Proliferative activity and characteristics of immunocytochemically identified oligodendrocytes in embryonic mouse brain cell cultures

Effect of Schwann cell transplantation combined with electroacupuncture on axonal regeneration and remyelination in rats with spinal cord injury

Axonal impairment and demyelination after compressed spinal cord injury lead to serious neurological dysfunction. Increasing studies have suggested that Schwann cells (SCs) transplantation is a reliable, effective, and promising method for treating spinal cord injury. However, single SCs transplantation is insufficient to promote the full recovery of neurological function. Additional approaches are required to support SCs transplantation as a treatment for spinal cord injury. In the study, we investigated whether the combination of electroacupuncture (EA) and SCs transplantation was a reliable intervention for spinal cord injury. We found that rats in the combination group had significantly higher functional locomotor scores than those received single treatment. By immunostaining, we found EA can not only improve survival and proliferation of transplanted SCs but also inhibit SC apoptosis and block the formation of an astrocytic scar. Additionally, EA promoted regenerated axons extending "bullet-shaped" growth cones into the lesion. Remarkably, EA can modify astrogliosis to promote axonal regeneration following SCs transplantation through inducing extension of astrocytic processes in the SCs graft interface. More importantly, the combination of SCs engraftment and EA can enhance corticospinal-tract axonal regeneration and remyelination after spinal cord injury through up-regulating neuregulin 1 type III in SCs and its downstream signaling mediators. Thus, it is concluded that SCs effectively promote axonal recovery after spinal cord injury when combined with EA stimulation. The experimental results have reinforced the theoretical basis of EA for its clinical efficacy in patients with spinal cord injury and merited further investigation for potential clinical application.

Protective Effect of Electroacupuncture on Neural Myelin Sheaths is Mediated via Promotion of Oligodendrocyte Proliferation and Inhibition of Oligodendrocyte Death After Compressed Spinal Cord Injury

Electroacupuncture (EA) has been used worldwide to treat demyelinating diseases, but its therapeutic mechanism is poorly understood. In this study, a custom-designed model of compressed spinal cord injury (CSCI) was used to induce demyelination. Zusanli (ST36) and Taixi (KI3) acupoints of adult rats were stimulated by EA to demonstrate its protective effect. At 14 days after EA, both locomotor skills and ultrastructural features of myelin sheath were significantly improved. Phenotypes of proliferating cells were identified by double immunolabeling of 5-ethynyl-2'-deoxyuridine with antibodies to cell markers: NG2 [oligodendrocyte precursor cell (OPC) marker], 2',3'-cyclic-nucleotide 3'-phosphodiesterase (CNPase) (oligodendrocyte marker), and glial fibrillary acidic protein (GFAP) (astrocyte marker). EA enhanced the proliferation of OPCs and CNPase, as well as the differentiation of OPCs by promoting Olig2 (the basic helix-loop-helix protein) and attenuating Id2 (the inhibitor of DNA binding 2). EA could also improve myelin basic protein (MBP) and protect existing oligodendrocytes from apoptosis by inhibiting caspase-12 (a representative of endoplasmic reticulum stress) and cytochrome c (an apoptotic factor and hallmark of mitochondria). Therefore, our results indicate that the protective effect of EA on neural myelin sheaths is mediated via promotion of oligodendrocyte proliferation and inhibition of oligodendrocyte death after CSCI.

Demyelination initiated by oligodendrocyte apoptosis through enhancing endoplasmic reticulum-mitochondria interactions and Id2 expression after compressed spinal cord injury in rats

BACKGROUND

Demyelination is one of the most important pathological factors of spinal cord injury. Oligodendrocyte apoptosis is involved in triggering demyelination. However, fewer reports on pathological changes and mechanism of demyelination have been presented from compressed spinal cord injury (CSCI). The relative effect of oligodendrocyte apoptosis on CSCI-induced demyelination and the mechanism of apoptosis remain unclear.

