Establishment and Characterization of Four Long-Term Cultures of Neural Stem/Progenitor Cell Lines from the Japanese Flounder Paralichthys olivaceus

GAO ChenSONG Huayu3WANG MengxunLIU XiumeiZHAO Jun,WANG Xuboand ZHANG Quanqi2

Establishment and Characterization of Four Long-Term Cultures of Neural Stem/Progenitor Cell Lines from the Japanese Flounder

GAO Chen1), #, SONG Huayu1),3), #, WANG Mengxun1), LIU Xiumei1), ZHAO Jun1),WANG Xubo1), and ZHANG Quanqi1), 2),*

1),,,,266003,2),,266237,3).,.,266003,

Neurogenesis is an important progress wherein the neural stem cells (NSCs) differentiate into functional neurons under conductive conditions. Neurogenesis occurs continuously in different areas of the central neural system in adult teleosts compared with adult mammals. Therefore, NSC cell lines must be established to offer a valuablesystem for studies on neurogenesis and other related functions. In this study, four cell lines designated as PoB1, PoB2, PoBf and PoBh were established from the brain of the Japanese flounder. The cell lines were sub-cultured over 150 times and still grew well in DMEM/F12 medium at 24℃. PoB1, PoB2, PoBf and PoBh were identified as neural stem/progenitor cell lines on the basis of the mRNA expression ofand/ororand the formation of neurospheres. The cells transfected with the pEGFP-C1 plasmid showed fluorescent signals with distinct reagent dependencies. The established cell lines from the brain ofoffer a valuable systemfor the study of neurogenesis, fish neural regulation and endocrinology-related functions.

brain; cell lines;; transfection; nestin

1 Introduction

Neurogenesis, which mainly involves cell proliferation, migration, differentiation and survival, is an important pro-gress that the neural stem cells (NSCs) differentiate into functional neurons under conductive conditions. Similar to other stem cells, NSCs also display self-renewal and dif- ferentiation abilities, as well as participate in the formation of the nervous system during development. In mammals, neural cells are mainly generated during the pre-natal phase of development, and neurogenesis is restricted to two re- gions of the adult brain (Taupin, 2006). However, neurogenesis considerably differs among various vertebrate classes. For example, teleosts continuously produce a tremendous number of new neurons in many regions of the adult brain. Moreover, the cell proliferation rate in teleosts is one to two orders of magnitude higher than that in mammals (Hinsch and Zupanc, 2006). Therefore, studying the NSCs in teleosts is important to understand the development and evolution from teleosts to mammals. In addition, the study of NSCs in fish is still in its infancy (Grandel., 2006; Zupanc, 2008) when compared with that in mammals (Cai., 2002; Charrier., 2006; Taupin, 2006; Duan., 2008).

Cell lines are an important system for many studies be- cause of their several advantages, including similar micro- environment to thatand abundant resources. Some scientists have attempted to establish cultures of brain cells from several fish species. For example, embryonic brain cell lines in the silky sharkwere established in 1992,and they have been successfully main-tained through 45 passages (Poyer and Hartmann, 1992). In addition, intrinsic stem cells from the telencephalon, corpus cerebelli, and valvula cerebelli of the brown ghost knifefishwere isolated, culti- vated and then examined (Hinsch andZupanc, 2006). Some primary cultures, such as those of tilapia brain from different ages, were also established to study the function of neural systems (Tsai., 2001). However, few studies established cell lines derived from fish brains. These cell lines include the neural progenitor cell line TB2 from tilapia (Wen., 2008a);GBC1 and GBC4 from the orange-spotted grouperBB from the Asian seabass(Wu and Chi, 2006);EAGB from the Hong Kong grouper(Huang., 2011);RGB from the Longfin grouper(Ku., 2009);and SBB-W1 fromEuropean seabass(Servili., 2009). These previously established cell lines indicate that neurogenesis continues at a high rate through- out the adult life in different regions of the fish central nervous system(Grandel., 2006; Hinsch and Zupanc, 2006). However, NSC lines have been reported in only a few fish species, including(Hinsch and Zupanc, 2006),tilapia (Wen., 2008a), sea bass (Ser- vili., 2009) and some groupers. Permanent cell lines provided opportunities to study neurogenesis,while the experiences can also be applied in fish brain cells(Wen., 2010; Hasoon., 2011; Huang., 2011).

The Japanese flounderis an im- portant economic marine fish in China. The permanent cell lines from this fish have been broadly applied in toxicology and immunology studies (Tong., 1997).However, few cell lines have been established from fish neural tissues. Therefore, neural stem/progenitor cell lines from the brain ofneed be established to offer a valuablesystem for the study of fish nervous regulation and endocrinology-related functions.

2 Materials and Methods

2.1 Animals and Tissue Collection

individuals were collected from a commer- cial hatchery located in Haiyang City , China. The fish were kept in indoor facilities under natural light with constant temperature and salinity. After acclimatization, the fish were randomly selected for cell culture. Nine apparently healthy adult fish were used in accordance with the guidelines and regulations for animal experiments of the Ocean University of China and the local government of Yantai City.

