Abstract
Mesenchymal stem cell (MSC) therapy is being increasingly used to treat dogs and horses with naturally-occurring diseases. However these animals also serve as critical large animal models for ongoing translation of cell therapy products to the human market. MSC manufacture for clinical use mandates improvement in cell culture systems to meet demands for higher MSC numbers and removal of xeno-proteins (i.e. fetal bovine serum, FBS). While serum-free media (SFM) is commercially available, its affects on MSC phenotype and immunomodulatory functions are not fully known. The objective of this study was to determine if specific MSC culture conditions, MSC expansion in HYPERFlasks® or MSC expansion in a commercially available SFM, would alter MSC proliferation, phenotype or immunomodulatory properties in vitro. MSCs cultured in HYPERFlasks® were similar in phenotype, proliferative capacity and immunomodulatory functions to MSCs grown in standard flasks however MSC yield was markedly increased. HYPERFlasks® therefore provide a viable option to generate greater cell numbers in a streamlined manner. Canine and equine MSCs expanded in SFM displayed similar proliferation, surface phenotype and inhibitory effect on lymphocyte proliferation in vitro. However, MSCs cultured in the absence of FBS secreted significantly less PGE2, and were significantly less able to inhibit IFNγ secretion by activated T-cells. Immunomodulatory functions altered by expansion in SFM were species dependent. Unlike equine MSCs, in canine adipose-derived MSCs, the inhibition of lymphocyte proliferation was not principally modulated by PGE2. The removal of FBS from both canine and equine MSC culture systems resulted in altered immunomodulatory properties in vitro and warrants further investigation prior to moving towards FBS-free culture conditions.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Adult-derived multipotent mesenchymal stem cells (MSCs) hold great appeal for regenerative medicine therapeutic approaches in both human and veterinary medicine given their potent immunomodulatory and pro-regenerative properties [1, 2]. MSCs are defined in vitro by their morphology, their expression of a panel of cell surface markers and their potential to tri-lineage differentiate in vitro into adipose, bone and cartilage [3]. MSCs can be harvested from numerous tissue sources including bone marrow and adipose tissue followed by ex vivo expansion of isolated cells [2]. MSCs are being investigated for their potential clinical application in multiple disorders including orthopedic injuries and inflammatory/immune-mediated diseases [2, 4]. A deeper understanding of canine and equine MSC biology is critical to guide veterinary clinical trials as well as to assure appropriate translational research into naturally occurring diseases that could inform human clinical trials [5–7].
MSCs are traditionally expanded as an adherent monolayer in medium supplemented with fetal bovine serum (FBS). The Food and Drug Administration (FDA) requires that MSC products meet good manufacturing practice (GMP) and encourages the use of xeno-protein free culture conditions to decrease the potential for xeno-protein immune reactions and transmission of infectious diseases [8]. In addition, previous studies in human patients suggest that the development of anti-FBS antibodies in patients after MSC administration may be associated with attenuated clinical efficacy [9, 10]. FBS also has high lot-to-lot variability, which makes reproducibility extremely difficult [11–13]. Human MSCs maintain differentiation and proliferative capacities in xeno-protein free culture conditions, however there are also reports of induced senescence in vitro [11, 14–19]. The use of xeno-protein free culture conditions for canine and equine MSCs does not alter osteogenic and adipogenic differentiation potential, but did lead to inferior MSC proliferation [13]. The effect of serum free media (SFM) on canine and equine MSC immunomodulatory functions has not yet been determined.
In addition to the concerns regarding the use of FBS, there is an increasing need for the expansion of even greater MSC numbers for clinical applications [20]. MSC culture in small tissue-culture flasks is inefficient and requires a significant amount of time and reagents in order to achieve the required cell numbers for treatment. Large bioreactors permit the expansion of greater absolute MSC numbers, while greatly reducing reagent costs and technician time [21, 22]. HYPERFlasks® are multilayer flasks that use gas permeable chambers coated with CellBIND® to optimize cell binding. However, the CellBIND® coating is a novel proprietary substance, and its effects on canine and equine MSC proliferative capacity and immunomodulatory properties have not been investigated.
The objectives of this study were to investigate the effects of xeno-free, and CellBIND® (HYPERFlasks®) culture conditions on canine and equine MSC functions in vitro compared to standard culture conditions. We hypothesized that MSC expansion in SFM or HYPERFlasks® would not alter canine or equine MSC proliferation, surface phenotype or immunomodulatory properties in vitro. We found that SFM and CellBIND® did not alter MSC proliferation or surface phenotype and MSCs cultured in both conditions were effective in inhibiting T-cell proliferation in vitro. However MSCs cultured in SFM displayed significant alterations in mediator secretion patterns. Our study suggests that while the use of CellBIND® coated HYPERFlasks® are suitable for MSC culture upscale, the use of commercially available SFM needs closer investigation prior to clinical implementation.
Materials and Methods
Animal Cells
Equine
Low passage (P2-P5) bone marrow-derived MSCs (eMSCs) from 5 horses were obtained from the UC Davis (UCD) William R. Pritchard Veterinary Medical Teaching Hospital Regenerative Medicine Laboratory. These samples were originally submitted for MSC expansion for autologous patient treatment. Excess eMSCS not used for treatment were donated for research purposes with written owner consent.
