Human Diploid Skin Fibroblasts Research Articles

6-bromo-indirubin-3\u2032-oxime (6BIO), a Glycogen synthase kinase-3\u03b2 inhibitor, activates cytoprotective cellular modules and suppresses cellular senescence-mediated biomolecular damage in human fibroblasts

As genetic interventions or extended caloric restriction cannot be applied in humans, many studies have been devoted to the identification of natural products that can prolong healthspan. 6-bromoindirubin-3′-oxime (6BIO), a hemi-synthetic derivative of indirubins found in edible mollusks and plants, is a potent inhibitor of Glycogen synthase kinase 3β (Gsk-3β). This pleiotropic kinase has been implicated in various age-related diseases including tumorigenesis, neurodegeneration and diabetes. Accordingly, 6BIO has shown anti-tumor and anti-neurodegenerative activities; nevertheless, the potential role of 6BIO in normal human cells senescence remains largely unknown. We report herein that treatment of human diploid skin fibroblasts with 6BIO reduced the oxidative load, conferred protection against oxidative stress-mediated DNA damage, and it also promoted the activation of antioxidant and proteostatic modules; these effects were largely phenocopied by genetic inhibition of Gsk-3. Furthermore, prolonged treatment of cells with 6BIO, although it decreased the rate of cell cycling, it significantly suppressed cellular senescence-related accumulation of biomolecular damage. Taken together, our presented findings suggest that 6BIO is a novel activator of antioxidant responses and of the proteostasis network in normal human cells; moreover, and given the low levels of biomolecules damage in 6BIO treated senescing cells, this compound likely exerts anti-tumor properties.

Delayed persistence of giant-nucleated cells induced by X-ray and proton irradiation in the progeny of replicating normal human f ibroblast cells

Ionising radiation can induce giant-nucleated cells (GCs) in the progeny of irradiated populations, as demonstrated in various cellular systems. Most in vitro studies have utilised quiescent cancerous or normal cell lines but it is not clear whether radiation-induced GCs persist in the progeny of normal replicated cells. In the current work we show persistent induction of GCs in the progeny of normal human-diploid skin fibroblasts (AG1522). These cells were originally irradiated with a single equivalent clinical dose of 0.2, 1 or 2Gy of either X-ray or proton irradiation and maintained in an active state for various post-irradiation incubation interval times before they were replated for GC analysis. The results demonstrate that the formation of GCs in the progeny of X-ray or proton irradiated cells was increased in a dose-dependent manner when measured 7 days after irradiation and this finding is in agreement with that reported for the AG1522 cells using other radiation qualities. For the 1Gy X-ray doses it was found that the GC yield increased continually with time up to 21 days post-irradiation. These results can act as benchmark data for such work and may have important implications for studies aimed at evaluating the efficacy of radiation therapy and in determining the risk of delayed effects particularly when applying protons.

Identification of potential anti-photoageing algal compounds using an in-vitro model of photoageing

Stress-induced premature senescence (SIPS) has been proposed as an in-vitro model for testing the long-term effects of stressful events and to find molecules/natural extracts that protect against such stress. Premature senescence of human skin diploid fibroblasts (HDFs) can be induced by repeated subcytotoxic exposure to UVB, with the appearance of so-called biomarkers of senescence such as growth arrest, senescence-associated beta-galactosidase activity, senescence-associated gene over-expression and the common 4977-bp mitochondrial DNA deletion. This model of UVB-induced premature senescence has been acknowledged as a robust in-vitro model in photoageing research. In this study, the potential anti-photoageing effects of a series of algal extracts were tested. The appearance of the biomarkers of UVB-induced premature senescence of HDFs was studied with or without algal extracts. One algal extract was shown to be particularly protective against UVB-induced SIPS. The results obtained here reinforce the notion that UVB-induced premature senescence of HDFs can be used to screen potential anti-photoageing compounds.

Genomic and proteomic profiling of oxidative stress response in human diploid fibroblasts

A number of lines of evidence suggest that senescence of normal human diploid fibroblasts (HDFs) in culture is relevant to the process of aging in vivo. Using normal human skin diploid fibroblasts, we examine the changes in genes and proteins following treatment with a mild dose of H2O2, which induces premature senescence. Multidimensional Protein Identification Technology (MudPIT) in combination with mass spectrometry analyses of whole cell lysates from HDFs detected 65 proteins in control group, 48 proteins in H2O2-treated cells and 109 proteins common in both groups. In contrast, cDNA microarray analyses show 173 genes up-regulated and 179 genes down-regulated upon H2O2 treatment. Both MudPIT and cDNA microarray analyses indicate that H2O2 treatment caused elevated levels of thioredoxin reductase 1. Semi-quantitative RT-PCR and Western-blot were able to verify the finding. Out of a large number of genes or proteins detected, only a small fraction shows the overlap between the outcomes of microarray versus proteomics. The low overlap suggests the importance of considering proteins instead of transcripts when investigating the gene expression profile altered by oxidative stress.

