PI3-kinase-dependent activation of apoptotic machinery occurs on commitment of epidermal keratinocytes to terminal differentiation

We have investigated the earliest events in commitment of human epidermal keratinocytes to terminal differentiation. Phosphorylated Akt and caspase activation were detected in cells exiting the basal layer of the epidermis. Activation of Akt by retroviral transduction of primary cultures of human keratinocytes resulted in an increase in abortive clones founded by transit amplifying cells, while inhibition of the upstream kinase, PI3-kinase, inhibited suspension-induced terminal differentiation. Caspase inhibition also blocked differentiation, the primary mediator being caspase 8. Caspase activation was initiated by 2 h in suspension, preceding the onset of expression of the terminal differentiation marker involucrin by several hours. Incubation of suspended cells with fibronectin or inhibition of PI3-kinase prevented caspase induction. At 2 h in suspension, keratinocytes that had become committed to terminal differentiation had increased side scatter, were 7-aminoactinomycin D (7-AAD) positive and annexin V negative; they exhibited loss of mitochondrial membrane potential and increased cardiolipin oxidation, but with no increase in reactive oxygen species. These properties indicate that the onset of terminal differentiation, while regulated by PI3-kinase and caspases, is not a classical apoptotic process.     

Analysis of the growth kinetics of murine erythroleukaemia cells following commitment to terminal differentiation

Differentiation of murine erythroleukaemia cells by various inducers involves a step of irreversible commitment, after which the presence of the inducer is not required for completion of the process. Some cells become partially committed and give rise to differentiated as well as undifferentiated progeny. Commitment occurs asynchronously; under suboptimal inducing conditions, such as low concentration of inducer or short duration of exposure, both committed and uncommitted cells co-exist. In the present study the growth of these subpopulations was compared. Murine erythroleukaemia cells were exposed to the inducer hexamethylene-bisacetamide for 24 hr, then the inducer was removed by washing and the rate of proliferation of committed and uncommitted cells was measured. Commitment was scored by cloning the cells in inducer-free semi-solid medium and determining the cellular composition of the colonies with respect to haemoglobin content. The results indicated that following removal of the inducer the rate of proliferation was retarded similarly for both committed and uncommitted cells. Partially committed cells disappeared rapidly due to assymetrical cell division into fully committed and uncommitted cells. Both committed and uncommitted cells resumed logarithmic growth at 53 hr, but while uncommitted cells continued this pace until saturation was achieved, committed cells stopped multiplying earlier as a result of terminal differentiation.     

Analysis of the growth kinetics of murine erythroleukaemia cells following commitment to terminal differentiation

Abstract Differentiation of murine erythroleukaemia cells by various inducers involves a step of irreversible commitment, after which the presence of the inducer is not required for completion of the process. Some cells become partially committed and give rise to differentiated as well as undifferentiated progeny. Commitment occurs asynchronously; under suboptimal inducing conditions, such as low concentration of inducer or short duration of exposure, both committed and uncommitted cells co-exist. In the present study the growth of these subpopulations was compared. Murine erythroleukaemia cells were exposed to the inducer hexamethylene-bisacetamide for 24 hr, then the inducer was removed by washing and the rate of proliferation of committed and uncommitted cells was measured. Commitment was scored by cloning the cells in inducer-free semi-solid medium and determining the cellular composition of the colonies with respect to haemoglobin content. The results indicated that following removal of the inducer the rate of proliferation was retarded similarly for both committed and uncommitted cells. Partially committed cells disappeared rapidly due to assymetrical cell division into fully committed and uncommitted cells. Both committed and uncommitted cells resumed logarithmic growth at 53 hr, but while uncommitted cells continued this pace until saturation was achieved, committed cells stopped multiplying earlier as a result of terminal differentiation.     

