Human Fibroblast Feeder Layers Research Articles

Impact of Dual Cell Co-culture and Cell-conditioned Media on Yield and Function of a Human Olfactory Cell Line for Regenerative Medicine.

Olfactory ensheathing cells (OECs) are a promising candidate therapy for neuronal tissue repair. However, appropriate priming conditions to drive a regenerative phenotype are yet to be determined. We first assessed the effect of using a human fibroblast feeder layer and fibroblast conditioned media on primary rat olfactory mucosal cells (OMCs). We found that OMCs cultured on fibroblast feeders had greater expression of the key OEC marker p75NTR (25.1 ± 10.7 cells/mm2) compared with OMCs cultured on laminin (4.0 ± 0.8 cells/mm2, p = 0.001). However, the addition of fibroblast-conditioned media (CM) resulted in a significant increase in Thy1.1 (45.9 ± 9.0 cells/mm2 versus 12.5 ± 2.5 cells/mm2 on laminin, p = 0.006), an undesirable cell marker as it is regarded to be a marker of contaminating fibroblasts. A direct comparison between human feeders and GMP cell line Ms3T3 was then undertaken. Ms3T3 cells supported similar p75NTR levels (10.7 ± 5.3 cells/mm2) with significantly reduced Thy1.1 expression (4.8 ± 2.1 cells/mm2). Ms3T3 cells were used as feeder layers for human OECs to determine whether observations made in the rat model were conserved. Examination of the OEC phenotype (S100β expression and neurite outgrowth from NG108-15 cells) revealed that co-culture with fibroblast feeders had a negative effect on human OECs, contrary to observations of rat OECs. CM negatively affected rat and human OECs equally. When the best and worst conditions in terms of supporting S100β expression were used in NG108-15 neuron co-cultures, those with the highest S100β expression resulted in longer and more numerous neurites (22.8 ± 2.4 μm neurite length/neuron for laminin) compared with the lowest S100β expression (17.9 ± 1.1 μm for Ms3T3 feeders with CM). In conclusion, this work revealed that neither dual co-culture nor fibroblast-conditioned media support the regenerative OEC phenotype. In our case, a preliminary rat model was not predictive of human cell responses.

Derivation, culture and retinal pigment epithelial differentiation of human embryonic stem cells using human fibroblast feeder cells

Retinal pigment epithelium cells derived from human embryonic stem cells (ESCs) could be useful for restoring retinal function in age-related macular degeneration. However the use of non-human feeder cells to support the growth of ESCs for clinical applications raises the concern of possible contamination because of direct contact between animal and human cells. In this study, we produced human ESCs using human fibroblast feeder layers isolated from foreskin and abdominal tissues. Using this system, human ESCs differentiated into retinal pigment epithelium cells in differentiation medium. Seven human ESC lines were established from 18 blastocysts. These human ESCs showed normal morphology, expressed all expected cell surface markers, had the ability to form embryoid bodies upon culture in vitro and teratomas after injection into SCID mice, and differentiated further into derivatives of all three germ layers. Under conditions of committed differentiation, these human ESCs could differentiate into retinal pigment epithelium cells after 2 months in culture. The results of this study demonstrated that human foreskin/abdominal fibroblasts have the potential to support the derivation and long-term culture of human ESCs, which can then be used to generate retinal pigment epithelium cells with characteristic morphology and molecular markers. This technique avoids the concerns of contamination from animal feeder layers during human ESC derivation, culture and differentiation, and will thus facilitate the development of retinal pigment epithelium cell transplantation therapy.

Cryopreserving and Recovering of Human iPS Cells using Complete KnockOut Serum Replacement Feeder-Free Medium

The discovery in 2006 that human and mouse fibroblasts could be reprogrammed to generate iPS cells with qualities remarkably similar to embryonic stem cells has created a valuable new source of pluripotent cells for drug discovery, cell therapy, and basic research. GIBCO media and reagents have been at the forefront of pluripotent stem cell research for years. Knockout DMEM supplemented with Knockout Serum Replacement is the media of choice for embryonic stem cell growth and now iPS cell culture. This gold standard media system can now be used for feeder-free culture with the addition of Knockout SR Growth Factor Cocktail. Traditional human ES and iPS cell culture methods require the use of mouse or human fibroblast feeder layers, or feeder-conditioned medium. These culture methods are labor-intensive, hard to scale and it is difficult to maintain hiPS cells undifferentiated due to the undefined conditions. Invitrogen has developed Knockout SR Growth Factor Cocktail to allow you to easily transition your hiPS and hES cell cultures to feeder-free while still maintaining your use of Knockout SR.

