Induction of differentiation and arrest of proliferation of mouse myeloid leukemia M1 cells

The relationship between differentiation and the cell cycle of mouse myeloid leukemia M1 cells was studied. The cells were induced to differentiate into macrophage-like cells by treatment with conditioned medium (CM) of hamster embryo cells. CM-treated cells traversed the S phase of the cell cycle at least once, then a fraction of the cells lost the ability to enter the S phase and accumulated in the G1 phase. Incorporation of [³H]thymidine in phagocytosis-induced cells decreased after 12–18 h of CM treatment. The morphology of the differentiated cells changed and the nucleus-cell ratio (NCR) of the individual cells decreased significantly between 12 h and 24 h of CM treatment. The decrease in NCR was well associated with arrest of proliferation in the G1 phase of the cells. The results suggest that G1 arrest of CM-treated M1 cells is an expression of cellular characteristics encoded in the differentiation program.     

Mechanism of regulating human leukemia cell growth and differentiation by a lymphokine

Human myelogenous leukemia cells can be induced to differentiate in vitro along the monocyte-macrophage pathway by a T cell lymphokine maturation inducer. Maturation inducer has now been purified from a human T cell line and determined to be a single chain protein with an approximate molecular weight of 53,500. It induces the differentiation and proliferation of human leukemic HL-60 promyelocytes in a dosage-dependent fashion. Initial interaction with cells at G1 phase induced the cells to enter proliferating S phase. Subsequent differentiation from S phase was dependent on an optimal inducer quantity (18.7 pM - 18.7 nM) which mediated growth cessation and termination differentiation to monocytes-macrophages. When inducer quantity was more or less than this optimal range, the cells did not undergo differentiation but were continuously stimulated to proliferate. This may represent an important proliferation mechanism of leukemic cells.     

Flow cytometric analysis of unbalanced control of protein accumulation and DNA synthesis in differentiating mouse myeloid leukemia cells

The protein and DNA contents of mouse myeloid leukemia M1 (clone B24) cells were determined by flow cytometry (FCM) after double fluorescent staining of the cells with fluorescein isothiocyanate and propidium iodide. FCM analysis showed that there was a linear relationship between the DNA and protein contents in logarithmically growing cells, although the protein content showed some variation. B24 cells can be induced to differentiate into macrophage-like cells by treatment with a protein inducer(s) in conditioned medium (CM) of hamster embryo cells. When the cells were treated with various concentrations of CM, cells with a 2C DNA content, G1/0 cells, increased and protein accumulated in these G1/0 cells. The increases in the number of G1/0 cells and in their protein content per cell were proportional to the concentration of CM. Serial analysis of changes in the contents of DNA and protein in differentiating B24 cells showed that DNA synthesis was suppressed by differentiation-induced block of the cell cycle at the G1/0 phase, whereas increase in the protein content was not completely suppressed by block of the cell cycle. These results suggest that unbalanced control of the DNA and protein contents of B24 cells is involved in the mechanisms of the morphological changes during differentiation into macrophages.     

Simultaneous enrichment of HL-60 cells in G1 and separation from differentiating cells by centrifugal elutriation for studies on differentiation induction

Cultures of the promyelocytic leukemia cell line HL-60 usually contain considerable numbers of spontaneously differentiating cells and are asynchronous in terms of cell-cycle phases. Counterflow centrifugal elutriation studies have been conducted to obtain a homogeneous cell population with regard to cell-cycle phases and stage of differentiation. Despite their small volume and probably because of their high buoyant density, differentiated cells are elutriated predominantly at higher flow rates. Accordingly, G1 cells elutriated at low flow rates are substantially free from spontaneously differentiating cells. By optimizing the technique, a population with approx. 90% G1 cells and less than 1% spontaneously differentiating cells was obtained. The yield in the fractions chosen was 5.1% of all cells recovered from elutriation. In culture, a cell population of this purity maintains a synchronous cell cycle for more than 2 days. This allows an exact determination of the time after induction when the first signs of differentiation occur. The presence of 1 microM retinoic acid (RA) causes the first significant increase of NBT-positive cells between the 24th and 27th h of culture.     

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.     

