Cell size and growth characteristics of cultured fibroblasts isolated from normal and keloid tissue.

No differences in appearance or in cell size distribution were observed between cultured fibroblasts derived from normal skin, mature scars, or keloids. Artifactual differences in cell size distributions between strains can result when populations are compared at different cell densities. Keloid derived fibroblasts remain euploid in culture, and they have the same growth rate and same degree of density-dependent growth inhibition as cultured normal human fibroblasts.     

Observations of de novo clones of cytogentically aberrant cells in primary fibroblast cell strains from phenotypically normal women.

In a recent study of chromosome breakage frequencies in 36 primary fibroblast cell strains derived from skin from 10 phenotypically normal women, we observed seven different clones of cells having consistent chromosomal abnormalities. Five of the stem lines were noted in cultures from "control" women and two in fibroblasts from women taking oral contraceptives. We observed aneuploid clones as well as stem lines bearing structural abnormalities (e.g., translocation, inversions). The various aberrant clones were found in cultures ranging in age from 41 to 144 days and comprised varying percentages of the cell populations ranging from 0.8% to virtually 100%. The possible evolution in culture of clones of cells having aberrant karyotypes should be considered in interpreting findings from fibroblast cultures initiated for clinical evaluation.     

Mitochondrial DNA in mortal and immortal human cells. Genome number, integrity, and methylation

Mitochondrial DNA was quantitated in total DNA of various normal and mutant strains of human diploid fibroblasts (finite replicative lifespan) and permanent cell lines, using Southern-transfer hybridization to 32P-labeled pure mtDNA probe and saturation hybridization to 3H-labeled cRNA copied from mtDNA. In six normal fibroblast strains, mtDNA copy number increased during serial passage roughly in proportion to cell volume or protein content, whereas normalized mtDNA content per pg of protein depended upon in vivo donor age but not passage level ("in vitro" age). Copy numbers for mtDNA varied much more widely in individual fibroblast clones than in mass cultures, but were not well correlated with longevity or growth rate. Five mutant fibroblast strains associated with reduced replicative lifespan, and four permanent cell lines, were also examined; in each group, mtDNA values were observed both lower and higher than any obtained for normal fibroblasts. No evidence was found of petite-type deletions from human mtDNA, either at late passage or in individual clones of fibroblasts. Methylation of mtDNA genomes was strikingly non-random and apparently decreased with culture age.     

Retinoids and cultured human fibroblasts : Effects on cell growth and presence of cellular retinoic acid-binding protein

We have examined the effects of retinoids on growth of cultured human skin fibroblasts from four individuals. Retinoic acid and retinol both produce a dose-dependent inhibition of growth in the four strains examined; retinoic acid was more potent than retinol in this respect. The growth inhibitory effect of retinoic acid is characterized by a decrease in the exponential growth rate, which is reversible upon removal of retinoic acid from the growth medium; the final saturation density, however, is not modified by retinoic acid treatment. No alterations of cell morphology, viability, or adhesiveness to substratum are induced by the retinoid concentrations utilized. The inhibitory effect of 10⁻⁶ M retinoic acid on cell growth is not affected by the concentration of fetal calf serum (FCS) in the medium. In all four human fibroblast strains examined, specific binding of [³H]retinoic acid to cytosol is present as determined by sucrose-density gradient centrifugation. Despite the effects of retinol on fibroblast growth, no cytoplasmic binding of [³H]retinol could be demonstrated in these cells.     

Observatons on the growth and metabolic functions of cultured cells derived from human adipose tissue.

The growth and metabolic activity of cultured cells derived from human adipose tissue (CAT cells) were studied and compared to cultured skin fibroblasts. The morphological appearance of the CAT cells was distinctly different from that of fibroblasts. The growth rate of CAT cells as measured by 3H-thymidine incorporation was much slower than the fibroblast growth rate. Cultured CAT cells synthesized significantly 14C-glucose, while fibroblast cultures had a higher metabolic rate as measured by CO2 production. Insulin stimulated 3H-thymidine incorporation in both CAT and fibroblast cultures. The CAT cells did not show a consistent insulin response of lipid or CO2 production, but this may be a reflection of donor age or nutritional status. Even though the CAT cell may be a type of stromal cell peculiar to adipose tissue rather than a preadipocyte or adipocyte, it may prove useful in studies of human obesity.     

