Polyoma middle T antigen in HL-60 cells accelerates hematopoietic myeloid and monocytic cell differentiation.

Expression of the polyoma virus middle T antigen in HL-60 cells accelerates their differentiation in response to both monocytic and granulocytic differentiation-inducing agents. Middle T-expressing cells treated with the granulocytic inducer retinoic acid or the monocytic inducer 1,25-dihydroxy vitamin D3 differentiated 24 h earlier than parental, mock-electroporated, or vector control cell lines. The rapid onset of differentiation correlated with an increase in the cellular level of the middle T protein as well as two known retinoic-acid-inducible markers in HL-60 cells: the paxillin and transglutaminase gene products. The accelerated functional differentiation response and expression of retinoic-acid-inducible markers indicate that middle T played a causal role in differentiation. Thus, expression of the polyoma middle T antigen in HL-60 cells enhanced a variety of molecular changes associated with cellular differentiation.

Expression of activated RAF accelerates cell differentiation and RB protein down-regulation but not hypophosphorylation.

Expression of an activated raf transgene accelerated the terminal myeloid differentiation of HL-60 human promyelocytic leukemia cells induced by retinoic acid. A similar result was obtained when 1,25-dihydroxyvitamin D3 was used to induce monocytic differentiation. The stable transfectants were derived by transfecting HL-60 cells with DNA encoding an N-terminal truncated raf-1 protein. In normal HL-60 cells retinoic acid is known to induce a colony-stimulating factor-1 (CSF-1)-dependent metabolic cascade culminating in G0 arrest and phenotypic conversion. Early in this cascade, expression of the RB tumor suppressor gene product is down-regulated. A progressive redistribution of the form of the protein from largely hyperphosphorylated protein to the hypophosphorylated form begins later with G0 arrest and differentiation. In the activated raf-transfected cells, RB down regulation occurred more rapidly, consistent with accelerated differentiation. But the conversion to the hypophosphorylated form was not accelerated and occurred after G0 arrest and phenotypic conversion to myeloid differentiated cells. Thus raf activation appears to be a component of the induced metabolic cascade culminating in terminal differentiation. In this cascade raf activation promotes RB down-regulation. The data are consistent with a model in which raf is an effector of the CSF-1-dependent metabolic cascade which culminates in terminal cell differentiation, and RB downregulation is one of the downstream consequences of RAF action. Furthermore, they indicate that RB down-regulation may be an essential component of the cellular processes causing G0 arrest and differentiation, but RB hypophosphorylation is more likely a consequence thereof and not a cause.

C-FMS dependent HL-60 cell differentiation and regulation of RB gene expression.

The dependence of induced myelomonocytic cell differentiation, and regulation of the RB tumor suppressor gene during this process, on the c-fms gene product, the CSF-1 lymphokine receptor, was determined in HL-60 promyelocytic leukemia cells. Adding a monoclonal antibody with specificity for the c-fms gene product to cells treated with various inducers of myelomonocytic or macrophage differentiation, including retinoic acid and 1,25-dihydroxy vitamin D3, inhibited the rate of differentiation. During the period of inducer treatment usually preceding onset of differentiation, longer periods of antibody exposure caused greater inhibition of differentiation. In a stable HL-60 transfectant overexpressing the CSF-1 receptor at the cell surface due to a constitutively driven c-fms trans gene, the rate of differentiation was enhanced compared to the wild type cell, consistent with a positive regulatory role for the CSF-1 receptor. The anti-fms antibody caused much less inhibition of differentiation in the transfectants than in wild type cells, consistent with a larger number of receptors causing reduced sensitivity. During the induced metabolic cascade leading to differentiation, the typical early down regulation of RB gene expression was inhibited by the antibody. The antibody itself caused an increase in RB expression per cell, which offset the decrease normally caused by differentiation inducers (1,25-dihydroxy vitamin D3 and retinoic acid). The changes in RB expression preceded changes in the RB protein to the hypophosphorylated state. Most of the RB protein in proliferating cells was phosphorylated and no significant accumulation of hypophosphorylated RB protein occurred until after onset of G0 arrest. Thus the metabolic cascade leading to myelomonocytic differentiation of HL-60 cells appears to be driven by a function of the c-fms protein. Inhibiting that process by attacking this receptor impedes differentiation and also compromises the early down regulation of RB tumor suppressor gene expression which normally precedes differentiation. These findings provide additional support for a potential role for down regulating RB expression in promoting cell differentiation, and suggest the possibility that RB may be either a target or intermediate mediator of CSF-1 actions.

12-O-tetradecanoylphorbol-13-acetate and staurosporine induce increased retinoblastoma tumor suppressor gene expression with megakaryocytic differentiation of leukemic cells.

The phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), induced increased expression of the retinoblastoma (RB) tumor suppressor gene product in the course of megakaryocytic differentiation of the K562 human leukemia cell line, a differentiatively multipotent hematopoietic precursor cell. The induced increase in RB protein per cell occurred early, by 8 h of treatment, preceding any significant phenotypic differentiation evidenced by cellular expression of the CD41 differentiation-specific megakaryocytic cell surface marker, but not inhibition of cell cycle transit, leading to a cell population arrested with 2 n, 4 n, and 8 n DNA content. The increase in RB protein per cell occurred for cells in all cell cycle phases. Staurosporine (STSP) was found to induce a similar course of cell cycle arrest and differentiation. Furthermore, STSP caused an up-regulation of RB expression similar to that caused by TPA. Almost all of the RB protein is phosphorylated in untreated cells, but TPA and STSP both caused the late appearance of hypophosphorylated RB protein following cell cycle arrest. The STSP-caused hypophosphorylation was much later than the TPA effect. Hypophosphorylation of RB is, thus, not necessarily a prerequisite for cell cycle arrest but may be a consequence of G0. Given that TPA can be an activator and STSP an inhibitor of protein kinase C, it appears that the induced processes of tumor suppressor gene regulation and growth and differentiation control are not necessarily protein kinase C dependent in K562 cells. Furthermore, the findings that these two presumably divergent inducing agents caused a similar increase in RB gene expression suggests that the up-regulation of RB associated with differentiation is not a coincidence of just one specific inducer but may be a common essential feature of the induced differentiation. The amount of RB protein per cell increased within hours of exposure to TPA or STSP and may have a role in the induced metabolic cascade producing the new phenotype.