Canine
Low passage (P2-P5) fat-derived MSCs from 5 dogs were obtained from falciform fat collected from UCD William R. Pritchard Veterinary Medical Teaching Hospital patients undergoing routine abdominal surgery. Fat was collected under an approved Institutional Animal Care and Use Committee and the Clinical Trials Review Board protocol at UCD. Fat was processed and canine adipose-derived MSCs (cMSCs) were isolated, expanded and cryopreserved exactly as previously described [23, 24].
MSC Culture and Expansion
Cryopreserved MSCs were thawed in a 37 °C water bath and seeded into 1 of 3 different culture conditions. The first group consisted of standard culture conditions [25, 26]. These cells were plated at a density of 5000 cells/cm2 into T185 flasks (Thermo Fisher Scientific, Waltham, MA) in the standard medium [Dulbecco’s Modified Eagle’s Medium (DMEM, Gibco, Invitrogen, Carlsbad, CA) with 10 % FBS (HyClone, Logan, UT) and 1 % penicillin-streptomycin (Gibco). The second group consisted of MSCs plated in HYPERFlasks® (Corning Inc., Tewksbury, MA). These cells were initially thawed in standard conditions and were then passed into HYPERFlasks® at 5000 cells/cm2 in standard medium. The third group consisted of MSCs cultured in SFM. MSCs do not readily adhere to plastic in the absence of serum. Therefore, in the third group, MSCs were thawed into flasks (Thermo Fisher Scientific) that had been coated with bovine fibronectin (25–50 μg/mL, Biomedical Technologies Inc., Stoughton, MA) for 24 h after which cells were replated at a density of 5000 cells/cm2 in StemPro® MSC SFM (Gibco) supplemented with 1 % L-glutamine (Gibco) and 1 % Pen/Strep (Gibco). All MSCs were grown to 70 % confluence in a standard cell culture incubator conditions (37 °C, 5 % CO2). During expansion, MSCs were monitored daily for morphologic alterations. Cells cultured under standard conditions and in HYPERFlasks® were dissociated using 0.05 % trypsin/EDTA (Gibco) and neutralized with standard media containing FBS. MSCs grown in SFM were harvested using HyQTase (HyClone), and resuspended in Dulbecco’s Phosphate Buffered Saline (DPBS, Gibco).
MSC Proliferation
Equine MSCs and cMSCs were harvested after 4 days of culture for proliferation studies. At day 4, MSCs were roughly 70 % confluent, and were counted using an automated cell counter (COULTER® AcT-Diff Cell Counter, Beckman Coulter Inc., Miami, FL). Cell doubling times were calculated as previously reported [26]. Absolute numbers were also recorded and normalized for differences in flask surface area in each culture condition.
MSC Phenotype
Equine
After harvesting, MSCs expanded in each of the three conditions were washed and incubated with antibodies directed against CD90 (VMRD, Pullman, WA, clone DH24A) [27, 28], CD44 (AbD Serotec, Raleigh, NC, clone CVS18) [29], CD29 (Beckman Coulter Inc., clone 4B4LDC9LDH8) [29], F6B (a pan leukocyte antibody, a generous gift from Dr. Jeffrey Stott, UCD, School of Veterinary Medicine) [30], CD86 (BD Biosciences, Franklin Lakes, NJ, clone IT2.2) [28], MHC I (AbD Serotec; clone CVS22) [31], and MHC II (AbD Serotec; clone CVS20) [28].
Canine
After harvesting, MSCs expanded in each of the 3 conditions were washed and incubated with antibodies directed against CD90 [23], CD45 [23], MHCII (all from Leukocyte Antigen Biology Laboratory, UCD, School of Veterinary Medicine, clone CA1.4G8, CA12.10C12, CA2.1C12 respectively) [23], CD34 (BD Biosciences, clone RAM34) [23], CD54 (a generous gift from C. Smith, Houston, TX, clone CL18.1D8) [23] and CD44 (R&D Systems, Minneapolis, MN, clone 69-S5).
Equine MSC and cMSC phenotype were evaluated via flow cytometry (Cytomics, Beckman Coulter FC500, Hialeah, FL). Flow cytometry data was analyzed using FlowJo flow cytometry software (Tree Star Inc., Ashland, OR).
Mixed Leukocyte Reaction (MLR)
Equine
Peripheral blood was collected into tubes containing acid–citrate dextrose (ACD; BD Biosciences) via jugular venipuncture. T lymphocytes were enriched from peripheral blood mononuclear cells (PBMCs) using nylon wool and plated exactly as previously described [27]. To inhibit MSC proliferation, MSCs were irradiated (10Gy, Varian 2100C linear accelerator, Varian Medical Systems Inc., Palo Alto, CA) and kept on ice before plating in each corresponding medium. Enriched T-cells were stimulated with phytohemagglutin at 5 μg/mL (PHA, Sigma-Aldrich, St. Louis, MO). Enriched T-cells from donor horses and allogeneic MSCs were plated exactly as previously described [27, 32].
Canine
Peripheral blood was collected into tubes containing sodium heparin (Vacutainer®, BD Biosciences) via jugular venipuncture. PBMCs were obtained using a discontinuous Ficoll gradient and were plated with allogeneic cMSCs exactly as previously described [24]. PBMCs were used for these assays in canines due to the large blood volume necessary to isolate lymphocytes using a nylon wool gradient. PMBCs were activated with 5 μg/mL concanavalin A (Con-A, Sigma-Aldrich).
