Primary astrocyte cultures—a key to astrocyte function

Morphological studies have established the ubiquitous nature of astrocytes in the CNS. Their processes surround capillaries and synapses, form the subpial and subependymal layers, and seemingly invest every neuronal surface not covered by other neuronal surfaces or oligodendroglial membranes. Although such interrelationships have long suggested that astrocytes may play many critical roles, there still remains relatively little experimental information on the functions and properties of these cells. About a decade ago it became evident that primary cultures from neonatal rodent brains can consist predominantly of normal astrocytes. Based on these findings there is now an increasing number of studies in which such primary cultures are being used to help unravel the continuing enigma of the properties and functions of astrocytes. Aspects of this work are reviewed in this article. Such work has already shown that astrocytes in primary culture exhibit the basic electrophysiological characteristics which had been the only functional property well established for these cells in situ. Further studies of the electrophysiological properties of these cells, which can be correlated with ion transport studies, are beginning to show that astrocytes may have more complex electrophysiological properties than had previously been supposed, as well as a number of important electrically silent ion fluxes. In addition, astrocytes in primary culture show uptake of and receptors for a number of transmitters, properties which have wide-ranging implications. Studies in culture also support work in vivo that astroglia may have an important role in neuronal development.     

A Modified In vitro Method to Obtain Pure Astrocyte Cultures Induced from Mouse Hippocampal Neural Stem Cells Using Clonal Expansion

The aim of the present study was to produce astrocyte cultures of high purity from mouse hippocampal neural stem cells and to compare their in vitro properties with those isolated from enriched mixed glial cultures prepared from mouse hippocampus, which are commonly contaminated by microglia. We produced primary cultures of newborn mouse hippocampal neural stem cells, which have the potential to differentiate into astrocytes, neurons, and oligodendrocytes. We produced monoclonal neural stem cell colonies by limiting dilution. We induced astrocyte differentiation by plating the colonies on poly-l-lysine and culturing them in induction medium consisting of minimum essential medium/F12 supplemented with 10% fetal bovine serum and 100 ng/ml ciliary neurotrophic factor. We then further purified the cells by differential adherence and shaking at a constant temperature, followed by a second round of limiting dilution. Immunocytochemistry for glial fibrillary acidic protein showed that our method yielded 99.4 ± 0.5% pure astrocytes, whereas traditionally enriched mixed glial cultures yielded 94.2 ± 2% pure astrocytes. Induced cells resembled primary astrocyte cultures in functional properties such as cell proliferation rates and lack of tumorigenicity and p53, and expression of epidermal growth factor receptor, bystin, and nitric oxygen synthase. Our novel method of culture and purification of neural stem cells can therefore be used routinely for the primary culture of highly purified astrocytes from mouse hippocampus.     

Substance P Receptors on O-2A Progenitor Cells and Type-2 Astrocytes In Vitro

Abstract: Bradykinin- and substance P (SP)-stimulated second messenger studies in isolated subsets of neuroglia showed bradykinin-stimulated synthesis of phospho- inositides (PI) in type-1 astrocytes and oligodendrocytes. SP-stimulated PI accumulation was restricted to oligoden- drocyte/type-2 astrocyte progenitor cells and type-2 astrocytes. These data were confirmed by analysis of calcium transients in single cells. In a regional study, SP-stimulated PI accumulation in primary astrocyte cultures was restricted to white matter. We conclude that regional heterogeneity in the expression of peptide receptors in cultures of primary astrocytes arises from a restricted distribution on subsets of macroglia. SP receptors restricted on cells of the oligodendrocyte/type-2 astrocyte type-2 lineage in vitro, coupled with in vivo observations by others, suggests that SP receptor expression is conserved on subsets of macroglia in vitro and possibly reactive astrocytes in vivo.     