Control of mouse myoblast commitment to terminal differentiation by mitogens

Regulation of the transition of mouse myoblasts from proliferation to terminal differentiation was studied with clonal density cultures of a permanent clonal myoblast cell line. In medium lacking mitogenic activity, mouse myoblasts withdraw from the cell cycle, elaborate muscle-specific gene products, and fuse to form multinucleated myotubes. Addition of a purified mitogen, fibroblast growth factor, to mitogen-depleted medium stimulates continued proliferation and prevents terminal differentiation. When mitogens are removed for increasing durations and then refed, mouse myoblasts irreversibly commit to terminal differentiation: after 2–4 h in the absence of mitogens, myoblasts withdraw from the cell cycle, elaborate muscle-specific gene products, and fuse in the presence of mitogens that have been fed back. Population kinetics of commitment determined with ³H-thymidine labeling and autoradiography suggest the following cell-cycle model for mouse myoblast commitment: (1) if mitogens are present in the extracellular environment of myoblasts in G₁ of the cell cycle, the cells enter S and continue through another cell cycle; (2) if mitogens have been absent for 2 or more hours, cells in G₁ do not enter S; the cells commit to differentiate, permanently withdraw from the cell cycle (will not enter S if mitogens are refed), and they subsequently elaborate acetylcholine receptors and fuse (even if mitogens are refed); (3) cells in other phases of the cell cycle continue to transit the cell cycle in the absence of mitogens until reaching the next G₁. The commitment kinetics and experiments with mitotically synchronized cells suggest that the commitment “decision” is made during G₁. Present results do not, however, exclude commitment of some cells in other phases of the cell cycle.     

Uncoupling of the calcium-induced terminal differentiation and the activation of membrane-associated transglutaminase in murine keratinocytes by type-beta transforming growth factor

Calcium is an important regulator of terminal differentiation of cultured epidermal cells. In order to investigate the relationship between the termination of proliferative activity and the process of keratinization, we studied the time course of events induced by a sudden increase of extracellular calcium (calcium-switch) in cultures of established murine skin keratinocytes (BALB/c MK-1). These cells displayed density-dependent growth arrest without undergoing terminal differentiation in the presence of serum- and mitogen-free medium with a calcium concentration less than 0.10 mM. The calcium-switch alone was sufficient to induce a dose-dependent burst of DNA synthesis, which was followed by a state in which the cells became progressively refractory to mitogenic stimulation with epidermal growth factor. Treatment of cultures with type beta transforming growth factor during the first 6- to 10 h following the calcium-switch completely eliminated the initial burst of DNA synthesis as well as the terminal differentiation in response to calcium. On the other hand, the calcium-switch also caused the induction of a four- to fivefold increase of the activity of the membrane-associated form of transglutaminase that is required for keratinization, which was not affected by the presence of type beta transforming growth factor. These observations suggest that type beta transforming growth factor regulates the calcium-induced terminal cell division independently of the induction of phenotypic markers of keratinization, such as transglutaminase.     

Caspase activation in the terminal differentiation of human epidermal keratinocytes

The epidermis is a multilayered squamous epithelium in which dividing basal cells withdraw from the cell cycle and progressively differentiate as they are displaced toward the skin surface. Eventually, the cells lose their nucleus and other organelles to become flattened squames, which are finally shed from the surface as bags of cross-linked keratin filaments enclosed in a cornified envelope [1]. Although keratinocytes can undergo apoptosis when stimulated by a variety of agents [2], it is not known whether their normal differentiation programme uses any components of the apoptotic biochemical machinery to produce the cornified cell. Differentiating keratinocytes have been reported to share some features with apoptotic cells, such as DNA fragmentation, but these features have not been seen consistently [3]. Apoptosis involves an intracellular proteolytic cascade, mainly mediated by members of the caspase family of cysteine proteases, which cleave one another and various key intracellular target proteins to kill the cell neatly and quickly [4]. Here, we show for the first time that caspases are activated during normal human keratinocyte differentiation and that this activation is apparently required for the normal loss of the nucleus.     

