Neural stem cells (NSCs) refer to cells which can self-renew and differentiate into the three neural lineages. Here, we describe a protocol to determine NSC frequency in a given cell population using neurosphere formation and differentiation under clonal conditions.
Neural stem cells (NSCs) have the ability to self-renew and generate the three major neural lineages — astrocytes, neurons and oligodendrocytes. NSCs and neural progenitors (NPs) are commonly cultured in vitro as neurospheres. This protocol describes in detail how to determine the NSC frequency in a given cell population under clonal conditions. The protocol begins with the seeding of the cells at a density that allows for the generation of clonal neurospheres. The neurospheres are then transferred to chambered coverslips and differentiated under clonal conditions in conditioned medium, which maximizes the differentiation potential of the neurospheres. Finally, the NSC frequency is calculated based on neurosphere formation and multipotency capabilities. Utilities of this protocol include the evaluation of candidate NSC markers, purification of NSCs, and the ability to distinguish NSCs from NPs. This method takes 13 days to perform, which is much shorter than current methods to enumerate NSC frequency.
Neural stem cells (NSCs) are cells of the central nervous system (CNS) that can self-renew and are multipotent. NSCs are first specified during development of the embryonic forebrain and continue to persist in the adult brain at specific regions such as the subventricular zone (SVZ) of the lateral ventricles and the dentate gyrus (DG) of the hippocampus. A number of NSC lines are being used in clinical trials for treatment of stroke and other neurological diseases such as Batten's disease1.
NSCs and neural progenitors (NPs) are propagated in culture as floating 3-dimensional spheroid structures called neurospheres. The neurosphere culture system was developed by Reynolds and Weiss in the early 1990s, when they found that embryonic and adult cortical cells could divide in the presence of epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF)2-4. Neurospheres consist of a heterogeneous mix of cells comprising of subclasses at different developmental stages5. It is challenging to specifically study NSCs using data obtained from neurospheres due to the presence of NPs. Hence, it is crucial to enrich NSCs from neurospheres. At present, four main methods have been used to enrich for NSCs in vitro. First is the use of cell surface markers. Lewis-X (LeX) and CD133 (also known as Prominin1) are the most prominent cell surface NSC markers6-9. Syndecan-1, Notch-1 and Integrin-beta1 are other surface proteins that enrich for NSCs10. Second is the dye exclusion. It has been shown that the side-population cells, which have the unique ability to pump out the fluorescent DNA-binding dye Hoechst 33342, are enriched for NSCs11. Third is the use of morphological selection. It has been demonstrated that cells with increased cell size and granularity harbor more NSCs than their counterparts5,12,13. Fourth is the addition of NSC survival factors to the culture medium. It has been shown that addition of Chondroitin sulphate proteoglycan and Apolipoprotein E enhances NSC survival and thus increases NSC frequency14,15. Although many markers including transcription factors have been associated with NSCs16,17, none of these markers are able to enrich NSCs to purity. Due to the lack of definitive NSC markers, it remains a challenge to quantify NSCs and distinguish them from NPs in vitro.
Initial studies used the neurosphere formation assay (NFA) to quantify NSCs7,11,13. In this assay, dissociated cells are cultured to form neurospheres and the number of neurospheres generated for every 100 cells plated is determined. This value is termed as the Neurosphere Formation Unit (NFU). The NFU equals the NSC frequency if all neurospheres arise from NSCs. However, it was shown that the NFU overestimates the NSC frequency as neurospheres are formed by both NSCs and early NPs5. Thus, it is inaccurate to enumerate NSCs solely based on neurosphere formation. It could be possible to quantify NSCs based on their ability to self-renew, proliferate extensively and generate multipotent neurospheres.
NSCs, which are EGF and bFGF responsive, usually survive for at least ten passages and thus display extensive self-renewal capacity in culture4,18-20. NPs, which are EGF and bFGF responsive as well, could also generate neurospheres for a few passages but not for an extended period of time. Hence, it has been widely accepted that bona fide NSCs can be enumerated with fair accuracy based on neurosphere formation for at least ten passages. In most studies, however, self-renewal is usually measured based on secondary or tertiary neurosphere formation due to the long experimental time required for ten passages. Hence, the secondary NFA can be used to broadly compare the self-renewal ability between populations, but cannot be used to accurately enumerate NSC frequency.
NSCs have a greater proliferative ability compared to NPs. This property of NSCs was used by Louis et al. to develop an assay for NSC enumeration — the neural colony-forming cell assay (NCFCA)21,22. In this assay, single cells are cultured for 3 weeks in a collagen-containing semisolid matrix. Under these culture conditions, it was shown that cells that form neurospheres above 2 mm in diameter are tripotent and can self-renew for long term. These cells are defined as NSCs. Therefore, the NSCs are effectively distinguished from NPs.