Proteomic Identification of Insulin-like Growth Factor-binding Protein-6 Induced by Sublethal H2O2 Stress from Human Diploid Fibroblasts

Fibroblasts are the most ubiquitous cell types within our body. They produce various factors to maintain the texture and structure of a particular organ or tissue. To identify protein factors secreted by fibroblasts and alteration of these protein factors upon oxidative stress, HCA3 human skin diploid fibroblasts were exposed to a sublethal dose of H2O2, which induces a prematurely senescent phenotype. Conditioned media from prematurely senescent cells versus control cells were analyzed for proteins using an LC-MS/MS-based proteomic technique. Collagen alpha1(VI), collagen alpha2(I), fibronectin, lumican, and matrix metalloproteinase 2 were among the proteins consistently detected from control and H2O2-treated cells. Insulin-like growth factor-binding protein-6 (IGFBP-6) consistently showed up in the conditioned medium of H2O2-treated cells but not from untreated cells. Increased IGFBP-6 production due to H2O2 treatment was confirmed by RT-PCR and Western blot analyses. While H2O2 induced a dose-dependent elevation of IGFBP-6 mRNA, Western blot analyses detected elevated levels of IGFBP-6 protein in the conditioned medium of H2O2-treated cells. In comparison, fibronectin or matrix metalloproteinase 2 did not show changes at the mRNA level in cell lysates or at the protein level in the conditioned medium by H2O2 treatment. Using several types of toxins at sublethal doses, including cis-platin, hydroxyurea, colchicine, L-mimosine, rhodamine, dithiothreitol, or N-ethylmaleimide, we found that these agents induced increases of IGFBP-6 at mRNA and protein levels. An increased level of IGFBP-6 protein was detected in the plasma of aging mice and of young mice treated with doxorubicin. These data suggest that IGFBP-6 may serve as a sensitive biomarker of cell degeneration or injury in vitro and in vivo.

Fibroblast Cell Behavior on Bound and Adsorbed Fibronectin onto Hyaluronan and Sulfated Hyaluronan Substrates

The effect of fibronectin protein (Fn) coating onto polysaccharide layers of hyaluronic acid (Hyal) and its sulfated derivative (HyalS) on fibroblast cell adhesion was analyzed. The Hyal or HyalS were coated and grafted on the glass substrate by a photolithographic method. The Fn coating was achieved by two different routes: the immobilization of Fn by covalent bond to the polysaccharide layers and the simple adsorption of Fn onto Hyal and HyalS surfaces. AFM, SEM, and ATR-FTIR techniques were used for the chemical and topographical characterization of the surfaces. According to AFM and SEM data, the surface topography was dependent on the method used to cover the polysaccharide layers with the protein. ATR-FTIR analysis supplied information about the rearrangement of Fn after the interaction (adsorption or binding) with the Hyal and the HyalS. The conformational changes of the Fn were minimal when it was simply adsorbed on HyalS surfaces and larger once bound, whereas on the Hyal layer the protein underwent a bigger conformational change once adsorbed and covalently grafted. Then, the biological characterization was carried out by analyzing the human diploid skin fibroblasts adhesion on these surfaces. The morphology of fibroblasts was evaluated by SEM, whereas the dynamics of fibroblasts movement were recorded by a time-lapse system. Cell variations in area, perimeter, and length were analyzed at 2, 4, and 6 h. It was found that the addition of Fn (covalently bound or merely adsorbed) was fundamental in the promotion of fibroblasts adhesion and spreading. The greatest adhesion occurred onto HyalS layers covered by the adsorbed Fn.

Exposure of human skin diploid fibroblasts to repeated subcytotoxic doses of ultraviolet-B induces the overexpression of transforming growth factor-beta1 mRNA.

In this work we show that the steady state mRNA level of TGF-beta1 is significantly increased in UVB-induced premature senescence.