After 3 days of co-culture, wells were treated with 1 mM Bromodeoxyuridine (BrdU, BD Biosciences). Twenty-four hours post BrdU treatment, leukocytes were collected and cells were stained for nuclear BrdU incorporation per manufacturer directions (FITC BrdU Flow Kit, BD Biosciences) and read by flow cytometry.
At the time of leukocyte collection, culture supernatant was collected, centrifuged and stored at −80 °C, as previously described [27] for the measurement of secreted mediators. The following ELISA kits were used: equine PGE2 (Prostaglandin E2 Parameter Assay Kit; R&D Systems) [33], canine PGE2 (Prostaglandin E2 Express EIA kit (Monoclonal); Cayman Chemical Company, Ann Arbor, MI) [24], equine interleukin10 (IL-10; Equine IL-10 Duoset; R&D Systems) [32], equine interferon-γ (IFNγ; Equine IFNγ Duoset; R&D Systems) [34] and equine tumor necrosis factor-α (TNFα; Equine TNFα screening kit; Thermo Fisher Scientific) [34]. Equine IL-6 was measured exactly as previously described [35]. ELISA plates were read spectrophotometrically on a microplate reader with Gen5 software (Synergy HT Multi-Mode, Biotek, Winooski, VT). Canine TNFα, IFNγ, IL-6 and IL-10 were determined using a canine cytokine magnetic bead panel (Milliplex Map, EMD Millipore, Billerica, MA) per manufacturer instructions and were read on a Bio-Plex 200 using Bio-Plex Manager 4.1.1 software (Bio-Rad Laboratories, Hercules, CA).
In some assays the cyclooxygenase (COX) inhibitor indomethacin was used to chemically block PGE2 production. Indomethacin was added to MLR assays during plating at a concentration of 10 μM (Sigma-Aldrich) exactly as previously described [32].
Statistical Analysis
Results are presented as median and interquartile range. Data were analyzed using non-parametric Mann-Whitney-Wilcoxon t-test (GraphPad InStat version 3.06 for Windows, La Jolla, CA). P < 0.05 was considered statistically significant.
Results
Equine and Canine MSC Cultured in HYPERFlasks® Did not Display Altered Proliferative Capacity, Immune-Suppressive Qualities or Mediator Profile
Equine
No alterations in the cell doubling times of eMSCs cultured in HYPERFlasks® (2.4 ± 0.3 days) were observed when compared to standard conditions (2.0 ± 0.6 days, Fig. 1a). However there was a marked increase in the absolute number of eMSCs produced after culture in HYPERFlasks®. This increase was due to the increased culture surface area (1721 cm2). Cells plated in HYPERFlasks® yielded ~4× more eMSCs than cells plated in standard conditions (44 × 106 ± 24 × 106 total cells compared to 9.3 × 106 ± 5 × 106 total cells).
We have previously published the immunomodulatory phenotype of equine MSCs cultured in standard conditions including results from MLR experiments [27, 32]. We found that equine MSCs inhibit activated lymphocyte proliferation via the induction of cell cycle arrest, inhibition IFNγ and TNFα secretion from activated T cells and the secretion of PGE2 and IL-6, among other mediators [27, 32]. The goal of the current project was to determine if this constellation of immune properties would be maintained after culture expansion in a more relevant cell expansion system and after expansion in SFM that did not contain FBS. Equine MSCs cultured in HYPERFlasks® maintained their ability to inhibit lymphocyte proliferation compared to eMSCs cultured in standard conditions (Fig. 1b). Mediator analysis of supernatants from MLR experiments demonstrated there was no difference in IL-6 (Fig. 1c) or PGE2 (Fig. 1d) secretion by activated eMSC cultured in HYPERFlasks® compared with eMSCs cultured in standard conditions. Equine MSCs grown in HYPERFlask® were as effective as eMSC cultured in standard conditions in inhibiting TNFα (Fig. 1e) and IFNγ (Fig. 1f) secretion by activated T-cells. However MSCs cultured in HYPERFlasks® secreted significantly higher concentrations of (P < 0.05) IL-10 (Fig. 1f) compared to eMSC cultured in standard conditions.
Canine
As with eMSCs, we have previously published the immunophenotype of canine MSCs after culture in standard conditions in our laboratory [24, 36]. As such, we focused on if the culture expansion of cMSCs in a larger, more relevant flask system and in the absence of FBS would result in a different immunophenotype than standard culture. cMSCs cultured in HYPERFlasks® generally mirrored findings with eMSCs. Whereas cMSC doubling time was not altered when cultured in HYPERFlasks® (2 ± 0.6 days) compared with standard culture conditions (1.6 ± 0.2 days, Fig. 2a), HYPERFlasks® yielded ~18× more cells due to increased surface area (39 × 106 ± 1.7 × 106 total cells as compared to 2.3 × 106 ± 6 × 106 in two flasks cultured under standard conditions). cMSC cultured in HYPERFlasks® were as effective as cMSC cultured in standard conditions in inhibiting PBMC proliferation (Fig. 2b). There was no difference in the ability of cMSC to secrete IL-6 (Fig. 2c) and PGE2 (Fig. 2d) and to inhibit TNFα (Fig. 2e), IFNγ (Fig. 2f) and IL-10 (Fig. 2g) secretion by activated PBMCs for MSCs cultured in HYPERFlasks® compared to standard conditions.