2.2 Primary Culture

The whole brain (including the telencephalon, dience- phalon, midbrain, cerebellum, and medulla oblongata) of three individuals and the hypothalamus of six individuals were separated and mixed for the primary cell culture. The two types of tissues were finely minced with scissors in D-Hank’s solution (containing 500IUmL?1penicillin and 500μgmL?1streptomycin) and then washed at least three times to remove any blood clots. The small brain fragments were washed several times with phosphate-buffered saline (PBS) supplemented with antibiotics (200IUmL?1penicillin and 200μgmL?1streptomycin), transferred into Dulbecco’s Modified Eagle Medium: Nutrient Mixture F-12 (DMEM/F12, Gibco) supplemented with antibiotics (100IUmL?1penicillin and 100μgmL?1streptomycin), and then further minced into small pieces (about 1mm3).

For the hypothalamus part, TrypLE? Express (Gibco) was added into the cell suspension at a ratio of 1:1 for 5min. Then the cell suspension was filteredthrough 40μm bore diameter and then transferred into a 25cm2tissue culture flask (Nunc) containing 5mL of DMEM/F12 medium supplemented with 20% fetal bovine serum (FBS, Gibco). This culture was named PoBh. The whole brain frag- ments were divided into two groups. The first group was transferred into a 25cm2tissue culture flask (Nunc) and se- parated in FBS without TrypLE? Express.Then DMEM/F12 medium (5mL) supplemented with 20% FBS was add-ed after these smaller fragments attached to the flask. After 3 days, the adherent cells were named PoB1. The upper non-adherent cells of the first group were transferred to a new flask and named PoBf. The second group was treated with TrypLE? Express as previously described and the resultant was named PoB2. All cultures were incubated at 24℃. Every 4–5 days, half of the growth medium was re- placed with fresh medium. Monolayers of primary cultured cells were obtained within a month.

2.3 Sub-Culture or Propagation

When the confluent monolayers reached 95%, the cells were examined under an inverted microscope to ensure that their morphologies were normal without microbial con- tamination. After removing the culture medium, the cells were washed twice with PBS buffer to eliminate the FBS and dead cells. Then 1mL of TrypLE? Express was added to each flask to dislodge cells from the surface. After the cells were dislodged, FBS was added to stop the reaction. The cells were sub-cultured at a split ratio of 1:2 to 1:3 in fresh DMEM/F12 medium supplemented with 10mmolL?1HEPES (pH 7.5), 10mmolL?1non-essential amino acid, antibiotics (100IUmL?1penicillin and 100μgmL?1strep- tomycin; Gibco), FBS, insulin-like growth factor 1 (IGF-1, Peprotech) and basic fibroblast growth factor (bFGF, Pe- protech). In addition, the PoB2 cell line also contained fi- broblast growth factor 9 (FGF9, Peprotech). The concentration of FBS was maintained at 20% before the 15th passage, at 15% before the 60th passage, and at 10% the- reafter. The concentrations of IGF-1, bFGF and FGF-9 were maintained at 10ngmL?1before the 50th passage, at 5ngmL?1before the 100th passage, and at 2ngmL?1the- reafter.

2.4 Effect of FBS on Cell Growth

The effects of FBS concentration on the proliferation of the four brain cell lines were examined. In brief, 2.8×105PoB1 cells, 2.8×105PoB2 cells, 6.8×104PoBf cells and 1×105PoBh cells were inoculated in a six-well plate and then incubated at 24℃ for growth test. The concentration of FBS was set to 5%, 10%, 15% and 20%. Cell density was measured microscopically using a haemocytometer. Every experiment was repeated three times.

2.5 Cryopreservation and Recovery

For cryopreservation, 24-hour-old brain cells at different passages were used.The cells were harvested by centrifugation and then suspended in 10% dimethyl sulfoxide, 15% FBS and 75% complete DMEM/F12 medium to a density of 1×106cellsmL?1. The cell suspensions were then transferred into cryovials. Cryopreservation was perform- ed by gradual freezing at 4℃ for 30min, ?20℃ for 2h and ?80℃ overnight, followed by prolonged storage in liquid.

For recovery, the cryovials from the liquid nitrogen were placed in running water at 37℃ and then finely shook until the cells were thawed. The cells in the frozen medium were immediately transferred into a fresh medium with 20% FBS and then cultured at 24℃. Meanwhile, the recovered cells were stained with trypan blue and counted with a haemo- cytometerto analyze the survival rate.