Complete differentiation of adipocyte precursors

Summary Evidence for the complete morphological maturation of precursor cells into adipocytes in vitro is presented. Cells were isolated from the stromal fraction of adipose tissue from adult humans and from rats and were grown in culture. Abdominal skin fibroblasts were used as controls. All cell strains were initially fusiform and replicated. On reaching monolayer confluency, they were transferred to an enriched growth medium in which the human and rat adipocyte precursors differentiated into a homogeneous population of cells, morphologically indistinguishable from mature adipocytes. In contrast, skin fibroblasts from the same person or animal, and grown under identical culture conditions, did not accumulate lipid and retained their fusiform contour. The same results were obtained in the first six subcultures that were studied. Thus, there is firm evidence that fat tissue of adult humans and rats contains adipocyte precursors that differentiate into mature fat cells. The culture system that has been described will facilitate the elucidation of the factors involved in replication and differentiation of adipocyte precursors.This work was supported by The Medical Research Council of Canada Grant MA-5827, The Ontario Heart Foundation, The Atkinson Charitable Foundation, The Banting Research Foundation, The J.P. Bickell Foundation, and the Physicians' Services Incorporated Foundation     

Surface enzymes in cultured fibroblasts from cystic fibrosis patients.

Membrane function was examined in cultured cells from cystic fibrosis patients by assaying several enzymes on intact skin fibroblasts attached to culture dishes. This technique required few cells and minimized disruption of cellular organization. Comparison of enzyme activities of intact and broken cells showed that 12% of total glucose-6-phosphate dehydrogenase, a cytoplasmic enzyme, was measurable using intact cells, while all adenosine monophosphatase was measurable using intact cells. Alkaline paranitrophenylphosphatase activity was divided between the cell surface and interior. Substrate competition experiments indicated that substrate specificities for adenosine monophosphatase and paranitrophenylphosphatase activities were different. Adenosine monophosphatase activities of 2 control and 2 cystic fibrosis strains fluctuated similarly during the cell culture cycle. The apparent Km values relative to adenosine monophosphate were similar in all strains. A chromatographic fraction of serum from a cystic fibrosis patient that was inhibitory to oyster ciliary activity had no effect on adenosine monophosphatase activity of normal fibroblasts. Furthermore, fractions of media from cystic fibrosis homozygote and heterozygote fibroblast cultures were not inhibitory to adenosine monophosphatase activities of intact normal fibroblasts or of part iculate fractions prepared from them. In light of previous studies that showed that factors from cystic fibrosis serum of culture medium disrupted specific membrane activities, it is proposed that the cystic fibrosis factor interacts with the plasma membrane, interfering most conspicuously with the protein functions that are sensitive to changes in their membrane environment.     

Effects of DNA damaging agents on cultured fibroblasts derived from patients with Cockayne syndrome.

The cytotoxic action of physical and chemical agents on 10 skin fibroblast strains in culture derived from individuals with Cockayne's syndrome was measured in terms of colony-forming ability. As compared to fibroblasts from normal donors, all Cockayne cell strains tested exhibited a significantly increased sensitivity to UV light and a normal sensitivity to X-rays. Cells from two sets of parents of unrelated Cockayne children showed an intermediate level of UV sensitivity. There was no effect of 0.5 mM caffeine on UV survival in normal and two Cockayne strains tested, indicating that postreplicational repair in Cockayne cells as measured by caffeine sensitivity was probably normal. Sensitivity of normal and Cockayne cells to the chemical carcinogens and mutagens 4NQO, N-AcO-AAF, ICR-170 and EMS was also compared. An increased sensitivity of Cockayne cells to 4NQO or N-AcO-AAF, but not the ICR-170 or EMS, was observed. However, unlike the intermediate UV sensitivity, the cell strains from two parents of Cockayne patients showed the same sensitivity to N-AcO-AAF or 4NQO as fibroblasts from normal individuals. Quantiation of damage to the DNA after 20 J . m-2 UV irradiation indicates normal levels of [3H] thymidine incorporation in the Cockayne cells, in contrast to UV-irradiated xeroderma pigmentosum cells (XP 12BE) in which there was a very low level of repari synthesis. Moreover, we have shown previously that excision of UV-induced pyrimidine dimers in 2 of the 10 Cockayne cell strains was normal.     

