Here we provide a protocol for culturing rat cortical neurons in the presence of a glial feeder layer. The cultured neurons establish polarity and create synapses, and can be separated from the glia for use in various applications, such as electrophysiology, calcium imaging, cell survival assays, immunocytochemistry, and RNA/DNA/protein isolation.
This video will guide you through the process of culturing rat cortical neurons in the presence of a glial feeder layer, a system known as a bilaminar or co-culture model. This system is suitable for a variety of experimental needs requiring either a glass or plastic growth substrate and can also be used for culture of other types of neurons.
Rat cortical neurons obtained from the late embryonic stage (E17) are plated on glass coverslips or tissue culture dishes facing a feeder layer of glia grown on dishes or plastic coverslips (known as Thermanox), respectively. The choice between the two configurations depends on the specific experimental technique used, which may require, or not, that neurons are grown on glass (e.g. calcium imaging versus Western blot). The glial feeder layer, an astroglia-enriched secondary culture of mixed glia, is separately prepared from the cortices of newborn rat pups (P2-4) prior to the neuronal dissection.
A major advantage of this culture system as compared to a culture of neurons only is the support of neuronal growth, survival, and differentiation provided by trophic factors secreted from the glial feeder layer, which more accurately resembles the brain environment in vivo. Furthermore, the co-culture can be used to study neuronal-glial interactions1.
At the same time, glia contamination in the neuronal layer is prevented by different means (low density culture, addition of mitotic inhibitors, lack of serum and use of optimized culture medium) leading to a virtually pure neuronal layer, comparable to other established methods1-3. Neurons can be easily separated from the glial layer at any time during culture and used for different experimental applications ranging from electrophysiology4, cellular and molecular biology5-8, biochemistry5, imaging and microscopy4,6,7,9,10. The primary neurons extend axons and dendrites to form functional synapses11, a process which is not observed in neuronal cell lines, although some cell lines do extend processes.
A detailed protocol of culturing rat hippocampal neurons using this co-culture system has been described previously4,12,13. Here we detail a modified protocol suited for cortical neurons. As approximately 20×106 cells are recovered from each rat embryo, this method is particularly useful for experiments requiring large numbers of neurons (but not concerned about a highly homogenous neuronal population). The preparation of neurons and glia needs to be planned in a time-specific manner. We will provide the step-by-step protocol for culturing rat cortical neurons as well as culturing glial cells to support the neurons.
1. Glia Dissection (~2 weeks before plating neurons)
2. Secondary Glia (48 hours before plating neurons)
3. Neuronal Dissection and Culture
4. Representative Results:
A few hours after neurons have attached to the substrate, they begin to extend lamelliopodia. Processes continue to elongate (Fig 2A) and polarize over several days in culture, and extended axons and dendrites are clearly visible (Fig 2B; MAP2 staining). As neurons mature the dendritic arbors become more elaborate and they develop synaptic contacts; about 2-3 weeks after plating many dendritic spines are visible (Fig 2C)11.
Figure 1. Flow chart of the procedure for culturing rat cortical neurons along with a glial feeder layer (secondary glia). First, 11 days before the neuronal dissection, a primary glia culture is prepared from neonatal rats (P2-4). When the cells are confluent (roughly nine days after plating the primary glia and two days before the neuronal dissection), astrocytes are mechanically separated from oligodendrocyte precursor cells and microglia and plated either on dishes or thermanox (secondary glia). Neurons are then obtained from the cortices of E17 embryos and plated either on coverslips or on dishes (coated with poly-lysine). Four hours after plating, the neuronal layer is added to the secondary glia.
Figure 2. Examples of cultures at various stages (e.g. 5 hours; 12 DIV; 21 DIV). Figures are representative images of cortical neurons on coverslips at different time points. After neurons attach to the substrate neurons begin to extend lamelliopodia. Phase contrast image shows a few extended neurites five hours after plating (A). The image in the middle (B, from Cook et al. 2010, with permission) shows 12 DIV cortical neurons fixed and immunostained with the neuronal dendritic marker MAP2. Hoechst staining was used as a counterstaining. As neurons mature dendritic spines also become visible (C). Scale bars: A, B = 25 μm; C = 10 μm.