2.6 Chromosome Analysis

After inoculation, the cells were cultured for 5h at nor- mal condition till the cells reached exponential stage. The cells were treated with 0.005% colcemid (Solarbio, China) for 2h. The monolayer was trypsinized and pelleted as des- cribed above. The cells were suspended in 0.8mL of hypotonic medium (0.075molL?1KCl) for 40min and prefixed with 0.4mL of pre-cooling Carnoy’s Fluid (3:1, me- thanoltoglacial acetic acid) at room temperature for 25min. After centrifugation at 3000for 5min, the cells were su- spended thrice in 1mL of pre-cooled Carnoy’s fluid at ?20℃ for 25min. Finally, the cells were resuspended in appro- ximately 0.2mL of fixative, and a drop of the cell suspension was immediately added to one side of a clean slide. The cells were dispersed and air-dried. Chromosomes were stained with Giemsa (Solarbio) for 10min, washed with running water, air-dried, mounted and then photographed. Chromosome counts were performed for at least 150 me- taphase plates.

2.7 Molecular Identification of Brain Cell Cultures

The expression of specific genes was examined to cha- racterize NSCs and their sub-lineages. The following mar- ker genes were used:, sex determining region Y-box 1 () and sex determining region Y-box 2 () for NSCs; glial fibrillary acidic protein (GFAP) and aldehyde dehydrogenase 1 family, member L1 () for astrocytes;myelin-associated glycoprotein (MAG) for oligodendrocytes; glutamate decarboxylase 1 (GAD1) for GABAergic/glutaminergic neurons; and solute carrier family 6 (neuro- transmitter transporter), member 4 () for serotonegic neurons. The primers (Table 1) used for gene expression detection were designed on the basis of the sequence data from NCBI.

Cells cultured in a flask for 24h were harvested and washed with PBS. After centrifugation, the cells were add- ed with 1mL of Trizol (Invitrogen) for RNA extraction. First-strand of cDNA was prepared as previously des-cribed (Song., 2015). PCR amplification for β-actin was performed using the following program: initial denaturation for 5min at 94℃; 35 cycles of 30s at 94℃, 30s at 58℃ and 30s at 72℃; and a final extension of 7min at 72℃. PCR amplifications for other genes were performed using the following program: initial denaturation for 5min at 94℃; 35 cycles of 30s at 94℃, 30s at 60℃, and 30s at 72℃; and a final extension of 7min at 72℃. An aliquot of PCR product was electrophoresed on 3% agarose gels, vi- sualized and then photographed for verification.

Table 1 Nucleotide sequences of the primers

2.8 Transfection Analysis

The pEGFP-C1 plasmid, which was conserved in the la- boratory, was used to evaluate the transfection ability of the four brain cell lines. The plasmid contains a cytome- galo virus promoter, an SV40 polyadenylation signal and a neomycin-resistant gene. The cells stored in DMEM/F12 medium with 10% FBS were seeded into a 24-well plate at a density of 1×105cellsmL?1and a growth volume of 1mL. After 10h, the cells were treated with a complex of the pEGFP-C1 plasmid (0.5μg) and the liposome transfection reagent Lipofectamine? 3000 (Invitrogen) or TurboFect (Thermo) in accordance with the manufacturer’s instructions. After the cells were incubated at 24℃, green fluorescence signals were observed every 12h under a Nikon fluorescence microscope. The transfection efficiency was evaluated by calculating the ratio of cells expressing green fluorescence signals to all cells employed for transfection.

2.9 Statistical Analysis

The cell amount was analyzed with independent sample tests. Data were expressed as mean±SD. Statistical significance was considered when<0.05. All statistical ana- lyses were computed using SPSS 18.0.

3 Results

3.1 Isolation and Cultivation of Brain Cells

Primary cultures of brains fromwere estab- lished through explant culturing and trypsinization method. When the explant fragments of whole brains attached onto the bottom of the flask, some cells emerged from the edges of tissue explants 2d after tissue explanting, whereas other cells did not emerge from the edges of tissue explants even 8d after tissue explanting. On the basis of their different rates of attachment and migration, the PoB1 and PoBf cell cultures were separated and established. Cells suspensions of PoBh and PoB2 in DMEM/F12 with 20% FBS usingtrypsinization attached to the flask 1d after inoculation. These cells grew rapidly and stably in DMEM/F12 medium. The two culture methods were found to be ideal for developing primary cultures and responded well to sub-culturing.

Primary cells from the brains showed various morpho- logies after explant culturing or trypsinization methods. PoB1 and PoBf cells adhered well and achieved conflu- ence within half a month after explant culturing. PoB1 cells merged from the edges of seeded tissue explants 2d after tissue explanting. The cells in primary culture were main- ly large, round with distinct borders, or irregularly shaped (Fig.1A). By contrast, PoBf cells adhered on the flask after 4d and were small, polygonal and in patches (Fig.1B). PoBh cells in primary cultures were larger than the other cell cultures and were mainly in irregular shape. Some cells exhibited many obvious pseudopodia which were similar to synapses (Fig.1C). The brains cells cultured using tryp- siniztion showed a similar morphology to those cultured using explanting (Fig.1D).