MSC Surface Phenotype is not Altered by Culture Conditions
Equine
In all culture conditions, eMSCs were positive for CD90, CD44 and CD29. Similarly, eMSCs did not express MHC II, CD86 or F6B (pan leukocyte marker) regardless of cell culture condition (Table 1).
Canine
In all culture conditions, cMSCs were positive for CD44, CD54 and CD90. cMSCs did not express CD34, MHCII or CD45 (Table 1). Thus expansion of MSCs in either HYPERFlask® or in SFM did not alter standard cell surface protein expression in either eMSCs or cMSCs.
MSC Proliferation Capacity is not Altered by Culture in SFM
Equine
eMSCs had population doubling times of 2.4 ± 0.3 and 2.4 ± 0.9 days in standard conditions and in SFM conditions, respectively (Fig. 3a). There was no statistical difference in doubling time of eMSCs between culture with and without FBS (p > 0.05).
Canine
The population doubling times for cMSCs were 1.4 ± 0.3 and 1.7 ± 0.8 days in standard conditions and in SFM conditions, respectively (Fig. 3b). There was no statistical difference in doubling time between cMSC cultured in standard media when compared to the SFM condition (p > 0.05).
SFM Culture Conditions Alter eMSC Immunomodulatory Properties in Vitro
While SFM-eMSC were as effective as eMSC cultured in standard conditions in their capacity to inhibit T-cell proliferation in vitro (Fig. 4a), secreted protein concentrations in MLR supernatant were altered when SFM-eMSC were compared with eMSC cultured under standard conditions. While IL-6 secretion by activated MSC (Fig. 4b) was not altered by eMSC culture method, the secretion of IL-10 (Fig. 4c) and PGE2 (Fig. 4d) displayed reciprocal inverse changes. IL-10 secretion was markedly and significantly (P < 0.05) increased when activated T-cells were co-cultured with eMSCs grown without FBS however PGE2 concentration was markedly and significantly (P < 0.05) decreased. Moreover, the concentrations of the pro-inflammatory mediators, TNFα (Fig. 4e) and IFNγ (Fig. 4f) were significantly higher when activated T-cells were co-cultured with eMSCs cultured in the absence of FBS compared to eMSCs cultured with FBS.
SFM Culture Conditions Alter cMSC Immunomodulatory Properties in Vitro
Similar to eMSCs, cMSCs cultured in the absence of FBS were as effective in inhibiting PBMC proliferation in vitro as cMSCs grown under standard conditions. However, as in eMSCs, secreted protein concentration within the supernatants of these MLR experiments was altered by culture method. IL-6 and IL-10 secretion by activated cMSCs was not changed by the absence of FBS (Fig. 5a, b). However PGE2 secretion by activated cMSCs was markedly and significantly (P < 0.05) decreased in cMSCs cultured in the absence of FBS compared with cMSCs cultured in standard conditions. cMSCs cultured without FBS were similar in the ability to modulate TNFα secretion (Fig. 5e) by Con-A activated PBMC, compared to cMSCs in standard conditions. However IFNγ concentration was markedly and significantly (P < 0.05) higher when activated PBMCs were co-cultured with cMSCs in the absence of FBS.
MSC-Derived PGE2 Modulated Equine Lymphocyte Proliferation but was not Responsible for the Inhibition of Canine Lymphocyte Proliferation
We have previously reported that activated eMSCs from a variety of tissue sources inhibit T lymphocyte proliferation through a predominantly PGE2 mediated pathway [32]. This was determined through the use of indomethacin, a COX inhibitor, to block PGE2 synthesis and secretion. Given that eMSCs and cMSC cultured in the absence of FBS retained their capacity to inhibit lymphocyte proliferation in spite of secreting significantly less PGE2, we determined if PGE2 still mediated the inhibitory effect in MSCs cultured in SFM. In agreement with previous findings, blocking PGE2 production in eMSCs restored lymphocyte proliferation in standard conditions (Fig. 6a, p < 0.05). Similarly, blocking PGE2 synthesis in eMSCs cultured in the absence of FBS also inhibited T-cell proliferation (Fig. 6a, p > 0.05) suggesting that while the secretion of PGE2 is markedly decreased by eMSCs cultured without FBS, it is still the primary soluble factor that facilitates the inhibition of equine T-cell proliferation. In this study, blocking PGE2 synthesis by cMSCs did not restore lymphocyte proliferation in standard or SFM conditions (Fig. 6b).
Discussion
In this study we determined the immunomodulatory and phenotypic consequences of a high yield, high performance tissue culture flask and FBS-free culture conditions for the culture of canine and equine MSCs. Both animal species are of great veterinary and translational research significance [7]. We determined that the expansion of canine and equine MSCs in HYPERFlasks® did not adversely alter MSC phenotype or immunomodulatory function and markedly improved MSC yield by providing 4–18× more MSCs in the same amount of time as traditional culture methods. This increase in MSC yield will allow more efficient banking of cells for research and clinical use. These findings are consistent with human MSC literature and may suggest that expansion systems are suitable for large scale and GMP-grade clinical use [21, 37, 38]. While optimal dosing of MSC for clinical applications has not been fully defined in literature, there is evidence that MSCs may act in a dose response fashion [20]. Large upscale production and banking of MSC will provide an accessible off the shelf product that may potentially be used for high dose clinical use pending further dose response studies.