UVB-induced premature senescence of human diploid skin fibroblasts

In this work, we show that repeated stresses with UVB (290–320 nm) induce stress-induced premature senescence (SIPS) of skin human diploid fibroblasts (HDFs). HDFs at early cumulative population doublings were exposed three or five times to increasing subcytotoxic doses of UVB with one stress per day. After 2 days of recovery, several biomarkers of replicative senescence were established. First, there was an increase in the proportion of cells positive for senescence-associated β-galactosidase activity. Second, there was a loss of replicative potential as assessed by a very low level of [ 3 H ]-thymidine incorporation. Third, the steady-state level of the mRNA of three senescence-associated genes, i.e. fibronectin, osteonectin and SM22, was increased in HDFs at 72 h after three and five exposures to UVB. In conclusion, these results suggest that it is possible to induce SIPS in HDFs after repeated exposures to subcytotoxic doses of UVB. This model could be used to test whether HDFs in UVB-induced premature senescence are able to promote epithelial cell growth and tumorigenesis in skin, as shown recently with HDFs in H 2O 2-induced premature senescence.

Reaction of the Skin Fibroblast Cytoskeleton to Micromanipulation Interventions

Micromanipulation is a strong mechanical intervention into cellular integrity and induces large changes in the fine structure of the treated cells. Human diploid skin fibroblasts (KF1 and KF2 cell lines) were chosen as an experimental model. Special hatching needles were used for defined micromanipulation interventions (deformation of plasma membrane). Changes in cytoskeletal structures were visualized by using fluorescent and confocal microscopy. The actin cytoskeleton showed a more sensitive response to micromanipulation than microtubules. Characteristic changes in microfilaments, i.e., thickenings and knot formation, were visible in treated cells fixed immediately after micromanipulation and were the result of hatching-needle pressure on the plasma membrane as well as a reaction of actin filaments localized near the plasma membrane deformation. These direct changes and also other specific alterations in the actin filament network were detectable 14 to 16 h after treatment, but they were not observed when longer reparation intervals were used.

Induction of the SAPK activator MIG-6 by the alkylating agent methyl methanesulfonate.

The alkylating agent methylmethanesulfonate (MMS) activates the c-jun N-terminal kinase (JNK)/stress-activated protein kinase (SAPK) and the p38 mitogen-activated protein kinase (p38MAPK) pathways via different mechanisms of action. Activation of p38MAPK by MMS involves the pp125 focal adhesion kinase-related tyrosine kinase RAFTK and the MAPK kinase 3. The way in which MMS can activate JNK/SAPK has not been elucidated. Here we describe the identification by differential display of human mitogen-activated gene-6 (MIG-6) as a novel MMS-inducible gene. Induction of MIG-6 by MMS was found in human diploid skin fibroblasts and in simian virus 40-transformed skin fibroblasts, indicating that the enhanced expression of MIG-6 after MMS-treatment did not require p53. The signal leading to activation of MIG-6 appeared to be independent of DNA damage. High MIG-6 expression was found in the liver, lung, and placenta. MIG-6 is an adapter protein that binds to the activated form of cdc42Hs and to 14-3-3 proteins, thereby activating JNK/SAPKs. Our results suggest that activation of JNK/SAPKs by MMS may involve the induction of MIG-6.

Gene-Specific DNA Repair of Pyrimidine Dimers Does Not Decline during Cellular Aging in Vitro

A large number of studies have demonstrated that various kinds of DNA damage accumulate during aging and one of the causes for this could be a decrease in DNA repair capacity. However, the level of total genomic repair has not been strongly correlated with aging. DNA repair of certain kinds of damage is known to be closely connected to the transcription process; thus, we chose to investigate the level of gene-specific repair of UV-induced damage using in vitro aging of human diploid skin fibroblasts and trabecular osteoblasts as model systems for aging. We find that the total genomic repair is not significantly affected during cellular aging of cultures of both human skin fibroblasts and trabecular osteoblasts. Gene-specific repair was analyzed during cellular aging in the dihydrofolate reductase housekeeping gene, the p53 tumor suppressor gene, and the inactive region X754. There was no clear difference in the capacity of young and old cells to repair UV-induced pyrimidine dimers in any of the analyzed genes. Thus, in vitro senescent cells can sustain the ability to repair externally induced damage.

P53 splice acceptor site mutation and increased HsRAD51 protein expression in Bloom's syndrome GM1492 fibroblasts.

GM1492 human diploid skin fibroblasts derived from a patient with Bloom's syndrome (BS), lack detectable p53 mRNA and protein as shown by Northern and Western blotting, and express an increased RecA-like activity. Here we demonstrate that the p53 gene is grossly intact in GM1492 cells according to Southern blotting. DNA sequencing did not reveal any mutations in the promoter region of p53. A highly sensitive RT-PCR produced a p53 cDNA fragment that was shorter than expected. DNA sequence analysis of p53 cDNA showed that exon 6 was missing, explaining the shorter PCR product. Furthermore, sequencing of genomic DNA revealed a base substitution at the nucleotide preceding the AG splice acceptor site of intron 5. The omission of exon 6 creates a frameshift at the junction of exons 5 and 7, and a premature stop codon in exon 7. The aberrant transcript is predicted to encode a truncated p53 protein containing 189 amino acid residues. Moreover, Western blotting demonstrated elevated HsRAD51 protein levels in GM1492 cells. The lack of sufficient levels of wild-type p53 and increased levels of HsRad51 protein may contribute to the elevated RecA-like activity in the GM1492 fibroblasts.