Functional studies in cultured astrocytes

Studies using primary cultures of astrocytes have made essential contributions to the understanding of astrocytic functions and neuronal-astrocytic interactions. The purposes of this article are to (i) outline principles and methodologies used in the preparation of such cultures and caveats for the interpretation of the observations made; (ii) summarize astrocytic functions in turnover of the amino acid transmitters glutamate and gamma-aminobutyric acid (GABA), in energy metabolism and in Na+,K+-ATPase-catalyzed processes and emphasize the degree to which the observations have been confirmed in intact tissue; (iii) describe regulations of astrocytic functions by transmitters and by calcium channel activity; and (iv) indicate suggestions for future functional studies using astrocytes in primary cultures and emphasize that some of the conclusions about neuronal-astrocytic interactions reached on the basis of studies in cultured cells and confirmed in intact tissue may not yet have been completely integrated into general neuroscience knowledge.     

Maturation of astrocytes in vitro alters the extent and molecular basis of neurite outgrowth

In the developing mammalian central nervous system astrocytes have been proposed as an important substrate for axon growth. In the adult central nervous system following injury, astrocytes are a major component of the gliotic response which has been proposed to block axon growth. Experimental transplantation studies using cultured astrocytes have suggested that immature but not mature cultured astrocytes have the capacity to support axon outgrowth when transplanted into the adult rodent CNS. These observations suggest that astrocyte maturation is accompanied by changes in the functional capacity of these cells to support axon outgrowth. To determine whether this functional change reflects an intrisic astrocyte property, the extent and molecular bases of neurite outgrowth from embryonic rat cortical and chick retinal neurons on cultures of purified immature and mature astrocytes have been compared in vitro. The rate and extent of neurite outgrowth from both neuronal populations are consistently greater over the surface of immature than over the surface of mature astrocytes. Furthermore, antibodies to NCAM and G4/L1 significantly reduce neurite outgrowth on immature but not mature astrocytes, while antibodies to the integrin B1 receptor reduced outgrowth on both immature and, to a lesser extent, mature astrocytes. These results suggest that in vitro mature astrocytes have a reduced capacity and different molecular bases for supporting neurite outgrowth compared to immature astrocytes and are consistent with the proposal that functional changes during astrocyte maturation may partially contribute to regulating axon growth in the mammalian CNS.     

Differences in nuclear proteins of neurons, astrocytes and C-6 glioma cells

In an effort to identify cell type specific proteins from brain, we have compared proteins of the cell nucleus from two brain cell types. Using a bulk isolation procedure, we fractionated neurons and astrocytes from adult rat brain. In addition, primary cultures of astrocytes were prepared from one-day old rats. Nuclei from these cells and C-6 glioma cell cultures were isolated and the resulting proteins subjected to two-dimensional gel electrophoresis. Several proteins specific for each cell type were found. While many similarities between bulk brain astrocyte preparations and cultured astrocytes were found, less than pure bulk astrocytes from brain were found to be most similar to those of neurons and not to those from primary cell culture.

The nuclear protein profile of cultured astrocytes differed significantly from that of C-6 cells, indicating the utility of two-dimensional gel analysis for detecting major cell type differences in uniform populations of cells.     

Cellular localization and functional expression of P-glycoprotein in rat astrocyte cultures