Fig.1 Photomicrographs of cell lines established from brains of Japanese flounder. Primary cell culture of PoB1 (A), PoBf (B), PoB2 (C), and PoBh (D), and confluent monolayer of PoB1 (passage 157, A’), PoBf (passage 136, B’), PoB2 (passage 100, C’), and PoBh (passage 130, D’) are shown. Bar=200μm.

Fig.2 The neurospheres of PoBh cells at passage 73 for 27d. The neurospheres cultured attach to the surface, and the differentiating cells migrate away from the core of the neu- rosphere. Magnification=100×.

Brain cells grew slowly and formed a monolayer 5–6d before passage 30 and then grew rapidly and formed a mo- nolayer within 3–4d. Confluent cells were continuously sub-cultured at the ratio of 1:2–1:4. The sub-cultured cells could adhere in 2h. After several sub-cultures, fibroblast-like cells were mainly observed. The concentrations of FBSand growth factors gradually reduced to 10% and 2ngmL?1, respectively. These brain cell lines gave rise to long-term cultures which lasted over a year and have been sub-cul- tured for more than 150 times so far. The four cell lines were found composed of fibrocytes and epithelium in mor- phologies and showed similar sizes (Figs.1A’, 1B’, 1C’, and 1D’).

Upon reaching confluence, the cells formed neurosphe- roidal bodies or cell clumps (Fig.2). The cell clumps ad- hered again and grew contiguously after inoculation in a new flask with small suspension form.

3.2 Effect of FBS on Cell Growth

The effects of various FBS concentrations on the growth of PoB1, PoBf, PoB2 and PoBh cells at passages 138, 123, 86 and 81 were investigated. PoB1 cells exhibited no different growth characteristics at FBS concentrations ranging from 5% to 20% (Fig.3A). PoBf and PoB2 cells showed poor growth at 5% and 10% FBS, and relatively good growth at 15% and 20% FBS (Figs.3B and 3C). PoBh cells exhi- bited relatively poor growth at 5% FBS (Fig.3D). No significant growth difference was observed at various FBS concentrations (Fig.3). The growth curves involving various FBS concentrations indicate that FBS had minimal influence on the growth of all four cell lines after several passages. However, high FBS concentration in the medium facilitated better the adherence and spreading of cells com- pared with low FBS concentration (data not shown).

3.3 Cryopreservation and Recovery

The brain cells were successfully cryopreserved in li- quid nitrogen and were recovered from different storage periods. The average viabilities of the cryopreserved PoB1, PoBf, PoB2 and PoBh cells were estimated to be appromately 94.4%, 95.57%, 90.52%, and 92.31% respectively. After recovering from storage, the cells grew confluency within 1 week and showed the same morphology. No significant changes in the morphology of recovered cells were observed after prolonged storage. However, the concentration of cells in frozen medium was vital for recovery. The suitable concentration for all cell lines was 106cellsmL?1.

Fig.3 Growth curves of brain cells in DMEM/F12 supplemented with different concentrations of fetal bovine serum. The cells were propagated at 24℃ and the cell number was determined every 12h. The effect of FBS on growth of PoB1 cells at passage 138 (A), of PoBf cells at passage 123 (B), of PoB2 cells at passage 86 (C) and of PoBh cells at passages 81 (D) are shown.

3.4 Chromosomal Analysis

The chromosomes numbers and karyotype are presented in Fig.4. PoB1 at passage 142 showed that the chromo- somes number mainly ranged from 60 to 69 (Fig.4A), while most of the cells had 64 or 66 chromosomes. In terms of karyotype (Fig.4A’), both end-centromere chromosomes and central-centromere chromosomes were observed. PoBf at passage 139 also showed that the number of chromosomes varied from 60 to 69 (Fig.4B), while most of the cells had 62, 64 or 66 chromosomes. Acrocentric, metacentric, subtelocentric and spot chromosomes were obser- ved (Fig.4B’). PoB2 at passage 90 showed that the number of chromosomes ranged mainly from 60 to 79 (Fig.4C), with a mode of 72 that was higher than the other three cell lines. PoBh at passage 121 showed that the chromosome number mainly ranged from 60 to 69 (Fig.4D) with a distinct peak of 64.

Fig.4 The distribution frequencies of chromosomes and karyotypes of four cell lines.A,The distribution frequencies of chromosomes of PoB1 cells at passage 142; B, PoBf cells at passage 139;C, PoB2 cells at passage 90; D, PoBh cells at passage 121 (D). A’, Karyotypes of PoB1 cells at passage 142; B’, PoBf cells at passage 139; C’, PoB2 cells at passage 90; D’, PoBh cells at passage 121. White arrows showed the spot chromosomes and black arrows showed the metacentric chromosome. Cellular chromosomes arrested in metaphase were shown as magnification =1000×. The x axis stands for chromosome number, and the y axis stands for the percentage of cells.The figuresA, B and D stand for the percentage of cells whose chromosome numbers are between 60 and 69.The figure C stands for the percentage of cells whose chromosome numbers are between 60 and 79.