Human skin fibroblast collagenase inhibitor. Comparative studies in human connective tissues, serum, and amniotic fluid

In order to gain insight into the biological significance of a collagenase inhibitor secreted by human skin fibroblasts, we examined various human connective tissues and body fluids for such a protein. The inhibitors found in these tissues were compared immunologically to skin fibroblast inhibitor by Ouchterlony analysis and by the development of a highly specific enzyme-linked immunosorbent assay (ELISA). Using this ELISA, cell cultures of human skin fibroblasts, corneal fibroblasts, gingival fibroblasts, and adult and fetal lung fibroblasts secreted similar amounts of immunoreactive inhibitor protein. Each culture medium displayed a reaction of immunologic identity with skin fibroblast inhibitor when examined in Ouchterlony gel diffusion. In testing for functional inhibitory activity, the same 1:1 stoichiometry of collagenase inhibition was observed in each culture medium that characterizes the human skin inhibitor. Other mesodermally derived human cell types, including human fetal osteoblasts, uterine smooth muscle cells, fibrosarcoma cells, and explants of tendon and articular cartilage behaved in the same manner as the fibroblast cultures. Because collagenase inhibitors with biochemical similarities to skin fibroblast inhibitor have been described in serum and in amniotic fluid, we also examined these sources of inhibitory proteins. The data indicate that both serum and amniotic fluid contain collagenase inhibitors which are immunologically and functionally identical with the skin fibroblast inhibitor. The concentration of inhibitor in serum, as measured by ELISA assay, is 1.03 +/- 0.27 micrograms/ml. The results suggest that collagenase inhibitors which are functionally equivalent and immunologically identical with human skin fibroblast collagenase inhibitor are synthesized by many, if not all, fetal and adult mesodermal tissues in the human organism. The inhibitor apparently gains access to certain body fluids such as serum and amniotic fluid. This inhibitor protein may, therefore, function in the regulation of collagen degradation in most human connective tissues.     

The mast cell-committed progenitor. II. W/Wv mice do not make mast cell-committed progenitors and S1/S1d fibroblasts do not support development of normal mast cell-committed progenitors

We have previously reported that the population of mesenteric lymph node cells from normal BALB/c mice infected 14 days with the rodent nematode Nippostrongylus brasiliensis (Nb-MLN) contains a nongranulated mast cell-committed progenitor (MCCP) which does not require IL-3 for proliferation and differentiation if either a fibroblast monolayer or soluble factors produced by monolayers of 3T3 fibroblasts or embryonic skin are present in the culture. When Nb-MLN were cloned in a methylcellulose culture system using fibroblast conditioned medium as the only source of growth factors, numerous colonies of pure mast cells developed. We wished to determine whether the mast cell deficiency of W/Wv or S1/S1d mice could be explained by the failure of these mice to make either the MCCP or the factor to support proliferation and differentiation of the MCCP. We found that Nb-MLN from W/Wv mice were only able to produce mast cell colonies in response to a source of IL-3 such as conditioned medium from pokeweed mitogen-stimulated spleen cells (CM), and cultures given fibroblast conditioned medium as the only source of growth factors did not produce mast cell colonies. In contrast, Nb-MLN from mast cell deficient S1/S1d mice developed many mast cell colonies in methylcellulose cultures supplemented with either fibroblast conditioned medium or conditioned medium from PWM-stimulated spleen cells. These data suggest that S1/S1d mice but not W/Wv mice produce the mast cell progenitor that responds to fibroblast conditioned medium. To determine if mast cell deficient mice make the fibroblast derived factors that support development of the MCCP, monolayers were prepared from skin connective tissues of S1/S1d and W/Wv mice and Nb-MLN from normal BALB/c mice were cloned in the presence of conditioned medium from these monolayers. Fibroblast conditioned medium from monolayers prepared from W/Wv but not S1/S1d mice supported development of numerous mast cell colonies. Taken together, these data demonstrate that W/Wv mice are incapable of producing normal MCCP whereas S1/S1d fibroblasts fail to produce the appropriate factor to support the MCCP. In accordance with these data, a candidate for the gene product of each of these mutant alleles is discussed.     