AIMS

In this study, a custom-designed model of CSCI was used to determine whether or not demyelination and oligodendrocyte apoptosis occur after CSCI. The pathological changes in axonal myelinated fibers were investigated by osmic acid staining and transmission electron microscopy. Myelin basic protein (MBP), which is used in myelin formation in the central nervous system, was detected by immunofluorescence and Western blot assays. Oligodendrocyte apoptosis was revealed by in situ terminal-deoxytransferase-mediated dUTP nick-end labeling. To analyze the mechanism of oligodendrocyte apoptosis, we detected caspase-12 [a representative of endoplasmic reticulum (ER) stress], cytochrome c (an apoptotic factor and hallmark of mitochondria), and inhibitor of DNA binding 2 (Id2, an oligodendrocyte lineage gene) by immunofluorescence and Western blot assays.

RESULTS

The custom-designed model of CSCI was successfully established. The rats were spastic, paralyzed, and incontinent. The Basso, Beattie, and Bresnahan (BBB) locomotor rating scale scores were decreased as time passed. The compressed spinal cord slices were ischemic. Myelin sheaths became swollen and degenerative; these sheaths were broken down as time passed after CSCI. MBP expression was downregulated after CSCI and consistent with the degree of demyelination. Oligodendrocyte apoptosis occurred at 1 day after CSCI and increased as caspase-12 expression was enhanced and cytochrome c was released. Id2 was distributed widely in the white matter. Id2 expression increased with time after CSCI.

CONCLUSION

Demyelination occurred after CSCI and might be partly caused by oligodendrocyte apoptosis, which was positively correlated with ER-mitochondria interactions and enhanced Id2 expression after CSCI in rats.

Problems encountered when immunocytochemistry is used for quantitative glial cell identification in autoradiographic studies of cell proliferation in the brain of the unlesioned adult mouse

We have used sections of adult mouse brain to determine whether antibodies specific for oligodendroglia (anti-carbonic anhydrase II, CA II; anti-galactocerebroside, GC; anti-myelin basic protein, MBP) and astroglia (anti-glial fibrillary acidic protein, GFAP; anti-S 100 protein) are suitable for quantitative studies of the proliferation and subsequent differentiation of these cells. Unlesioned adult mice received a single injection of 3H-thymidine (TdR) and were killed between 1 h and 70 days later. Quantitative evaluations of autoradiographs of 2-microns-thick serial sections stained immunocytochemically with the antibodies mentioned above or with Richardson's method for histological control led to the following conclusions. Anti-GC and anti-MBP stained only the oligodendrocytic processes and, thus, cannot be used in well-myelinated brain areas. Anti-CA II stained only a portion of the differentiated oligodendrocytes, but no proliferating cells. Anti-S 100 protein recognized all the astrocytes, but also many (interfascicular) oligodendrocytes. Anti-GFAP stained only a few astrocytes in the unlesioned mouse; all astrocytes may become GFAP-immunopositive only after wounding the brain. Thus, in contrast to in vitro studies, immunocytochemical studies with these antibodies on sections of adult animals cannot be recommended for the quantitative analysis of cell proliferation. In addition, our results show that differentiated glial cells proliferate in adult mice. Astro- and oligodendrocytes divide with the same cell cycle parameters and mode of proliferation up to about 1 month after 3H-TdR injection. In contrast to oligodendrocytes, some astrocytes might re-enter the cycle after a few weeks of quiescence.

Differences in neuronal and glial cell phenotypic expression in neuron-glia cocultures: Influence of glia-conditioned media and living glial cell substrata