NSCs have the ability to differentiate into astrocytes, oligodendrocytes and neurons. For differentiation of neurospheres, growth factors are removed and serum is added to the culture medium. If all three neural lineages are observed in a neurosphere, then the cell that initiated that neurosphere is an NSC. However, the differentiation assay has some limitations. First, the culture conditions used for differentiation may not be optimal for generation of all three neural lineages. In fact, in a single neurosphere differentiation process, significant cell death occurs and mostly astrocyte generation occurs (Tham M and Ahmed S, unpublished). Second, there is the issue of clonality. For accurate enumeration of NSCs, formation and differentiation of neurospheres have to be performed under clonal conditions, where each neurosphere arises from a single cell. In bulk suspension cultures, aggregation occurs at both cellular and neurosphere levels23-25. Hence, it is possible for each neurosphere to arise from multiple cells or neurospheres, which complicates neurosphere counting and evaluation of multipotency. Recent evidence shows that aggregation of cells does not occur at low plating density of 0.5 cells/µL or below, and when culture plates are not moved during neurosphere formation15. Thus culturing cells at such low density would ensure clonality.
Currently, the NCFCA is the most commonly used method to distinguish NSCs from NPs and enumerate NSC frequency. The NCFCA, however, requires a relatively long time of three weeks. Here, we describe a protocol to enumerate NSC frequency based on the ability of NSCs to form multipotent neurospheres. This protocol takes only 13 days to perform. The NCFCA ensures clonality as the collagen matrix prevents movement of the neurospheres. The culture conditions used in this protocol also allows clonality to be maintained throughout. For instance, the use of 50-well chambered coverslips ensures that the neurospheres will differentiate without contacting each other. Furthermore, we use conditioned medium that supplies neurotrophic factors during differentiation to maximize the differentiation potential of the neurospheres (Figure 1).
The treatment of animals was performed in accordance with the IACUC and NACLAR guidelines and approved by the animal department ((http://www.brc.astar.edu.sg/index.php?sectionID-11).
NOTE: Neurosphere cultures were prepared from the forebrain of embryonic (E14) C57BL/6 mice as previously described5.
1. Culture of Clonal Sample Neurospheres (Day 1)
2. Culture of Neurospheres for Conditioned Medium (Day 3)
3. Preparation of Neurosphere Conditioned Medium (Day 8)
4. Determination of NFU of Sample Neurospheres (Day 8)
5. Transfer of Sample Neurospheres to 50-well Chambered Coverslip (Day 8)
6. Differentiation of Sample Neurospheres (Day 9)
7. Fixing of Differentiated Neurospheres (Day 12)
8. O4 Staining of Differentiated Neurospheres (Day 12)
9. Tuj1 and Glial Fibrillary Acidic Protein (GFAP) Staining of Differentiated Neurospheres (Day 12)
10. Imaging of Differentiated Neurospheres (Day 13)
We have used this protocol to assess the ability of LeX, a known cell surface NSC marker7, to enrich for NSCs. Data from this study will be used to illustrate how NSCs are enumerated using the clonal assays in the protocol. E14.5 mouse neurosphere cells were incubated with anti-LeX antibody. Subsequently, cells that express LeX (LeX+) and cells that do not express LeX (LeX–) were seeded at 50 cells/mL by Fluorescence-Activated Cell Sorting (FACS) and left to generate clonal neurospheres for 1 wk. Time-lapse imaging shows that the neurospheres generated at 50 cells/mL are clonal (Figure 2). The NFU for LeX+ and LeX– cells was determined. It is shown that LeX+ cells have a significantly higher neurosphere formation capability compared to LeX– cells (Figure 3g). The neurospheres generated were then differentiated under clonal conditions, subsequently immunostained and imaged (Figure 3a-e). LeX+ cells generate significantly more tripotent neurospheres than LeX– cells (Figure 3f). The NSC frequency was then calculated based on the NFU and % of tripotent neurospheres (Figure 3g). Selection based on LeX, enriches NSC frequency by more than 14 fold, validating LeX as a NSC marker. We have also determined the NSC frequency of E14.5 mouse neurospheres using this protocol27 and NCFCA28. Both methods report comparable NSC frequency of about 2% in E14.5 mouse neurospheres.
Figure 1. Protocol for Neurosphere Differentiation under Clonal Conditions. Sample neurospheres grown under clonal conditions are individually placed in each PLL/Laminin-coated well of a 50-well chambered coverslip, and allowed to adhere O/N. On the same day, bulk cultured neurospheres are plated in differentiation medium in a PLL/Laminin-coated 10 cm dish, and allowed to adhere O/N. The next day, conditioned medium from the bulk cultured neurospheres is filtered and placed back in the 10 cm dish. The sample neurospheres are then inverted onto the conditioned medium and allowed to differentiate for 3-4 days28. Please click here to view a larger version of this figure.
