Myc/Max/Mad regulate the frequency but not the duration of productive cell cycles.

Upregulation of the proto-oncoprotein Myc, a basic, helix-loop-helix, leucin zipper domain transcription factor has profound consequences on cell proliferation, cell growth and apoptosis. Cell cultures of somatic c-myc-/- rat fibroblasts show extremely prolonged doubling times of 52 h. Using time-lapse microscopy, we show here that individual c-myc-/- cells proceeded within approximately 24 h through the cell cycle as fast as c-myc+/+ cells. However, c-myc-/- cells were highly sensitive to contact inhibition and readily arrested in the cell cycle already at low density. Activation of conditional MycER overcame cell cycle arrest in c-myc-/- cells and led to continuous proliferation at the expense of increased apoptosis at high cell density. Conditional expression of Mad1, a Myc antagonist, represses proliferation of different cell types including U2OS cells. In analogy to the effect of Myc, this occurs mainly by reducing the probability of cells remaining in the cycle. Our data demonstrate that the Myc/Max/Mad network does not regulate the duration of the cell cycle, but the decision of cells to enter or exit the cell cycle.

The transcriptional program of a human B cell line in response to Myc.

The proto-oncogene c-myc (myc) encodes a transcription factor (Myc) that promotes growth, proliferation and apoptosis. Myc has been suggested to induce these effects by induction/repression of downstream genes. Here we report the identification of potential Myc target genes in a human B cell line that grows and proliferates depending on conditional myc expression. Oligonucleotide microarrays were applied to identify downstream genes of Myc at the level of cytoplasmic mRNA. In addition, we identified potential Myc target genes in nuclear run-on experiments by changes in their transcription rate. The identified genes belong to gene classes whose products are involved in amino acid/protein synthesis, lipid metabolism, protein turnover/folding, nucleotide/DNA synthesis, transport, nucleolus function/RNA binding, transcription and splicing, oxidative stress and signal transduction. The identified targets support our current view that myc acts as a master gene for growth control and increases transcription of a large variety of genes.

Cell cycle activation by c-myc in a burkitt lymphoma model cell line.

The product of the proto-oncogene c-myc (myc) is a potent activator of cell proliferation. In Burkitt lymphoma (BL), a human B-cell tumor, myc is consistently found to be transcriptionally activated by chromosomal translocation. The mechanisms by which myc promotes cell cycle progression in B-cells is not known. As a model for myc activation in BL cells, we have established a human EBV-EBNA1 positive B-cell line, P493-6, in which myc is expressed under the control of a tetracycline regulated promoter. If the expression of myc is switched off, P493-6 cells arrest in G0/G1 in the presence of serum. Re-expression of myc activates the cell cycle without inducing apoptosis. myc triggers the expression of cyclin D2, cyclin E and Cdk4, followed by the activation of cyclin E-associated kinase and hyper-phosphorylation of Rb. The transcription factor E2F-1 is expressed in proliferating and arrested cells at constant levels. The Cdk inhibitors p16, p21, p27 and p57 are expressed at low or not detectable levels in proliferating cells and are not induced after repression of myc. Ectopic expression of p16 inhibits cell cycle progression. These data suggest that myc triggers proliferation of P493-6 cells by promoting the expression of a set of cell cycle activators but not by inactivating cell cycle inhibitors.

Identification of CDK4 as a target of c-MYC.

The prototypic oncogene c-MYC encodes a transcription factor that can drive proliferation by promoting cell-cycle reentry. However, the mechanisms through which c-MYC achieves these effects have been unclear. Using serial analysis of gene expression, we have identified the cyclin-dependent kinase 4 (CDK4) gene as a transcriptional target of c-MYC. c-MYC induced a rapid increase in CDK4 mRNA levels through four highly conserved c-MYC binding sites within the CDK4 promoter. Cell-cycle progression is delayed in c-MYC-deficient RAT1 cells, and this delay was associated with a defect in CDK4 induction. Ectopic expression of CDK4 in these cells partially alleviated the growth defect. Thus, CDK4 provides a direct link between the oncogenic effects of c-MYC and cell-cycle regulation.

Control of cell growth by c-Myc in the absence of cell division.