Feeder-Free Adaptation, Culture and Passaging of Human IPS Cells using Complete KnockOut Serum Replacement Feeder-Free Medium

The discovery in 2006 that human and mouse fibroblasts could be reprogrammed to generate iPS cells with qualities remarkably similar to embryonic stem cells has created a valuable new source of pluripotent cells for drug discovery, cell therapy, and basic research. GIBCO media and reagents have been at the forefront of pluripotent stem cell research for years. Knockout DMEM supplemented with Knockout Serum Replacement is the media of choice for embryonic stem cell growth and now iPS cell culture. This gold standard media system can now be used for feeder-free culture with the addition of Knockout SR Growth Factor Cocktail. Traditional human ES and iPS cell culture methods require the use of mouse or human fibroblast feeder layers, or feeder-conditioned medium. These culture methods are labor-intensive, hard to scale and it is difficult to maintain hiPS cells undifferentiated due to the undefined conditions. Invitrogen has developed Knockout SR Growth Factor Cocktail to allow you to easily transition your hiPS cell cultures to feeder-free while still maintaining your use of Knockout SR.

Cryopreserving and Recovering of Human iPS Cells using Complete KnockOut Serum Replacement Feeder-Free Medium

The discovery in 2006 that human and mouse fibroblasts could be reprogrammed to generate iPS cells 1-3 with qualities remarkably similar to embryonic stem cells has created a valuable new source of pluripotent cells for drug discovery, cell therapy, and basic research. GIBCO media and reagents have been at the forefront of pluripotent stem cell research for years. Knockout DMEM supplemented with Knockout Serum Replacement is the media of choice for embryonic stem cell growth and now iPS cell culture 3-9. This gold standard media system can now be used for feeder-free culture with the addition of Knockout SR Growth Factor Cocktail. Traditional human ES and iPS cell culture methods require the use of mouse or human fibroblast feeder layers, or feeder-conditioned medium. These culture methods are labor-intensive, hard to scale and it is difficult to maintain hiPS cells undifferentiated due to the undefined conditions. Invitrogen has developed Knockout SR Growth Factor Cocktail to allow you to easily transition your hiPS and hES cell cultures to feeder-free while still maintaining your use of Knockout SR.

A New System for Cultivation of Human Keratinocytes on Acellular Dermal Matrix Substitute with the Use of Human Fibroblast Feeder Layer

To improve the proliferative potential of human keratinocytes (HK) cultured on acellular dermal matrix (ADM), HK and mitomycin C-treated human fibroblasts (MMC-HF) were seeded onto ADM to form four types of composite skin: type I, HK were seeded onto the epidermal side of ADM; type II, both HK and MMC-HF were seeded onto the epidermal side; type III, MMC-HF were preseeded onto the dermal side of ADM, and then HK were seeded onto the epidermal side, and type IV, where MMC-HF were preseeded onto both sides, and then HK were seeded onto the epidermal side. Compared with type I and III, the proliferative potential of HK of type II and IV was significantly higher on day 3, 5, 7 and 9 in vitro. In type I and III, HK grew into one layer on day 7–9, while in type II and IV keratinocytes grew into a confluent monolayer by day 4–6. The adherence to ADM of HK in types II and IV was stronger than that in type I and III. The take rate of type II and IV composite skin was also significantly higher. In conclusion, when MMC-HF and HK were cocultured on the epidermal side of ADM, MMC-HF could serve as excellent feeder cells.

Use of Human Fibroblasts in the Development of a Xenobiotic-Free Culture and Delivery System for Human Keratinocytes

Previous work has shown that keratinocytes can be cultured serum-free on an acid-functionalized, plasma-polymerized surface (for subsequent delivery to patients' wound beds) by inclusion of a fibroblast feeder layer. This study seeks to extend this work by substituting human for murine feeder cells in serum-free culture and examining the performance of keratinocytes expanded in this way to transfer to an in vitro human dermal wound bed model. We compared murine and human fibroblasts (both short-term dermal fibroblasts and a fetal lung fibroblast cell line MRC-5, which has a long history in human vaccine production), alternative methods for growth-arresting fibroblasts, establishing culture of cells serum-free, and the impact of culture with fibroblasts on the differentiation of the keratinocytes. Irradiated human and murine fibroblasts were equally effective in supporting initial keratinocyte expansion, both in the presence and absence of serum. Keratinocytes were significantly less differentiated, as assessed by measuring involucrin expression relative to DNA when grown serum-free with fibroblasts than when grown with serum. Initial cultures of fibroblasts and keratinocytes could be initiated serum-free but were much slower to establish than if serum were used. Transfer of keratinocytes from keratinocyte/fibroblast co-cultures cultured on a plasma polymer surface to a human dermal wound bed model was as successful as from monocultures in both serum and serum-free cultures. In summary, we have revisited a well-accepted methodology for expanding human keratinocytes for clinical use and avoided the use of bovine serum and a mouse fibroblast feeder layer by introducing an irradiated human fibroblast feeder layer.

Culture of human main pancreatic duct epithelial cells.