We investigated the cellular/subcellular localization and functional expression of P-glycoprotein, an ATP-dependent membrane-associated efflux transporter, in astrocytes, a brain parenchyma compartment that is poorly characterized for the expression of membrane drug transporters. Analyses were carried out on primary cultures of astrocytes isolated from the cerebral cortex of neonatal Wistar rats and CTX TNA2, an immortalized rat astrocyte cell line. Both cell cultures display morphological features typical of type I astrocytes. RT-PCR analysis revealed mdr1a and mdr1b mRNA in primary cultures of astrocytes and in CTX TNA2 cells. Western blot analysis using the P-glycoprotein monoclonal C219 antibody detected a single band of appropriate size in both cell systems. Immunocytochemical analysis using the monoclonal antibodies C219 and MRK16 labeled P-glycoprotein along the plasma membrane, caveolae, coated vesicles and nuclear envelope. Immunoprecipitation studies using the caveolin-1 polyclonal H-97 antibody demonstrated that P-glycoprotein is physically associated with caveolin-1 in both cell culture systems. The accumulation of [(3)H]digoxin (an established P-glycoprotein substrate) by the astrocyte cultures was significantly enhanced in the presence of standard P-glycoprotein inhibitors and an ATP depleting agent. These results demonstrate the cellular/subcellular location and functional expression of P-glycoprotein in rat astrocytes and suggest that this glial compartment may play an important role in the regulation of drug transport in the CNS.     

GFAP-Deficient Astrocytes Are Capable of Stellationin VitroWhen Cocultured with Neurons and Exhibit a Reduced Amount of Intermediate Filaments and an Increased Cell Saturation Density

Glial fibrillary acidic protein (GFAP) is an intermediate filament protein predominantly expressed in cells of astroglial origin. To allow for the study of the biological functions of GFAP we have previously generated GFAP-negative mice by gene targeting [Peknyet al.(1995)EMBO J.14, 1590–1598]. Astrocytes in culture, similar to reactive astrocytesin vivo,express three intermediate filament proteins: GFAP, vimentin, and nestin. Using primary astrocyte-enriched cultures from GFAP-negative mice, we now report on the effect of GFAP absence on (i) the synthesis of other intermediate filament proteins in astrocytes, (ii) intermediate filament formation, (iii) astrocyte process formation (stellation) in response to neurons in mixed cerebellar astrocyte/neuron cultures, and (iv) saturation cell densityin vitro.GFAP−/− astrocytes were found to produce both nestin and vimentin. At the ultrastructural level, the amount of intermediate filaments as revealed by transmission electron microscopy was reduced in GFAP−/− astrocytes compared to that in GFAP+/+ astrocytes. GFAP−/− astrocytes retained the ability to form processes in response to neurons in mixed astrocyte/neuron cultures from the cerebellum. GFAP−/− astrocyte-enriched primary cultures exhibited an increased final cell saturation density. The latter leads us to speculate that the loss of GFAP expression observed focally in a proportion of human malignant gliomas may reflect tumor progression toward a more rapidly growing and malignant phenotype.     

Transplantation of specific human astrocytes promotes functional recovery after spinal cord injury

Repairing trauma to the central nervous system by replacement of glial support cells is an increasingly attractive therapeutic strategy. We have focused on the less-studied replacement of astrocytes, the major support cell in the central nervous system, by generating astrocytes from embryonic human glial precursor cells using two different astrocyte differentiation inducing factors. The resulting astrocytes differed in expression of multiple proteins thought to either promote or inhibit central nervous system homeostasis and regeneration. When transplanted into acute transection injuries of the adult rat spinal cord, astrocytes generated by exposing human glial precursor cells to bone morphogenetic protein promoted significant recovery of volitional foot placement, axonal growth and notably robust increases in neuronal survival in multiple spinal cord laminae. In marked contrast, human glial precursor cells and astrocytes generated from these cells by exposure to ciliary neurotrophic factor both failed to promote significant behavioral recovery or similarly robust neuronal survival and support of axon growth at sites of injury. Our studies thus demonstrate functional differences between human astrocyte populations and suggest that pre-differentiation of precursor cells into a specific astrocyte subtype is required to optimize astrocyte replacement therapies. To our knowledge, this study is the first to show functional differences in ability to promote repair of the injured adult central nervous system between two distinct subtypes of human astrocytes derived from a common fetal glial precursor population. These findings are consistent with our previous studies of transplanting specific subtypes of rodent glial precursor derived astrocytes into sites of spinal cord injury, and indicate a remarkable conservation from rat to human of functional differences between astrocyte subtypes. In addition, our studies provide a specific population of human astrocytes that appears to be particularly suitable for further development towards clinical application in treating the traumatically injured or diseased human central nervous system.     