Fibroblasts isolated from human pterygia exhibit transformed cell characteristics

Summary Pterygium is a degenerative corneal limbal process and UV irradiation has been suggested as being a major environmental predisposing factor. The invasive nature of the fibroblasts associated with pterygia raises the question as to whether these cells are transformed. To test this hypothesis, we established fibroblast strains from autologous and heterologous pterygial and conjunctival specimens, respectively, from subjects between 40 to 50 yr of age, and compared their growth characteristics in culture. All pterygial fibroblast strains exhibited a reduced dependence on serum and exogenous growth factors for growth and reached a saturation population density that was threefold higher than conjunctival fibroblasts cultured under the same conditions. In addition, all pterygial fibroblast strains were able to form colonies in soft agar in 5% fetal bovine serum at a 6.0 to 7.5% efficiency. Under the same experimental conditions, none of the conjunctival fibroblast strains were able to grow. The results presented support the conclusion that pterygial fibroblasts have acquired many of the properties of the transformed phenotype.     

Differences in the Nemosis Response of Normal and Cancer-Associated Fibroblasts from Patients with Oral Squamous Cell Carcinoma

Background

Tumor-stroma reaction is associated with activation of fibroblasts. Nemosis is a novel type of fibroblast activation. It leads to an increased production of growth factors and proinflammatory and proteolytic proteins, while at the same time cytoskeletal proteins are degraded. Here we used paired normal skin fibroblasts and cancer-associated fibroblasts (CAF) and primary and recurrent oral squamous cell carcinoma (SCC) cells to study the nemosis response.

Principal Findings

Fibroblast nemosis was analyzed by protein and gene expression and the paracrine regulation with colony formation assay. One of the normal fibroblast strains, FB-43, upregulated COX-2 in nemosis, but FB-74 cells did not. In contrast, CAF-74 spheroids expressed COX-2 but CAF-43 cells did not. Alpha-SMA protein was expressed in both CAF strains and in FB-74 cells, but not in FB-43 fibroblasts. Its mRNA levels were downregulated in nemosis, but the CAFs started to regain the expression. FSP1 mRNA was downregulated in normal fibroblasts and CAF-74 cells, but not in CAF-43 fibroblasts. Serine protease FAP was upregulated in all fibroblasts, more so in nemotic CAFs. VEGF, HGF/SF and FGF7 mRNA levels were upregulated to variable degree in nemosis. CAFs increased the colony formation of primary tumor cell lines UT-SCC-43A and UT-SCC-74A, but normal fibroblasts inhibited the anchorage-independent growth of recurrent UT-SCC-43B and UT-SCC-74B cells.

Conclusions

Nemosis response, as observed by COX-2 and growth factor induction, and expression of CAF markers α-SMA, FSP1 and FAP, varies between fibroblast populations. The expression of CAF markers differs between normal fibroblasts and CAFs in nemosis. These results emphasize the heterogeneity of fibroblasts and the evolving tumor-promoting properties of CAFs.     

Fibroblasts share mesenchymal phenotypes with stem cells, but lack their differentiation and colony-forming potential