The c-Myc protein (Myc) is a transcription factor, and deregulated expression of the c-myc gene (myc) is frequently found in tumours. In Burkitt's lymphoma (BL), myc is transcriptionally activated by chromosomal translocation. We have used a B-cell line called P493-6 that carries a conditional myc allele to elucidate the role of Myc in the proliferation of BL cells. Regulation of proliferation involves the coordination of cell growth (accumulation of cell mass) and cell division [1] [2] [3]. Here, we show that division of P493-6 cells was strictly dependent on the expression of the conditional myc allele and the presence of foetal calf serum (FCS). More importantly, cell growth was regulated by Myc without FCS: Myc alone induced an increase in cell size and positively regulated protein synthesis. An increase in protein synthesis is thought to be one of the causes of cell mass increase. Furthermore, Myc stimulated metabolic activities, as indicated by the acidification of culture medium and the activation of mitochondrial enzymes. Our results confirm the model that Myc is involved in the regulation of cell growth [4] and provide, for the first time, direct evidence that Myc induces cell growth, that is, an increase in cell size, uncoupled from cell division.

Latent membrane protein 1 of Epstein-Barr virus interacts with JAK3 and activates STAT proteins.

Latent membrane protein 1 (LMP1) acts like a permanently activated receptor of the tumor necrosis factor (TNF)-receptor superfamily and is absolutely required for B cell immortalization by Epstein-Barr virus. Molecular and biochemical approaches demonstrated that LMP1 usurps cellular signaling pathways resulting in the induction of NF-kappaB and AP-1 via two C-terminal activating regions. We demonstrate here that a third region encompassing a proline rich sequence within the 33 bp repetitive stretch of LMP1's C-terminus is required for the activation of Janus kinase 3 (JAK3). The interaction of LMP1 and JAK3 leads to the enhanced tyrosine auto/transphosphorylation of JAK3 within minutes after crosslinking of a conditional NGF-R:LMP1 chimera and is a prerequisite for the activation of STAT transcription factors. These results reveal a novel activating region in the LMP1 C-terminus and identify the JAK/STAT pathway as a target of this viral integral membrane protein in B cells.

Activation of Jak2 catalytic activity requires phosphorylation of Y1007 in the kinase activation loop.

The Janus protein tyrosine kinases (Jaks) play critical roles in transducing growth and differentiation signals emanating from ligand-activated cytokine receptor complexes. The activation of the Jaks is hypothesized to occur as a consequence of auto- or transphosphorylation on tyrosine residues associated with ligand-induced aggregation of the receptor chains and the associated Jaks. In many kinases, regulation of catalytic activity by phosphorylation occurs on residues within the activation loop of the kinase domain. Within the Jak2 kinase domain, there is a region that has considerable sequence homology to the regulatory region of the insulin receptor and contains two tyrosines, Y1007 and Y1008, that are potential regulatory sites. In the studies presented here, we demonstrate that among a variety of sites, Y1007 and Y1008 are sites of trans- or autophosphorylation in vivo and in in vitro kinase reactions. Mutation of Y1007, or both Y1007 and Y1008, to phenylalanine essentially eliminated kinase activity, whereas mutation of Y1008 to phenylalanine had no detectable effect on kinase activity. The mutants were also examined for the ability to reconstitute erythropoietin signaling in gamma2 cells, which lack Jak2. Consistent with the kinase activity, mutation of Y1007 to phenylalanine eliminated the ability to restore signaling. Moreover, phosphorylation of a kinase-inactive mutant (K882E) was not detected, indicating that Jak2 activation during receptor aggregation is dependent on Jak2 and not another receptor-associated kinase. The results demonstrate the critical role of phosphorylation of Y1007 in Jak2 regulation and function.

A JAK1/JAK2 chimera can sustain alpha and gamma interferon responses.

Cell lines that are mutated in interferon (IFN) responses have been critical in establishing an essential role for the JAK family of nonreceptor tyrosine kinases in interferon signalling. Mutant gamma1A cells have previously been shown to be complemented by overexpression of JAK2. Here, it is shown that these cells carry a defect in, and can also be complemented by, the beta-subunit of the IFN-gamma receptor, consistent with the hypothesis that the mutation in these cells affects JAK2-receptor association. In contrast, mutant gamma2A cells lack detectable JAK2 mRNA and protein. By using gamma2A cells, the role of various domains and conserved tyrosine residues of JAK2 in IFN-gamma signalling was examined. Individual mutation of six conserved tyrosine residues, mutation of a potential phosphatase binding site, or mutation of the arginine residue in the proposed SH2-like domain had no apparent effect on signalling in response to IFN-gamma. Results with deletion mutants, however, indicated that association of JAK2 with the IFN-gammaR2 subunit requires the amino-terminal region but not the pseudokinase domain. Consistent with this, in chimeras with JAK1, the JAK2 amino-terminal region was required for receptor association and STAT1 activation. Conversely, a JAK1-JAK2 chimera with the amino-terminal domains of JAK1 linked to the pseudokinase and kinase domains of JAK2 is capable of reconstituting JAK-STAT signalling in response to IFN-alpha and -gamma in mutant U4C cells lacking JAK1. The specificity of the JAKs may therefore lie mainly in their structural interaction with different receptor and signalling proteins rather than in the substrate specificity of their kinase domains.