Neuron-glia cocultures were prepared using, as a source for glial cells, either C6 glia (2B clone) of early (2B23) or late (2B111) passages or advanced passages of glial cells derived from primary cultures prepared from aged mouse cerebral hemispheres (MACH). Six-day-old chick embryo cerebral hemispheres (E6CH) were the source of neuron-enriched cultures. Glutamine synthetase (GS) activity was used as a marker for astrocytes and 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNP) activity was used as a marker for oligodendrocytes. GS activity was markedly enhanced in cocultures of E6CH neurons and 2B23 glioblastic cells, whereas GS activity was reduced in cocultures of E6CH neurons and 2B111 astrocytic glia. In contrast, CNP activity was enhanced in cocultures of C6 glial cells with E6CH neurons. Glial cells from aged mouse brain did not respond to coculturing with E6CH neurons. It appears from these findings that neuronal input enhances the differentiation of glioblastic cells to either astrocytic or oligodendrocytic expression, whereas it decreases the activity of committed astrocytes. In contrast, glial cells from aged mouse brain do not respond to neuronal input. Choline acetyltransferase (ChAT) activity, a marker for cholinergic neurons, was enhanced only when E6CH cultures were grown in conditioned medium (CM) from 2B23 glioblastic cells. In contrast, ChAT activity was markedly diminished when E6CH neurons were cocultured with MACH glial cells but not when grown in CM from MACH glial cells. Thus, humoral factors from immature glial cells appear to enhance cholinergic neuronal phenotypic expression whereas cell-cell membrane contacts with aged glial cells diminish cholinergic phenotypic expression. The findings present supportive evidence that neuron-glia interrelationships are age dependent.

Radiation sensitivity of glial cells in primary culture

Primary cultures from newborn mouse brain were subjected to ionizing radiation to determine the sensitivity of galactocerebroside-positive oligodendrocytes and A2B5-positive progenitor cells during development. The radiosensitivity or D0 of the 2 cell populations was determined by measuring the fraction of surviving cells after various doses of x-rays. When the cultures were exposed to a single dose of x-rays at 6 days, oligodendrocytes showed a D0 of 1.4 Gy, and A2B5-positive cells a D0 of 4.5 Gy. When the cultures were exposed to a single dose of x-rays at 12 days, oligodendrocytes showed a D0 of 4.4 Gy, indicating that they have become more radioresistant. Cultures exposed to a dose of 1.5 Gy and monitored from 9 h to 2 weeks after irradiation showed a reduced but constant number of galactocerebroside-positive cells at all time points. Since galactocerebroside-positive oligodendrocytes are non-dividing or slowly dividing cells, the radiosensitivity of young oligodendrocytes was attributed to interphase cell death. These results indicate that young differentiated oligodendrocytes are more radiosensitive than other glial cell types, and that there is no significant replacement of lost oligodendrocytes either through proliferation or through differentiation of progenitors after irradiation in the culture system.

Theiler's virus-associated antigens on the surfaces of cultured glial cells

Infection of the central nervous system by Theiler's murine encephalomyelitis virus (TMEV), a picornavirus, produces chronic demyelinating disease in susceptible mice. In this immunoelectron microscopic study of TMEV infection of neonatal mouse brain cells in culture, TMEV antigen was found on the surfaces of infected oligodendrocytes and astrocytes by labeling with hyperimmune serum from TMEV-infected mice or with rabbit antiserum to purified inactivated DA strain TMEV. Brain-derived macrophages had no TMEV-specific antigen on their surfaces and were not able to maintain productive TMEV infection, even though TMEV antigen was present in the cytoplasm. The presence of TMEV antigens on the surfaces of oligodendrocytes (myelin-producing cells) was unexpected because picornaviruses are nonenveloped viruses and do not bud from cell surfaces. The finding is consistent with the hypothesis that demyelination follows damage of infected oligodendrocytes by immune cells or immunoglobulins that recognize surface virus antigen.

Effects of trembler mouse serum and laminin on oligodendrocyte proliferation and differentiation in culture

Oligodendrocytes in primary cultures derived from rat embryo spinal cord were examined in control medium and in Trembler mouse serum (TMS)-supplemented medium. The oligodendrocytes were identified on the basis of the synthesis and surface expression of galactocerebrosides revealed by a monoclonal antibody directed against this component. We noticed two effects of TMS compared to control mouse serum. First, our results revealed that in TMS medium there is a mitogenic response of galactocerebroside (GalC)-positive cells. Second, in the presence of TMS, oligodendrocytes do not develop processes as they do in the presence of normal mouse serum. When laminin, a basal lamina component was added to TMS medium, GalC+ oligodendrocytes decreased in number and differentiation was normal. Possible explanations of the effects of TMS and laminin on oligodendrocyte proliferation and differentiation are discussed.