Although the expansion of cMSCs and eMSCs in the absence of FBS did not alter MSC proliferation, surface phenotype or their capacity to inhibit T-cell proliferation in vitro, MSC immunomodulatory properties were significantly altered. It is important to note that while serum was removed from the SFM condition, bovine fibronectin was used as the minimal foreign component to allow for MSC adherence. Fibronectin is an extracellular matrix glycoprotein involved in cell adherence. Given MSC proliferation was not alerted in SFM conditions, fibronectin likely had no significant effects on MSCs in culture. Both cMSCs and eMSCs expanded in SFM secreted significantly less PGE2 than cells grown in FBS-containing media. cMSCs and eMSCs were also less able to inhibit pro-inflammatory cytokine production. These findings are concerning as PGE2 is a key mediator by which MSCs exert many of their immunomodulatory and trophic effects [1, 2, 39]. Prior to the removal or substitution of FBS from culture systems, a clearer understanding of how species-specific MSCs activate, signal and secrete their trophic and immunomodulatory mediators will be critical.
In our experiments, IL-10 concentration was inversely related to PGE2 concentration in eMSCs. Notably, eMSC cultured in HYPERFlasks® also significantly increased IL-10 production. These observations prompted us to hypothesize that in the relative absence of PGE2 secretion by activated MSCs, an alternative cellular pathway could be engaged which results in increased secretion (likely by activated T regulatory cells) of the potent immunoregulatory cytokine, IL-10. We further hypothesized that while the inhibition of PGE2 synthesis in standard culture conditions will rescue lymphocyte proliferation, such a rescue will not be seen in SFM conditions. Our results demonstrate that while IL-10 secretion was markedly induced in SFM conditions, PGE2 was still the primary effector mediator inhibiting equine lymphocyte proliferation, suggesting that a basal level of PGE2 in an MLR setting is sufficient to induce an inhibitory effect on T-cell proliferation. A similar response to PGE2 blocking was not seen in cMSCs, suggesting that PGE2 may play a less significant role in inhibiting lymphocyte proliferation in this species. These findings are consistent with previous studies in our laboratory [24] but are in disagreement with other studies that indicate the necessary role of PGE2 for cMSC mediated immune regulation [40, 41]. These discrepancies may be explained by differing methodologies, variable enrichment of T-cells versus PBMCs and perhaps MSC tissue source. Most notably, in our hands, cMSCs co-cultured with stimulated PBMCs produce nearly 10× the levels of PGE2 as compared to previous reports [40, 41]. Results from this in vitro study suggest that PGE2 secretion is not the primary mechanism by which MSCs mediate immunomodulation in dogs. An in-depth investigation of the role that MSC-derived PGE2 plays in lymphocyte regulation in dogs is warranted.
In this study, we discovered a disconnect between the inhibition of lymphocyte proliferation and a corresponding decrease in the proinflammatory mediators IFNγ and TNFα typically noted in a MLR [24, 32]. MSCs cultured in SFM markedly inhibited lymphocyte proliferation however the secretion of the pro-inflammatory mediators IFNγ (canine and equine) and TNFα (equine) was poorly inhibited. These data further suggest that in the absence of serum in the culture media, MSC immunomodulatory properties are compromised. The use of SFM for human MSC culture has remained controversial [11]. There have been reports that human MSCs can readily be expanded in SFM, while other groups argue that for MSCs to be expanded in serum free conditions, cytokines and other growth factors must be supplemented [11]. Our data coincides with previous reports, which suggest that while MSCs can proliferate in serum free conditions, sustained immunomodulatory properties in vitro are most potent in the presence of FBS [42–44].
The objectives of this study were to investigate potential modifications to ex vivo MSC expansion that would increase MSC yield and potentially permit removal of FBS to decrease the risk of FBS-induced immune response and culture heterogeneity. Our results suggest that HYPERFlask® provide a suitable scale up alternative to standard MSC culture, while substantially minimizing technician time and reagents required for culture of larger MSC doses. We also demonstrated that MSCs can be expanded successfully to achieve higher absolute cell numbers using HYPERFlask® without altering basic MSC characteristics including proliferation, phenotype or immunomodulatory functions. It can also be concluded that while canine and equine MSCs can be successfully cultured in a commercially available SFM media that does not alter surface phenotype or proliferative capacity, differing results in the mediator secretion profile warrant further investigation before the use of this media should be recommended for use in the clinical setting.
In conclusion, both eMSCs and cMSCs can be cultured in HYPERFlask® vessels to generate greater absolute numbers of MSC without altering MSC characteristics. Culturing MSCs in a commercially available SFM did not alter MSC proliferative capacity, surface protein phenotype or immune functions, however the cytokine profile was drastically altered. These findings warrant further studies for the use of xeno-free mediums for the culture of veterinary MSCs. These results also highlight species differences of MSCs and the need to further elucidate changes in mechanisms by which MSCs downregulate inflammation in different species.