Prolonged cell cycle arrest in irradiated human diploid skin fibroblasts: the role of nutrient deprivation.

Ionizing radiation has been reported to cause an irreversible cell cycle arrest in normal human diploid fibroblasts. However, colony survival assays show that even at high doses of gamma radiation, human diploid fibroblasts do not irreversibly arrest, and that a dose-dependent fraction is capable of continued cycling. In this study, we resolve the apparent discrepancy between colony survival assays and the observed radiation-induced prolonged arrest. Using flow cytometry analysis, we have confirmed that human diploid fibroblasts do exhibit a prolonged cell cycle arrest in both G(1) and G(2)/M phases of the cell cycle. However, a single replacement of fresh growth medium stimulated a fraction of the arrested population of cells to transiently re-enter the cell cycle. Daily medium changes stimulated these irradiated human diploid fibroblasts to continue cycling until they were contact-inhibited. Thus the fraction of human diploid fibroblasts which survive radiation exposure and are capable of cycling appears to permanently arrest as a result of nutrient insufficiency. Western blot analysis demonstrated a radiation-induced elevation in TP53 (formerly known as p53) protein levels within 2 h postirradiation, followed by a decrease to levels comparable to those in unirradiated controls. The TP53 and CDKN1A (formerly known as p21) protein levels were indistinguishable after 24 h and remained elevated for a 6-day period of observation in both control and irradiated cultures. Our studies indicate that human diploid fibroblasts are capable of re-entering the cell cycle after exposure to ionizing radiation and that this re-entry is dependent on a constant supply of nutrients provided by fresh medium changes. The fraction of cells capable of resuming cell cycling is consistent with the surviving fraction of cells in colony assays.

Induction of Intracellular Calcium Oscillations in Human Skin Fibroblast Populations by Sinusoidal Extremely Low-Frequency Magnetic Fields (20 Hz, 8 mT) Is Dependent on the Differentiation State of the Single Cell

Experiments were performed to analyze whether short-term exposure to a sinusoidal extremely low-frequency electromagnetic field (20 Hz, 8 mT) can alter the dynamics of intracellular calcium in diploid human skin fibroblasts. In heterogeneous fibroblast populations, about 30% of the cells responded with a change in the oscillation activity of intracellular calcium within 40 min. It was demonstrated at the level of the single cell that the responsiveness of fibroblast populations to extremely low-frequency electromagnetic fields depends on the specific differentiation state of the exposed cell. The data obtained clearly indicate that mitotic progenitor fibroblasts respond with an enhancement of the dynamics of calcium, whereas in postmitotic fibrocytes a reduction of the dynamics was observed when the cells were co-stimulated with suboptimal concentrations of platelet-derived growth factor. Thus data from our laboratory on terminal differentiation induced by extremely low-frequency electromagnetic fields may be correlated with changes in the dynamics of Ca2+ reported here.

Wavelength specific activation of PI 3-kinase by UVB irradiation

We investigated the effect of UVB irradiation on phospholipid metabolism using normal human diploid skin fibroblasts. When cells were exposed to monochromatic UV light, the intracellular PIP 3 level was increased within 1 min in a wavelength-specific manner. The increase was most marked in the UVB range and was inhibited by a PI 3-kinase inhibitor, tyrosine kinase inhibitor, or antioxidant reagents. Furthermore, the decrease of cell viability induced by UVB irradiation was significantly blocked by wortmannin. These results suggest that PI 3-kinase activation is involved in novel cellular responses specific for UVB that lead to cell death.

The time-pattern of rises and falls in proliferation fades with senescence of mortal lines and is perpetuated in immortal rat hepatoma Fao cell line.