Interferon-gamma modulates terminal differentiation and the expression of desquamin in cultured keratinocytes

Interferon (IFN)-gamma has been shown to modulate cell differentiation and the expression of cell surface molecules of cultured human keratinocytes; it also induces cell shedding. We have previously described the properties of desquamin, a cell surface adhesion molecule from the stratum corneum. We report here on the impact of IFN-gamma on the expression of desquamin. We document the related morphological changes in terminal differentiation. We cultured human keratinocytes in three different culture systems: in serum-free medium at low Ca2+ (0.1 mM), at high Ca2+ (1.5 mM), and at high Ca2+ with 10% serum. IFN-gamma (100 U/ml) was added to each culture system after overnight incubation. In all cases, IFN-gamma induced an altered phenotype, as shown by phase contrast and electron microscopy. We exposed cultured cells to antibodies to the desquamins (glycoproteins from the stratum corneum). Immunoflurescent localization and Western blotting showed that the desquamins were expressed only under culture conditions where both serum and IFN-gamma were present. The induction of desquamin expression by IFN-gamma coupled with an increase in cell shedding, suggests that we have developed a suitable culture system for the study of desquamation in vitro.     

The role of cathepsin E in terminal differentiation of keratinocytes

Cathepsin E (CatE) is predominantly expressed in the rapidly regenerating gastric mucosal cells and epidermal keratinocytes, in addition to the immune system cells. However, the role of CatE in these cells remains unclear. Here we report a crucial role of CatE in keratinocyte terminal differentiation. CatE deficiency in mice induces abnormal keratinocyte differentiation in the epidermis and hair follicle, characterized by the significant expansion of corium and the reduction of subcutaneous tissue and hair follicle. In a model of skin papillomas formed in three different genotypes of syngeneic mice, CatE deficiency results in significantly reduced expression and altered localization of the keratinocyte differentiation induced proteins, keratin 1 and loricrin. Involvement of CatE in the regulation of the expression of epidermal differentiation specific proteins was corroborated by in vitro studies with primary cultures of keratinocytes from the three different genotypes of mice. In wild-type keratinocytes after differentiation inducing stimuli, the CatE expression profile was compatible to those of the terminal differentiation marker genes tested. Overexpression of CatE in mice enhances the keratinocyte terminal differentiation process, whereas CatE deficiency results in delayed differentiation accompanying the reduced expression or the ectopic localization of the differentiation markers. Our findings suggest that in keratinocytes CatE is functionally linked to the expression of terminal differentiation markers, thereby regulating epidermis formation and homeostasis.     

Kinetics of histone H10 accumulation and commitment to differentiation in murine erythroleukemia cells

The accumulation of histone H10 (also denoted IP 25) in murine erythroleukemia cells, induced to differentiate with hexamethylene bis-acetamide, was shown to precede by 15-20 h the appearance in the culture of cells irreversibly committed to differentiate. In addition the rates of accumulation of H10 and of committed cells vary in a similar manner with the HMBA concentration. Flow microfluorimetric analysis demonstrated that the accumulation of H10 did not occur simultaneously in all the cells. This accumulation of histone H10 was initiated first in cell in the G2 phase of the cell cycle and subsequently in the cells situated in all the phases of the cell cycle.     

Regulation of terminal differentiation of cultured human keratinocytes by vitamin A

Vitamin A is known to exert an important influence on epithelial differentiation. The fetal calf serum supplement of cell-culture medium contains enough of the vitamin to affect the differentiation of cultured keratinocytes derived from epidermis and from other stratified squamous epithelia. The cellular and molecular properties of the cultures are altered when the medium is supplemented with serum from which the vitamin A has been removed by solvent extraction (delipidized serum). Cell motility is reduced, the adhesiveness of cells increases and pattern formation is prevented. In both epidermal and conjunctival keratinocytes, removal of vitamin A leads to the synthesis of a 67 kd keratin characteristic of terminally differentiating epidermis and to much reduced synthesis of the 52 kd and 40 kd keratins typical of conjunctiva. These changes, both cellular and molecular, are reversed by the addition of retinyl acetate to the medium containing delipidized serum. Cell motility and pattern formation are restored, and detachment of the most mature cells from the surface of the stratified epithelium is promoted. Synthesis of the 67 kd keratin is prevented and the synthesis of the 40 and 52 kd keratins is stimulated. The nature of the keratins synthesized is regulated by the concentration of vitamin A, and each cell type adjusts its synthesis differently at a given vitamin concentration.     