Background information. Although MSCs (mesenchymal stem cells) and fibroblasts have been well studied, differences between these two cell types are not fully understood. We therefore comparatively analysed antigen and gene profiles, colony‐forming ability and differentiation potential of four human cell types in vitro: commercially available skin‐derived fibroblasts [hSDFs (human skin‐derived fibroblasts)], adipose tissue‐derived stem cells [hASCs (human adipose tissue‐derived stem cells)], embryonic lung fibroblasts (WI38) and dermal microvascular endothelial cells [hECs (human dermal microvascular endothelial cells)]. Results. hSDFs, hASCs and WI38 exhibited a similar spindle‐like morphology and expressed same antigen profiles: positive for MSC markers (CD44, CD73 and CD105) and fibroblastic markers [collagen I, HSP47 (heat shock protein 47), vimentin, FSP (fibroblast surface protein) and αSMA (α smooth muscle actin)], and negative for endothelial cell marker CD31 and haemopoietic lineage markers (CD14 and CD45). We further analysed 90 stem cell‐associated gene expressions by performing real‐time PCR and found a more similar gene expression pattern between hASCs and hSDFs than between hSDFs and WI38. The expression of embryonic stem cell markers [OCT4, KLF4, NANOG, LIN28, FGF4 (fibroblast growth factor 4) and REST] in hASCs and hSDFs was observed to differ more than 2.5‐fold as compared with WI38. In addition, hSDFs and hASCs were able to form colonies and differentiate into adipocytes, osteoblasts and chondrocytes in vitro, but not WI38. Moreover, single cell‐derived hSDFs and hASCs obtained by clonal expansion were able to differentiate into adipocytes and osteoblasts. However, CD31 positive hECs did not show differentiation potential. Conclusions. These findings suggest that (i) so‐called commercially available fibroblast preparations from skin (hSDFs) consist of a significant number of cells with differentiation potential apart from terminally differentiated fibroblasts; (ii) colony‐forming capacity and differentiation potential are specific important properties that discriminate MSCs from fibroblasts (WI38), while conventional stem cell properties such as plastic adherence and the expression of CD44, CD90 and CD105 are unspecific for stem cells.     

Growth kinetics and collagen synthesis of normal skin, normal scar and keloid fibroblasts in vitro.

Fibroblasts were isolated from keloid, normal skin, and normal scar and maintained in tissue culture for four passages. Growth kinetics were the same for all groups on days 2 through 12. However, the rate of collagen synthesis per fibroblast was greater in keloid derived cells than any controls at all growth phases. Keloid fibroblasts have an autonomous capacity to synthesize collagen at a significantly increased level in vitro, which may explain in part why these lesions are characterized by increased collagen deposition.     

Reduced lysyl oxidase activity in skin fibroblasts from patients with Menkes'' syndrome.

Lysyl oxidase activity against both collagen and elastin substrates has been examined in the culture medium of skin fibroblasts derived from unrelated patients with Menkes' syndrome and from control subjects. The medium of three Menkes' fibroblast lines showed 3--30% of the activity present in the medium of control fibroblasts, against a purified collagen substrate. Lysyl oxidase activity in the culture medium of two of the Menkes' fibroblast lines was also examined by using a crude aortic-elastin substrate and was similarly decreased in comparison with that in the medium of control fibroblasts. Lysyl oxidase activity in the medium of a fourth fibroblast line, derived from a foetus with Menkes' syndrome, was 42% of that in the medium of control fibroblasts derived from a 1-day-old baby against a collagen substrate, and 26% of that in control fibroblast medium against an elastin substrate. The copper content of the cell layers of the Menkes' fibroblast cultures was elevated in comparison with normal fibroblast cultures, as has previously been reported to be characteristic of such cells. It is suggested that the decrease in lysyl oxidase activity would help to explain the connective tissue defects observed in Menkes' syndrome, and that this reduction, in conjunction with the elevated concentrations of cellular copper, would support the hypothesis that a functional intracellular copper deficiency exists in Menkes' syndrome.     

Lack of sensitivity of primary Fanconi's anemia fibroblasts to UV and ionizing radiation

Clinical observations and theoretical considerations suggest some degree of radiosensitivity in Fanconi's anemia (FA), but experimental evidence remains controversial. We tested the sensitivity of primary skin fibroblast cultures from all known FA complementation groups to ionizing radiation and ultraviolet light using conventional cell growth and colony formation assays. In contrast to previous studies, and because FA fibroblasts grow and clone poorly at ambient oxygen, we performed our sensitivity tests under hypoxic cell culture conditions. Fibroblast strains from healthy donors served as negative controls and those from patients with ataxia telangiectasia (AT) and Cockayne syndrome (CS) as positive controls. We observed interstrain variation but no systematic difference in the response of FA and non-FA control fibroblasts to ionizing radiation. After exposure to UV radiation, only complementation group A, G and D2 strains displayed values for colony formation EC50 that were intermediate between those for the negative and positive controls. Because of considerable interstrain variation, minor alterations of the response of individual FA strains to ionizing and UV radiation should be interpreted with caution and should not be taken as evidence for genotype-specific sensitivities of primary FA fibroblasts. All together, our data indicate neither systematic nor major sensitivities of primary FA fibroblast cultures of any complementation group grown under hypoxic cell culture conditions to ionizing or UV radiation.     