Commitment,fusion and biochemical differentiation of a myogenic cell line in the absence of DNA synthesis

L₆E₉ rat myoblasts derived from the L₆ cell line can be induced to differentiate to a very high percentage by manipulating the culture conditions. Under standard differentiating conditions, L₆E₉ cells divide an average of 2.5 times before differentiating and >99% of them incorporate ³H-TdR before fusing. By inhibiting DNA replication by a variety of means, data have been obtained which demonstrate that this DNa synthesis is not required to switch from growth to differentiation. After every cell division, L₆E₉ cells have the option either to fuse or to proliferate without intervening DNA synthesis.Cell cloning and DNA labeling experiments show a direct correlation between the time of culture in differentiating medium and a progressive loss of proliferative capacity of mononucleated L₆E₉ cells, demonstrating that these cells become irreversibly committed to differentiation and withdraw from the cell cycle prior to and not as a consequence of cell fusion. The commitment step occurs during the G1 phase prior to fusion. This G1 phase has a latent period during which no irreversible step toward differentiation occurs and the cells remain ambivalent toward growth or differentiation. Under proper conditions, this period is followed by an irreversible commitment toward differentiation and a loss of proliferative capacity. The kinetics of this commitment step strongly suggest that L₆E₉ cells become irreversibly committed in a stochastic manner. Once the cells have become committed, with or without DNA synthesis, they will fuse to form myotubes and biochemically differentiate in a deterministic fashion.The data presented are consistent with a stochastic model of differentiation for L₆E₉ cells and demonstrate that the switch from a proliferating to a differentiating genetic program can occur in the absence of DNA synthesis.     

Differentiated melanocyte cell division occurs in vivo and is promoted by mutations in Mitf

Coordination of cell proliferation and differentiation is crucial for tissue formation, repair and regeneration. Some tissues, such as skin and blood, depend on differentiation of a pluripotent stem cell population, whereas others depend on the division of differentiated cells. In development and in the hair follicle, pigmented melanocytes are derived from undifferentiated precursor cells or stem cells. However, differentiated melanocytes may also have proliferative capacity in animals, and the potential for differentiated melanocyte cell division in development and regeneration remains largely unexplored. Here, we use time-lapse imaging of the developing zebrafish to show that while most melanocytes arise from undifferentiated precursor cells, an unexpected subpopulation of differentiated melanocytes arises by cell division. Depletion of the overall melanocyte population triggers a regeneration phase in which differentiated melanocyte division is significantly enhanced, particularly in young differentiated melanocytes. Additionally, we find reduced levels of Mitf activity using an mitfa temperature-sensitive line results in a dramatic increase in differentiated melanocyte cell division. This supports models that in addition to promoting differentiation, Mitf also promotes withdrawal from the cell cycle. We suggest differentiated cell division is relevant to melanoma progression because the human melanoma mutation MITF(4T)(Δ)(2B) promotes increased and serial differentiated melanocyte division in zebrafish. These results reveal a novel pathway of differentiated melanocyte division in vivo, and that Mitf activity is essential for maintaining cell cycle arrest in differentiated melanocytes.     

Neural differentiation of murine embryonic stem cells ES

Pluripotent murine embryonic stem (ES) cells can differentiate into all cell types both in vivo and in vitro. Based on their capability to proliferate and differentiate, these ES cells appear as a very promising tool for cell therapy. The understanding of the molecular mechanisms underlying the neural differentiation of the ES cells is a pre-requisite for selecting adequately the cells and conditions which will be able to correctly repair damaged brain and restore altered cognitive functions. Different methods allow obtaining neural cells from ES cells. Most of the techniques differentiate ES cells by treating embryoid bodies in order to keep an embryonic organization. More recent techniques, based on conditioned media, induce a direct differentiation of ES cells into neural cells, without going through the step of embryonic bodies. Beyond the fact that these techniques allow obtaining large numbers of neural precursors and more differentiated neural cells, these approaches also provide valuable information on the process of differentiation of ES cells into neural cells. Indeed, sequential studies of this process of differentiation have revealed that globally ES cells differentiating into neural cells in vitro recapitulate the molecular events governing the in vivo differentiation of neural cells. Altogether these data suggest that murine ES cells remain a highly valuable tool to obtain large amounts of precursor and differentiated neural cells as well as to get a better understanding of the mechanisms of neural differentiation, prior to a potential move towards the use of human ES cells in therapy.     