Emergence of three myelin proteins in oligodendrocytes cultured without neurons

Oligodendrocytes, the myelin-forming cells of the central nervous system, were cultured from newborn rat brain and optic nerve to allow us to analyze whether two transmembranous myelin proteins, myelin-associated glycoprotein (MAG) and proteolipid protein (PLP), were expressed together with myelin basic protein (MBP) in defined medium with low serum and in the absence of neurons. Using double label immunofluorescence, we investigated when and where these three myelin proteins appeared in cells expressing galactocerebroside (GC), a specific marker for the oligodendrocyte membrane. We found that a proportion of oligodendrocytes derived from brain and optic nerve invariably express MBP, MAG, and PLP about a week after the emergence of GC, which occurs around birth. In brain-derived oligodendrocytes, MBP and MAG first emerge between the fifth and the seventh day after birth, followed by PLP 1 to 2 d later. All three proteins were confined to the cell body at that time, although an extensive network of GC positive processes had already developed. Each protein shows a specific cytoplasmic localization: diffuse for MBP, mostly perinuclear for MAG, and particulate for PLP. Interestingly, MAG, which may be involved in glial-axon interactions, is the first myelin protein detected in the processes at approximately 10 d after birth. MBP and PLP are only seen in these locations after 15 d. All GC-positive cells express the three myelin proteins by day 19. Simultaneously, numerous membrane and myelin whorls accumulate along the oligodendrocyte surface. The sequential emergence, cytoplasmic location, and peak of expression of these three myelin proteins in vitro follow a pattern similar to that described in vivo and, therefore, are independent of continuous neuronal influences. Such cultures provide a convenient system to study factors regulating expression of myelin proteins.

Theiler's virus in brain cell cultures: lysis of neurons and oligodendrocytes and persistence in astrocytes and macrophages

The mechanisms of persistence and of demyelination in Theiler's virus (TV)-induced chronic neurologic disease (a murine model for multiple sclerosis) are, as yet, disputed. We investigated the tropism and persistence of TV in brain cell culture to better understand the pathogenesis of this disease. Using anti-genic markers to identify specific cells in culture, we have demonstrated that TV infects, lytically, neurons and oligodendrocytes and persistently astrocytes and macrophages. These results suggest that host cell factors play a key role in the mechanism of demyelination and the persistence of TV in the nervous system.

Synthesis of a myelin-like membrane by oligodendrocytes in culture

We have prepared highly purified cultures of rat oligodendrocytes by a modification of the procedure of McCarthy and de Vellis [1980]. By utilizing a substratum derived from lysed glia and a calf serum-containing medium with a high concentration of transferrin, the oligodendrocyte cultures display a high degree of purity, the ability to survive several months of culture, and a striking ability to produce a myelin-like membrane. We have examined the production of this myelin-like membrane using immunocytochemical and biochemical probes as well as an extensive morphological examination at the electron microscopic level. The membrane appears to be produced in a similar developmental pattern to that observed in vivo and it has the structural characteristics of loosely packed central nervous system myelin.

A modification of the hemolytic plaque test to investigate simultaneously secretion and morphological characteristics of individual cells

A simple modification of the hemolytic plaque test is proposed which provides a morpho-functional approach to the study of secreting cells. The experimental procedure described here, an 'open system' with glass coverslips, involves the association of the reverse hemolytic plaque test performed in liquid medium with Feulgen's reaction used to reveal the nuclear characteristics of the secreting cells. A monolayer cell carpet, prepared with hepatocytes and sheep red blood cells coated with specific antibodies to transferrin, was attached to glass coverslips coated with 2 substrates, collagen and poly-L-lysine. Incubation was performed in a routine liquid culture medium. Under the conditions reported here to obtain an optimal attachment of the cells to the substrates, it was possible to stain hepatocytes after the formation of hemolytic plaques, whilst maintaining the monolayer cell structure intact. This technical modification should be of value in establishing correlations between secretory activity and cellular characteristics.