Immortal cells perpetuate the rises and falls of proliferation that are progressively damped in mortal long-term cultured cells. For immortal rat hepatoma Fao cells, similar waves of proliferation occurred about every 3-4 wk. Under the same conditions, embryonic human fibroblasts and transformed but not immortalized embryonic fibroblasts display similarly recurring proliferation waves that progressively decrease in amplitude until senescence of the lines. In addition, strains of diploid normal human skin fibroblasts cultured under different culture conditions display a similar time-pattern of proliferation. Although the amplitude and baseline of these fluctuations are characteristic for each cell line, a common point was marked slow down in proliferation after every sequence of about 25 population doublings for all cells. Renewed proliferation waves of Fao cells allow about 22-23 additional population doublings each. Normal embryonic fibroblast culture and its transformed counterpart accumulate about 30 and 60 population doublings, respectively, before senescence. Normal fibroblast strains accumulate about 25 population doublings over their entire life spans. This halt in proliferation after every stretch of about 25 population doublings may correspond to a structural or functional stop following attrition of telomeric DNA. This putative stop may be bypassed once in transformed embryonic cells and repetitively in immortal cells. In support of this hypothesis, we observed rapid telomere shortening, in two steps, during divisions of mortal embryonic cells, and maintenance of long telomeres in immortal Fao cells, which may indicate episodic repair of telomeres. Alternatively, such maintenance of long telomeres may reflect survival and successive clonal growth of rare cells with long telomeres. We suggest that the balance between telomere attrition and repair processes regulates the waves of proliferation.

Evaluation of the trophic effect of human placental polydeoxyribonucleotide on human knee skin fibroblasts in primary culture.

A simple assay capable of evaluating the trophic effect of growth factors or active principles on human skin diploid fibroblasts in primary culture has been developed. The results indicate that at physiological concentrations (20-100 micrograms/ml) a human placental polydeoxyribonucleotide (PDRN) preparation enhances the growth of human skin diploid fibroblasts of the knee in primary culture. This effect is consistently reproducible in the case of patients over 60 years of age, and may explain previously reported data on the successful clinical applications of human placental preparations, suggesting a selective benefit of PDRN in wound healing when compared to other treatments.

HETEROGENEITY IN RADIOSENSITIVITY OF HUMAN DIPLOID FIBROBLASTS FROM KELOIDS AND NORMAL SKINS

Colony-forming ability was employed in evaluating the susceptibility to in vitrogamma ionizing radiation in human diploid skin fibroblasts (HDF). Twelve pairs of HDF, each composed of fibroblasts from excised keloid lesion and local normal skin tissue as its control, were studied in patients with clinically persistent keloids. Parameters of radiosensitivity, both D 0and D 10, and growth kinetics were examined. The radiosensitivity in three of the 12 keloids (25%) were demonstrated significantly increased than their counterpart controls, even though no difference in growth kinetics in between. Moreover, a broad range in the radiosensitivity of fibroblast cells was demonstrated and it is suggested that there is a great heterogeneity of cellular response to radiation in HDF.

GM1492 Human Diploid Skin Fibroblasts Lack the p53-Dependent G1 Cell-Cycle Checkpoint

Recently, we reported that GM1492 human diploid skin fibroblasts derived from a Bloom′s patient upon UV-C irradiation fail to increase p53 to a detectable level and nevertheless accumulate in the G1-phase of the cell-cycle, Here we show that in GM1492 cells other types of DNA-damaging agents also fail to induce p53 as well as WAF1, a p53-regulated gene product involved in G1 cell-cycle arrest, Furthermore, the p53-dependent G1 cell-cycle checkpoint is indeed defective in these cells. However, induction of GADD45 mRNA still occurs in GM1492 after irradiation with UV-C, Since GADD45 is known to inhibit the entry into S, these data suggest that the observed accumulation of GM1492 cells in G1 after W-C irradiation occurs at the G1/S boundary and is due to an inhibition of initiation of DNA-replication.

Fructose-induced enhanced mitogenicity of diploid human cells: possible relationship with cell differentiation.

Fructose strongly stimulates the growth of normal diploid human skin fibroblasts (SFs) and induces marked changes in their morphology and lipid accumulation. This mitogenic effect occurs despite very low fructose consumption and depends on the presence of glutamine. The cell kinetics of cultured fructose-fed human skin fibroblasts were different from those fed on glucose: in the presence of fructose a high proliferative index persisted at Day 14 of culture and the duration of the total cell cycle and of the G1 + 1/2 M and S phases was slightly shorter. The mitogenic effect of fructose on SF was largest in the presence of human serum: it was small or undetectable when fibroblasts were cultured in media supplemented with dialyzed human serum, fetal bovine serum, or serum substitutes. This suggests that serum growth factor(s) mediate the mitogenic effect of fructose. Only normal diploid human cells seem to be sensitive to this mitogenic effect of fructose: the long-term growth of normal human liver cells on fructose was slightly better or similar to that on glucose. In contrast, fructose could only support limited growth of hamster fibroblastic Nil cells and of a transformed human fibroblastic line, which grew better with glucose.