Karyotype analysis revealed that few cells had a diploid chromosome number of 2=48 (Yu., 1995; Wang., 2009) as the modal chromosome numbers in. A high proportion of the cells displayed aneuploidy and heteroploidy (Figs.4A’, 4B’, 4C’ and 4D’). These pheno-mena were pronounced in some immortal cell lines (Tong., 1997; Wang., 2008).

3.5 Molecular Identification of Brain Cell Cultures

To verify whether the four brain cell lines express specific neural genes, we performed reverse transcription (RT) PCR using the total RNA extracted from the cells. Electrophoretic analyses of the amplification of these genes from the cell lines andbrain tissue were con- ducted. The PCR products obtained from the cells’ cDNA displayed the expected sizes that were the same with those obtained using cDNA from brain tissue, which was used as a positive control (Fig.5). The expected 443, 357 and 450bp PCR products of,andwere observed in all samples, respectively (Fig.5). In addition, an obvious band at approximately 421bp forwas observed in PoB1 cells (Fig.5). Weak bands at about 182bp forand 107bp for, whereas obvious bands at 421bp for, were observed in PoBh cells (Fig.5). However, no PCR product was obtained from the cDNA template prepared from PoBf and PoB2 cells (Fig.5).

Fig.5 Expressions of neural genes in brain cell lines PoB1, PoBf, PoB2, and PoBh, and brain tissue (positive control). M, 100bp ladder DNA marker; lane 1, sox1 (182bp); lane 2,sox2 (107bp); lane 3, nestin (443bp); lane 4, mag (352bp);lane 5, aldh1l1 (421bp); lane 6, gfap (304bp); lane 7,gad1 (244bp); lane 8, slc6a4 (166bp); lane 9, actin (450bp).

The sequences ofandwere 100% identical to the mRNA of thetranscription factors SOX-1a (, Genbank accession no. KR108250.1) and SOX-2 (, Genbank accession no. KF709692.1), respectively. The sequences of,andamplicons were 80%, 90% and 90% identical to thenes- tin mRNA sequence (Genbank accession no.XM_008297933.1), thecytosolic 10-formyltetra- hydrofolate dehydrogenase-like mRNA sequences (Genbank accession no. XM_010752381.1) and themRNA sequences (Genbank accession no. XM_010739044.1), respectively. The sequences of,andwere 100% identical to those sequences in the ge- nome of(data unpublished). These data indicate that the four cell lines are derived frombut have different expression patterns.

3.6 Transfection Study

The four brain cell lines were successfully transfected with pEGFP-C1 by using Lipofectamine? 3000 (Figs.6A–6D) or TurboFect (Figs.6A’–6D’). The expression of GFP in these cell lines could be weakly detected under a fluorescent microscopeas early as 12h after transfection. Clear green fluorescent signals were detected at 24h after trans- fection (Fig.6). These results suggest that the four brain cell lines ofare suitable for transfection with Li- pofectamine? 3000 or TurboFect.

However, the transfection efficiency of one special cell line with different transfection reagents differed. The trans- fection efficiency of the PoB1 cell with TurboFect was ap- proximately 40% (Fig.6A’), whereas that of the PoB1 cells with Lipofectamine? 3000 was only approximately 10% (Fig.6A). By contrast, the PoBf cells showed a significant- ly higher transfection efficiency with Lipofectamine? 3000 (70%, Fig.6B) than with TurboFect (approximately 15%, Fig.6B’). The clear green fluorescent signals in the PoBf cells were stronger when theywere transfected with Lipofectamine? 3000 than with TurboFect. The PoB2 cells transfected with Lipofectamine? 3000 and TurboFect show- ed no significant difference in transfection efficiency (, approximately 20%–25%, Figs.6C and 6C’). The results of transfection in PoBh cells were similar to those in PoB1 cells; that is, a high efficiency of approximately 40% was caused by TurboFect transfection (Fig.6D’), whereas low efficiency of approximately 25% was caused by Lipofectamine? 3000 transfection (Fig.6D).

4 Discussion

In the present study, four cell lines were established from the brain of. These cell lines designated as PoB1, PoB2, PoBf and PoBh on the basis of their origin, isolation and culture methods of themselves showed distinct morphological and genetic characteristics. The four types of brain cell lines have been sub-cultured for more than 176, 140, 184 and 165 times since their establishment in January of 2014 and are still in active growth.