Significance of the cell cycle in commitment of murine erythroleukemia cells to erythroid differentiation.

The relationship between differentiation of murine erythroleukemia cells (MEL) induced by DMSO and the cell division cycle has been analyzed. We demonstrate that incubation in the presence of DMSO increases the length of the G1 phase of the cell cycle. A method of synchronization of MEL cells by unit gravity sedimentation has been developed and characterized. Using this method, a series of synchronized cell populations covering the entire cell division cycle can be generated simultaneously. Cells synchronized by this technique were challenged with DMSO and analyzed for kinetics of commitment to the differentiation program. Our results indicate that populations of cells in G1 or G2 at the time of addition of inducer give rise to a greater proportion of committed cells than an unfractionated population, while cells in S phase result in a lower percentage of committed cells than the unfractionated population when cultured in DMSO.     

Lanthanum influx into cultured human keratinocytes: effect on calcium flux and terminal differentiation.

Trivalent cation lanthanum (La) binds to calcium binding sites of cells and either mimics the properties of calcium or inhibits the effects of calcium by displacing calcium from its binding sites. Extracellular calcium induces differentiation of human epidermal keratinocytes in culture, in part by increasing the intracellular calcium levels (Cai). Therefore, in this study we determined the effect of La on differentiation and intracellular calcium levels of keratinocytes. We observed that La inhibited the production of cornified envelopes, a marker for terminal differentiation of keratinocytes. La inhibited the calcium requiring envelope cross-linking enzyme, transglutaminase, in a direct manner, presumably, by displacing calcium from its binding site on the enzyme. La inhibited the influx and the efflux of 45Ca from keratinocytes. Paradoxically, extracellular La appeared to increase the Cai levels of keratinocytes as measured by the fluorescent probe indo-1. However, subsequent experiments revealed that indo-1 bound La with a higher affinity than Ca and emitted fluorescence in the same wavelength as the Ca bound form. Using this probe, we observed that La enters keratinocytes in a dose-dependent fashion and achieves concentrations exceeding 80 nM when the external La concentration is raised to 300 microM. This fully accounted for the apparent increase in Cai when La was added to the cells. Treatment of cells with ionomycin increased indo-1 fluorescence maximally in the presence of La indicating influx of La via this Ca specific ionophore. Our results indicate that La enters cells and inhibits calcium mediated keratinocyte differentiation both by blocking Ca influx and by blocking calcium regulated intracellular processes such as transglutaminase directed cornified envelope formation.     

Seric factors influence cell cycle modifications during commitment of murine erythroleukemia cells to differentiation.

Cell cycle modifications are among the early events which take place during the induced differentiation of murine erythroleukemia (MEL) cells; a transient accumulation of the cells in the G1 phase of the cell cycle, followed by a re-entry of the cells into a proliferation state, has been described. In order to characterize a putative role of serum in such variations, we have studied the modifications of the cell cycle parameters when cells were induced to differentiate in the presence or in the absence of seric factors. We show that, in the absence of exogenous factors brought by serum, the G1 accumulation was enhanced both in amplitude and in duration, but cells were still able to bypass the G1 block and re-enter into the S phase. These results indicate that the resumption of cell proliferation after the transient block is under synergistic control of seric and endogenous factors, but these later are sufficient to overcome the block. However, MEL cells were unable to differentiate in the absence of seric factors, as measured by the number of benzidine-positive cells during induction with hexamethylene-bisacetamide (HMBA) or butyric acid. This capacity to differentiate was recovered when serum was added back to the culture medium, and the efficiency of recovery was maximal when cells underwent a full round of DNA replication in the presence of serum after the G1 block. The analysis of two molecular markers of cell differentiation confirmed these results.     