Macroglial cell development in embryonic rat brain: studies using monoclonal antibodies, fluorescence activated cell sorting, and cell culture

Astrocytes, ependymal cells, and oligodendrocytes have been shown to develop on the same schedule in dissociated cell cultures of early embryonic rat brain as in vivo. Subsequent studies showed that there are two major types of astrocyte (type-1 and type-2), which, in cultures of perinatal optic nerve, develop as two distinct lineages. In such cultures, type-2 astrocytes and oligodendrocytes develop from the same, bipotential, (O-2A) progenitor cells, which differentiate into type-2 astrocytes in 10% fetal calf serum (FCS) and into oligodendrocytes in less than or equal to 0.5% FCS. In light of these findings, we now have extended our studies on macroglial cell development in rat brain and show the following: (i) The first astrocytes to develop have a type-1 phenotype, while astrocytes with a type-2 phenotype do not develop until almost 2 weeks later, just as in the optic nerve. (ii) Most importantly, type-2 astrocytes, like the other macroglial cells, develop on the same schedule in cultures of early embryonic (less than or equal to E15) brain as they do in vivo. (iii) By contrast, both oligodendrocytes and type-2 astrocytes develop prematurely in cultures of E17 brain, and FCS influences this development in the same way it does in perinatal optic nerve cultures. (iv) Type-2 astrocyte precursors are labeled by the A2B5 monoclonal antibody, as shown previously for oligodendrocyte precursors in brain and for O-2A progenitor cells in optic nerve. Taken together with our previous findings, these results suggest that oligodendrocytes and type-2 astrocytes in brain develop from bipotential O-2A progenitor cells, whose choice of developmental pathway and timing of differentiation depend on mechanisms that operate independently of brain morphogenesis.     

High extracellular potassium modulates nitric oxide synthase expression in human astrocytes

Inducible nitric oxide synthase (iNOS) is a molecule of great interest, given the numerous biological activities of nitric oxide and the documented expression of iNOS in several CNS pathologies. There also appears to be species-dependent regulation of iNOS expression as well as CNS-specific regulation. In this study, we have examined cultures of cytokine-activated primary human astrocytes as a model system with which to study the mechanisms of iNOS regulation in human CNS. As one of the major functions of astrocytes is spatial buffering of K+ ion, we examined the effect of high extracellular KCI on astrocyte iNOS expression. The results demonstrate that KCI at 25-75 mM potently inhibits astrocyte nitrite production stimulated by interleukin-1 (IL-1)/interferon-gamma (IFNgamma). In addition, several potassium channel inhibitors such as CsCl, tetraethylammonium, and 4-aminopyridine as well as nigericin inhibited astrocyte iNOS expression induced by IL-1/IFNgamma. These results demonstrate a novel role for astrocyte potassium channel activity in modulation of astrocyte function. They further suggest neural-specific mechanisms for glial iNOS regulation.     

Iron accumulation, iron-mediated toxicity and altered levels of ferritin and transferrin receptor in cultured astrocytes during incubation with ferric ammonium citrate