Brain tissues ofwere either digested with enzyme trypsin or were cultured directly to initiate the pri- mary culture of cells. The establishment of the four brain cell lines proved that the two methods were helpful. All four cell lines adapted well for growth in DMEM/F12 me- dium. Although many trials used Leibovitz’s L-15 (Poyer and Hartmann, 1992; Wen., 2008a, 2008b;Sun., 2015) and special neurobasal media to culture brain cell lines and murine neural stem/ progenitor cells (Corti., 2007), respectively. DMEM/ F12 me- dium was chosen in the present study on the basis of the culture condition of the NSC lines of(Hinsch and Zupanc, 2006). No significant cell growth was observed when EAGB cell lines were incubated in M199, DMEM and RPIM1640 (Huang., 2011). In addition, no cytokines were used in the above cell cultures, expect for that of the adult brain of, wherein B27, bFGF and epidermal growth factor (EGF) were supplemented. Therefore, the cultivation and growth of brain neural cells required less nutrition, and almost all of the common culture media could facilitate satisfactory growth. In the present study, bFGF and IGF were initially present in all four brain cells, whereas FGF-9 was only supple- mented in the culture medium for PoB2. Thus, the different morphological and genetic features present in the four cell lines may share a certain relationship to these factors.

Fig.6 Green fluorescent protein expression in Japanese flounder brain cells transfected with pEGFP-C1 using transfection reagents Lipofectamine? 3000 (A–D) or TurboFect (A’–D’). A and A’, PoB1; B and B’, PoBf; C and C’, PoB2; D and D’, PoBh. Green signals indicate the expression of EGFP. Bar=100μm.

The cell lines grew well at 24℃. It has been reported that the FG cell lines exhibited optimal growth at the same temperature (Tong., 1997). Therefore, this temperature was used to maintain the cultures. The four cell lines showed different reactions to FBS (Fig.3). In general, PoB1 and PoB2 were independent of FBS concentration during the growth period, whereas PoBf and PoBh showed partial independent to FBS. Karyotype analyses of the PoB1, PoBf, PoB2, and PoBh cell lines revealed that all four cell lines did not possess a diploid chromosome number of 2=48, which is identical to the modal of(Tong., 1997; Wang., 2009). Their chromosome numbers ranged from less than 20 to more than 100. The rate of diploid chro- mosomes in the cell lines was low and the chromosome numbers of approximately 50% of the cell lines were 60–72. The distribution and change of chromosome of the four cell lines indicate that their genetic characteristics may have changed. We also checked the DNA content of these cell lines through flow cytometry. Results showed that the DNA contents of these cell lines were 1.5–2 times of that of normal cell lines.The presence of metacentric, sub-telocen- tric and spot chromosomes suggests the occurence of chro- mosome duplication, assembly and fracture in these cell lines. Alternative explanations to the aneuploidy have been elaborated as cell fusion, resulting from the possibility that the chromosomes simply failed to separate properly (Chen., 2006). Examination of karyotype and growth characteristics indicated that PoB1, PoB2, PoBf and PoBh were transformed (Frank, 1994) and were immortal similar to the reported FG cell lines(Wang., 2008). Even though these cell lines were all derived from the brain tissue, molecular identification indicated that they were different from each other (Fig.5). All four cell lines significantly expressed, a marker for the NSCs. This result suggests that the cell lines still exhibit some properties of NSCs. Nestin is an intermediate filament protein which is abundantly expressed during early embryogenesis in neuro-epithelial stem cells and then is downregulated in mature cells. On the basis of its expression and immunochemistry,has been recognized as a marker for NSCs in brain tissues and many brain cells(Strojnik., 2007; Wei., 2008). In the present study, the PoB2 and PoBf lines shared similar expression patterns, while onlyexpressed in all of the tested cells. This result indicates that these PoB2 and PoBf are still neural stem cells or progenitor cells with a limited differentiation towards neurons. The PoB1 cell line also expressedmRNA. Slc6a4, encoded by thegene, is also known as a serotonin transporter (SERT or 5-HTT). SERT is located in axons, where it is concentrated in varicosities and terminal boutons.Thus it is anexquisite marker for serotonergic synapses (Hummerich., 2004). In recent years, several reports have provided com- pelling evidences for the expression of functionally active SERT in glial cells lines and primary astrocytes (Hirst., 1998; Kubota., 2001; Malynn., 2010). Therefore, the PoB1 cell line was recognized to comprise neural stem cells or progenitor cells with some differentiation towards serotonergic neurons. The PoBh line expressed not onlybut also weakand significantmRNA. In addition to,has also been recognized as a marker gene for NSCs (Archer., 2011). Aldh1L1 is ro- bustly expressed in brain astrocytes and cells in NSC cul- ture conditions could promote the activity of Aldh1L1 (Ca- hoy., 2008; Yang., 2011; Foo andDougherty, 2013). Moreover, another intermediate filament protein GFAP also expresses in differentiated astrocytes (Lendahl., 1990;Zendra, 1991;Strojnik., 2007). GFAP-/- astrocytes pro- duce both nestin and vimentin, and retain the ability to formneurons (Pekny., 1998). Therefore, we recognized PoBh cells as primary astrocytes with no or limited differentiation. The deficiency of GFAP suggests that the as- trocytes have not differentiated or GFAP gene loss has oc- curred during transformation as GBC1 cells (Wen., 2008b). Furthermore, the four cell lines showed a similar morphology to previously reported NSC lines of other fishes(Hinsch and Zupanc 2006; Wen., 2008a, 2008b;Ser- vili., 2009; Huang., 2011). Neurosphere formation was also observed in the four cell lines (Fig.2). This observation further validates that these cell cultures are NSCs or progenitor cells (Servili., 2009).