This protocol provides a method for culturing rat primary cortical neurons in the presence of glia cells, while allowing the neurons to be easily isolated for experimental analysis. The glia support development of a healthy neuronal phenotype, while also modulating neuronal responses to experimental treatments in a physiologically relevant manner. Additionally, by passaging the primary glia before culturing with neurons this cell population becomes selectively enriched in astrocytes, thereby preventing inflammatory microglial stimulation. For certain types of experiments, however, different proportions of glial cells may be desired, thus additional glia cultures may be performed to optimize this cellular composition. This protocol may also be adapted for culturing neurons derived from other brain regions, such as the hippocampus, to fit particular experimental demands
Major concerns of this technique include preventing bacterial contamination and preventing glial proliferation into the neuronal layer. This system does not include antibiotic agents, thus sterile techniques are especially critical at all stages. Glial proliferation is prevented by the addition of the anti-mitotic agent cytosine arabinofuranoside, the low density plating and the serum-free culture medium; following this protocol astrocytes should compose no more than 3-5% of cells in the neuronal layer1,4 and less than 1% microglia should be detected. Immunopanning or other techniques can be used to remove even this low glia contamination4.
This technique can also be modified for co-culturing any variety of adherent cell types when isolating a single type for analysis is desirable. For example, this system was successfully adapted for analyzing the effects of osteoblasts on Ca2+ signaling in bone-metastatic cancer cells14.
The authors have nothing to disclose.
The authors thank previous laboratory members who contributed to refinement of this protocol and the NIH for support over the years (DA19808 and DA15014 to OM). Anna Abt1 is a fellow of the “Interdisciplinary and Translational Research Training in neuroAIDS” (T32-MH078795); thus, this work was supported in part by the National Institutes of Health under Ruth L. Kirschstein National Research Service Award 5T32MH079785.
Reagent | Concentration |
---|---|
Glucose | 16 mM |
Sucrose | 22 mM |
NaCl | 135 mM |
KCl | 5 mM |
Na2HPO4 | 1 mM |
KH2PO4 | 0.22 mM |
HEPES | 10 mM |
pH | 7.4 |
Osmolarity | 310±10 mOsm |
Table 1. Dissection Medium.
Reagent | Concentration |
---|---|
DMEM | 90% |
FBS | 10% |
Gentamicin | 50 μg/mL |
Tabe 2. Glia Plating Medium.
Reagent | Concentration |
---|---|
DMEM | 90% |
Horse Serum | 10% |
Table 3. Neuron Plating Medium.
Reagent | Concentration |
---|---|
DMEM | 98% |
N2 Supplement | 1% |
1M HEPES | 1% |
Ovalbumin | 50 mg/100mL |
Table 4. N2 Medium.
Reagent | Concentration |
---|---|
Boric Acid | 50 mM |
Sodium Borate | 12.5 mM |
Table 5. Borate Buffer (for poly-lysine).
Reagent | Company | Catalogue number |
---|---|---|
High glucose Dulbecco’s Modified Eagle Medium (DMEM) |
Invitrogen | 11995-073 |
Fetal Bovine Serum (FBS), Heat-inactivated | Hyclone | 26400-044 |
Horse Serum, Heat-inactivated | Hyclone | H1138 |
Gentamicin (50mg/mL) | Invitrogen | 15750-060 |
N2 Supplement (100x) | Invitrogen | 17502-048 |
HEPES buffer solution | Invitrogen | 15630-080 |
Albumin from chicken egg white, Grade VI (Ovalbumin) |
Sigma-Aldrich | A2512 |
2.5% Trypsin | Invitrogen | 15090-046 |
0.5% Trypsin-EDTA (10X) | Invitrogen | 15400-054 |
Deoxyribonuclease I from bovine pancreas (DNase) |
Sigma-Aldrich | D-5025 |
Paraplast | Fisher | 12-646-106 |
Poly-L-lysine | Sigma-Aldrich | P1274 |
Cytosine-β-D-arabinofuranoside hydrochloride | Sigma-Aldrich | C6645 |
Stereomicroscope | Leica | Leica ZOOM 2000 |
Cover glasses, Circles, 15 mm, Thickness 0.13-0.17 mm |
Carolina | 633031 |
Thermanox sheets | Grace BioLabs | HS4550 |
Large forceps | Biomedical Research Instruments |
70-4000 |
Fine-tipped No.5 forceps | Fine Science Tools |
91150-20 |
Pattern No.1 forceps | Biomedical Research |
10-1400 |
Instruments | ||
Scissors, straight, sharp-blunt | Biomedical Research Instruments |
28-1435 |
Micro Dissecting scissors | Biomedical Research Instruments |
11-2070 |
Micro Dissecting Curved scissors | Biomedical Research Instruments |
11-1395 |