The cellular uptake and storage of iron have to be tightly regulated in order to provide iron for essential cellular functions while preventing the iron-catalysed generation of reactive oxygen species (ROS). In contrast to cells in other organs, little is known about the regulation of iron metabolism in brain cells, particularly in astrocytes. To investigate the regulation of iron metabolism in astrocytes we have used primary astrocyte cultures from the brains of newborn rats. After application of ferric ammonium citrate (FAC), cultured astrocytes accumulated iron in a time- (0-48 h) and concentration-dependent (0.01-1 mm) manner. This accumulation was prevented if FAC was applied in combination with the iron-chelator deferoxamine (DFX). Application of FAC to astrocyte cultures caused a strong increase in the cellular content of the iron storage protein ferritin and a decrease in the amount of transferrin receptor (TfR), which is involved in the transferrin-mediated uptake of iron into cells. In contrast, application of DFX strongly increased the level of TfR. Both up-regulation of ferritin content by iron application and up-regulation of TfR content by DFX were prevented by the protein synthesis inhibitor cycloheximide (CHX). During incubation of astrocytes with FAC, a mild and transient increase in the extracellular activity of the cytosolic enzyme lactate dehydrogenase and in the concentration of intracellular ROS was observed. In contrast, prevention of protein synthesis by CHX during incubation with FAC resulted in significantly more cell loss and a persistent and intense increase in the production of intracellular ROS. These results demonstrate that both iron accumulation and deprivation modulate the synthesis of ferritin and TfR in astrocytes and that protein synthesis is required to prevent iron-mediated toxicity in astrocytes.     

Inhibition of mitochondrial function in astrocytes: implications for neuroprotection

Much evidence suggests that astrocytes protect neurons against ischemic injury. Although astrocytes are more resistant to some insults than neurons, few studies offer insight into the real time changes of astrocytic protective functions with stress. Mitochondria are one of the primary targets of ischemic injury in astrocytes. We investigated the time course of changes in astrocytic ATP levels, plasma membrane potential, and glutamate uptake, a key protective function, induced by mitochondrial inhibition. Our results show that significant functional change precedes reduction in astrocytic viability with mitochondrial inhibition. Using the mitochondrial inhibitor fluorocitrate (FC, 0.25 mmol/L) that is preferentially taken by astrocytes we found that inhibition of astrocyte mitochondria increased vulnerability of co-cultured neurons to glutamate toxicity. In our studies, the rates of FC-induced astrocytic mitochondrial depolarization were accelerated in mixed astrocyte/neuron cultures. We hypothesized that the more rapid mitochondrial depolarization was promoted by an additional energetic demand imposed be the co-cultured neurons. To test this hypothesis, we exposed pure astrocytic cultures to 0.01-1 mmol/L aspartate as a metabolic load. Aspartate application accelerated the rates of FC-induced mitochondrial depolarization, and, at 1 mmol/L, induced astrocytic death, suggesting that strong energetic demands during ischemia can compromise astrocytic function and viability.     

Immunocytochemical and Biochemical Analysis of Carbonic Anhydrase in Primary Astrocyte Cultures from Rat Brain

Carbonic anhydrase (CA) was studied in primary monolayer cultures from neonatal rat cerebral hemispheres with both immunocytochemical and biochemical techniques. In such cultures, which consist predominantly of astrocytes, immunocytochemical staining for CA using antibody raised against the type II enzyme from rat erythrocytes resulted in positive staining of the flat, glial fibrillary acidic protein-positive, astrocytic monolayer. Smaller, process-bearing, round cells that grew on top of the astrocytes stained intensely for CA. We estimated that these cells represented 1% or less of the total cells in the cultures, and they have been identified by others as oligodendrocytes. The intensity of the staining of astrocytes for CA could be increased to that observed in oligodendrocytes when the astrocytes were made to round up and form processes by treatment with 2',3'-dibutyryl cyclic AMP. Enzymatic assays showed that CA activity of the cultures after 3 weeks of growth was 2.5- to 5-fold less than that found for cerebral homogenates from perfused 3-week-old rat brains. However, both activities were totally inhibited by acetazolamide with an I50 of 10(-8) M, confirming that both rat brain and the astrocyte cultures possess the high-activity type II enzyme. CA-II activity was unaffected by treatment of the cultures with a method reported to remove oligodendrocytes. Thus, the immunocytochemical and biochemical studies reported here demonstrate that astroglial cells in primary cultures from neonatal rat brain contain CA-II.     