Cloning and functional analysis of the hematopoietic cell-specific phospholipase C(gamma)2 promoter.

Phospholipase C(gamma)2 (PLCgamma2) is a phospholipid-converting enzyme which, upon receptor stimulation, is activated within membrane-bound signalling complexes. In contrast to the highly ubiquitous PLCgamma1, PLCgamma2 is expressed predominantly in B-lymphocytes. Associated with antigen-coupling receptors it is activated by tyrosine phosphorylation after the triggering of B-cell surface immunoglobulin. We have cloned and sequenced the human PLCgamma2 promoter. Primer extension analysis reveals the existence of a major transcriptional start site. The TATA-less promoter contains G+C-rich stretches with a cluster of contiguous SP1 consensus sites, an NF1, and an AP2 site between bp -220 to -70. A construct containing the region from -189 to +78 confers full promoter activity, as shown by fusion to a luciferase reporter gene construct. The distal part of the promoter between bp -662 to -293 containing an SRE, EBF and CACCC box contributed negatively to promoter activity in the B-cell line Raji but not in three adherent cell lines. In Raji cells, PLCgamma2 mRNA is expressed at low levels with a half life greater than 4 h. After treatment with serum, TPA, retinoic acid, or with 5-azacytidine increased levels of PLCgamma2 mRNA were induced in B-cells.

Protein kinase C activation is involved in ultraviolet B irradiation-induced endothelial cell ICAM-1 up-regulation and lymphocyte-endothelium interaction in vitro.

Lymphocyte-endothelium interactions are pivotal steps in mediating inflammatory responses. The authors have analysed the influence of ultraviolet B (UVB) irradiation on intercellular adhesion molecule (ICAM)-1 expression on cells of the human microvascular endothelial cell line (HMEC)-1 and the intracellular signalling pathways involved. Flow cytometry revealed dose-dependent ICAM-1 up-regulation with maximum induced expression 24h after sublethal UVB irradiation of 10 mJ/cm2. While anti-tumour necrosis factor (TNF)-alpha antibodies or recombinant human interleukin (IL)-10 did not influence this response, anti-interferon (IFN)-gamma antibodies blocked the UVB-induced ICAM-1 up-regulation. Significant induction of intracellular/membrane-bound IFN-gamma was measured as early as 6 h post-UVB. Since previous work has shown a differential role of protein kinase C (PKC) in cytokine induced ICAM-1 expression, the effect of a selective bisindolylmaleimide-derived PKC-inhibitor (GF109203X) was studied. Ultraviolet B-induced ICAM-1 up-regulation was effectively blocked by the PKC-inhibitor, whereas a PKA-inhibitor was ineffective. Moreover, immunofluorescence analysis showed a radiation-induced membrane translocation of PKC-alpha, indicative of enzyme activation, in HMEC-1 cells already 30 min post-UVB. The functional relevance of the UVB-induced ICAM-1 expression and involvement of PKC in this process was demonstrated in an adhesion assay with peripheral blood mononuclear cells. In conclusion, UVB-induced ICAM-1 expression on human endothelial cells involves PKC-dependent pathways and can be prevented by a PKC-inhibitor. The use of PKC-inhibitors as additive modulators in immune reactions may bear clinical potential. The mechanisms of IFN-gamma induction in endothelial cells by UVB deserve further investigation.

JAKs and STATs branch out.

The JAK-STAT signal-transduction pathway is utilized by a wide range of cytokines to regulate gene expression. Cytokines activate members of the JAK family o f protein tyrosine kinases, which in turn activate, by tyrosine phosphorylation, one or more STAT transcription factor family members. Activated STATs form dimers, translocate to the nucleus and bind to response elements to induce transcription. Recent findings are beginning to connect JAKs and STATs with other signalling pathways: JAKs may phosphorylate and activate signalling proteins other than STATs, and STATs can be phosphorylated by non-]AK tyrosine kinases. STAT activity can also be modulated by serine phosphorylation.

Critical involvement of transmembrane tumor necrosis factor-alpha in endothelial programmed cell death mediated by ionizing radiation and bacterial endotoxin.

