Interferons and interleukin-6 suppress the DNA-binding activity of E2F in growth-sensitive hematopoietic cells.

Transcription factor E2F binds to cellular promoters of certain growth- and cell cycle-controlling genes and forms distinct heteromeric complexes with other nuclear proteins. We show here that alpha and beta interferons (alpha, beta) and interleukin-6 abolished the E2F-containing DNA-binding complexes in Daudi Burkitt lymphoma cells and in M1 myeloblastic cells, which responded to the cytokines by suppression of c-myc transcription. Time kinetics studies showed that the abolishment of E2F complexes coincided with reduction of c-myc expression and that both molecular events preceded the cell cycle block in G0/G1 phase. In contrast, the pattern of E2F complexes remained unchanged in an interferon-treated growth-resistant Daudi cell mutant that displayed relaxed regulation of c-myc. All of the DNA-binding E2F complexes, including those containing the retinoblastoma protein (pRB), cyclin A-p33cdk2, and the free forms of E2F, were reduced by interferons or interleukin-6. Their abolishment was unperturbed by pharmacological treatments that alleviated the cyclin A and pRB responses to interferon. Thus, changes in cyclin A expression and pRB phosphorylation are not primary events that influence the pattern of E2F responses to cytokines. Addition of EDTA to cell extracts of interferon-treated Daudi cells restored the DNA-binding activity of E2F, resulting in the appearance of a single E2F complex that exclusively contained pRB. It is suggested that the regulation of E2F by growth-inhibitory cytokines that induce cell cycle exit takes place at the level of the DNA-binding activity, and by that mean it differs basically from the phase-specific regulation of E2F in cycling cells.

Alpha interferon suppresses the cyclin D3 and cdc25A genes, leading to a reversible G0-like arrest.

Alpha interferon is a potent growth inhibitor of Daudi Burkitt's lymphoma cells. We show here that alpha-interferon signaling interacted simultaneously with several components of the basic cell cycle machinery, causing cells to enter into a state that had many features characteristic of the G0 state. Within a few hours after alpha-interferon treatment, cyclin D3 mRNA and protein levels dropped to undetectable levels and, in parallel, the activities of cyclin A- and cyclin E-associated kinases were significantly reduced. The latter resulted from the rapid alpha-interferon-mediated elimination of cdc25A, a phosphatase that is required for antagonism of negative tyrosine phosphorylation of cdk2 in cyclin-cdk complexes. This regulation represents a novel mechanism through which an external inhibitory cytokine interacts with the cell cycle machinery. At later time points after alpha-interferon treatment, the levels of the 55-kDa slowly migrating hyperphosphorylated form of cyclin E and of cyclin A were also reduced. The antiproliferative effects were reversible, and cultures from which alpha interferon was removed reentered S phase after a lag that typically corresponded to approximately two doubling times. During this lag period, the expression of cyclin D3 and cyclin A, as well as of the cdc25A phosphatase, continued to be switched off, in spite of the removal of alpha interferon from the cell surface. In contrast, c-myc, which represents another downstream target gene that is subjected to negative regulation by alpha interferon, was relieved from suppression much earlier, concomitant with the decay in early signaling of the cytokine. The delayed pattern of cyclin reexpression provides evidence that alpha-interferon signaling imposes a G0-like state on this system.

The involvement of protein kinase C in mediating growth suppressive signals of interferons in hematopoietic cells.

The possible involvement of protein kinase C in transducing the growth suppressive signals of interferons was studies in this work in two different hematopoietic cell lines. Chronic exposure of human Burkitt lymphoma and mouse M1 myeloblastic cell lines to phorbol myristate acetate (PMA), reduced by more than 90% the PKC protein levels and enzymatic activity in cell extracts. The depletion of PKC from cells abrogated the ability of IFN (alpha + beta) to arrest cell growth at the G0/G1 resting phase of the cell cycle. In contrast, other responses to IFN such as the induction of (2'-5') oligoadenylate synthetase gene, continued to take place at the same dose response pattern thus excluding the possibility that early targets in the pathway, such as the number or affinity of IFN cell surface receptors might be affected by PMA. The same prolonged treatment of M1 cells with PMA did not interfere with the ability of another cytokine, transforming growth factor beta (TGF-beta), to induce the normal type of G0/G1 arrest further supporting the specificity of the effect towards IFN responses. Unexpectedly, depletion of PKC from cells did not interfere with the negative effects of IFN on c-myc mRNA and protein expression in spite of the direct involvement of this molecular event in growth responses to IFN. The putative PKC dependent molecular event could therefore function either downstream to or in combination with the reduction in c-myc protein levels, providing a necessary but not a sufficient step to arrest cell cycle progression at the G0/G1 phase.

Interferons and interleukin 6 suppress phosphorylation of the retinoblastoma protein in growth-sensitive hematopoietic cells.

One approach to identify postreceptor molecular events that transduce the negative-growth signals of inhibitory cytokines is to analyze the cytokine-induced modifications in the expression of cell-cycle-controlling genes. Here we report that suppression of phosphorylation of the retinoblastoma gene product (pRb) is a receptor-generated event triggered by interferons and interleukin 6 (IL-6) in hematopoietic cell lines. The conversion of pRb to the underphosphorylated forms occurs concomitantly with the decline in c-myc protein expression and both events precede the G0/G1-phase arrest induced by the cytokines. Loss of IL-6-induced c-myc responses in cells that have been stably transfected with constitutive versions of the c-myc gene abrogates the typical G0/G1-phase arrest but does not prevent the specific dephosphorylation of pRb. Conversely, depletion of protein kinase C from cells interferes with part of the interferon-induced suppression of pRb phosphorylation and relieves the G0/G1-phase cell-cycle block without affecting the extent of c-myc inhibition. None of the cytokines, including transforming growth factor beta, reduce the phosphorylation of pRb in S-phase-blocked cells. In contrast, the other IL-6-induced molecular responses, including the decline in c-myc mRNA levels, are not phase-specific and develop normally in S-phase-blocked cells that are depleted of the underphosphorylated functional forms of pRb. These and the suppression of pRb phosphorylation, which occur independently of each other, and suggest that the development of the interferon- or IL-6-induced G0/G1-specific arrest requires at least these two receptor-generated events.