We also tested the PoB1, PoBf, PoB2 and PoBh cell lines for potential use in transfection and have observed successful signals (Fig.6). The transfection capability of the cells suggests their potential use as modelsfor studies on neurogenesis and fish nerv-related genes’ functions,which can elucidate the mechanisms of neurophysiology, neuro- toxicity and neuroendocrinology.

In summary, four brain cell lines designated as PoB1, PoBf, PoB2 and PoBh were established from the brain of. These cell lines grew well and were characterized as NSCs or progenitor cells. The four cell lines may serve as useful tools for the study of genetic manipulation, cytotoxicity and virus pathogenesis in relation to brain de- velopment.

Acknowledgements

This work was supported by the National High-Tech Re- search and Development Program of China (Nos. 2012AA10A402, 2012AA10A408).

Archer, T. C., Jin, J., and Casey, E. S., 2011. Interaction of Sox1, Sox2, Sox3 and Oct4 during primary neurogenesis.,350(2): 429-440.

Cahoy, J. D., Emery, B., Kaushal, A., Foo, L. C., Jennifer, L. Z., Karen, S. C.,Yi, X.,Jane, L. L.,Paul, A. K.,Sergey, A. K.,Wesley, J. T., andBen, A. B., 2008. A transcriptome database for astrocytes, neurons, and oligodendrocytes: A new resource for understanding brain development and function.,28(1): 264-278.

Cai, J., 2002. Properties of a fetal multipotent neural stem cell (NEP cell).,251(2): 221-240.

Charrier, C., Coronas, V., Fombonne, J., Roger, M., Jean, A., and Krantic, S., 2006. Characterization of neural stem cells in the dorsal vagal complex of adult rat byproliferation labeling andneurosphere assay.,138(1): 5-16.

Chen, K. A., Laywell, E. D., Marshall, G., Walton, N., Zheng, T., and Steindler, D. A., 2006. Fusion of neural stem cells in culture.,198(1): 129-135.

Corti, S., Nizzardo, M., Nardini, M., Donadoni, C., Locatelli, F., and Papadimitriou, D., 2007. Isolation and characterization of murine neural stem/progenitor cells based on prominin-1 expression.,205(2): 547-562.

Duan, X., Kang, E. K., Liu, Y. C., Ming, G. L., and Song, H. J., 2008. Development of neural stem cell in the adult brain.,18(1): 108-115.

Foo, L. C., and Dougherty, J. D., 2013. Aldh1L1 is expressed by postnatal neural stem cells.,61(9): 1533-1541.

Frank, D. A., 1994. Culture of animal cells: A manual of basic technique.,57(2):247-248.

Grandel, H., Kaslin, J., Ganz, J., Wenzel, I., and Brand, M., 2006. Neural stem cells and neurogenesis in the adult zebrafish brain: Origin, proliferation dynamics, migration and cell fate.,295(1): 263-277.

Hasoon, M. F., Daud, H. M., Abdullah, A. A., Arshad, S. S., and Bejo, H. M., 2011. Development and partial characterization of new marine cell line from brain of Asian sea bassfor virus isolation.,47(1): 16-25.

Hinsch, K., and Zupanc,G. K., 2006. Isolation, cultivation, and dif-ferentiation of neural stem cells from adult fish brain.,158(1): 75-88.

Hirst, W. D., Price, G. W., Rattray, M., and Wilkin, G. P., 1998. Serotonin transporters in adult rat brain astrocytes revealed by [3H]5-HT uptake into glial plasmalemmal vesicles.,33(1): 11-22.

Huang, X., Huang, Y., Ouyang, Z., and Qin, Q., 2011. Establish- ment of a cell line from the brain of grouper () for cytotoxicity testing and virus pathogenesis.,311(1-4): 65-73.

Hummerich, R., Reischl, G., Ehrlichmann, W., Machulla, H. J., Heinz, A., and Schloss, P., 2004. DASBbinding cha- racteristics on human recombinant monoamine transporters with regard to its potential as positron emission tomography (PET) tracer.,90(5): 1226.

Ku, C. C., Teng, Y. C., Wang, C. S., and Lu, C. H., 2009. Establishment and characterization of three cell lines derived from the rockfish grouper: Use for transge- nic studies and cytotoxicity testing.,294(1-2): 147-151.

Kubota, N., Kiuchi, Y., Nemoto, M., Oyamada, H., Ohno, M., and Funahashi, H., 2001. Regulation of serotonin transporter gene expression in human glial cells by growth factors.,417(1-2): 69-76.