ACD Acid-citrate dextrose, BrdU Bromodeoxyuridine, cMSC Adipose derived canine mesenchymal stem cell, DMEM Dulbecco’s Modified Eagle Medium, DPBS Dulbecco phosphate buffered saline, ELISA Enzyme-linked immunosorbent assay, eMSC Bone marrow derived equine mesenchymal stem cell, FBS Fetal bovine serum, GMP Good manufacturing practice, IFNγ Interferon-γ, MSC Mesenchymal stem cell, PBMC Peripheral blood mononuclear cells, PGE 2 Prostaglandin E2, SFM Serum free media, TNFα Tissue necrosis factor α, UCD University of California, Davis
References
Carrade, D. D., & Borjesson, D. L. (2013). Immunomodulation by mesenchymal stem cells in veterinary species. Comparative Medicine, 63(3), 207–217.
Singer, N. G., & Caplan, A. I. (2011). Mesenchymal stem cells: mechanisms of inflammation. Annual Review of Pathology, 6, 457–478. doi:10.1146/annurev-pathol-011110-130230.
Dominici, M., Le Blanc, K., Mueller, I., Slaper-Cortenbach, I., Marini, F., Krause, D., et al. (2006). Minimal criteria for defining multipotent mesenchymal stromal cells. The international society for cellular therapy position statement. Cytotherapy, 8(4), 315–317. doi:10.1080/14653240600855905.
Arnhold, S., & Wenisch, S. (2015). Adipose tissue derived mesenchymal stem cells for musculoskeletal repair in veterinary medicine. American Journal of Stem Cells, 4(1), 1–12.
Fortier, L. A., & Travis, A. J. (2011). Stem cells in veterinary medicine. Stem Cell Research & Therapy, 2(1), 9. doi:10.1186/scrt50.
Borjesson, D. L., & Peroni, J. F. (2011). The regenerative medicine laboratory: facilitating stem cell therapy for equine disease. Clinics in Laboratory Medicine, 31(1), 109–123. doi:10.1016/j.cll.2010.12.001.
Kol, A., Arzi, B., Athanasiou, K. A., Farmer, D. L., Nolta, J. A., Rebhun, R. B., et al. (2015). Companion animals: translational scientists’ new best friends. Science Translational Medicine, 7(4).
Murphey, D. B. (1998). Guidance for industry: Guidance for human somatic cell therapy and gene therapy. In: U.S. Food and Drug Administration, Vaccines, Blood & Biologics. http://www.fda.gov/BiologicsBloodVaccines/GuidanceComplianceRegulatoryInformation/Guidances/CellularandGeneTherapy/ucm072987.htm.
Horwitz, E. M., Gordon, P. L., Koo, W. K., Marx, J. C., Neel, M. D., McNall, R. Y., et al. (2002). Isolated allogeneic bone marrow-derived mesenchymal cells engraft and stimulate growth in children with osteogenesis imperfecta: implications for cell therapy of bone. Proceedings of the National Academy of Sciences of the United States of America, 99(13), 8932–8937. doi:10.1073/pnas.132252399.
Sundin, M., Ringden, O., Sundberg, B., Nava, S., Gotherstrom, C., & Le Blanc, K. (2007). No alloantibodies against mesenchymal stromal cells, but presence of anti-fetal calf serum antibodies, after transplantation in allogeneic hematopoietic stem cell recipients. Haematologica, 92(9), 1208–1215.
Mannello, F., & Tonti, G. A. (2007). Concise review: no breakthroughs for human mesenchymal and embryonic stem cell culture: conditioned medium, feeder layer, or feeder-free; medium with fetal calf serum, human serum, or enriched plasma; serum-free, serum replacement nonconditioned medium, or ad hoc formula? All that glitters is not gold! Stem Cells, 25(7), 1603–1609. doi:10.1634/stemcells.2007-0127.
Kinzebach, S., & Bieback, K. (2013). Expansion of mesenchymal stem/stromal cells under xenogenic-free culture conditions. Advances in Biochemical Engineering/Biotechnology, 129, 33–57. doi:10.1007/10_2012_134.
Schwarz, C., Leicht, U., Rothe, C., Drosse, I., Luibl, V., Rocken, M., et al. (2012). Effects of different media on proliferation and differentiation capacity of canine, equine and porcine adipose derived stem cells. Research in Veterinary Science, 93(1), 457–462. doi:10.1016/j.rvsc.2011.08.010.
Li, C. Y., Wu, X. Y., Tong, J. B., Yang, X. X., Zhao, J. L., Zheng, Q. F., et al. (2015). Comparative analysis of human mesenchymal stem cells from bone marrow and adipose tissue under xeno-free conditions for cell therapy. Stem Cell Research & Therapy, 6(1), 55. doi:10.1186/s13287-015-0066-5.
Shimazu, T., Mori, Y., Takahashi, A., Tsunoda, H., Tojo, A., & Nagamura-Inoue, T. (2015). Serum- and xeno-free cryopreservation of human umbilical cord tissue as mesenchymal stromal cell source. Cytotherapy, 17(5), 593–600. doi:10.1016/j.jcyt.2015.03.604.
Diez, J. M., Bauman, E., Gajardo, R., & Jorquera, J. I. (2015). Culture of human mesenchymal stem cells using a candidate pharmaceutical grade xeno-free cell culture supplement derived from industrial human plasma pools. Stem Cell Research & Therapy, 6(1), 28. doi:10.1186/s13287-015-0016-2.
