myelin, had significantly decreased TPO1 expression and an altered localization pattern, suggesting that TPO1 is a functional myelin membrane protein. In OL lineage cell cultures, TPO1 was detected in A2B5+ bipolar early progenitors, A2B5+ multipolar Pro-OLs, GalC+ immature OLs and MBP+ mature OLs. The subcellular localization of TPO1 in OL lineage cells was mapped to the GM130+ Golgi in cell bodies and Fyn+ cell processes and myelin-like sheets. Furthermore, TPO1 selectively colocalized with non-phosphorylated Fyn and promoted Fyn autophosphorylation in COS7 cells, suggesting that TPO1 may play a role in myelin formation via Fyn kinase activation in the PNS and CNS.     

Peripheral glial cell differentiation from neurospheres derived from adipose mesenchymal stem cells

Mesenchymal stem cells derived from bone marrow and adipose tissue are being considered for use in neural repair because they can differentiate after appropriate induction in culture into neurons and glia. The question we asked was if neurospheres could be harvested from adipose-derived stem cells and if they then could differentiate in culture to peripheral glial-like cells. Here, we demonstrate that adipose-derived mesenchymal stem cells can form nestin-positive non-adherent neurosphere cellular aggregates when cultured with basic fibroblast growth factor and epidermal growth factor. Dissociation of these neurospheres and removal of mitogens results in expression of the characteristic Schwann cell markers S100 and p75 nerve growth factor receptor and GFAP. The simultaneous expression of these glia markers are characteristic features of Schwann cells and olfactory ensheathing cells which have unique properties regarding remyelination and enhancement of axonal regeneration. When co-cultured with dorsal root ganglion neurons, the peripheral glial-like cells derived from adipose mesenchymal stem cells aligned with neuritis and stimulated neuritic outgrowth. These results indicate that neurospheres can be generated from adipose-derived mesenchymal stem cells, and upon mitogen withdrawal can differentiate into peripheral glial cells with neurotrophic effects.     

Metabolic properties of astrocytes differentiated from rat neurospheres

The metabolic properties of astroglia differentiated from neurospheres have not been fully assessed. In this study, the glycolytic and oxidative metabolism of glucose in astroglia differentiated from rat tertiary neurospheres (astroglia(NS)) was compared with that in astroglia prepared from the striata of embryonic day 16 rats (astroglia(ST)). In addition to the basal condition, we also investigated energy metabolism under Na+,K+-ATPase activation. Furthermore, the effects of glucose concentration in the culture medium were assessed. No significant differences in 2-deoxy-D-[1-(14)C]glucose phosphorylation were observed between astroglia(NS) and astrogliaST. The rates of L-[U-14C]lactate ([14C]lactate) and D-[U-14C]glucose ([14C]glucose) oxidation were 5.74+/-0.82 and 2.83+/-0.4 pmol/60 min/microg protein, respectively, in astrogliaNS grown in low glucose (2 mM) and 3.01+/-1.03 and 1.77+/-0.23 pmol/60 min/microg protein, respectively, in astrogliaNS grown in high glucose (22 mM). Neither the [14C]lactate nor the [14C]glucose oxidation rates in astrogliaNS were significantly different from those in astrogliaST. D-aspartate (500 microM) significantly increased the [14C]lactate and [14C]glucose oxidation rates by 127% and 62%, respectively, in astrogliaNS grown in low glucose and by 217% and 115%, respectively, in astroglia(NS) grown in high glucose. D-aspartate also increased the oxidation of [14C]lactate and [14C]glucose to 236% and 147% of the control values, respectively, in astrogliaST grown in low glucose and to 174% and 144%, respectively, in astrogliaST grown in high glucose. Rat astroglia differentiated from neurospheres might possess an equivalent capacity for utilizing energy substrates under both basal and activated conditions to that of astroglia prepared from striatum.