Lendahl, U., Zimmerman, L. B., and Mckay, R. D. G., 1990. CNS stem cells express a new class of intermediate filament protein.,60(4): 585-595.

Malynn, S., Torres, A. C., Moynagh, P., and Haase, J., 2010. The pro-inflammatory cytokine TNF-α regulates the expression of the serotonin transporter (SERT) gene in primary astrocytesand the C6 glioma cell line.,24: S70-S71.

Pekny, M., Eliasson, C., Chien, C. L., Kindblom, L. G., Liem, R., and Hamberger, A., 1998. GFAP-deficient astrocytes are capa- ble of stellationwhen cocultured with neurons and ex- hibit a reduced amount of intermediate filaments and an increased cell saturation density.,239(2): 332-343.

Poyer, J., and Hartmann, J., 1992. Establishment of a cell line from brain tissue of the silky shark,.–,28(11-12): 682-684.

Servili, A., Bufalino, M. R., Nishikawa, R., Melo, I. S. D., Muo- Oz-Cueto, J. A., and Lee, L. E. J., 2009. Establishment of long term cultures of neural stem cells from adult sea bass,.,152(2): 245-254.

Song, H., He, Y., Ma, L., Zhou, X., Liu, X., and Qi, J., 2015. Cha- racterisation of kisspeptin system genes in an ovoviviparous teleost:.,214: 114-125.

Strojnik, T., RoSland, G. V., Sakariassen, P. O., Kavalar, R., and Lah, T., 2007. Neural stem cell markers, nestin and musashi proteins, in the progression of human glioma: Correlation of nestin with prognosis of patient survival., 68(2): 133-143.

Sun, A., Wang, T. Z., Wang, N., Liu, X. F., Sha, Z. X., and Chen, S. L., 2015. Establishment and characterization of an ovarian cell line from half-smooth tongue.,86(1): 46-59.

Taupin, P., 2006. Neurogenesis in the adult central nervous system.,329(7): 465-475.

Tong, S. L., Li, H., and Miao, H. Z., 1997. The establishment and partial characterization of a continuous fish cell line FG-9307 from the gill of flounder.,156(3-4): 327-333.

Tsai, C. L., Wang, L. H., and Lin, Y. H., 2001. Effects of estrogen and neurotransmitters on the primary cultures of tilapia brain from different ages.,129(1): 111-113.

Wang, X. B., Zhang, Q. Q., Chen, Y. J., Qi, J., Wang, Z. G., and Wang, X. L., 2009. Cytogenetic characterization of olive flounder: DNA content, karyotype, agnors and location of major ribosomal genes.,28 (4): 72-77.

Wang, X. B., Zhang, Q. Q., Qi, J., Wang, Z. G., and Wang, X. L., 2008. Variation analysis of karyotype of flounder gill cell line.,15(3): 483-487.

Wei, L. C., Shi, M., Cao, R., Chen, L. W., and Chan, Y. S., 2008. Nestin small interfering RNA (siRNA) reduces cell growth in cultured astrocytoma cells.,1196: 103-112.

Wen, C. M., Cheng, Y. H., Huang, Y. F., and Wang, C. S., 2008a. Isolation and characterization of a neural progenitor cell line from tilapia brain.,149(2): 167-180.

Wen, C. M., Lee, C. W., Wang, C. S., Cheng, Y. H., and Huang, H. Y., 2008b. Development of two cell lines frombrain tissue for characterization of betanodavirus and megalocytivirus infectivity and propagation., 278(1-4): 14-21.

Wen, C. M., Wang, C. S., Chin, T. C., Cheng, S. T., and Nan, F. H., 2010. Immunochemical and molecular characterization of a novel cell line derived from the brain of(Teleostei, Perciformes): A fish cell line with oligodendrocyte progenitor cell and tanycyte characteristics.,156(2): 224-231.

Wu, Y. C., and Chi, S. C., 2006. Persistence of betanodavirus in Barramundi brain (BB) cell line involves the induction of interferon response.,21(5): 540-547.

Yang, Y. J., Vidensky, S., Jin, L.,Jie, C. F.,Lorenzini, I.,Frankl, M., andRothstein, D. J., 2011. Molecular comparison of GLT1+and ALDH1l1+astrocytesin astroglial reporter mice.,59(2): 200-207.

Yu, Z. N., Kong, X. Y., and Xie, Z. Y., 1995. Studies on karyotypes of fishes of economic importance in coastal waters of ShandongPeninsula.,2(2): 1-6.

Zendra, E. Z., 1991. Regulation of intermediate filament gene ex- pression.,3(1): 67-74.

Zupanc, G. K., 2008. Adult neurogenesis and neuronal regeneration in the brain of teleost fish.–,102(4-6): 357-373.

#The two authors contributed equally to this work.

. E-mail: qzhang@ouc.edu.cn

January 3, 2020;

March 26, 2020;

May 8, 2020

(Edited by Qiu Yantao)