Commitment to differentiation and expression of early differentiation markers in murine keratinocytes in vitro are regulated independently of extracellular calcium concentrations

In the epidermis, one of the earliest characterized events in keratinocyte differentiation is the coordinate induction of a pair of keratins specifically expressed in suprabasal cells, keratin 1 (K1) and keratin 10 (K10). Both in vivo and in vitro, extracellular calcium is necessary for several biochemical and structural changes during keratinocyte differentiation. However, it has been unclear if calcium serves as a differentiation signal in keratinocytes. In these studies, expression of suprabasal keratin mRNA and protein is used to test whether the initial differentiation of primary mouse keratinocytes in vitro is dependent on changes in the concentration of extracellular calcium. K1 mRNA was expressed at low levels in cultures of keratinocytes growing on plastic in 0.05 mM calcium but in attached cells was not further induced by increases in the concentration of extracellular calcium. Suspension of the keratinocytes into semi-solid medium induced a rapid and substantial increase in both expression of K1 mRNA and in the percentage of cells expressing suprabasal keratin proteins. The induction was unaffected by the concentration of calcium in the semi-solid medium and could not be enhanced by exposing attached cells to higher calcium before suspension. The induction of K1 mRNA could be inhibited by exposure of the keratinocytes to either EGF or fibronectin. These results suggest that commitment of mouse keratinocytes to terminal differentiation is independent of extracellular calcium and may be regulated primarily by extracellular factors other than calcium.     

Kinetics of histone H1 ° accumulation and commitment to differentiation in murine erythroleukemia cells

The accumulation of histone H1 ° (also denoted IP 25) in murine erythroleukemia cells, induced to differentiate with hexamethylene bis-acetamide, was shown to precede by 15–20 h the appearance in the culture of cells irreversibly committed to differentiate. In addition the rates of accumulation of H1 ° and of committed cells vary in a similar manner with the HMBA concentration. Flow microfluorimetric analysis demonstrated that the accumulation of H1 ° did not occur simultaneously in all the cells. This accumulation of histone H1 ° was initiated first in cell in the G2 phase of the cell cycle and subsequently in the cells situated in all the phases of the cell cycle.     

Differential effects of fibroblast growth factor and tumor promoters on the initiation and maintenance of adipocyte differentiation

Fibroblast growth factor (FGF) has been shown to inhibit the differentiation of myogenic and adipogenic cell lines without inducing a proliferative response. We have previously shown that agents capable of activating protein kinase C (PKC), such as FGF and the phorbol ester tetradecanoyl phorbol-13-acetate (TPA), inhibit the differentiation of the adipogenic cell line TA1, as measured by the rapid loss of adipocyte-specific RNAs. We report here that the treatment of fully differentiated TA1 adipocytes with FGF at 10 ng/ml induces the reversal of adipocyte differentiation, even in cells where PKC activity has been down-regulated by TPA pretreatment. In contrast, TPA or lower concentrations of FGF (1 ng/ml), both effective inducers of c-fos RNA in adipocytes, fail to reverse adipocyte differentiation. The adipocytes, however, will extinguish differentiation-specific functions in response to TPA by the addition of a calcium ionophore. Therefore, we propose that there are two FGF-sensitive pathways in TA1 cells: one responsible for the initiation of differentiation (TPA sensitive) and another required for maintenance of the adipose phenotype (TPA insensitive). These results suggest that activation of two distinct signaling pathways--one PKC and calcium dependent, the other FGF activated but PKC independent--are capable of inhibiting the biochemical events responsible for the maintenance of adipocyte differentiation.