Differences in cell division rates drive the evolution of terminal differentiation in microbes

Multicellular differentiated organisms are composed of cells that begin by developing from a single pluripotent germ cell. In many organisms, a proportion of cells differentiate into specialized somatic cells. Whether these cells lose their pluripotency or are able to reverse their differentiated state has important consequences. Reversibly differentiated cells can potentially regenerate parts of an organism and allow reproduction through fragmentation. In many organisms, however, somatic differentiation is terminal, thereby restricting the developmental paths to reproduction. The reason why terminal differentiation is a common developmental strategy remains unexplored. To understand the conditions that affect the evolution of terminal versus reversible differentiation, we developed a computational model inspired by differentiating cyanobacteria. We simulated the evolution of a population of two cell types -nitrogen fixing or photosynthetic- that exchange resources. The traits that control differentiation rates between cell types are allowed to evolve in the model. Although the topology of cell interactions and differentiation costs play a role in the evolution of terminal and reversible differentiation, the most important factor is the difference in division rates between cell types. Faster dividing cells always evolve to become the germ line. Our results explain why most multicellular differentiated cyanobacteria have terminally differentiated cells, while some have reversibly differentiated cells. We further observed that symbioses involving two cooperating lineages can evolve under conditions where aggregate size, connectivity, and differentiation costs are high. This may explain why plants engage in symbiotic interactions with diazotrophic bacteria.     

Transition of G1 to early S phase may be required for zinnia mesophyll cells to trans-differentiate to tracheary elements

We have used the Zinnia elegans mesophyll cell system, in which single isolated leaf mesophyll cells can be induced to trans-differentiate into tracheary elements in vitro, to study the relationship between the cell division cycle and cell differentiation. Almost all cells go through several rounds of division before characteristic features of tracheary element formation are observed. The addition of aphidicolin, a DNA synthesis inhibitor, blocks cell division but not cell differentiation in the zinnia system. Low concentrations of aphidicolin, which possibly delay cells in the early S phase, can significantly enhance levels of tracheary element formation. In contrast, roscovitine, an inhibitor of cyclin-dependent kinase activity, decelerates the cell division cycle and inhibits tracheary element formation with similar dose responses. Cells blocked in S phase and then transferred to roscovitine-containing medium can divide once, indicating that roscovitine may target the G1/S transition, but do not differentiate. Cells inhibited in G1/S in roscovitine-containing medium that are subsequently blocked in S phase by transfer to aphidicolin-containing medium, do not divide but do differentiate. Taken together, our results indicate that cells may be required to transit the G1/S checkpoint and enter early S phase to acquire competence to trans-differentiate to tracheary elements.     

The cell cycle,cell death,and cell morphology during retinoic acid-induced differentiation of embryonal carcinoma cells

Time-lapse films were made of PC13 embryonal carcinoma cells, synchronized by mitotic shake off, in the absence and presence of retinoic acid. Using a method based on the transition probability model, cell cycle parameters were determined during the first five generations following synchronization. In undifferentiated cells, cell cycle parameters remained identical for the first four generations, the generation time being 11–12 hr. In differentiating cells, with retinoic acid added at the beginning of the first cycle, the first two generations were the same as controls. The duration of the third generation, however, was increased to 15.7 hr while the fourth and fifth generation were approximately 20 hr, the same as in exponentially growing, fully differentiated cells. The increase in generation time of dividing cells was principally due to an increase in the length of S phase. Cell death induced by retinoic acid also occurred principally in the third and subsequent generations. Cell population growth was then significantly less than that expected from the generation time derived from cycle analysis of dividing cells. Cells lysed frequently as sister pairs suggesting susceptibility to retinoic acid toxicity determined in a generation prior to death. Morphological differentiation, as estimated by the area of substrate occupied by cells, was shown to begin in the second cell cycle after retinoic acid addition. These results demonstrate that as in the early mammalian embryo, differentiation of embryonal carcinoma cells to an endoderm-like cell is also accompanied by a decrease in growth rate but that this is preceded by acquisition of the morphology characteristic of the differentiated progeny.     

Control of normal differentiation of myeloid leukemic cells. XI. Induction of a specific requirement for cell viability and growth during the differentiation of myeloid leukemic cells

Normal hematopoietic cells require the presence of a protein (MGI) in the appropriate conditioned medium (CM) for cell viability and growth and for differentiation to mature macrophages and granulocytes. Clones of myeloid leukemic cells have been established in culture (D⁺ clones) which require CM with this protein for differentiation, but not for cell viability and growth. It has been shown that these leukemic cells can be induced by CM to again require, like normal cells, the presence of CM for cell viability and growth. Induction of this requirement, which will be referred to as RVG, occurred before the D⁺ cells differentiated to mature granulocytes. Clones of myeloid leukemic cells (D^? clones) that could not be induced to differentiate to mature cells, did not show the induction of RVG. The steroid hormones prednisolone and dexamethasone can induce some, but not all the changes associated with differentiation of D⁺ cells. Incubation with these steroids did not result in the induction of a requirement for these steroids for cell growth and viability. Studies with CM from different sources have shown, that all batches that induced RVG also induced differentiation of D⁺ cells and that both activities were inhibited after treating the CM with trypsin. It is suggested that the same protein (MGI) may be involved in both activities. Incubation of D⁺ cells with CM resulted in an increase in agglutinability by concanavalin A and this increase was maintained even in the absence of CM. This suggests, that the induction of RVG in D⁺ myeloid leukemic cells is associated with a change in the cell surface membrane.     