Al-Saqi, S. H., Saliem, M., Quezada, H. C., Ekblad, A., Jonasson, A. F., Hovatta, O., et al. (2015). Defined serum- and xeno-free cryopreservation of mesenchymal stem cells. Cell and Tissue Banking, 16(2), 181–193. doi:10.1007/s10561-014-9463-8.
Al-Saqi, S. H., Saliem, M., Asikainen, S., Quezada, H. C., Ekblad, A., Hovatta, O., et al. (2014). Defined serum-free media for in vitro expansion of adipose-derived mesenchymal stem cells. Cytotherapy, 16(7), 915–926. doi:10.1016/j.jcyt.2014.02.006.
Muller, I., Kordowich, S., Holzwarth, C., Spano, C., Isensee, G., Staiber, A., et al. (2006). Animal serum-free culture conditions for isolation and expansion of multipotent mesenchymal stromal cells from human BM. Cytotherapy, 8(5), 437–444. doi:10.1080/14653240600920782.
Sharma, R. R., Pollock, K., Hubel, A., & McKenna, D. (2014). Mesenchymal stem or stromal cells: a review of clinical applications and manufacturing practices. Transfusion, 54(5), 1418–1437. doi:10.1111/trf.12421.
Rojewski, M. T., Fekete, N., Baila, S., Nguyen, K., Furst, D., Antwiler, D., et al. (2013). GMP-compliant isolation and expansion of bone marrow-derived MSCs in the closed, automated device quantum cell expansion system. Cell Transplantation, 22(11), 1981–2000. doi:10.3727/096368912X657990.
Robinson, S., Niu, T., de Lima, M., Ng, J., Yang, H., McMannis, J., et al. (2005). Ex vivo expansion of umbilical cord blood. Cytotherapy, 7(3), 243–250. doi:10.1080/14653240510027172.
Wood, J. A., Chung, D. J., Park, S. A., Zwingenberger, A. L., Reilly, C. M., Ly, I., et al. (2012). Periocular and intra-articular injection of canine adipose-derived mesenchymal stem cells: an in vivo imaging and migration study. Journal of Ocular Pharmacology and Therapeutics : the Official Journal of the Association for Ocular Pharmacology and Therapeutics, 28(3), 307–317. doi:10.1089/jop.2011.0166.
Kol, A., Foutouhi, S., Walker, N. J., Kong, N. T., Weimer, B. C., & Borjesson, D. L. (2014). Gastrointestinal microbes interact with canine adipose-derived mesenchymal stem cells in vitro and enhance immunomodulatory functions. Stem Cells and Development, 23(16), 1831–1843. doi:10.1089/scd.2014.0128.
Toupadakis, C. A., Wong, A., Genetos, D. C., Cheung, W. K., Borjesson, D. L., Ferraro, G. L., et al. (2010). Comparison of the osteogenic potential of equine mesenchymal stem cells from bone marrow, adipose tissue, umbilical cord blood, and umbilical cord tissue. American Journal of Veterinary Research, 71(10), 1237–1245. doi:10.2460/ajvr.71.10.1237.
Vidal, M. A., Walker, N. J., Napoli, E., & Borjesson, D. L. (2012). Evaluation of senescence in mesenchymal stem cells isolated from equine bone marrow, adipose tissue, and umbilical cord tissue. Stem Cells and Development, 21(2), 273–283. doi:10.1089/scd.2010.0589.
Carrade, D. D., Lame, M. W., Kent, M. S., Clark, K. C., Walker, N. J., & Borjesson, D. L. (2012). Comparative analysis of the immunomodulatory properties of equine adult-derived mesenchymal stem cells(). Cell Medicine, 4(1), 1–11. doi:10.3727/215517912X647217.
Carrade, D. D., Owens, S. D., Galuppo, L. D., Vidal, M. A., Ferraro, G. L., Librach, F., et al. (2011). Clinicopathologic findings following intra-articular injection of autologous and allogeneic placentally derived equine mesenchymal stem cells in horses. Cytotherapy, 13(4), 419–430. doi:10.3109/14653249.2010.536213.
Radcliffe, C. H., Flaminio, M. J., & Fortier, L. A. (2010). Temporal analysis of equine bone marrow aspirate during establishment of putative mesenchymal progenitor cell populations. Stem Cells and Development, 19(2), 269–282. doi:10.1089/scd.2009.0091.
Watson, J. L., Stott, J. L., Blanchard, M. T., Lavoie, J. P., Wilson, W. D., Gershwin, L. J., et al. (1997). Phenotypic characterization of lymphocyte subpopulations in horses affected with chronic obstructive pulmonary disease and in normal controls. Veterinary Pathology, 34(2), 108–116.
Carrade, D. D., Affolter, V. K., Outerbridge, C. A., Watson, J. L., Galuppo, L. D., Buerchler, S., et al. (2011). Intradermal injections of equine allogeneic umbilical cord-derived mesenchymal stem cells are well tolerated and do not elicit immediate or delayed hypersensitivity reactions. Cytotherapy, 13(10), 1180–1192. doi:10.3109/14653249.2011.602338.
Carrade Holt, D. D., Wood, J. A., Granick, J. L., Walker, N. J., Clark, K. C., & Borjesson, D. L. (2014). Equine mesenchymal stem cells inhibit T cell proliferation through different mechanisms depending on tissue source. Stem Cells and Development, 23(11), 1258–1265. doi:10.1089/scd.2013.0537.