Figure 2. Growth of a Clonal Neurosphere. Cells derived from E14.5 neurospheres were dissociated and seeded at 50 cells/mL in 96-well dish. Individual cells were tracked for 6 d by time-lapse imaging. Images of one such cell growing into a neurosphere is shown. Note that the neurosphere maintains clonality. (a) 0 days; (b) 1.19.45; (c) 2.95.37; (d) 3.32.76; (e) 4.46.53; (f) 5.61.44; where the first number refers to the day, second number refers to the fraction of the day, and third number refers to the fraction of the h. 10X magnification. Scale bar, 100 µm. Please click here to view a larger version of this figure.
Figure 3. Differentiation of Clonal Neurospheres and Enumeration of NSC Frequency. Single neurospheres were picked and differentiated in 50-well chambered coverslip for 3 d. A representative image of a tripotent neurosphere stained with (a) DAPI and immunostained for (b) GFAP, (c) Tuj1 and (d) O4. (e) Shows the overlay of (a) – (d). Scale bar, 65 µm. (f) The % of unipotent, bipotent and tripotent neurospheres generated by LeX+ and LeX– cells (mean ±SEM; n = 3). (g) NSC frequency in LeX+ and LeX– cells calculated as the product of NFU and % of tripotent neurospheres. Please click here to view a larger version of this figure.
We describe hee the enumeration of NSCs under clonal conditions. Critical steps include the use of fresh NSC growth and differentiation medium, and also the use of freshly prepared PLL/Laminin solution to coat the chambered coverslips, as well as the culture dishes. This ensures optimal growth and differentiation conditions of the neurospheres. The use of good quality antibodies to effectively detect the neurons and glia, as well as the selective picking of clonal neurospheres that are not in contact with other neurospheres, are critical. Furthermore, it is important to ensure the picked neurospheres do not dry up. It is recommended to add 10 µL of differentiation medium to each well after picking every 10 neurospheres. It is important to use one chambered coverslip in one 10 cm dish per sample to avoid cross talk between neurospheres from different samples. If two coverslips (each containing neurospheres from different samples) are placed in the same 10 cm dish, neurospheres from one coverslip might release factors that may alter the propensity of neurospheres in the other coverslip to differentiate into specific lineages. Two coverslips in the same 10 cm dish may also result in mix up between samples.
In the event the NFU or the NSC frequency is lower than expected, ensure that low passage number neurospheres are used. It is also important that healthy low passage neurospheres are used for generating conditioned medium. Next, if the neurospheres are cultured in wells with small diameter, such as in 96-well dish, then it will be difficult to maneuver and pick neurospheres using a micropipette. In this case, transfer the neurospheres to a larger culture dish, such as a 6-well dish, prior to picking. Some of the picked neurospheres may lift off from the chambered coverslip during culture and immunostaining. Minimizing the movement of the chambered coverslip during culture, and less intensive washing during immunostaining, would help to avoid detachment of neurospheres.
Initial studies quantified NSCs using only the NFA7,11,13. However, the NFA overestimates the NSC frequency as both NSCs and early NPs generate neurospheres5. Louis et al. developed another method to quantify NSCs known as the NCFCA21,22. The NCFCA involves culturing single cells in a collagen based matrix to ensure clonality, and it was shown that neurospheres above 2 mm in diameter are formed by NSCs only. Similar to the NCFCA, clonality is ensured throughout this protocol. This is achieved by generating neurospheres at clonal density and differentiating the neurospheres in chambered coverslips. The use of chambered coverslips confers a number of advantages. The chambered coverslip allows each sample neurosphere to differentiate without having physical contact with other sample neurospheres, thereby ensuring clonality during differentiation. The chambered coverslip can be placed suspended on the differentiation medium to allow the sample neurospheres to be continuously conditioned and to ensure maximum differentiation. In the absence of conditioned medium and serum during differentiation, survival of the neurospheres decreases and the neurospheres mostly generate astrocytes (Tham M and Ahmed S, unpublished). In addition, the immunostained neurospheres can be conveniently stored for long period of time and the chambered coverslips can be mounted directly on the microscope glass slides. Additionally, imaging of the immunostained neurospheres is made easy as one can quickly locate the neurosphere in the small chambered well, capture an image, and move on to the next well.