Differentiation of primary and secondary fibroblasts in cell culture systems.

As a function of the advancing development of Valo chicken, C3H mice, BN rats, and man in the embryonic, juvenile, adolescent, and senescent phases, stem cells and fibroblasts in the connective tissues of skin and lung differentiate along an 11-stage differentiation sequence in five compartments of the fibroblast stem cell system, when studied in primary ex vivo-in vitro systems. In the fibroblast stem cell system, three stem cells develop in the stem cell compartment along the cell lineage S1-S2-S3, three mitotic fibroblasts (MF) differentiate along the sequence MF I-MF II-MF III in the fibroblast progenitor compartment, three postmitotic fibroblasts (PMF) proceed in the fibroblast maturing compartment along the row PMF IV-PMF V-PMF VI. PMF VI is the terminally differentiated end cell of the fibroblast stem cell system. After a species- and tissue-specific period of high metabolic activity, PMF VI either dies as PMF VIIa in the fibroblast apoptosis compartment or transforms as PMF VIIb in the fibroblast transforming compartment. The reiterated appearance of the 11 cell types in primary stem cell and fibroblast populations and the reiterated age-related changes in the cell type composition of the primary stem cell and fibroblast populations make it very likely that stem cell, mitotic and postmitotic fibroblast equivalents exist in vivo and that age-related changes of the frequencies of the stem cell and fibroblast equivalents result from the progressing differentiation of stem cell, mitotic, and postmitotic fibroblast equivalents along the 11 stage differentiation sequence in the fibroblast equivalent stem cell system in vivo. Secondary fibroblast populations derived from connective tissue of prenatal and postnatal skin of Valo chicken, C3H mice, BN rats, and man, including the normal embryonic human lung fibroblast cell line WI38, were also found to develop along a terminal stem cell sequence. Thus, secondary fibroblast populations in vitro constitute a representative material for studies of general and special issues of cell biology, such as terminal differentiation, aging, apoptosis, and transformation, as long as stem cell system-specific concepts and methods are employed in such investigations.     

Some metabolic differences between human skin and aponeurosis fibroblasts in culutre

Two types of human fibroblast strains were studied in culture. One was derived from abdomen skin and the other from abdominal muscle aponeurosis. Tissue-specific differences were found between thése two cell strains. Skin fibroblasts had faster doubling time, smaller cell volume, and lower glucose consumption when compared to aponeurosis fibroblasts. Furthermore, extracellular amino acid variations showed some specific differences, in particular a lack of serine consumption in skin fibroblasts.     

Air exposure promotes fibroblast growth with increased expression of mitogen-activated protein kinase cascade

Subepithelial tissue cell types in vivo are separated from air by the surface-covering epithelial layer of various organs, e.g., the skin, cornea, and respiratory and upper alimentary tracts. The epithelial defect caused by inflammatory, traumatic or surgical injury would be expected to expose the subepithelial tissue-localized fibroblasts to influx air. However, it is unclear what effects air stimulation elicits in fibroblast growth, which is critical for wound healing. To address this question, we examined the proliferation of 3T3 fibroblasts with bromodeoxyuridine (BrdU) uptake, using fibroblast-embedded collagen gel culture with or without air exposure. The BrdU intake of air-exposed fibroblasts was about 6 times that of air-nonexposed cells. To further characterize this fibroblast growth, we examined the expression of mitogen-activated protein kinase (MAPK) cascade, which plays a key role in the growth-signaling pathway of various cell types. Immunohistochemistry and Western blotting showed that air exposure increased MAPK cascade expression of the cells more strongly than air nonexposure. The data indicate that air exposure promotes MAPK cascade-associated fibroblast growth, suggesting in turn that in wound repair air stimulation itself may be involved in the basic mechanisms of subepithelial fibroblast proliferation and that it may be related to the pathogenesis of excessive fibroplasia through fibroblast overgrowth.