Role of Rho GTPase in astrocyte morphology and migratory response during in vitro wound healing

Small Rho GTPases are key regulators of the cytoskeleton in a great variety of cells. Rho function mediates morphological changes as well as locomotor activity. Using astrocyte cultures established from neonatal mice we investigated the role of Rho in process formation during astrocyte stellation. Using a scratch-wound model, we examined the impact of Rho on a variety of morphological and functional variables such as stellation and migratory activity during wound healing. C3 proteins are widely used to study cellular Rho functions. In addition, C3 derived from Clostridium botulinum (C3bot) is considered selectively to promote neuronal regeneration. Because the latter requires a balanced activity of neurones and glial cells, the effects of C3 protein on glial cells such as astrocytes have to be considered carefully. Low nanomolar concentrations of C3 proteins significantly promoted process outgrowth and increased process branching. Besides enzymatic inactivation of Rho by ADP-ribosylation, changes in protein levels of the various Rho GTPases may also contribute to the observed effects. Furthermore, incubation of scratch-wounded astrocyte cultures with C3bot accelerated wound healing. By inhibiting the Rho downstream effector ROCK with the selective inhibitor Y27632 we were able to demonstrate that the accelerated wound closure resulted from both enhanced polarized process formation and increased migratory activity of astrocytes into the lesion site. These results suggest that Rho negatively regulates astrocytic process growth and migratory responses after injury and that its inactivation by C3bot in nanomolar concentrations promotes astrocyte migration.     

Type-2 astrocyte development in rat brain cultures is initiated by a CNTF-like protein produced by type-1 astrocytes

O-2A progenitor cells are bipotential glial precursors that give rise to both oligodendrocytes and type-2 astrocytes on a precise schedule in the rat CNS. Studies in culture suggest that oligodendrocyte differentiation occurs constitutively, while type-2 astrocyte differentiation requires an exogenous inducer such as fetal calf serum. Here we describe a rat brain cell culture system in which type-2 astrocytes develop on schedule in the absence of exogenous inducers. Coincident with type-2-astrocyte development, the cultures produce an approximately 20 kd type-2-astrocyte-inducing factor(s). Purified cultures of type-1 astrocytes can produce a similar factor(s). Under conditions where they produce type-2-astrocyte-inducing factor(s), both brain and type-1 astrocyte cultures produce a factor(s) with ciliary neurotrophic (CNTF)-like activity. Purified CNTF, like the inducers from brain and type-1 astrocyte cultures, prematurely induces type-2 astrocyte differentiation in brain cultures. These findings suggest that type-2 astrocyte development is initiated by a CNTF-like protein produced by type-1 astrocytes.     

A novel human astrocyte cell line (A735) with astrocyte-specific neurotransmitter function

Summary Studies of brain cell function and physiology are hampered by the limited availability of imortal human brain-derived cell lines, as a result of the technical difficulties encountered in establishing immortal human cells in culture. In this study, we demonstrate the application of recombinant DNA vectors expressing SV40 T antigen for the development of immortal human cell cultures, with morphological, growth, and functional properties of astrocytes. Primary human astrocytes were transfected with the SV40 T antigen expression vectors, pSV3neo or p735.6, and cultures were established with an extended lifespan. One of these cultures gave rise to an immortal cell line, designated A735. All the human SV40-derived lines retained morphological features and growth properties of type 1 astrocytes. Immunohistochemical studies and Western blot analysis of the intermediate filament proteins and glutamine synthetase demonstrated a differentiated but immature astrocyte phenotype. Transport of γ-amino butyric acid and glutamate were examined and found to be by a glial-specific mechanism, consistent with the cell lines’ retaining aspects of normal glial function. We conclude that methods based on the use of SV40 T antigen can successfully immortalize human astrocytes, retaining key astrocyte functions, but T antigen-induced proliferation appeared to interfere with expression of glial fibrillary acidic protein. We believe A735 is the first documented nontumor-derived human glial cell line which is immortal.