In this report, we show that ionizing radiation (IR) at a clinically relevant dose (4 Gy) causes apoptosis in macrovascular and microvascular human endothelial cells. Treatment of irradiated cells with a low dose of bacterial endotoxin (LPS), similar to the levels observed in serum during endotoxemia, enhanced the rate of apoptosis, although LPS alone was unable to induce programmed cell death. The cytokine and endotoxin antagonist interleukin-10 (IL-10) reduced the rate of LPS + IR-induced apoptosis to levels obtained with irradiation alone. Using neutralizing antibodies against tumor necrosis factor-alpha (TNF), we could show crucial involvement of TNF in the LPS-mediated enhancement of IR-induced apoptosis, but not in the IR-induced apoptosis per se. However, further analysis strongly suggested the transmembrane form of TNF (mTNF), but not soluble TNF, to be accountable for the LPS-mediated cytotoxic effects. Studies with anatagonistic receptor specific antibodies clearly showed that TNF receptor type I (TR60) is essential and sufficient to elicit this effect. These findings are of potential clinical importance because they may disclose a relevant mechanism that leads to endothelial damage after radiotherapy or total body irradiation used for conditioning in bone marrow transplantation and that may thus contribute to transplant related complications, especially in association with endotoxemia or related inflammatory states.

Induction of apoptosis by the c-Myc helix-loop-helix/leucine zipper domain in mouse 3T3-L1 fibroblasts.

The cellular proto-oncogene c-myc is involved in cell proliferation and transformation but is also implicated in the induction of programmed cell death (apoptosis). The c-Myc protein is a transcriptional activator with a carboxyl-terminal basic region/helix-loop-helix (HLH)/leucine zipper (LZ) domain. It forms heterodimers with the HLH/LZ protein Max and transactivates gene expression after binding DNA E-box elements. We have studied the phenotype of dominant-negative mutants of c-Myc and Max in microinjection experiments. Max mutants with a deleted or mutated basic region inhibited DNA synthesis in serum-stimulated 3T3-L1 mouse fibroblasts. In contrast, mutants of c-Myc expressing only the basic region/HLH/LZ or HLH/LZ domains rapidly induced apoptosis at low and high serum levels. Co-expression of the HLH/LZ domains of c-Myc and Max failed to do so. We suggest that the c-Myc HLH/LZ domain induces apoptosis by specific interaction with cellular factors different to Max.

Role of c-myc in simian virus 40 large tumor antigen-induced DNA synthesis in quiescent 3T3-L1 mouse fibroblasts.

Stably transfected NIH 3T3-L1 mouse fibroblasts (L1 cells) expressing the simian virus 40 large tumor antigen (LTAg) maintain c-myc expression and proliferation in low serum, whereas cells expressing the mutant form LTAg-K1, defective in binding of the retinoblastoma suppressor gene product pRb, showed reduced levels of c-myc RNA and only background levels of DNA synthesis in low serum. The role of the c-Myc protein in LTAg-induced DNA synthesis was studied in microinjection experiments. Expression of LTAg induced cellular DNA synthesis in > 95% of microinjected serum-starved L1 cells, whereas the mutant LTAg-K1 could not induce DNA synthesis. Coexpression of dominant negative c-Myc or Max mutants with LTAg inhibited DNA synthesis, indicating that functional c-Myc is necessary for induction of DNA synthesis by LTAg. Expression of c-Myc induced programmed cell death (apoptosis) in serum-starved L1 cells. Coexpression of c-Myc with LTAg-K1 restored induction of DNA synthesis without apoptosis. Expression of a truncated LTAg, LTAg-(1-259), defective in binding of the tumor suppressor gene product p53, failed to prevent c-Myc-induced apoptosis. The data indicate that c-Myc can restore the ability of LTAg-K1 to induce DNA synthesis and that LTAg-K1 prevents c-Myc-induced apoptosis in serum-starved L1 cells by its interaction with p53.

Activation of pausing RNA polymerases by nuclear run-on experiments.

The nuclear run-on transcription assay is the only approach to measure the transcriptional activity of a given gene in its genuine structural and regulatory cellular context. However, serious problems in the interpretation of results can arise from the artificial activation of paused RNA polymerases during the transcription reaction, leading to false results with regard to the level and mode of gene regulation in vivo. We have used the example of the human proto-oncogene c-myc, which has previously been reported to be regulated by premature termination of transcription, to describe the problems and pitfalls in the interpretation of nuclear run-on experiments. We show here that activation of paused, elongation-incompetent polymerases in nuclear run-on experiments produces a strong transcription signal on c-myc exon 1 in cells which do not express c-myc steady-state RNA.

Ongoing mutations in the N-terminal domain of c-Myc affect transactivation in Burkitt's lymphoma cell lines.