Attempts to grow human pancreatic duct epithelial cells in long-term culture have proven difficult. We have developed a system of growing these cells for several passages by adapting methods used to culture dog pancreatic duct cells. Epithelial cells were enzymatically dissociated from the main pancreatic duct and plated onto collagen-coated culture inserts suspended above a human fibroblast feeder layer. After primary culture, the cells were either passaged onto new inserts or plastic tissue culture plates in the absence of collagen. Cells grown on the latter plates were maintained in a serum-free medium. Primary pancreatic duct epithelial cells grow steadily to confluence as a monolayer in the feeder layer system. After primary culture, cells passaged onto new inserts with fresh feeder layer or plastic plates and fed with serum-free medium continued to develop into confluent monolayers for up to four passages. The cells were columnar with prominent apical microvilli, sub-apical secretory vesicles, and lateral intercellular junctions resembling the morphology of normal in vivo epithelial cells. These cells were also positive for cytokeratin 19, 7, and 8 and carbonic anhydrase II, as measured by immunohistochemistry. Metabolically, these cells synthesized and secreted mucin, as measured by incorporation of tritiated N-acetyl-D-glucosamine. In conclusion, we demonstrated that human pancreatic epithelial cells from the main duct can be successfully grown in culture and repeatedly passaged using a feeder layer system, with serum-free medium, and in organotypic cultures.

Culture of hair matrix and follicular keratinocytes

In recent years, a variety of in vitro models for the cultivation of hair follicles and their constituents have been developed. Outer root sheath (ORS) keratinocytes (KC) have been mainly studied in explant cultures, planted on bovine eye lens capsules, collagen substrata, 3T3 cell feeder layers, or dermal equivalents, yielding outgrowth of a multilayered stratified epithelium with some biochemical and ultrastructural characteristics of keratinocytic differentiation. More recently, ORS KC cultures have also been initiated from single cell suspensions, and organotypic cultures have been obtained by recombination with dermal cells, inducing a higher degree of epidermal differentiation. Presumptive human hair matrix cells have been isolated from plucked anagen hair follicles and have been successfully propagated on 3T3 cell or normal human fibroblast feeder layers, giving rise to multilayered stratified KC cultures. In contrast, only preliminary data exist concerning the cultivation of bulge cells that have been suggested to represent follicular stem cells. In conclusion we dispose of several in vitro models today to cultivate ORS KC and hair matrix cells that have increased our knowledge on the regulation of the human hair cycle by soluble factors and dermal-epidermal interactions. Further comparative studies on ORS KC, bulge cells and matrix cells have to be carried out to confirm the distinct character of these hair KC subsets.

Culture of Hair Matrix and Follicular Keratinocytes.

In recent years, a variety of in vitro models for the cultivation of hair follicles and their constituents have been developed. Outer root sheath (ORS) keratinocytes (KC) have been mainly studied in explant cultures, planted on bovine eye lens capsules, collagen substrata, 3T3 cell feeder layers, or dermal equivalents, yielding outgrowth of a multilayered stratified epithelium with some biochemical and ultrastructural characteristics of keratinocytic differentiation. More recently, ORS KC cultures have also been initiated from single cell suspensions, and organotypic cultures have been obtained by recombination with dermal cells, inducing a higher degree of epidermal differentiation. Presumptive human hair matrix cells have been isolated from plucked anagen hair follicles and have been successfully propagated on 3T3 cell or normal human fibroblast feeder layers, giving rise to multilayered stratified KC cultures. In contrast, only preliminary data exist concerning the cultivation of bulge cells that have been suggested to represent follicular stem cells. In conclusion we dispose of several in vitro models today to cultivate ORS KC and hair matrix cells that have increased our knowledge on the regulation of the human hair cycle by soluble factors and dermal-epidermal interactions. Further comparative studies on ORS KC, bulge cells and matrix cells have to be carried out to confirm the distinct character of these hair KC subsets.

Can Epstein-Barr virus infect and transform all the B-lymphocytes of human cord blood?

Quantitative aspects of Epstein-Barr virus infection and transformation of human neonatal B-lymphocytes have been investigated. 72 to 90% B-cells were obtained with enrichment. Of the B-cells, 19 to 97% showed nuclear antigen (EBNA) 2 days after infection. A difference between different B-cell donors in susceptibility to infection was noted. Analysis of the virus dose-response curves obtained with twofold virus dilutions showed that one virus particle is sufficient to induce EBNA in a cell. Of the infected cells, 50 to 95% multiplied in microtitre wells containing a human fibroblast feeder layer, while only a small proportion established growing colonies in soft agarose, that could be picked up and subcultured.

Interactions between human lymphoblastoid cells and human fibroblast feeder layers in vitro.

Lymphoblastoid (LB) cells interact in vitro with human fibroblasts. Cell complexes can be dissociated by trypsin treatment. Binding on fibroblasts is higher for Epstein-Barr virus-producer LB cells than for nonproducers, and depends on the origin of the fibroblastic cells. Stromal fibroblasts isolated from a metastatic lymph node tumor exhibited a highly increased potency of binding LB cells in comparison with fibroblasts isolated from normal breast epidermis or the primary breast tumor from the same patient. After a 10-hour interaction period, LB cells undergo abnormal divisions giving rise to the formation of 'mini cells'.