Cell and tissue culture of the central nervous system: recent developments and current applications

A survey of methods for cell and tissue culture of the central nervous system (CNS) is given. This includes a brief historical outline and description of methods in current use. Recent methodological improvements are emphasized, and it is shown how these are applied in modern neurobiological research. Both monolayer cell cultures and three-dimensional organ culture systems are widely used, each having advantages and limitations. In recent years, there has been considerable improvement of culture for prolonged periods in chemically defined media. Brain tissue from a wide spectrum of species have been used, including different types of human brain cells which can be propagated for several months. At present, these culture systems are employed for dynamic studies of the developing, the adult and ageing brain. It is possible to select neurons and the different classes of glial cells for culture purposes. Cell culture of the CNS has given new insights into the biology of brain tumours. Culture systems for experimental tumour therapy in vitro are also available. Recently, it has been shown that organ cultures of brain tissue can be used as targets for invasive glioma cells, enabling a direct study of the interactions between tumour cells and normal tissue to take place.

Myelin basic protein stimulates the proliferation of astrocytes: possible explanation for multiple sclerosis plaque formation

In dissociated mouse brain cell cultures we frequently observed an association between myelin basic protein (MBP) positive oligodendrocytes and proliferating astrocytes. When MBP was added in a purified form to the culture medium, it greatly stimulated the proliferation of astrocytes, while other proteins tested did not. This finding allows us to speculate that the gliosis observed in demyelinating diseases or/and in central nervous system (CNS) injury would be due to the mitogenic effect exerted by MBP or its fragments when there is myelin breakdown.

Characterization of cultured rat oligodendrocytes proliferating in a serum-free, chemically defined medium

A serumless, chemically defined medium has been developed for the culture of oligodendrocytes isolated from primary neonatal rat cerebral cultures. Combined together, insulin, transferrin, and fibroblast growth factor synergistically induced an essentially homogenous population (95-98%) of cells expressing glycerol-3-phosphate dehydrogenase (EC 1.1.1.8) activity to undergo cell division. Proliferating cels were characterized by several criteria: (i) ultrastructural analysis by transmission electron microscopy identified the cell type as an oligodendrocyte; (ii) biochemical assays showed expression of three oligodendrocyte biochemical markers, induction of both glycerol phosphate dehydrogenase and lactate dehydrogenase (EC 1.1.1.27), and presence of 2',3'-cyclic nucleotide 3'-phosphodiesterase (EC 3.1.4.37); and (iii) immunocytochemical staining showed cultures to be 95-98% positive for glycerol phosphate dehydrogenase, 90% for myelin basic protein, 60-70% for galactocerebroside, and 70% for A2B5. Few cells (less than 5%) stained positive for glial fibrillary acidic protein, and none were detected positive for fibronectin.

Precursor cells of oligodendrocytes in rat primary cultures

In monolayer primary cultures of brain from newborn rats, which contain astrocytes and oligodendrocytes, a new morphological cell type (flat black cells) was observed. Microphotographs of different areas of the monolayer, taken every 30 min, showed that these flat black cells can divide and that they undergo morphological transformation in vitro. They give rise to oligodendrocytes which were identified by their characteristics morphology but also by their content of W1 Wolfgram protein. These findings suggest that the flat black cells are precursors for oligodendrocytes, in culture.

The mitotic history and radiosensitivity of developing oligodendrocytes in vitro

By use of pulse-chase exposure of dissociated cells of rat fetal spinal cord or brain to [3H]thymidine (TdR) and unlabeled TdR it has been shown that oligodendroglial precursors which do not express galactocerebroside (GalC) divide first and later differentiate to express GalC. The rate of proliferation of more mature GalC+ oligodendrocytes is considerably lower than that of their GalC- precursors. It has been found that oligodendrocyte precursor cells are extremely sensitive to [3H]TdR irradiation. Exposure to as little as 0.03 microCi/ml for 24 hr proved to be harmful, particularly during a critical period before birth. This critical period corresponded to the peak of division of oligodendrocyte precursor cells.