A panel of 18 Burkitt's lymphoma (BL) and nine other cell lines was examined for mutations in the N-terminal transactivation domain of c-Myc. Mutations leading to exchange of amino acids were detected in 13 BL but in none of the control cell lines. Mutations in c-Myc clustered between amino acid positions 57 and 62. Thr-58 and Ser-62 are known phosphorylation sites of c-Myc in vivo. BL cell lines derived from the same tumour revealed different mutations. Mutant cDNAs of the BL cell line Raji differed at 14 positions indicating ongoing mutation of the translocated c-myc during long-term propagation in cell culture. The effect of mutations on transactivation by c-Myc was tested by expression of GAL4/c-Myc fusion proteins in the BL cell line Raji. Mutants with an amino acid exchange at positions 58 or 60 transactivated a reporter gene two- to fivefold weaker than wildtype c-Myc. Thr-58 and Ser-62 were replaced by aspartic acid to mimic constitutively phosphorylated forms of c-Myc. These mutants transactivated two- to three-fold weaker than wildtype c-Myc indicating that a negative charge at positions 58 and/or 62 per se does not enhance transactivation. We propose that mutations in the N-terminal domain of c-Myc correlate with reduced transactivation and provide a growth advantage for BL cells.

Absence of a paused transcription complex from the c-myc P2 promoter of the translocation chromosome in Burkitt's lymphoma cells: implication for the c-myc P1/P2 promoter shift.

We have shown recently that pausing of RNA polymerase II (pol II) at the transcription start site regulates expression from the P2 promoter of the proto-oncogene c-myc. RNAs initiated at the P2 promoter usually contribute > 80% to steady-state c-myc RNA levels in normal cells. In Burkitt's lymphoma (BL) cells c-myc is chromosomally translocated to an immunoglobulin (Ig) gene and preferentially transcribed from the upstream P1 promoter. We have studied the activity of c-myc promoters in two BL cell lines with high expression of P1 RNA. Kinetic nuclear run-on experiments show that the initiation rate at the c-myc P1 promoter in BL2 and BL60 cells is not increased compared with control BJAB cells, whereas the number of paused polymerases at the P2 promoter is greatly diminished. The translocation c-myc gene of BL60 cells was cloned and stably transfected into the BL cell line Raji. The transfected c-myc gene regained the ability to form a paused transcription complex at the c-myc P2 promoter. The data suggest that a paused polymerase at the c-myc P2 promoter impedes transcription from the upstream P1 promoter on a normal c-myc gene. The c-myc gene on the translocation chromosome in BL cells has lost the ability to retain pol II at the P2 promoter, probably by interaction with elements of the adjacent Ig gene locus.

Early down-regulation of c-myc in dimethylsulfoxide-induced mouse erythroleukemia (MEL) cells is mediated at the P1/P2 promoters.

A block of RNA elongation in exon 1 of the murine c-myc gene has been described for normal mouse fibroblasts, lymphoid and myeloid cell lines and mouse erythroleukemia (MEL) cells. MEL cells differentiate after induction with the chemical agent dimethylsulfoxide (DMSO). The rapid initial down-regulation of c-myc that occurs after treatment with DMSO has been explained by an increase in the block of RNA elongation within the 3' part of c-myc exon 1. In contrast to these reports, we find that down-regulation of c-myc in DMSO-induced MEL cells occurs at the c-myc P1 and P2 promoters. The P1 promoter is repressed by inhibition of initiation, whereas transcription of P2 RNA is blocked by retention of RNA polymerase II at or close to the P2 promoter. The earlier described block of RNA elongation at a run of five thymidines in the 3' part of c-myc exon 1 was not observed.

Transcriptional down-regulation of c-myc in human prostate carcinoma cells by the synthetic androgen mibolerone.

The mechanism of down-regulation of c-myc RNA associated with androgen-induced suppression of the transformed phenotype in the human prostate carcinoma cell line LNCaP was investigated. The synthetic androgen mibolerone (7 alpha-17 alpha-Dimethyl-19-nortestosterone) reversibly inhibits the proliferation of LNCaP cells and, from 12-72 h after hormone addition reduces the level of c-myc transcripts to a few per cent of controls. P1, P2, and P0 c-myc transcripts decline at the same rate, whereas P3 transcripts are much less hormone sensitive. Nuclear run-on analysis revealed that c-myc is down-regulated at the level of transcription initiation in LNCaP cells. The level of c-myc transcripts prevailing in untreated control cells can be restored in androgen-induced cells by excess antiandrogen, indicating the involvement of the androgen receptor in c-myc down-regulation.