Frisbie, D. D., Al-Sobayil, F., Billinghurst, R. C., Kawcak, C. E., & McIlwraith, C. W. (2008). Changes in synovial fluid and serum biomarkers with exercise and early osteoarthritis in horses. Osteoarthritis and Cartilage/OARS, Osteoarthritis Research Society, 16(10), 1196–1204. doi:10.1016/j.joca.2008.03.008.
McFarlane, D., & Holbrook, T. C. (2008). Cytokine dysregulation in aged horses and horses with pituitary pars intermedia dysfunction. Journal of Veterinary Internal Medicine/American College of Veterinary Internal Medicine, 22(2), 436–442. doi:10.1111/j.1939-1676.2008.0076.x.
Burton, A. B., Wagner, B., Erb, H. N., & Ainsworth, D. M. (2009). Serum interleukin-6 (IL-6) and IL-10 concentrations in normal and septic neonatal foals. Veterinary Immunology and Immunopathology, 132(2–4), 122–128. doi:10.1016/j.vetimm.2009.05.006.
Screven, R., Kenyon, E., Myers, M. J., Yancy, H. F., Skasko, M., Boxer, L., et al. (2014). Immunophenotype and gene expression profile of mesenchymal stem cells derived from canine adipose tissue and bone marrow. Veterinary Immunology and Immunopathology, 161(1–2), 21–31. doi:10.1016/j.vetimm.2014.06.002.
Dos Santos, F., Campbell, A., Fernandes-Platzgummer, A., Andrade, P. Z., Gimble, J. M., Wen, Y., et al. (2014). A xenogeneic-free bioreactor system for the clinical-scale expansion of human mesenchymal stem/stromal cells. Biotechnology and Bioengineering, 111(6), 1116–1127. doi:10.1002/bit.25187.
Hartmann, I., Hollweck, T., Haffner, S., Krebs, M., Meiser, B., Reichart, B., et al. (2010). Umbilical cord tissue-derived mesenchymal stem cells grow best under GMP-compliant culture conditions and maintain their phenotypic and functional properties. Journal of Immunological Methods, 363(1), 80–89. doi:10.1016/j.jim.2010.10.008.
Aggarwal, S., & Pittenger, M. F. (2005). Human mesenchymal stem cells modulate allogeneic immune cell responses. Blood, 105(4), 1815–1822. doi:10.1182/blood-2004-04-1559.
Lee, W. S., Suzuki, Y., Graves, S. S., Iwata, M., Venkataraman, G. M., Mielcarek, M., et al. (2011). Canine bone marrow-derived mesenchymal stromal cells suppress alloreactive lymphocyte proliferation in vitro but fail to enhance engraftment in canine bone marrow transplantation. Biology of Blood and Marrow Transplantation : Journal of the American Society for Blood and Marrow Transplantation, 17(4), 465–475. doi:10.1016/j.bbmt.2010.04.016.
Kang, J. W., Kang, K. S., Koo, H. C., Park, J. R., Choi, E. W., & Park, Y. H. (2008). Soluble factors-mediated immunomodulatory effects of canine adipose tissue-derived mesenchymal stem cells. Stem Cells and Development, 17(4), 681–693. doi:10.1089/scd.2007.0153.
Hatlapatka, T., Moretti, P., Lavrentieva, A., Hass, R., Marquardt, N., Jacobs, R., et al. (2011). Optimization of culture conditions for the expansion of umbilical cord-derived mesenchymal stem or stromal cell-like cells using xeno-free culture conditions. Tissue Engineering Part C, Methods, 17(4), 485–493. doi:10.1089/ten.TEC.2010.0406.
Kinzebach, S., Dietz, L., Kluter, H., Thierse, H. J., & Bieback, K. (2013). Functional and differential proteomic analyses to identify platelet derived factors affecting ex vivo expansion of mesenchymal stromal cells. BMC Cell Biology, 14, 48. doi:10.1186/1471-2121-14-48.
Jung, S., Sen, A., Rosenberg, L., & Behie, L. A. (2010). Identification of growth and attachment factors for the serum-free isolation and expansion of human mesenchymal stromal cells. Cytotherapy, 12(5), 637–657. doi:10.3109/14653249.2010.495113.
Acknowledgments
This project was supported by the Center for Equine Health (University of California, Davis) and a generous gift from Mr. Dick and Carolyn Randall. KC was supported by a California Institute of Regenerative Medicine, Stem Cell Training Grant. AK was supported by the ARCS foundation and a California Institute for Regenerative Medicine, Stem Cell Training grant. An Animal Models of Infectious Diseases T32 AI60555 supported JG.
Authors’ Contributions
KCC, AK, SS, JG, NJW - study design, data collection, conduction of experiments
KCC, AK – data analysis, manuscript writing
DLB -study design, grant writing, student mentoring, data review, manuscript writing and final manuscript approval
All authors have read and approve of the final version of the manuscript.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Competing Interests
The authors declare that they have no competing interests.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Clark, K.C., Kol, A., Shahbenderian, S. et al. Canine and Equine Mesenchymal Stem Cells Grown in Serum Free Media Have Altered Immunophenotype. Stem Cell Rev and Rep 12, 245–256 (2016). https://doi.org/10.1007/s12015-015-9638-0
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12015-015-9638-0