The Dictyostelium cell cycle and its relationship to differentiation

Abstract The Dictyostelium vegetative cell cycle is characterized by a short mitotic period followed immediately by a short S-phase (less than 30 min) and a long and variable G2 phase. The cell cycle continues during differentiation despite a decrease in cell mass: DNA replication and mitosis occur early in development and also at the tipped aggregate stage. Cells that are in mitosis, S-phase or early G2, when starved differentiate into prestalk cells and cells that are in the middle of G2 differentiate into prespore cells. We postulate that there is a restriction point late in the G2 phase, about 1–2 h before mitosis, where the cells can be arrested either by starvation and the initiation of development, by growing into stationary phase, or by prolonged incubation at low temperature. During development, this block persists to the tipped aggregate stage, where it is specifically released in prespore cells, and these cells then go through one more round of cell division. Genes encoding components of the cell cycle machinery have recently been isolated and attemps to specifically block the cell cycle by reverse genetics to study the effects on differentiation have been initiated.     

On the mechanism of erythropoietin-induced differentiation : XV. Induced transcription restricted by cytosine arabinoside

We have examined the role of DNA synthesis in the induced differentiation of erythropoietin-responsive cells (ERC) by using cultured marrow cells from plethoric rats. In such marrow cell populations there are minimal numbers of differentiated erythroid cells permitting the study of erythropoietin action on the non-differentiated primitive ERC. Cytosine arabinoside (10⁻⁴ M) and 5-fluorodeoxyuridine (10⁻⁷ M) were used for inhibition of DNA synthesis. The data indicate that DNA synthesis is not required for the early steps in the initiation of RNA synthesis or hemoglobin synthesis by erythropoietin. The evidence suggests, however, that ERC may be sensitive to erythropoietin only in a cell cycle phase after S. This period, presumably in G2, is approx. 85 min long. The full response to erythropoietin, therefore, requires DNA synthesis both to replenish the G2 compartment and to permit amplification divisions of induced cells.     

Decreased repair of radiation-induced DNA double-strand breaks with cellular differentiation.

Although the majority of mammalian cells in situ are terminally differentiated, most DNA repair studies have used proliferating cells. In an attempt to understand better the relationship between differentiation and DNA repair, we have used the murine 3T3-T proadipocyte cell line. In this model system, proliferating (stem) cells undergo growth arrest (GD cells) and subsequently terminally differentiate into adipocytes when exposed to media containing platelet-depleted human plasma. Pulsed-field gel electrophoresis was used to evaluate the induction and repair of DNA double-strand breaks (DSBs) after ionizing radiation. The levels of radiation-induced DSBs in GD and terminally differentiated cells were similar, but in both cases greater than those found in stem cells at each radiation dose tested (0 to 40 Gy); these differences appear to be due to growth arrest in G1 phase. DNA DSBs were repaired with biphasic kinetics for each cell type. For terminally differentiated cells 25% of DNA DSBs remained unrejoined compared with < 10% for GD and stem cells after a repair time of 4 h. These data indicate that terminal differentiation of 3T3-T cells is associated with a reduction in the repair of ionizing radiation-induced DNA DSBs.     

Cell-cycle characteristics of undifferentiated and differentiating embryonal carcinoma cells

The cell-cycle parameters of undifferentiated and differentiating embryonal carcinoma cells were determined. Undifferentiated cultures of an F9 subclone, OTF9-63, had a 12-hr generation time, 10-hr S, and 2-hr G2 + M. G1 was less than 0.5 hr. In contrast, OTF9-63 cells induced to differentiate by treatment with retinoic acid had a 16.8-hr generation time, 12.5-hr S, 2-hr G2 + M, and 2.3-hr G1. Similar results were obtained with undifferentiated cultures and aggregation-induced differentiating cultures of PSA-1 cells. These data demonstrate that the undifferentiated stem cells have little or no G1, and that both G1 and S lengthen during differentiation.