We have determined the NSC frequency in E14.5 mouse neurosphere culture using both the protocol described in this manuscript27 and NCFCA28. The NSC frequency in E14.5 mouse neurospheres determined by both methods are comparable. The NCFCA enumerates NSCs that are multipotent and have long-term self-renewal capacity. Since the NSC frequency from our method is comparable to that from NCFCA, the readout from our protocol does not seem to overestimate the NSC frequency. The NCFCA requires three weeks to be completed and mainly involves cell plating and medium replenishment. The protocol described here requires 13 days to perform and involves a different series of steps, e.g., neurosphere picking and immunostaining. This protocol could serve as an alternative method to enumerate NSCs. Researchers can use both NCFCA and this protocol to verify NSC frequency in their samples.
One limitation of this protocol is that a series of important steps have to be all performed on day 8. The preparation of the conditioned medium, determination of NFU of sample neurospheres, and transfer of sample neurospheres to the 50-well chambered coverslip have to be performed on day 8. One might take time to complete these steps. In addition, it requires practice to perform these steps in an efficient manner.
Neurospheres have been widely used to study NSC function and behavior. However, neurospheres consist of both NSCs and NPs. Hence, it is important to enrich NSCs from neurospheres to study NSC biology. Currently, cell surface markers, dye exclusion property as well as cell size and granularity have been used to enrich for NSCs6,7,9-13,29,30. This protocol could be used to quantify the enrichment of NSCs by potential NSC markers, and to facilitate the search for a definitive NSC marker. Four recent studies have used this protocol to enumerate NSC frequency5,14,15,26.
The authors have nothing to disclose.
We thank the Agency for Science, Technology and Research (A*STAR), Singapore for funding this research.
15 ml conical centrifuge tubes | BD | 352096 | |
50 ml conical centrifuge tubes | BD | 352070 | |
20 ml sterile syringe | BD | 300141 | |
50 ml sterile syringe | BD | 300144 | |
Fetal bovine serum (FBS) | Biowest | S1810 | |
Mouse anti-Tuj1 IgG2a antibody | Covance | MMS-435P-100 | |
Rabbit anti-GFAP IgG antibody | Dako | Z033401 | |
Hemocytometer | Hausser Scientific | 3100 | |
Microscope fitted to laminar flow hood | Leica | MZ6 | |
Glass slides | Marienfeld-superior | 1000200 | |
Mouse anti-O4 IgM antibody | Merck Millipore | MAB345 | |
Hydromount | National Diagnostics | HS-106 | |
Microscope | Nikon Eclipse | TS100-F | |
Laminar flow hood | NuAire | NU-543 | |
96-well culture dishes | NUNC | 167008 | |
10-cm culture dishes | NUNC | 150350 | |
Paraffin film | Parafilm | PM999 | |
Human epidermal growth factor (EGF) | Peprotech | AF-100-15 | |
Recombinant human basic fibroblast growth factor (bFGF) | Peprotech | 100-18B | |
0.2 µm filter | Sartorius Stedim | 16534-K | |
0.45 µm filter | Sartorius Stedim | 16555-K | |
1.0 N Sodium hydroxide (NaOH) | Sigma-Aldrich | S2770 | |
1.0 N Hydrochloric acid (HCl) | Sigma-Aldrich | H9892 | |
Trypan Blue | Sigma-Aldrich | T8154 | |
Poly-L-lysine (PLL) | Sigma-Aldrich | P8920 | |
Paraformaldehyde (PFA) powder | Sigma-Aldrich | P6148 | Toxic |
Bovine serum albumin (BSA) powder | Sigma-Aldrich | A7906 | |
50-well chambered coverslips | Sigma-Aldrich | C7735 | |
Stir plate with heat function | Stuart | UC152 | |
DMEM/F12 medium | Thermo Fisher Scientific | 11320-033 | |
B27 | Thermo Fisher Scientific | 17504044 | |
Penicillin-Streptomycin | Thermo Fisher Scientific | 15140-122 | |
Laminin | Thermo Fisher Scientific | 23017-015 | |
1x phosphate buffered saline without Ca2+ and Mg2+ (DPBS) | Thermo Fisher Scientific | 14190144 | |
Alexa Fluor 488 goat anti-mouse IgM antibody | Thermo Fisher Scientific | A21042 | |
Alexa Fluor 594 goat anti-mouse IgG2a antibody | Thermo Fisher Scientific | A21135 | |
Alexa Fluor 647 goat anti-rabbit IgG antibody | Thermo Fisher Scientific | A31573 | |
4’,6’-diamidino-2-phenylindole dihydrochloride (DAPI) | Thermo Fisher Scientific | D3571 | |
Cell culture centrifuge | Thermo Fisher Scientific | RT1 75002383 | |
Pasteur pipettes | Thermo Fisher Scientific | 10006021 | |
CO2 incubator | |||
Ventilated fume hood | |||
Aspirator | |||
Confocal microscope | |||
Micropipettes | |||
Micropipette tips | |||
Plastic pipettes | |||
Multichannel pipettes | |||
Glass beaker | |||
Sterile forceps | |||
pH meter |